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| Intellectual disability - microarray and sequencing v5.536 | FEM1B | Zornitza Stark edited their review of gene: FEM1B: Added comment: Five individuals reported now with same recurrent missense variant, NM_015322.5:c.377G>A NP_056137.1:p.(Arg126Gln). Affected individuals shared a severe neurodevelopmental disorder with behavioral phenotypes and a variable set of malformations, including brain anomalies, clubfeet, skeletal abnormalities, and facial dysmorphism. Overexpression of the the FEM1BR126Q variant but not FEM1B wild-type protein, during mouse brain development, resulted in delayed neuronal migration of the target cells.; Changed rating: GREEN; Changed publications to: 31036916, 38465576; Changed phenotypes to: Syndromic disease MONDO:0002254, FEM1B-related | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Intellectual disability - microarray and sequencing v5.483 | PPP2R2B |
Arina Puzriakova edited their review of gene: PPP2R2B: Added comment: - PMID: 25356899 (2014) - missense variant (c.413G>C, p.Arg138Pro) in the PPP2R2B gene identified in a 7-year-old boy with moderate ID, intractable seizures and autistic features. Otherwise limited information provided. Comment on publications: PMID: 25356899 was identified by the Genomics England Applied Machine Learning (ML) team in a Biocuration-ML project for identifying new gene-disease associations using Natural Language Processing (NLP) and Generative AI techniques; Changed publications to: 25356899; Changed mode of inheritance: MONOALLELIC, autosomal or pseudoautosomal, NOT imprinted |
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| Intellectual disability - microarray and sequencing v5.268 | U2AF2 |
celia duff changed review comment from: Literature evidence Ref1-5, identification of affected patients in the diagnostic setting (CVA database, 19:55661148:C>T ) and further accounts in open access databases (ClinVar and LOVD), make this gene suitable for clinical review and upgrading to a green gene status on relevant panels. It is associated with a phenotype encompassing dysmorphism, epilepsy, developmental delay, intellectual disability, and brain malformation Ref1-5. There is a recent publication that proposes an extension of this phenotype to include hypomyelination leukodystrophy Ref6. A loss of function mechanism has been suggested, associated with disruption of RNA recognition motifs required for the function of U2AF2 as a pre-mRNA splicing factor Ref4. At least one recurrent pathogenic variant has been identified by this review U2AF2 c.445C>T p.(Arg149Trp). U2AF2 is constrained for missense in gnomAD Z=4.71. total variants reported 1) De novo U2AF2 (NM_007279.3:c.445C>T p.(Arg149Trp)) recurrent variant; 1x patient in Hiraide (PubMed: 34112922), 1x patient in Kittock (PubMed: 37092751), 2x patients in Kaplanis (Pubmed: 33057194), 7x patients in the Leiden Open Variation Database (LOVD, https://www.lovd.nl/), 1x patient in house BGL and 4x additional on CVA 2) De novo U2AF2 c.603G>T; 1 patient in Wang 2023 (PubMed: 36747105) 3) De novo U2AF2 c.470C>T p.Pro157Leu) in Kuroda (PubMed: 37134193) 4) 9x additional pathogenic or likely pathogenic variants on LOVD 5) 2x additional likely pathogenic variants on ClinVar References 1. PubMed: 28135719 McRae (2017)-DDD data 2. PubMed: 31785789 Turner (2019)-DDD data 3. PubMed: 34112922 Hiraide (2021) de novo U2AF2 c.445C>T p.R149W 4. PubMed: 36747105 Wang (2023) de novo U2AF2 c.603G>T, p.163_201del 5. PubMed: 37092751 Kittock (2023) de novo U2AF2 c.445C>T p.R149W Possible emerging phenotype of hypomyelinating leukodystrophy 6. PubMed: 37134193 Kuroda (2023); to: Literature evidence Ref1-5, identification of affected patients in the diagnostic setting (CVA database, 19:55661148:C>T ) and further accounts in open access databases (ClinVar and LOVD), make this gene suitable for clinical review and upgrading to a green gene status on relevant panels. It is associated with a phenotype encompassing dysmorphism, epilepsy, developmental delay, intellectual disability, and brain malformation Ref1-5. There is a recent publication that proposes an extension of this phenotype to include hypomyelination leukodystrophy Ref6. A loss of function mechanism has been suggested, associated with disruption of RNA recognition motifs required for the function of U2AF2 as a pre-mRNA splicing factor Ref4. At least one recurrent pathogenic variant has been identified by this review U2AF2 c.445C>T p.(Arg149Trp). U2AF2 is constrained for missense in gnomAD Z=4.71. total variants/patients identified 1) De novo U2AF2 (NM_007279.3:c.445C>T p.(Arg149Trp)) recurrent variant; 1x patient in Hiraide (PubMed: 34112922), 1x patient in Kittock (PubMed: 37092751), 2x patients in Kaplanis (Pubmed: 33057194), 7x patients in the Leiden Open Variation Database (LOVD, https://www.lovd.nl/), 1x patient in house BGL and 4x additional on CVA 2) De novo U2AF2 c.603G>T; 1 patient in Wang 2023 (PubMed: 36747105) 3) De novo U2AF2 c.470C>T p.Pro157Leu) in Kuroda (PubMed: 37134193) 4) 9x additional pathogenic or likely pathogenic variants on LOVD 5) 2x additional likely pathogenic variants on ClinVar 6) We are collaborating with a researcher in the USA with a cohort of 40+ cases. References 1. PubMed: 28135719 McRae (2017)-DDD data 2. PubMed: 31785789 Turner (2019)-DDD data 3. PubMed: 34112922 Hiraide (2021) de novo U2AF2 c.445C>T p.R149W 4. PubMed: 36747105 Wang (2023) de novo U2AF2 c.603G>T, p.163_201del 5. PubMed: 37092751 Kittock (2023) de novo U2AF2 c.445C>T p.R149W Possible emerging phenotype of hypomyelinating leukodystrophy 6. PubMed: 37134193 Kuroda (2023) |
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| Intellectual disability - microarray and sequencing v5.247 | MKL2 | Achchuthan Shanmugasundram commented on gene: MKL2: PMID:37013900 - Two unrelated paediatric cases with de novo variants in MKL2 gene (p.Arg103Gly & p.Ala91Pro) were reported with mild dysmorphic features, severe intellectual disability, global developmental delays, speech apraxia, and impulse control issues. Functional studies in a Drosophila model suggest a gain of function disease mechanism. | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Intellectual disability - microarray and sequencing v5.70 | INTS11 |
Achchuthan Shanmugasundram changed review comment from: PMID:37054711 reported ten unrelated families with biallelic variants in INTS11 gene and they present with intellectual disability, global developmental and language delay, impaired motor development, and brain atrophy. Functional studies in Drosophila showed that dIntS11 (fly ortholog of INTS11) is essential and expressed in the central nervous systems in a subset of neurons and most glia in larval and adult stages. In addition, genes with two variants (p.Arg17Leu and p.His414Tyr) fail to rescue the lethality of null mutants in the Drosophila model, indicating that they are strong loss-of-function variants. The other five variants (p.Gly55Ser, p.Leu138Phe, p.Lys396Glu, p.Val517Met and p.Ile553Glu) rescue lethality but cause a shortened lifespan and bang sensitivity and affect locomotor activity, indicating that they are partial loss-of-function variants. Sources: Literature; to: PMID:37054711 reported ten unrelated families with biallelic variants in INTS11 gene and they present with intellectual disability, global developmental and language delay, impaired motor development, and brain atrophy. Functional studies in Drosophila showed that dIntS11 (fly ortholog of INTS11) is essential and expressed in the central nervous systems in a subset of neurons and most glia in larval and adult stages. In addition, genes with two variants (p.Arg17Leu and p.His414Tyr) fail to rescue the lethality of null mutants in the Drosophila model, indicating that they are strong loss-of-function variants. The other five variants (p.Gly55Ser, p.Leu138Phe, p.Lys396Glu, p.Val517Met and p.Ile553Glu) rescue lethality but cause a shortened lifespan and bang sensitivity and affect locomotor activity, indicating that they are partial loss-of-function variants. This gene has not yet been associated with relevant phenotypes in OMIM or in Gene2Phenotype. Sources: Literature |
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| Intellectual disability - microarray and sequencing v5.68 | INTS11 |
Achchuthan Shanmugasundram gene: INTS11 was added gene: INTS11 was added to Intellectual disability - microarray and sequencing. Sources: Literature Mode of inheritance for gene: INTS11 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: INTS11 were set to 37054711 Phenotypes for gene: INTS11 were set to intellectual disability, MONDO:0001071 Review for gene: INTS11 was set to GREEN Added comment: PMID:37054711 reported ten unrelated families with biallelic variants in INTS11 gene and they present with intellectual disability, global developmental and language delay, impaired motor development, and brain atrophy. Functional studies in Drosophila showed that dIntS11 (fly ortholog of INTS11) is essential and expressed in the central nervous systems in a subset of neurons and most glia in larval and adult stages. In addition, genes with two variants (p.Arg17Leu and p.His414Tyr) fail to rescue the lethality of null mutants in the Drosophila model, indicating that they are strong loss-of-function variants. The other five variants (p.Gly55Ser, p.Leu138Phe, p.Lys396Glu, p.Val517Met and p.Ile553Glu) rescue lethality but cause a shortened lifespan and bang sensitivity and affect locomotor activity, indicating that they are partial loss-of-function variants. Sources: Literature |
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| Intellectual disability - microarray and sequencing v5.12 | MED11 |
Sarah Leigh gene: MED11 was added gene: MED11 was added to Intellectual disability - microarray and sequencing. Sources: Literature Q2_23_promote_green tags were added to gene: MED11. Mode of inheritance for gene: MED11 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: MED11 were set to 36001086 Phenotypes for gene: MED11 were set to MED11-associated neurodevelopmental disorder Review for gene: MED11 was set to GREEN Added comment: Not associated with a phenotype in OMIM, but is associated with MED11-associated neurodevelopmental disorder in Gen2Phen. PMID: 36001086 reports a single MED11 variant (NM_001001683.4: c.325C>T, p.Arg109*), that segregates with the condition in five unrelated families, however, there is homozygosity between two of these families, idicating that they may be related. Global delay was observed in three individuals from three unrelated familes and seizures were evident in four individuals from four unrelated families. Severe microcephaly was apparent in the two unrelated familes where this parameter was recorded. Overall, the MED11-associated neurodevelopmental disorder appeared to result in profound effects and proved fatal at birth and 10 days in two of the cases reported. Sources: Literature |
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| Intellectual disability - microarray and sequencing v4.95 | RBSN |
Achchuthan Shanmugasundram gene: RBSN was added gene: RBSN was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: RBSN was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: RBSN were set to 25233840; 29784638; 35652444 Phenotypes for gene: RBSN were set to intellectual disability, MONDO:0001071 Review for gene: RBSN was set to GREEN Added comment: PMID:25233840 reported a 6.5 year old female patient with a homozygous missense variant c.1273G > A (p.Gly425Arg) and her clinical presentation included intractable seizures, developmental delay, microcephaly, dysostosis, osteopenia, craniofacial dysmorphism, macrocytosis and megaloblastoid erythropoiesis. PMID:29784638 reported three siblings with homozygous variant c.289G>C (p.Gly97Arg) in RBSN. The proband presented global developmental delay, had complete 46,XY male-to-female sex reversal and died at age 20 months after multiple infections. The other 2 affected siblings underwent unrelated-donor bone marrow or stem cell transplantation at 8 and 6.5 months of age, respectively. Both have severe intellectual disability and are nonambulatory and nonverbal. PMID:35652444 reported two unrelated families (three siblings from a family of Iranian descent identified with homozygous variant c.547G>A (p.Gly183Arg) and four members from a family of indigenous Cree descent identified with homozygous variant c.538C>G (p.Arg180Gly)) with overlapping phenotypes including developmental delay, intellectual disability, distal motor axonal neuropathy and facial dysmorphism. Sources: Literature |
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| Intellectual disability - microarray and sequencing 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 ] ----- 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 |
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| Intellectual disability - microarray and sequencing v3.1561 | CCDC82 |
