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Intellectual disability - microarray and sequencing v5.127 NSF Achchuthan Shanmugasundram Added comment: Comment on phenotypes: This gene is now associated with a relevant phenotype in OMIM (MIM #619340), but not in Gene2Phenotype.
Intellectual disability - microarray and sequencing v5.127 NSF Achchuthan Shanmugasundram Phenotypes for gene: NSF were changed from Developmental and epileptic encephalopathy 96, OMIM:619340 to Developmental and epileptic encephalopathy 96, OMIM:619340
Intellectual disability - microarray and sequencing v5.127 NSF Achchuthan Shanmugasundram Added comment: Comment on phenotypes: This gene is now associated with a relevant phenotype in OMIM (MIM #619340), but not in Gene2Phenotype.
Intellectual disability - microarray and sequencing v5.127 NSF Achchuthan Shanmugasundram Phenotypes for gene: NSF were changed from Developmental and epileptic encephalopathy 96, OMIM:619340 to Developmental and epileptic encephalopathy 96, OMIM:619340
Intellectual disability - microarray and sequencing v5.127 NSF Achchuthan Shanmugasundram Added comment: Comment on phenotypes: This gene is now associated with a relevant phenotype in OMIM (MIM #619340), but not in Gene2Phenotype.
Intellectual disability - microarray and sequencing v5.127 NSF Achchuthan Shanmugasundram Phenotypes for gene: NSF were changed from Developmental and epileptic encephalopathy 96, OMIM:619340 to Developmental and epileptic encephalopathy 96, OMIM:619340
Intellectual disability - microarray and sequencing v5.127 NSF Achchuthan Shanmugasundram Deleted their comment
Intellectual disability - microarray and sequencing v5.127 NSF Achchuthan Shanmugasundram Added comment: Comment on phenotypes: This gene is now associated with a relevant phenotype in OMIM (MIM #619340), but not in Gene2Phenotype.
Intellectual disability - microarray and sequencing v5.127 NSF Achchuthan Shanmugasundram Phenotypes for gene: NSF were changed from Developmental and epileptic encephalopathy 96, OMIM:619340 to Developmental and epileptic encephalopathy 96, OMIM:619340
Intellectual disability - microarray and sequencing v5.126 NSF Achchuthan Shanmugasundram Deleted their comment
Intellectual disability - microarray and sequencing v5.126 NSF Achchuthan Shanmugasundram Added comment: Comment on phenotypes: This gene is now associated with a relevant phenotype in OMIM (MIM #619340), but not in Gene2Phenotype.
Intellectual disability - microarray and sequencing v5.126 NSF Achchuthan Shanmugasundram Phenotypes for gene: NSF were changed from Developmental and epileptic encephalopathy 96, OMIM:619340 to Developmental and epileptic encephalopathy 96, OMIM:619340
Intellectual disability - microarray and sequencing v5.126 NSF Achchuthan Shanmugasundram Added comment: Comment on phenotypes: This gene is now associated with a relevant phenotype in OMIM (MIM #619340), but not in Gene2Phenotype.
Intellectual disability - microarray and sequencing v5.126 NSF Achchuthan Shanmugasundram Phenotypes for gene: NSF were changed from Seizures; EEG with burst suppression; Global developmental delay; Intellectual disability to Developmental and epileptic encephalopathy 96, OMIM:619340
Intellectual disability - microarray and sequencing v5.125 NSF Achchuthan Shanmugasundram reviewed gene: NSF: Rating: RED; Mode of pathogenicity: None; Publications: 36645181; Phenotypes: Developmental and epileptic encephalopathy 96, OMIM:619340; Mode of inheritance: MONOALLELIC, autosomal or pseudoautosomal, NOT imprinted
Intellectual disability - microarray and sequencing v5.125 NSF Achchuthan Shanmugasundram Publications for gene: NSF were set to 31675180; 36645181
Intellectual disability - microarray and sequencing v5.125 NSF Achchuthan Shanmugasundram Publications for gene: NSF were set to 31675180
Intellectual disability - microarray and sequencing v3.1750 GATM Arina Puzriakova Phenotypes for gene: GATM were changed from Cerebral creatine deficiency syndrome 3, 612718; ARGININE:GLYCINE AMIDINOTRANSFERASE DEFICIENCY (AGAT DEFICIENCY) to Cerebral creatine deficiency syndrome 3, OMIM:612718
Intellectual disability - microarray and sequencing v3.1564 BUB1 Konstantinos Varvagiannis gene: BUB1 was added
gene: BUB1 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: BUB1 was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: BUB1 were set to 35044816
Phenotypes for gene: BUB1 were set to Congenital microcephaly; Global developmental delay; Intellectual disability; Abnormal heart morphology; Growth delay
Penetrance for gene: BUB1 were set to Complete
Review for gene: BUB1 was set to AMBER
Added comment: A recent study provides evidence that this gene (biallelic variants) is relevant for inclusion in the DD/ID panel likely with amber / green rating (2 unrelated individuals with similar phenotype, 3 variants, role of this gene, extensive variant studies and demonstrated effects on cohesion and chromosome segregation, similarities with other disorders caused by mutations in mitosis-associated genes at the clinical and cellular level || number of affected subjects/families, different protein levels/kinase activity likely underlying few differences observed, role of monoallelic variants unclear).

This gene could probably be included in other panels e.g. for microcephaly (not added).

There is no BUB1-related phenotype in OMIM, G2P, SysID, PanelApp Australia.

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Carvalhal, Bader et al (2022 - PMID: 35044816) describe the phenotype of 2 unrelated individuals with biallelic BUB1 pathogenic variants and provide evidence for the underlying mechanism for this condition.

Common features comprised congenital microcephaly (2/2 | -2,8 and -2.9 SDs respectively / -7 and -4,9 SDs on last evaluation), DD/ID (2/2 - in one case with formal evaluation mild), some degree of growth retardation (2/2) and cardiovascular findings (2/2 - small ASD type II). Other findings limited to one subject included Pierre-Robin sequence, Axenfeld-Rieger anomaly, choanal stenosis, hypospadias, tracheal stenosis, etc.

Initial genetic testing was normal (incl. CMA in both, metabolic testing and individual genes incl. PITX2, GREM1, FOXD3, FOXC1 for one proband).

Exome sequencing revealed homozygosity for a start-lost variant (NM_004336.4:c.2T>G / p.?) in the first subject (P1). The variant lied within a 14-Mb region of homozygosity (no reported consanguinity). The second individual (P2) was compound htz for a splice-site and a frameshift variant (c.2625+1G>A and c.2197dupG) with Sanger sequencing used for confirmation and segregation studies.

BUB1 encodes BUB1 Mitotic checkpoint serine/threonine kinase (/Budding uninhibited by benzimidazoles 1, s. cerevisiae, homolog of) a multifunctional component of the segregation machinery contributing to multiple mitotic processes. The protein has a kinetochore localization domain, multiple binding motifs and a C-terminal kinase domain (aa 784-1085) this structure allowing both kinase dependent/independent activities.

cDNA sequencing revealed that the splice variant leads to skipping of ex21 and in-frame deletion of 54 residues in the kinase domain (c.2625+1G>A / p.Val822_Leu875del).

Both individuals exhibited normal BUB1 mRNA levels (fibroblasts in both, tracheal tissue in one) but severely reduced protein levels (fibroblasts). A shorter protein product corresponding to the in-frame deletion variant was also detected.

The authors performed additional experiments to confirm small amounts of full-length protein produced by the start-lost variant. This was shown in SV40-transformed fibroblasts from the corresponding individual (treatment with a proteasome inhibitor resulted also in higher levels). Upon generation RPE1 cells using CRISPR for the start-lost variant, again, small amounts of full length protein were detected, which was not the case for complete knockout HAP1 cells. No shorter versions could be detected in the patient cells or RPE1 cells, arguing against utilization of an alternative start codon. (Use of non-AUG start codons discussed based on literature).

In line with small amounts of full-length protein the authors provided evidence for residual kinase activity for the start-loss variant (through proxy of phosphorylation of its substrate and use of a BUB1 kinase inhibitor). Cells from the individual with the frameshift variant and the splice variant had no residual kinase activity.

The authors provide evidence for mitotic defects in cells from both individuals with prolonged mitosis duration and chromosome segregation defects. Some patient-specific findings were thought to be related with BUB1 protein levels (affecting BUB1-mediated kinetochore recruitment of BUBR1, important for chromosome alignment) and others due to residual kinase activity [->phosphorylation of H2A at Threonine 120-> affecting centromeric recruitment of Aurora B, SGO1 (role in protection of centromeric cohesion), TOP2A (a protein preventing DNA breakage during sister chromatid separation), these correlated with high anaphase bridges (in P2), aneuploidy observed in lymphoblasts and primary fibroblasts from P2 but not P2's lymphocytes or lymphocytes from P1) and defective sister chromatid cohesion defects (in primary fibroblasts from P2, milder effect for P1).

Overall the authors provide evidence for overlapping clinical and cellular phenotype for this condition with primary microcephalies (MCPH - mutations in genes for mitotic regulators incl. kinetochore proteins or regulators of chromosome organization), mosaic variegated aneuploidy (biallelic variants in genes for kinetochore proteins, with random aneuploidies occurring in >5% cells of different tissues) and cohesinopathies (mostly Roberts or Warsaw breakage syndromes - characterized by cohesion loss and/or spontaneous railroad chromosomes).

Mouse model: Hmz disruption in mice is lethal shortly after E3.5 (cited PMID: 19772675), while a hypomorphic mutant mouse (lacking exons 2-3, expressing <5% of wt protein levels) is viable but exhibits increased tumorigenesis with aging and aneuploidy (cited PMID: 19117986). Mutant mice that lack kinase activity though with preserved Bub1 protein abundance, did not display increased susceptibility, despite substantial segregation errors and aneuploidies (cited PMID: 23209306).

The authors note that monoallelic germline BUB1 variants have been described in small number of individuals with CRC, exhibiting reduced expression levels and variegated aneuploidy in multiple tissues (cited PMID: 23747338) although the role of BUB1 is debated (cited PMIDs: 27713038, 29448935).

Based on the discussion, complete loss of BUB1 activity is presumed to be embryonically lethal based on the mouse study (PMID: 19772675) and reduced BUB1 expression associated with spontaneous miscarriages (cited PMID: 20643875, to my understanding in this study mRNA levels remained relatively constant despite reduced Bub1 protein levels, mRNA RT-PCR followed by sequencing revealed only 2 synonymous BUB1 variants).
Sources: Literature
Intellectual disability - microarray and sequencing v3.1561 DPH5 Konstantinos Varvagiannis gene: DPH5 was added
gene: DPH5 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: DPH5 was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: DPH5 were set to 35482014
Phenotypes for gene: DPH5 were set to Abnormality of prenatal development or birth; Neonatal hypotonia; Global developmental delay; Intellectual disability; Seizures; Abnormality of the cardiovascular system; Abnormality of the globe; Feeding difficulties; Short stature; Abnormality of head or neck
Penetrance for gene: DPH5 were set to unknown
Review for gene: DPH5 was set to AMBER
Added comment: Shankar et al (2022 - PMID: 35482014) present evidence for a diphthamide-deficiency syndrome due to biallelic DPH5 pathogenic variants.

As the authors summarize, DPH5 encodes a methyltransferase critical to the biosynthesis of diphthamide. Diphthamide is a post translationally modified histidine residue found in eukaryotic elongation factor 2 (eEF2). eEF2 is essential for mRNA translation and protein synthesis. The role of diphthamide is not clear, although it serves as a target for ADP-ribosylation, the latter resulting in inactivation of the eEF2 (inhibition of its translocation activity) and arrest of protein synthesis. Biosynthesis of diphthamide is complex involving multiple components (DPH1-DPH7) and the methylating co-factor S-adenosyl methionine, with 2 diphthamide-deficiency disorders due to biallelic DPH1 or DPH2 pathogenic variants and a NDD phenotype reported to date.

The authors describe a phenotypic spectrum associated with biallelic DPH5 variants ranging from a prenatally lethal presentation to profound neurodevelopmental disorder. Details are provided on 5 individuals from 3 unrelated families. While one subject died at the age of few days due to multisystem complications, the phenotype appeared to be relatively consistent with prenatal findings (decreased fetal movements in 2 from 2 families, polyhydramnios in 2 from 2 families), hypotonia, global DD and ID (4/4 from 2 families - profound in 3), seizures (3/5 from 2 families - abnormal EEG in 4/4), cardiovascular findings (5/5, MVP and regurgitation in 2 from Fam1 || aortic dilatation in 2 sibs from Fam2 || VSD, ASD and hypopl. PA, pericardial effusion in 5th), GI issues (5/5, poor feeding in 4), short stature (4/4). Ocular findings were reported in 3/4 (gray sclerae in 2, ocular melanocytosis in 2). The authors describe some common craniofacial findings incl. broad/prominent forehead (5/5), sparse eyebrows (4/5), downturned corners of mouth or triangular chin (each in 3/5).

WES/WGS revealed biallelic DPH5 variants in all affected individuals, namely: homozygosity for a missense variant in 2 sibs (NM_001077394.2:c.779A>G/p.His260Arg). Homozygosity for c.521dupA/p.Asn174LysTer10 for the individual deceased in the neonatal period (for this family there was significant history of spontaneous miscarriages/stillbirth/neonatal death). Two sibs born to non-consanguineous parents were compound htz for a stopgain and a missense SNV (c.619C>T/p.Arg207*, c.329A>G/p.Asn110Ser).

In silico modeling revealed that the pLoF variants, not predicted to lead to NMD, likely remove the domain for interaction with eEF2 while the missense ones also affected interaction with eEF2.

In recombinant MCF7 breast cancer cell line-derived DPH5-knockouts, transfected with recombinant expr. plasmids encoding wt or the 4 variants, the 2 truncating variants were shown to affect ADP-ribosylation of eEF2's diphthamide (total lack / minimal enzymatic activity for Arg207* and Asn174Lysfs respectively). Asn110Ser and His260Arg had residual activities which was thought to be explained by high expression levels compensating partial inactivation (given the multicopy plasmid-driven expression).

ADP-ribosylation assays in S. cerevisiae demonstrated loss of function for the 2 truncating variants. Although the 2 missense variants retained sufficient activity to produce diphthamide (assayed through toxin induced ADP-ribosylation of eEF2), more sensitive assays indicated that diphthamide synthesis was also partially compromised for both variants.

Generation of a knockin mouse model for His260Arg, appeared to recapitulate the human phenotypes with craniofacial, ophthalmologic, cardiac and visceral abnormalities and hmz mice being subviable. A single homozygous liveborn mouse had low birthweight, FTT, craniofacial dysmorphology, polydactyly, abnormal grooming behavior and early death. Few heterozygous embryos had craniofacial features, decreased body weight, reduced neuromuscular function without other abnormalities, either due to their inbred background or in the context of milder phenotype of heterozygosity in mice.

DPH5 is ubiquitously expressed in all human tissues. The gene has a pLI of 0 and LOEUF score of 0.77 (0.48-1.27) in gnomAD. The authors refer to unpublished data, noting that complete absence of DPH5 is incompatible with life with embryonic lethality of a Dph5(ko/ko) line.

The phenotype bears similarities to DPH1- and DPH2- related NDDs (both AR / green and amber respectively in ID panel) and appears to be more severe compared to the phenotype of de novo EEF2 variants (cited PMID: 33355653).

Please consider inclusion in the ID panel with amber (4 individuals from 2 families with ID) / green rating (rather consistent phenotype in 3 families probably representing a continuous spectrum, variant studies, mouse model, similarities with diphthamide-deficiency syndromes). Also consider amber rating in the epilepsy panel (3 individuals from 2 families reported). The gene may be also relevant in other gene panels e.g. for congenital heart disease, short stature, etc (not added).
Sources: Literature
Intellectual disability - microarray and sequencing v3.1558 SLC35B2 Konstantinos Varvagiannis gene: SLC35B2 was added
gene: SLC35B2 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: SLC35B2 was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: SLC35B2 were set to 35325049
Phenotypes for gene: SLC35B2 were set to Abnormality of the skeletal system; Short long bone; Short stature; Abnormality of epiphysis morphology; Scoliosis; Multiple joint dislocation; Global develpmental delay; Intellectual disability; CNS hypomyelination; Abnormality of the corpus callosum; Cerebral atrophy; Abnormality of the amniotic fluid
Penetrance for gene: SLC35B2 were set to Complete
Review for gene: SLC35B2 was set to AMBER
Added comment: 2 unrelated individuals with biallelic SLC35B2 variants have been reported. DD and ID were part of the phenotype.

There is currently no associated phenotype in OMIM/G2P/SysID. The gene has amber rating in the leukodystrophies panel of PanelApp Australia.

Consider inclusion in the current panel (or other possibly relevant ones eg. for skeletal disorders, short stature, white matter disorders, corpus callosum, etc) with amber rating.

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Guasto et al (2022 - PMID:35325049) report 2 unrelated individuals with biallelic SLC35B2 variants.

SLC35B2 encodes solute carrier family 35 (3'-phosphoadenosine 5'-phosphosulfate (PAPS) transporter), member B2.

The protein is located in the Golgi membrane and serves as transporter of the activated nucleotide sulfate PAPS from the cytosol, where it is synthesized to the Golgi lumen. Another PAPS transporter is encoded by SLC35B3. In the Golgi apparatus PAPS serves as substrate of sulfotransferases for the addition sulfate to the covalently attached GAG chains of proteoglycans (PGs).

The phenotype corresponded to a chondrodysplasia manifesting as severe pre- and postnatal growth retardation (height <-4 SD and -8 SD), early scoliosis, multiple joint dislocations (in one). There was severe DD affecting motor and expressive language development with associated ID. Brain imaging was suggestive of hypomyelinating leukodystrophy with thin corpus callosum and cerebral atrophy. One individual had a cleft palate in the context of Pierre Robin sequence.

Both individuals were investigated with exome sequencing.

The first individual - born to consanguineous parents - was homozygous for an in-frame del (NM_178148.3:c.1218_1220del, p.Leu407del) with Sanger sequencing confirming the variants, and heterozygosity in parents and 2 unaffected sibs. There was an initially identified hmz CUL7 variant (for 3M syndrome), which was not felt sufficient to explain the severity of the phenotype and notably ID.

The 2nd proband was homozygous for a fs variant (c.1224_1225delAG / p.Arg408SerfsTer18 - leading to loss of the last 8 amino acids) occurring in the context of uniparental isodisomy [iUPD(6)] spanning the complete chr6 based on the exome data.

Among the evidence presented for SLC35B2 and the variants :
- SLC35B2 has high mRNA expression in fetal and adult mouse brain and other tissues.
- Upon qPCR analysis of mRNA expression in human brain samples, the gene had expression across the brain (frontal lobe grey matter, subcortical frontal white matter/cerebellum).
- High expression was shown upon analysis of mouse brain single cell RNA data (EMBL) in oligodendrocytes and microglial cells.
- RT-PCR on mRNA from skin fibroblasts (both individuals) revealed significant decrease of SCL35B2 mRNA levels compared to controls.
- Transfection of C-terminal c-myc tagged wt or mutant proteins in HEK293F cells, followed by western blotting did not reveal significant difference at the protein level. Wt SLC35B2 localized at the Golgi apparatus as suggested by colocalization with GM130 marker. The 2 variants however displayed only partial colocalization (/loss of localization specificity) with diffuse signal in the cell.
- Chondroitin sulfate disaccharide sulfation was decreased upon HPLC disaccharide analysis in patient fibroblasts and bikunin (a circulating proteoglycan in blood) electrophoretic pattern in patient sera.
- Disorders due to variants in genes implicated in proteoglycan biogenesis (e.g. XYLT1, B3GALT6, CHSY1) are associated with skeletal/connective tissue manifestations with DD/ID.
- C-elegans model lacking pst-1 (SLC35B2 ortholog) provides support that the protein is required for migration, axonal guidance, and presynaptic development in a subset of neurons.
- dsm-1 - the rat ortholog - is expressed in rat brain in D-serine and NMDA receptor rich regions. When expressed in Xenopus oocytes it accelerated the efflux of D-serine (a co-agonist for NMDA receptor).
- Variants in other members of SLC superfamily (e.g. SLC17A5, SLC35A3, SLC29A3, SLC35A2) have been associated with brain-bone phenotypes.
Sources: Literature
Intellectual disability - microarray and sequencing v3.1534 ATP2B1 Konstantinos Varvagiannis gene: ATP2B1 was added
gene: ATP2B1 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: ATP2B1 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
Publications for gene: ATP2B1 were set to 35358416; 35358416
Phenotypes for gene: ATP2B1 were set to Global developmental delay; Intellectual disability; Autism; Behavioral abnormality; Seizures; Abnormality of head or neck
Penetrance for gene: ATP2B1 were set to unknown
Review for gene: ATP2B1 was set to GREEN
Added comment: Monoallelic missense/pLoF ATP2B1 variants have been reported in 12 unrelated individuals with DD/ID making this gene relevant to the current panel.

Currently there is no associated phenotype in OMIM, G2P, SysID, PanelApp Australia.

Based also on the evidence discussed below, please consider inclusion with green (rather than amber) rating.
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Rahimi et al (2022 - PMID: 35358416) describe 12 unrelated individuals with monoallelic ATP2B1 variants.

Phenotype consisted of DD (12/12), ID [9/12 - mild or less commonly moderate, with 3 additional subjects "unclassified" likely due to their age (#6: 3y nonverbal/nonambulatory, could sit and roll / #8: 3y, sitting at 1y, 1st words:26m / #12: at 5y nonambulatory/nonverbal)]. Behavioral issues were observed in 8/11 (ASD in 5/11). Seizures were reported in 5/12 (one further had abnormal EEG). Minor features - albeit not consistent/without recognizable gestalt - were reported in 6. Anomalies of digits and marfanoid habitus were reported in 4 and 2.

All subjects were investigated by singleton/trio exome sequencing.

Previous investigations incl. karyotype, CMA, analysis of individual genes (e.g. FMR1, ZEB2) or metabolic workup were normal for several individuals with one having a concurrent diagnosis of mosaic (20%) XXY and another harboring an additional hmz variant for a liver disorder.

9 different missense and 3 nonsense ATP2B1 variants were identified, shown to have occurred de novo in all cases where parental samples were available (9/12).

ATPase plasma membrane Ca+2 transporting 1, the protein encoded by ATP2B1, is an ATP-driven calmodulin-dependent Ca+2 pump which removes intracellular calcium from the cytosol. As the authors comment calcium pumps are thought to have a crucial role on neuronal function.

All variants identified were absent from gnomAD with the exception of c.2365C>T / p.Arg789Cys (de novo) which is present once in the database. ATP2B1 has a pLI of 1 and a missense Z-score of 5.29.

The variants affected several ATP2B1 isoforms. Variants were reported using NM_001001323.2, corresponding to ATP2B1a isoform which is mainly detected in brain (as also in GTEx).

In silico predictions were in favor of a deleterious effect and structural modeling supported the role of the affected residues.

The nonsense variants occurred in positions predicted to lead to NMD (not studied).

Transfection of an ATP2B1-yellow fluorescent protein (YFP) expression plasmid for wt or variants in HEK293 cells, revealed membranous fluorescence for wt, significantly altered localization for 3 variants (Asp239Gly, Thr264Ile, Arg991Gln), shift to cytoplasmic localization for 4 others (Thr425Lys, Arg763Pro, Glu824Lys, Gln857Arg) with statistically non-significant effect for 2 others (His459Arg and Arg789Cys).

Fluorometric [Ca+2]i analysis in HEK293 cells expressing wt or variant ATP2B1 revealed that all missense variants affected Ca+2 transport. This was not the case for wt ATP2B1 or for another missense variant used as control (drawn from gnomAD).

Of note, a further (13th) affected individual with another missense variant (c.1793T>C / p.Ile598Thr) was excluded from the phenotypic analysis. The membrane localization and Ca+2 transport did not appear to be affected by this variant which was classified as VUS although it a different impact from those studied.

Overall loss-of-function is thought to be the underlying mechanism based on the above (and supported by few reported cases with gross deletions spanning also ATP2B1). A dominant negative effect for missense variants (affecting heteromeric complex formation with neuroplastin or basigin) could not be completely excluded, but not supported either by the localization of the identified variants.

In the supplement the authors include 3 DDD study participants previously reported to harbor de novo pLoF/missense variants though with few available clinical information (PMID: 33057194 - DDD13k.05076 : c.2883del / DDD13k.04028 : c2512A>C - p.Ile838Val / DDD13k.08944 : c.2129A>C - p.Asp710Ala).

