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Intellectual disability v8.174 PLAT Achchuthan Shanmugasundram changed review comment from: PMID:39574431 reported the identification of three different homozygous truncating variants in PLAT gene in four individuals from three unrelated families. All of them presented with tetraventricular hydrocephalus. Dandy–Walker malformation was reported in three unrelated cases, of which mild intellectual disability was reported in one (family 2). Global developmental delay was reported in another (family 3), but this could partially be explained by a co-occurring Cohen syndrome diagnosis. Mild ID was also reported in the proband from family 1 that did not show Dandy–Walker malformation.

This gene has not yet been associated with any relevant phenotypes in OMIM or in Gene2Phenotype.
Sources: Literature; to: PMID:39574431 reported the identification of three different homozygous truncating variants in PLAT gene in four cases from three unrelated families. All of them presented with tetraventricular hydrocephalus. Dandy–Walker malformation was reported in three unrelated cases (two individuals and one foetus), of which mild intellectual disability was reported in one (family 2). Global developmental delay was reported in another (family 3), but this could partially be explained by a co-occurring Cohen syndrome diagnosis. Mild ID was also reported in the proband from family 1 that did not show Dandy–Walker malformation.

This gene has not yet been associated with any relevant phenotypes in OMIM or in Gene2Phenotype.
Sources: Literature
Intellectual disability v8.174 PLAT Achchuthan Shanmugasundram changed review comment from: PMID:39574431 reported the identification of three different homozygous truncating variants in PLAT gene in four individuals from three unrelated families. All of them presented with tetraventricular hydrocephalus. Dandy–Walker malformation was reported in three unrelated cases, of which mild intellectual disability was reported in two. Global developmental delay was reported in the third one.

This gene has not yet been associated with any relevant phenotypes in OMIM or in Gene2Phenotype.
Sources: Literature; to: PMID:39574431 reported the identification of three different homozygous truncating variants in PLAT gene in four individuals from three unrelated families. All of them presented with tetraventricular hydrocephalus. Dandy–Walker malformation was reported in three unrelated cases, of which mild intellectual disability was reported in one (family 2). Global developmental delay was reported in another (family 3), but this could partially be explained by a co-occurring Cohen syndrome diagnosis. Mild ID was also reported in the proband from family 1 that did not show Dandy–Walker malformation.

This gene has not yet been associated with any relevant phenotypes in OMIM or in Gene2Phenotype.
Sources: Literature
Intellectual disability v8.174 PLAT Achchuthan Shanmugasundram Classified gene: PLAT as Amber List (moderate evidence)
Intellectual disability v8.174 PLAT Achchuthan Shanmugasundram Added comment: Comment on list classification: This gene should be rated amber with current evidence as there is one case reported with GDD and two cases reported with only mild ID.
Intellectual disability v8.174 PLAT Achchuthan Shanmugasundram Gene: plat has been classified as Amber List (Moderate Evidence).
Intellectual disability v8.172 PLAT Achchuthan Shanmugasundram gene: PLAT was added
gene: PLAT was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: PLAT was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: PLAT were set to 39574431
Phenotypes for gene: PLAT were set to neurodevelopmental disorder, MONDO:0700092; intellectual disability, MONDO:0001071
Review for gene: PLAT was set to AMBER
Added comment: PMID:39574431 reported the identification of three different homozygous truncating variants in PLAT gene in four individuals from three unrelated families. All of them presented with tetraventricular hydrocephalus. Dandy–Walker malformation was reported in three unrelated cases, of which mild intellectual disability was reported in two. Global developmental delay was reported in the third one.

