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28 Jul 2025	Intellectual disability v9.46	RNU5B-1	Arina Puzriakova gene: RNU5B-1 was added gene: RNU5B-1 was added to Intellectual disability. Sources: Literature Q3_25_promote_green tags were added to gene: RNU5B-1. Mode of inheritance for gene: RNU5B-1 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown Publications for gene: RNU5B-1 were set to 40379786; 40442284 Phenotypes for gene: RNU5B-1 were set to Neurodevelopmental disorder, MONDO:0700092 Review for gene: RNU5B-1 was set to GREEN Added comment: At least 19 individuals with de novo and/or recurrent variants in RNU5B-1 and a neurodevelopmental disorder characterised by ID/DD, brain MRI abnormalities, hypotonia, microcephaly or macrocephaly, failure to thrive, and in some cases seizures. PMID: 40379786 (2025) - 15 unrelated probands with heterozygous variants in RNU5B-1. Clinical data was available for 9 individuals who presented with a neurodevelopmental disorder including severe ID/DD (although one patient had normal cognition but attention difficulties) and brain MRI abnormalities. Other features were variable and include hypotonia, epilepsy, ocular abnormalities, acquired microcephaly or macrocephaly and other variable congenital abnormalities. Variants typically arose de novo on the maternal allele and cluster in regions critical for splicing. Functional studies demonstrate variant-specific splicing abnormalities in patient-derived cells which may underline the clinical variability observed in patients. PMID: 40442284 (2025) - 9 unrelated individuals with de novo variants in RNU5B-1 and a neurodevelopmental disorder characterised by GDD/ID, macrocephaly, eye abnormalities, seizures, hypotonia and failure to thrive, among other variable features - based on 6 cases where phenotype information was available. Variants were again found in regions critical for splicing. Both studies investigated participants of the 100KGP and/or NHS GMS (6 in PMID: 40379786 and 5 in PMID: 40442284) so likely refer to the same individuals. Sources: Literature
01 May 2025	Intellectual disability v9.11	SEL1L	Achchuthan Shanmugasundram changed review comment from: PMID:37943610 reported six patients from three unrelated families with a neurodevelopmental disorder involving developmental delay, intellectual disability, facial dysmorphisms, short stature, microcephaly and seizures. Five patients from two families (Saudi Arabian and Moroccan descent) were identified with homozygous SEL1L variants (p.(Gly585Asp) & p.(Met528Arg)), while an unrelated patient of Italian descent was identified with homozygous HRD1 variant. Although there are additional variants reported in Saudi Arabian patient, SEL1L variant was considered as the potential candidate due to its biological relevance as reported in previous studies in mice. The variants were hypomorphic and impaired endoplasmic reticulum (ER)-associated degradation. PMID:37943617 reported the identification of a homozygous SEL1L variant (p.(Cys141Tyr)) in five patients from a consanguineous Slovakian family. These patients presented with not only ERAD-associated neurodevelopmental disorders with onset in infancy (ENDI) syndromes, but infantile-onset agammaglobulinemia with no mature B cells, resulting in frequent infections and early death. All patients exhibited intellectual disability and were unable to speak words and sentences. Although variant in FAR2 gene was also identified in these patients, Sanger sequencing confirmed the segregation of the FAR2 variant with symptoms in patient 2 and FAR2 function is not linked to neurological disorder or agammaglobulinemia, leading to its exclusion from being causal for these patients. This gene has been associated with relevant phenotypes in OMIM (MIMs #621067 & #621068), but not yet in Gene2Phenotype.; to: PMID:37943610 reported six patients from three unrelated families with a neurodevelopmental disorder involving developmental delay, intellectual disability, facial dysmorphisms, short stature, microcephaly and seizures. Five patients from two families (Saudi Arabian and Moroccan descent) were identified with homozygous SEL1L variants (p.(Gly585Asp) & p.(Met528Arg)), while an unrelated patient of Italian descent was identified with homozygous HRD1 variant. The variants were hypomorphic and impaired endoplasmic reticulum (ER)-associated degradation. PMID:37943617 reported the identification of a homozygous SEL1L variant (p.(Cys141Tyr)) in five patients from a consanguineous Slovakian family. These patients presented with not only ERAD-associated neurodevelopmental disorders with onset in infancy (ENDI) syndromes, but infantile-onset agammaglobulinemia with no mature B cells, resulting in frequent infections and early death. All patients exhibited intellectual disability and were unable to speak words and sentences. This gene has been associated with relevant phenotypes in OMIM (MIMs #621067 & #621068), but not yet in Gene2Phenotype.
01 May 2025	Intellectual disability v9.11	SEL1L	Achchuthan Shanmugasundram Phenotypes for gene: SEL1L were changed from Neurodevelopmental disorder to Neurodevelopmental disorder with hypotonia, poor growth, dysmorphic facies, and agammaglobulinemia, OMIM:621068; ?Neurodevelopmental disorder with poor growth, absent speech, progressive ataxia, and dysmorphic facies, OMIM:621067
01 May 2025	Intellectual disability v9.9	SEL1L	Achchuthan Shanmugasundram changed review comment from: PMID:37943610 reported six patients from three unrelated families with a neurodevelopmental disorder involving developmental delay, intellectual disability, facial dysmorphisms, short stature, microcephaly and seizures. Five patients from two families (Saudi Arabian and Moroccan descent) were identified with homozygous SEL1L variants (p.(Gly585Asp) & p.(Met528Arg)), while an unrelated patient of Italian descent was identified with homozygous HRD1 variant. Although there are additional variants reported in Saudi Arabian patient, SEL1L variant was considered as the potential candidate due to its biological relevance as reported in previous studies in mice. The variants were hypomorphic and impaired endoplasmic reticulum (ER)-associated degradation. PMID:37943617 reported the identification of a homozygous SEL1L variant (p.(Cys141Tyr)) in five patients from a consanguineous Slovakian family. These patients presented with not only ERAD-associated neurodevelopmental disorders with onset in infancy (ENDI) syndromes, but infantile-onset agammaglobulinemia with no mature B cells, resulting in frequent infections and early death. All patients exhibited intellectual disability and were unable to speak words and sentences. Although variant in FAR2 gene was also identified in these patients, Sanger sequencing confirmed the segregation of the FAR2 variant with symptoms in patient 2 and FAR2 function is not linked to neurological disorder or agammaglobulinemia (33), leading to its exclusion from being causal for these patients. This gene has been associated with relevant phenotypes in OMIM (MIMs #621067 & #621068), but not yet in Gene2Phenotype.; to: PMID:37943610 reported six patients from three unrelated families with a neurodevelopmental disorder involving developmental delay, intellectual disability, facial dysmorphisms, short stature, microcephaly and seizures. Five patients from two families (Saudi Arabian and Moroccan descent) were identified with homozygous SEL1L variants (p.(Gly585Asp) & p.(Met528Arg)), while an unrelated patient of Italian descent was identified with homozygous HRD1 variant. Although there are additional variants reported in Saudi Arabian patient, SEL1L variant was considered as the potential candidate due to its biological relevance as reported in previous studies in mice. The variants were hypomorphic and impaired endoplasmic reticulum (ER)-associated degradation. PMID:37943617 reported the identification of a homozygous SEL1L variant (p.(Cys141Tyr)) in five patients from a consanguineous Slovakian family. These patients presented with not only ERAD-associated neurodevelopmental disorders with onset in infancy (ENDI) syndromes, but infantile-onset agammaglobulinemia with no mature B cells, resulting in frequent infections and early death. All patients exhibited intellectual disability and were unable to speak words and sentences. Although variant in FAR2 gene was also identified in these patients, Sanger sequencing confirmed the segregation of the FAR2 variant with symptoms in patient 2 and FAR2 function is not linked to neurological disorder or agammaglobulinemia, leading to its exclusion from being causal for these patients. This gene has been associated with relevant phenotypes in OMIM (MIMs #621067 & #621068), but not yet in Gene2Phenotype.
01 May 2025	Intellectual disability v9.9	SEL1L	Achchuthan Shanmugasundram changed review comment from: PMID:37943610 reported six patients from three unrelated families with a neurodevelopmental disorder involving developmental delay, intellectual disability, facial dysmorphisms, short stature, microcephaly and seizures. Five patients from two families (Saudi Arabian and Moroccan descent) were identified with homozygous SEL1L variants (p.(Gly585Asp) & p.(Met528Arg)), while an unrelated patient of Italian descent was identified with homozygous HRD1 variant. Although there are additional variants reported in Saudi Arabian patient, SEL1L variant was considered as the potential candidate due to its biological relevance as reported in previous studies in mice. The variants were hypomorphic and impaired endoplasmic reticulum (ER)-associated degradation. PMID:37943617 reported the identification of a homozygous SEL1L variant (p.(Cys141Tyr)) in five patients from a consanguineous Slovakian family. These patients presented with not only ERAD-associated neurodevelopmental disorders with onset in infancy (ENDI) syndromes, but infantile-onset agammaglobulinemia with no mature B cells, resulting in frequent infections and early death. All patients exhibited intellectual disability and were unable to speak words and sentences. This gene has been associated with relevant phenotypes in OMIM (MIMs #621067 & #621068), but not yet in Gene2Phenotype.; to: PMID:37943610 reported six patients from three unrelated families with a neurodevelopmental disorder involving developmental delay, intellectual disability, facial dysmorphisms, short stature, microcephaly and seizures. Five patients from two families (Saudi Arabian and Moroccan descent) were identified with homozygous SEL1L variants (p.(Gly585Asp) & p.(Met528Arg)), while an unrelated patient of Italian descent was identified with homozygous HRD1 variant. Although there are additional variants reported in Saudi Arabian patient, SEL1L variant was considered as the potential candidate due to its biological relevance as reported in previous studies in mice. The variants were hypomorphic and impaired endoplasmic reticulum (ER)-associated degradation. PMID:37943617 reported the identification of a homozygous SEL1L variant (p.(Cys141Tyr)) in five patients from a consanguineous Slovakian family. These patients presented with not only ERAD-associated neurodevelopmental disorders with onset in infancy (ENDI) syndromes, but infantile-onset agammaglobulinemia with no mature B cells, resulting in frequent infections and early death. All patients exhibited intellectual disability and were unable to speak words and sentences. Although variant in FAR2 gene was also identified in these patients, Sanger sequencing confirmed the segregation of the FAR2 variant with symptoms in patient 2 and FAR2 function is not linked to neurological disorder or agammaglobulinemia (33), leading to its exclusion from being causal for these patients. This gene has been associated with relevant phenotypes in OMIM (MIMs #621067 & #621068), but not yet in Gene2Phenotype.