The authors discuss on the role of ATP2B1 on Ca+2 homeostasis in the CNS and neurodevelopment overall (also based on isoform expression in rat brain).
Sources: Literature
Intellectual disability - microarray and sequencing v3.1525 CACNA2D1 Konstantinos Varvagiannis gene: CACNA2D1 was added
gene: CACNA2D1 was added to Intellectual disability. Sources: Literature,Other
Mode of inheritance for gene: CACNA2D1 was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: CACNA2D1 were set to 35293990; 28097321
Phenotypes for gene: CACNA2D1 were set to Abnormal muscle tone; Feeding difficulties; Global developmental delay; Intellectual disability; Seizures; Microcephaly; Abnormality of the corpus callosum; Cerebral atrophy; Abnormality of movement; Cortical visual impairment; Pain insensitivity
Penetrance for gene: CACNA2D1 were set to Complete
Review for gene: CACNA2D1 was set to GREEN
Added comment: Consider inclusion in the current panel with green rating.

Recent report of 2 unrelated individuals with DEE due to biallelic CACNA2D1 variants. Both referred to neurology/genetics for hypotonia/severe DD prior to onset of seizures.

One further individual with hypotonia and severe ID (seizures not discussed, age unknown).

Gene with established role, encoding α2δ-1 subunit of Cav channels. Studies for the variants support loss-of-function as the underlying effect.

Eventual contribution of monoallelic variants to NDD-phenotypes discussed (and put in question) in Ref [1] below.

There is currently no phenotype for CACNA2D1 in OMIM/G2P. In SysID this gene is listed among the candidates for ID, based on a previous report. CACNA2D1 is not currently included in the ID/epilepsy panels in PanelApp Australia.

See also relevant review in epilepsy panel (Dr. H. Lord).

Please consider also inclusion in other panels (e.g. microcephaly, corpus callosum, movement disorders, etc).

[1] ----
Dahimene et al (2022 - PMID: 35293990) describe the phenotype of 2 unrelated individuals with biallelic CACNA2D1 variants.

Overall, the phenotype corresponded to an early-onset DEE, characterized by abnormal muscle tone (axial hypotonia 2/2 with spasticity in extremities in 2/2), feeding difficulties (2/2), profound DD and ID (2/2), microcephaly (2/2 - approx. -2 SD in both), seizures (2/2 - 1st : onset 9m with absences and later generalized seizures, 2nd : onset 11m with hemi-clonic seizures and atypical absences). Other features included cortical visual impairment (2/2) and movement disorder (incl. choreiform movements 2/2, orofacial dyskinesia 2/2 and dystonic episodes 1/2). Brain MRI revealed corpus callosum anomalies (2/2) and cerebral atrophy (2/2). Both had echocardiography (abnormal in 1/2 - tiny PFO) and electrocardiography which was normal. Both exhibited insensibility to pain.

Presentation is relevant to the current panel as first symptoms in the first 3 months with severe hypotonia and poor head control (2/2) with evaluation in neurology/genetics preceding onset of seizures in both.

Trio ES was performed for both individuals and their (healthy) parents and revealed homozygosity for a fs variant in the first [NM_000722.3:c.818_822dup / p.(Ser275Asnfs*13)] and compound htz for a fs and a missense variant [c.13_23dup / p.(Leu9Alafs*5) and c.626G>A / p.(Gly209Asp)] in the second affected individual, respectively.

Eventual additional variants were not discussed.

Previous investigations are only provided for the 2nd and were all normal (karyotype, CMA, 15q methylation, epilepsy/neurometabolic gene panels).

Voltage-gated calcium channels are heteromultimers comprising different subunits incl. an alpha-1 (α1), α2δ (alpha-2/delta), beta (β) and gamma (γ). CACNA2D1 is one of the 4 genes (CACNA2D1-4) encoding the alpha-2/delta subunit. Its product is post-translationally processed into 2 peptides, an alpha-2 and a delta subunit, held by a disulfide bond.

Biallelic variants in CACNA2D2 - also encoding an alpha-2/delta subunit - cause cerebellar atrophy with seizures and variable developmental delay (# 618501).

Variant studies support loss-of-function effect for the studied variants, notably by NMD for the fs one, and severe impairment of the Cav2 channel function for the missense one :
- CACNA2D1 mRNA was reduced to 6-9% compared with control in fibroblasts from the 1st individual. mRNA levels for the 2nd subject were similar to control.
- Quantification of the protein in whole-cell lysates from fibroblasts revealed lower α2δ levels compared to control (10-12% and 31-38% applying to the 1st and 2nd individual).
- CACNA2D3 mRNA levels in fibroblasts from the 2nd patient were 2-7x higher compared to the 1st or controls suggesting a possible compensatory effect. CACNA2D2/4 mRNA levels were too low for quantification.
- Gly209 lies within the gabapentin and amino-acid binding pocket and this residue is invariable in CACNA2D1/CACNA2D2 in all vertebrates and paralogs.
- Transfection of tsA-201 cells with either WT or G209D HA-tagged α2δ revealed reduced cell surface expression for this missense variant (~80, for biotinylated form ~86%).
- In tsA-201 cells transfected with HA-tagged Cav2.2/β1b and either α2δ-1-WT, no α2δ-1 or α2δ-1-G209D, WT resulted in increased 13x currents with no increase applying to G209D (or in absence of α2δ). Plasma membrane expression of double (GFP/HA) tagged Cav2.2 was increased upon co-expression with WT α2δ-1 which was not the case for α2δ-1-G209D.
- In hippocampal neurons, double (GFP/HA)-tagged Cav2.2 could not be detected at the cell surface in the presence of α2δ-1-G209D (or no α2δ) in contrast with strong expression in presence of α2δ-1-WT. α2δ-1-G209D did not promote trafficking of Cav2.2 into hippocampal neurites, as indicated by reduced signals for both HA and GFP (for cell surface and total Cav2.2 respectively).
- Co-expression of double (GFP/HA) tagged Cav2.2 with β1b and either HA-α2δ-1-WT or HA-α2δ-1-G209D in tsA-201 cells, revealed reduced complex formation of G209D with Cav2.2 Co-immunoprecipitated HA-α2δ-1-G209D had higher molecular weight compared to HA-α2δ-1-WT which suggests that α2δ-1-G209D remains as the uncleaved immature form (probably in the ER).

Mouse model (several Refs in text):
Mild cardiac phenotype and reduced ventricular myocyte Ca current density was observed in hmz ko mice. Similarly to the insensibility to pain human phenotype, mice had delayed neuropathic pain-related responses. Overexpression of a2δ-1 resulted in epileptiform EEG and behavioral arrest, overall supporting a critical role of α2δ-1 for mouse brain.

The authors underscore that the parents of both patients (htz carriers) were healthy and review previous literature for association of monoallelic variants with epilepsy, ID and arrhythmogenic disorders (in suppl.) [Refs not here reviewed].

As for the NDD phenotype, CACNA2D1 is within a previously defined small region of overlap for 7q21.11 microdeletions associated with ID+/-epilepsy. The same study did not reveal de novo SNVs in any of the 3 contained genes within this SRO (HGF, CACNA2D1, PCLO) in 4293 patients with NDD [cited PMID: 28240412]. A frameshift variant (c.2625del) was identified in a 13-yo girl with infantile spasms and normal intelligence [cited PMID: 25877686]. A 1-bp insertion (c.659-2_659-1insT / not studied at the mRNA level) was identified in another 14-yo female with ID and epilepsy [cited PMID: 34356170]. The authors state that the phenotype (/differences) of these individuals as well as presence of pLoF CACNA2D1 variants in gnomAD [still pLI of 1] put in question pathogenicity of monoallelic variants for these phenotypes.

The role of heterozygous missense variants described in relation to arrhythmogenic disorders is also discussed extensively (some downgraded to LB/VUS, others having a relatively high MAF and presence of 1-2 homozygotes in gnomAD).

[2] ----
In an article cited by SysID for CACNA2D1 (2017 - PMID: 28097321), Reuter et al studied with WES and autozygosity mapping individuals with NDD belonging to consanguineous families.

As in eTables1/3, a male - single affected individual born to consanguineous parents from Turkey (MR150) - was investigated by singleton ES.

This individual was homozygous for a missense CACNA2D1 SNV [NM_000722.2:c.1514C>T;p.(Thr505Ile)].

Prior investigations are unavailable (although individuals with previously known P/LP CNVs were excluded).

The phenotype - briefly reported - included hypotonia, severe ID, stereotypic behaviors, inguinal hernia and omphalocele. Presence of seizures was not commented on. The age of this individual was not reported.
Sources: Literature, Other
Intellectual disability - microarray and sequencing v3.1222 RNF220 Konstantinos Varvagiannis gene: RNF220 was added
gene: RNF220 was added to Intellectual disability. Sources: Literature,Other
Mode of inheritance for gene: RNF220 was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: RNF220 were set to 33964137; 10881263
Phenotypes for gene: RNF220 were set to Leukodystrophy; CNS hypomyelination; Ataxia; Intellectual disability; Sensorineural hearing impairment; Elevated hepatic transaminases; Hepatic fibrosis; Dilated cardiomyopathy; Spastic paraplegia; Dysarthria; Abnormality of the corpus callosum
Penetrance for gene: RNF220 were set to Complete
Review for gene: RNF220 was set to GREEN
Added comment: Sferra et al (2021 - PMID: 33964137) provide extensive evidence that biallelic RNF220 mutations cause a disorder characterized by hypomyelinating leukodystrophy, ataxia (9/9 - onset 1-5y), borderline intellectual functioning (3/9) / intellectual disability (5/9 - in most cases mild), sensorineural deafness (9/9) with complete hearing loss in the first decade of life, hepatopathy (9/9) with associated periportal fibrosis, and dilated cardiomyopathy (9/9) which was fatal.

Other neurologic manifestations apart from ataxia incl. hyperreflexia (8/8), spastic paraplegia (9/9), dysarthria (9/9), peripheral neuropathy (4/9), seizures in one case (1/9). Upon brain MRI there was thin corpus callosum (9/9) or cerebellar atrophy in some (2/9).

The authors identified homozygosity for 2 recurrent missense RNF220 variants in affected members belonging to these 5 broad consanguineous pedigrees (7 families), namely NM_018150.4:c.1094G>A / p.Arg365Gly in 4 Roma families in the context of a shared haplotype (/founder effect) as well as c.1088G>A / p.Arg363Gly in a large pedigree from southern Italy initially reported by Leuzzi et al (2000 - PMID: 10881263).

Extensive segregation analyses were carried out including several affected and unaffected members.

RNF220 encodes ring finger protein 220, which functions as an E3 ubiquitin ligase. Previous studies have shown among others a role in modulation of Sonic hedgehog/GLI signaling and cerebellar development

Evidence for the role of RNF220 included relevant expression, localization within the cell, interaction partners (lamin B1, 20S proteasome), similarities with other laminopathies in terms of phenotype, etc :
*RNF220 has a relevant expression pattern in CNS (based on qRT-PCR analyses in human brain, cerebellum, cerebral cortex / mRNA levels in human fetal CNS with higher expression in cerebellum, spinal cord and cortex / previous GTEx data / protein levels in mouse CNS)
*The protein displays nuclear localization based on iPSC cells differentiated to motor neurons (also supported by data from the Human Protein Atlas). Transfection of COS-1 cells demonstrated localization primarily to the nucleus (as also previously demonstrated in HEK293T cells) in vesicle like structures with ASF2/SF2 colocalization suggesting enrichment in nuclear speckles. There was also partial co-distribution with the 20S proteasome. R363Q and R365Q additionally coalesced in the cytoplasm forming protein aggregates/inclusions.
*Immunofluorescence studies in patient fibroblasts also confirmed abnormal increase of the protein in the cytoplasm and increased fluorescence with the 20S proteasome.
*Proteomic identification of RNF220-interacting proteins in transfected HEK293T cells demonstrated enrichment for all members of the lamin protein family (incl . lamin B1, AC, B2).
*RNAi-mediated downregulation of RNF222 in Drosophila suggested altered subcellular localization and accumulation of the fly orthologue for human lamin B1.
*Immunoprecipitation of lamin B1 from the nuclear matrix of cerebellar cells suggested significant interaction of endogenous lamin B1 with RNF220, while transfection studies in HEK293T cells for wt/mt suggested reduced binding to endogenous lamin B1 for RNF220 mt compared to wt (more prominent for R365Q). RNF220 mutants also reduced ubiquitination of nuclear lamin B1 compared to wt.
*Patient fibroblasts immunostained with different nuclear envelope markers displayed abnormal nuclear shapes with multiple invaginations and lobulations, findings also observed in laminopathies.

There is currently no associated phenotype in OMIM or G2P. SysID includes RNF220 among the current primary ID genes.

Consider inclusion in panels for leukodystrophies, childhood onset ataxia, sensorineural hearing loss, corpus callosum anomalies, cardiomyopathies, hepatopathies, etc in all cases with green rating.
Sources: Literature, Other
Intellectual disability - microarray and sequencing v3.1220 VPS50 Konstantinos Varvagiannis gene: VPS50 was added
gene: VPS50 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: VPS50 was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: VPS50 were set to 34037727
Phenotypes for gene: VPS50 were set to Neonatal cholestatic liver disease; Failure to thrive; Profound global developmental delay; Postnatal microcephaly; Seizures; Abnormality of the corpus callosum
Penetrance for gene: VPS50 were set to Complete
Review for gene: VPS50 was set to AMBER
Added comment: Schneeberger et al (2021 - PMID: 34037727) describe the phenotype of 2 unrelated individuals with biallelic VPS50 variants.

Common features included transient neonatal cholestasis, failure to thrive, severe DD with failure to achieve milestones (last examination at 2y and 2y2m respectively), postnatal microcephaly, seizures (onset at 6m and 25m) and irritability. There was corpus callosum hypoplasia on brain imaging.

Both individuals were homozygous for variants private to each family (no/not known consanguinity applying to each case). The first individual was homozygous for a splicing variant (NM_017667.4:c.1978-1G>T) and had a similarly unaffected sister deceased with no available DNA for testing. The other individual was homozygous for an in-frame deletion (c.1823_1825delCAA / p.(Thr608del)).

VPS50 encodes a critical component of the endosome-associated recycling protein (EARP) complex, which functions in recycling endocytic vesicles back to the plasma membrane [OMIM based on Schindler et al]. The complex contains VPS50, VPS51, VPS52, VPS53, the three latter also being components of GARP (Golgi-associated-retrograde protein) complex. GARP contains VPS54 instead of VPS50 and is required for trafficking of proteins to the trans-golgi network. Thus VPS50 (also named syndetin) and VPS54 function in the EARP and GARP complexes, to define directional movement of their endocytic vesicles [OMIM based on Schindler et al]. The VPS50 subunit is required for recycling of the transferrin receptor.

As discussed by Schneeberger et al (refs provided in text):
- VPS50 has a high expression in mouse and human brain as well as throughout mouse brain development.
- Mice deficient for Vps50 have not been reported. vps50 knockdown in zebrafish results in severe developmental defects of the body axis. Knockout mice for other proteins of the EARP/GARP complex (e.g. Vps52, 53 and 54) display embryonic lethality.

Studies performed by Schneeberger et al included:
- Transcript analysis for the 1st variant demonstrated skipping of ex21 (in patient derived fabriblasts) leading to an in frame deletion of 81 bp (r.1978_2058del) with predicted loss of 27 residues (p.Leu660_Leu686del).
- Similar VPS50 mRNA levels but significant reduction of protein levels (~5% and ~8% of controls) were observed in fibroblasts from patients 1 and 2. Additionally, significant reductions in the amounts of VPS52 and VPS53 protein levels were observed despite mRNA levels similar to controls. Overall, this suggested drastic reduction of functional EARP complex levels.
- Lysosomes appeared to have similar morphology, cellular distribution and likely unaffected function in patient fibroblasts.
- Transferrin receptor recycling was shown to be delayed in patient fibroblasts suggestive of compromise of endocytic-recycling function.

As the authors comment, the phenotype of both individuals with biallelic VPS50 variants overlaps with the corresponding phenotype reported in 15 subjects with biallelic VPS53 or VPS51 mutations notably, severe DD/ID, microcephaly and early onset epilepsy, CC anomalies. Overall, for this group, they propose the term "GARP and/or EARP deficiency disorders".

There is no VPS50-associated phenotype in OMIM or G2P. SysID includes VPS50 among the ID candidate genes.

Consider inclusion in other relevant gene panels (e.g. for neonatal cholestasis, epilepsy, microcephaly, growth failure in early infancy, corpus callosum anomalies, etc) with amber rating pending further reports.
Sources: Literature
Intellectual disability - microarray and sequencing v3.1201 ATP9A Konstantinos Varvagiannis gene: ATP9A was added
gene: ATP9A was added to Intellectual disability. Sources: Literature,Other
Mode of inheritance for gene: ATP9A was set to BIALLELIC, autosomal or pseudoautosomal
Phenotypes for gene: ATP9A were set to Global developmental delay; Intellectual disability; Postnatal microcephaly; Failure to thrive; Abnormality of the abdomen
Penetrance for gene: ATP9A were set to Complete
Review for gene: ATP9A was set to AMBER
Added comment: Vogt, Verheyen et al (2021 - http://dx.doi.org/10.1136/jmedgenet-2021-107843) report 3 affected individuals from 2 unrelated consanguineous families.

Features included DD, variable ID (Fam1: sib1-mild, sib2-possible, Fam2: severe), postnatal microcephaly (-2.33 to -3.58 SD), failure to thrive as well as gastrointestinal symptoms (nausea, vomiting, GE reflux).

These subjects were homozygous for pLoF ATP9A variants private to each family.

Previous investigations incl. karyotype, aCGH and transferrin electophoresis (CDGs) and were unremarkable.

Diagnosis was made by exome sequencing and homozygosity mapping. Affected sibs from the first family were homozygous for a stopgain variant [NM_006045.3:c.868C>Τ / p.(Arg290*)]. The subject from the second family was homozygous for a variant affecting the consensus (donor) splice site [c.642+1G>A - same RefSeq]. Both variants were absent from gnomAD. Sanger sequencing was used to confirm variants, carrier status of the parents and unaffected sibs in both families.

Sequencing of cDNA from the individual homozygous for the splicing variant demonstrated skipping of exon 7 with the variant likely leading to frameshift and introduction of a premature stop codon.

qPCR in dermal fibroblasts from affected individuals from both families revealed expression downregulation of ATP9A (14% and 4% respectively for the stopgain and splice variant). Study at the protein level was not possible due to absence of antibody against endogenous ATP9A.

ATP9A encodes ATPase phospholipid transporting 9A (similarly to ATP9B) belonging to the subclass 2 of the P4-ATPase family. As the authors comment, the protein is mainly expressed in the brain although the precise function or subcellular distribution of endogenous ATP9A are unknown.

A previous study showed that overexpressed ATP9A in HeLa cells localizes to early/recycling endosomes and the trans-Golgi network, being required for endocytic recycling of the transferrin receptor to the plasma membrane. ATP9A (in complex with DOP1B and MON2) functionally interacts with the SNX3-retromer. A previous ATP9A knockdown cell line suggested dysregulation of >100 genes with ARPC3 (actin-related protein 2/3 complex subunit 3) being strongly upregulated.

Overall ATP9A appears to have a role in endosome trafficking pathways as well as to inhibit secretion of exosomes at the plasma membrane likely due to alteration of the actin cytoskeleton.

In line with the role of APT9A in early/recycling endosomes and identified interactions, the authors demonstrated overexpression of ARPC3 and SNX3. Study of genes encoding other known interacting proteins was not possible due to poor expression in fibroblasts.

As the authors note, mutations in genes encoding proteins of the Golgi and endosomal trafficking are important for brain development and have been associated with postnatal microcephaly.

In OMIM, G2P, SysID there is no associated phenotype.

The gene is included in the ID panel of PanelApp AUS with amber rating.
Sources: Literature, Other
Intellectual disability - microarray and sequencing v3.1075 NSF Sarah Leigh reviewed gene: NSF: Rating: AMBER; Mode of pathogenicity: None; Publications: ; Phenotypes: ; Mode of inheritance: None
Intellectual disability - microarray and sequencing v3.634 PSAT1 Arina Puzriakova Phenotypes for gene: PSAT1 were changed from PHOSPHOSERINE AMINOTRANSFERASE DEFICIENCY to Phosphoserine aminotransferase deficiency, OMIM:610992; Neu-Laxova syndrome 2, OMIM:616038
Intellectual disability - microarray and sequencing v3.420 SHMT2 Konstantinos Varvagiannis gene: SHMT2 was added
gene: SHMT2 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: SHMT2 was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: SHMT2 were set to 33015733
Phenotypes for gene: SHMT2 were set to Congenital microcephaly; Infantile axial hypotonia; Spastic paraparesis; Global developmental delay; Intellectual disability; Abnormality of the corpus callosum; Abnormal cortical gyration; Hypertrophic cardiomyopathy; Abnormality of the face; Proximal placement of thumb; 2-3 toe syndactyly
Penetrance for gene: SHMT2 were set to Complete
Review for gene: SHMT2 was set to GREEN
Added comment: García‑Cazorla et al. (2020 - PMID: 33015733) report 5 individuals (from 4 families) with a novel brain and heart developmental syndrome caused by biallelic SHMT2 pathogenic variants.

All affected subjects presented similar phenotype incl. microcephaly at birth (5/5 OFC < -2 SD though in 2/5 cases N OFC was observed later), DD and ID (1/5 mild-moderate, 1/5 moderate, 3/5 severe), motor dysfunction in the form of spastic (5/5) paraparesis, ataxia/dysmetria (3/4), intention tremor (in 3/?) and/or peripheral neuropathy (2 sibs). They exhibited corpus callosum hypoplasia (5/5) and perisylvian microgyria-like pattern (4/5). Cardiac problems were reported in all, with hypertrophic cardiomyopathy in 4/5 (from 3 families) and atrial-SD in the 5th individual (1/5). Common dysmorphic features incl. long palpebral/fissures, eversion of lateral third of lower eylids, arched eyebrows, long eyelashes, thin upper lip, short Vth finger, fetal pads, mild 2-3 toe syndactyly, proximally placed thumbs.

Biallelic variants were identified following exome sequencing in all (other investigations not mentioned). Identified variants were in all cases missense SNVs or in-frame del, which together with evidence from population databases and mouse model might suggest a hypomorphic effect of variants and intolerance/embryonic lethality for homozygous LoF ones.

SHMT2 encodes the mitohondrial form of serine hydroxymethyltransferase. The enzyme transfers one-carbon units from serine to tetrahydrofolate (THF) and generates glycine and 5,10,methylene-THF.

Mitochondrial defect was suggested by presence of ragged red fibers in myocardial biopsy of one patient. Quadriceps and myocardial biopsies of the same individual were overall suggestive of myopathic changes.

While plasma metabolites were within N range and SHMT2 protein levels not significantly altered in patient fibroblasts, the authors provide evidence for impaired enzymatic function eg. presence of the SHMT2 substrate (THF) in patient but not control (mitochondria-enriched) fibroblasts , decrease in glycine/serine ratios, impared folate metabolism. Patient fibroblasts displayed impaired oxidative capacity (reduced ATP levels in a medium without glucose, diminished oxygen consumption rates). Mitochondrial membrane potential and ROS levels were also suggestive of redox malfunction.

Shmt2 ko in mice was previously shown to be embryonically lethal attributed to severe mitochondrial respiration defects, although there was no observed brain metabolic defect.

The authors performed Shmt2 knockdown in motoneurons in Drosophila, demonstrating neuromuscular junction (# of satellite boutons) and motility defects (climbing distance/velocity).

Overall this gene can be considered for inclusion with (probably) green rating in gene panels for ID, metabolic / mitochondrial disorders, cardiomyopathy, congenital microcephaly, corpus callosum anomalies, etc.
Sources: Literature
Intellectual disability - microarray and sequencing v3.314 LMNB1 Konstantinos Varvagiannis gene: LMNB1 was added
gene: LMNB1 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: LMNB1 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
Publications for gene: LMNB1 were set to 32910914
Phenotypes for gene: LMNB1 were set to Global developmental delay; Intellectual disability; Microcephaly; Short stature; Seizures; Abnormality of the corpus callosum; Cortical gyral simplification; Feeding difficulties; Scoliosis
Penetrance for gene: LMNB1 were set to unknown
Mode of pathogenicity for gene: LMNB1 was set to Loss-of-function variants (as defined in pop up message) DO NOT cause this phenotype - please provide details in the comments
Review for gene: LMNB1 was set to GREEN
Added comment: Cristofoli et al (2020 - PMID: 32910914) report 7 individuals (from 5 families) harboring mostly de novo LMNB1 variants.