Konstantinos Varvagiannis gene: CCDC82 was added gene: CCDC82 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: CCDC82 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: CCDC82 were set to 27457812; 28397838; 35118659; 35373332 Phenotypes for gene: CCDC82 were set to Global developmental delay; Intellectual disability; Spastic paraparesis Penetrance for gene: CCDC82 were set to Complete Review for gene: CCDC82 was set to AMBER Added comment: The phenotype of individuals with biallelic CCDC82 variants has been reported - in most cases briefly - in the following reports (each summarizing the findings of previous ones): Riazzudin et al (2017 - PMID: 27457812) in a large consanguineous pedigree from Pakistan (PKMR206) identified 4 individuals homozygous for a fs variant [NM_024725.3:c.373delG / p.(Asp125Ilefs*6)] (V3,V4,V5,V10). There was no other variant segregating with the phenotype of ID (Delayed CMS, moderate ID and speech delay probably common to all, V3,4,5 had also mild hypotonia and motor weakness). There was one unaffected sib tested (homozygous for ref. alelle). 2 further affected males (V1, V2) with similar phenotype were not tested. Harripaul et al (2018 - PMID: 28397838) reported 2 sibs with nonsyndromic ID belonging to a consanguineous family (AS17) from the Middle-East. Both were homozygous for NM_024725.3:c.535C>T / p.Arg179*. The variant was confirmed with Sanger sequencing and parents were heterozygous carriers. Two additional affected sibs were probably not tested. Yahia et al (2022 - PMID: 35118659) described 2 sibs belonging to a consanguineous family from Sudan. These presented global DD (last evaluation at 4y and 9m) and spasticity. There was a common history of infantile spasms with the elder developing GTC convulsions with spontaneous resolution. Additionaly, both presented microcephaly (<-2 and <-3SD). Exome sequencing revealed homozygosity for c.535C>T / p.Arg179* (previously reported by Harripaul et al). Sanger sequencing was used for confirmation and demonstration of carrier state of parents. Two similarly affected sibs were not available for testing. Bauer et al (2022 - PMID: 35373332) reported a 21 y.o. male born to consanguineous parents from Pakistan. Features included short stature, ID, spastic paraparesis (at the age of 3y). Gelastic seizures were suspected but not confirmed (repeated normal EEGs). WES revealed homozygosity for a fs CCDC82 variant [NM_001318736.1:c.183del / p.(Phe61Leufs*27)] with Sanger confirmation in proband and heterozygous parents. There was another hmz variant, albeit classified as VUS and not thought to fit the clinical presentation. As proposed by Bauer et al. overlapping features include spastic paraparesis, DD and dysmorphic features. As commented, CCDC82 encodes coiled-coil domain protein 82, a protein with unknown function. Consider inclusion probably with amber rating (>3 individuals/families/variants, role of the gene not known, variant studies not performed to date, animal models not discussed). Sources: Literature |
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| Intellectual disability - microarray and sequencing v3.1500 | CHKA |
Konstantinos Varvagiannis gene: CHKA was added gene: CHKA was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: CHKA was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: CHKA were set to 35202461 Phenotypes for gene: CHKA were set to Abnormal muscle tone; Global developmental delay; Intellectual disability; Seizures; Microcephaly; Abnormality of movement; Abnormality of nervous system morphology; Short stature Penetrance for gene: CHKA were set to Complete Review for gene: CHKA was set to GREEN Added comment: Klöckner (2022 - PMID: 35202461) describe the phenotype of 6 individuals (from 5 unrelated families) harboring biallelic CHKA variants. Shared features incl. abnormal muscle tone(6/6 - hypertonia or hypotonia, 3/6 each), DD/ID (6/6,severe in 4, severe/profound in 2), epilepsy (6/6 - onset: infancy - 3y2m | epileptic spasms or GS at onset), microcephaly (6/6), movement disorders (3/6 - incl. dyskinesia, rigidity, choreoatetotic movements). 2/5 individuals exhibited MRI abnormalities, notably hypomyelination. Short stature was observed in 4/6. Eventual previous genetic testing was not discussed. Exome sequencing (quattro ES for 2 sibs, trio ES for 1 individual, singleton for 3 probands) revealed biallelic CHKA variants in all affected individuals. Sanger sequencing was performed for confirmation and segregation studies. Other variants (in suppl.) were not deemed to be causative for the neurodevelopmental phenotype. 3 different missense, 1 start-loss and 1 truncating variant were identified, namely (NM_0012772.2): - c.421C>T/p.(Arg141Trp) [3 hmz subjects from 2 consanguineous families], - c.580C>T/p.Pro194Ser [1 hmz individual born to consanguineous parents], - c.2T>C/p.(Met1?) [1 hmz individual born to related parents], - c.14dup/p.(Cys6Leufs*19) in trans with c.1021T>C/p.(Phe341Leu) in 1 individual. CHKA encodes choline kinase alpha, an enzyme catalyzing the first step of phospholipid synthesis in the Kennedy pathway. The pathway is involved in de novo synthesis of glycerophospholipids, phosphatidylcholine and phosphatidylethanolamine being the most abundant in eukaryotic membranes. CHKA with its paralog (CHKB) phosphorylates either choline or ethanolamine to phosphocholine or phosphoethanolamine respectively with conversion of ATP to ADP. As the authors comment, biallelic pathogenic variants in CHKB cause a NDD with muscular dystrophy, hypotonia, ID, microcephaly and structural mitochondrial anomalies (MIM 602541). [Prominent mitochondrial patterning was observed in a single muscle biopsy available from an individual with biallelic CHKA variants]. Other disorders of the Kennedy pathway (due to biallelic PCYT2, SELENOI, PCYT1A variants) present with overlapping features incl. variable DD/ID (no-severe), microcephaly, seizures, visual impairment etc. CHKA variants were either absent or observed once in gnomAD, affected highly conserved AAs with multiple in silico predictions in favor of a deleterious effect. In silico modeling suggests structural effects for several of the missense variants (Arg141Trp, Pro194Ser presumably affect ADP binding, Phe341 lying close to the binding site of phosphocholine). Each of the missense variants was expressed in yeast cells and W. Blot suggested expression at the expected molecular weight at comparative levels. The 3 aforementioned variants exhibited reduced catalytic activity (20%, 15%, 50% respectively). NMD is thought to underly the deleterious effect of the frameshift one (not studied). The start-loss variant is expected to result in significantly impaired expression and protein function as eventual utilization of the next possible start codon - occurring at position 123 - would remove 26% of the protein. Chka(-/-) is embryonically lethal in mice, suggesting that complete loss is not compatible with life. Reduction of choline kinase activity by 30% in heterozygous mice did not appear to result in behavioral abnormalities although this was not studied in detail (PMID cited: 18029352). Finally, screening of 1566 mouse lines identified 198 genes whose disruption yields neuroanatomical phenotypes, Chka(+/-) mice being among these (PMID cited: 31371714). There is no associated phenotype in OMIM, Gene2Phenotype or SysID. Overall this gene can be considered for inclusion in the ID and epilepsy panes with green or amber rating (>3 individuals, >3 variants, variant studies, overlapping phenotype of disorders belonging to the same pathway, etc). Consider also inclusion in the microcephaly panel (where available this seemed to be of postnatal onset). Sources: Literature |
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| Intellectual disability - microarray and sequencing v3.1223 | ARG1 | Arina Puzriakova Phenotypes for gene: ARG1 were changed from Argininemia, 207800; ARGININEMIA (ARGIN) to Argininemia, OMIM:207800 | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Intellectual disability - microarray and sequencing v3.982 | DDB1 |
Arina Puzriakova changed review comment from: - PMID: 33743206 (2021) - 8 unrelated individuals with de novo variants in DDB1, including one recurrent variant in four individuals (c.637G>A, p.Glu213Lys) and two different substitutions at the same amino acid residue (p.Arg188Trp and p.Arg188Gln). Clinical features were consistent and include hypotonia (7/8) and mild-moderate developmental delay or intellectual disability (8/8) and similar facial gestalt. Brachydactyly was common and most noticeable in the feet (6/8), and two individuals had cutaneous toe syndactyly. All three older individuals had a BMI in the obese range for their age. Functional studies using patient-derived lymphoblasts showed altered DDB1 function resulting in abnormal DNA damage signatures and histone methylation following UV-induced DNA damage. Sources: Literature; to: - PMID: 33743206 (2021) - 8 unrelated individuals with de novo variants in DDB1, including one recurrent variant in four individuals (c.637G>A, p.Glu213Lys) and two different substitutions at the same amino acid residue (p.Arg188Trp and p.Arg188Gln). Clinical features were consistent and include hypotonia (7/8) and mild-moderate developmental delay or intellectual disability (8/8) and similar facial gestalt. Brachydactyly was common and most noticeable in the feet (6/8), and two individuals had cutaneous toe syndactyly. All three older individuals had a BMI in the obese range for their age. Functional studies using patient-derived lymphoblasts showed altered DDB1 function resulting in abnormal DNA damage signatures and histone methylation following UV-induced DNA damage. Variants in other CRL4 complex components, such as CUL4B (MIM# 300304) and PHIP (MIM# 612870), have been shown to cause overlapping phenotypes consisting of syndromic ID with hypotonia and obesity. Sources: Literature |
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| Intellectual disability - microarray and sequencing v3.982 | DDB1 |
Arina Puzriakova gene: DDB1 was added gene: DDB1 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: DDB1 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown Publications for gene: DDB1 were set to 33743206 Phenotypes for gene: DDB1 were set to Intellectual disability Review for gene: DDB1 was set to GREEN Added comment: - PMID: 33743206 (2021) - 8 unrelated individuals with de novo variants in DDB1, including one recurrent variant in four individuals (c.637G>A, p.Glu213Lys) and two different substitutions at the same amino acid residue (p.Arg188Trp and p.Arg188Gln). Clinical features were consistent and include hypotonia (7/8) and mild-moderate developmental delay or intellectual disability (8/8) and similar facial gestalt. Brachydactyly was common and most noticeable in the feet (6/8), and two individuals had cutaneous toe syndactyly. All three older individuals had a BMI in the obese range for their age. Functional studies using patient-derived lymphoblasts showed altered DDB1 function resulting in abnormal DNA damage signatures and histone methylation following UV-induced DNA damage. Sources: Literature |
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| Intellectual disability - microarray and sequencing v3.201 | MORC2 |
Konstantinos Varvagiannis gene: MORC2 was added gene: MORC2 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: MORC2 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown Publications for gene: MORC2 were set to https://doi.org/10.1016/j.ajhg.2020.06.013 Phenotypes for gene: MORC2 were set to Charcot-Marie-Tooth disease, axonal, type 2Z, MIM #616688 Penetrance for gene: MORC2 were set to unknown Mode of pathogenicity for gene: MORC2 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: MORC2 was set to GREEN Added comment: The current review is based on a recent report by Sacoto et al (2020 - https://doi.org/10.1016/j.ajhg.2020.06.013). While several previous studies focused on the phenotype of axonal motor and senory neuropathy in individuals with heterozygous MORC2 pathogenic variants (Charcot-Marie-Tooth disease, axonal, type 2Z, MIM #616688) some of them presented among others with hypotonia, muscle weakness, intellectual disability, microcephaly or hearing loss [refs provided by Sacoto et al - learning disabilities (in some patients) also listed in OMIM's clinical synopsis]. Sacoto et al present a cohort of 20 individuals having genetic testing for developmental delay or growth failure (with a single one for a diagnosis of sensorimotor neuropathy). Overlapping features included DD, ID (18/20 - mild to severe), short stature (18/20), microcephaly (15/20) and variable craniofacial dysmorphisms. The authors comment that features suggestive of neuropathy (weakness, hyporeflexia, abnormal EMG/NCS) were frequent but not the predominant complaint. EMG/NCS abnormalities were abnormal in 6 out of 10 subjects investigated in this cohort. Other findings included brain MRI abnormalities (12/18 - in 5/18 Leigh-like lesions), hearing loss (11/19) and pigmentary retinopathy in few (5). Affected subjects were found to harbor in all cases missense variants in the ATPase module of MORC2 [residues 1 to 494 - NM_001303256.1 - the module consists of an ATPase domain (aa 1-265), a transducer S5-like domain (266-494) and a coiled-coiled domain (CC1 - aa 282-361)]. Variants had occured mostly as de novo events although inheritance from a similarly affected parent was also reported. Some of them were recurring within this cohort and/or the literature eg. c.79G>A/p.Glu27Lys (x5), c.260C>T/p.Ser87Leu (x2), c.394C>T/p.Arg132Cys (4x), c.1164C>G/p.Ser388Arg (x2), c.1181A>G/p.Tyr394Cys (x3). MORC2 encodes an ATPase involved in chromatin remodeling, DNA repair and transcriptional regulation. Chromatin remodeling and epigenetic silencing by MORC2 is mediated by the HUSH (Human Silencing Hub) complex. Functional studies (MORC2-knockout HeLa cells harboring a HUSH-sensitive GFP reporter were transduced with wt or mt MORC2 followed by measurement of reporter repression) supported the deleterious effect of most variants known at the time (hyperactivation of HUSH-mediating silencing, in line with previous observations). Overall this gene can be considered for inclusion in the ID panel with green rating. Also other gene panels (e.g. for short stature, microcephaly, hearing loss, pigmentary retinopathy, etc) if it meets the respective criteria for inclusion. Sources: Literature |