01 May 2025	Intellectual disability v9.9	SEL1L	Achchuthan Shanmugasundram reviewed gene: SEL1L: Rating: GREEN; Mode of pathogenicity: None; Publications: 37943610, 37943617; Phenotypes: Neurodevelopmental disorder with hypotonia, poor growth, dysmorphic facies, and agammaglobulinemia, OMIM:621068, ?Neurodevelopmental disorder with poor growth, absent speech, progressive ataxia, and dysmorphic facies, OMIM:621067; Mode of inheritance: BIALLELIC, autosomal or pseudoautosomal
26 Feb 2025	Intellectual disability v8.102	ISCA-37447-Loss	Arina Puzriakova Added comment: Comment on mode of inheritance: MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown has been agreed for the R29 Intellectual disability panel. This would capture both imprinting patterns where there is clinical overlap between Kagami-Ogata and Temple syndrome which are both relevant to this panel. These disorders are suitable for R27 Paediatric disorders and R69 Hypotonic infant super panels (included via R29)
26 Feb 2025	Intellectual disability v8.101	ISCA-37447-Loss	Arina Puzriakova Region: ISCA-37447-Loss was added Region: ISCA-37447-Loss was added to Intellectual disability. Sources: ClinGen Mode of inheritance for Region: ISCA-37447-Loss was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown Publications for Region: ISCA-37447-Loss were set to 20585555; 24801763; 27406249; 33579810; 18176563; 28640239 Phenotypes for Region: ISCA-37447-Loss were set to Kagami-Ogata syndrome, OMIM:608149; Temple syndrome, OMIM:616222 Review for Region: ISCA-37447-Loss was set to GREEN Added comment: Multiple unrelated cases curated in ClinGen - sufficient evidence to add this region (https://search.clinicalgenome.org/kb/gene-dosage/region/ISCA-37447) DLK1-MEG3 Intergenic Region includes the paternally expressed DLK1 gene, the 2 differentially methylated regions (DMRs) DLK1/MEG3:IG-DMR and MEG3:TSS-DMR, and the 5' end of the maternally expressed gene MEG3 (4 exons). The phenotype depends on the parental origin: Kagami Ogata syndrome/KOS (maternally derived imprinting) or Temple syndrome/TS (paternally derived imprinting) Kagami-Ogata syndrome is characterized by typical facial features, skeletal abnormalities (including ""coat-hanger ribs"", and bell-shaped thorax), abdominal wall defects, and developmental delay. Temple syndrome is a less specific phenotype including intrauterine and postnatal growth restriction, hypotonia, feeding difficulties in infancy, truncal obesity, and small feet and hands. Sources: ClinGen
31 Oct 2022	Intellectual disability 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
08 May 2022	Intellectual disability 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. ------ 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
24 Jul 2021	Intellectual disability 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
25 May 2021	Intellectual disability v3.1094	UFSP2	Konstantinos Varvagiannis changed review comment from: Ni et al (2021 - PMID: 33473208) describe the phenotype of 8 children (belonging to 4 families - 2 of which consanguineous) homozygous for a UFSP2 missense variant [NM_018359.5:c.344T>A; p.(Val115Glu)]. Members of a broader consanguineous pedigree from Pakistan with 3 affected children with epilepsy and DD and ID underwent exome sequencing. All affected individuals were homozygous for the specific SNV with their parents (2 parent pairs, in both cases first cousins) being heterozygous. An unaffected sib was homozygous for the wt allele. Through genematching platforms 3 additional families with similarly affected individuals and homozygosity for the same variant were recruited. These additional families were from Pakistan (1/3) and Afganistan (2/3). Based on ROH analysis from the broader first pedigree and an additional family the authors concluded on a single shared region of homozygosity on chr 4q. Lack of ES data did not allow verification of whether 2/4 families shared the same haplotype with the other 2. The authors calculated the probability of the genotype-phenotype cosegragation occurring by chance (0.009) and this was lower than the recommended criterion (0.06) for strong evidence of pathogenicity. Shared features included abnormal tone in most (hypotonia 6/8, limb hypertonia 1/8), seizures (8/8 - onset 2d - 7m), severe DD with speech delay/absent speech (8/8), ID (8/8), strabismus (6/8). UFSP2 encodes UFM1-specific protease 2 involved in UFmylation, a post-translational protein modification. As summarized by the authors the cysteine protease encoded by this gene (as is also the case for UFSP1) cleaves UFM1 in the initial step of UFMylation. Apart from producing mature UFM1, the 2 proteases have also the ability to release UFM1 from UFMylated proteins, in the process of de-UFMylation. [several refs. provided] UFMylation is important in brain development with mutations in genes encoding other components of the pathway reported in other NDD disorders (incl. UFM1, UBA5, UFC1). Additional studies were carried to provide evidence for pathogenicity of this variant. Skin biopsies from 3 individuals were carried out to establish fibroblast cultures. Immunoblotting revealed reduced UFSP2 levels relative to controls. mRNA levels measured by qRT-PCR revealed no differences compared to controls altogether suggesting normal mRNA but reduced protein stability. The authors demonstrated increased levels of UFM1-conjugated proteins (incl. DDRGK1, or TRIP4). Ectopic expression of wt UFSP2 normalized the levels of UFMylated proteins in the fibroblasts which was not the case for the V115E variant. Further the variant was difficult to detect by immunoblotting consistent with an effect on protein destabilization. Although disruption of UFMylation induces ER stress, this was not shown to occur in patient fibroblast lines, when assessed for ER stress markers. Evaluation of data from the GTEx project, concerning UFSP2 as well as well as DDRGK1 or TRIP4 - an UFMylation target - revealed relevant expression in multiple regions of the human brain. Overall the authors provide evidence for defective de-UFMylation in patient fibroblasts (presence of increased UFMylation marks). The authors stress out that the effect of the variant in UFMylation in brain is unknown, as UFSP1 or other enzymes might compensate in the presence of hypomorphic UFSP2 mutants. Biallelic UFSP2 variants have previously been reported in 2 skeletal dysplasias [# 142669. BEUKES HIP DYSPLASIA; BHD and # 617974. SPONDYLOEPIMETAPHYSEAL DYSPLASIA, DI ROCCO TYPE; SEMDDR]. These disorders are not characterized by neurological dysfunction or epilepsy. The authors underscore the fact that variants identified in these disorders (Y290H, D526A, H428R) localize within the C-terminal catalytic (peptidase) domain [aa 278 – 461] while the variant here identified lies in the N-terminal substrate binding domain affecting protein stability/abundance. In OMIM, only the 2 aforementioned disorders are currently associated with biallelic UFSP2 mutations. There is no associated phenotype in G2P. SysID includes UFSP2 among the primary ID genes. You may consider inclusion in the current panel with amber/green rating. Sources: Literature; to: Ni et al (2021 - PMID: 33473208) describe the phenotype of 8 children (belonging to 4 families - 2 of which consanguineous) homozygous for a UFSP2 missense variant [NM_018359.5:c.344T>A; p.(Val115Glu)]. Members of a broader consanguineous pedigree from Pakistan with 3 affected children with epilepsy and DD and ID underwent exome sequencing. All affected individuals were homozygous for the specific SNV with their parents (2 parent pairs, in both cases first cousins) being heterozygous. An unaffected sib was homozygous for the wt allele. Through genematching platforms 3 additional families with similarly affected individuals and homozygosity for the same variant were recruited. These additional families were from Pakistan (1/3) and Afganistan (2/3). Based on ROH analysis from the broader first pedigree and an additional family the authors concluded on a single shared region of homozygosity on chr 4q. Lack of ES data did not allow verification of whether 2/4 families shared the same haplotype with the other 2. The authors calculated the probability of the genotype-phenotype cosegragation occurring by chance (0.009) and this was lower than the recommended criterion (0.06) for strong evidence of pathogenicity. Shared features included abnormal tone in most (hypotonia 6/8, limb hypertonia 1/8), seizures (8/8 - onset 2d - 7m), severe DD with speech delay/absent speech (8/8), ID (8/8), strabismus (6/8). UFSP2 encodes UFM1-specific protease 2 involved in UFmylation, a post-translational protein modification. As summarized by the authors the cysteine protease encoded by this gene (as is also the case for UFSP1) cleaves UFM1 in the initial step of UFMylation. Apart from producing mature UFM1, the 2 proteases have also the ability to release UFM1 from UFMylated proteins, in the process of de-UFMylation. [several refs. provided] UFMylation is important in brain development with mutations in genes encoding other components of the pathway reported in other NDD disorders (incl. UFM1, UBA5, UFC1). Additional studies were carried to provide evidence for pathogenicity of this variant. Skin biopsies from 3 individuals were carried out to establish fibroblast cultures. Immunoblotting revealed reduced UFSP2 levels relative to controls. mRNA levels measured by qRT-PCR revealed no differences compared to controls altogether suggesting normal mRNA but reduced protein stability. The authors demonstrated increased levels of UFM1-conjugated proteins (incl. DDRGK1, or TRIP4). Ectopic expression of wt UFSP2 normalized the levels of UFMylated proteins in the fibroblasts which was not the case for the V115E variant. Further the variant was difficult to detect by immunoblotting consistent with an effect on protein destabilization. Although disruption of UFMylation induces ER stress, this was not shown to occur in patient fibroblast lines, when assessed for ER stress markers. Evaluation of data from the GTEx project, concerning UFSP2 as well as well as DDRGK1 or TRIP4 - an UFMylation target - revealed relevant expression in multiple regions of the human brain. Overall the authors provide evidence for defective de-UFMylation in patient fibroblasts (presence of increased UFMylation marks). The authors stress out that the effect of the variant in UFMylation in brain is unknown, as UFSP1 or other enzymes might compensate in the presence of hypomorphic UFSP2 mutants. Monoallelic (correction to previous review) UFSP2 variants have previously been reported in 2 skeletal dysplasias [# 142669. BEUKES HIP DYSPLASIA; BHD and # 617974. SPONDYLOEPIMETAPHYSEAL DYSPLASIA, DI ROCCO TYPE; SEMDDR]. These disorders are not characterized by neurological dysfunction or epilepsy. The authors underscore the fact that variants identified in these disorders (Y290H, D526A, H428R) localize within the C-terminal catalytic (peptidase) domain [aa 278 – 461] while the variant here identified lies in the N-terminal substrate binding domain affecting protein stability/abundance. In OMIM, only the 2 aforementioned disorders are currently associated with biallelic UFSP2 mutations. There is no associated phenotype in G2P. SysID includes UFSP2 among the primary ID genes. You may consider inclusion in the current panel with amber/green rating. Sources: Literature