The common phenotype consisted of primary microcephaly (7/7 ranging from -4.4 to -10 SD), DD/ID (7/7), relative short stature in most (+0.7 to -4 SD). Additional features included brain MRI abnormalities (abnormal CC in 3, simplified gyral pattern in 3, small structurally normal brain, etc), seizures (4 individuals from 2 families), limb spasticity (1/7), cortical visual impairment (in 3), feeding difficulties (5/7), scoliosis (4/7). Non-overlapping dysmorphic features were reported in some.

Variants were identified by WES or custom-designed gene panel and included 3 missense variants, 1 in-frame deletion and a splice variant. The in-frame deletion was inherited from a similarly affected parent in whom the variant occurred as a dn event. The splice SNV(NM_005573.3:c.939+1G>A) occurred in 3 sibs and was present as mosaic variant (15%) in the parent. This variant was predicted to result to extension of exon 5 by 6 amino-acids (samples were unavailable for mRNA studies).

LMNB1 encodes a B-type lamin (the other being encoded by LMNB2). A- and B- type lamins are major components of the nuclear lamina. As the authors comment, LMNB1 is expressed in almost all cell types beginning at the earliest stages of development.

Lamin-deficient mouse models support an essential role of B-type lamins in organogenesis, neuronal migration, patterning during brain development.

Functional studies performed, demonstrated impaired formation of LMNB1 nuclear lamina in LMNB1-null HeLa cells transfected with cDNAs for 3 missense variants.

Two variants (Lys33Glu/Arg42Trp) were shown to result in decreased nuclear localization with increased abundance in the cytosolic fraction. In patient derived LCLs these variants led to abnormal nuclear morphology. A missense variant in another domain (Ala152Gly - 1st coil domain) resulted also in lower abundance of lamin B1, irregular lamin A/C nuclear lamina, as well as more condensed nuclei (HeLa cells).

LMNB1 duplications or missense mutations increasing LMNB1 expression are associated with a different presentation of AD leuodystrophy. A variant previously associated with leukodystrophy (Arg29Trp) was shown to behave differently (present in the nuclear extract but not in the cytosol, lamin B1 to A/C ratio in nuclear extract was not significantly altered compared to wt as was the case for Arg42Trp, Lys33Glu).

Given the pLI score of 0.55 as well as the phenotype of individuals with deletions (not presenting microcephaly) the authors predict that a dominant-negative effect applies (rather than haploinsufficiency).

Consider inclusion in the following panels : DD/ID (green), epilepsy (amber - 4 of 7 patients belonging to 2 families), primary microcephaly (green), callosome (amber/green - 3 individuals belonging to 3 families), mendeliome (green), etc.
Sources: Literature
Intellectual disability - microarray and sequencing v3.239 FAM50A Konstantinos Varvagiannis gene: FAM50A was added
gene: FAM50A was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: FAM50A was set to X-LINKED: hemizygous mutation in males, monoallelic mutations in females may cause disease (may be less severe, later onset than males)
Publications for gene: FAM50A were set to 32703943
Phenotypes for gene: FAM50A were set to Mental retardation syndrome, X-linked, Armfield type (MIM #300261)
Penetrance for gene: FAM50A were set to unknown
Review for gene: FAM50A was set to GREEN
Added comment: Lee et al (2020 - PMID: 32703943) provide evidence that Armfield X-Linked intellectual disability syndrome is caused by monoallelic FAM50A pathogenic variants. The current review is based only on this reference.

The authors provide clinical details on 6 affected individuals from 5 families.

Features included postnatal growth delay, DD and ID (6/6 - also evident for those without formal IQ assesment), seizures (3/6 from 2 families), prominent forehead with presence of other facial features and variable head circumference (5th to >97th %le), ocular anomalies (5/6 - strabismus/nystagmus/Axenfeld-Rieger), cardiac (3/6 - ASD/Fallot) and genitourinary anomalies (3/6).

In the first of these families (Armfield et al 1999 - PMID: 10398235), linkage analysis followed by additional studies (Sanger, NGS of 718 genes on chrX, X-exome NGS - several refs provided) allowed the identification of a FAM50A variant. Variants in other families were identified by singleton (1 fam) or trio-ES (3 fam).

In affected individuals from 3 families, the variant had occurred de novo. Carrier females in the other families were unaffected (based on pedigrees and/or the original publication). XCI was rather biased in most obligate carrier females from the 1st family (although this ranged from 95:5 to 60:40).

Missense variants were reported in all affected subjects incl. Trp206Gly, Asp255Gly, Asp255Asn (dn), Glu254Gly (dn), Arg273Trp (dn) (NM_004699.3).

Previous studies have demonstrated that FAM50A has ubiquitous expression in human fetal and adult tissues (incl. brain in fetal ones).

Immunostaining suggests a nuclear localization for the protein (NIH/3T3 cells). Comparison of protein levels in LCLs from affected males and controls did not demonstrate significant differences. Protein localization for 3 variants (transfection of COS-7 cells) was shown to be similar to wt.

Complementation studies in zebrafish provided evidence that the identified variants confer partial loss of function (rescue of the morpholino phenotype with co-injection of wt but not mt mRNA). The zebrafish ko model seemed to recapitulate the abnormal development of cephalic structures and was indicative of diminished/defective neurogenesis. Transcriptional dysregulation was demonstrated in zebrafish (altered levels and mis-splicing). Upregulation of spliceosome effectors was demonstrated in ko zebrafish.

Similarly, mRNA expression and splicing defects were demonstrated in LCLs from affected individuals. FAM50A pulldown followed by mass spectrometry in transfected HEK293T cells demonstrated enrichment of binding proteins involved in RNA processing and co-immunoprecipitation assays (transfected U-87 cells) suggested that FAM50A interacts with spliceosome U5 and C-complex proteins.

Overall aberrant spliceosome C-complex function is suggested as the underlying pathogenetic mechanism.

Several other neurodevelopmental syndromes are caused by variants in genes encoding C-complex affiliated proteins (incl. EFTUD2, EIF4A3, THOC2, etc.).

Please consider inclusion in the ID panel with green rating and epilepsy panel with amber (seizures in individuals from 2 families).
Sources: Literature
Intellectual disability - microarray and sequencing v3.183 LIPT1 Arina Puzriakova reviewed gene: LIPT1: Rating: GREEN; Mode of pathogenicity: ; Publications: 24341803, 29681092, 31042466, 24256811, 27247813; Phenotypes: Lipoyltransferase 1 deficiency, 616299; Mode of inheritance: BIALLELIC, autosomal or pseudoautosomal
Intellectual disability - microarray and sequencing v3.3 SLC9A7 Zornitza Stark gene: SLC9A7 was added
gene: SLC9A7 was added to Intellectual disability. Sources: Expert list
Mode of inheritance for gene: SLC9A7 was set to X-LINKED: hemizygous mutation in males, biallelic mutations in females
Publications for gene: SLC9A7 were set to 30335141
Phenotypes for gene: SLC9A7 were set to Intellectual developmental disorder, X-linked 108; OMIM #301024
Review for gene: SLC9A7 was set to AMBER
Added comment: 6 males from 2 unrelated families with hemizygous missense mutation in the SLC9A7 gene. The mutation segregated with the disorder in the family. In vitro functional expression studies in CHO cells (AP-1 cells) showed that the mutation caused decreased levels of protein expression and reduced oligosaccharide maturation/glycosylation compared to wildtype, indicating impaired posttranslational processing. Subcellular localization studies indicated that protein trafficking was unaffected by the mutation. However, examination of the trans-Golgi compartment suggested a gain-of-function effect and a perturbation of glycosylation of secretory cargo. Serum transferrin studies in 1 patient suggested a glycosylation defect. One to watch.
Sources: Expert list
Intellectual disability - microarray and sequencing v3.3 PSAT1 Zornitza Stark reviewed gene: PSAT1: Rating: AMBER; Mode of pathogenicity: None; Publications: 26960553, 17436247, 25152457; Phenotypes: Phosphoserine aminotransferase deficiency, MIM# 610992, Neu-Laxova syndrome 2, MIM# 616038; Mode of inheritance: BIALLELIC, autosomal or pseudoautosomal
Intellectual disability - microarray and sequencing v3.0 LIPT1 Zornitza Stark gene: LIPT1 was added
gene: LIPT1 was added to Intellectual disability. Sources: Expert list
Mode of inheritance for gene: LIPT1 was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: LIPT1 were set to 24341803; 24256811; 29681092
Phenotypes for gene: LIPT1 were set to Lipoyltransferase 1 deficiency, MIM#616299
Review for gene: LIPT1 was set to GREEN
gene: LIPT1 was marked as current diagnostic
Added comment: Cognitive development is affected in this metabolic condition.
Sources: Expert list
Intellectual disability - microarray and sequencing v3.0 PUM1 Konstantinos Varvagiannis commented on gene: PUM1: 5 unrelated individuals with de novo pathogenic PUM1 variants have been reported in the literature. DD (5/5), ID (4/5 - relevant severity to the current panel), seizures (4/4 - absence/tonic-clonic, abnormal EEG) and variable other features (incl. facial dysmorphism, ataxia, cryptorchidism) appear to be part of the phenotype. 9 individuals with deletions spanning PUM1 and proximal genes presented similar features.

[1] PMID: 29474920 - Gennarino et al (2018)
[2] PMID: 30903679 - Bonnemason-Carrere et al (2019)
[3] PMID: 31859446 - Voet et al (2019) [with review of the literature]

SNVs in relevant individuals were identified by exome sequencing and were in all cases de novo.

Arg1147Trp was a recurrent variant reported in 3 unrelated subjects with ID and seizures (Refs 1,2,3 / NM_001020658.1:c.3439C>T). A nonsense variant was reported in an additional one with DD, ID, seizures and additional features (c.2509C>T / p.Arg837* - Ref3). One individual with a de novo missense variant (c.3416G>A / p.Arg1139Trp) with DD and ataxia, though without ID was reported in Ref1.

Details on 9 individuals with 0.3 - 5.6 Mb deletions spanning PUM1 and other genes are provided in Ref1. Features also included DD, ID, seizures, ataxia, etc.

Extensive initial investigations were reported for individuals in Refs 2 and 3 (various investigations incl. karyotype, SNP-array, targeted sequencing of OPHN1, KANSL1 or of a small panel of ID genes, biopsies and/or metabolic work-up) to rule out alternative causes. These only revealed a likely benign CNV and a GRIA3 SNV of uncertain significance in the case of an individual harboring the recurrent Arg1147Trp variant [Ref2].

Role of the gene (from OMIM):
Pumilio proteins, such as PUM1, negatively regulate gene expression by repressing translation of mRNAs to which they bind (Lee et al., 2016). A clinically significant PUM1 target is ataxin (ATXN1; 601556), mutation in which causes spinocerebellar ataxia-1 (SCA1; 601556).

Variant studies:
- Arg1147Trp was shown to be associated with normal PUM1 mRNA levels, but reduced (to ~43%) PUM1 protein levels in patient fibroblasts. ATXN1 mRNA and protein levels, as well as protein and/or mRNA levels of other PUM1 targets were shown to be increased (Ref1).
- In Ref1, in vitro transfection assays with wt or mt PUM1 were performed in HEK293T cells to evaluate repression of ATXN1 and E2F3. While overexpression of wt and Arg1147Trp were able to reduce ATXN1 and E2F3 levels, Arg1139Trp was not able to repress ATXN1 or E2F3.
- Upon overexpression in mouse hippocampal neurons, PUM1 missense mutations (among others Arg1139Trp and Arg1147Trp) were shown to alter neuronal morphology.

Overall haploinsufficiency is the proposed mechanism for the disorder for which the acronym PADDAS is used (Pumilio1-associated developmental disability, ataxia and seizure).

Milder mutations reducing PUM1 levels by 25% are associated with adult-onset ataxia without ID (PRCA or Pumilio1-related cerebellar ataxia) [Ref1].

Mouse models:
The role of PUM1 was first suggested in mouse models where Pum1 mutations were shown to lead to a SCA1-like phenotype (PMID cited : 12086639 - Watase et al 2002) further shown to be caused by increased Atxn1 mRNA and protein levels (PMID cited : 25768905 - Gennarino et al 2015).
The mouse model seems to recapitulate several of the features observed in affected individuals : Pum1 homozygous ko mice display among others hyperactivity, progressive cerebellar signs, spontaneous seizures as also observed in affected individuals (PMID cited : 25768905 - Gennarino et al 2015). Cryptorchidism was observed in 2 patients similar to testicular hypoplasia reported in Pum1 ko mice (PMID cited : 22342750 - Chen et al 2012).
- Heterozygous mice were evaluated in Ref1 with 69% or 75% exhibiting spontaneous seizures by the end of 30 or 35 wks respectively, with abnormal EEG activity already by 16 wks.

Additional individuals with PUM1 variants and a relevant phenotype of ID with or without seizures have been reported as part of the DDD study or as external submissions to Decipher and ClinVar :

https://decipher.sanger.ac.uk/search?q=PUM1#research-variants/results [ DDD4K.01387 participant ]
https://decipher.sanger.ac.uk/search?q=pum1#consented-patients/results [ external submission(s) ]
https://www.ncbi.nlm.nih.gov/clinvar/variation/431110/ [ splice-site variant in an individual with ID submitted prior to the 1st publication on the disorder ]
Intellectual disability - microarray and sequencing v3.0 MN1 Konstantinos Varvagiannis gene: MN1 was added
gene: MN1 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: MN1 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
Publications for gene: MN1 were set to 31834374; 31839203; 15870292
Phenotypes for gene: MN1 were set to Central hypotonia; Feeding difficulties; Global developmental delay; Intellectual disability; Hearing impairment; Abnormality of facial skeleton; Craniosynostosis; Abnormality of the face; Abnormality of the cerebellum; Abnormality of the corpus callosum; Polymicrogyria
Penetrance for gene: MN1 were set to Complete
Review for gene: MN1 was set to GREEN
Added comment: Two studies by Mak et al (2019 - PMID: 31834374 / Ref1) and Miyake et al (2019 - PMID: 31839203 / Ref2) provide sufficient evidence for heterozygous MN1 C-terminal truncating variants (predicted to escape NMD - localizing within the last nucleotides of exon 1 or in exon 2) being associated with a distinctive phenotype and DD and ID among the features.

Mak et al also discuss on the phenotype of individuals with variants causing N-terminal truncation or with MN1 deletions (discussed at the end of this review).

Overlapping features for C-terminal truncating variants included hypotonia, feeding difficulties, global DD and ID, hearing loss, cranial shape defects (/craniosynostosis in few), highly suggestive/distinctive facial features (eg. frontal bossing, hypertelorism, downslanting palpebral-fissures, shallow orbits, short upturned nose, low-set/posteriorly rotated/dysplastic ears, etc) and brain MRI abnormalities (eg. rhomboencephalosynapsis or cerebellar dysplasia, polymicrogyria, dysplastic CC).

The majority of the affected individuals were investigated by WES/WGS with a single one tested by targeted MN1 Sanger sequencing due to highly suggestive features. Variable previous investigations incl. CMA in several, gene panel testing (Rasopathies, hearing loss, craniofacial panels, FMR1, etc) and metabolic work were normal in most. In a single case a likely pathogenic ACSL4 also explained part of the phenotype (Ref2). In the majority of these individuals, the variant had occured as a de novo event. Two sibs had inherited the truncating variant from a milder affected mosaic parent. A parental sample was not available for an additional individual.

p.(Arg1295*) or NM_002430.2:c.3883C>T was a recurrent variant, seen in several individuals and in both studies.

Several lines of evidence are provided for the MN1 variants and the role of the gene including:
- For few individuals for whom cell lines were available, variants were shown to escape NMD by cDNA/RT-PCR/RNA-seq [Ref1 & 2].
- The gene has a high expression in fetal brain [Ref2 / fig S2]
- MN1 (* 156100 - MN1 protooncogene, transcriptional regulator) has been proposed to play a role in cell proliferation and shown to act as transcription cofactor (increasing its transactivation capacity in synergy with coactivators EP300 and RAC3) [Discussion and Refs provided in Ref2].
- In vitro studies suggested increased protein stability (upon transfection of wt/mut constructs in HEK293T cells), enhanced MN1 aggregation in nuclei (when wt/mut GFP-tagged MN1 was expressed in HeLa cells), increased inhibitory effect on cell growth (MG63 cells - role of MN1 in cell proliferation discussed above) and retained transactivation activity (upon transient MN1 overexpression of wt/mt MN1 in HEK293T cells) for the variants. These seem to support a gain-of-function effect for the C-terminal truncating variants [Ref2].
- The truncating variants are proposed to raise the fraction of Intrinsically disordered regions (IDRs = regions without fixed tertiary structure) probably contributing to the above effects [Ref2].
- Expression of FLAG-tagged MN1 wt/mut MN1 followed by immunoprecipitation and mass spectrometry analysis (mCAT-Hela cells), provided evidence that MN1 is involved in transcriptional regulation: a. through binding ZBTB24 and RING1 E3 ubiquitin ligase (with mutant MN1 displaying impaired interaction with ZBTB24 and no binding to RING1) and/or b. through interaction with DNA-binding transcription factors PBX1 and PKNOX1. Proper MN1 degradation is proposed to mediate precise transcriptional regulation. [Ref2]
- Transcriptome analysis in LCLs from an affected individual suggested dysregulation of genes relevant to neuronal development (eg. LAMP, ITGA, etc) and GO analysis suggested enrichment for pathways possibly linked to the observed phenotypes [Ref2].
- Discussed in both Refs1/2, homozygous Mn1-ko mice display abnormal skull bone development and die at/shortly after birth as a result of cleft palate. Heterozygous Mn1-ko mice display hypoplastic membranous bones of the cranial skeleton and cleft palate (CP), the latter with incomplete penetrance [Meester-Smoor et al 2005 - PMID: 15870292]. This is thus compatible with the cranial shape defects observed in C-terminal truncations (while CP has been reported in gene deletions, bifid uvula was reported once in C-terminal and N-terminal truncating variants, in the latter case with submucous CP).
-----
The phenotype of other MN1 variants is discussed by Mak et al (Ref1) :
- 3 individuals with MN1 N-terminal truncating variants (eg. Ser179*, Pro365Thrfs*120, Ser472*) presented speech delay, mild conductive hearing loss and facial features different from C-terminal truncations. None of these individuals had significant ID.
- Microdeletions: One individual (#27) with 130 kb deletion harboring only MN1, presented microcephaly, DD and ID and mildly dysmorphic facial features. Deletions spanning MN1 and other genes (eg a 1.17 Mb deletion in ind. #28) and relevant cases from the literature reviewed, with mild DD/ID, variable palatal defects and/or facial dysmorphisms (distinct from the C-terminal truncating variants) among the frequent findings.

[Please consider inclusion in other possibly relevant gene panels eg. for hearing loss (conductive/sensorineural in 16/20 reported by Mak et al) or craniosynostosis, etc].
Sources: Literature
Intellectual disability - microarray and sequencing v3.0 CXorf56 Konstantinos Varvagiannis gene: CXorf56 was added
gene: CXorf56 was added to Intellectual disability. Sources: Literature,Radboud University Medical Center, Nijmegen
Mode of inheritance for gene: CXorf56 was set to X-LINKED: hemizygous mutation in males, monoallelic mutations in females may cause disease (may be less severe, later onset than males)
Publications for gene: CXorf56 were set to 29374277; 31822863
Phenotypes for gene: CXorf56 were set to ?Mental retardation, X-linked 107, 301013
Penetrance for gene: CXorf56 were set to unknown
Review for gene: CXorf56 was set to AMBER
Added comment: Verkerk et al (2018 - PMID: 29374277) reported on a three-generation family with five males and one female presenting mild non-syndromic ID. Segregation was compatible with X-linked inheritance.

Multipoint linkage analysis with XL microsatellite markers demonstrated a linkage peak at Xq23-24 with LOD score of 3.3. Haplotype analysis and utilization of additional STR markers allowed narrowing to a region of 7.6 Mb containing 92 genes.

WGS in 3 affected males (spanning 3 generations) and 1 unaffected male and application of relevant filters for rare protein affecting variants within this region - present only in affected but absent in the unaffected individual - suggested a CXorf56 frameshift variant in exon 2 [NM_022101.3:c.159_160insTA / p.(Asp54*)] as the only relevant for this phenotype.

Sanger sequencing was performed for 25 family members with all 5 affected males and 1 affected female harboring this insertion and 8 unaffected females (also) shown to be carriers.

X-chromosome inactivation studies demonstrated that unaffected females had skewed inactivation (76-93%) of the variant allele, while the single affected female did not have a skewed XCI pattern (54%).

In EBV-transformed lymphoblasts grown with/without cycloheximide, mRNA levels were shown to be significantly lower in the affected female compared to unaffected ones (and corrected upon treatment with cycloheximide). mRNA levels were also significantly lower in cell lines from an affected male, with expression showing significant increase after treatment with cycloheximide. These results confirmed that nonsense-mediated decay applies.

The variant was absent from ExAC (where CXorf56 has a pLI of 0.93) and 188 healthy Dutch individuals.

The function of CXorf56 is not known. The gene appears to be expressed in brain and a (broad) range of other tissues [ https://gtexportal.org/home/gene/CXORF56 ].

Immunostaining in 8-week old murine brain, showed that the protein is present in the nucleus and cell soma of most neurons in brain cortex and cerebellum. Upon transfection of human CXorf56 cDNA in mouse primary hippocampal neurons, the protein localized in the nucleus, dendrites (co-localizing with Map2) and dendritic spines. As the authors note, the latter may suggest a role in synaptic function.

Overexpression in HEK293T cells demonstrated predominantly nuclear localization.

Mouse : Based on MGI (and an article by Cox et al. - PMID: 20548051 / both cited by the authors) male chimeras hemizygous for a gene trapped allele have abnormal midbrain-hindbrain boundary morphology, decreased forebrain size, while a subset hemizygous for a different gene trapped allele show growth delay [ http://www.informatics.jax.org/marker/MGI:1924894 ].

-----

Rocha et al (2019 - PMID: 31822863) report on 9 affected individuals with mild to severe ID belonging to 3 unrelated families. Additional features in this cohort - observed in some - included abnormal reflexes, fine tremor, seizures (in 3), abnormal gait, etc.

In the 1st family, 3 males presented with (severe/severe/moderate) ID and 2 females with mild ID. Following a normal CMA and FMR1 testing, trio plus exome sequencing revealed a CXorf56 in-frame deletion [NM_022101.3:c.498_503del / p.(Glu167_Glu168del)]. Sanger sequencing in 9 members, confirmed presence of the variant in one unaffected mother, all her affected sons (2) and daughers(2) and an affected grandson and absence in 2 remaining unaffected daughters. Skewing of XCI was seen in blood cells from affected females (97 and 83%) while the unaffected mother had complete inactivation of the carrier X-chromosome. The authors commented that even minor reductions in CXorf56 (suggested by XCI in affected females) may be detrimental and/or that inactivation for this gene may be different than that of AR gene (which was studied instead) or in other tissues.

In family 2, an affected mother (with learning difficulties) and her 2 sons - the most severely affected presenting moderate ID - harbored a frameshift variant [c.303_304delCTinsACCC / p.(Phe101Leufs*20)].

A male with ID belonging to a 3rd family, for which no further information was available, was found to harbor the c.498_503del variant (also discussed above) as a de novo event.

It has been commented that individuals with Xq24 deletions spanning CXorf56 present with ID, although (all) such deletions reported in the literature also span the neighboring UBE2A gene, associated with Mental retardation, X-linked syndromic, Nascimento-type (MIM #300860).

-----

In OMIM, the CXorf56-related phenotype is ?Mental retardation, X-linked 107 (# 301013), based only on the report by Verkerk et al.

This gene is included in gene panels for ID offered by some diagnostic laboratories (incl. Radboudumc).

-----

Overall, CXorf56 can be considered for inclusion in the ID panel either with amber (function of the gene unknown, skewed XCI also in affected females in the 2nd reference) or with green rating (several individuals from 4 families, compatible segregation studies and females presenting a milder phenotype than males or unaffected, LOD score in the 1st report, studies confirming lower mRNA levels and NMD, gene expressed in human brain, expression in mouse brain cortex and cerebellum, evidence from transfection studies in mouse hippocampal neurons).