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| Intellectual disability - microarray and sequencing v3.177 | FEM1B |
Arina Puzriakova changed review comment from: Gene not associated with any phenotype on OMIM or G2P. Lecoquierre et al. (2019) (PMID: 31036916) conducted a large candidate gene discovery study and identified a de novo missense variant (p.Arg126Gln) in a patient with syndromic global developmental delay. Recurrence of the same variant was highlighted in an individual from the DDD study, and the another from GeneMatcher. It is said that the three patients share a similar phenotype; however, any further details are limited and it is not possible to ascertain whether the additional cases refer to different individuals. No function analysis was undertaken to validate the implication of FEM1B.; to: Gene not associated with any phenotype on OMIM or G2P. Lecoquierre et al. (2019) (PMID: 31036916) conducted a large candidate gene discovery study and identified a de novo missense variant (p.Arg126Gln) in a patient with syndromic global developmental delay. Recurrence of the same variant was highlighted in an individual from the DDD study, and the another from GeneMatcher, who were said to share a similar phenotype. No function analysis was undertaken to validate the implication of FEM1B. |
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| Intellectual disability - microarray and sequencing v3.174 | FEM1B |
Arina Puzriakova changed review comment from: Lecoquierre et al. (2019) (PMID: 31036916) conducted a large candidate gene discovery studying and identified a de novo missense variant (p.Arg126Gln) in a patient with syndromic global developmental delay. Recurrence of the same variant was highlighted in an individual from the DDD study, and the another from GeneMatcher. It is said that the three patients share a similar phenotype; however, any further details are limited and it is not possible to ascertain whether the additional patients refer to different individuals. No function analysis was undertaken to validate the implication of FEM1B. Gene not associated with any phenotype on OMIM or G2P.; to: Gene not associated with any phenotype on OMIM or G2P. Lecoquierre et al. (2019) (PMID: 31036916) conducted a large candidate gene discovery study and identified a de novo missense variant (p.Arg126Gln) in a patient with syndromic global developmental delay. Recurrence of the same variant was highlighted in an individual from the DDD study, and the another from GeneMatcher. It is said that the three patients share a similar phenotype; however, any further details are limited and it is not possible to ascertain whether the additional cases refer to different individuals. No function analysis was undertaken to validate the implication of FEM1B. |
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| Intellectual disability - microarray and sequencing v3.170 | HERC2 |
Konstantinos Varvagiannis edited their review of gene: HERC2: Added comment: Please consider upgrading this gene to green in the current panel based on the following updated review (13-07-2020): Biallelic pathogenic HERC2 variants cause Mental retardation, autosomal recessive 38 (MIM 615516). The current review is based mostly on the information provided by Elpidorou et al (2020 - PMID: 32571899) summarizing the findings in several affected individuals as published in the literature. ID was a universal feature among them (27/27) and seizures were reported in some (9/27): - 22 subjects from Amish/Mennonite families were homozygous for p.Pro594Leu [NM_004667.5(HERC2):c.1781C>T] (Puffenberger et al 2012 - PMID: 23065719, Harlalka et al 2013 - PMID: 23243086, Abraham et al - PMID: 30902390) - 2 additional patients were homozygous for another missense SNV [NM_004667.5(HERC2):c.4625G>A - p.Arg1542His] (Abraham et al 2019 - PMID: 30902390) - 3 sibs born to consanguineous parents, homozygous for NM_004667.5:c.13767_13770delTGAA - p.(Asn4589LysTer4598)] as described by Elpidorou et al. - 1 male homozygous 286 kb deletion spanning several 5' exons of HERC2 as well as the first exons of OCA2 was described by Morice-Picard et al (2016 - PMID: 27759030). Despite a neurological presentation (axial hypotonia, peripheral hypertonia, extrapyramidal symptoms and uncoordinated movements) further information was not available. Apart from the cases summarized by Elpidorou et al, there have been few additional ones e.g. : - Trujillano et al (2017 - PMID: 27848944) reported briefly on a patient, homozygous for NM_004667.5:c.4676-1G>A displaying seizures, hypotonia, global DD, "Encephalopathy" and abnormality of the liver. - Yavarna et al (2015 - PMID: 26077850) provided few details with on an individual with primarily 'neurocognitive' phenotype but rather atypical presentation (MRI abnormalities, TGA, VSD, renal anomaly, growth retardation, hearing loss) due to p.Q3164X variant (recessive inheritance was specified). Several lines of evidence support an important role for the protein encoded (an E3 ubiquitin protein ligase, interacting also with UBE3A, involved in several cellular processes incl. cell cycle regulation, spindle formation during mitosis, mitochondrial functions, DNA damage responses by targeting proteins such as XPA) as well as the effect of the reported variants (mRNA studies, Western blot, detection of a fusion transcript in the case of the deletion, etc). Individuals from the Amish families displayed Angelman-like features (in line with HERC2-UBE3A interaction) with - among others - gait instability. Mouse models recapitulate some of these features (e.g. the movement disorder) as extensively discussed by Abraham et al. Overall this gene can be included in the ID and epilepsy panels with green rating. -----; Changed rating: GREEN; Changed publications: 23065719, 23243086, 30902390, 32571899, 27848944, 26077850, 27759030 |
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| Intellectual disability - microarray and sequencing v3.157 | FEM1B |
Arina Puzriakova changed review comment from: Lecoquierre et al. (2019) (PMID: 31036916) conducted a large candidate gene discovery studying and identified a de novo missense variant (p.Arg126Gln) in a patient with syndromic global developmental delay. Recurrence of the same variant was highlighted in an individual from the DDD study, and the another from GeneMatcher. It is said that the three patients share a similar phenotype; however, any further details are limited and it is not possible to ascertain whether the additional patients refer to different individuals. No function analysis was undertaken to validate the implication of FEM1B. Gene not associated with any phenotype on OMIM or G2P.; to: Lecoquierre et al. (2019) (PMID: 31036916) conducted a large candidate gene discovery studying and identified a de novo missense variant (p.Arg126Gln) in a patient with syndromic global developmental delay. Recurrence of the same variant was highlighted in an individual from the DDD study, and the another from GeneMatcher. It is said that the three patients share a similar phenotype; however, any further details are limited and it is not possible to ascertain whether the additional patients refer to different individuals. No function analysis was undertaken to validate the implication of FEM1B. Gene not associated with any phenotype on OMIM or G2P. |
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| Intellectual disability - microarray and sequencing 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 |
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| Intellectual disability - microarray and sequencing v3.0 | PUM1 |
Konstantinos Varvagiannis commented on gene: PUM1: 5 unrelated individuals with de novo pathogenic PUM1 variants have been reported in the literature. DD (5/5), ID (4/5 - relevant severity to the current panel), seizures (4/4 - absence/tonic-clonic, abnormal EEG) and variable other features (incl. facial dysmorphism, ataxia, cryptorchidism) appear to be part of the phenotype. 9 individuals with deletions spanning PUM1 and proximal genes presented similar features. [1] PMID: 29474920 - Gennarino et al (2018) [2] PMID: 30903679 - Bonnemason-Carrere et al (2019) [3] PMID: 31859446 - Voet et al (2019) [with review of the literature] SNVs in relevant individuals were identified by exome sequencing and were in all cases de novo. Arg1147Trp was a recurrent variant reported in 3 unrelated subjects with ID and seizures (Refs 1,2,3 / NM_001020658.1:c.3439C>T). A nonsense variant was reported in an additional one with DD, ID, seizures and additional features (c.2509C>T / p.Arg837* - Ref3). One individual with a de novo missense variant (c.3416G>A / p.Arg1139Trp) with DD and ataxia, though without ID was reported in Ref1. Details on 9 individuals with 0.3 - 5.6 Mb deletions spanning PUM1 and other genes are provided in Ref1. Features also included DD, ID, seizures, ataxia, etc. Extensive initial investigations were reported for individuals in Refs 2 and 3 (various investigations incl. karyotype, SNP-array, targeted sequencing of OPHN1, KANSL1 or of a small panel of ID genes, biopsies and/or metabolic work-up) to rule out alternative causes. These only revealed a likely benign CNV and a GRIA3 SNV of uncertain significance in the case of an individual harboring the recurrent Arg1147Trp variant [Ref2]. Role of the gene (from OMIM): Pumilio proteins, such as PUM1, negatively regulate gene expression by repressing translation of mRNAs to which they bind (Lee et al., 2016). A clinically significant PUM1 target is ataxin (ATXN1; 601556), mutation in which causes spinocerebellar ataxia-1 (SCA1; 601556). Variant studies: - Arg1147Trp was shown to be associated with normal PUM1 mRNA levels, but reduced (to ~43%) PUM1 protein levels in patient fibroblasts. ATXN1 mRNA and protein levels, as well as protein and/or mRNA levels of other PUM1 targets were shown to be increased (Ref1). - In Ref1, in vitro transfection assays with wt or mt PUM1 were performed in HEK293T cells to evaluate repression of ATXN1 and E2F3. While overexpression of wt and Arg1147Trp were able to reduce ATXN1 and E2F3 levels, Arg1139Trp was not able to repress ATXN1 or E2F3. - Upon overexpression in mouse hippocampal neurons, PUM1 missense mutations (among others Arg1139Trp and Arg1147Trp) were shown to alter neuronal morphology. Overall haploinsufficiency is the proposed mechanism for the disorder for which the acronym PADDAS is used (Pumilio1-associated developmental disability, ataxia and seizure). Milder mutations reducing PUM1 levels by 25% are associated with adult-onset ataxia without ID (PRCA or Pumilio1-related cerebellar ataxia) [Ref1]. Mouse models: The role of PUM1 was first suggested in mouse models where Pum1 mutations were shown to lead to a SCA1-like phenotype (PMID cited : 12086639 - Watase et al 2002) further shown to be caused by increased Atxn1 mRNA and protein levels (PMID cited : 25768905 - Gennarino et al 2015). The mouse model seems to recapitulate several of the features observed in affected individuals : Pum1 homozygous ko mice display among others hyperactivity, progressive cerebellar signs, spontaneous seizures as also observed in affected individuals (PMID cited : 25768905 - Gennarino et al 2015). Cryptorchidism was observed in 2 patients similar to testicular hypoplasia reported in Pum1 ko mice (PMID cited : 22342750 - Chen et al 2012). - Heterozygous mice were evaluated in Ref1 with 69% or 75% exhibiting spontaneous seizures by the end of 30 or 35 wks respectively, with abnormal EEG activity already by 16 wks. Additional individuals with PUM1 variants and a relevant phenotype of ID with or without seizures have been reported as part of the DDD study or as external submissions to Decipher and ClinVar : https://decipher.sanger.ac.uk/search?q=PUM1#research-variants/results [ DDD4K.01387 participant ] https://decipher.sanger.ac.uk/search?q=pum1#consented-patients/results [ external submission(s) ] https://www.ncbi.nlm.nih.gov/clinvar/variation/431110/ [ splice-site variant in an individual with ID submitted prior to the 1st publication on the disorder ] |
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| Intellectual disability - microarray and sequencing v3.0 | MN1 |