23 May 2021	Intellectual disability v3.1092	UFSP2	Konstantinos Varvagiannis gene: UFSP2 was added gene: UFSP2 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: UFSP2 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: UFSP2 were set to 33473208 Phenotypes for gene: UFSP2 were set to Abnormal muscle tone; Seizures; Global developmental delay; Delayed speech and language development; Intellectual disability; Strabismus Penetrance for gene: UFSP2 were set to Complete Added comment: Ni et al (2021 - PMID: 33473208) describe the phenotype of 8 children (belonging to 4 families - 2 of which consanguineous) homozygous for a UFSP2 missense variant [NM_018359.5:c.344T>A; p.(Val115Glu)]. Members of a broader consanguineous pedigree from Pakistan with 3 affected children with epilepsy and DD and ID underwent exome sequencing. All affected individuals were homozygous for the specific SNV with their parents (2 parent pairs, in both cases first cousins) being heterozygous. An unaffected sib was homozygous for the wt allele. Through genematching platforms 3 additional families with similarly affected individuals and homozygosity for the same variant were recruited. These additional families were from Pakistan (1/3) and Afganistan (2/3). Based on ROH analysis from the broader first pedigree and an additional family the authors concluded on a single shared region of homozygosity on chr 4q. Lack of ES data did not allow verification of whether 2/4 families shared the same haplotype with the other 2. The authors calculated the probability of the genotype-phenotype cosegragation occurring by chance (0.009) and this was lower than the recommended criterion (0.06) for strong evidence of pathogenicity. Shared features included abnormal tone in most (hypotonia 6/8, limb hypertonia 1/8), seizures (8/8 - onset 2d - 7m), severe DD with speech delay/absent speech (8/8), ID (8/8), strabismus (6/8). UFSP2 encodes UFM1-specific protease 2 involved in UFmylation, a post-translational protein modification. As summarized by the authors the cysteine protease encoded by this gene (as is also the case for UFSP1) cleaves UFM1 in the initial step of UFMylation. Apart from producing mature UFM1, the 2 proteases have also the ability to release UFM1 from UFMylated proteins, in the process of de-UFMylation. [several refs. provided] UFMylation is important in brain development with mutations in genes encoding other components of the pathway reported in other NDD disorders (incl. UFM1, UBA5, UFC1). Additional studies were carried to provide evidence for pathogenicity of this variant. Skin biopsies from 3 individuals were carried out to establish fibroblast cultures. Immunoblotting revealed reduced UFSP2 levels relative to controls. mRNA levels measured by qRT-PCR revealed no differences compared to controls altogether suggesting normal mRNA but reduced protein stability. The authors demonstrated increased levels of UFM1-conjugated proteins (incl. DDRGK1, or TRIP4). Ectopic expression of wt UFSP2 normalized the levels of UFMylated proteins in the fibroblasts which was not the case for the V115E variant. Further the variant was difficult to detect by immunoblotting consistent with an effect on protein destabilization. Although disruption of UFMylation induces ER stress, this was not shown to occur in patient fibroblast lines, when assessed for ER stress markers. Evaluation of data from the GTEx project, concerning UFSP2 as well as well as DDRGK1 or TRIP4 - an UFMylation target - revealed relevant expression in multiple regions of the human brain. Overall the authors provide evidence for defective de-UFMylation in patient fibroblasts (presence of increased UFMylation marks). The authors stress out that the effect of the variant in UFMylation in brain is unknown, as UFSP1 or other enzymes might compensate in the presence of hypomorphic UFSP2 mutants. Biallelic UFSP2 variants have previously been reported in 2 skeletal dysplasias [# 142669. BEUKES HIP DYSPLASIA; BHD and # 617974. SPONDYLOEPIMETAPHYSEAL DYSPLASIA, DI ROCCO TYPE; SEMDDR]. These disorders are not characterized by neurological dysfunction or epilepsy. The authors underscore the fact that variants identified in these disorders (Y290H, D526A, H428R) localize within the C-terminal catalytic (peptidase) domain [aa 278 – 461] while the variant here identified lies in the N-terminal substrate binding domain affecting protein stability/abundance. In OMIM, only the 2 aforementioned disorders are currently associated with biallelic UFSP2 mutations. There is no associated phenotype in G2P. SysID includes UFSP2 among the primary ID genes. You may consider inclusion in the current panel with amber/green rating. Sources: Literature
21 Apr 2021	Intellectual disability v3.1034	NEUROD2	Arina Puzriakova gene: NEUROD2 was added gene: NEUROD2 was added to Intellectual disability. Sources: Literature Q2_21_rating tags were added to gene: NEUROD2. Mode of inheritance for gene: NEUROD2 was set to MONOALLELIC, autosomal or pseudoautosomal, NOT imprinted Publications for gene: NEUROD2 were set to 16504944; 30323019; 33438828 Phenotypes for gene: NEUROD2 were set to Developmental and epileptic encephalopathy 72, OMIM:618374 Review for gene: NEUROD2 was set to GREEN Added comment: NEUROD2 is associated with a relevant phenotype in OMIM (MIM# 618374), but is not yet listed in Gene2Phenotype. - PMID: 30323019 (2019) - Two unrelated children with refractory early-infantile epileptic encephalopathy. Developmental delay (DD) preceded onset of seizures in both cases, with signs of DD becoming evident at 2-4 months and seizures arising at 5 months of age. Patient 1 became seizure-free after introducing a ketogenic diet at 16 months; however, an EEG at 22 months remained abnormal and she continues to have severe GDD with no independent sitting, walking or speaking at the chronological age of 3 years and 2 months. Patient 2 became seizure-free when a vagal nerve stimulator (VNS) was placed at 16 months of age. He displayed significant improvement on EEG and subsequently began regaining neurodevelopmental milestones. WES revealed different de novo variants in the NEUROD2 gene (P1: c.388G>C, p.E130Q; P2: c.401T>C, p.M134T, respectively). Knockdown of the neurod2 in Xenopus tropicalis tadpoles resulted in abnormal swimming behaviour and progressive seizures followed by periods of immobility. Overexpression of wild-type human NEUROD2 in tadpoles induced non-neuronal cells to differentiate into neurons - on the other hand, overexpression of the mutant alleles failed to to cause any (p.E130Q) or a comparable degree (p.M134T) of ectopic neuronal induction as seen with the wild-type protein. - Conference poster (Genomics of Rare Disease 2021) - 'Neuronal Differentiation Factor 2 (NEUROD2) Pathogenic Variant as a Molecular Aetiology of Infantile Spasm ' by Sakpichaisakul et al, QSNICH, Thailand - In a 15 month-old female with infantile spasm, trio exome sequencing revealed a de novo variant in NEUROD2 (c.388G>C, p.E130Q). She was born of non-consanguineous healthy parents with no family history of epilepsy. Poor eye contact and no social smile were noted in the first few months, followed by the first infantile spasm at 5 months of age. This was initially controlled by combined vigabatrin and prednisolone therapy - however relapsing seizures were detected at 15 months. Sequential treatment with vigabatrin following prednisolone resulted in cessation of seizures, and subsequently regaining of neurodevelopmental milestones (sitting without support, grabbing objects without pincer grasp and speaking one single word) ----- Cases without seizures - - PMID: 33438828 (2021) - Adolescent (14 yrs old) with GDD but without seizures who was found to have a novel de novo NEUROD2 missense variant (c.488 T > C, p.L163P). An additional individual (12 yrs) with DD and a different missense NEUROD2 (c.703G>A, p.A235T) was also identified, but lacking parental samples for segregation analysis. Functional analysis in Xenopus laevis revealed that injection of the p.L163P mRNA variant resulted in a defective ability to induce ectopic neurons in tadpoles as compared with wild-type NEUROD2 mRNA, while the p.A235T variant functioned similarly to wild-type. Sources: Literature
20 Nov 2020	Intellectual disability v3.563	AGAP1	Arina Puzriakova Classified gene: AGAP1 as Amber List (moderate evidence)
20 Nov 2020	Intellectual disability v3.563	AGAP1	Arina Puzriakova Gene: agap1 has been classified as Amber List (Moderate Evidence).