[Note : penetrance was here set to unknown / It was complete for males, incomplete for females].
Sources: Literature, Radboud University Medical Center, Nijmegen
Intellectual disability - microarray and sequencing v3.0 KAT8 Konstantinos Varvagiannis gene: KAT8 was added
gene: KAT8 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: KAT8 was set to BOTH monoallelic and biallelic, autosomal or pseudoautosomal
Publications for gene: KAT8 were set to 31794431
Phenotypes for gene: KAT8 were set to Global developmental delay; Intellectual disability; Seizures; Abnormality of vision; Feeding difficulties; Abnormality of the cardiovascular system; Autism
Penetrance for gene: KAT8 were set to unknown
Review for gene: KAT8 was set to GREEN
Added comment: Heterozygous pathogenic missense KAT8 variants have been reported in individuals with DD, ID and epilepsy. Variants occurred as de novo events within the chromobarrel or the acetyltransferase domain and were all shown to affect H4K16 acetylation, as would be predicted by the gene's function (lysine acetyltransferase). Evidence from brain specific Kat8 knockout in mouse, supports the role of the gene in brain development. One similarly affected individual compound heterozygous for a nonsense and a missense variant (the former affecting subnuclear localization and the latter H4K16ac) was also reported, with carrier relatives being unaffected. Mutations in genes of the MSL/NSL complexes (with which KAT8 forms multisubunit complexes) or genes in other acetyltransferases of the same subfamily (MYST) as KAT8 cause neurodevelopmental disorders [Details provided below].
-----
Li et al. (2019 - PMID: 31794431) report on 8 unrelated individuals with heterozygous de novo pathogenic KAT8 variants, as well as an additional one compound heterozygous for a nonsense and a missense one.

Overlapping phenotype consisted of DD/ID (8/8), seizures/epilepsy (6/8), brain MRI anomalies as well as presence of variable facial dysmorphic features. Less frequent features included abnormal vision (5/8), feeding difficulties (3/8), cardiac anomalies (3/8), autism (in 1).

The (9th) individual with biallelic variants had similar phenotype of DD/ID, epilepsy, autism and dysmorphic facial features. Heterozygous parents and sister, the latter carrier for the missense variant, were all unaffected.

All individuals had undergone exome sequencing, while extensive other investigations for at least 7/9 had only revealed variants of uncertain significance/contribution to the phenotype or were normal.

KAT8 encodes lysine acetyltransferase 8, which acetylates histone H4 at lysine 16 (H4K16). It belongs to the MYST subfamily of lysine acetyltransferases, the other members of which include KAT6A, KAT6B (both involved in neurodevelopmental disorders) and KAT5.

KAT8 forms two stoichiometric multisubunitcomplexes, one with the MSL complex and the other with the NSL. Mutations in genes encoding for subunits of the NSL or MSL complex (eg. KANSL1 and MSL3) are associated with neurodevelopmental disorders.

Overall 6 missense SNVs were reported among the heterozygous patients, p.Tyr90Cys (NM_032188.2:c.269A>G) being a recurrent one seen in 3. The compound heterozygous patient had a missense (c.973C>T / p.Arg325Cys) and a nonsense variant (c.523A>T / p.Lys175*). All missense variants lied either in the chromobarrel domain or the acetyltransferase domain. Variants in the latter domain localized within the KAT8/Mof-specific region or - in the case of the compound heterozygous individual - within the acetyl-CoA binding motif.

FLAG-tagged KAT8 (either wt or for all missense SNVs) was transfected in HEK293 cells with vectors for HA-tagged MSL proteins. While the nonsense variant was difficult to express, missense SNVs were expressed to similar levels to wt, promoted expression of MSL proteins but resulted in defective H4K16 acetylation and to a lesser extent H4K5 acetylation. As a result all missense variants impaired acetylation. This was also the case for chromobarrel domain variants, while expression of a KAT8 lacking the chromobarrel domain confirmed its ability to form complex with the MSL proteins and the impairment of H4K16 acetylation.

The nonsense variant demonstrated abnormal subnuclear localization.

The mouse model provides extensive evidence for the involvement of KAT8 in cerebral development. Cerebrum-specific Kat8 knockout mice presented postnatal growth retardation, hyperactivity/irritability, pre-weaning lethality, and cerebral hypoplasia upon autopsy. Loss of Kat8 reduced the number of neural stem and progenitor cells available for embryonic cerebrocortical development, impaired cell proliferation and stimulated apoptosis. The article also provides additional evidence from mouse model.
Sources: Literature
Intellectual disability - microarray and sequencing v3.0 SUZ12 Konstantinos Varvagiannis changed review comment from: ID can be a feature in individuals heterozygous for SUZ12 pathogenic variants. 13 affected individuals (from 12 families) have been reported:

[1] PMID 28229514 (Imagawa et al, 2017) : 1 individual
[2] PMID 30019515 (Imagawa et al, 2018) : 2 further unrelated subjects
[3] PMID 31736240 (Cyrus et al, 2019) : 10 additional subjects (from 9 families)

Reviewed by Cyrus et al, features observed in more than half of the (13) affected individuals included prenatal and/or postnatal overgrowth (in some only prenatal, others only postnatal, others did not manifest overgrowth at all), some suggestive facial features (eg. prominent forehead, hypertelorism, downslanting palpebral fissures, round face, broad/low nasal bridge), DD and ID (the latter in 7/13, in most cases mild), advanced bone age, musculoskeletal abnormalities and cryptorchidism. Less frequent features included brain MRI abnormalities (eg. CC hypoplasia/agenesis, etc.), umbilical hernias, respiratory abnormalities, cardiac anomalies (in one).

All were diagnosed with WES/WGS/panel testing, with few having additional findings upon this or prior testing (eg. CNVs/SNVs).

SUZ12 encodes one of the 4 core proteins of the PRC2 complex (the 3 other being encoded by EZH1/2, EED and RBBP4/7). The complex has a methyltransferase activity, catalyzing addition of up to 3 methyl groups on histone 3 at lysine residue 27 (H3K27), leading to chromatin compaction and further to gene silencing.

Mutations in genes encoding 2 other core components of the PRC2 complex - namely EZH2 and EED - cause Weaver and Cohen-Gibson syndrome with overlapping phenotype incl. overgrowth, advanced bone age, craniofacial features and DD/ID.

The SET domain of EZH1/2 and EED as well as the VEFS domain of SUZ12 are contributing to the catalytic activity.

SUZ12 variants reported to date include missense and pLoF variants (frameshift, nonsense, splice site ones) predicted to disrupt or eliminate the VEFS-box domain [almost all missense within this domain with the exception of one proximal to it (Arg535Gln) / pLoF causing truncation prior or within this domain (Arg654Ter might be an exception)] {NP_056170.2}.

Variants either occurred de novo or were inherited (~1/3), on some occasions from a mildly affected parent. Parental mosaicism has also been reported (eg. in ref1, and one or possibly two additional families in ref3).

Some preliminary assumptions on possible genotype-phenotype correlations (for overgrowth and ID related to missense/pLoF variants) are discussed in ref3.

SUZ12 is also be deleted in some patients with NF1 deletion (and a diagnosis of neurofibromatosis type 1). Deletion of SUZ12 has been proposed to contribute to the phenotype of these individuals (eg. overgrowth, cognitive development, facial features). [Discussed in ref1].

Functional studies have been carried out only in the first report (ref1) and demonstrated decreased trimethylation of H3K27 in the case of a missense variant. Overall a partial loss-of-function mechanism has been proposed for the variants.

Mouse models: A study by Pasini et al (PMID: 15385962) did not report phenotypic differences between wt and heterozygous Suz12 knockout mice (gene-trap vector) as for size, morphology and fertility. Total knockout resulted in embryonic lethality, significant growth retardation and several developmental defects. Loss of Suz12 was shown to result in absence of di- and tri-methylated H3K27 in the ko embryos. In another study cited (Miro et al - PMID: 19535498) heterozygous mice (replacement of exons 12-16 with a lacZ gene and neo cassette) displayed variable CNS defects with incomplete penetrance.

The role of the PRC2 complex and the phenotypes related to mutations in genes encoding its core components, are discussed in PMID: 31724824 (also by Cyrus et al, 2019).

SUZ12 is not associated with any phenotype in OMIM. In G2P it is included in the DD panel associated with Weaver-like overgrowth syndrome (disease confidence : confirmed). The gene is also included in gene panels for ID offered by some diagnostic laboratories (eg. GeneDx).
Sources: Literature; to: ID can be a feature in individuals heterozygous for SUZ12 pathogenic variants. 13 affected individuals (from 12 families) have been reported:

[1] PMID 28229514 (Imagawa et al, 2017) : 1 individual
[2] PMID 30019515 (Imagawa et al, 2018) : 2 further unrelated subjects
[3] PMID 31736240 (Cyrus et al, 2019) : 10 additional subjects (from 9 families)

Reviewed by Cyrus et al, features observed in more than half of the (13) affected individuals included prenatal and/or postnatal overgrowth (in some only prenatal, others only postnatal, others did not manifest overgrowth at all), some suggestive facial features (eg. prominent forehead, hypertelorism, downslanting palpebral fissures, round face, broad/low nasal bridge), DD and ID (the latter in 7/13, in most cases mild), advanced bone age, musculoskeletal abnormalities and cryptorchidism. Less frequent features included brain MRI abnormalities (eg. CC hypoplasia/agenesis, etc.), umbilical hernias, respiratory abnormalities, cardiac anomalies (in one).

All were diagnosed with WES/WGS/panel testing, with few having additional findings upon this or prior testing (eg. CNVs/SNVs).

SUZ12 encodes one of the 4 core proteins of the PRC2 complex (the 3 other being encoded by EZH1/2, EED and RBBP4/7). The complex has a methyltransferase activity, catalyzing addition of up to 3 methyl groups on histone 3 at lysine residue 27 (H3K27), leading to chromatin compaction and further to gene silencing.

Mutations in genes encoding 2 other core components of the PRC2 complex - namely EZH2 and EED - cause Weaver and Cohen-Gibson syndrome with overlapping phenotype incl. overgrowth, advanced bone age, craniofacial features and DD/ID.

The SET domain of EZH1/2 and EED as well as the VEFS domain of SUZ12 are contributing to the catalytic activity.

SUZ12 variants reported to date include missense and pLoF variants (frameshift, nonsense, splice site ones) predicted to disrupt or eliminate the VEFS-box domain [almost all missense within this domain with the exception of one proximal to it (Arg535Gln) / pLoF causing truncation prior or within this domain (Arg654Ter might be an exception)] {NP_056170.2}.

Variants either occurred de novo or were inherited (~1/3), on some occasions from a mildly affected parent. Parental mosaicism has also been reported (eg. in ref1, and one or possibly two additional families in ref3).

Some preliminary assumptions on possible genotype-phenotype correlations (for overgrowth and ID related to missense/pLoF variants) are discussed in ref3.

SUZ12 may also be deleted in some patients with NF1 deletion (and a diagnosis of neurofibromatosis type 1). Deletion of SUZ12 has been proposed to contribute to the phenotype of these individuals (eg. overgrowth, cognitive development, facial features). [Discussed in ref1].

Functional studies have been carried out only in the first report (ref1) and demonstrated decreased trimethylation of H3K27 in the case of a missense variant. Overall a partial loss-of-function mechanism has been proposed for the variants.

Mouse models: A study by Pasini et al (PMID: 15385962) did not report phenotypic differences between wt and heterozygous Suz12 knockout mice (gene-trap vector) as for size, morphology and fertility. Total knockout resulted in embryonic lethality, significant growth retardation and several developmental defects. Loss of Suz12 was shown to result in absence of di- and tri-methylated H3K27 in the ko embryos. In another study cited (Miro et al - PMID: 19535498) heterozygous mice (replacement of exons 12-16 with a lacZ gene and neo cassette) displayed variable CNS defects with incomplete penetrance.

The role of the PRC2 complex and the phenotypes related to mutations in genes encoding its core components, are discussed in PMID: 31724824 (also by Cyrus et al, 2019).

SUZ12 is not associated with any phenotype in OMIM. In G2P it is included in the DD panel associated with Weaver-like overgrowth syndrome (disease confidence : confirmed). The gene is also included in gene panels for ID offered by some diagnostic laboratories (eg. GeneDx).
Sources: Literature
Intellectual disability - microarray and sequencing v3.0 SUZ12 Konstantinos Varvagiannis changed review comment from: ID can be a feature in individuals heterozygous for SUZ12 pathogenic variants. 13 affected individuals (from 12 families) have been reported:

[1] PMID 28229514 (Imagawa et al, 2017) : 1 individual
[2] PMID 30019515 (Imagawa et al, 2018) : 2 further unrelated subjects
[3] PMID 31736240 (Cyrus et al, 2019) : 10 newly diagnosed subjects (from 9 families)

Reviewed by Cyrus et al, features observed in more than half of the (13) affected individuals included prenatal and/or postnatal overgrowth (in some only prenatal, others only postnatal, others did not manifest overgrowth at all), some suggestive facial features (eg. prominent forehead, hypertelorism, downslanting palpebral fissures, round face, broad/low nasal bridge), DD and ID (the latter in 7/13, in most cases mild), advanced bone age, musculoskeletal abnormalities and cryptorchidism. Less frequent features included brain MRI abnormalities (eg. CC hypoplasia/agenesis, etc.), umbilical hernias, respiratory abnormalities, cardiac anomalies (in one).

All were diagnosed with WES/WGS/panel testing, with few having additional findings upon this or prior testing (eg. CNVs/SNVs).

SUZ12 encodes one of the 4 core proteins of the PRC2 complex (the 3 other being encoded by EZH1/2, EED and RBBP4/7). The complex has a methyltransferase activity, catalyzing addition of up to 3 methyl groups on histone 3 at lysine residue 27 (H3K27), leading to chromatin compaction and further to gene silencing.

Mutations in genes encoding 2 other core components of the PRC2 complex - namely EZH2 and EED - cause Weaver and Cohen-Gibson syndrome with overlapping phenotype incl. overgrowth, advanced bone age, craniofacial features and DD/ID.

The SET domain of EZH1/2 and EED as well as the VEFS domain of SUZ12 are contributing to the catalytic activity.

SUZ12 variants reported to date include missense and pLoF variants (frameshift, nonsense, splice site ones) predicted to disrupt or eliminate the VEFS-box domain [almost all missense within this domain with the exception of one proximal to it (Arg535Gln) / pLoF causing truncation prior or within this domain (Arg654Ter might be an exception)] {NP_056170.2}.

Variants either occurred de novo or were inherited (~1/3), on some occasions from a mildly affected parent. Parental mosaicism has also been reported (eg. in ref1, and one or possibly two additional families in ref3).

Some preliminary assumptions on possible genotype-phenotype correlations (for overgrowth and ID related to missense/pLoF variants) are discussed in ref3.

SUZ12 is also be deleted in some patients with NF1 deletion (and a diagnosis of neurofibromatosis type 1). Deletion of SUZ12 has been proposed to contribute to the phenotype of these individuals (eg. overgrowth, cognitive development, facial features). [Discussed in ref1].

Functional studies have been carried out only in the first report (ref1) and demonstrated decreased trimethylation of H3K27 in the case of a missense variant. Overall a partial loss-of-function mechanism has been proposed for the variants.

Mouse models: An study by Pasini et al (PMID: 15385962) did not report phenotypic differences between wt and heterozygous Suz12 knockout mice (gene-trap vector) as for size, morphology and fertility. Total knockout resulted in embryonic lethality, significant growth retardation and several developmental defects. Loss of Suz12 was shown to result in absence of di- and tri-methylated H3K27 in the ko embryos. In another study cited (Miro et al - PMID: 19535498) heterozygous mice (replacement of exons 12-16 with a lacZ gene and neo cassette) displayed variable CNS defects with incomplete penetrance.

The role of the PRC2 complex and the phenotypes related to mutations in genes encoding its core components, are discussed in PMID: 31724824 (also by Cyrus et al, 2019).

SUZ12 is not associated with any phenotype in OMIM. In G2P it is included in the DD panel associated with Weaver-like overgrowth syndrome (disease confidence : confirmed). The gene is also included in gene panels for ID offered by some diagnostic laboratories (eg. GeneDx).
Sources: Literature; to: ID can be a feature in individuals heterozygous for SUZ12 pathogenic variants. 13 affected individuals (from 12 families) have been reported:

[1] PMID 28229514 (Imagawa et al, 2017) : 1 individual
[2] PMID 30019515 (Imagawa et al, 2018) : 2 further unrelated subjects
[3] PMID 31736240 (Cyrus et al, 2019) : 10 additional subjects (from 9 families)

Reviewed by Cyrus et al, features observed in more than half of the (13) affected individuals included prenatal and/or postnatal overgrowth (in some only prenatal, others only postnatal, others did not manifest overgrowth at all), some suggestive facial features (eg. prominent forehead, hypertelorism, downslanting palpebral fissures, round face, broad/low nasal bridge), DD and ID (the latter in 7/13, in most cases mild), advanced bone age, musculoskeletal abnormalities and cryptorchidism. Less frequent features included brain MRI abnormalities (eg. CC hypoplasia/agenesis, etc.), umbilical hernias, respiratory abnormalities, cardiac anomalies (in one).

All were diagnosed with WES/WGS/panel testing, with few having additional findings upon this or prior testing (eg. CNVs/SNVs).

SUZ12 encodes one of the 4 core proteins of the PRC2 complex (the 3 other being encoded by EZH1/2, EED and RBBP4/7). The complex has a methyltransferase activity, catalyzing addition of up to 3 methyl groups on histone 3 at lysine residue 27 (H3K27), leading to chromatin compaction and further to gene silencing.

Mutations in genes encoding 2 other core components of the PRC2 complex - namely EZH2 and EED - cause Weaver and Cohen-Gibson syndrome with overlapping phenotype incl. overgrowth, advanced bone age, craniofacial features and DD/ID.

The SET domain of EZH1/2 and EED as well as the VEFS domain of SUZ12 are contributing to the catalytic activity.

SUZ12 variants reported to date include missense and pLoF variants (frameshift, nonsense, splice site ones) predicted to disrupt or eliminate the VEFS-box domain [almost all missense within this domain with the exception of one proximal to it (Arg535Gln) / pLoF causing truncation prior or within this domain (Arg654Ter might be an exception)] {NP_056170.2}.

Variants either occurred de novo or were inherited (~1/3), on some occasions from a mildly affected parent. Parental mosaicism has also been reported (eg. in ref1, and one or possibly two additional families in ref3).

Some preliminary assumptions on possible genotype-phenotype correlations (for overgrowth and ID related to missense/pLoF variants) are discussed in ref3.

SUZ12 is also be deleted in some patients with NF1 deletion (and a diagnosis of neurofibromatosis type 1). Deletion of SUZ12 has been proposed to contribute to the phenotype of these individuals (eg. overgrowth, cognitive development, facial features). [Discussed in ref1].

Functional studies have been carried out only in the first report (ref1) and demonstrated decreased trimethylation of H3K27 in the case of a missense variant. Overall a partial loss-of-function mechanism has been proposed for the variants.

Mouse models: A study by Pasini et al (PMID: 15385962) did not report phenotypic differences between wt and heterozygous Suz12 knockout mice (gene-trap vector) as for size, morphology and fertility. Total knockout resulted in embryonic lethality, significant growth retardation and several developmental defects. Loss of Suz12 was shown to result in absence of di- and tri-methylated H3K27 in the ko embryos. In another study cited (Miro et al - PMID: 19535498) heterozygous mice (replacement of exons 12-16 with a lacZ gene and neo cassette) displayed variable CNS defects with incomplete penetrance.

The role of the PRC2 complex and the phenotypes related to mutations in genes encoding its core components, are discussed in PMID: 31724824 (also by Cyrus et al, 2019).

SUZ12 is not associated with any phenotype in OMIM. In G2P it is included in the DD panel associated with Weaver-like overgrowth syndrome (disease confidence : confirmed). The gene is also included in gene panels for ID offered by some diagnostic laboratories (eg. GeneDx).
Sources: Literature
Intellectual disability - microarray and sequencing v3.0 SUZ12 Konstantinos Varvagiannis gene: SUZ12 was added
gene: SUZ12 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: SUZ12 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
Publications for gene: SUZ12 were set to 28229514; 30019515; 31736240; 15385962; 19535498; 31724824
Phenotypes for gene: SUZ12 were set to Overgrowth; Global developmental delay; Intellectual disability; Accelerated skeletal maturation; Abnormality of the skeletal system; Abnormality of the genitourinary system; Abnormality of the corpus callosum; Abnormality of the respiratory system; Abnormality of the abdominal wall
Penetrance for gene: SUZ12 were set to unknown
Review for gene: SUZ12 was set to GREEN
Added comment: ID can be a feature in individuals heterozygous for SUZ12 pathogenic variants. 13 affected individuals (from 12 families) have been reported:

[1] PMID 28229514 (Imagawa et al, 2017) : 1 individual
[2] PMID 30019515 (Imagawa et al, 2018) : 2 further unrelated subjects
[3] PMID 31736240 (Cyrus et al, 2019) : 10 newly diagnosed subjects (from 9 families)

Reviewed by Cyrus et al, features observed in more than half of the (13) affected individuals included prenatal and/or postnatal overgrowth (in some only prenatal, others only postnatal, others did not manifest overgrowth at all), some suggestive facial features (eg. prominent forehead, hypertelorism, downslanting palpebral fissures, round face, broad/low nasal bridge), DD and ID (the latter in 7/13, in most cases mild), advanced bone age, musculoskeletal abnormalities and cryptorchidism. Less frequent features included brain MRI abnormalities (eg. CC hypoplasia/agenesis, etc.), umbilical hernias, respiratory abnormalities, cardiac anomalies (in one).

All were diagnosed with WES/WGS/panel testing, with few having additional findings upon this or prior testing (eg. CNVs/SNVs).

SUZ12 encodes one of the 4 core proteins of the PRC2 complex (the 3 other being encoded by EZH1/2, EED and RBBP4/7). The complex has a methyltransferase activity, catalyzing addition of up to 3 methyl groups on histone 3 at lysine residue 27 (H3K27), leading to chromatin compaction and further to gene silencing.

Mutations in genes encoding 2 other core components of the PRC2 complex - namely EZH2 and EED - cause Weaver and Cohen-Gibson syndrome with overlapping phenotype incl. overgrowth, advanced bone age, craniofacial features and DD/ID.

The SET domain of EZH1/2 and EED as well as the VEFS domain of SUZ12 are contributing to the catalytic activity.

SUZ12 variants reported to date include missense and pLoF variants (frameshift, nonsense, splice site ones) predicted to disrupt or eliminate the VEFS-box domain [almost all missense within this domain with the exception of one proximal to it (Arg535Gln) / pLoF causing truncation prior or within this domain (Arg654Ter might be an exception)] {NP_056170.2}.

Variants either occurred de novo or were inherited (~1/3), on some occasions from a mildly affected parent. Parental mosaicism has also been reported (eg. in ref1, and one or possibly two additional families in ref3).

Some preliminary assumptions on possible genotype-phenotype correlations (for overgrowth and ID related to missense/pLoF variants) are discussed in ref3.

SUZ12 is also be deleted in some patients with NF1 deletion (and a diagnosis of neurofibromatosis type 1). Deletion of SUZ12 has been proposed to contribute to the phenotype of these individuals (eg. overgrowth, cognitive development, facial features). [Discussed in ref1].

Functional studies have been carried out only in the first report (ref1) and demonstrated decreased trimethylation of H3K27 in the case of a missense variant. Overall a partial loss-of-function mechanism has been proposed for the variants.

Mouse models: An study by Pasini et al (PMID: 15385962) did not report phenotypic differences between wt and heterozygous Suz12 knockout mice (gene-trap vector) as for size, morphology and fertility. Total knockout resulted in embryonic lethality, significant growth retardation and several developmental defects. Loss of Suz12 was shown to result in absence of di- and tri-methylated H3K27 in the ko embryos. In another study cited (Miro et al - PMID: 19535498) heterozygous mice (replacement of exons 12-16 with a lacZ gene and neo cassette) displayed variable CNS defects with incomplete penetrance.

The role of the PRC2 complex and the phenotypes related to mutations in genes encoding its core components, are discussed in PMID: 31724824 (also by Cyrus et al, 2019).

SUZ12 is not associated with any phenotype in OMIM. In G2P it is included in the DD panel associated with Weaver-like overgrowth syndrome (disease confidence : confirmed). The gene is also included in gene panels for ID offered by some diagnostic laboratories (eg. GeneDx).
Sources: Literature
Intellectual disability - microarray and sequencing v2.1135 SLC5A6 Konstantinos Varvagiannis changed review comment from: SLC5A6 encodes the sodium dependent multivitamin transporter (SMVT), a transporter of biotin, pantothenate and lipoate. The transporter has a major role in vitamin uptake in the digestive system (among others is the sole transporter for intestinal uptake of biotin which is not synthesized and but must be obtained from exogenous sources) as well as transport across the blood-brain barrier (SMVT being responsible for 89% of biotin transport) [several refs provided by Subramanian et al and Byrne et al].

4 affected individuals from 3 families have been reported.