Konstantinos Varvagiannis gene: MN1 was added gene: MN1 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: MN1 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown Publications for gene: MN1 were set to 31834374; 31839203; 15870292 Phenotypes for gene: MN1 were set to Central hypotonia; Feeding difficulties; Global developmental delay; Intellectual disability; Hearing impairment; Abnormality of facial skeleton; Craniosynostosis; Abnormality of the face; Abnormality of the cerebellum; Abnormality of the corpus callosum; Polymicrogyria Penetrance for gene: MN1 were set to Complete Review for gene: MN1 was set to GREEN Added comment: Two studies by Mak et al (2019 - PMID: 31834374 / Ref1) and Miyake et al (2019 - PMID: 31839203 / Ref2) provide sufficient evidence for heterozygous MN1 C-terminal truncating variants (predicted to escape NMD - localizing within the last nucleotides of exon 1 or in exon 2) being associated with a distinctive phenotype and DD and ID among the features. Mak et al also discuss on the phenotype of individuals with variants causing N-terminal truncation or with MN1 deletions (discussed at the end of this review). Overlapping features for C-terminal truncating variants included hypotonia, feeding difficulties, global DD and ID, hearing loss, cranial shape defects (/craniosynostosis in few), highly suggestive/distinctive facial features (eg. frontal bossing, hypertelorism, downslanting palpebral-fissures, shallow orbits, short upturned nose, low-set/posteriorly rotated/dysplastic ears, etc) and brain MRI abnormalities (eg. rhomboencephalosynapsis or cerebellar dysplasia, polymicrogyria, dysplastic CC). The majority of the affected individuals were investigated by WES/WGS with a single one tested by targeted MN1 Sanger sequencing due to highly suggestive features. Variable previous investigations incl. CMA in several, gene panel testing (Rasopathies, hearing loss, craniofacial panels, FMR1, etc) and metabolic work were normal in most. In a single case a likely pathogenic ACSL4 also explained part of the phenotype (Ref2). In the majority of these individuals, the variant had occured as a de novo event. Two sibs had inherited the truncating variant from a milder affected mosaic parent. A parental sample was not available for an additional individual. p.(Arg1295*) or NM_002430.2:c.3883C>T was a recurrent variant, seen in several individuals and in both studies. Several lines of evidence are provided for the MN1 variants and the role of the gene including: - For few individuals for whom cell lines were available, variants were shown to escape NMD by cDNA/RT-PCR/RNA-seq [Ref1 & 2]. - The gene has a high expression in fetal brain [Ref2 / fig S2] - MN1 (* 156100 - MN1 protooncogene, transcriptional regulator) has been proposed to play a role in cell proliferation and shown to act as transcription cofactor (increasing its transactivation capacity in synergy with coactivators EP300 and RAC3) [Discussion and Refs provided in Ref2]. - In vitro studies suggested increased protein stability (upon transfection of wt/mut constructs in HEK293T cells), enhanced MN1 aggregation in nuclei (when wt/mut GFP-tagged MN1 was expressed in HeLa cells), increased inhibitory effect on cell growth (MG63 cells - role of MN1 in cell proliferation discussed above) and retained transactivation activity (upon transient MN1 overexpression of wt/mt MN1 in HEK293T cells) for the variants. These seem to support a gain-of-function effect for the C-terminal truncating variants [Ref2]. - The truncating variants are proposed to raise the fraction of Intrinsically disordered regions (IDRs = regions without fixed tertiary structure) probably contributing to the above effects [Ref2]. - Expression of FLAG-tagged MN1 wt/mut MN1 followed by immunoprecipitation and mass spectrometry analysis (mCAT-Hela cells), provided evidence that MN1 is involved in transcriptional regulation: a. through binding ZBTB24 and RING1 E3 ubiquitin ligase (with mutant MN1 displaying impaired interaction with ZBTB24 and no binding to RING1) and/or b. through interaction with DNA-binding transcription factors PBX1 and PKNOX1. Proper MN1 degradation is proposed to mediate precise transcriptional regulation. [Ref2] - Transcriptome analysis in LCLs from an affected individual suggested dysregulation of genes relevant to neuronal development (eg. LAMP, ITGA, etc) and GO analysis suggested enrichment for pathways possibly linked to the observed phenotypes [Ref2]. - Discussed in both Refs1/2, homozygous Mn1-ko mice display abnormal skull bone development and die at/shortly after birth as a result of cleft palate. Heterozygous Mn1-ko mice display hypoplastic membranous bones of the cranial skeleton and cleft palate (CP), the latter with incomplete penetrance [Meester-Smoor et al 2005 - PMID: 15870292]. This is thus compatible with the cranial shape defects observed in C-terminal truncations (while CP has been reported in gene deletions, bifid uvula was reported once in C-terminal and N-terminal truncating variants, in the latter case with submucous CP). ----- The phenotype of other MN1 variants is discussed by Mak et al (Ref1) : - 3 individuals with MN1 N-terminal truncating variants (eg. Ser179*, Pro365Thrfs*120, Ser472*) presented speech delay, mild conductive hearing loss and facial features different from C-terminal truncations. None of these individuals had significant ID. - Microdeletions: One individual (#27) with 130 kb deletion harboring only MN1, presented microcephaly, DD and ID and mildly dysmorphic facial features. Deletions spanning MN1 and other genes (eg a 1.17 Mb deletion in ind. #28) and relevant cases from the literature reviewed, with mild DD/ID, variable palatal defects and/or facial dysmorphisms (distinct from the C-terminal truncating variants) among the frequent findings. [Please consider inclusion in other possibly relevant gene panels eg. for hearing loss (conductive/sensorineural in 16/20 reported by Mak et al) or craniosynostosis, etc]. Sources: Literature |
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| Intellectual disability - microarray and sequencing v2.1135 | SLC5A6 |
Konstantinos Varvagiannis changed review comment from: SLC5A6 encodes the sodium dependent multivitamin transporter (SMVT), a transporter of biotin, pantothenate and lipoate. The transporter has a major role in vitamin uptake in the digestive system (among others is the sole transporter for intestinal uptake of biotin which is not synthesized and but must be obtained from exogenous sources) as well as transport across the blood-brain barrier (SMVT being responsible for 89% of biotin transport) [several refs provided by Subramanian et al and Byrne et al]. 4 affected individuals from 3 families have been reported. Subramanian et al (2017 - PMID: 27904971) et al reported on a girl with feeding difficulties and failure to thrive (requiring nasogastric tube placement), microcephaly, DD (at 15m developmental age corresponding to 6m with features suggestive of spastic cerebral palsy), occurrence of multiple infections, osteoporosis and pathologic bone fractures. MRIs suggested brain atrophy, thin CC and hypoplasia of the pons. Metabolic (AA, OA) investigations and array-CGH were normal. Whole exome sequencing revealed presence of a missense (Arg123Leu - RefSeq not provided) and a nonsense (Arg94Ter) SLC5A6 variant. Serum biotin was normal although - at the time - the child was on parenteral and G-T nutrition. Following administration of biotin, pantothenic acid and lipoic acid the child demonstrated among others improved motor and verbal skills, head growth and normalization of immunoglobulin levels. Transfection of mutants in human derived intestinal HuTu-80 cells and brain U87 cells was carried out and a 3H-biotin assay showed no induction in biotin uptake confirming impaired functionality of the transporter. While wt protein displayed normal expression/membrane localization, Arg94Ter was poorly expressed with ectopic localization (cytoplasm). Arg123Leu was retained predominantly intracellularly, probably in the ER as was further supported by colocalization with DsRed-ER. Evidence from the literature is provided that deficiencies of the specific vitamins explain the clinical features (DD, microcephaly, immunological defect, osteopenia, etc). Schwantje et al (2019 - PMID: 31392107) described a girl with severe feeding problems, vomiting with blood (suspected Mallory-Weiss syndrome), poor weight gain and delayed gross motor development. The child presented an episode of gastroenteritis associated with reduced consciousness, circulatory insufficiency and metabolic derangement (hypoglycemia, severe metabolic acidosis, hyperammonemia, mild lactate elevation, ketonuria). Investigations some months prior to the admission (?) were suggestive of a metabolic disorder due to elevated plasma C3-carnitine, C5-OH-carnitine and elevated urinary excretion of 3-OH-isovaleric acid (biotinidase deficiency was considered in the DD but enzymatic activity was only marginally decreased). Biotin supplementation was initiated. Trio-exome sequencing (at 3yrs) demonstrated compound heterozygosity for 2 frameshift variants [NM_021095.2:c.422_423del / p.(Val141Alafs*34) and c.1865_1866del]. Following this result, increase of biotin supplementation and introduction of pantothenic acid, GI symptoms (incl. chronic diarrhea) resolved and the child displayed improved appetite and growth, yet a stable motor delay. The authors cite previous studies of conditional ko mice, displaying intestinal mucosal abnormalities and growth defects (similar to the child's problems), prevented by biotin and pantothenic acid supplementation. Byrne et al (2019 - PMID: 31754459) reported on a sibling pair with severe motor/speech developmental regression following a plateau (at 12m and 14m), development of ataxia and dyskinetic movements (both), seizures (one). Feeding difficulties, reflux and failure to thrive required N-G/gastrostomy feeding while both presented GI hemorrhage (in the case of the older sib, lethal). Other features in the youngest sib included brain MRI abnormalities (cerebral/cerebellar atrophy, thin CC, etc) and IgG deficiency. Biochemical, single-gene testing and mtDNA sequencing were not diagnostic. Exome in one, revealed presence of a frameshift [c.422_423del as above] and a missense variant (Arg400Thr). Sanger sequencing confirmed variants in both sibs and heterozygosity in parents. HeLa cells transfected with empty vector, wt or mut expression constructs confirmed significantly decreased 3H-biotin uptake for mut constructs compared to wt (and similar to empty vector). Parenteral triple vitamin replacement at the age of ~7 years resulted in improved overall condition, regain of some milestones, attenuation of vomiting, and resolution of peripheral neuropathy. Seizure were well-controlled (as was the case before treatment) despite persistence of epileptiform discharges. Again the authors cite studies of conditional (intestine-specific) SLC5A6 ko mice, with those viable (~1/3) demonstrating growth retardation, decreased boned density and GI abnormalities (similar to affected individuals). The phenotype could be rescued by oversupplementation of biotin and pantothenic acid (PMIDs cited: 23104561, 29669219). [Please consider inclusion in other relevant panels eg. metabolic disorders] Sources: Literature; to: SLC5A6 encodes the sodium dependent multivitamin transporter (SMVT), a transporter of biotin, pantothenate and lipoate. The transporter has a major role in vitamin uptake in the digestive system (among others is the sole transporter for intestinal uptake of biotin which is not synthesized but must be obtained from exogenous sources) as well as transport across the blood-brain barrier (SMVT being responsible for 89% of biotin transport) [several refs provided by Subramanian et al and Byrne et al]. 4 affected individuals from 3 families have been reported. Subramanian et al (2017 - PMID: 27904971) et al reported on a girl with feeding difficulties and failure to thrive (requiring nasogastric tube placement), microcephaly, DD (at 15m developmental age corresponding to 6m with features suggestive of spastic cerebral palsy), occurrence of multiple infections, osteoporosis and pathologic bone fractures. MRIs suggested brain atrophy, thin CC and hypoplasia of the pons. Metabolic (AA, OA) investigations and array-CGH were normal. Whole exome sequencing revealed presence of a missense (Arg123Leu - RefSeq not provided) and a nonsense (Arg94Ter) SLC5A6 variant. Serum biotin was normal although - at the time - the child was on parenteral and G-T nutrition. Following administration of biotin, pantothenic acid and lipoic acid the child demonstrated among others improved motor and verbal skills, head growth and normalization of immunoglobulin levels. Transfection of mutants in human derived intestinal HuTu-80 cells and brain U87 cells was carried out and a 3H-biotin assay showed no induction in biotin uptake confirming impaired functionality of the transporter. While wt protein displayed normal expression/membrane localization, Arg94Ter was poorly expressed with ectopic localization (cytoplasm). Arg123Leu was retained predominantly intracellularly, probably in the ER as was further supported by colocalization with DsRed-ER. Evidence from the literature is provided that deficiencies of the specific vitamins explain the clinical features (DD, microcephaly, immunological defect, osteopenia, etc). Schwantje et al (2019 - PMID: 31392107) described a girl with severe feeding problems, vomiting with blood (suspected Mallory-Weiss syndrome), poor weight gain and delayed gross motor development. The child presented an episode of gastroenteritis associated with reduced consciousness, circulatory insufficiency and metabolic derangement (hypoglycemia, severe metabolic acidosis, hyperammonemia, mild lactate elevation, ketonuria). Investigations some months prior to the admission (?) were suggestive of a metabolic disorder due to elevated plasma C3-carnitine, C5-OH-carnitine and elevated urinary excretion of 3-OH-isovaleric acid (biotinidase deficiency was considered in the DD but enzymatic activity was only marginally decreased). Biotin supplementation was initiated. Trio-exome sequencing (at 3yrs) demonstrated compound heterozygosity for 2 frameshift variants [NM_021095.2:c.422_423del / p.(Val141Alafs*34) and c.1865_1866del]. Following this result, increase of biotin supplementation and introduction of pantothenic acid, GI symptoms (incl. chronic diarrhea) resolved and the child displayed improved appetite and growth, yet a stable motor delay. The authors cite previous studies of conditional ko mice, displaying intestinal mucosal abnormalities and growth defects (similar to the child's problems), prevented by biotin and pantothenic acid supplementation. Byrne et al (2019 - PMID: 31754459) reported on a sibling pair with severe motor/speech developmental regression following a plateau (at 12m and 14m), development of ataxia and dyskinetic movements (both), seizures (one). Feeding difficulties, reflux and failure to thrive required N-G/gastrostomy feeding while both presented GI hemorrhage (in the case of the older sib, lethal). Other features in the youngest sib included brain MRI abnormalities (cerebral/cerebellar atrophy, thin CC, etc) and IgG deficiency. Biochemical, single-gene testing and mtDNA sequencing were not diagnostic. Exome in one, revealed presence of a frameshift [c.422_423del as above] and a missense variant (Arg400Thr). Sanger sequencing confirmed variants in both sibs and heterozygosity in parents. HeLa cells transfected with empty vector, wt or mut expression constructs confirmed significantly decreased 3H-biotin uptake for mut constructs compared to wt (and similar to empty vector). Parenteral triple vitamin replacement at the age of ~7 years resulted in improved overall condition, regain of some milestones, attenuation of vomiting, and resolution of peripheral neuropathy. Seizure were well-controlled (as was the case before treatment) despite persistence of epileptiform discharges. Again the authors cite studies of conditional (intestine-specific) SLC5A6 ko mice, with those viable (~1/3) demonstrating growth retardation, decreased boned density and GI abnormalities (similar to affected individuals). The phenotype could be rescued by oversupplementation of biotin and pantothenic acid (PMIDs cited: 23104561, 29669219). [Please consider inclusion in other relevant panels eg. metabolic disorders] Sources: Literature |