20 Nov 2020	Intellectual disability v3.562	AGAP1	Arina Puzriakova reviewed gene: AGAP1: Rating: AMBER; Mode of pathogenicity: None; Publications: 31700678, 30472483, 25666757; Phenotypes: Cerebral palsy, Developmental delay; Mode of inheritance: MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
02 Nov 2020	Intellectual disability v3.500	AGAP1	Zornitza Stark gene: AGAP1 was added gene: AGAP1 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: AGAP1 was set to MONOALLELIC, autosomal or pseudoautosomal, NOT imprinted Publications for gene: AGAP1 were set to 31700678; 25666757; 30472483 Phenotypes for gene: AGAP1 were set to Cerebral palsy Review for gene: AGAP1 was set to AMBER Added comment: Two individuals reported with de novo variants in this gene and a CP phenotype. Rare variants over-represented in a case-control study. Supportive zebrafish model. Another individual with a deletion (+1 other gene) reported with ID and autism. This seems the most appropriate panel? Sources: Literature
08 Oct 2020	Intellectual disability v3.401	GPSM2	Eleanor Williams changed review comment from: Associated with Chudley-McCullough syndrome604213 in OMIM Summary: From 19 reported families, 3 individuals from 2 families showed cognitive delay. PMID: 27180139 - Hemzeh et al 2016 - report two brothers from a Yemeni family who were diagnosed clinically with CMS then tested for GPSM2 mutations using Sanger sequencing. A homozygous mutation in GPSM2 was found in both brothers (c.1055C > A) leading to a truncating protein change; (p.Ser352). The 12 year old brother showed cognitive delay, noted by the inability to tell the time in minutes, or to follow complex commands. The 11 year old brother could speak in sentences but with poor articulation, and could not respond to complex commands. PMID: 23494849 - Almomani et al 2013 - report three patients from two unrelated Dutch families with CMS were investigated in which the same c.1473delG variant observed in 4 of the Menonite families by Doherty et al was observed. All three patients had normal cognitive abilities. PMID: 22578326 - Doherty et al 2012 - report on 5 Menonite, 1 European-American, 1 Dutch and 1 Mexican-American family in which probands had severe/profound hearing loss and ventriculomegaly (total of 12 affected individuals). They also look again at the patients reported with autosomal recessive nonsyndromic deafness (DFNB82) by Walsh et al 2010 (PMID: 20602914, 1 proband ina Pakistani family) and Yariz et al 2012 (PMID: 21348867, 3 probands in a Turkish family) who they found had brain abnormalities consistent with with a diagnosis of Chudley-McCullough syndrome. Oout of the 16 patients reported, only one had developmental issues beyond what is typically seen in individuals with severe hearing loss. - -; to: Associated with Chudley-McCullough syndrome604213 in OMIM Summary: From 19 reported families, 3 individuals from 2 families showed cognitive delay. PMID: 27180139 - Hemzeh et al 2016 - report two brothers from a Yemeni family who were diagnosed clinically with CMS then tested for GPSM2 mutations using Sanger sequencing. A homozygous mutation in GPSM2 was found in both brothers (c.1055C > A) leading to a truncating protein change; (p.Ser352). The 12 year old brother showed cognitive delay, noted by the inability to tell the time in minutes, or to follow complex commands. The 11 year old brother could speak in sentences but with poor articulation, and could not respond to complex commands. The poor articulation was thought to be due to late cochlear implant surgery. PMID: 23494849 - Almomani et al 2013 - report three patients from two unrelated Dutch families with CMS were investigated in which the same c.1473delG variant observed in 4 of the Menonite families by Doherty et al was observed. All three patients had normal cognitive abilities. PMID: 22578326 - Doherty et al 2012 - report on 5 Menonite, 1 European-American, 1 Dutch and 1 Mexican-American family in which probands had severe/profound hearing loss and ventriculomegaly (total of 12 affected individuals). They also look again at the patients reported with autosomal recessive nonsyndromic deafness (DFNB82) by Walsh et al 2010 (PMID: 20602914, 1 proband ina Pakistani family) and Yariz et al 2012 (PMID: 21348867, 3 probands in a Turkish family) who they found had brain abnormalities consistent with with a diagnosis of Chudley-McCullough syndrome. Oout of the 16 patients reported, only one had developmental issues beyond what is typically seen in individuals with severe hearing loss. - -
03 Oct 2020	Intellectual disability v3.369	NEMF	Konstantinos Varvagiannis changed review comment from: Martin et al (2020 - PMID:32934225) report on 8 individuals from 6 families with a juvenile neuromuscular disease due to biallelic NEMF variants. (In one of these 8 cases it could not be ruled out that a de novo and maternally inherited variant were on the same allele, as phase was not determined). A ninth individual with similar presentation was found to harbor a single NEMF missense SNV as de novo event (due to a speculated dominant-negative effect). This individual had a similar presentation. Features incl. hypotonia (4/8 with biallelic variant (B) \| 1/1 monoallelic (M) ), DD/ID (7/8B \| 0/1M) with speech delay as universal feature (8/8B \| 1/1M), axonal neuropathy (3/3B \| 1/1M), ataxia (3/8B \| 0/1M). Other findings included tremor (1/7B \| 1/1M), abnormal brain imaging (2/6B / ?/1M), kyphosis/scoliosis (4/8B \| 0/1M), respiratory distress (1/8B \| 0/1M). NEMF (Rqc2 in yeast) encodes the nuclear export mediator factor, a component of the Ribosome-associated Quality Control (RCQ) complex which is involved in proteolytic targeting of incomplete polypeptides prodduced by ribosome stalling. NEMF facilitates the recruitment of E3 ligase Listerin (LTN1) which ubiquitinates nascent polypeptide chains for subsequent proteasomal degradation. The author provide evidence that mice homozygous for Nemf missense mutations display progressive motor phenotypes, exhibit neurogenic atrophy and progressive axonal degeneration. A further NEMF-null mouse model displayed more severe phenotype (with heterozygous mice being unaffected). Equivalent mutations (of those in the above mouse model) in yeast (Rqc2) were shown to interfere with its ability to modify aberrant translation products with C-terminal tails which assist RQC-mediated protein degradation. Mutation of Ltn1 (belonging to the same protein control pathway) has been also shown to lead to neurodegeneration im mice. Overall NEMF is thought to play a role in neuronal translational homeostasis and the disorder to be mediated by dysfunction of the RQC pathway (normally protecting neurons against degeneration). Sources: Literature; to: Martin et al (2020 - PMID:32934225) report on 8 individuals from 6 families with a juvenile neuromuscular disease due to biallelic NEMF variants. (In one of these 8 cases it could not be ruled out that a de novo and maternally inherited variant were on the same allele, as phase was not determined). A ninth individual with similar presentation was found to harbor a single NEMF missense SNV as de novo event (due to a speculated dominant-negative effect). This individual had a similar presentation. Features incl. hypotonia (4/8 with biallelic variant (B) \| 1/1 monoallelic (M) ), DD/ID (7/8B \| 0/1M) with speech delay as universal feature (8/8B \| 1/1M), axonal neuropathy (3/3B \| 1/1M), ataxia (3/8B \| 0/1M). Other findings included tremor (1/7B \| 1/1M), abnormal brain imaging (2/6B / ?/1M), kyphosis/scoliosis (4/8B \| 0/1M), respiratory distress (1/8B \| 0/1M). NEMF (Rqc2 in yeast) encodes the nuclear export mediator factor, a component of the Ribosome-associated Quality Control (RCQ) complex which is involved in proteolytic targeting of incomplete polypeptides produced by ribosome stalling. NEMF facilitates the recruitment of E3 ligase Listerin (LTN1) which ubiquitinates nascent polypeptide chains for subsequent proteasomal degradation. The author provide evidence that mice homozygous for Nemf missense mutations display progressive motor phenotypes, exhibit neurogenic atrophy and progressive axonal degeneration. A further NEMF-null mouse model displayed more severe phenotype (with heterozygous mice being unaffected). Equivalent mutations (of those in the above mouse model) in yeast (Rqc2) were shown to interfere with its ability to modify aberrant translation products with C-terminal tails which assist RQC-mediated protein degradation. Mutation of Ltn1 (belonging to the same protein control pathway) has been also shown to lead to neurodegeneration in mice. Overall NEMF is thought to play a role in neuronal translational homeostasis and the disorder to be mediated by dysfunction of the RQC pathway (normally protecting neurons against degeneration). Sources: Literature
03 Oct 2020	Intellectual disability v3.369	NEMF	Konstantinos Varvagiannis changed review comment from: Martin et al (2020 - PMID:32934225) report on 8 individuals from 6 families with a juvenile neuromuscular disease due to biallelic NEMF variants. (In one of these 8 cases it could be ruled out that the de novo and maternally inherited variants were on the same allele, as phase was not been determined). A ninth individual with similar presentation was found to harbor a single NEMF missense SNV as de novo event (due to a speculated dominant-negative effect). This individual had a similar presentation. Features incl. hypotonia (4/8 with biallelic variant (B) \| 1/1 monoallelic (M) ), DD/ID (7/8B \| 0/1M) with speech delay as universal feature (8/8B \| 1/1M), axonal neuropathy (3/3B \| 1/1M), ataxia (3/8B \| 0/1M). Other findings included tremor (1/7B \| 1/1M), abnormal brain imaging (2/6B / ?/1M), kyphosis/scoliosis (4/8B \| 0/1M), respiratory distress (1/8B \| 0/1M). NEMF (Rqc2 in yeast) encodes the nuclear export mediator factor, a component of the Ribosome-associated Quality Control (RCQ) complex which is involved in proteolytic targeting of incomplete polypeptides prodduced by ribosome stalling. NEMF facilitates the recruitment of E3 ligase Listerin (LTN1) which ubiquitinates nascent polypeptide chains for subsequent proteasomal degradation. The author provide evidence that mice homozygous for Nemf missense mutations display progressive motor phenotypes, exhibit neurogenic atrophy and progressive axonal degeneration. A further NEMF-null mouse model displayed more severe phenotype (with heterozygous mice being unaffected). Equivalent mutations (of those in the above mouse model) in yeast (Rqc2) were shown to interfere with its ability to modify aberrant translation products with C-terminal tails which assist RQC-mediated protein degradation. Mutation of Ltn1 (belonging to the same protein control pathway) has been also shown to lead to neurodegeneration im mice. Overall NEMF is thought to play a role in neuronal translational homeostasis and the disorder to be mediated by dysfunction of the RQC pathway (normally protecting neurons against degeneration). Sources: Literature; to: Martin et al (2020 - PMID:32934225) report on 8 individuals from 6 families with a juvenile neuromuscular disease due to biallelic NEMF variants. (In one of these 8 cases it could not be ruled out that a de novo and maternally inherited variant were on the same allele, as phase was not determined). A ninth individual with similar presentation was found to harbor a single NEMF missense SNV as de novo event (due to a speculated dominant-negative effect). This individual had a similar presentation. Features incl. hypotonia (4/8 with biallelic variant (B) \| 1/1 monoallelic (M) ), DD/ID (7/8B \| 0/1M) with speech delay as universal feature (8/8B \| 1/1M), axonal neuropathy (3/3B \| 1/1M), ataxia (3/8B \| 0/1M). Other findings included tremor (1/7B \| 1/1M), abnormal brain imaging (2/6B / ?/1M), kyphosis/scoliosis (4/8B \| 0/1M), respiratory distress (1/8B \| 0/1M). NEMF (Rqc2 in yeast) encodes the nuclear export mediator factor, a component of the Ribosome-associated Quality Control (RCQ) complex which is involved in proteolytic targeting of incomplete polypeptides prodduced by ribosome stalling. NEMF facilitates the recruitment of E3 ligase Listerin (LTN1) which ubiquitinates nascent polypeptide chains for subsequent proteasomal degradation. The author provide evidence that mice homozygous for Nemf missense mutations display progressive motor phenotypes, exhibit neurogenic atrophy and progressive axonal degeneration. A further NEMF-null mouse model displayed more severe phenotype (with heterozygous mice being unaffected). Equivalent mutations (of those in the above mouse model) in yeast (Rqc2) were shown to interfere with its ability to modify aberrant translation products with C-terminal tails which assist RQC-mediated protein degradation. Mutation of Ltn1 (belonging to the same protein control pathway) has been also shown to lead to neurodegeneration im mice. Overall NEMF is thought to play a role in neuronal translational homeostasis and the disorder to be mediated by dysfunction of the RQC pathway (normally protecting neurons against degeneration). Sources: Literature