This gene has not yet been associated with any relevant phenotypes in OMIM or in Gene2Phenotype.
Sources: Literature
Intellectual disability v3.1580 DROSHA Konstantinos Varvagiannis gene: DROSHA was added
gene: DROSHA was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: DROSHA was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
Publications for gene: DROSHA were set to 35405010
Phenotypes for gene: DROSHA were set to Global developmental delay; Intellectual disability; Seizures; Cerebral white matter atrophy; Abnormality of the corpus callosum; Abnormality of movement; Stereotypic behavior; Abnormality of head or neck; Short foot
Penetrance for gene: DROSHA were set to unknown
Mode of pathogenicity for gene: DROSHA 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: DROSHA was set to AMBER
Added comment: Profound DD, ID and seizures have been reported in 2 unrelated subjects with de novo missense variants. The gene has a role in miRNA biogenesis. Both variants described have been shown to have effect on DROSHA's function in Drosophila / C. elegans (partial loss-of-function vs possibility of antimorphic effect discussed || in gnomAD several individuals with LoF alleles / Z=3.98 – pLI : 0.09).

There is currently no DROSHA-related phenotype in OMIM, G2P, SysNDD. In PanelApp Australia the gene has amber rating in genetic epilepsy and microcephaly panels (not currently included in the ID one).

Consider inclusion in the current panel with amber rating. Also consider inclusion in other possibly relevant panels (given postnatal microcephaly, abn. corpus callosum, progressive white matter atrophy, etc) [ NOT added ]

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Barish, Senturk, Schoch et al (2022 - PMID: 35405010) describe the phenotype of 2 unrelated individuals with de novo missense DROSHA variants.

Features included generalized hypotonia, postnatal microcephaly (-2,6 and -6 SD), feeding difficulties, profound DD and ID, seizures, abnormal movements (choreoathetosis / stereotypic movements), variable respiratory symptoms (in one case episodes of hyperventilation/apnea), cardiovascular or skeletal findings. Brain MRI demonstrated white matter atrophy and thin corpus callosum in both. Brachycephaly with broad face as well as short feet were also among the shared features.

Both were investigated by trio ES/GS which were otherwise non diagnostic and without other candidate variants. The 1st individual harbored a de novo htz missense DROSHA variant (c.3656A>G/p.Asp1219Gly) while the 2nd subject had another missense variant (c.4024C>T/p.Arg1342Trp) [NM_013235.4] confirmed by Sanger seq.

DROSHA (on 5p13.3) encodes a ribonuclease, subunit of the microprocessor complex, involved in miRNA biogenesis. Specifically, miRNAs are transcribed as part of pri-miRNAs (primary-miRNAs) which are cleaved to pre-miRNAs (precursor-miRNAs) in the nucleus by DROSHA (and its partner DGCR8 or Pasha) and then exported to the cytoplasm for further processing. Cleavage of pre-miRNAs by DICER1 generates mature miRNAs subsequently loaded to the RISC (RNA-induced silencing) complex which uses miRNA as template for recognition and cleavage of complementary mRNA with RNAse.

As the authors discuss, miRNA defects have a well-established role in development of model organisms e.g. (several Refs. provided):
- in C. elegans miRNA mutants causing lethality, developmental arrest and heterochronicity
- in Drosophila playing a role in the development of ovary, eye, nervous system etc.
- in mice mRNAs play a role in BMP and TGF-beta signaling while neuronal loss of miRNA processing leads to neurodegeneration/anatomical defects.

Feingold syndrome 2 is the single Mendelian disease associated to date with miRNAs, through deletion of a cluster containing 6 MIR genes.

miRNA dysregulation is also observed in Rett syndrome - and DROSHA implicated in the pathogenesis of the syndrome - as MECP2 and FOXG1 are cofactors of the microprocessor complex regulating processing of miRNA. One of the individuals here reported had a clinical diagnosis of Rett spectrum while both had overlapping features with Rett s.

Studies of DROSHA-dependent miRNAs in fibroblasts from one individual revealed significantly altered expression of mature miRNA (e.g. increased miR98, a miRNA with reduced expression in studies of somatic DROSHA variants) although this was not likely due to processing errors (given only a modest decrease of precursor miRNAs).

Previous studies have demonstrated that drosha (the Drosophila ortholog) null mutants die during post-embryonic development with 100% lethality before adulthood (3rd instar larval stage/beginning of pupariation). Mosaic flies with mutant eyes are small-eyed, while viable hypomorphic alleles display synaptic transmission defects (several Refs provided).