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| Intellectual disability - microarray and sequencing v2.1135 | SLC5A6 |
Konstantinos Varvagiannis gene: SLC5A6 was added gene: SLC5A6 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: SLC5A6 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: SLC5A6 were set to 27904971; 31392107; 31754459; 23104561; 29669219 Phenotypes for gene: SLC5A6 were set to Feeding difficulties; Failure to thrive; Global developmental delay; Developmental regression; Intellectual disability; Seizures; Microcephaly; Cerebral atrophy; Abnormality of the corpus callosum; Vomiting; Chronic diarrhea; Gastrointestinal hemorrhage; Abnormal immunoglobulin level; Osteopenia; Abnormality of metabolism/homeostasis Penetrance for gene: SLC5A6 were set to Complete Review for gene: SLC5A6 was set to GREEN Added comment: SLC5A6 encodes the sodium dependent multivitamin transporter (SMVT), a transporter of biotin, pantothenate and lipoate. The transporter has a major role in vitamin uptake in the digestive system (among others is the sole transporter for intestinal uptake of biotin which is not synthesized and but must be obtained from exogenous sources) as well as transport across the blood-brain barrier (SMVT being responsible for 89% of biotin transport) [several refs provided by Subramanian et al and Byrne et al]. 4 affected individuals from 3 families have been reported. Subramanian et al (2017 - PMID: 27904971) et al reported on a girl with feeding difficulties and failure to thrive (requiring nasogastric tube placement), microcephaly, DD (at 15m developmental age corresponding to 6m with features suggestive of spastic cerebral palsy), occurrence of multiple infections, osteoporosis and pathologic bone fractures. MRIs suggested brain atrophy, thin CC and hypoplasia of the pons. Metabolic (AA, OA) investigations and array-CGH were normal. Whole exome sequencing revealed presence of a missense (Arg123Leu - RefSeq not provided) and a nonsense (Arg94Ter) SLC5A6 variant. Serum biotin was normal although - at the time - the child was on parenteral and G-T nutrition. Following administration of biotin, pantothenic acid and lipoic acid the child demonstrated among others improved motor and verbal skills, head growth and normalization of immunoglobulin levels. Transfection of mutants in human derived intestinal HuTu-80 cells and brain U87 cells was carried out and a 3H-biotin assay showed no induction in biotin uptake confirming impaired functionality of the transporter. While wt protein displayed normal expression/membrane localization, Arg94Ter was poorly expressed with ectopic localization (cytoplasm). Arg123Leu was retained predominantly intracellularly, probably in the ER as was further supported by colocalization with DsRed-ER. Evidence from the literature is provided that deficiencies of the specific vitamins explain the clinical features (DD, microcephaly, immunological defect, osteopenia, etc). Schwantje et al (2019 - PMID: 31392107) described a girl with severe feeding problems, vomiting with blood (suspected Mallory-Weiss syndrome), poor weight gain and delayed gross motor development. The child presented an episode of gastroenteritis associated with reduced consciousness, circulatory insufficiency and metabolic derangement (hypoglycemia, severe metabolic acidosis, hyperammonemia, mild lactate elevation, ketonuria). Investigations some months prior to the admission (?) were suggestive of a metabolic disorder due to elevated plasma C3-carnitine, C5-OH-carnitine and elevated urinary excretion of 3-OH-isovaleric acid (biotinidase deficiency was considered in the DD but enzymatic activity was only marginally decreased). Biotin supplementation was initiated. Trio-exome sequencing (at 3yrs) demonstrated compound heterozygosity for 2 frameshift variants [NM_021095.2:c.422_423del / p.(Val141Alafs*34) and c.1865_1866del]. Following this result, increase of biotin supplementation and introduction of pantothenic acid, GI symptoms (incl. chronic diarrhea) resolved and the child displayed improved appetite and growth, yet a stable motor delay. The authors cite previous studies of conditional ko mice, displaying intestinal mucosal abnormalities and growth defects (similar to the child's problems), prevented by biotin and pantothenic acid supplementation. Byrne et al (2019 - PMID: 31754459) reported on a sibling pair with severe motor/speech developmental regression following a plateau (at 12m and 14m), development of ataxia and dyskinetic movements (both), seizures (one). Feeding difficulties, reflux and failure to thrive required N-G/gastrostomy feeding while both presented GI hemorrhage (in the case of the older sib, lethal). Other features in the youngest sib included brain MRI abnormalities (cerebral/cerebellar atrophy, thin CC, etc) and IgG deficiency. Biochemical, single-gene testing and mtDNA sequencing were not diagnostic. Exome in one, revealed presence of a frameshift [c.422_423del as above] and a missense variant (Arg400Thr). Sanger sequencing confirmed variants in both sibs and heterozygosity in parents. HeLa cells transfected with empty vector, wt or mut expression constructs confirmed significantly decreased 3H-biotin uptake for mut constructs compared to wt (and similar to empty vector). Parenteral triple vitamin replacement at the age of ~7 years resulted in improved overall condition, regain of some milestones, attenuation of vomiting, and resolution of peripheral neuropathy. Seizure were well-controlled (as was the case before treatment) despite persistence of epileptiform discharges. Again the authors cite studies of conditional (intestine-specific) SLC5A6 ko mice, with those viable (~1/3) demonstrating growth retardation, decreased boned density and GI abnormalities (similar to affected individuals). The phenotype could be rescued by oversupplementation of biotin and pantothenic acid (PMIDs cited: 23104561, 29669219). [Please consider inclusion in other relevant panels eg. metabolic disorders] Sources: Literature |
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| Intellectual disability - microarray and sequencing v2.1098 | TMX2 |
Konstantinos Varvagiannis gene: TMX2 was added gene: TMX2 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: TMX2 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: TMX2 were set to 31586943; 31270415 Phenotypes for gene: TMX2 were set to Global developmental delay; Intellectual disability; Seizures; Microcephaly; Abnormal cortical gyration Penetrance for gene: TMX2 were set to Complete Review for gene: TMX2 was set to AMBER Added comment: PMID: 31586943 - Ghosh et al. 2019 - reported on 8 individuals from 4 consanguineous families from the Middle East and Central Asia, all with a phenotype of DD/ID, seizures and microcephaly with lissencephaly (microlissencephaly is the term applying to the combination of two) upon brain MRI. All patients were investigated by exome sequencing and the variant localized within a region of ROH which was common to all 4 families. All were homozygous for a TMX2 missense variant (NM_001144012.2:c.500G>A or p.Arg167Gln / NM_015959.4:c.614G>A p.Arg205Gln or hg38 - Chr11:g.57739039G>A). The variant was considered to be the best candidate, upon review of all other homozygous ones. Sanger sequencing confirmed homozygosity for the variant in affected subjects, with additional compatible segregation studies including parents in all families as well as unaffected sibs (in two families). Despite presence of the same mutation in all, several proximal to this variant SNPs did not appear to be shared among the families studied, thus suggesting that the variant had arisen within different haplotype blocks. The authors comment that the variant was not previously identified in public databases. (The variant seems to correspond to rs370455806, present in 10 htz individuals in gnomAD, as well as in the GME database [GME Genotype Count 992:0:1 (hmz?) | Allele Count: 2,1984] . GME includes primarily - although not necessarily - healthy individuals). This SNV affecting the last nucleotide of an exon of several transcripts (correct ref. is NM_001144012.2 as appears in the supplement / using NM_001347898.1 as in the fig./text the variant would lie within an intron), an eventual splicing effect was studied. mRNA transcript levels were assessed following RT-PCR using different sets of primers. There was no evidence of novel splice isoforms but mRNA levels were reduced compared to controls (15-50% in affected individuals, to a lesser level in carriers). This led to the hypothesis that NMD of an aberrantly spliced mRNA might apply, although this was not proven. TMX2 encodes a protein disulfide isomerase (PDI). PDIs are transmembrane ER proteins which have a critical role in protein folding (PMID cited: 12670024). There were no relevant studies carried out in the article. As for animal models, the authors comment that mice homozygous for null mutations display preweaning lethality with complete penetrance.(http://www.informatics.jax.org/diseasePortal/popup?isPhenotype=true&markerID=MGI:1914208&header=mortality/aging). ------- Previously, Schot el al. (ESHG Conference 2018 Oral Presentation - Mutations in the thioredoxin related gene TMX2 cause primary microcephaly, polymicrogyria and severe neurodegeneration with impaired mitochondrial energy metabolism - available in PMID: 31270415 / https://www.nature.com/articles/s41431-019-0407-4 ) reported on 7 individuals from 5 unrelated families with biallelic TMX2 mutations. A newborn with microcephaly, polymicrogyria who died of refractory epilepsy, was compound heterozygous for 2 TMX2 variants. 6 additional individuals (from 4 unrelated families) with similar phenotype were found to harbor biallelic TMX2 mutations. It was commented that TMX2 is enriched in mitochondria-associated membrane of the ER with a role in ER stress protection and regulation of neuronal apoptosis. In line with this, fibroblasts from 2 unrelated patients showed secondary OXPHOS deficiency and increased glycolytic activity (the latter possibly as a compensatory mechanism). ------- There is no associated phenotype in OMIM/G2P/SysID. ------- Overall this gene could be considered for inclusion in the ID/epilepsy panel probably with amber (/red) rating pending further evidence. Sources: Literature |
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| Intellectual disability - microarray and sequencing v2.1098 | KCNT2 |
Konstantinos Varvagiannis gene: KCNT2 was added gene: KCNT2 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: KCNT2 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown Publications for gene: KCNT2 were set to 29069600; 29740868 Phenotypes for gene: KCNT2 were set to ?Epileptic encephalopathy, early infantile 57, MIM 617771 Penetrance for gene: KCNT2 were set to unknown Review for gene: KCNT2 was set to GREEN Added comment: Heterozygous pathogenic KCNT2 variants cause ?Epileptic encephalopathy, early infantile, 57 (MIM 617771). At least 3 unrelated affected individuals have been reported : - PMID: 29069600 - Gururaj et al. 2017 : a male child with EOEE (hypotonia, profound DD and intractable infantile seizures) due to a de novo KCNT2 missense variant (NM_001287819.1:c.720T>A or p.Phe240Leu) identified by exome sequencing. - PMID: 29740868 - Ambrosino et al. 2018 : A girl with phenotype corresponding to West syndrome later evolving to Lennox-Gastaut syndrome. At the age of 9 years the girl displayed severe ID. Trio exome sequencing revealed a de novo missense KCNT2 variant (NM_001287820.2:c.569G>A or p.Arg190His). A 14 y.o. female recruited through the DDD study with phenotype corresponding to epilepsy of infancy with migrating focal seizures. The girl had poor language development and severe learning disability. Infective and metabolic causes were initially ruled out. Trio exome sequencing revealed a de novo missense SNV (c.569G>C or Arg190Pro). Overall KCNT2 has been commented to contribute to a phenotypic spectrum similar and overlapping to that of KCNT1 (Ambrosino et al.). [KCNT1 is rated green in both epilepsy and ID panels]. KCNT2 was recently included in the epilepsy panel as green (functional studies summarized in the respective reviews). The gene was also recently added to G2P, associated with 'Developmental and infantile epileptic encephalopathy'. It is not commonly included in gene panels for ID offered by diagnostic laboratories. As a result, KCNT2 could be considered for inclusion in the ID panel with green (or amber) rating. Sources: Literature |