03 Oct 2020	Intellectual disability v3.369	NEMF	Konstantinos Varvagiannis changed review comment from: Martin et al (2020 - PMID:32934225) report on 8 individuals from 6 families with a juvenile neuromuscular disease due to biallelic NEMF variants. A ninth individual with similar presentation was found to harbor a single NEMF missense SNV as de novo event (due to a speculated dominant-negative effect). This individual had a similar presentation. Features incl. hypotonia (4/8 with biallelic variant (B) \| 1/1 monoallelic (M) ), DD/ID (7/8B \| 0/1M) with speech delay as universal feature (8/8B \| 1/1M), axonal neuropathy (3/3B \| 1/1M), ataxia (3/8B \| 0/1M). Other findings included tremor (1/7B \| 1/1M), abnormal brain imaging (2/6B / ?/1M), kyphosis/scoliosis (4/8B \| 0/1M), respiratory distress (1/8B \| 0/1M). NEMF (Rqc2 in yeast) encodes the nuclear export mediator factor, a component of the Ribosome-associated Quality Control (RCQ) complex which is involved in proteolytic targeting of incomplete polypeptides prodduced by ribosome stalling. NEMF facilitates the recruitment of E3 ligase Listerin (LTN1) which ubiquitinates nascent polypeptide chains for subsequent proteasomal degradation. The author provide evidence that mice homozygous for Nemf missense mutations display progressive motor phenotypes, exhibit neurogenic atrophy and progressive axonal degeneration. A further NEMF-null mouse model displayed more severe phenotype (with heterozygous mice being unaffected). Equivalent mutations (of those in the above mouse model) in yeast (Rqc2) were shown to interfere with its ability to modify aberrant translation products with C-terminal tails which assist RQC-mediated protein degradation. Mutation of Ltn1 (belonging to the same protein control pathway) has been also shown to lead to neurodegeneration im mice. Overall NEMF is thought to play a role in neuronal translational homeostasis and the disorder to be mediated by dysfunction of the RQC pathway (normally protecting neurons against degeneration). Sources: Literature; to: Martin et al (2020 - PMID:32934225) report on 8 individuals from 6 families with a juvenile neuromuscular disease due to biallelic NEMF variants. (In one of these 8 cases it could be ruled out that the de novo and maternally inherited variants were on the same allele, as phase was not been determined). A ninth individual with similar presentation was found to harbor a single NEMF missense SNV as de novo event (due to a speculated dominant-negative effect). This individual had a similar presentation. Features incl. hypotonia (4/8 with biallelic variant (B) \| 1/1 monoallelic (M) ), DD/ID (7/8B \| 0/1M) with speech delay as universal feature (8/8B \| 1/1M), axonal neuropathy (3/3B \| 1/1M), ataxia (3/8B \| 0/1M). Other findings included tremor (1/7B \| 1/1M), abnormal brain imaging (2/6B / ?/1M), kyphosis/scoliosis (4/8B \| 0/1M), respiratory distress (1/8B \| 0/1M). NEMF (Rqc2 in yeast) encodes the nuclear export mediator factor, a component of the Ribosome-associated Quality Control (RCQ) complex which is involved in proteolytic targeting of incomplete polypeptides prodduced by ribosome stalling. NEMF facilitates the recruitment of E3 ligase Listerin (LTN1) which ubiquitinates nascent polypeptide chains for subsequent proteasomal degradation. The author provide evidence that mice homozygous for Nemf missense mutations display progressive motor phenotypes, exhibit neurogenic atrophy and progressive axonal degeneration. A further NEMF-null mouse model displayed more severe phenotype (with heterozygous mice being unaffected). Equivalent mutations (of those in the above mouse model) in yeast (Rqc2) were shown to interfere with its ability to modify aberrant translation products with C-terminal tails which assist RQC-mediated protein degradation. Mutation of Ltn1 (belonging to the same protein control pathway) has been also shown to lead to neurodegeneration im mice. Overall NEMF is thought to play a role in neuronal translational homeostasis and the disorder to be mediated by dysfunction of the RQC pathway (normally protecting neurons against degeneration). Sources: Literature
03 Oct 2020	Intellectual disability v3.369	NEMF	Konstantinos Varvagiannis gene: NEMF was added gene: NEMF was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: NEMF was set to BOTH monoallelic and biallelic, autosomal or pseudoautosomal Publications for gene: NEMF were set to 32934225 Phenotypes for gene: NEMF were set to Hypotonia; Global developmental delay; Intellectual disability; Axonal neuropathy; Ataxia; Abnormal brain imaging; Kyphosis; Scoliosis; Tremor; Respiratory distress Penetrance for gene: NEMF were set to Complete Review for gene: NEMF was set to GREEN Added comment: Martin et al (2020 - PMID:32934225) report on 8 individuals from 6 families with a juvenile neuromuscular disease due to biallelic NEMF variants. A ninth individual with similar presentation was found to harbor a single NEMF missense SNV as de novo event (due to a speculated dominant-negative effect). This individual had a similar presentation. Features incl. hypotonia (4/8 with biallelic variant (B) \| 1/1 monoallelic (M) ), DD/ID (7/8B \| 0/1M) with speech delay as universal feature (8/8B \| 1/1M), axonal neuropathy (3/3B \| 1/1M), ataxia (3/8B \| 0/1M). Other findings included tremor (1/7B \| 1/1M), abnormal brain imaging (2/6B / ?/1M), kyphosis/scoliosis (4/8B \| 0/1M), respiratory distress (1/8B \| 0/1M). NEMF (Rqc2 in yeast) encodes the nuclear export mediator factor, a component of the Ribosome-associated Quality Control (RCQ) complex which is involved in proteolytic targeting of incomplete polypeptides prodduced by ribosome stalling. NEMF facilitates the recruitment of E3 ligase Listerin (LTN1) which ubiquitinates nascent polypeptide chains for subsequent proteasomal degradation. The author provide evidence that mice homozygous for Nemf missense mutations display progressive motor phenotypes, exhibit neurogenic atrophy and progressive axonal degeneration. A further NEMF-null mouse model displayed more severe phenotype (with heterozygous mice being unaffected). Equivalent mutations (of those in the above mouse model) in yeast (Rqc2) were shown to interfere with its ability to modify aberrant translation products with C-terminal tails which assist RQC-mediated protein degradation. Mutation of Ltn1 (belonging to the same protein control pathway) has been also shown to lead to neurodegeneration im mice. Overall NEMF is thought to play a role in neuronal translational homeostasis and the disorder to be mediated by dysfunction of the RQC pathway (normally protecting neurons against degeneration). Sources: Literature
06 Aug 2020	Intellectual disability v3.236	SUZ12	Sarah Leigh Phenotypes for gene: SUZ12 were changed from 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 to Imagawa-Matsumoto syndrome 618786
13 Jul 2020	Intellectual disability v3.170	PAX1	Konstantinos Varvagiannis gene: PAX1 was added gene: PAX1 was added to Intellectual disability. Sources: Literature,Radboud University Medical Center, Nijmegen Mode of inheritance for gene: PAX1 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: PAX1 were set to 29681087; 23851939; 28657137 Phenotypes for gene: PAX1 were set to Otofaciocervical syndrome 2, 615560 Penetrance for gene: PAX1 were set to Complete Review for gene: PAX1 was set to AMBER Added comment: Biallelic PAX1 pathogenic variants cause Otofaciocervical syndrome 2 (OMIM 615560). Brief review of the literature suggests 3 relevant publications to date (04-07-2020). 2 individuals with DD and ID have been reported (Patil et al, 2018 - PMID: 29681087 and Pohl et al, 2013 - PMID: 23851939). Other subjects reported were only evaluated as newborns(mostly)/infants [Paganini et al, 2017 - PMID: 28657137, Patil et al, 2018 - PMID: 29681087]. While the first report by Pohl et al identified a homozygous missense variant supported by functional studies [NM_006192.5:c.497G>T - p.(Gly166Val)] subsequent ones identified homozygosity for pLoF mutations [Patil et al: NM_006192.4:c.1173_1174insGCCCG / Paganini et al: NM_006192:c.1104C>A - p.(Cys368*)]. As discussed by Pohl et al: PAX1 encodes a transcription factor with critical role in pattern formation during embryogenesis. Study of the mouse Gly157Val (equivalent to human Gly166Val) Pax1 variant suggested reduced binding affinity (reduced transactivation of a regulatory sequence of the Nkx3-2 promoter) and hypofunctional nature of this variant. Mouse models seem to recapitulate features of the disorder (skeletal, immunodeficiency) while the role of Pax1 in hearing process was thought to be supported by early expression (P6) in mouse cochlea. Overall this gene can be considered for inclusion in the ID panel with amber/green rating. Sources: Literature, Radboud University Medical Center, Nijmegen
23 Apr 2020	Intellectual disability v3.31	FEM1B	Zornitza Stark gene: FEM1B was added gene: FEM1B was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: FEM1B was set to MONOALLELIC, autosomal or pseudoautosomal, NOT imprinted Publications for gene: FEM1B were set to 31036916 Phenotypes for gene: FEM1B were set to Syndromic intellectual disability Review for gene: FEM1B was set to AMBER Added comment: PMID: 31036916 - a single individual with de novo variant reported in a neurodevelopmental disorder cohort. Authors note another de novo case with the exact same variant (p.Arg126Gln) from the DDD study, and a 3rd patient from GeneMatcher with the same de novo missense again. The variant is in a highly constrained region of the protein. Cannot be certain the DDD and GeneMatcher individuals are unrelated, therefore I have treated as two reports for now. Sources: Literature
29 Feb 2020	Intellectual disability v3.3	SUZ12	Zornitza Stark edited their review of gene: SUZ12: Changed phenotypes: Imagawa-Matsumoto syndrome, MIM# 618786, Intellectual disability, Overgrowth
10 Dec 2019	Intellectual disability 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
10 Dec 2019	Intellectual disability 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
10 Dec 2019	Intellectual disability 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
02 Dec 2019	Intellectual disability 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.(Val141Alafs34) 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.(Val141Alafs34) 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
02 Dec 2019	Intellectual disability 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
11 Nov 2019	Intellectual disability 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