Here, homozygous flies for null alleles died at the end of 3rd instar larval stage/beginning of pupariation, while loss of drosha resulted in lack of imaginal disc tissue (which surrounds the larval brain) and severely reduced brain size, the latter similar to the microcephaly phenotype. [To the best of my understanding] introduction of a mutated genomic rescue construct (carrying similar substitutions as those observed in human subjects) in eye-specific drosha null (W1123X) flies was partially able to rescue eye/head size for wt or Asp1219Gly (human:Asp1084Gly) suggesting that the latter is a partial LoF allele. Arg1210Trp (corresponding to human Arg1342Trp) was able to rescue the eye phenotype and was not damaging to the function in the specific assay. Drosha expression levels were similar for genomic rescue flies either for wt or for the Asp-Gly variant suggesting that the effect was not due to expression levels (but rather function). Expression of mature miRNAs known to be regulated by Drosha were not affected when comparing wildtype larvae with genomic construct for wt or Asp1084Gly.

Upon expression of human cDNA using GAL4/UAS system in drosha mutant (null) eye clones, the reference partially rescued the eye size defect, Asp-Gly behaved as partial loss-of-function allele (~50% function compared to ref), while the Arg-Trp variant was shown to behave as a weaker loss-of-function allele.

The authors generated eye-specific drosha mutant clones to study the aging adult eye using ERG recordings. While null mutants display almost no response to light (7- and 20-day old flies), wt genomic rescue was shown to rescue ERG responses, Asp-Gly variant had significant defects (at both 7 and 20 days) and the Arg-Trp had defects approaching statistical significance only at the age of 20 days. Overall these data suggested that Arg-Trp had less severe effect compared to Asp-Gly (as above) while both variants led to progressive neuronal dysfunction.

Using CRISPR/Cas9 the authors generated C.elegans knock-ins for a variant analogous to the Asp1219Gly human one. Homozygous animals were inviable at larval stages, displayed a heterochronic phenotype (heterochronicity : development of cells or tissues at an abnormal time relative to other unaffected events in an organism / miRNAs are known to be involved in the heterochronic gene pathway) while this variant was deleterious to the Drosha's ability to process miRNAs.
Sources: Literature
Intellectual disability v3.1520 PAN2 Konstantinos Varvagiannis gene: PAN2 was added
gene: PAN2 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: PAN2 was set to BIALLELIC, autosomal or pseudoautosomal
Publications for gene: PAN2 were set to 29620724; https://doi.org/10.1038/s41431-022-01077-y
Phenotypes for gene: PAN2 were set to Global developmental delay; Intellectual disability; Sensorineural hearing impairment; Abnormality of the genitourinary system; Abnormality of the cardiovascular system; Abnormality of blood and blood-forming tissues; EEG abnormality; Seizures; Anorectal anomaly; Abnormality of the skeletal system; Abnormality of the eye; Abnormality of head or neck
Penetrance for gene: PAN2 were set to Complete
Review for gene: PAN2 was set to AMBER
Added comment: 1.
Maddirevula et al (2018 - PMID: 29620724) first reported on the phenotype associated with biallelic pathogenic variants in PAN2.

This concerned a male (15DG2222) born to consanguineous parents and exhibiting MCA, dysmorphic features and global DD (age of 34 m). Features incl. imperforate anus, metopic craniosynostosis, scoliosis, CHD (PFO, PDA, VSD), renal anomalies (duplicated collecting system) and abnormalities of the eye (posterior embryotoxon, maculopathy).

As the other 411 individuals from the cohort, the child had 1st-tier testing genetic testing using a dysmorphology/skeletal dysplasia panel of 296 genes.

Subsequent autozygome analysis (Axiom genotyping platform) was used to identify ROH (authors state "segregating within the family", in pedigree the proband was the single affected person and single child).

WES revealed a PAN2 indel. [NM_001166279.1:c.3162delC / p.(Ser1055Profs*4)].

There were no additional studies.

Role of PAN2 and animal models discussed as below.
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2.
Reuter et al. (2022 - https://doi.org/10.1038/s41431-022-01077-y) describe the phenotype of 5 additional individuals - from 3 unrelated families (2 consanguineous) - harboring biallelic PAN2 variants. The authors review the phenotype of the previously described case.