Subramanian et al (2017 - PMID: 27904971) et al reported on a girl with feeding difficulties and failure to thrive (requiring nasogastric tube placement), microcephaly, DD (at 15m developmental age corresponding to 6m with features suggestive of spastic cerebral palsy), occurrence of multiple infections, osteoporosis and pathologic bone fractures. MRIs suggested brain atrophy, thin CC and hypoplasia of the pons. Metabolic (AA, OA) investigations and array-CGH were normal. Whole exome sequencing revealed presence of a missense (Arg123Leu - RefSeq not provided) and a nonsense (Arg94Ter) SLC5A6 variant. Serum biotin was normal although - at the time - the child was on parenteral and G-T nutrition. Following administration of biotin, pantothenic acid and lipoic acid the child demonstrated among others improved motor and verbal skills, head growth and normalization of immunoglobulin levels. Transfection of mutants in human derived intestinal HuTu-80 cells and brain U87 cells was carried out and a 3H-biotin assay showed no induction in biotin uptake confirming impaired functionality of the transporter. While wt protein displayed normal expression/membrane localization, Arg94Ter was poorly expressed with ectopic localization (cytoplasm). Arg123Leu was retained predominantly intracellularly, probably in the ER as was further supported by colocalization with DsRed-ER. Evidence from the literature is provided that deficiencies of the specific vitamins explain the clinical features (DD, microcephaly, immunological defect, osteopenia, etc).

Schwantje et al (2019 - PMID: 31392107) described a girl with severe feeding problems, vomiting with blood (suspected Mallory-Weiss syndrome), poor weight gain and delayed gross motor development. The child presented an episode of gastroenteritis associated with reduced consciousness, circulatory insufficiency and metabolic derangement (hypoglycemia, severe metabolic acidosis, hyperammonemia, mild lactate elevation, ketonuria). Investigations some months prior to the admission (?) were suggestive of a metabolic disorder due to elevated plasma C3-carnitine, C5-OH-carnitine and elevated urinary excretion of 3-OH-isovaleric acid (biotinidase deficiency was considered in the DD but enzymatic activity was only marginally decreased). Biotin supplementation was initiated. Trio-exome sequencing (at 3yrs) demonstrated compound heterozygosity for 2 frameshift variants [NM_021095.2:c.422_423del / p.(Val141Alafs*34) and c.1865_1866del]. Following this result, increase of biotin supplementation and introduction of pantothenic acid, GI symptoms (incl. chronic diarrhea) resolved and the child displayed improved appetite and growth, yet a stable motor delay. The authors cite previous studies of conditional ko mice, displaying intestinal mucosal abnormalities and growth defects (similar to the child's problems), prevented by biotin and pantothenic acid supplementation.

Byrne et al (2019 - PMID: 31754459) reported on a sibling pair with severe motor/speech developmental regression following a plateau (at 12m and 14m), development of ataxia and dyskinetic movements (both), seizures (one). Feeding difficulties, reflux and failure to thrive required N-G/gastrostomy feeding while both presented GI hemorrhage (in the case of the older sib, lethal). Other features in the youngest sib included brain MRI abnormalities (cerebral/cerebellar atrophy, thin CC, etc) and IgG deficiency. Biochemical, single-gene testing and mtDNA sequencing were not diagnostic. Exome in one, revealed presence of a frameshift [c.422_423del as above] and a missense variant (Arg400Thr). Sanger sequencing confirmed variants in both sibs and heterozygosity in parents. HeLa cells transfected with empty vector, wt or mut expression constructs confirmed significantly decreased 3H-biotin uptake for mut constructs compared to wt (and similar to empty vector). Parenteral triple vitamin replacement at the age of ~7 years resulted in improved overall condition, regain of some milestones, attenuation of vomiting, and resolution of peripheral neuropathy. Seizure were well-controlled (as was the case before treatment) despite persistence of epileptiform discharges. Again the authors cite studies of conditional (intestine-specific) SLC5A6 ko mice, with those viable (~1/3) demonstrating growth retardation, decreased boned density and GI abnormalities (similar to affected individuals). The phenotype could be rescued by oversupplementation of biotin and pantothenic acid (PMIDs cited: 23104561, 29669219).

[Please consider inclusion in other relevant panels eg. metabolic disorders]
Sources: Literature; to: SLC5A6 encodes the sodium dependent multivitamin transporter (SMVT), a transporter of biotin, pantothenate and lipoate. The transporter has a major role in vitamin uptake in the digestive system (among others is the sole transporter for intestinal uptake of biotin which is not synthesized but must be obtained from exogenous sources) as well as transport across the blood-brain barrier (SMVT being responsible for 89% of biotin transport) [several refs provided by Subramanian et al and Byrne et al].

4 affected individuals from 3 families have been reported.

Subramanian et al (2017 - PMID: 27904971) et al reported on a girl with feeding difficulties and failure to thrive (requiring nasogastric tube placement), microcephaly, DD (at 15m developmental age corresponding to 6m with features suggestive of spastic cerebral palsy), occurrence of multiple infections, osteoporosis and pathologic bone fractures. MRIs suggested brain atrophy, thin CC and hypoplasia of the pons. Metabolic (AA, OA) investigations and array-CGH were normal. Whole exome sequencing revealed presence of a missense (Arg123Leu - RefSeq not provided) and a nonsense (Arg94Ter) SLC5A6 variant. Serum biotin was normal although - at the time - the child was on parenteral and G-T nutrition. Following administration of biotin, pantothenic acid and lipoic acid the child demonstrated among others improved motor and verbal skills, head growth and normalization of immunoglobulin levels. Transfection of mutants in human derived intestinal HuTu-80 cells and brain U87 cells was carried out and a 3H-biotin assay showed no induction in biotin uptake confirming impaired functionality of the transporter. While wt protein displayed normal expression/membrane localization, Arg94Ter was poorly expressed with ectopic localization (cytoplasm). Arg123Leu was retained predominantly intracellularly, probably in the ER as was further supported by colocalization with DsRed-ER. Evidence from the literature is provided that deficiencies of the specific vitamins explain the clinical features (DD, microcephaly, immunological defect, osteopenia, etc).

Schwantje et al (2019 - PMID: 31392107) described a girl with severe feeding problems, vomiting with blood (suspected Mallory-Weiss syndrome), poor weight gain and delayed gross motor development. The child presented an episode of gastroenteritis associated with reduced consciousness, circulatory insufficiency and metabolic derangement (hypoglycemia, severe metabolic acidosis, hyperammonemia, mild lactate elevation, ketonuria). Investigations some months prior to the admission (?) were suggestive of a metabolic disorder due to elevated plasma C3-carnitine, C5-OH-carnitine and elevated urinary excretion of 3-OH-isovaleric acid (biotinidase deficiency was considered in the DD but enzymatic activity was only marginally decreased). Biotin supplementation was initiated. Trio-exome sequencing (at 3yrs) demonstrated compound heterozygosity for 2 frameshift variants [NM_021095.2:c.422_423del / p.(Val141Alafs*34) and c.1865_1866del]. Following this result, increase of biotin supplementation and introduction of pantothenic acid, GI symptoms (incl. chronic diarrhea) resolved and the child displayed improved appetite and growth, yet a stable motor delay. The authors cite previous studies of conditional ko mice, displaying intestinal mucosal abnormalities and growth defects (similar to the child's problems), prevented by biotin and pantothenic acid supplementation.

Byrne et al (2019 - PMID: 31754459) reported on a sibling pair with severe motor/speech developmental regression following a plateau (at 12m and 14m), development of ataxia and dyskinetic movements (both), seizures (one). Feeding difficulties, reflux and failure to thrive required N-G/gastrostomy feeding while both presented GI hemorrhage (in the case of the older sib, lethal). Other features in the youngest sib included brain MRI abnormalities (cerebral/cerebellar atrophy, thin CC, etc) and IgG deficiency. Biochemical, single-gene testing and mtDNA sequencing were not diagnostic. Exome in one, revealed presence of a frameshift [c.422_423del as above] and a missense variant (Arg400Thr). Sanger sequencing confirmed variants in both sibs and heterozygosity in parents. HeLa cells transfected with empty vector, wt or mut expression constructs confirmed significantly decreased 3H-biotin uptake for mut constructs compared to wt (and similar to empty vector). Parenteral triple vitamin replacement at the age of ~7 years resulted in improved overall condition, regain of some milestones, attenuation of vomiting, and resolution of peripheral neuropathy. Seizure were well-controlled (as was the case before treatment) despite persistence of epileptiform discharges. Again the authors cite studies of conditional (intestine-specific) SLC5A6 ko mice, with those viable (~1/3) demonstrating growth retardation, decreased boned density and GI abnormalities (similar to affected individuals). The phenotype could be rescued by oversupplementation of biotin and pantothenic acid (PMIDs cited: 23104561, 29669219).

[Please consider inclusion in other relevant panels eg. metabolic disorders]
Sources: Literature
Intellectual disability - microarray and sequencing v2.1135 SLC5A6 Konstantinos Varvagiannis gene: SLC5A6 was added
gene: SLC5A6 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: SLC5A6 was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: SLC5A6 were set to 27904971; 31392107; 31754459; 23104561; 29669219
Phenotypes for gene: SLC5A6 were set to Feeding difficulties; Failure to thrive; Global developmental delay; Developmental regression; Intellectual disability; Seizures; Microcephaly; Cerebral atrophy; Abnormality of the corpus callosum; Vomiting; Chronic diarrhea; Gastrointestinal hemorrhage; Abnormal immunoglobulin level; Osteopenia; Abnormality of metabolism/homeostasis
Penetrance for gene: SLC5A6 were set to Complete
Review for gene: SLC5A6 was set to GREEN
Added comment: SLC5A6 encodes the sodium dependent multivitamin transporter (SMVT), a transporter of biotin, pantothenate and lipoate. The transporter has a major role in vitamin uptake in the digestive system (among others is the sole transporter for intestinal uptake of biotin which is not synthesized and but must be obtained from exogenous sources) as well as transport across the blood-brain barrier (SMVT being responsible for 89% of biotin transport) [several refs provided by Subramanian et al and Byrne et al].

4 affected individuals from 3 families have been reported.

Subramanian et al (2017 - PMID: 27904971) et al reported on a girl with feeding difficulties and failure to thrive (requiring nasogastric tube placement), microcephaly, DD (at 15m developmental age corresponding to 6m with features suggestive of spastic cerebral palsy), occurrence of multiple infections, osteoporosis and pathologic bone fractures. MRIs suggested brain atrophy, thin CC and hypoplasia of the pons. Metabolic (AA, OA) investigations and array-CGH were normal. Whole exome sequencing revealed presence of a missense (Arg123Leu - RefSeq not provided) and a nonsense (Arg94Ter) SLC5A6 variant. Serum biotin was normal although - at the time - the child was on parenteral and G-T nutrition. Following administration of biotin, pantothenic acid and lipoic acid the child demonstrated among others improved motor and verbal skills, head growth and normalization of immunoglobulin levels. Transfection of mutants in human derived intestinal HuTu-80 cells and brain U87 cells was carried out and a 3H-biotin assay showed no induction in biotin uptake confirming impaired functionality of the transporter. While wt protein displayed normal expression/membrane localization, Arg94Ter was poorly expressed with ectopic localization (cytoplasm). Arg123Leu was retained predominantly intracellularly, probably in the ER as was further supported by colocalization with DsRed-ER. Evidence from the literature is provided that deficiencies of the specific vitamins explain the clinical features (DD, microcephaly, immunological defect, osteopenia, etc).

Schwantje et al (2019 - PMID: 31392107) described a girl with severe feeding problems, vomiting with blood (suspected Mallory-Weiss syndrome), poor weight gain and delayed gross motor development. The child presented an episode of gastroenteritis associated with reduced consciousness, circulatory insufficiency and metabolic derangement (hypoglycemia, severe metabolic acidosis, hyperammonemia, mild lactate elevation, ketonuria). Investigations some months prior to the admission (?) were suggestive of a metabolic disorder due to elevated plasma C3-carnitine, C5-OH-carnitine and elevated urinary excretion of 3-OH-isovaleric acid (biotinidase deficiency was considered in the DD but enzymatic activity was only marginally decreased). Biotin supplementation was initiated. Trio-exome sequencing (at 3yrs) demonstrated compound heterozygosity for 2 frameshift variants [NM_021095.2:c.422_423del / p.(Val141Alafs*34) and c.1865_1866del]. Following this result, increase of biotin supplementation and introduction of pantothenic acid, GI symptoms (incl. chronic diarrhea) resolved and the child displayed improved appetite and growth, yet a stable motor delay. The authors cite previous studies of conditional ko mice, displaying intestinal mucosal abnormalities and growth defects (similar to the child's problems), prevented by biotin and pantothenic acid supplementation.

Byrne et al (2019 - PMID: 31754459) reported on a sibling pair with severe motor/speech developmental regression following a plateau (at 12m and 14m), development of ataxia and dyskinetic movements (both), seizures (one). Feeding difficulties, reflux and failure to thrive required N-G/gastrostomy feeding while both presented GI hemorrhage (in the case of the older sib, lethal). Other features in the youngest sib included brain MRI abnormalities (cerebral/cerebellar atrophy, thin CC, etc) and IgG deficiency. Biochemical, single-gene testing and mtDNA sequencing were not diagnostic. Exome in one, revealed presence of a frameshift [c.422_423del as above] and a missense variant (Arg400Thr). Sanger sequencing confirmed variants in both sibs and heterozygosity in parents. HeLa cells transfected with empty vector, wt or mut expression constructs confirmed significantly decreased 3H-biotin uptake for mut constructs compared to wt (and similar to empty vector). Parenteral triple vitamin replacement at the age of ~7 years resulted in improved overall condition, regain of some milestones, attenuation of vomiting, and resolution of peripheral neuropathy. Seizure were well-controlled (as was the case before treatment) despite persistence of epileptiform discharges. Again the authors cite studies of conditional (intestine-specific) SLC5A6 ko mice, with those viable (~1/3) demonstrating growth retardation, decreased boned density and GI abnormalities (similar to affected individuals). The phenotype could be rescued by oversupplementation of biotin and pantothenic acid (PMIDs cited: 23104561, 29669219).

[Please consider inclusion in other relevant panels eg. metabolic disorders]
Sources: Literature
Intellectual disability - microarray and sequencing v2.1122 TMX2 Konstantinos Varvagiannis edited their review of gene: TMX2: Added comment: A recent report by Vandervore, Schot et al. following the previous review (Am J Hum Genet. 2019 Nov 12 - PMID: 31735293), provides further evidence that biallelic TMX2 mutations cause malformations of cortical development, microcephaly, DD and ID and epilepsy.

As a result this gene should probably be considered for inclusion in the ID/epilepsy panels with green rating.

Overall, 14 affected subjects from 10 unrelated families are reported in the aforementioned study. The majority had severe DD/ID (failure to achieve milestones, absent speech/ambulation and signs of cerebral palsy) with few having a somewhat milder impairment. 12 (of the 14) presented with epilepsy (spasms, myoclonic seizures, focal seizures with/without generalization or generalized tonic-clonic seizures) with onset most often in early infancy. Upon brain MRI (in 12 individuals), 5 presented polymicrogyria, 2 others pachygyria, 4 with brain atrophy, etc.

All individuals were found to harbor biallelic TMX2 mutations by exome sequencing while previous investigations in several had ruled out alternative causes (infections, metabolic or chromosomal anomalies). Missense variants, an in-frame deletion as well as pLoF (stopgain/frameshift) variants were reported. [NM_015959.3 used as ref below].

The effect of variants was supported by mRNA studies, eg. RT-qPCR/allele specific RT-qPCR. The latter proved reduced expression for a frameshift variant (c.391dup / p.Leu131Profs*6) most likely due to NMD. Total mRNA levels were also 23% lower in an individual compound htz for a missense variant and a stopgain one localized in the last exon (c.757C>T / p.Arg253*). As for the previously reported c.614G>A (p.Arg205Gln), affecting the last nucleotide of exon 6, total mRNA in skin fibroblasts from a homozygous individual was not significantly decreased. RNA-Seq however demonstrated the presence of 4 different transcripts (roughly 25% each), one representing the regular mRNA, one with intron 6 retention (also present at low levels in healthy individuals), one with loss of 11 nucleotides within exon 6 and a fourth one due to in-frame skipping of exon 6.

*To the best of my understanding :

Thioredoxin (TRX)-related transmembrane proteins (TMX) belong to the broader family of oxidoreductases of protein disulfide isomerase (PDI) having an important role in protein folding.

Study of the data from the Allen Human Brain Atlas suggest relevant fetal expression also increasing during postnatal life.

As RNA-seq was carried out for 2 individuals, GO analysis suggested that the most deregulated clusters of genes are implicated in post-translational protein modifications (as would be expected for PDIs), membranes and synapse while pathway analysis suggested that relevant categories were inhibited eg. nervous system development/function and cell growth/proliferation/survival.

Upon transfection of HEK293T cells, exogenous TMX2 was shown to co-localize with calnexin (CNX) to the (ER) mitochondria-associated-membrane. Mass-spectrometry based analysis of co-immunoprecipitated proteins confirmed interaction with CNX but also other regulators of calcium homeostasis, mitochondrial membrane components and respiratory chain NADH dehydrogenase.

Study of the mitochondrial activity of TMX2-deficient fibroblasts suggested reduced respiratory reserve capacity, compensated by increased glycolytic activity.

TMX2 occurs in both reduced and oxidized monomeric form. It also forms (homo)dimers with the ratio of dimers/monomers increasing under conditions of oxidative stress. Variant TMX2 increased propensity to form dimers, thus mimicking increased oxidative state. This was observed under stress but also under native conditions.

---------; Changed rating: GREEN
Intellectual disability - microarray and sequencing v2.1117 NSF Ivone Leong Classified gene: NSF as Red List (low evidence)
Intellectual disability - microarray and sequencing v2.1117 NSF Ivone Leong Added comment: Comment on list classification: New gene submitted by expert reviewed. Based on the evidence provided it was decided that there is currently not enough evidence to establish a gene-phenotype association. Therefore, this gene has been given a Red rating.
Intellectual disability - microarray and sequencing v2.1117 NSF Ivone Leong Gene: nsf has been classified as Red List (Low Evidence).
Intellectual disability - microarray and sequencing v2.1098 NSF Konstantinos Varvagiannis gene: NSF was added
gene: NSF was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: NSF was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
Publications for gene: NSF were set to 31675180
Phenotypes for gene: NSF were set to Seizures; EEG with burst suppression; Global developmental delay; Intellectual disability
Penetrance for gene: NSF were set to unknown
Mode of pathogenicity for gene: NSF was set to Loss-of-function variants (as defined in pop up message) DO NOT cause this phenotype - please provide details in the comments
Review for gene: NSF was set to AMBER
Added comment: Suzuki et al. (2019 - PMID: 31675180) report on 2 unrelated individuals with de novo missense NSF variants. Overall the phenotype corresponded to an early infantile epileptic encephalopathy. The first patient developed vomiting and tonic seizures immediately after birth, with burst-suppression pattern upon EEG. Trio exome sequencing, followed by Sanger sequencing of proband and parents, revealed a de novo missense variant (NM_006178.3:c.1375G>A / p.Ala459Thr), absent from public databases and predicted in silico to be deleterious (CADD score of 30). The girl died 36 days after birth due to respiratory failure. Another subject, having necessitated mechanical ventilation due to absence of spontaneous respiration after birth, developed myoclonic seizures. EEG showed a burst-suppression pattern. At the age of 3, she was noted to have persistence of seizures and profound ID. Trio exome sequencing identified a missense NSF variant (c.1688C>T / p.Pro563Leu) also confirmed and shown to be de novo by Sanger sequencing. Again the variant was absent from public datasets and had a CADD score of 34. While expression of wt NSF allele in the developing eye of Drosophila had no effect, expression of mutants severely affected eye development - suggesting a dominant negative effect. NSF encodes a homo-hexameric AAA ATPase, which is recruited by SNAPs (Soluble NSF Attachment Proteins) - and the latter by SNAREs (SNAP REceptors) - thus having a role in vesicular transport and membrane fusion. There is currently no associated phenotype in OMIM/G2P. Overall, this gene could be considered for inclusion probably with amber/red rating pending further evidence (eg. additional work-up or alternative causes/explanations not discussed).
Sources: Literature
Intellectual disability - microarray and sequencing v2.1098 PCYT2 Konstantinos Varvagiannis gene: PCYT2 was added
gene: PCYT2 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: PCYT2 was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: PCYT2 were set to 31637422
Phenotypes for gene: PCYT2 were set to Global developmental delay; Developmental regression; Intellectual disability; Spastic paraparesis; Seizures; Spastic tetraparesis; Cerebral atrophy; Cerebellar atrophy
Penetrance for gene: PCYT2 were set to Complete
Review for gene: PCYT2 was set to GREEN
Added comment: Vaz et al. (2019 - PMID: 31637422 - DDD study among the co-authors) report on 5 individuals - from 4 families - with biallelic PCYT2 mutations.

The phenotype corresponded to a complex hererditary paraplegia with global DD, regression (4/5), ID (mild in 3/5, severe in 2/5), spastic para-/tetraparesis, epilepsy (5/5 - variable onset 2-16 yrs - focal or tonic-clonic seizures) and progressive cerebral and cerebellar atrophy.

Exome sequencing in all revealed biallelic PCYT2 variants, confirmed with Sanger s. in probands and their parents (NM_001184917.2 - corresponding to the canonical transcript used as Ref below):
- P1 (Fam1) : 2 missense SNVs in trans configuration, c.730C>T or p.His244Tyr and c.920C>T or p.Pro307Leu
- P2 (Fam2 - consanguineous of White British origin), P3 (Fam3 - Consanguineous of Turkish origin), P4,5 (Fam4 - consanguineous, unspecified origin) : homozygosity for c.1129C>T or p.Arg377Ter) affecting the last exon of 8/12 transcripts, including the canonical one.

Individuals with the same genotype displayed variable degrees of ID (eg P3 - severe / P2, P4,5 - mild ID).

For sibs in Fam4, homozygosity for a missense SACS variant led to consideration of the respective disorder (AR spastic ataxia of Charlevoix-Saguenay) though the variant was predicted to be tolerated in silico and notably the MRI images not suggestive.

All variants were absent from / had extremely low AF in public databases, with no homozygotes.

Posphatidylethanolamine (PE) is a membrane lipid, particularly enriched in human brain (45% of phospholypid fraction). PE is synthesized either via the CDP-ethanolamine pathway or by decarboxylation of phosphatidylserine in mitochondria. PCYT2 encodes CTP:phosophoethanolamine cytidyltransferase (ET) which is an ubiquitously expressed rate-limiting enzyme for PE biosynthesis in the former pathway.

In silico, the 2 missense variants - localizing in the CTP catalytic domain 2 - were predicted to be damaging, as well as to affect protein stability.

Fibroblasts of 3 patients (P1, P2, P3) representing all variants were studied:
- Enzymatic activity was shown to be significantly reduced (though not absent) compared to controls. Abnormalities were noted upon Western Blot incl. absence in all 3 patients studied of one of the 2 bands normally found in controls (probably representing the longer isoform), reduced intensity in all 3 of another band probably corresponding to a shorter isoform, and presence of an additional band of intermediate molec. mass in patients with the truncating variant.
- RT-PCR on mRNA from patient fibroblasts did not reveal (significant) reduction compared to controls.
- Lipidomic profile of patient fibroblasts was compatible with the location of the block in the phospholipid biosynthesis pathway and different from controls.

The lipidomic profile had similarities with what has been reported for EPT1 deficiency, the enzyme directly downstream of ET. The SELENO1-related phenotype (/EPT1 deficiency) is also highly overlapping.

CRISPR-Cas9 was used to generate pcyt2 partial or complete knockout (ko) zebrafish, targeting either the final (ex13) or another exon (ex3) respectively. mRNA expression was shown to be moderately reduced in the first case and severely reduced/absent in the second, compared to wt. Similarly, complete-ko (ex3) led to significantly lower survival, with impaired though somewhat better survival of partial-ko (ex13) zebrafish.

Complete knockout of Pcyt2 in mice is embryonically lethal (PMID cited: 17325045) while heterozygous mice develop features of metabolic syndrome (PMID cited: 22764088).

Given lethality in knockout zebrafish / mice and the residual activity (15-20%) in patient fibroblasts, the variants reported were thought to be hypomorphic and complete loss of function possibly incompatible with life.

PCYT2 is not associated with any phenotype in OMIM/G2P/SysID and not commonly included in gene panels for ID.

As a result this gene could included in the ID / epilepsy panels with green (~/>3 indiv/fam/variants with the nonsense found in different populations, consistent phenotype, lipidomics, in silico/in vitro/in vivo evidence) or amber rating.