06 Oct 2019	Intellectual disability v2.1062	TDP2	Konstantinos Varvagiannis gene: TDP2 was added gene: TDP2 was added to Intellectual disability. Sources: Literature,Radboud University Medical Center, Nijmegen Mode of inheritance for gene: TDP2 was set to MONOALLELIC, autosomal or pseudoautosomal, NOT imprinted Publications for gene: TDP2 were set to 24658003; 30109272; 31410782 Phenotypes for gene: TDP2 were set to Spinocerebellar ataxia, autosomal recessive 23, 616949) Penetrance for gene: TDP2 were set to unknown Review for gene: TDP2 was set to GREEN gene: TDP2 was marked as current diagnostic Added comment: Biallelic pathogenic TGP2 variants cause Spinocerebellar ataxia, autosomal recessive 23 (MIM 616949). At least 6 affected individuals from 4 families have been reported, in all cases homozygous for LoF variants (3 different). ID, epilepsy and ataxia are consistent features of the disorder. TDP2 encodes a phosphodiesterase that is required for efficient repair of double strand breaks (DSBs) produced by abortive topoisomerase II (TOP2) activity. The gene is expressed in fetal and adult human brain. Evidence at the variant level (mRNA, protein levels) and additional studies for impairment of TOP2-induced DSB repair support a role. Animal models (primarily mice) reproduce the DSB repair defect, provide some histopathological evidence, show transcriptional dysregulation of genes (in line with the role of TOP2 in transcription). They have however failed to reproduce relevant neurological phenotypes. Published studies are summarized below. TDP2 is included in gene panels for ID offered by some diagnostic laboratories (incl. Radboudumc and GeneDx). There is no associated phenotype in G2P. TDP2 is listed among the current primary ID genes in SysID. Overall, this gene could be considered for inclusion in the ID and epilepsy panels probably as green (>=3 patients/families/variants, relevant ID and seizures in all, expression in brain, mRNA/protein levels tested, impaired activity) or amber (absence of neurological phenotypes in mouse model). ------------ [1] - PMID: 24658003 (Gómez-Herreros et al. 2014): Reports 3 individuals from a consanguineous Irish family. Features included seizures (onset by 2m, 6m and 12y), ID (3/3) and ataxia (3/3). A splicing variant (NM_016614.3:c.425+1G>A) was found in a 9.08-Mb region of homozygosity shared by all. A further ZNF193 missense variant localizing in the same region was thought unlikely to contribute to the phenotype (evidence also provided in subsequent study). The effect of the specific variant was proven by abnormal mRNA size, lower mRNA levels due to NMD (corrected upon cyclohexamide treatment), loss of TDP2 protein upon WB, loss of protein activity in lymphoblastoid cells from affected individuals, decreased repair of DSBs and increased cell death upon addition of etoposide (which promotes TOP2 abortive activity). The authors report very briefly on a further patient (from Egypt), with ID, 'reports of fits' and ataxia. This individual, with also affected sibs, was homozygous LoF (c.413_414delinsAA / p.Ser138*). Again, the authors were not able to detect TDP2 activity in blood from this subject. As also commented: - TDP2 has relevant expression in human (particularly adult) brain. - Mouse model : Tdp2 is expressed in relevant tissues, absence of Tdp2 activity was observed in neural tissue of mice homoyzgous for an ex1-3 del, with impairment of DSB repair. The authors were unable to detect a neurological phenotype with behavioral analyses, preliminary assesment of seizure propensity. Mice did not show developmental defects. Histopathology however, revealed ~25% reduction in the density of interneurons in cerebellum (a 'hallmark of DSB repair' and associated with seizures and ataxia). Transcription of several genes was shown to be disregulated. - Knockdown in zebrafish appears to affect left-right axis detremination (cited PMID: 18039968). [2] - PMID: 30109272 (Zagnoli-Vieira et al. 2018): A 6 y.o. male with seizures (onset by 5m), hypotonia, DD and ID, microcephaly and some additional clinical features and testing (ETC studies on muscle biopsy, +lactate, +(lactate/pyruvate) ratio) which could be suggestive of mitochondrial disorder. This individual from the US was homozygous for the c.425+1G>A variant but lacked the ZNF193 one (despite a shared haplotype with the Irish patients). Again absence of the protein was shown upon WB in patient fibroblasts, also supported by its activity. Complementation studies restored the DSB repair defect. The defect was specific to TOP2-induced DSBs as suggested by hypersensitivity to etoposide but not to ionizing radiation. CRISPR/Cas9 generated mutant human A549 cells demonstrated abnormal DSB repair. Fibroblasts / edited A549 cells failed to show mitochondrial defects (which were noted in muscle). [3] - PMID: 31410782 (Ciaccio et al. 2019): A girl born to consanguineous Italian parents, presented with moderate/severe ID, seizures (onset at 12y) and - among others - gait ataxia, tremor and dysmetria. MRI at the age of 12, demonstrated cerebellar atrophy (although previous exams were N). WES revealed a homozygous nonsense variant (c.400C>T / p.Arg134Ter) for which each parent was found to be carrier. Previous investigations included aCGH, NGS testing for epilepsy and metabolic testing. Sources: Literature, Radboud University Medical Center, Nijmegen
04 Oct 2019	Intellectual disability v2.1062	MED25	Helen Brittain edited their review of gene: MED25: Added comment: There are now different variants (potentially each founders) in three populations, and several families, that have been reported in association with ID. Therefore the evidence for a green rating in terms of a gene:disease association now seems sufficient. To determine the extent of the phenotype, in terms of associated features, further cases would be beneficial. Therefore I would currently recommend a green rating for the ID panel.; Changed rating: GREEN; Changed phenotypes: Basel-Vanagait-Smirin-Yosef syndrome 616449; Changed mode of inheritance: BIALLELIC, autosomal or pseudoautosomal
22 Sep 2019	Intellectual disability 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
20 Sep 2019	Intellectual disability v2.1035	PAX7	Louise Daugherty changed review comment from: Comment on list classification: removed from panel, this gene is not relevant for this panel; to: Comment on list classification: downgraded to Red again, this gene is not pertinent. I have left the gene on the panel as the gene is on the ID panel from the Victorian Clinical Genetics Services
01 Sep 2019	Intellectual disability v2.1021	MED25	Konstantinos Varvagiannis reviewed gene: MED25: Rating: AMBER; Mode of pathogenicity: None; Publications: 30800049, DOI:10.1159/000501114, 25527630, 25792360; Phenotypes: Basel-Vanagait-Smirin-Yosef syndrome (MIM 616449); Mode of inheritance: None; Current diagnostic: yes
31 Aug 2019	Intellectual disability v2.1021	PAK1	Konstantinos Varvagiannis changed review comment from: Horn et al. (2019 - doi.org/10.1093/brain/awz264) report on 4 additional individuals with de novo missense PAK1 pathogenic variants. ID, seizures and macrocephaly and walking difficulties were observed in all (4/4). ASD was reported in 3 (but was not among the features in the study by Harms et al). PAK1 encodes p21 protein-activated kinase 1. The protein has 2 major domains, an autoregulatory and a protein kinase domain. Homodimerization masks the active site of the kinase, leading to autoinhibition (inactive form). PAK1 is activated by dissociation into monomers upon binding of the GTP-bound forms of the Rho GTPases CDC42 and RAC1. TRIO and HACE1 are indirect regulators of PAK1, via RAC1. PAK1 in turn, activates LIMK1 which plays a critical role in dendritic spine morphogenesis and brain function. CDC42, RAC1, TRIO, HACE1 are all associated with neurodevelopmental disorders. Activation of RAC-PAK1-LIMK1 pathway has been demonstrated for Fragile-X syndrome (sharing ID, macrocephaly and seizures). Mutations in PAK3, another member of the group I PAK subfamily with similar activation mechanism to PAK1 (by CDC42 / RAC1), cause Mental retardation, X-linked 30/47 (MIM 300558) (Green rating in the current panel). 4 additional missense variants - further to the 2 previously described ones - were found, all as de novo events: c.397T>C (p.Ser133Pro) / c.361C>T p.(Pro121Ser) / c.328T>A p.(Ser110Thr) / c.1409T>G (p.Leu470Arg) [For the specific variants, cDNA and aa change are the same for both NM_001128620.1 and NM_002576]. The 3 former variants located within the autoinhibitory domain while the latter in the protein kinase domain though - again - close to the autoinhibitory one (in tertiary structure). A gain of function effect by reduced ability of autoinhibition (leading to autophosphorylation) and activation of PAK1 is the suggested mechanism. Gain of function is also supported by the fact that Pak1-/- do not exhibit neurodevelopmental anomalies / abnormal head size. PAK1 is not particularly intolerant to LoF variants as suggested by its pLI of 0.67. The corresponding phenotype in OMIM is Intellectual developmental disorder with macrocephaly, seizures, and speech delay (MIM 618158). The gene is part of the DD panel of G2P, associated with "Neurodevelopmental Disorder" (monoallelic, activating / disease confidence : probable). PAK1 is included in the gene panel for ID offered by Radboudumc.; to: Based on a further recent study, PAK1 can probably be upgraded to green in both ID and epilepsy gene panels: Horn et al. (2019 - doi.org/10.1093/brain/awz264) report on 4 additional individuals with de novo missense PAK1 pathogenic variants. ID, seizures and macrocephaly and walking difficulties were observed in all (4/4). ASD was reported in 3 (but was not among the features in the study by Harms et al). PAK1 encodes p21 protein-activated kinase 1. The protein has 2 major domains, an autoregulatory and a protein kinase domain. Homodimerization masks the active site of the kinase, leading to autoinhibition (inactive form). PAK1 is activated by dissociation into monomers upon binding of the GTP-bound forms of the Rho GTPases CDC42 and RAC1. TRIO and HACE1 are indirect regulators of PAK1, via RAC1. PAK1 in turn, activates LIMK1 which plays a critical role in dendritic spine morphogenesis and brain function. CDC42, RAC1, TRIO, HACE1 are all associated with neurodevelopmental disorders. Activation of RAC-PAK1-LIMK1 pathway has been demonstrated for Fragile-X syndrome (sharing ID, macrocephaly and seizures). Mutations in PAK3, another member of the group I PAK subfamily with similar activation mechanism to PAK1 (by CDC42 / RAC1), cause Mental retardation, X-linked 30/47 (MIM 300558) (Green rating in the current panel). 4 additional missense variants - further to the 2 previously described ones - were found, all as de novo events: c.397T>C (p.Ser133Pro) / c.361C>T p.(Pro121Ser) / c.328T>A p.(Ser110Thr) / c.1409T>G (p.Leu470Arg) [For the specific variants, cDNA and aa change are the same for both NM_001128620.1 and NM_002576]. The 3 former variants located within the autoinhibitory domain while the latter in the protein kinase domain though - again - close to the autoinhibitory one (in tertiary structure). A gain of function effect by reduced ability of autoinhibition (leading to autophosphorylation) and activation of PAK1 is the suggested mechanism. Gain of function is also supported by the fact that Pak1-/- do not exhibit neurodevelopmental anomalies / abnormal head size. PAK1 is not particularly intolerant to LoF variants as suggested by its pLI of 0.67. The corresponding phenotype in OMIM is Intellectual developmental disorder with macrocephaly, seizures, and speech delay (MIM 618158). The gene is part of the DD panel of G2P, associated with "Neurodevelopmental Disorder" (monoallelic, activating / disease confidence : probable). PAK1 is included in the gene panel for ID offered by Radboudumc. (Previous review below)