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| Intellectual disability - microarray and sequencing 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 |
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| Intellectual disability - microarray and sequencing v2.1047 | METTL5 |
Konstantinos Varvagiannis gene: METTL5 was added gene: METTL5 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: METTL5 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: METTL5 were set to 29302074; http://doi.org/10.1016/j.ajhg.2019.09.007; https://imgc2019.sciencesconf.org/data/abstract_book_complete.pdf Phenotypes for gene: METTL5 were set to Delayed speech and language development; Intellectual disability; Microcephaly; Behavioral abnormality Penetrance for gene: METTL5 were set to Complete Review for gene: METTL5 was set to GREEN Added comment: [1] - PMID: 29302074 : In a WES/WGS study of 404 consanguineous families with two or more offspring affected by ID, Hu et al. identified two sibs homozygous for a METTL5 missense variant [NM_014168:c.182G>A / p.Gly61Asp]. These 2 subjects, born to first cousin parents from Iran, presented with early learning impairment, aggressive behaviour, severe microcephaly (-7SD and -8SD) and ID formally evaluated to be in the severe range. Sanger confirmation of variants and segregation studies were performed for all available and informative members in families participating in the study. In silico predictions were all in favour of a deleterious effect (PolyPhen2, MutationTaster, SIFT, CADD) and the variant was absent from ExAC. The effect of the specific variant was studied in ref. 2 (below). [2] - DOI: 10.1016/j.ajhg.2019.09.007 : Richard et al. (2019) reported on 5 additional individuals from 2 consanguineous families. Common phenotype consisted of speech delay, moderate/severe ID (4/4), microcephaly (4/4 - though milder than in the first report), behavioral problems (ADHD, aggressiveness, autistic feat.) and possibly some overlapping facial features (nose and ear abnormalities). 3 sibs from the 1st family, from Pakistan, were homozygous for a frameshift variant (NM_014167.2:c.344_345delGA / p.Arg115Asnfs*19) while sibs from the 2nd family, from Yemen, were homozygous for p.Lys191Valfs*1 (c.571_572delAA). Confirmation and segregation studies supported a role for the variants. The authors performed additional studies for METTL5 and all 3 variants reported to date, notably: - Based on RNA-seq data from the Allen Brain Atlas, METTL5 is expressed in the developing and adult human brain (incl. cerebellar cortex, hippocampus and striatum). - Immunostaining in mouse brain demonstrated ubiquitous expression (postnatal day 30). - In rat hippocampal neurons, enrichment of METTL5 was found in the soma, the nucleus and pre- and post- synaptic regions. - Myc-/GFP-tagged METTL5 wt or mutants were transiently expressed in COS7 cells, and were found in the cytoplasm and nucleus. Levels of the 2 frameshift variants were significantly reduced compared with wt, although this was not the case for Gly61Asp. - Upon transfection of rat hippocampal neurons, METTL5-GFP tagged wt and mt proteins showed similar localicalization in nucleus and dendrites. - Western blot on HEK293T cells transfected with Myc-METTL5 wt or mt constructs demonstrated decreased amounts for the frameshift (but not the missense) variants while comparison after addition of a proteasome inhibitor or cyclohexamide suggested that this is not probably due to decreased mutant protein - rather than mRNA (NMD) - stability. - In zebrafish, morpholino knockdown of mettl5 led to reduced head size and head/body ratio (reproducing the microcephaly phenotype) and curved tails. Forebrain and midbrain sizes were also significantly reduced. Based on the ACMG criteria, Gly61Asp is classified as VUS (PM2, PP1, PP3) and the frameshift ones as pathogenic (PS3, PM2, PM4, PP1, PP3). The authors comment that METTL5 is an uncharacterized member of the methyltransferase superfamily (of 33 METTL proteins). Variants in other methyltransferase-like genes (mainly METTL23) have been associated with ID, while various histone-/DNA-/tRNA-/rRNA- methyltransferases such as EHMT1, DNMT3A, NSUN2, FTSJ1, etc have been implicated in ID. Given the role of methyltransferases in neurodevelopment and neuroplasticity, homology comparisons suggesting presence of relevant domain in METTL5 and accumulation of the protein in the nucleus, a role as epigenetic regulator is proposed (see also ref. 3). [3] - Conference abstract by Helmut et al. ["A novel m6A RNA methyltransferase in mammals - characterization of Mettl5 mutant mice in the German Mouse Clinic" - Oral presentation in the 33rd International Mammalian Genome Conference Sept. 2019 - available at : https://imgc2019.sciencesconf.org/data/abstract_book_complete.pdf ] The group using an in vitro methyltransferase assay, identified METTL5 as a m6A RNA methyltransferase. Generation of Mettl5-knockout mice using the CRISPR/Cas technology, suggested that homozygous mice are subviable, with lower body mass and abnormal growth of nasal bones in half. Homozygous mice were hypoactive and hypoexploratory during an open field test at the age of 8 weeks, while further alterations were observed in neurological functions. Phenotypic deviations were absent or very mild in heterozygous animals. As a result, the mouse model appeared to recapitulate relevant human phenotypes (microcephaly, ID and growth retardation). ---- There is no associated entry in OMIM (neither for the gene nor for a related disorder). G2P does not list any phenotype for this gene, either. METTL5 is included in the SysID database as a current primary ID gene (cited: 27457812, 28097321 / Given the shared co-authors with the study by Richard et al. as well as the overlapping variants, these articles probably report on the same individuals recently described in more detail). The gene is included in gene panels for ID offered by some diagnostic laboratories (eg. GeneDx). ---- Overall, METTL5 could be considered for inclusion in the ID panel probably as green (3 families, 3 variants, segregation, suggested role of the gene, relevant expression patterns, some evidence at the variant-level, zebrafish and mouse models) or amber (underlying effect of Gly61Asp unknown and variant classified as VUS). Sources: Literature |
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| Intellectual disability - microarray and sequencing v2.1046 | PMPCB |
Konstantinos Varvagiannis changed review comment from: Biallelic pathogenic PMPCB variants cause, Multiple mitochondrial dysfunctions syndrome 6 (MIM 617954). 5 relevant individuals from 4 unrelated families (in one case consanguineous) have been reported by Vögtle et al. (2018 - PMID: 29576218). Onset of symptoms (eg. hypotonia) often preceded a period of developmental regression/stagnation which was common in all individuals and occurred within the first 2 years of life, usually following febrile illness. In all cases neurological features were severe (lack of ambulation/speech). Seizures were observed in 4 individuals from 3 families, with onset at the age of 11-24m. MRI images demonstrated T2 signal hyperintensities of the basal ganglia with cerebellar and cerebral atrophy in some. Deterioration with early death was reported on three occasions, though some years after symptom onset. Following exclusion of other diagnoses in some cases (eg. aCGH, epilepsy panel), WES identified biallelic PMPCB missense variants, supported by Sanger confirmation and segregation studies. The following variants were reported (NM_004279.2): - c.523C>T (p.Arg175Cys) in trans with c.601G>C (p.Ala201Pro) [Fam A and B] - c.524G>A (p.Arg175His) in trans with c.530T>G (p.Val177Gly) [Fam C] - c.1265T>C (p.Ile422Thr) in homozygous state [Fam D with 2 affected sibs] The gene encodes the catalytic (beta) subunit of the mitochondrial processing protease (MPP) which is responsible for the cleavage/maturation of nuclear-encoded mitochondrial precursor proteins after their import in mitochondria. The alpha subunit is encoded by PMPCA (green rating proposed for this panel). Extensive studies demonstrated (perhaps a better summary provided by OMIM): - Reduced PMPCB protein levels in mitochondria isolated from patient fibroblasts or patient-derived pluripotent stem cells. - Frataxin maturation was impaired with accumulation of the intermediate form and lower amounts of mature FXN, indicating decrease in MPP activity. - Analysis of the homologous Mas1 S. cerevisiae mutants was carried out, with the exception of Ile422Thr (corresponding to Mas1 - Ile398Thr), the introduction of which did not yield viable yiest strains. Homologous mutations led to a temperature-sensitive phenotype with accumulation of immature/unprocessed precursor proteins and decrease of mature/processed forms both in vivo or in organello (following isolation of mitochondria). Under conditions of heat stress, Mas1 mutations decreased biogenesis of Fe-S clusters. - Respiratory chain complexes I-III contain Fe-S clusters. In muscle biopsy from an affected individual, complex II activity was significantly reduced (although this was not the case in fibroblasts or liver biopsy). Dysfunction of mitochondrial and cytosolic Fe-S cluster-dependent enzymes (eg. aconitase) was also shown in muscle tissue. Regression/stagnation with seizures/non-achievement of milestones may justify testing for an ID / epilepsy gene panel. In addition, metabolic studies or mitochondrial respiratory chain complex studies were sometimes non-informative (lactate elevated in 3/5 subjects) or not carried out at all / in relevant tissues (muscle biopsy in 2 individuals, fibroblasts/liver biopsy did not demonstrate reduced complex activity when tested). PMPCB is included in the ID gene panel of Radboudumc, as well as the SysID database. The gene is included in the DD panel of G2P associated with "Neurodegeneration in Early Childhood" (disease confidence : probable). As a result, PMPCB can be considered for inclusion in both epilepsy and ID panels as green (or amber). Sources: Literature, Radboud University Medical Center, Nijmegen; to: Biallelic pathogenic PMPCB variants cause, Multiple mitochondrial dysfunctions syndrome 6 (MIM 617954). 5 relevant individuals from 4 unrelated families (in one case consanguineous) have been reported by Vögtle et al. (2018 - PMID: 29576218). Onset of symptoms (eg. hypotonia) often preceded a period of developmental regression/stagnation which was common in all individuals and occurred within the first 2 years of life, usually following febrile illness. In all cases neurological features were severe (lack of ambulation/speech). Seizures were observed in 4 individuals from 3 families, with onset at the age of 11-24m. MRI images demonstrated T2 signal hyperintensities of the basal ganglia with cerebellar and cerebral atrophy in some. Deterioration with early death was reported on three occasions, though some years after symptom onset. Following exclusion of other diagnoses in some cases (eg. aCGH, epilepsy panel), WES identified biallelic PMPCB missense variants, supported by Sanger confirmation and segregation studies. The following variants were reported (NM_004279.2): - c.523C>T (p.Arg175Cys) in trans with c.601G>C (p.Ala201Pro) [Fam A and B] - c.524G>A (p.Arg175His) in trans with c.530T>G (p.Val177Gly) [Fam C] - c.1265T>C (p.Ile422Thr) in homozygous state [Fam D with 2 affected sibs] The gene encodes the catalytic (beta) subunit of the mitochondrial processing protease (MPP) which is responsible for the cleavage/maturation of nuclear-encoded mitochondrial precursor proteins after their import in mitochondria. The alpha subunit is encoded by PMPCA (green rating proposed for this panel). Extensive studies demonstrated (perhaps a better summary provided by OMIM): - Reduced PMPCB protein levels in mitochondria isolated from patient fibroblasts or patient-derived pluripotent stem cells. - Frataxin maturation was impaired with accumulation of the intermediate form and lower amounts of mature FXN, indicating decrease in MPP activity. - Analysis of the homologous Mas1 S. cerevisiae mutants was carried out, with the exception of Ile422Thr (corresponding to Mas1 - Ile398Thr), the introduction of which did not yield viable yeast strains. Homologous mutations led to a temperature-sensitive phenotype with accumulation of immature/unprocessed precursor proteins and decrease of mature/processed forms both in vivo or in organello (following isolation of mitochondria). Under conditions of heat stress, Mas1 mutations decreased biogenesis of Fe-S clusters. - Respiratory chain complexes I-III contain Fe-S clusters. In muscle biopsy from an affected individual, complex II activity was significantly reduced (although this was not the case in fibroblasts or liver biopsy). Dysfunction of mitochondrial and cytosolic Fe-S cluster-dependent enzymes (eg. aconitase) was also shown in muscle tissue. Regression/stagnation with seizures/non-achievement of milestones may justify testing for an ID / epilepsy gene panel. In addition, metabolic studies or mitochondrial respiratory chain complex studies were sometimes non-informative (lactate elevated in 3/5 subjects) or not carried out at all / in relevant tissues (muscle biopsy in 2 individuals, fibroblasts/liver biopsy did not demonstrate reduced complex activity when tested). PMPCB is included in the ID gene panel of Radboudumc, as well as the SysID database. The gene is included in the DD panel of G2P associated with "Neurodegeneration in Early Childhood" (disease confidence : probable). As a result, PMPCB can be considered for inclusion in both epilepsy and ID panels as green (or amber). Sources: Literature, Radboud University Medical Center, Nijmegen |