Features included DD (6/6), ID (4/5 with relevant age in the mild-moderate range, 1/5 had borderline IF), sensorineural hearing loss (5/6) and incompletely penetrant congenital anomalies of the heart (4/6 - TOF, septal defects, Ao root dilat), urinary malformations (4/6 - hypoplasia/agenesis, anovesical fistula), ophthalmological anomalies (2/6 - Rieger, posterior embryotoxon, etc). EEG anomalies or seizures were noted in 4/6. Craniofacial feat. in >=2/6 included cleft palate/bifid uvula, ptosis, hypertelorism, abn. of the nose, low-set ears, short neck. There was no comprehensive evaluation for skeletal dysplasia despite short stature/skeletal anomalies in multiple individuals. Hematological anomalies were reported in 2, possibly explained by another concurrent diagnosis (of GSD) in one individual.

WGS was performed for 1 individual, and WES for 4 members of the 2nd family and the proband in the 3rd. ROH identified in all 3 families (1 non-consanguineous but from the same region of Italy) are mentioned in the suppl. Sanger sequencing for parents and affected/unaffected sibs was mentioned for the 2 families with solo WGS/WES. One individual had a dual - previously established - diagnosis (of SLC37A4-related GSD) not related to his NDD. There were no other candidate variants except for VUS or variants in 'genes of uncertain significance'.

The majority of mammalian mature mRNAs have polyA tails, added during RNA processing. PAN2 encodes a subunit of the Pan2-Pan3 deadenylation complex which shortens mRNA 3' polyA tails, regulating mRNA stability/translation efficiency.

Specifically Pan2 is the catalytic subunit, while the interaction with Pan3 mediates efficient mRNA binding. Deadenylation in cytoplasm is mostly carried out by the Pan2-Pan3 or Ccr4-Not compexes. While perturbations of mRNA metabolism/decay are established causes of NDD and ID. In particular, monoallelic variants in genes of Ccr4-Not complex (inc. CNOT1/2/3) already causative of NDDs.

All affected individuals were homozygous for pLoF PAN2 variants, namely (NM_001166279.2): c.2335G>T / p.(Glu779*) [Fam1], c.3408dupT / p.(Glu1137*) [Fam2], c.574-2A>G / p.? [Fam3].

Variants were absent from gnomAD (where PAN2 has a pLI:0.94, o/e:0.19).

There were no variant studies performed. The splicing variant is predicted in silico to abolish the splice-acceptor site, with in-frame skippling of ex5 which codes a repeat within the WD40 domain. Previous studies in yeast have shown that this domain is important for sensing the length of the polyA tail, with absence of this domain resulting in impaired deadenylation of 90A tails (similarly to complete Pan2 del) [cited PMID: 31104843].

Overall PAN2 loss-of-function is thought to be the underlying disease mechanism.

Partial functional redundancy of Pan2/Pan3 (initiation of deadenylation) and Ccr4-Not complexes (further shortening of polyA) is speculated to mitigate consequences of PAN2 LoF in humans.

In yeast Pan2Δ, Ccr4Δ and Pan2Δ/Ccr4Δ have been studied with more severe phenotypes in double mutants where ability to shorten mRNA polyA tails was abolished [cited PMID:11239395]. In yeast extracts lacking Pan2p and Pan3p, transcripts were polyadenylated to >90-200 adenosines [cited PMID: 9774670]

Mouse mutants (MGI:1918984) had increased heart weight, increased eosinophil cell number while homozygosity for a stopgain allele (by ENU mutagenesis) was shown to result in embyonic lethality.

Finally, given the presence of thrombocytopenia and anemia in 3 individuals (2 families) as well as the link between mRNA deadenylation and telomere disease, telomere length analyses from WGS data were performed (TelSeq/Expansion Hunter dn), but there was no evidence for telomeric shortening.
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Currently, there is no PAN2-related phenotype in OMIM/G2P/SysID/PanelApp Australia.
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Consider inclusion in the ID panel with amber rating [>3 individuals/families/variants, though variant studies not performed (NMD/splicing) and authors of 2nd study recognize possibility of additional/concurrent diagnoses in individuals from consanguineous families, possibility of missed dn variants due to singleton WGS/WES in 2 fam. Also the presumed deadenylation defect not studied to date].