31 Aug 2019	Intellectual disability v2.1021	PAK1	Konstantinos Varvagiannis edited their review of gene: PAK1: Added comment: Horn et al. (2019 - doi.org/10.1093/brain/awz264) report on 4 additional individuals with de novo missense PAK1 pathogenic variants. ID, seizures and macrocephaly and walking difficulties were observed in all (4/4). ASD was reported in 3 (but was not among the features in the study by Harms et al). PAK1 encodes p21 protein-activated kinase 1. The protein has 2 major domains, an autoregulatory and a protein kinase domain. Homodimerization masks the active site of the kinase, leading to autoinhibition (inactive form). PAK1 is activated by dissociation into monomers upon binding of the GTP-bound forms of the Rho GTPases CDC42 and RAC1. TRIO and HACE1 are indirect regulators of PAK1, via RAC1. PAK1 in turn, activates LIMK1 which plays a critical role in dendritic spine morphogenesis and brain function. CDC42, RAC1, TRIO, HACE1 are all associated with neurodevelopmental disorders. Activation of RAC-PAK1-LIMK1 pathway has been demonstrated for Fragile-X syndrome (sharing ID, macrocephaly and seizures). Mutations in PAK3, another member of the group I PAK subfamily with similar activation mechanism to PAK1 (by CDC42 / RAC1), cause Mental retardation, X-linked 30/47 (MIM 300558) (Green rating in the current panel). 4 additional missense variants - further to the 2 previously described ones - were found, all as de novo events: c.397T>C (p.Ser133Pro) / c.361C>T p.(Pro121Ser) / c.328T>A p.(Ser110Thr) / c.1409T>G (p.Leu470Arg) [For the specific variants, cDNA and aa change are the same for both NM_001128620.1 and NM_002576]. The 3 former variants located within the autoinhibitory domain while the latter in the protein kinase domain though - again - close to the autoinhibitory one (in tertiary structure). A gain of function effect by reduced ability of autoinhibition (leading to autophosphorylation) and activation of PAK1 is the suggested mechanism. Gain of function is also supported by the fact that Pak1-/- do not exhibit neurodevelopmental anomalies / abnormal head size. PAK1 is not particularly intolerant to LoF variants as suggested by its pLI of 0.67. The corresponding phenotype in OMIM is Intellectual developmental disorder with macrocephaly, seizures, and speech delay (MIM 618158). The gene is part of the DD panel of G2P, associated with "Neurodevelopmental Disorder" (monoallelic, activating / disease confidence : probable). PAK1 is included in the gene panel for ID offered by Radboudumc.; Changed rating: GREEN; Changed publications: 30290153, doi.org/10.1093/brain/awz264; Set current diagnostic: yes
07 Aug 2019	Intellectual disability v2.996	WDR37	Konstantinos Varvagiannis gene: WDR37 was added gene: WDR37 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: WDR37 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown Publications for gene: WDR37 were set to 31327510; 31327508 Phenotypes for gene: WDR37 were set to Global developmental delay; Intellectual disability; Seizures; Abnormality of the eye; Abnormality of nervous system morphology; Hearing abnormality; Abnormality of the cardiovascular system; Abnormality of the skeletal system; Abnormality of the genitourinary system Penetrance for gene: WDR37 were set to unknown Review for gene: WDR37 was set to GREEN Added comment: Two concurrent publications by Reis et al. and Kanca et al. (2019 - PMIDs: 31327510, 31327508) report on the phenotype of individuals with de novo WDR37 mutations. The study by Reis et al. provides clinical details on 4 affected individuals, while 5 further are described by Kanca et al. 4 different de novo variants were reported in these individuals who appear to be unrelated in (and between) the 2 studies [NM_014023.3]: - c.356C>T (p.Ser119Phe) [Reis indiv. 1 - 3y, Kanca proband 3 - 5m2w] - c.389C>T (p.Thr130Ile) [Reis indiv. 2 - 22m , Kanca proband 5 - 6w] - c.374C>T (p.Thr125Ile) [Reis indiv. 3 - 8y , Kanca proband 1 - 7y] - c.386C>G (p.Ser129Cys) [Reis indiv. 4 - unkn age, Kanca probands 2 and 4, 6.5y and 19y] Common features included DD/ID (severity relevant for the current panel), seizures (9/9), ocular anomalies (corneal opacity/Peters anomaly, coloboma, microphthalmia etc.) and variable brain, hearing, cardiovascular, skeletal and genitourinary anomalies. Some facial and/or other dysmorphic features (incl. excess nuchal skin / webbed neck) were also frequent among affected individuals. Feeding difficulties and growth deficiency were also among the features observed. The function of WDR37 is not known. Variants demonstrated comparable protein levels and cellular localization compared to wt. Reis et al. provide evidence using CRISPR-Cas9 mediated genome editing in zebrafish, to introduce the Ser129Cys variant observed in affected individuals as well as novel missense and frameshift variants. Poor growth (similar to the human phenotype) and larval lethality were noted for missense variants. Head size was proportionately small. Ocular (coloboma/corneal) or craniofacial anomalies were not observed. Zebrafish heterozygous for LoF variants survived to adulthood. Based on these a dominant-negative mechanism was postulated for missense alleles. RNA-seq analysis in zebrafish showed upregulation of cholesterol biosynthesis pathways (among the most dysregulated ones). Previous data in mice, suggest a broad expression pattern for Wdr37 with enrichment in ocular and brain tissues, significant associations in homozygous mutant mice for decreased body weight, grip strength, skeletal anomalies and possible increase (p =< 0.05) in ocular (lens/corneal) and other anomalies [BioGPS and International Mouse Phenotyping Consortium cited]. CG12333 loss (the Drosophila WDR37 ortholog) causes increased bang sensitivity in flies (analogous to the human epilepsy phenotype), defects in copulation and grip strength, phenotypes that were rescued by human reference but not variant cDNAs. As discussed by Kanca et al. based on data from Drosophila and mice, limited phenotypic similarity of CNVs spanning WDR37 and adjacent genes with the reported individuals and the presence of LoF variants in control populations haploinsufficiency appears unlikely. Gain-of-function is also unlikely, as expression of human variants in flies did not exacerbate the observed phenotypes. A dominant-negative effect is again proposed. WDR37 is not associated with any phenotype in OMIM/G2P. As a result WDR37 can be considered for inclusion in the ID and epilepsy panels with green (relevant phenotype, sufficient cases, animal models) or amber rating. Sources: Literature
25 Jan 2019	Intellectual disability 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
15 Jan 2019	Intellectual disability v2.595	STAG2	Konstantinos Varvagiannis gene: STAG2 was added gene: STAG2 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: STAG2 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: STAG2 were set to 29263825; 28296084; 30158690; 30447054; 19449417; 26443594; 25677961; 23637084; 25450604 Phenotypes for gene: STAG2 were set to Global developmental delay; Intellectual disability; Abnormality of head or neck; Microcephaly; Growth delay; Hearing impairment; Abnormal heart morphology Penetrance for gene: STAG2 were set to unknown Review for gene: STAG2 was set to GREEN gene: STAG2 was marked as current diagnostic Added comment: Several affected individuals (from at least 8 unrelated) families have been reported in the literature. The phenotype consists - among others - of DD/ID. STAG2 is located on long arm of chromosome X (Xq25). Based on these reports, both males and females can be affected. Soardi et al. (2017 - PMID: 29263825) report an affected male belonging to a large pedigree with 4 other similarly affected males. The disorder in this pedigree followed a typical X-linked inheritance pattern. All affected males were hemizygous for a missense variant (NM_001042749.1:c.980G>A or p.Ser327Asn). Common phenotype consisted of moderate ID, short stature, sensory hearing loss and some similar facial features. Unaffected males did not harbor the variant. Heterozygous females were not affected. Co-segragation of the variant with the affected status under an X-linked model, appeared unlikely to have occurred by chance (probability of 1/131,072 - logarithm of odds score of 5.12). Mullegama et al. (2017 - PMID: 28296084) report on an 8-year-old girl harboring a de novo nonsense variant in STAG2 (NM_001042749.1:c.205C>T or p.Arg69Ter). This individual presented - among others with - DD, microcephaly, growth delay, digit anomalies, particular facial features, and anomalies of other systems (eg. hearing loss, cardiac defect, etc). The authors summarize the features of 2 subjects from the DDD study as available in DECIPHER, without additional details. [Variants of these individuals NM_001042749.1:c.1913_1922del10 or p.(A638Vfs*10) / NM_001042749.1:c.1811G>A p.(R604Q)]. Yuan et al. (2018 - PMID: 30158690) report on 4 females with de novo LoF STAG2 variants as well as 1 male subject with a de novo missense one. DD (5/5) and ID (4/4) were features in all individuals for whom this information was available. One additional female had an intragenic STAG2 deletion, although this subject was not reported to have DD or ID (table S6 : microcephaly, seizures and facial phenotype). It is not known whether the deletion was inherited or had occurred as a de novo event. All variants from this study have been submitted in ClinVar (phenotype : STAG2-related disorder). Mullegama et al. (2018 - PMID: 30447054) report on a 4-year-old male with DD, microcephaly, growth delay, digit anomalies due to a de novo missense STAG2 variant (c.3027A>T or p.Lys1009Asn). As discussed by the authors at the time of the study 33 males with Xq25 duplications and ID had been reported (PMIDs cited: 19449417, 26443594, 25677961, 23637084, 25450604). Discussed in these articles : STAG2 (or STAG1) is one of the 4 core proteins of the cohesin complex, the other 3 being SMC1A, SMC3 and RAD21. Mutations in genes encoding these proteins or their interactors (eg. NIBPL, HDAC8, ESCO2, etc) have been associated cohesinopathies, a group of multisystem developmental disorders (eg. Cornelia de Lange syndrome, Roberts/SC phocomelia, etc). It has been commented that the phenotype of STAG2-related disorder presents overlap with other cohesinopathies (eg. DD, microcephaly and growth retardation, craniofacial features, anomalies of the digits, etc). Decreased proportion of nuclei with premature sister chromatid separation compared to controls was found on one occasion (suggestive of tighter sister chromatid cohesion) [Mullegama-A]. Sister chromatid cohesion was not affected in another report [Soardi et al.]. Western blot demonstrated significant reduction of STAG2 levels for a nonsense variant [Mullegama-A]. Levels were not perturbed for a missense variant [Soardi et al.]. Upon immunofluorescence STAG2 presented normal (nuclear) localization for a missense variant for which this was studied [Soardi et al.]. Perturbation of the cell cycle profile (higher percentage of G2/M cells) was demonstrated for patient fibroblasts compared to controls on one occasion where this was studied. [Soardi et al.]. Microarray expression studies in patient fibroblasts demonstrated altered transcription (upregulation) of genes implicated in cell division, mitosis and DNA replication upon comparison with normal fibroblasts [Soardi et al.]. The effect of a missense variant on STAG2 binding to other cohesin subunits (SCC1, SMC1 and SMC3) and regulators was studied. Binding was found to be reduced in vivo (in HeLa cells) for SCC1 (its direct binding partner) as well as SMC1, SMC3 (possibly indirectly). Reduced STAG2 binding to cohesin regulators was also shown in vivo. However, in vitro studies were not suggestive of impaired binding of STAG2 to SCC1 (a finding difficult to explain) [Soardi et al.]. STAG2 appears to be intolerant to LoF variants (pLI of 1 in ExAC). Z-Score for missense variants is 5.11. Mullegama et al. (B) comment that Xq25 duplications in males may be associated with milder phenotypes compared to intragenic variants. They further hypothesize that males are able to survive less damaging variants while females are able to survive more deleterious (eg. LoF) ones though with more severe phenotypes (similarity to the MECP2 model is discussed). ---------- STAG2 is not associated with any phenotype in OMIM. In G2P this gene is associated with STAG2-related developmental delay with microcephaly and congenital anomalies (disease confidence : confirmed / Both DD and ID among the phenotypes assigned to this entry). ---------- STAG2 is included in gene panels for ID offered by some diagnostic laboratories. ---------- As a result, this gene can be considered for inclusion in the ID panel as green (or amber). Sources: Literature