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| Intellectual disability - microarray and sequencing v2.1046 | PMPCB |
Konstantinos Varvagiannis gene: PMPCB was added gene: PMPCB was added to Intellectual disability. Sources: Literature,Radboud University Medical Center, Nijmegen Mode of inheritance for gene: PMPCB was set to BIALLELIC, autosomal or pseudoautosomal Phenotypes for gene: PMPCB were set to Multiple mitochondrial dysfunctions syndrome 6, 617954 Penetrance for gene: PMPCB were set to Complete Review for gene: PMPCB was set to GREEN gene: PMPCB was marked as current diagnostic Added comment: Biallelic pathogenic PMPCB variants cause, Multiple mitochondrial dysfunctions syndrome 6 (MIM 617954). 5 relevant individuals from 4 unrelated families (in one case consanguineous) have been reported by Vögtle et al. (2018 - PMID: 29576218). Onset of symptoms (eg. hypotonia) often preceded a period of developmental regression/stagnation which was common in all individuals and occurred within the first 2 years of life, usually following febrile illness. In all cases neurological features were severe (lack of ambulation/speech). Seizures were observed in 4 individuals from 3 families, with onset at the age of 11-24m. MRI images demonstrated T2 signal hyperintensities of the basal ganglia with cerebellar and cerebral atrophy in some. Deterioration with early death was reported on three occasions, though some years after symptom onset. Following exclusion of other diagnoses in some cases (eg. aCGH, epilepsy panel), WES identified biallelic PMPCB missense variants, supported by Sanger confirmation and segregation studies. The following variants were reported (NM_004279.2): - c.523C>T (p.Arg175Cys) in trans with c.601G>C (p.Ala201Pro) [Fam A and B] - c.524G>A (p.Arg175His) in trans with c.530T>G (p.Val177Gly) [Fam C] - c.1265T>C (p.Ile422Thr) in homozygous state [Fam D with 2 affected sibs] The gene encodes the catalytic (beta) subunit of the mitochondrial processing protease (MPP) which is responsible for the cleavage/maturation of nuclear-encoded mitochondrial precursor proteins after their import in mitochondria. The alpha subunit is encoded by PMPCA (green rating proposed for this panel). Extensive studies demonstrated (perhaps a better summary provided by OMIM): - Reduced PMPCB protein levels in mitochondria isolated from patient fibroblasts or patient-derived pluripotent stem cells. - Frataxin maturation was impaired with accumulation of the intermediate form and lower amounts of mature FXN, indicating decrease in MPP activity. - Analysis of the homologous Mas1 S. cerevisiae mutants was carried out, with the exception of Ile422Thr (corresponding to Mas1 - Ile398Thr), the introduction of which did not yield viable yiest strains. Homologous mutations led to a temperature-sensitive phenotype with accumulation of immature/unprocessed precursor proteins and decrease of mature/processed forms both in vivo or in organello (following isolation of mitochondria). Under conditions of heat stress, Mas1 mutations decreased biogenesis of Fe-S clusters. - Respiratory chain complexes I-III contain Fe-S clusters. In muscle biopsy from an affected individual, complex II activity was significantly reduced (although this was not the case in fibroblasts or liver biopsy). Dysfunction of mitochondrial and cytosolic Fe-S cluster-dependent enzymes (eg. aconitase) was also shown in muscle tissue. Regression/stagnation with seizures/non-achievement of milestones may justify testing for an ID / epilepsy gene panel. In addition, metabolic studies or mitochondrial respiratory chain complex studies were sometimes non-informative (lactate elevated in 3/5 subjects) or not carried out at all / in relevant tissues (muscle biopsy in 2 individuals, fibroblasts/liver biopsy did not demonstrate reduced complex activity when tested). PMPCB is included in the ID gene panel of Radboudumc, as well as the SysID database. The gene is included in the DD panel of G2P associated with "Neurodegeneration in Early Childhood" (disease confidence : probable). As a result, PMPCB can be considered for inclusion in both epilepsy and ID panels as green (or amber). Sources: Literature, Radboud University Medical Center, Nijmegen |
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| Intellectual disability - microarray and sequencing v2.1046 | PMPCA |
Konstantinos Varvagiannis gene: PMPCA was added gene: PMPCA was added to Intellectual disability. Sources: Literature,Radboud University Medical Center, Nijmegen Mode of inheritance for gene: PMPCA was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: PMPCA were set to 25808372; 26657514; 27148589; 30617178 Phenotypes for gene: PMPCA were set to Spinocerebellar ataxia, autosomal recessive 2 (MIM 213200) Penetrance for gene: PMPCA were set to Complete Review for gene: PMPCA was set to GREEN gene: PMPCA was marked as current diagnostic Added comment: Biallelic pathogenic PMPCA variants cause Spinocerebellar ataxia, autosomal recessive 2 (SCAR2 - MIM 213200). More than 20 individuals from several unrelated families have been reported. At least 6 different pathogenic variants have been identified. Loss of PMPCA function is the suggested mechanism. ID is a feature of the disorder. PMPCA encodes the α-subunit of mitochondrial processing peptidase (αMPP), a heterodimeric enzyme responsible for the cleavage of nuclear-encoded mitochondrial precursor proteins after import in the mitochondria (summary by Jobling et al and OMIM). Arguments for involvement of the gene include the highly similar phenotype, segregation studies, expression of the gene in fetal and relevant adult tissues (in brain/cerebellum/cerebellar vermis), lower protein levels demonstrated for some variants, abnormal processing of frataxin (in line with the role of αMPP) demonstrated in most cases, rescue of the maturation defect upon transduction of wt PMPCA cDNA, disruption of REDOX balance in patient cells, etc. Relevant studies are summarized below. PMPCA is included in gene panels for ID offered by several diagnostic laboratories (incl. Radboud UMC, GeneDx, etc) and listed as a confirmed ID gene in SysID. It is not associated with any phenotype in G2P. As a result, this gene can be considered for inclusion in the current panel probably as green (or amber). ---- [1] - Jobling et al. (2015 - PMID: 25808372) described the phenotype of 17 individuals from 4 families, all presenting with non-progressive cerebellar ataxia and the majority with ID of variable severity (15/17 - relevant to the current panel). Individuals from 3 of the families - all of Lebanese origin - were homozygous for NM_015160.3:c.1129G>A (p.Ala377Thr). A further similarly affected subject was compound heterozygous for c.287C>T (p.Ser96Leu) and c.1543G>A (p.Gly515Arg). The homozygous variant in the first family was found within a 2.85 Mb linkage region on chr 9q34. An additional variant within this region (in CAMSAP1) was discarded following results in other families of the same origin. Semi-quantitative RT-PCR demonstrated fetal expression of the PMPCA as well as relatively higher expression in adult brain, cerebellum and cerebellar vermis. As for Ala377Thr, protein levels were shown to be lowest in affected individuals (LCLs, fibroblasts) and low - though somewhat higher - in carrier parents (LCL) compared to controls. RT-PCR on total RNA from LCLs did not show evidence of abnormal transcripts/additional splicing defect. Localization of mutant protein and morphology of mitochondrial reticulum was similar to controls. Maturation of frataxin - the protein depleted in Friedreich ataxia - was shown to be abnormal in patient lymphoblasts, compatible with the role of αMPP. In line with abnormal mitochondrial function, REDOX balance was increased in patient cells. [2] - Choquet et al. (2016 - PMID: 26657514) reported on 2 sibs - born to distantly related parents. The authors noted a phenotype corresponding to SCAR2 although the presentation was somewhat milder, intellectual disability was not a feature (despite some learning difficulties in one) and ataxia was progressive. WES demonstrated homozygosity for NM_015160:c.766G>A (p.Val256Met). Western blot in patient lymphoblasts showed αMPP levels similar to carriers and controls. Abnormal maturation (accumulation of specific isoforms) was shown for frataxin. [3] - Joshi et al. (2016 - PMID: 27148589) described the phenotype of 2 cousins belonging to a large Lebanese pedigree. Presentation in both was compatible with multisystem involvement incl. profound global DD, severe hypotonia, weakness, respiratory insufficiency, blindness suggestive of mitochondrial disorder. mtDNA, analyses of mitochondrial focused nuclear gene panel and aCGH were non-diagnostic. Both subjects were compound heterozygous for NM_015160.3:c.1066G>A (p.Gly356Ser) and c.1129G>A (p.Ala377Thr) following WES, with compatible segregation studies within the family. Western blot revealed PMPCA levels similar to control. Reduction of PMPCA staining and abnormally enlarged mitochondria were observed upon immunofluorescence in patient fibroblasts. Frataxin processing was abnormal. Lentiviral transduction of patient fibroblasts with wt PMPCA cDNA, led to increased PMPCA levels and correction of frataxin processing. [4] - Rubegni et al. (2019 - PMID: 30617178) report on a 7-y.o. boy with global DD, spastic-ataxic gait and 'low IQ'. MRI images were suggestive of cerebellar atrophy with hyperintensity in the striatum. The child was homozygous for c.553C>T / p.Arg185Trp (reference not specified, although the variant would be compatible with NM_015160.3). Sources: Literature, Radboud University Medical Center, Nijmegen |
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| Intellectual disability - microarray and sequencing v2.1046 | TIMM50 |
Konstantinos Varvagiannis gene: TIMM50 was added gene: TIMM50 was added to Intellectual disability. Sources: Literature,Radboud University Medical Center, Nijmegen Mode of inheritance for gene: TIMM50 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: TIMM50 were set to 27573165; 30190335; 31058414; Serajee et al. (ASHG conference 2015 - abstract Nr. 2299T) Phenotypes for gene: TIMM50 were set to 3-methylglutaconic aciduria, type IX (MIM 617698) Penetrance for gene: TIMM50 were set to Complete Review for gene: TIMM50 was set to GREEN gene: TIMM50 was marked as current diagnostic Added comment: Biallelic pathogenic TIMM50 variants cause 3-methylglutaconic aciduria, type IX (MIM 617698). At least 9 affected individuals from 5 unrelated (but often consanguineous) families of variable origin have been reported (based on a conference abstract and PMIDs : 27573165, 30190335, 31058414). TIMM50 encodes encodes a subunit of the mitochondrial presequence import machinery called the TIM23 complex. TIMM50 serves as a major receptor in the intermembrane space that binds to proteins on their way to cross the mitochondrial inner membrane (summary by Shahrour et al., 2017 and OMIM). The highly overlapping patient clinical features [seizures, DD and ID - the latter in all age-appropriate individuals (5 from 3 families - refs 2,4)], metabolic investigations (lactate elevations in many, elevated urinary 3MGA in almost all, variable mitochondrial complex deficiencies in some), additional extensive functional evidence of mitochondrial dysfunction or the similar phenotypes in other types of 3-methylglutaconic aciduria all support a role for the gene. [AUH- / CLPB- / DNAJC19- / HTRA2- / OPA3- / SERAC1-related methylglutaconic acidurias are all included as relevant disorders in the ID panel, with the respective genes rated green.] TIMM50 is included in gene panels for ID offered by some diagnostic laboratories (incl. Radboudumc and GeneDx). The gene is not associated with any phenotype in G2P As a result this gene could be considered for inclusion/upgrade as green in both ID and epilepsy panels respectively. --------- [1] - Serajee et al. (ASHG conference 2015 - abstract Nr. 2299T) reported on a patient born to consanguineous parents of South Asian ancestry with intractable epilepsy, microcephaly, DD and spastic quadriplegia. Metabolic investigations revealed increased urinary 3MGA. Two similarly affected sisters with demonstrated increase of 3MGA, were deceased following an infection. WES in the affected child, 2 unaffected sibs and the parents suggested a homozygous missense variant as the likely cause of the disorder in the proband (c.1114G>A / p.G372S - Reference not specified though the variant probably corresponds to ENST00000314349.4 and ClinVar's entry