[Please consider inclusion in other possibly relevant panels eg. for metabolic disorders, etc].
Sources: Literature
Intellectual disability - microarray and sequencing v2.1047 METTL5 Konstantinos Varvagiannis gene: METTL5 was added
gene: METTL5 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: METTL5 was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: METTL5 were set to 29302074; http://doi.org/10.1016/j.ajhg.2019.09.007; https://imgc2019.sciencesconf.org/data/abstract_book_complete.pdf
Phenotypes for gene: METTL5 were set to Delayed speech and language development; Intellectual disability; Microcephaly; Behavioral abnormality
Penetrance for gene: METTL5 were set to Complete
Review for gene: METTL5 was set to GREEN
Added comment: [1] - PMID: 29302074 :
In a WES/WGS study of 404 consanguineous families with two or more offspring affected by ID, Hu et al. identified two sibs homozygous for a METTL5 missense variant [NM_014168:c.182G>A / p.Gly61Asp]. These 2 subjects, born to first cousin parents from Iran, presented with early learning impairment, aggressive behaviour, severe microcephaly (-7SD and -8SD) and ID formally evaluated to be in the severe range. Sanger confirmation of variants and segregation studies were performed for all available and informative members in families participating in the study. In silico predictions were all in favour of a deleterious effect (PolyPhen2, MutationTaster, SIFT, CADD) and the variant was absent from ExAC. The effect of the specific variant was studied in ref. 2 (below).

[2] - DOI: 10.1016/j.ajhg.2019.09.007 :
Richard et al. (2019) reported on 5 additional individuals from 2 consanguineous families. Common phenotype consisted of speech delay, moderate/severe ID (4/4), microcephaly (4/4 - though milder than in the first report), behavioral problems (ADHD, aggressiveness, autistic feat.) and possibly some overlapping facial features (nose and ear abnormalities). 3 sibs from the 1st family, from Pakistan, were homozygous for a frameshift variant (NM_014167.2:c.344_345delGA / p.Arg115Asnfs*19) while sibs from the 2nd family, from Yemen, were homozygous for p.Lys191Valfs*1 (c.571_572delAA). Confirmation and segregation studies supported a role for the variants.

The authors performed additional studies for METTL5 and all 3 variants reported to date, notably:
- Based on RNA-seq data from the Allen Brain Atlas, METTL5 is expressed in the developing and adult human brain (incl. cerebellar cortex, hippocampus and striatum).
- Immunostaining in mouse brain demonstrated ubiquitous expression (postnatal day 30).
- In rat hippocampal neurons, enrichment of METTL5 was found in the soma, the nucleus and pre- and post- synaptic regions.
- Myc-/GFP-tagged METTL5 wt or mutants were transiently expressed in COS7 cells, and were found in the cytoplasm and nucleus. Levels of the 2 frameshift variants were significantly reduced compared with wt, although this was not the case for Gly61Asp.
- Upon transfection of rat hippocampal neurons, METTL5-GFP tagged wt and mt proteins showed similar localicalization in nucleus and dendrites.
- Western blot on HEK293T cells transfected with Myc-METTL5 wt or mt constructs demonstrated decreased amounts for the frameshift (but not the missense) variants while comparison after addition of a proteasome inhibitor or cyclohexamide suggested that this is not probably due to decreased mutant protein - rather than mRNA (NMD) - stability.
- In zebrafish, morpholino knockdown of mettl5 led to reduced head size and head/body ratio (reproducing the microcephaly phenotype) and curved tails. Forebrain and midbrain sizes were also significantly reduced.

Based on the ACMG criteria, Gly61Asp is classified as VUS (PM2, PP1, PP3) and the frameshift ones as pathogenic (PS3, PM2, PM4, PP1, PP3).

The authors comment that METTL5 is an uncharacterized member of the methyltransferase superfamily (of 33 METTL proteins). Variants in other methyltransferase-like genes (mainly METTL23) have been associated with ID, while various histone-/DNA-/tRNA-/rRNA- methyltransferases such as EHMT1, DNMT3A, NSUN2, FTSJ1, etc have been implicated in ID. Given the role of methyltransferases in neurodevelopment and neuroplasticity, homology comparisons suggesting presence of relevant domain in METTL5 and accumulation of the protein in the nucleus, a role as epigenetic regulator is proposed (see also ref. 3).

[3] - Conference abstract by Helmut et al. ["A novel m6A RNA methyltransferase in mammals - characterization of Mettl5 mutant mice in the German Mouse Clinic" - Oral presentation in the 33rd International Mammalian Genome Conference Sept. 2019 - available at : https://imgc2019.sciencesconf.org/data/abstract_book_complete.pdf ]
The group using an in vitro methyltransferase assay, identified METTL5 as a m6A RNA methyltransferase. Generation of Mettl5-knockout mice using the CRISPR/Cas technology, suggested that homozygous mice are subviable, with lower body mass and abnormal growth of nasal bones in half. Homozygous mice were hypoactive and hypoexploratory during an open field test at the age of 8 weeks, while further alterations were observed in neurological functions. Phenotypic deviations were absent or very mild in heterozygous animals. As a result, the mouse model appeared to recapitulate relevant human phenotypes (microcephaly, ID and growth retardation).

----
There is no associated entry in OMIM (neither for the gene nor for a related disorder). G2P does not list any phenotype for this gene, either.

METTL5 is included in the SysID database as a current primary ID gene (cited: 27457812, 28097321 / Given the shared co-authors with the study by Richard et al. as well as the overlapping variants, these articles probably report on the same individuals recently described in more detail).

The gene is included in gene panels for ID offered by some diagnostic laboratories (eg. GeneDx).
----

Overall, METTL5 could be considered for inclusion in the ID panel probably as green (3 families, 3 variants, segregation, suggested role of the gene, relevant expression patterns, some evidence at the variant-level, zebrafish and mouse models) or amber (underlying effect of Gly61Asp unknown and variant classified as VUS).
Sources: Literature
Intellectual disability - microarray and sequencing v2.1046 TIMM50 Konstantinos Varvagiannis gene: TIMM50 was added
gene: TIMM50 was added to Intellectual disability. Sources: Literature,Radboud University Medical Center, Nijmegen
Mode of inheritance for gene: TIMM50 was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: TIMM50 were set to 27573165; 30190335; 31058414; Serajee et al. (ASHG conference 2015 - abstract Nr. 2299T)
Phenotypes for gene: TIMM50 were set to 3-methylglutaconic aciduria, type IX (MIM 617698)
Penetrance for gene: TIMM50 were set to Complete
Review for gene: TIMM50 was set to GREEN
gene: TIMM50 was marked as current diagnostic
Added comment: Biallelic pathogenic TIMM50 variants cause 3-methylglutaconic aciduria, type IX (MIM 617698).

At least 9 affected individuals from 5 unrelated (but often consanguineous) families of variable origin have been reported (based on a conference abstract and PMIDs : 27573165, 30190335, 31058414).

TIMM50 encodes encodes a subunit of the mitochondrial presequence import machinery called the TIM23 complex. TIMM50 serves as a major receptor in the intermembrane space that binds to proteins on their way to cross the mitochondrial inner membrane (summary by Shahrour et al., 2017 and OMIM).

The highly overlapping patient clinical features [seizures, DD and ID - the latter in all age-appropriate individuals (5 from 3 families - refs 2,4)], metabolic investigations (lactate elevations in many, elevated urinary 3MGA in almost all, variable mitochondrial complex deficiencies in some), additional extensive functional evidence of mitochondrial dysfunction or the similar phenotypes in other types of 3-methylglutaconic aciduria all support a role for the gene.

[AUH- / CLPB- / DNAJC19- / HTRA2- / OPA3- / SERAC1-related methylglutaconic acidurias are all included as relevant disorders in the ID panel, with the respective genes rated green.]

TIMM50 is included in gene panels for ID offered by some diagnostic laboratories (incl. Radboudumc and GeneDx).

The gene is not associated with any phenotype in G2P

As a result this gene could be considered for inclusion/upgrade as green in both ID and epilepsy panels respectively.

---------

[1] - Serajee et al. (ASHG conference 2015 - abstract Nr. 2299T) reported on a patient born to consanguineous parents of South Asian ancestry with intractable epilepsy, microcephaly, DD and spastic quadriplegia. Metabolic investigations revealed increased urinary 3MGA. Two similarly affected sisters with demonstrated increase of 3MGA, were deceased following an infection. WES in the affected child, 2 unaffected sibs and the parents suggested a homozygous missense variant as the likely cause of the disorder in the proband (c.1114G>A / p.G372S - Reference not specified though the variant probably corresponds to ENST00000314349.4 and ClinVar's entry VCV000208697.1 - www.ncbi.nlm.nih.gov/clinvar/variation/208697/).

[2] - Shahroor et al. (2017, PMID: 27573165) reported on 2 consanguineous families, each with 2 affected individuals. Two sibs from the 1st family (of Bedouin origin) presented with seizures (onset at 3m and 4m respectively), DD and ID with slightly elevated plasma lactate and increased urinary 3MGA upon metabolic investigations. Enzymatic activities of mitochondrial complex I-V were carried out for 1 sib and were normal also after normalization for citrate synthase. Following a SNP array, WES was carried out in affected children and their parents. Both sibs were homozygous for a missense SNV [NM_001001563.1:c.755C>T / p.Thr252Met]. Segregation studies - also in 3 unaffected sibs - supported a role for the variant.

Two sibs from the 2nd family (of Muslim origin) presented with seizures (myoclonic jerks at 3m, generalized tonic movements at 2m - respectively) with DD and ID. Urinary 3MGA was elevated for both, with CSF lactate also elevated in one. WES revealed homozygosity for p.Arg217Trp (NM_001001563.1:c.649C>T) and segregation studies in parents and an unaffected sib were again compatible.

The authors could not demonstrate pathogenicity of the variants in a yeast based system although - as also commented on in Ref 4 - the human TIMM50 could not rescue the yeast ΔΤim50 growth defect and global conservation between the two proteins is poor.

[3] - Reyes et al. (2018, PMID: 30190335) reported on one individual with onset of infantile spasms at the age of 2m with hypsarrythmia upon EEG and psychomotor regression. Leigh-like features were noted upon brain MRI. Lactate was elevated in both plasma and CSF. Urinary 3MGA was normal. WES, Sanger confirmation and segregation studies demonstrated compound htz for 2 variants (NM_001001563:c.335C>A or p.S112* and c.569G>C or p.G190A). Functional studies demonstrated among others decrease in all components of the TIM23 complex and decreased mitochondrial membrane potential. Patient fibroblasts grown in glucose had lower levels of all complex II and IV subunits and one complex I subunit (due to the impairment in import system) with decreased mitochondrial respiration and increase in ROS production. Growth in galactose - shifting energy production toward OxPhos - caused massive cell death. The phenotype was rescued/substantially improved following complementation of patient fibroblasts with wt TIMM50.

[4] - Tort et al. (2019, PMID: 31058414) reported on a boy with seizures and ID (diagnosis of West syndrome), Leigh-like MRI anomalies, cardiomyopathy with elevated plasma and CSF lactate and persistent urinary elevation of 3MGA. The proband was found to be compound heterozygous for 2 TIMM50 variants [NM_001001563.5:c.341 G>A (p.Arg114Gln) in trans with c.805 G>A (p.Gly269Ser)] following WES and Sanger confirmation/segregation studies. In patient fibroblasts TIMM50 protein levels were severely reduced upon WB although mRNA levels were similar to control. Muscle biopsy revealed decreased activity of the complexes I-IV, when normalized to the citrate synthase activity. Accumulation of lipidic material in muscle fibers was shown to be associated with mitochondria upon EM. Expression and sublocalization of mitochondria-targeted proteins were not found to be affected in patient fibroblasts. In extracts from muscle biopsy reduced protein levels of SDHA, COX4L and MTCO1 were demonstrated, in line with the disruptions in the activities of the MRC. Mitochondrial morphology and network were shown to be altered in patient fibroblasts. Patient fibroblasts showed marked reduction of max respiratory capacity. Similar reduction was noted in CRISPR/Cas9 generated TIMM50-ko HEK293T cells, but rescued upon transient transfection with a plasmid encoding for wt TIMM50.

(Functional studies better summarized in the respective articles).
Sources: Literature, Radboud University Medical Center, Nijmegen
Intellectual disability - microarray and sequencing v2.1022 PIGP Konstantinos Varvagiannis gene: PIGP was added
gene: PIGP was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: PIGP was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: PIGP were set to 28334793; 31139695
Phenotypes for gene: PIGP were set to Generalized hypotonia; Global developmental delay; Seizures; Intellectual disability; Feeding difficulties; Cortical visual impairment
Penetrance for gene: PIGP were set to Complete
Review for gene: PIGP was set to GREEN
gene: PIGP was marked as current diagnostic
Added comment: Johnstone et al. (2017 - PMID: 28334793) report on 2 sibs born to non-consanguineous parents of French-Irish ancestry. Both presented with seizures (onset at the age of 2 and 7 weeks respectively), hypotonia and profound DD. Other features included CVI and feeding difficulties. Extensive metabolic testing as well as prior genetic testing (ARX, STXBP1, MECP2, aCGH) in the family were non-diagnostic. WES suggested the presence of 2 PIGP variants with Sanger sequencing used for confirmation and segregation studies.

PIGP encodes a subunit of the enzyme that catalyzes the first step of glycophosphatidylinositol (GPI) anchor biosynthesis. Mutations in other genes whose proteins are in complex with PIGP (PIGA, PIGC, PIGQ, PIGY, DPM2) lead to similar phenotypes. The phenotype overall was also overlapping with the inherited GPI deficiencies (belonging to the broader group of CDGs).

PIGP has 2 isoforms, which differ by 24 amino acids due to utilization of alternative start codons [corresponding to NM_153681.2 (158 aa) and NM_153682.2 (134 aa)].

The variants identified affected both transcripts with the first SNV leading either to loss of the start codon (NM_153682.2:c.2T>C - p.Met1Thr) or to substitution of a methionine at position 25(NM_153681.2:c.74T>C;p.Met25Thr). The second variant led to frameshift in the last exon of both transcripts predicting a longer protein product (NM_153681.2:c.456delA / p.Glu153AsnfsTer34 or NM_153682.2:c.384delA / p.Glu129AsnfsTer34).

Overall extensive studies demonstrated decreased levels of PIGP mRNA in patient fibroblast, decreased amounts of mutant protein in transfected HEK293 cells. The decreased levels of GPI-APs further supported the effect of variants :

- mRNA levels in patient fibroblasts were reduced compared to controls. Conclusions could not be drawn from Western blot, since no antibodies could specifically detect PIGP. HEK293 cells transfected of mt or wt HA-tagged PIGP cDNA led to undetectable amounts for the first variant (both M1T/M25T) and a protein product of increased molecular weight for the frameshift one.
- Flow cytometry of patient granulocytes indicated reduced signal of CD16 (a GPI-anchored protein) and FLAER (binding directly to the GPI anchor).
- Reduced levels of GPI-APs were also observed in PIGP deficient HAP1 cells transfected with either wt, or mutant PIGP cDNA (of both isoforms for the M1T/M25T or isoform 2 for the frameshift mutation).

--------

Krenn et al. (2019 - PMID: 31139695) described a patient born to non-consanguineous Polish parents. Features were highly similar to those reported by Johnstone et al. and incl. intractable infantile seizures (onset at 7m), hypotonia, severe DD and feeding difficulties. Metabolic work-up failed to identify an alternative diagnosis. WES revealed homozygosity for the frameshift variant reported by Johnstone et al. Sanger sequencing confirmed the variant and carrier state in both parents. Identified ROH of less than 7 Mb in the WES data, suggested a founder mutation rather than unreported consanguinity. The variant is present 9 times in gnomAD (AF of 3.2e-5 / no homozygotes). Flow cytometry of patient granulocytes, revealed markedly reduced expression of GPI-APs (CD157, CD59, FLAER) compared to parents/controls.

ALP was normal in all aforementioned individuals (probably in line with PIGP being involved in the 1st step of the GPI anchor biosynthesis).

--------

A further individual with phenotype of EIEE-55;GPIBD-14 is reported in LOVD [Individual #00246132]. This individual, born to consanguineous parents, was tested by WES and found to be homozygous for a frameshift variant, also affecting the last exon in both transcripts (NM_153681.2:c.384delA (p.Glu129ArgfsTer7) / NM_153682.2:c.312delA (p.Glu105ArgfsTer7). This was probably in agreement with segregation studies according to the respective entry. The specific variant is reported as pathogenic [variant ID #0000500090].

--------

?Epileptic encephalopathy, early infantile, 55 (MIM 617599) is the corresponding phenotype in OMIM. There is no relevant G2P entry.
PIGP is included in gene panels for ID offered by some diagnostic laboratories (eg. GeneDx).

--------

As a result, PIGP can be considered for inclusion in the ID/epilepsy panels probably as green (3 individuals, role of the gene and similarity to other inherited GPI deficiencies, extensive supporting studies) or amber.

(Please consider inclusion in other possibly relevant panels eg. CDGs, etc).
Sources: Literature
Intellectual disability - microarray and sequencing v2.953 PIGB Konstantinos Varvagiannis gene: PIGB was added
gene: PIGB was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: PIGB was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: PIGB were set to 31256876
Phenotypes for gene: PIGB were set to Generalized hypotonia; Global developmental delay; Intellectual disability; Seizures; Hearing abnormality; Abnormality of vision; Elevated alkaline phosphatase; Abnormality of the head; Abnormality of the hand; Abnormality of the foot
Penetrance for gene: PIGB were set to Complete
Review for gene: PIGB was set to GREEN
Added comment: Murakami et al. (2019 - PMID: 31256876) provide detailed information on 14 individuals from 10 families (4 of which consanguineous) with biallelic pathogenic PIGB variants.

Overlapping features included DD/ID (13/13), epilepsy (14/14), deafness (7/14), ophthalmological or brain anomalies, hand and feet anomalies as well as presence of dysmorphic features. ID was common, in those individuals with appropriate age. Some had a previous diagnosis of DOORS syndrome (deafness/onychodystrophy/osteodystrophy,retardation, seizures) and few showed 2-oxoglutatic aciduria which can also be seen in DOORS s.

PIGB encodes phosphatidylinositol glycan anchor biosynthesis class B protein.

Overall the phenotype was similar to other inherited glycosylphosphatidylinositol (GPI) deficiencies (IGDs). As happens to be the case in some other GPI deficiencies alkaline phosphatase was also elevated in those tested (8/9).

8 missense, 1 stopgain as well as an intronic SNV are reported. All variants were either absent or ultra-rare and with no homozygotes in gnomAD.

Affected individuals from 4 families, harbored an intronic SNV in the homozygous state. For this variant - with MAF of 0.0001592 or 6.51x10-5 in ExAC and gnomAD - activation of an aberrant splice acceptor site was shown [NM_004855.4:c.847-10A>G or p.Gln282_Trp283insArgCysGln].

Flow cytometric analysis of blood cells or fibroblasts showed decreased levels for various GPI-AP (GPI-anchored protein) markers in affected individuals. These levels were rescued upon transduction with a PIGB-encoding-Lx304 lentiviral vector of fibroblasts from one affected individual, suggesting that the PIGB defect was responsible.

The effect of the variants was evaluated using PIGB-deficient CHO cells, transfected with wt or mutant PIGB cDNAs. FACS analysis and immunoblotting demonstrated that variants were able to restore only slightly/partially - if at all - the surface presence of GPI-APs in the case of variants while the levels of mutant protein were reduced.

PIGB is not associated with any phenotype in OMIM/G2P. This gene is not commonly included in gene panels for ID offered by diagnostic laboratories.

As a result, this gene can be considered for inclusion in the ID and epilepsy panels probably as green (or amber).
Sources: Literature
Intellectual disability - microarray and sequencing v2.938 CTBP1 Konstantinos Varvagiannis changed review comment from: 12 individuals with a recurrent missense variant in CTBP1 have been reported, all summarized in the last article:
- Beck et al. 2016 (PMID: 27094857) : 4 individuals
- Sommerville et al. 2017 (PMID: 28955726) : 1 subject
- Beck et al. 2019 (PMID: 31041561) : 7 further individuals

Features included hypotonia, DD/ID, ataxia and tooth enamel defects. The degree of ID - when present - appeared to be highly variable based at least on the first two reports (3 individuals with severe ID, 1 with borderline-normal intellectual functioning, 1 did not exhibit ID) where this feature was further commented on.

A recurrent missense variant was found in all 12 affected individuals [NM_001328.2:c.1024C>T - p.(Arg342Trp) or NM_001012614.1:c.991C>T - p.(Arg331Trp)]. De novo occurrence this SNV was shown for (almost) all individuals, although in one case maternal sequencing reads were compatible with low-level somatic mosaicism (4/75 reads) not detected by Sanger sequencing. The mother of this individual was phenotypically normal. The variant is absent from gnomAD. Several in silico predictions (SIFT, PolyPhen2, MutationTaster, etc) suggest a deleterious effect.

Given recurrence of this specific variant, and presence of LoF ones in healthy individuals (pLI of 0.98 though in gnomAD) Beck et al. suggested a dominant negative or a gain-of-function effect rather than a loss of function mechanism.

Exclusion of alternative causes: was mainly discussed for the subject reported by Sommerville et al., due to the primary suspicion of a mitochondrial disorder (sequencing and research for mtDNA rearrangements, additional analysis of nuclear genes for mitochondrial disorders).

Expression: CTBP1 encodes C-terminal binding protein 1, with expression among others in brain and cerebellum (https://gtexportal.org/home/gene/CTBP1).

Role and Functional studies:
- The major nuclear isoform of CTBP1 (corresponding to NM_001328.2) and of its paralog CTBP2 function as transcriptional regulators (corepressors). The PLDLS(Pro-Leu-Asp-Leu-Ser)-binding cleft domain where this variant lies, acts as a high-affinity protein-binding interface to recruit DNA-binding repressors and chromatin modifying enzymes (PMID: 17967884).
- In a human glioblastoma cell line interaction of various cofactors with (Flag-tagged) CTBP1 was studied by immunoprecitipation with the Flag antibody and subsequent proteomic (LC-MS) analysis. This demonstrated reduced interaction in the case of R342W (compared to wt) with Zn-finger transcription factors, histone deacetylases, histone methyltransferases, histone H3-K4 demethylase etc. Western blot analyses also revealed reduced interaction of the R342W with several CTBP cofactors.
- RNA-seq analysis in glioblastoma cell line revealed similar overall transcriptional profiles between wt and R342W though multiple RNA species showed significant differences (eg. genes involved in the biological processes of mitotic nuclear division, DNA repair, transcription and regulation of transcription among those that were most upregulated and genes involved in brain development among the most downregulated).
- Patient fibroblasts under conditions of glucose deprivation exhibited strikingly more cell death compared to control fibroblasts. Study of mRNA levels of pro-apoptotic genes by q-RT-PCR revealed that Noxa expression under glucose deprivation vs under normal glucose was 8 to 10-fold enhanced for control fibroblasts, but more than 30-fold enhanced in the case patient fibroblasts. Western blot analyses were also in line with this.
- Mitochondrial dysfunction (probably secondary) with evidence of decreased complex I (and complex IV) activities in skeletal muscle was the case for 2 individuals among multiple patients who had muscle biopsies.

Animal models:
- Beck et al. discuss previously published mouse models where Ctbp1/2 both play overlapping transcriptional roles during development. Homozygous deletion of Ctbp2 is embryonically lethal (>E10.5). Homozygous deletion of Ctbp1 results in viable mice with reduced size and lifespan (Cited: Hildebrand et al. 2002 - PMID: 12101226)
- As commented on by Sommerville et al., Ctbp1 knockout in mouse embryonic fibroblasts resulted in elongated mitochondria, abnormal mitochondrial cristae, diminished ATP and O2 consumption and mitochondrial membrane potential.

----
CTBP1 is associated with Hypotonia, ataxia, developmental delay, and tooth enamel defect syndrome (617915) in OMIM. It is not associated with any phenotype in G2P.
Some diagnostic laboratories (eg. GeneDx participating in the first study and others) include this gene in panels for intellectual disability.
----

As a result, CTBP1 can be added in the current panel probably as green.; to: 12 individuals with a recurrent missense variant in CTBP1 have been reported, all summarized in the last article:
- Beck et al. 2016 (PMID: 27094857) : 4 individuals
- Sommerville et al. 2017 (PMID: 28955726) : 1 subject
- Beck et al. 2019 (PMID: 31041561) : 7 further individuals

Features included hypotonia, DD/ID, ataxia and tooth enamel defects. The degree of ID - when present - appeared to be highly variable based at least on the first two reports (3 individuals with severe ID, 1 with borderline-normal intellectual functioning, 1 did not exhibit ID) where this feature was further commented on.