10 Dec 2018	Intellectual disability v2.579	PUS3	Konstantinos Varvagiannis gene: PUS3 was added gene: PUS3 was added to Intellectual disability. Sources: Literature,Radboud University Medical Center, Nijmegen Mode of inheritance for gene: PUS3 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: PUS3 were set to 27055666; 30308082 Phenotypes for gene: PUS3 were set to Global developmental delay; Intellectual disability; Microcephaly Penetrance for gene: PUS3 were set to Complete Review for gene: PUS3 was set to AMBER gene: PUS3 was marked as current diagnostic Added comment: PUS3 (Pseudouridylate synthase 3) is proposed as a gene related to ID in a recent publication on PUS7. Biallelic mutations in this gene are associated in OMIM with ?Mental retardation, autosomal recessive 55 (MIM 617051). PMID: 27055666 reports on 3 sisters from a consanguineous Saudi Arabian family with failure to thrive, DD/ID, microcephaly and some common (coarse) facial features. These individuals were homozygous for a stopgain mutation in the last exon of the gene. Pseudouridylation appeared to be defective (as has also been the case with other genes related to ID, eg. PUS7). PMID: 30308082 describes 1 individual born to consanguineous Palestinian parents, homozygous for a further LoF variant. Despite the localisation of this variant (again in the last exon of the gene) qPCR analyses were suggestive of degradation of the abnormal transcript possibly by NMD. The phenotype consisted of DD/ID and microcephaly. In a further publication (http://dx.doi.org/10.7124/bc.0008D6) Gulkovskyi et al. report on 2 siblings with ID, born to non-consanguineous Ukranian parents. Pathogenicity of the variant is disputed. [NM_031307.4:c.212A>G or p.(Tyr71Cys) is found in an apparent homozygous state in the sibs but was only found in their father. De novo occurence in the maternal allele is proposed although the possibility of microdeletion missed by aCGH or other plausible mechanisms are not considered. This variant has maximum pathogenicity scores in silico (not discussed) and has an allele frequency of 0.00006717 in gnomAD. The authors did not perform studies of pseudouridylation but examined for the presence of hypoproteinemia, observed in some disorders affecting this process). PUS3 is not associated with any phenotype in G2P but is associated with disease in OMIM. The gene is included in gene panels for ID offered by various diagnostic laboratories (including Radboudumc). PUS1 is included in the current panel as green and PUS7 has been suggested for inclusion. As a result, these gene can be considered for inclusion as amber (2 families) or green (given the supportive functional studies and/or the proposed role for the gene). Sources: Literature, Radboud University Medical Center, Nijmegen
07 Dec 2018	Intellectual disability v2.576	PPP1R21	Konstantinos Varvagiannis gene: PPP1R21 was added gene: PPP1R21 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: PPP1R21 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: PPP1R21 were set to 29808498; 28940097 Phenotypes for gene: PPP1R21 were set to Generalized hypotonia; Feeding difficulties; Profound global developmental delay; Abnormality of the face; Abnormality of vision; Abnormal heart morphology; Abnormality of the respiratory system; Hepatosplenomegaly Penetrance for gene: PPP1R21 were set to Complete Review for gene: PPP1R21 was set to GREEN Added comment: Biallelic pathogenic variants in PPP1R21 have been reported so far in 9 individuals from 7 unrelated families. All (7 different) variants reported to date are truncating. PMID: 29808498 is the first detailed clinical description on the related phenotype. 3 individuals from 3 families are reported. One of these individuals was previously included in a larger patient cohort (in PMID: 28940097). In a subsequent further publication, Rehman et al. (https://doi.org/10.1002/humu.23694) describe 6 additional patients from 4 unrelated consanguineous families. Again, these individuals were homozygous for truncating mutations. The authors summarize the findings in their patients as well as the previously reported ones. Common features included feeding difficulties, hypotonia with severe global DD and mildly coarsened facial features (all were observed in 9/9), visual anomalies (8/9), respiratory problems (7/9), cardiac anomalies (4/9) and hepato-/splenomegaly (3/7). Brain MRI anomalies were observed in the majority. DD was severe in all and ID (which is not explicitly mentioned) was evident from the clinical description of several individuals (eg. in PMID: 29808498). In total 7 loss-of-function variants have been reported. The authors in the first article, underscore the possibility of less severe phenotypes associated to biallelic missense variants (although none has been reported so far). Functional studies have shown great reduction (but not complete absence) of PPP1R21 mRNA levels in patient fibroblasts compared to controls. A role of PPP1R21 in the endosomal-lysosomal function is demonstrated in line with the presence of myelin figures in patient fibroblasts as well as some phenotypic similarities to neurometabolic/lysosomal storage disorders. Most variants reported in the most recent publication except one (NM_001135629.2:c.1607dupT) seem to affect all 3 PPP1R21 isoforms (which also seems to be the case for previously published variants). c.1607dupT appears to be the single truncating variant affecting 2 (of 3) isoforms. This variant was however shown to have severely reduced expression in fibroblasts upon qPCR, absent protein staining, and increase in myelin figures. The protein is expressed in embryonic mouse cortex. Overall, this gene can be considered for inclusion in this panel as green (or amber). Sources: Literature
10 Nov 2018	Intellectual disability v2.530	RHOBTB2	Konstantinos Varvagiannis gene: RHOBTB2 was added gene: RHOBTB2 was added to Intellectual disability. Sources: Expert Review,Literature Mode of inheritance for gene: RHOBTB2 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown Publications for gene: RHOBTB2 were set to 29276004; 29768694; 26740508 Phenotypes for gene: RHOBTB2 were set to Global developmental delay; Intellectual disability; Seizures; Postnatal microcephaly Penetrance for gene: RHOBTB2 were set to unknown Mode of pathogenicity for gene: RHOBTB2 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: RHOBTB2 was set to GREEN gene: RHOBTB2 was marked as current diagnostic Added comment: PMID: 29276004 reports on 10 unrelated patients with de novo pathogenic missense variants in RHOBTB2. The phenotype in all individuals was compatible with a developmental and epileptic encephalopathy including early-onset seizures, severe intellectual disability, postnatal onset microcephaly (6/10) and movement disorders (8/10). The variants occured as de novo events and clustered within the BTB-domain encoding region (within and between the 2 BTB domains). Three missense variants were recurrent and/or concerned the same residue (p.Arg483His in 4 individuals, Arg511Gln was reported in 2, and Arg511Trp was was found in another 2 individuals). Functional studies in HEK293 cells suggested increased abundance of the mutant protein secondary to decreased proteasome degradation. Using Drosophila as a model organism, altered expression of RhoBTB (the single ortholog of the 3 vertebrate paralogs, closest to RHOBTB2) was shown to result in neurological phenotypes. RhoBTB overexpression in particular was associated with increased bang sensitivity (which was not the case or milder in the case if knockdown of this gene) and impaired performance upon the negative geotaxis assay, similar to the human neurological phenotypes. Altered RhoBTB dosage was shown to be associated with impaired dendrite development. As commented by the authors, these results as well as the clustering of missense variants and the pLI score of 0.51 reported for RHOBTB2 are consistent with altered protein function (due to the missense variants) rather than haploinsufficiency or loss-of-function. PMID: 29768694 describes 3 additional individuals, all found to harbor de novo missense variants again within the BTB-domain encoding region. Two of the variants had been reported in the previous study (Arg511Gln and Arg483His) while the third was a private one (Arg507Cys). The phenotype was similar to the previous descriptions. Functional studies were suggestive of impaired degradation of the mutant protein by the CUL3 complex although this was not secondary to decreased binding with CUL3. PMID: 26740508 (cited by the two aforementioned publications) reports briefly on an individual with de novo missense variant in the same region of RHOBTB2 (Asn510Asp) and Rett-like phenotype. RHOBTB2 is included in gene panels for intellectual disability offered by different diagnostic laboratories. As a result the gene can be considered for inclusion in the intellectual disability and epilepsy panels as green. Sources: Expert Review, Literature
29 Sep 2018	Intellectual disability v2.468	NAGA	Louise Daugherty Source Victorian Clinical Genetics Services was added to NAGA.
27 Sep 2018	Intellectual disability v2.458	KDM1A	Louise Daugherty edited their review of gene: KDM1A: Added comment: Recommendation that this gene should be Green. Three patients https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4902791/, there is functional characterisation of the three described mutations https://www.ncbi.nlm.nih.gov/pubmed/27094131?dopt=Abstract and the patients seem to share a similar phenotype, which recapitulates features of other deleterious mutations in better-characterised lysine demethylase and chromatin remodelling genes. There is also a recurrent de novo variant p.Tyr831Cys which has been reported in two separate "autism spectrum" patients in large cohort studies. The gene is also extensively constrained against both missense and LOF variation in humans http://exac.broadinstitute.org/gene/ENSG00000004487. I think what's been reported so far is probably robust enough to use the gene clinically.Pers comm. Ian Berry (NHS Leeds Genetics Laboratory); Changed rating: GREEN
12 Sep 2018	Intellectual disability v2.408	GBA	Louise Daugherty commented on gene: GBA: In view of an external green review, this gene was reviewed again internally and with out internal clinical team. it was decided his gene should remain Amber. It was noted that the commonest type is type 1, where ID is not a clear feature, and that there are sufficient other features to suggest a metabolic / storage dysfunction in all types of Gaucher disease to prompt diagnosis via the undiagnosed metabolic route. So we have decided to leave this gene as amber on ID panel in view of the likely low yield and the complication of the later incidental neurological risks.
02 Aug 2017	Intellectual disability	NAGA	BRIDGE consortium edited their review of NAGA
02 Aug 2017	Intellectual disability	AGA	BRIDGE consortium edited their review of AGA
27 Jul 2017	Intellectual disability	NAGA	BRIDGE consortium edited their review of NAGA
27 Jul 2017	Intellectual disability	AGA	BRIDGE consortium edited their review of AGA
19 Jul 2017	Intellectual disability	NAGA	BRIDGE consortium reviewed NAGA
19 Jul 2017	Intellectual disability	AGA	BRIDGE consortium reviewed AGA