Please consider adding this gene to other panels - eg. for sens. hearing loss (5/6 - 3 fam), urinary tract anomalies (4/6 - 4 fam), congenital (4/6 - 3fam), anorectal malformations (2/6 - 2 families, incl. fistula or imperforate anus), clefting (2/6 - 1 fam), hematological disorders, etc.

For the time being, not added in epilepsy panel as some individuals had only EEG anomalies, few had also clinical seizures not necessarily requiring treatment.
Sources: Literature
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
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
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.(Val141Alafs*34) and c.1865_1866del]. Following this result, increase of biotin supplementation and introduction of pantothenic acid, GI symptoms (incl. chronic diarrhea) resolved and the child displayed improved appetite and growth, yet a stable motor delay. The authors cite previous studies of conditional ko mice, displaying intestinal mucosal abnormalities and growth defects (similar to the child's problems), prevented by biotin and pantothenic acid supplementation.

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

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

4 affected individuals from 3 families have been reported.

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

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

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

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

4 affected individuals from 3 families have been reported.

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

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

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

[Please consider inclusion in other relevant panels eg. metabolic disorders]
Sources: Literature
Intellectual disability v2.1098 SCAMP5 Konstantinos Varvagiannis gene: SCAMP5 was added
gene: SCAMP5 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: SCAMP5 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
Publications for gene: SCAMP5 were set to 31439720; 20071347
Phenotypes for gene: SCAMP5 were set to Global developmental delay; Intellectual disability; Seizures; Abnormality of nervous system morphology; Behavioral abnormality
Penetrance for gene: SCAMP5 were set to unknown
Mode of pathogenicity for gene: SCAMP5 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: SCAMP5 was set to AMBER
Added comment: PMID: 31439720 (Hubert et al. 2019) reported on 2 unrelated individuals with severe ID, seizures behavioral and brain MRI abnormalities (white matter hyperintensity and mesial temporal sclorosis), both harboring the same missense SCAMP5 mutation as a de novo event (NM_001178111.1:c.538G>T or p.Gly180Trp).

Previously aCGH +/- metabolic workup were non diagnostic.

The occurrence of the same de novo variant in both as well as the similar presentation (incl. MRI images) suggested SCAMP5 as the most probable candidate gene, despite presence of few other variants in both.

SCAMP5 is highly expressed in brain (https://www.proteinatlas.org/ENSG00000198794-SCAMP5) and previous studies have suggested a role in synaptic vesicle trafficking (PMIDs cited: 29562188, 25057210, etc).

Cultured skin fibroblasts from affected individuals failed to express SCAMP5.

Scamp is the Drosophila orthologue, with previous studies having demonstrated that mutants display defects in climbing, olfactory-assisted memory and susceptibility to heat induced seizures (PMIDs cited: 25478561, 19144841). Expression of the Scamp Gly302Trp variant in Drosophila ('equivalent' to the SCAMP5 Gly180Trp) revealed strongly reduced levels for the variant compared with wt upon Western Blot, either due to reduced expression or due to increased turnover. Overall the effect of Gly302Trp expression was similar to Scamp knockdown by RNAi (eg. rough eye phenotype, reduced ability to climb the walls of a graded tube after tapping, less/no flies reaching adult stage) but significantly different compared to wt.

As a result, a dominant-negative effect was presumed.
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PMID: 20071347 (Castermans et al. 2010) is cited as a previous report of a relevant affected individual. In this study a 40 y.o. male with early DD, mild ID (IQ of 63) and ASD was found to harbor a de novo apparently balanced t(1;15) translocation affecting CLIC4 and PPCDC (both not associated with ID). [1-Mb resolution aCGH revealed no relevant CNVs].