A recurrent missense variant was found in all 12 affected individuals [NM_001328.2:c.1024C>T - p.(Arg342Trp) or NM_001012614.1:c.991C>T - p.(Arg331Trp)]. De novo occurrence this SNV was shown for (almost) all individuals, although in one case maternal sequencing reads were compatible with low-level somatic mosaicism (4/75 reads) not detected by Sanger sequencing. The mother of this individual was phenotypically normal. The variant is absent from gnomAD. Several in silico predictions (SIFT, PolyPhen2, MutationTaster, etc) suggest a deleterious effect.

Given recurrence of this specific variant, and presence of LoF ones in healthy individuals (pLI of 0.98 though in gnomAD) Beck et al. suggested a dominant negative or a gain-of-function effect rather than a loss of function mechanism.

Exclusion of alternative causes: was mainly discussed for the subject reported by Sommerville et al., due to the primary suspicion of a mitochondrial disorder (sequencing and research for mtDNA rearrangements, additional analysis of nuclear genes for mitochondrial disorders).

Expression: CTBP1 encodes C-terminal binding protein 1, with expression among others in brain and cerebellum (https://gtexportal.org/home/gene/CTBP1).

Role and Functional studies:
- The major nuclear isoform of CTBP1 (corresponding to NM_001328.2) and of its paralog CTBP2 function as transcriptional regulators (corepressors). The PLDLS(Pro-Leu-Asp-Leu-Ser)-binding cleft domain where this variant lies, acts as a high-affinity protein-binding interface to recruit DNA-binding repressors and chromatin modifying enzymes (PMID: 17967884).
- In a human glioblastoma cell line interaction of various cofactors with (Flag-tagged) CTBP1 was studied by immunoprecitipation with the Flag antibody and subsequent proteomic (LC-MS) analysis. This demonstrated reduced interaction in the case of R342W (compared to wt) with Zn-finger transcription factors, histone deacetylases, histone methyltransferases, histone H3-K4 demethylase etc. Western blot analyses also revealed reduced interaction of the R342W with several CTBP cofactors.
- RNA-seq analysis in glioblastoma cell line revealed similar overall transcriptional profiles between wt and R342W though multiple RNA species showed significant differences (eg. genes involved in the biological processes of mitotic nuclear division, DNA repair, transcription and regulation of transcription among those that were most upregulated and genes involved in brain development among the most downregulated).
- Patient fibroblasts under conditions of glucose deprivation exhibited strikingly more cell death compared to control fibroblasts. Study of mRNA levels of pro-apoptotic genes by q-RT-PCR revealed that Noxa expression under glucose deprivation vs under normal glucose was 8 to 10-fold enhanced for control fibroblasts, but more than 30-fold enhanced in the case patient fibroblasts. Western blot analyses were also in line with this.
- Mitochondrial dysfunction (probably secondary) with evidence of decreased complex I (and complex IV) activities in skeletal muscle was the case for 2 individuals among multiple patients who had muscle biopsies.

Animal models:
- Beck et al. discuss previously published mouse models where Ctbp1/2 both play overlapping transcriptional roles during development. Homozygous deletion of Ctbp2 is embryonically lethal (>E10.5). Homozygous deletion of Ctbp1 results in viable mice with reduced size and lifespan (Cited: Hildebrand et al. 2002 - PMID: 12101226)
- As commented on by Sommerville et al., Ctbp1 knockout in mouse embryonic fibroblasts resulted in elongated mitochondria, abnormal mitochondrial cristae, diminished ATP and O2 consumption and mitochondrial membrane potential (Cited: Kim and Youn 2009 - PMID: 19136938).

----
CTBP1 is associated with Hypotonia, ataxia, developmental delay, and tooth enamel defect syndrome (617915) in OMIM. It is not associated with any phenotype in G2P.
Some diagnostic laboratories (eg. GeneDx participating in the first study and others) include this gene in panels for intellectual disability.
----

As a result, CTBP1 can be added in the current panel probably as green.
Intellectual disability - microarray and sequencing v2.938 CTBP1 Konstantinos Varvagiannis changed review comment from: 12 individuals with a recurrent missense variant in CTBP1 have been reported, all summarized in the last article:
- Beck et al. 2016 (PMID: 27094857) : 4 individuals
- Sommerville et al. 2017 (PMID: 28955726) : 1 subject
- Beck et al. 2019 (PMID: 31041561) : 7 further individuals

Features included hypotonia, DD/ID, ataxia and tooth enamel defects. The degree of ID - when present - appeared to be highly variable based at least on the first two reports (3 individuals with severe ID, 1 with borderline-normal intellectual functioning, 1 did not exhibit ID) where this feature was further commented on.

A recurrent missense variant was found in all 12 affected individuals [NM_001328.2:c.1024C>T - p.(Arg342Trp) or NM_001012614.1:c.991C>T - p.(Arg331Trp)]. De novo occurrence this SNV was shown for (almost) all individuals, although in one case maternal sequencing reads were compatible with low-level somatic mosaicism (4/75 reads) not detected by Sanger sequencing. The mother of this individual was phenotypically normal. The variant is absent from gnomAD. Several in silico predictions (SIFT, PolyPhen2, MutationTaster, etc) suggest a deleterious effect.

Given recurrence of this specific variant, and presence of LoF ones in healthy individuals (pLI of 0.98 though in gnomAD) Beck et al. suggested a dominant negative or a gain-of-function effect rather than a loss of function mechanism.

Exclusion of alternative causes: was mainly discussed for the subject reported by Sommerville et al., due to the primary suspicion of a mitochondrial disorder (sequencing and research for mtDNA rearrangements, additional analysis of nuclear genes for mitochondrial disorders).

Expression: CTBP1 encodes C-terminal binding protein 1, with expression among others in brain and cerebellum (https://gtexportal.org/home/gene/CTBP1 ).

Role and Functional studies:
- The major nuclear isoform of CTBP1 (corresponding to NM_001328.2) and of its paralog CTBP2 function as transcriptional regulators (corepressors). The PLDLS(Pro-Leu-Asp-Leu-Ser)-binding cleft domain where this variant lies, acts as a high-affinity protein-binding interface to recruit DNA-binding repressors and chromatin modifying enzymes (PMID: 17967884).
- In a human glioblastoma cell line interaction of various cofactors with (Flag-tagged) CTBP1 was studied by immunoprecitipation with the Flag antibody and subsequent proteomic (LC-MS) analysis. This demonstrated reduced interaction in the case of R342W (compared to wt) with Zn-finger transcription factors, histone deacetylases, histone methyltransferases, histone H3-K4 demethylase etc. Western blot analyses also revealed reduced interaction of the R342W with several CTBP cofactors.
- RNA-seq analysis in glioblastoma cell line revealed similar overall transcriptional profiles between wt and R342W though multiple RNA species showed significant differences (eg. genes involved in the biological processes of mitotic nuclear division, DNA repair, transcription and regulation of transcription among those that were most upregulated and genes involved in brain development among the most downregulated).
- Patient fibroblasts under conditions of glucose deprivation exhibited strikingly more cell death compared to control fibroblasts. Study of mRNA levels of pro-apoptotic genes by q-RT-PCR revealed that Noxa expression under glucose deprivation vs under normal glucose was 8 to 10-fold enhanced for control fibroblasts, but more than 30-fold enhanced in the case patient fibroblasts. Western blot analyses were also in line with this.
- Mitochondrial dysfunction (probably secondary) with evidence of decreased complex I (and complex IV) activities in skeletal muscle was the case for 2 individuals among multiple patients who had muscle biopsies.

Animal models:
- Beck et al. discuss previously published mouse models where Ctbp1/2 both play overlapping transcriptional roles during development. Homozygous deletion of Ctbp2 is embryonically lethal (>E10.5). Homozygous deletion of Ctbp1 results in viable mice with reduced size and lifespan (Cited: Hildebrand et al. 2002 - PMID: 12101226)
- As commented on by Sommerville et al., Ctbp1 knockout in mouse embryonic fibroblasts resulted in elongated mitochondria, abnormal mitochondrial cristae, diminished ATP and O2 consumption and mitochondrial membrane potential.

----
CTBP1 is associated with Hypotonia, ataxia, developmental delay, and tooth enamel defect syndrome (617915) in OMIM. It is not associated with any phenotype in G2P.
Some diagnostic laboratories (eg. GeneDx participating in the first study and others) include this gene in panels for intellectual disability.
----

As a result, CTBP1 can be added in the current panel probably as green.
Sources: Literature; to: 12 individuals with a recurrent missense variant in CTBP1 have been reported, all summarized in the last article:
- Beck et al. 2016 (PMID: 27094857) : 4 individuals
- Sommerville et al. 2017 (PMID: 28955726) : 1 subject
- Beck et al. 2019 (PMID: 31041561) : 7 further individuals

Features included hypotonia, DD/ID, ataxia and tooth enamel defects. The degree of ID - when present - appeared to be highly variable based at least on the first two reports (3 individuals with severe ID, 1 with borderline-normal intellectual functioning, 1 did not exhibit ID) where this feature was further commented on.

A recurrent missense variant was found in all 12 affected individuals [NM_001328.2:c.1024C>T - p.(Arg342Trp) or NM_001012614.1:c.991C>T - p.(Arg331Trp)]. De novo occurrence this SNV was shown for (almost) all individuals, although in one case maternal sequencing reads were compatible with low-level somatic mosaicism (4/75 reads) not detected by Sanger sequencing. The mother of this individual was phenotypically normal. The variant is absent from gnomAD. Several in silico predictions (SIFT, PolyPhen2, MutationTaster, etc) suggest a deleterious effect.

Given recurrence of this specific variant, and presence of LoF ones in healthy individuals (pLI of 0.98 though in gnomAD) Beck et al. suggested a dominant negative or a gain-of-function effect rather than a loss of function mechanism.

Exclusion of alternative causes: was mainly discussed for the subject reported by Sommerville et al., due to the primary suspicion of a mitochondrial disorder (sequencing and research for mtDNA rearrangements, additional analysis of nuclear genes for mitochondrial disorders).

Expression: CTBP1 encodes C-terminal binding protein 1, with expression among others in brain and cerebellum (https://gtexportal.org/home/gene/CTBP1).

Role and Functional studies:
- The major nuclear isoform of CTBP1 (corresponding to NM_001328.2) and of its paralog CTBP2 function as transcriptional regulators (corepressors). The PLDLS(Pro-Leu-Asp-Leu-Ser)-binding cleft domain where this variant lies, acts as a high-affinity protein-binding interface to recruit DNA-binding repressors and chromatin modifying enzymes (PMID: 17967884).
- In a human glioblastoma cell line interaction of various cofactors with (Flag-tagged) CTBP1 was studied by immunoprecitipation with the Flag antibody and subsequent proteomic (LC-MS) analysis. This demonstrated reduced interaction in the case of R342W (compared to wt) with Zn-finger transcription factors, histone deacetylases, histone methyltransferases, histone H3-K4 demethylase etc. Western blot analyses also revealed reduced interaction of the R342W with several CTBP cofactors.
- RNA-seq analysis in glioblastoma cell line revealed similar overall transcriptional profiles between wt and R342W though multiple RNA species showed significant differences (eg. genes involved in the biological processes of mitotic nuclear division, DNA repair, transcription and regulation of transcription among those that were most upregulated and genes involved in brain development among the most downregulated).
- Patient fibroblasts under conditions of glucose deprivation exhibited strikingly more cell death compared to control fibroblasts. Study of mRNA levels of pro-apoptotic genes by q-RT-PCR revealed that Noxa expression under glucose deprivation vs under normal glucose was 8 to 10-fold enhanced for control fibroblasts, but more than 30-fold enhanced in the case patient fibroblasts. Western blot analyses were also in line with this.
- Mitochondrial dysfunction (probably secondary) with evidence of decreased complex I (and complex IV) activities in skeletal muscle was the case for 2 individuals among multiple patients who had muscle biopsies.

Animal models:
- Beck et al. discuss previously published mouse models where Ctbp1/2 both play overlapping transcriptional roles during development. Homozygous deletion of Ctbp2 is embryonically lethal (>E10.5). Homozygous deletion of Ctbp1 results in viable mice with reduced size and lifespan (Cited: Hildebrand et al. 2002 - PMID: 12101226)
- As commented on by Sommerville et al., Ctbp1 knockout in mouse embryonic fibroblasts resulted in elongated mitochondria, abnormal mitochondrial cristae, diminished ATP and O2 consumption and mitochondrial membrane potential.

----
CTBP1 is associated with Hypotonia, ataxia, developmental delay, and tooth enamel defect syndrome (617915) in OMIM. It is not associated with any phenotype in G2P.
Some diagnostic laboratories (eg. GeneDx participating in the first study and others) include this gene in panels for intellectual disability.
----

As a result, CTBP1 can be added in the current panel probably as green.
Sources: Literature
Intellectual disability - microarray and sequencing v2.938 CTBP1 Konstantinos Varvagiannis gene: CTBP1 was added
gene: CTBP1 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: CTBP1 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
Publications for gene: CTBP1 were set to 27094857; 28955726; 31041561
Phenotypes for gene: CTBP1 were set to Generalized hypotonia; Global developmental delay; Intellectual disability; Ataxia; Abnormality of dental enamel
Penetrance for gene: CTBP1 were set to unknown
Mode of pathogenicity for gene: CTBP1 was set to Loss-of-function variants (as defined in pop up message) DO NOT cause this phenotype - please provide details in the comments
Review for gene: CTBP1 was set to GREEN
gene: CTBP1 was marked as current diagnostic
Added comment: 12 individuals with a recurrent missense variant in CTBP1 have been reported, all summarized in the last article:
- Beck et al. 2016 (PMID: 27094857) : 4 individuals
- Sommerville et al. 2017 (PMID: 28955726) : 1 subject
- Beck et al. 2019 (PMID: 31041561) : 7 further individuals

Features included hypotonia, DD/ID, ataxia and tooth enamel defects. The degree of ID - when present - appeared to be highly variable based at least on the first two reports (3 individuals with severe ID, 1 with borderline-normal intellectual functioning, 1 did not exhibit ID) where this feature was further commented on.

A recurrent missense variant was found in all 12 affected individuals [NM_001328.2:c.1024C>T - p.(Arg342Trp) or NM_001012614.1:c.991C>T - p.(Arg331Trp)]. De novo occurrence this SNV was shown for (almost) all individuals, although in one case maternal sequencing reads were compatible with low-level somatic mosaicism (4/75 reads) not detected by Sanger sequencing. The mother of this individual was phenotypically normal. The variant is absent from gnomAD. Several in silico predictions (SIFT, PolyPhen2, MutationTaster, etc) suggest a deleterious effect.

Given recurrence of this specific variant, and presence of LoF ones in healthy individuals (pLI of 0.98 though in gnomAD) Beck et al. suggested a dominant negative or a gain-of-function effect rather than a loss of function mechanism.

Exclusion of alternative causes: was mainly discussed for the subject reported by Sommerville et al., due to the primary suspicion of a mitochondrial disorder (sequencing and research for mtDNA rearrangements, additional analysis of nuclear genes for mitochondrial disorders).

Expression: CTBP1 encodes C-terminal binding protein 1, with expression among others in brain and cerebellum (https://gtexportal.org/home/gene/CTBP1 ).

Role and Functional studies:
- The major nuclear isoform of CTBP1 (corresponding to NM_001328.2) and of its paralog CTBP2 function as transcriptional regulators (corepressors). The PLDLS(Pro-Leu-Asp-Leu-Ser)-binding cleft domain where this variant lies, acts as a high-affinity protein-binding interface to recruit DNA-binding repressors and chromatin modifying enzymes (PMID: 17967884).
- In a human glioblastoma cell line interaction of various cofactors with (Flag-tagged) CTBP1 was studied by immunoprecitipation with the Flag antibody and subsequent proteomic (LC-MS) analysis. This demonstrated reduced interaction in the case of R342W (compared to wt) with Zn-finger transcription factors, histone deacetylases, histone methyltransferases, histone H3-K4 demethylase etc. Western blot analyses also revealed reduced interaction of the R342W with several CTBP cofactors.
- RNA-seq analysis in glioblastoma cell line revealed similar overall transcriptional profiles between wt and R342W though multiple RNA species showed significant differences (eg. genes involved in the biological processes of mitotic nuclear division, DNA repair, transcription and regulation of transcription among those that were most upregulated and genes involved in brain development among the most downregulated).
- Patient fibroblasts under conditions of glucose deprivation exhibited strikingly more cell death compared to control fibroblasts. Study of mRNA levels of pro-apoptotic genes by q-RT-PCR revealed that Noxa expression under glucose deprivation vs under normal glucose was 8 to 10-fold enhanced for control fibroblasts, but more than 30-fold enhanced in the case patient fibroblasts. Western blot analyses were also in line with this.
- Mitochondrial dysfunction (probably secondary) with evidence of decreased complex I (and complex IV) activities in skeletal muscle was the case for 2 individuals among multiple patients who had muscle biopsies.

Animal models:
- Beck et al. discuss previously published mouse models where Ctbp1/2 both play overlapping transcriptional roles during development. Homozygous deletion of Ctbp2 is embryonically lethal (>E10.5). Homozygous deletion of Ctbp1 results in viable mice with reduced size and lifespan (Cited: Hildebrand et al. 2002 - PMID: 12101226)
- As commented on by Sommerville et al., Ctbp1 knockout in mouse embryonic fibroblasts resulted in elongated mitochondria, abnormal mitochondrial cristae, diminished ATP and O2 consumption and mitochondrial membrane potential.

----
CTBP1 is associated with Hypotonia, ataxia, developmental delay, and tooth enamel defect syndrome (617915) in OMIM. It is not associated with any phenotype in G2P.
Some diagnostic laboratories (eg. GeneDx participating in the first study and others) include this gene in panels for intellectual disability.
----

As a result, CTBP1 can be added in the current panel probably as green.
Sources: Literature
Intellectual disability - microarray and sequencing v2.853 AP2M1 Konstantinos Varvagiannis gene: AP2M1 was added
gene: AP2M1 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: AP2M1 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
Publications for gene: AP2M1 were set to 31104773
Phenotypes for gene: AP2M1 were set to Generalized hypotonia; Global developmental delay; Intellectual disability; Seizures; Ataxia; Autistic behavior
Penetrance for gene: AP2M1 were set to Complete
Review for gene: AP2M1 was set to GREEN
Added comment: Helbig et al. (2019 - PMID: 31104773) report on 4 individuals with developmental and epileptic encephalopathy due to a recurrent de novo AP2M1 missense variant (NM_004068.3:c.508C>T or p.Arg170Trp). Seizure types included atonic, myoclonic-atonic, absence seizures (with or without eyelid myoclonia), tonic-clonic etc. Hypotonia, developmental delay (prior to the onset of seizures at 1y 3m to 4y) and intellectual disability were observed in all four. Other features included ataxia (3/4) or autism spectrum disorder (2/4).

AP2M1 encodes the μ-subunit of the adaptor protein complex 2 (AP-2). AP2M1 is highly expressed in the CNS. The AP-2 complex is involved in clathrin-mediated endocytosis at the plasma mebrane of neurons and non-neuronal cells. This mechanism is important for recycling synaptic vesicle components at mammalian central synapses. Previous evidence suggests regulation of GABA and/or glutamate receptors at the neuronal surface by AP-2 (several references provided by Helbig et al.).

The authors provide evidence for impaired (reduced) clathrin-mediated endocytosis of transferrin in AP-2μ-depleted human HeLa cells upon plasmid-based re-expression of the Arg170Trp variant compaired to re-expression of WT. A similar defect was demonstrated upon comparison of the same process when WT and Arg170Trp re-expression was studied in primary astrocytes from conditional AP-2μ knockout mice.

Expression levels, protein stability, membrane recruitment and localization of the AP-2 complex in clathrin-coated pits were similar for the Arg170Trp variant and WT. As a result, the effect of the specific variant is suggested to be mediated by alteration of the AP-2 complex function (/impaired recognition of cargo membrane proteins) rather than haploinsufficiency.

AP2M1 is highly intolerant to missense / LoF variants with z-score and pLI in ExAC of 5.82 and 0.99 respectively.

As the authors discuss, heterozygous Ap2m1 mutant mice do not have an apparent phenotype. Homozygous mutant mice die before day 3.5 postcoitus, suggesting a critical role in early embryonic development (PMID 16227583 cited)

AP2M1 is currently not associated with any phenotype in OMIM / G2P.

As a result, this gene can be considered for inclusion in the epilepsy and ID panels probably as green (4 individuals with highly similar phenotype of DEE, relevance of phenotype and/or degree of ID, functional studies, etc) rather than amber (single recurrent variant - although this is also the case for other genes rated green).
Sources: Literature
Intellectual disability - microarray and sequencing v2.783 TRRAP Konstantinos Varvagiannis gene: TRRAP was added
gene: TRRAP was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: TRRAP was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
Publications for gene: TRRAP were set to 30827496
Phenotypes for gene: TRRAP were set to Global developmental delay; Intellectual disability; Autism; Microcephaly; Abnormal heart morphology; Abnormality of the urinary system; Seizures
Penetrance for gene: TRRAP were set to unknown
Mode of pathogenicity for gene: TRRAP was set to Loss-of-function variants (as defined in pop up message) DO NOT cause this phenotype - please provide details in the comments
Review for gene: TRRAP was set to GREEN
gene: TRRAP was marked as current diagnostic
Added comment: Cogné et al. (DDD study among the co-authors - PMID: 30827496) report on 24 individuals with pathogenic TRRAP variants.

17 different variants were reported. All variants were missense SNVs and on most occasions had occurred as de novo or apparently de novo events (paternity and maternity not checked). On one occasion, a parent was not unavailable although the respective grand-parents were not found to harbor the variant. Parental germline mosaicism explained the occurence of a variant in 2 sibs.

The authors suggest a strong genotype-phenotype correlation. Individuals whose variant localized within the residues 1031-1159 (NM_001244580.1) presented with a syndromic form of ID with additional malformations. ID was a universal feature in this group (for those subjects evaluated). For variants outside this cluster of residues the phenotype was rather that of ASD without ID or isolated ID with or without ASD, albeit with some exceptions (eg. F860L also associated with a syndromic presentation). ID was a feature in the majority of individuals belonging to the latter group (67% - all with DD) or overall irrespective of the variant localization (85% for those evaluated - all with DD).

Epilepsy was a feature in 4 individuals (4/24) belonging to either group.

All 17 variants were absent from gnomAD with CADD scores supporting a deleterious effect (SIFT/PolyPhen2 (both) predicted a tolerated/benign effect for some eg. Ala1043Thr). A few variants were recurrent, namely Ala1043Thr (5 individuals), Glu1106Lys (2), Gly1883Arg (2), Pro1932Leu (in 2 sibs).

6 further subjects (individuals 25-30, reported separately in the supplement) harbored 6 additional variants with lesser evidence for pathogenicity.

TRRAP is among the 5 most intolerant genes to missense mutations (z-score of 10.1 in ExAC) while it is also intolerant to LoF variants (pLI of 1). No deletions have been reported in DECIPHER and no LoF were identified in the study. Given type of variants and their clustering rather a gain-of-function effect or dominant-negative effect is suggested. As the authors note a LoF effect of non-clustering variants, associated with a milder phenotype cannot excluded. [Mode of pathogenicity to change if thought to be useful].

TRRAP encodes a protein involved in the recruitment to chromatin of histone acetyltransferases. The latter control the process of acetylation of lysine residues in histones and other DNA-binding proteins thus playing a major role in regulation of gene expression. In line with this, RNA sequencing analysis in skin fibroblasts from affected subjects demonstrated dysregulation of expression for several genes implicated in neuronal function and ion transport.

As summarized by the authors: In mice, Trapp knockout is embryonically lethal. Brain-specific knockout leads to premature differentiation of neural progenitors and abnormal brain development. Brain atrophy and microcephaly are observed (microcephaly was a feature in some affected individuals as well, primarily those with variants affecting residues 1031-1159). [PMIDs cited: 11544477, 24792116].

De novo TRRAP variants have been reported also in individuals with neuropsychiatric disorders (PMIDs: 21822266, 23042115, 28392909, 30424743) while TRRAP has been classified among the prenatally-biased genes relevant to its brain expression (PMID:23042115).