Studies were however focused on SCAMP5 given that the gene is located downstream of / proximal to PPCDC, has brain-enriched expression as well as involvement in synaptic trafficking and demonstrated:
- Less than 50% expression upon quantitative RT-PCR in patients leukocytes, compared to control.
- Silencing and overexpression of Scamp5 in mouse β-TC3 cells resulted in increased and suppressed respectively secretion of large dense-core vesicles (LDCVs).
- Given conservation of some components involved in secretion of dense core granules (DCGs) in platelets and LDCVs in neuronal cells, study of patient platelets - where SCAMP5 was confirmed to be expressed - suggested an altered pattern of DCGs.
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SCAMP5 is not associated with any phenotype in OMIM/G2P/SysID and not commonly included in gene panels for ID.
----------
Overall, this gene could be considered for inclusion in the ID and epilepsy panels probably with amber (# of unrelated individuals, 1 recurrent de novo variant and 1 regulatory effect, gene expressed in brain with a role in synaptic vesicle trafficking) or red rating (pending further evidence).
Sources: Literature
Intellectual disability v2.654 CUX1 Konstantinos Varvagiannis gene: CUX1 was added
gene: CUX1 was added to Intellectual disability. Sources: Literature,Radboud University Medical Center, Nijmegen
Mode of inheritance for gene: CUX1 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
Publications for gene: CUX1 were set to 30014507; 20510857; 25059644
Phenotypes for gene: CUX1 were set to Global developmental delay with or without impaired intellectual development, 618330
Penetrance for gene: CUX1 were set to unknown
Review for gene: CUX1 was set to GREEN
gene: CUX1 was marked as current diagnostic
Added comment: Heterozygous pathogenic variants in CUX1 cause Global developmental delay with or without impaired intellectual development (MIM 618330).

Platzer et al. (2018 - PMID: 30014507) report on 9 individuals from 7 families with heterozygous null-allele variants in CUX1.

All individuals displayed DD (speech delay 9/9 - motor delay 7/9 - hypotonia 3/7 for whom this information was available). Mild/moderate ID was a feature in 5/8. Catch up was observed in 3/8 individuals who - despite a history of previous significant DD - displayed a normal age-related intelligence. For 1/9 individual (Decipher 338131) information on eventual ID was unavailable. Overall the phenotype was compatible with non-syndromic DD with possible ID.

CUX1 encodes Cut homebox-1 transcription factor.

5 LoF variants (Gln21*, Gln800Argfs*19, Gln873*, Ala1067Cysfs*3, Leu1262Argfs*10) and 2 intragenic deletions (deletion of exons 9-24 in one subject and 3-24 in another) are reported.

In 6/9 individuals the variant (SNV/CNV) had occurred as a de novo event. Mosaic de novo intragenic deletion was reported for the subject from Decipher. In one family 2 sibs with mild ID had inherited a LoF variant from their affected mother with moderate ID (origin of the variant unknown in her case).

Leu1262Argfs*10 lies in the penultimate exon (NM_001202543.1 used as ref.) and is presumed to escape NMD.

Expression studies (or functional studies) are not performed for any of the variants.

As Gln800Argfs*19, found in one subject with mild ID in the present study, has been reported once in gnomAD, and given the presence of 12 individuals overall with LoF variants in the specific database, plausible explanations are discussed (among others : mild phenotype, incomplete penetrance, somatic mosaicism, exclusion of individuals with severe early-onset disorders in gnomAD, etc).

Given the reported variants, the probability of LoF intolerance (pLI:1.00), and the haploinsufficiency score (% HI) of 7.19, haploinsufficiency is thought to be the underlying mechanism. CUX1 however appears to be intolerant also to missense SNVs (z-score : 5.05).

Mouse models suggest a role for Cux1 in brain development and signaling. As the authors note, Cux1 (similar to its paralog, Cux2) is selectively expressed in layer II to IV cortical neurons. In Cux1-deficient mice, dendrites display a simpler morphology with decrease in dendritic length and number of branches (PMIDs cited: 20510857, 25059644). (MGI db for Cux1 - http://www.informatics.jax.org/marker/MGI:88568 : "Homozygotes for a targeted null mutation exhibit delayed lung development and neonatal mortality. Survivors show growth retardation and hair defects. Homozygotes for a partially deleted protein have curly hair, and females tend to lose their litters").