A de novo missense variant (c.11270G>A or p.R3757Q) was also previously reported in a study of 264 individuals with epileptic encephalopathy (Epi4K Consortium - PMID: 23934111 - indiv. ND29352).
-----------
TRRAP is not associated with any phenotype in OMIM, nor in G2P.
The gene is included in gene panels for ID offered by some diagnostic laboratories (eg. GeneDx participating in the current study).
-----------
As a result, this gene can be considered for inclusion in the ID panel as green (or amber).
Sources: Literature
Intellectual disability - microarray and sequencing v2.611 CYFIP2 Konstantinos Varvagiannis gene: CYFIP2 was added
gene: CYFIP2 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: CYFIP2 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
Publications for gene: CYFIP2 were set to 29534297; 29667327; 30664714; 25432536; 27524794; 12818175; 20537992
Phenotypes for gene: CYFIP2 were set to Epileptic encephalopathy, early infantile 65, 618008
Penetrance for gene: CYFIP2 were set to unknown
Review for gene: CYFIP2 was set to GREEN
gene: CYFIP2 was marked as current diagnostic
Added comment: Heterozygous pathogenic variants in CYFIP2 cause Epileptic encephalopathy, early infantile, 65 (MIM 618008)
--------------
[Apologies for any eventual mistakes esp.as for the functional evidence]:

Nakashima et al. (2018 - PMID: 29534297) report on 4 unrelated individuals with early-onset epileptic encephalopathy due to de novo missense CYFIP2 variants.

The phenotype consisted of early-onset intractable seizures (diagnosis of West syndrome in 2, Ohtahara syndrome in further individuals) with hypotonia (3/4), DD/ID (4/4) and microcephaly (3/4).

All variants affected Arg87 residue (NM_001037333.2:c.259C>T or p.Arg87Cys in 2 individuals, the 2 other subjects harbored Arg87Leu and Arg87Pro respectively).

CYFIP2 encodes the cytoplasmic FMRP interacting protein 2. CYFIP2 (similar to CYFIP1) is a component of the WAVE regulatory complex (WRC) which has been shown to play a role in actin remodeling, axon elongation, dendritic morphogenesis and synaptic plasticity (several PMIDs cited).

In the inactive state of the WRC complex, CYFIP2 binds to the VCA domain of WAVE. GTP-bound Rac1 (GTPase) leads to release of the VCA domain from CYFIP2 which allows binding of this domain to the Arp2/3 complex (active WRC state) and in turn stimulates actin polymerization and lamellipodia formation.

Using lymphoblastoid cell lines from affected individuals and healthy controls and CYFIP2 expression was evaluated by Western Blot and was found to be similar between the 2 groups.

Additional studies suggested weaker binding of the WAVE1 VCA domain to mutant CYFIP2 compared to WT CYFIP2 (upon transfection of HEK293T cells). This could possibly favor activation of WRC (/the WAVE signalling pathway).

As a result a gain-of-function effect on the WAVE signalling pathway is suggested as a possible mechanism.

Using B16F1 mouse melanoma cells lamellipodia formation (process in which CYFIP2 has previously been implicated) was not shown to be impaired in the case of mutant CYFIP2. However aberrant accumulation of F-actin (and co-localization with mutant CYFIP2) was observed in the present study.

Only large 5q deletions spanning CYFIP2 (and several other genes) have been described to date.

Cyfip2 heterozygous knockout in mice results in abnormal behavior and memory loss. WAVE activity was enhanced (despite reduced WAVE protein production). Homozygous Cyfip2 loss is lethal (PMIDs cited by the authors: 25432536, 27524794). Impaired axonal growth, guidance and branching is noted in Drosophila mutants (CYFIP1/2 ortholog) (PMID cited: 12818175). The authors comment that Cyfip2 (nev) mutant zebrafish show a similar phenotype to mutant flies (PMID cited: 20537992).
--------------
Peng et al. (2018 - PMID: 29667327) in a study of 56 Chinese families with West Syndrome (epileptic/infantile spasms, hypsarrhytmia and ID) identified 1 individual with the Arg87Cys CYFIP2 variant as a de novo occurrence.
--------------
Zweier et al. (2019 - DDD study among the co-authors - PMID: 30664714) report on 12 unrelated subjects with heterozygous pathogenic de novo CYFIP2 variants.

The common phenotype consisted of tone abnormalities (12/12), DD/ID (12/12) and seizures (12/12 though a single individual had experienced a single episode of febrile seizure). Absolute or relative microcephaly and/or additional features were also noted in several individuals.

7 missense variants (4 occurrences of the Arg87Cys variant) as well as splice variant (shown to lead to exon skipping) are reported, as de novo events in these individuals. The splice variant was expected to escape NMD producing a truncating protein.

Although the variants are distantly located in the primary structure, spatial clustering (in the tertiary structure) is suggested by in silico modelling (all in proximity at the CYFIP2-WAVE1 interface).

CYFIP2 appears to be intolerant to both missense and LoF variants (Z-score of 6.15 and pLI of 1 respectively in ExAC).

The authors comment that haploinsufficiency as a mechanism is rather unlikely given the absence of small CNVs or variants predicted to lead to NMD. Again, a gain-of-function effect of these variants on WAVE activation (partial-loss-of function in terms of WRC stabilization and/or conformation of the VCA region in the inactive state) is proposed.
--------------
CYFIP2 is not associated with any phenotype in G2P.
The gene is included in gene panels for intellectual disability offered by some diagnostic laboratories (eg. participants in these studies).
--------------
As a result this gene could be considered for inclusion in this panel as green.
Sources: Literature
Intellectual disability - microarray and sequencing v2.597 PLEKHG2 Konstantinos Varvagiannis gene: PLEKHG2 was added
gene: PLEKHG2 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: PLEKHG2 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
Publications for gene: PLEKHG2 were set to 26539891; 26573021; 24001768
Phenotypes for gene: PLEKHG2 were set to Leukodystrophy and acquired microcephaly with or without dystonia, 616763
Penetrance for gene: PLEKHG2 were set to unknown
Review for gene: PLEKHG2 was set to AMBER
gene: PLEKHG2 was marked as current diagnostic
Added comment: Karaca et al. (2015 - PMID: 26539891) in a study of 128 - mostly consanguineous - families with neurogenetic disorders and brain malformations, identified an individual homozygous for a PLEKHG2 missense variant (NM_022835.2:c.1708G>A or p.Gly570Arg). This individual (BAB4830) had a similarly affected sib. Features included hypotonia, intellectual disability, microcephaly, cerebellar atrophy and nystagmus (description provided in supplement - Table S1). This variant has been submitted in ClinVar as likely pathogenic by the corresponding laboratory (SCV000537940.1).
-------
Edvardson et al. (2016 - PMID: 26573021) reported on 5 individuals from 2 unrelated consanguineous Palestinian families, harboring a missense variant in the homozygous state (NM_022835.2:c.610C>T or p.Arg204Trp - 1/5 was unavailable for testing).
Unaffected relatives here either heterozygous for this variant or homozygous for the reference allele.

Common features included hypotonia (5/5), DD/ID (5/5), postnatal microcephaly (5/5), dystonia (3/5), nystagmus (2/5) or seizures (1/5) [many of these similar to those reported by Karaca et al]. Brain MRI images were consistent with leukodystrophy and prolonged relaxation of dorsal tegmental tracts (similar findings were not commented by Karaca et al).

PLEKHG2 encodes a Rho guanine exchange factor (RhoGEF). RhoGEFs activate RhoGTPases through release of GDP and binding of GTP. Mutations in other RhoGEFs have been associated with neurodevelopmental disorders.

PLEKHG2 activity was shown to be significantly decreased in HEK293A cells transfected with R204W-PLEKHG2 when compared to tranfection with wt. Western blotting suggested that this was not the result of defective expression.

Using lymphoblastoid cell lines from peripheral B lymphocytes from individuals homozygous for R204W and controls, similar levels of expression were shown between the 2 groups.

As the authors note, PLEKHG2 is required for Rac- and Cdc42-stimulated actin polymerization in leukocytes (PMID cited: 24001768).

SDF1a-stimulated actin polymerization was studied in patient cells and was shown to be significantly impaired. In line with this actin polymerization was also impaired upon siRNA-mediated downregulation of PLEKHG2 expression in control cells.
-------
A subsequent submission of the Gly570Arg variant in ClinVar (2017 - SCV000609979.1 - same variant as the one reported by Karaca et al) reports this as a VUS.
-------
PLEKHG2 is associated with Leukodystrophy and acquired microcephaly with or without dystonia (616763) in OMIM.
This gene is not associated with any phenotype in G2P.
PLEKHG2 is included in gene panels for ID offered by some diagnostic laboratories.
-------
As a result, this gene could be considered for inclusion in this panel probably as amber (or green if the current evidence is considered to be sufficient).
Sources: Literature
Intellectual disability - microarray and sequencing v2.597 DHPS Konstantinos Varvagiannis gene: DHPS was added
gene: DHPS was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: DHPS was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: DHPS were set to 21389784; 21850436
Phenotypes for gene: DHPS were set to Abnormal muscle tone; Global developmental delay; Intellectual disability; Seizures; EEG abnormality; Behavioral abnormality; Abnormality of head or neck
Penetrance for gene: DHPS were set to Complete
Review for gene: DHPS was set to GREEN
Added comment: Ganapathi et al. (doi.org/10.1016/j.ajhg.2018.12.017 - PMID : NA) report on 5 individuals from 4 unrelated families with biallelic pathogenic variants in DHPS.

The phenotype consisted of DD/ID (5/5), tone abnormalities (hypotonia/hypertonia/spasticity - 5/5), seizures (5/5 - in one case though unclear staring spells) with EEG abnormalities (5/5). Additionally most individuals displayed behavioral issues, or some common facial features.

Several other disorders had been ruled prior to the diagnosis, in all cases by exome sequencing.

All individuals harbored a specific missense variant (c.518A>G or p.Asn173Ser) in trans with various other variants incl. a splice site mutation (c.1014+1G>A), an in-frame deletion of 2 amino acids (c.912_917delTTACAT or p.Tyr305_Ile306del) or a variant abolishing the translation initiation codon (c.1A>G or p.Met1?) [All variants using NM_001930.3 as a reference].

Deoxyhypusine synthase (encoded by DHPS) is an enzyme participating in the first step of hypusine synthesis, an amino-acid which is specific to eukaryotic initiation factor 5A (eIF5A) and its homolog (eIF5A2).

eIF5A, its hypusinated form and DHPS have all been previously implicated in cellular proliferation/differentiation. eIF5A has also been proposed to be a mRNA translation elongation factor. A role of eIF5A in neuronal growth and survival has been proposed previously (all ref. in present article).

Neither eIF5A, nor DHPS or DOHH (an enzyme required for the second step of hypusination) have been associated to any disorders previously. Mutations in genes encoding other eukaryotic elongator factors (eg. EEF1A2, EEF2) have been associated with neurodevelopmental disorders.

Concerning the DHPS variants reported:

cDNA studies suggested that the c.1014+1G>A variant is translated but results in aberrant splicing and truncation of the protein before its active site.

The in-frame deletion as well as the missense variant were shown to have absent or partial (20%) enzyme activity in vitro respectively compared to wild-type (following expression in E.coli BL21(DE3) cells).

In line with this, reduced hypusination of eIF5A was observed for these 2 variants when compared to wild-type DHPS, upon co-transfection of constructs overexpressing DHPS (wt or mut.) and eIF5A in HEK293T cells.

Absence of homozygous DHPS LoF variants in population databases might suggest that complete deficiency is incompatible with normal embryonic development. Mice heterozygous for Dhps deletion do not demonstrate severe phenotypes, though homozygosity is embryonically lethal (PMIDs: 21389784, 21850436).
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DHPS is not associated with any phenotype in G2P, nor in OMIM.
This gene is not - at least commonly - included in gene panels for ID offered by diagnostic laboratories.
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As a result, DHPS can be considered for inclusion in this panel as green (or amber).
Sources: Literature
Intellectual disability - microarray and sequencing v2.597 SOX4 Konstantinos Varvagiannis gene: SOX4 was added
gene: SOX4 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: SOX4 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
Phenotypes for gene: SOX4 were set to Global developmental delay; Intellectual disability; Growth delay; Clinodactyly of the 5th finger; Abnormality of head or neck
Penetrance for gene: SOX4 were set to unknown
Review for gene: SOX4 was set to GREEN
Added comment: Zawerton et al. (DDD study among the co-authors - doi.org/10.1016/j.ajhg.2018.12.014 - PMID:NA) report on 4 unrelated individuals with de novo SOX4 pathogenic variants. The common phenotype consisted of DD/ID (4/4 - very mild to severe), overlapping facial features as well as digital anomalies (5th finger clinodactyly in 4/4).

SOX4 is a member of the SOX family of transcription factors, all presenting at least 50% identity with SRY (the first identified member of this family) in the HMG (DNA-binding) domain. Most SOX genes have important roles in cell fate / differentiation. Mutations in other genes of this family (eg. SRY, SOX9, SOX10, SOX5) are associated with severe human syndromes.

SOX4 is highly expressed in human brain during gestation - particularly in areas of active neurogenesis - with progressive decrease thereafter until the 3rd - 4th decade of life.

Knockdown of the SOX4 ortholog in Xenopus laevis embryos resulted in smaller head size, microphthalmia, shorter body length and underdevelopment of fore- and mid-brain. (Growth deficiency was a common feature in affected individuals, and microcephaly in 2/4).

Sox4-null mice die in utero due to heart septation defects, while such abnormalities were not reported in heterozygous mice. One affected subject had a VSD. Sox4 inactivation in mice results in impaired skeletal growth (similarly to the patients).

All 4 different missense variants clustered in the HMG domain (aa 58-133) which appears relatively (more) depleted in missense variants (only 12 missense HMG-domain variants in gnomAD). [Overall the Z-score for missense variants is 3.72. pLI = 0.38. %HI in DECIPHER : 24.67%].

The 4 missense variants presented impaired DNA binding and transcription activation in COS-1 transfected cells which appeared to distinguish them from the 12 gnomAD ones. Synthesis, stability and nuclear translocation appeared to be similar to wt.

Other parameters eg. residue conservation in the SOX family, presence of "equivalent" known disease causing mutations in other SOX genes or in silico analyses suggesting structural consequences were supportive of a deleterious effect for the 4 variants (but also for some of the 12 gnomAD ones).

SOX4 and SOX11 have almost identical DNA-binding domains, while the mechanism of mutations reported and the phenotypes appear to be relatively similar, as commented by the authors.
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SOX4 is not associated with any phenotype in G2P, nor in OMIM.
This gene is not - at least commonly - included in gene panels for ID offered by diagnostic laboratories.
--------------
As a result SOX4 can be considered for inclusion in the ID panel as green (or amber).
Sources: Literature
Intellectual disability - microarray and sequencing v2.595 NUS1 Konstantinos Varvagiannis gene: NUS1 was added
gene: NUS1 was added to Intellectual disability. Sources: Literature,Radboud University Medical Center, Nijmegen
Mode of inheritance for gene: NUS1 was set to BOTH monoallelic and biallelic (but BIALLELIC mutations cause a more SEVERE disease form), autosomal or pseudoautosomal
Publications for gene: NUS1 were set to 25066056; 29100083; 24824130; 30348779
Phenotypes for gene: NUS1 were set to #617082 - ?Congenital disorder of glycosylation, type 1aa; #617831 - Mental retardation, autosomal dominant 55, with seizures; Abnormality of extrapyramidal motor function
Penetrance for gene: NUS1 were set to unknown
Review for gene: NUS1 was set to AMBER
gene: NUS1 was marked as current diagnostic
Added comment: Mutations in NUS1 have been implicated in recessive as well as dominant forms of ID (1 and 3 unrelated individuals respectively). The latter individuals presented with a developmental and epileptic encephalopathy with ID. At least 2 of these individuals had tremor and other movement disorders. A recent study proposes that NUS1 variants contribute to Parkinson's disease (1 individual with de novo variant affecting the canonical splice site, 26 additional individuals with missense variants - for which segregation studies where not however performed). ID is not commented on for these individuals.

NUS1 is included in the DD panel of G2P, associated with "Epilepsy and intellectual disability". (Monoallelic LoF variants / Disease confidence : probable). This gene is included in gene panels for ID offered by diagnostic laboratories (incl. Radboudumc). Associated phenotypes in OMIM and others discussed in the literature are summarized below (to my understanding).

As a result, NUS1 can be considered for inclusion in the ID panel probably as amber.
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Recessive - [MIM #617082 - ?Congenital disorder of glycosylation, type 1aa] :

Park et al. (2014 - PMID: 25066056) report on an individual homozygous for a NUS1 missense variant (R290H) and suggest that biallelic variants cause a congenital disorder of glycosylation.

The authors based in studies in yeast, mice and man provide evidence that NUS1 encodes the Nogo-B receptor (NgBR), a subunit of cis-prenyltransferase (cis-PTase), important for its activation. cis-PTase catalyzes one of the reactions for dolichol biosynthesis. Dolichol, in turn, is a carrier of glycans for N-linked glycosylation, O-mannosylation and GPI anchor biosynthesis.

Genetic defects in the dolichol biosynthetic pathway have been linked to other forms of CDG and/or other recessive or dominant neurodevelopmental disorders (eg. SRD5A3- and DHDDS-related disorders).

Similarities are provided at the cellular level between different organisms. Heterozygous knockout mice appear normal. Homozygosity is associated with embryonic lethality before E6.5. Conditional knockout in mouse embryonic fibroblasts led to accumulation of free cholesterol, decreased cis-PTase activity, and mannose incorporation in protein (the first & third rescued by transduction with lentiviral human NgBR).

In patient fibroblasts protein levels appeared similar to controls. Interaction with Nogo-B (and hCIT - the product of DHDDS) was not affected. As in mice, accumulation of free cholesterol was observed in cells, with decreased cis-PTase activity and mannose incorporation. LAMP-1 and ICAM-1 were hypoglycosylated in patient fibroblasts. Altered dolichol profiles in serum and urine were observed in carriers of the NUS1 variant, similarly to what described in individuals with DHDDS LoF variants.
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Dominant - [MIM #617831 - Mental retardation, autosomal dominant 55, with seizures].

Hamdan et al. (2017 - PMID: 29100083) report on 3 unrelated individuals with developmental and epileptic encephalopathy (onset: 10m - 2.5y) and ID. Two individuals harbored de novo LoF variants while a third subject had a deletion of exon 2. Movement disorders were noted in all 3 and included tremor (2 subjects) or ataxia (1 additional subject).

The authors cite a previous study on 6q22.1 deletions the critical region of which encompassed only NUS1 and the promoter of SLC35F1 (Szafranski et al. - PMID: 24824130). Haploinsufficiency is discussed as a possible mechanism (pLI of 0.87). A more severe phenotype due to dramatic reduction of NUS1 activity is proposed for the previously reported patient with CDG.
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Other:
Guo et al. (2018 - PMID: 30348779) suggest that NUS1 pathogenic variants contribute to Parkinson's disease. By performing WES in 39 individuals with early onset Parkinson's disease and their unaffected patients (and sibs) the authors identified 1 individual with de novo insertion affecting a NUS1 canonical splice site. RT-PCR demonstrated increased mRNA levels compared with controls. Skipping of 91 bp of exon 3 was demonstrated.

Study in 2 large sporadic PD-patient (N=1852+3237)/control cohorts (N=1565+2858) suggested association between NUS1 non-synonymous variants and PD (P=1.01e-5, OR:11.3). Other genetic causes of PD were excluded in 26 additional individuals with NUS1 missense variants.

Phenotypes of all 27 individuals are provided in Dataset_S04.

NUS1 has been found to be differentially expressed in PD mouse models.

RNAi-mediated knockdown of Tango14 (the Drosophila NUS1) resulted in impaired climbing activity, reduction in brain dopamine levels and abnormal apoptotic signals in brain.
Sources: Literature, Radboud University Medical Center, Nijmegen
Intellectual disability - microarray and sequencing v2.579 METTL23 Konstantinos Varvagiannis gene: METTL23 was added
gene: METTL23 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: METTL23 was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: METTL23 were set to 24501276; 24626631
Phenotypes for gene: METTL23 were set to Mental retardation, autosomal recessive 44 (MIM 615942)
Penetrance for gene: METTL23 were set to Complete
Review for gene: METTL23 was set to GREEN
gene: METTL23 was marked as current diagnostic
Added comment: Biallelic pathogenic variants in METTL23 cause Mental retardation, autosomal recessive 44 (MIM 615942).

Reiff et al. (PMID: 24501276) report on a consanguineous pedigree of Yemeni origin with 7 individuals presenting intellectual disability. Clinical details are provided for 3 subjects from one branch of the family. Findings included moderate (2/3) or severe (1/3) ID, seizures (2/3) and some common facial features. Seizures were not observed in individuals from other branch of the family. The affected individuals were homozygous for a 4-bp deletion.

Bernkopf et al. (PMID: 24626631) report on a consanguineous family from Pakistan with 2 affected sibs as well as a non-consanguineous family from Austria with 4 affected sibs. The parents in the latter family originated from a small - geographically isolated - village. Individuals from the Pakistani family were homozygous for a nonsense variant, while the sibs from the Austrian family for a frameshift variant. Mild ID was noted in all.

In total 3 different LoF variants have been reported. Extensive functional studies have been performed in both articles.

METTL23 (methyltransferase like 23) is expressed at low-to-moderate levels in the developping human brain. Bernkopf et al. suggest that METTL23 is indeed a methyltransferase.

The gene has 7 transcripts of which one is non-coding. 3 transcripts encode isoform 1 and 3 other encode isoform 2.

The variant reported by Reiff et al. affects the coding region of 3 (of the 6 coding) transcripts (corresponding to isoform 1) and the 5'-UTR of the other 3 transcripts. It is however shown that this first coding exon (specific to isoform 1) is expressed in the developing human brain, though at lower levels than downstream exons common to both isoforms. In addition, only isoform 1 appears to be conserved in most other species.

The variants described by Bernkopf et al. affect all 6 coding trancripts and as a result both isoforms. [However, the individuals reported by Bernkopf et al. were less severely affected compared to those reported by Reiff et al.]

Nonsense-mediated decay appeared unlikely since mRNA levels for both isoforms in lymphoblasts from affected individuals were similar to controls (upon qRT-PCR) [The specific nonsense variant tested would be expected to be subject to NMD given its localization].

METTL23 is not associated with any phenotype in G2P.

This gene is included in gene panels for intellectual disability offered by various diagnostic laboratories.

As a result, METTL23 can be considered for inclusion in the ID panel as green (or amber).
Sources: Literature
Intellectual disability - microarray and sequencing v2.555 COG6 Konstantinos Varvagiannis gene: COG6 was added
gene: COG6 was added to Intellectual disability. Sources: Literature,Expert Review
Mode of inheritance for gene: COG6 was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: COG6 were set to 26260076; 20605848; 23430903; 23606727; 28139241; 28742265; 29445937; 29709711
Phenotypes for gene: COG6 were set to Congenital disorder of glycosylation, type IIl, 614576; Shaheen syndrome, 615328
Penetrance for gene: COG6 were set to Complete
Review for gene: COG6 was set to GREEN
gene: COG6 was marked as current diagnostic
Added comment: DD/ID is an almost universal feature of individuals with biallelic COG6 mutations, whether this is associated with a type II transferrin IEF pattern (as in Congenital disorder of glycosylation, type IIl, 614576) or not (as in Shaheen syndrome, 615328).

More than 15 patients from several different families have been reported to date.

PMID: 26260076 is a collaborative study reporting on new patients as well as on individuals previously described up to 2015 by Lubbehusen et al. (2010 - PMID: 20605848), Huybrechts et al. (2012 - PMID: 23430903) as well as Shaheen et al. (2013 - PMID: 23606727).

As summarized in table 1 of this article, developmental disability was a feature in 8/10, although for a further 2/10 this was probably not relevant (both deceased too early).

The following articles are additional reports although there might be some overlap (applicable for the Saudi patients) : PMIDs: 28139241 (individuals with diagnosis of CDG from Spain), 28742265 (cohort of CDG patients from Saudi Arabia), 29445937 (case report of Saudi subject), 29709711 (Chinese individual with COG6-CDG).

All types of variants have been observed including missense, stopgain and frameshift ones, as well as variants leading to aberrant splicing [eg. positions -2, -9, -24]. The deep intronic variant (position -24) in the individuals reported by Shaheen and others is considered a founder mutation in the Saudi population.

Individuals homozygous for the latter variant have detectable levels of the normal transcript, although 75% of the produced transcript (upon RT-PCR analysis) correspond to retention of 37 intronic nucleotides leading to frameshift and introduction of a premature stop codon. This was also confirmed with Western blot.

Given the detectable levels of the normal transcript, it has been proposed that Shaheen syndrome represents the mildest end of the spectrum COG6-related disorders.

COG6 is included in gene panels for intellectual disability offered by different diagnostic laboratories.

As a result this gene can be considered for inclusion in this panel as green.
Sources: Literature, Expert Review