Finally, heterozygous mutations in CUX2, encoding cut-like homeobox-2 transcription factor, cause Epileptic encephalopathy, early infantile, 67 (MIM 618141 - in all cases reported to date due to a recurrent missense variant. Gene rated green in the current panel).
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CUX1 is not associated with any phenotype in G2P.
This gene is included in panels for ID offered by diagnostic laboratories (incl. Radboudumc).
-------
As a result, CUX1 can be considered for inclusion in the ID panel as green (or amber).
Sources: Literature, Radboud University Medical Center, Nijmegen
Intellectual disability v2.588 MAPK8IP3 Konstantinos Varvagiannis gene: MAPK8IP3 was added
gene: MAPK8IP3 was added to Intellectual disability. Sources: Literature
Mode of inheritance for gene: MAPK8IP3 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown
Phenotypes for gene: MAPK8IP3 were set to 25363768; 28213671; 28135719
Penetrance for gene: MAPK8IP3 were set to unknown
Review for gene: MAPK8IP3 was set to GREEN
Added comment: Platzer et al. (doi.org/10.1016/j.ajhg.2018.12.008) report on 13 unrelated individuals with de novo pathogenic variants in MAPK8IP3.

The phenotype consisted - among others - of DD with ID (13/13) as well as variable brain anomalies (incl. cerebral or cerebellar atrophy, corpus callosum anomalies, perisylvian polymicrogyria, etc). Microcephaly, seizures, ataxia, ASD were features seen in fewer individuals.

The variants reported included 2 nonsense, 1 frameshift as well as 6 missense mutations (3 missense variants were found - each - in 2 or more individuals).

All three LoF variants were located in the first exon. (mRNA levels were not studied for these variants although NMD is presumed). The brain anomalies were more consistent for missense variants.

MAPK8IP3 appears intolerant to LoF variants (pLI of 1) with constraint also for missense variants (Z-score of 4.06).

In silico structural modeling was possible for 4 missense variants based on available crystal structures and different mechanisms were presumed (disruption of contacts between Leu444 of adjacent subunits, altered interaction between proximal residues at positions 461 and 466, or disruption of protein protein interactions).

The C.elegans MAPK8IP3 ortholog is encoded by the unc-16 gene. Impaired clearance and accumulation of organelles (incl. lysosomes) in axons is observed in unc-16 mutants (recessive phenotype).

For 6 variants, also conserved in C.elegans, mutants were engineered using CRISPR genome editing. The observed mutant phenotypes (increased axonal lysosomal density compared to controls for 2 variants, sluggish locomotion with lower swimming cycle rate for 1 nonsense and 4 missense variants) were rescued upon CRISPR reverse engineering of each mutant allele back to its wild-type sequence.

The authors cite 3 previous studies, in which individuals investigated for neurodevelopmental disorders where found to harbor de novo MAPK8IP3 variants, namely:
- PMID 25363768 (Iossifov et al.) : p.Tyr94Cys [ASD without ID]
- PMID 28213671 (Berger et al.) : p.Glu461Gly [Smith-Magenis-like phenotype)
- PMID 28135719 (DDD study) p.Arg1146Cys [This variant was found in 3 individuals in the study by Platzer et al.]
------------
A few additional individuals with neurodevelopmental disorders appear in the denovo-db after filtering for coding variants:
http://denovo-db.gs.washington.edu/denovo-db/QueryVariantServlet?searchBy=Gene&target=MAPK8IP3
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NM_015133.4:c.111C>G (p.Tyr37Ter) has been submitted in ClinVar by the Undiagnosed Diseases Network (NIH) as likely pathogenic, associated with MAPK8IP3-related disorder (hypotonia, DD, EEG anomalies among the phenotypes). It is not clear whether this subject corresponds to individual #3 reported by the previous study (possibly not the case).
------------
MAPK8IP3 is not associated with any phenotype in OMIM, nor in G2P.
This gene is not commonly included in gene panels for ID.
------------
As a result, MAPK8IP3 can be considered for inclusion in this panel as green (rather than amber).
Sources: Literature