VCV000208697.1 - www.ncbi.nlm.nih.gov/clinvar/variation/208697/). [2] - Shahroor et al. (2017, PMID: 27573165) reported on 2 consanguineous families, each with 2 affected individuals. Two sibs from the 1st family (of Bedouin origin) presented with seizures (onset at 3m and 4m respectively), DD and ID with slightly elevated plasma lactate and increased urinary 3MGA upon metabolic investigations. Enzymatic activities of mitochondrial complex I-V were carried out for 1 sib and were normal also after normalization for citrate synthase. Following a SNP array, WES was carried out in affected children and their parents. Both sibs were homozygous for a missense SNV [NM_001001563.1:c.755C>T / p.Thr252Met]. Segregation studies - also in 3 unaffected sibs - supported a role for the variant. Two sibs from the 2nd family (of Muslim origin) presented with seizures (myoclonic jerks at 3m, generalized tonic movements at 2m - respectively) with DD and ID. Urinary 3MGA was elevated for both, with CSF lactate also elevated in one. WES revealed homozygosity for p.Arg217Trp (NM_001001563.1:c.649C>T) and segregation studies in parents and an unaffected sib were again compatible. The authors could not demonstrate pathogenicity of the variants in a yeast based system although - as also commented on in Ref 4 - the human TIMM50 could not rescue the yeast ΔΤim50 growth defect and global conservation between the two proteins is poor. [3] - Reyes et al. (2018, PMID: 30190335) reported on one individual with onset of infantile spasms at the age of 2m with hypsarrythmia upon EEG and psychomotor regression. Leigh-like features were noted upon brain MRI. Lactate was elevated in both plasma and CSF. Urinary 3MGA was normal. WES, Sanger confirmation and segregation studies demonstrated compound htz for 2 variants (NM_001001563:c.335C>A or p.S112* and c.569G>C or p.G190A). Functional studies demonstrated among others decrease in all components of the TIM23 complex and decreased mitochondrial membrane potential. Patient fibroblasts grown in glucose had lower levels of all complex II and IV subunits and one complex I subunit (due to the impairment in import system) with decreased mitochondrial respiration and increase in ROS production. Growth in galactose - shifting energy production toward OxPhos - caused massive cell death. The phenotype was rescued/substantially improved following complementation of patient fibroblasts with wt TIMM50. [4] - Tort et al. (2019, PMID: 31058414) reported on a boy with seizures and ID (diagnosis of West syndrome), Leigh-like MRI anomalies, cardiomyopathy with elevated plasma and CSF lactate and persistent urinary elevation of 3MGA. The proband was found to be compound heterozygous for 2 TIMM50 variants [NM_001001563.5:c.341 G>A (p.Arg114Gln) in trans with c.805 G>A (p.Gly269Ser)] following WES and Sanger confirmation/segregation studies. In patient fibroblasts TIMM50 protein levels were severely reduced upon WB although mRNA levels were similar to control. Muscle biopsy revealed decreased activity of the complexes I-IV, when normalized to the citrate synthase activity. Accumulation of lipidic material in muscle fibers was shown to be associated with mitochondria upon EM. Expression and sublocalization of mitochondria-targeted proteins were not found to be affected in patient fibroblasts. In extracts from muscle biopsy reduced protein levels of SDHA, COX4L and MTCO1 were demonstrated, in line with the disruptions in the activities of the MRC. Mitochondrial morphology and network were shown to be altered in patient fibroblasts. Patient fibroblasts showed marked reduction of max respiratory capacity. Similar reduction was noted in CRISPR/Cas9 generated TIMM50-ko HEK293T cells, but rescued upon transient transfection with a plasmid encoding for wt TIMM50. (Functional studies better summarized in the respective articles). Sources: Literature, Radboud University Medical Center, Nijmegen |
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| Intellectual disability - microarray and sequencing v2.853 | AP2M1 |
Konstantinos Varvagiannis gene: AP2M1 was added gene: AP2M1 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: AP2M1 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown Publications for gene: AP2M1 were set to 31104773 Phenotypes for gene: AP2M1 were set to Generalized hypotonia; Global developmental delay; Intellectual disability; Seizures; Ataxia; Autistic behavior Penetrance for gene: AP2M1 were set to Complete Review for gene: AP2M1 was set to GREEN Added comment: Helbig et al. (2019 - PMID: 31104773) report on 4 individuals with developmental and epileptic encephalopathy due to a recurrent de novo AP2M1 missense variant (NM_004068.3:c.508C>T or p.Arg170Trp). Seizure types included atonic, myoclonic-atonic, absence seizures (with or without eyelid myoclonia), tonic-clonic etc. Hypotonia, developmental delay (prior to the onset of seizures at 1y 3m to 4y) and intellectual disability were observed in all four. Other features included ataxia (3/4) or autism spectrum disorder (2/4). AP2M1 encodes the μ-subunit of the adaptor protein complex 2 (AP-2). AP2M1 is highly expressed in the CNS. The AP-2 complex is involved in clathrin-mediated endocytosis at the plasma mebrane of neurons and non-neuronal cells. This mechanism is important for recycling synaptic vesicle components at mammalian central synapses. Previous evidence suggests regulation of GABA and/or glutamate receptors at the neuronal surface by AP-2 (several references provided by Helbig et al.). The authors provide evidence for impaired (reduced) clathrin-mediated endocytosis of transferrin in AP-2μ-depleted human HeLa cells upon plasmid-based re-expression of the Arg170Trp variant compaired to re-expression of WT. A similar defect was demonstrated upon comparison of the same process when WT and Arg170Trp re-expression was studied in primary astrocytes from conditional AP-2μ knockout mice. Expression levels, protein stability, membrane recruitment and localization of the AP-2 complex in clathrin-coated pits were similar for the Arg170Trp variant and WT. As a result, the effect of the specific variant is suggested to be mediated by alteration of the AP-2 complex function (/impaired recognition of cargo membrane proteins) rather than haploinsufficiency. AP2M1 is highly intolerant to missense / LoF variants with z-score and pLI in ExAC of 5.82 and 0.99 respectively. As the authors discuss, heterozygous Ap2m1 mutant mice do not have an apparent phenotype. Homozygous mutant mice die before day 3.5 postcoitus, suggesting a critical role in early embryonic development (PMID 16227583 cited) AP2M1 is currently not associated with any phenotype in OMIM / G2P. As a result, this gene can be considered for inclusion in the epilepsy and ID panels probably as green (4 individuals with highly similar phenotype of DEE, relevance of phenotype and/or degree of ID, functional studies, etc) rather than amber (single recurrent variant - although this is also the case for other genes rated green). Sources: Literature |
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| Intellectual disability - microarray and sequencing v2.800 | ZNF142 |
Konstantinos Varvagiannis gene: ZNF142 was added gene: ZNF142 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: ZNF142 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: ZNF142 were set to 31036918 Phenotypes for gene: ZNF142 were set to Global developmental delay; Intellectual disability; Seizures; Tremor; Dystonia Penetrance for gene: ZNF142 were set to unknown Review for gene: ZNF142 was set to GREEN Added comment: Khan et al. (2019 - PMID: 31036918) describe the phenotype of 7 females from 4 families, harboring biallelic likely pathogenic ZNF142 variants. Overlapping features included cognitive impairment (ID in 6/7 from 3 families, borderline intellectual functioning was reported one occasion), speech impairement and motor impairment (7/7), and variably penetrant seizures (5/7), tremor (4/7) and dystonia (3/7). Most individuals (5/7) had experienced at least one episode of seizures (tonic-clonic) though seizures were recurrent in 3 sibs. Other disorders with ID (eg. Angelman syndrome, Rett syndrome, chromosomal disorders) or movement disorders as a feature were previously ruled out for many subjects. 6 individuals were homozygous or compound heterozygous for LoF (stopgain or frameshift) variants. One individual harbored 2 missense SNVs in the compound heterozygous state. Variants reported include (NM_001105537.2): c. 817_818delAA (p.Lys273Glufs*32), c.1292delG (p.Cys431Leufs*11), c.3175C>T (p.Arg1059*), c.4183delC (p.Leu1395*), c.3698G>T (p.Cys1233Phe), c.4498C>T (p.Arg1500Trp) with the LoF variants predicted to result in NMD. Expression or functional studies were not carried out. ZNF142 encodes a C2H2 domain-containing transcription factor. Mutations in other zinc finger proteins (ZNF/zfp) have been reported in several neurodevelopmental disorders impacting the CNS (eg. ZBTB20 and ZBTB11 heterozygous and biallelic mutations, respectively) and/or presenting with movement disorders among their manifestations (eg. YY1). As the authors comment, homozygous ablation of the orthologous (Zfp142) locus in mice results in behavioral and neurological phenotypes [MGI ref.ID: J:211773 cited - http://www.informatics.jax.org/marker/reference/J:211773 (though Zfp142 or its locus do not seem to appear in the list)]. ZNF142 is not - at least commonly - included in gene panels for ID offered by diagnostic laboratories. It is not associated with any phenotype in OMIM, nor in G2P. As a result, this gene can be considered for inclusion in the current panel as probably as green (individuals from 3 families, appropriate degree of ID for the current panel) or amber (if further evidence would be required). Sources: Literature |
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| Intellectual disability - microarray and sequencing v2.621 | PUS3 |
Konstantinos Varvagiannis edited their review of gene: PUS3: Added comment: PMID: 30697592 reports 2 additional individuals with intellectual disability, leukoencephalopathy and adult onset nephropathy. These individuals harbored 2 missense variants in the compound heterozygous state (c.497G>A - p.Arg166Gln and c.1097T>C - p.Leu366Pro - Ref. sequence not mentioned). As a result amber/green rating could be considered.; Changed publications: 27055666, 30308082, 30697592 |
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| Intellectual disability - microarray and sequencing v2.621 | PUS3 |
Konstantinos Varvagiannis edited their review of gene: PUS3: Added comment: PMID: 30697592 reports 2 additional individuals with intellectual disability, leukoencephalopathy and adult onset nephropathy. These individuals harbored 2 missense variants in the compound heterozygous state (c.497G>A - p.Arg166Gln and c.1097T>C - p.Leu366Pro - Ref. sequence not mentioned). As a result amber/green rating could be considered.; Changed publications: 30697592 |
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| Intellectual disability - microarray and sequencing 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 ------------ 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 |
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| Intellectual disability - microarray and sequencing v2.588 | ZNF462 |
Konstantinos Varvagiannis gene: ZNF462 was added gene: ZNF462 was added to Intellectual disability. Sources: Literature,Radboud University Medical Center, Nijmegen Mode of inheritance for gene: ZNF462 was set to MONOALLELIC, autosomal or pseudoautosomal, imprinted status unknown Publications for gene: ZNF462 were set to 28513610; 29427787; 14564155; 12825074 Phenotypes for gene: ZNF462 were set to Ptosis; Prominent metopic ridge; Craniosynostosis; Global developmental delay; Intellectual disability; Autistic behavior Penetrance for gene: ZNF462 were set to unknown Review for gene: ZNF462 was set to AMBER gene: ZNF462 was marked as current diagnostic Added comment: Weiss et al. (PMID: 28513610) report on 8 individuals (from 6 unrelated families) with heterozygous pathogenic variants affecting ZNF462. Frequent features included ptosis metopic ridging, craniosynostosis, dysgenesis of corpus callosum. DD (with or without ASD) was a feature in 4 (4/8), one of whom was reported to present mild ID. 4 LoF mutations as well as 2 9q31.2 deletions spanning also other genes are reported [NM_021224.4]: Fam. 1 - c.3787C>T p.(Arg1263*) (familial) - Normal development in all 3 family members Fam. 2 - c.2979_2980delinsA p.(Val994Trpfs*147) (de novo) - DD Fam. 3 - c.4263delA p.(Glu1422Serfs*6) (de novo) - DD Fam. 4 - Chr9:g.(108940763-110561397)del (hg19) (de novo) - Normal development Fam. 5- Chr9:g(108464368-110362345)del (hg19) (de novo) - DD with mild ID Fam. 6 - c.5145delC p.(Tyr1716Thrfs*28) (de novo) - DD There were no expression/functional studies performed although haploinsufficiency can be presumed based on these variants (ZNF462 has a pLI of 1 in ExAC). ----------- Cosemans et al. (PMID: 29427787) report on an individual investigated - among others - for mild ID and ASD. This individual harbored a de novo (complex) translocation disrupting ZNF462 and KLF12. As this subject presented similar features to those reported by Weiss et al. (eg. craniofacial anomalies, abn. development, ASD) and given that KLF12 is not associated with any disorder, the phenotype of this individual was thought to be secondary to disruption of ZNF462. Details on this patient - before delineation of the translocation breakpoints - were provided previously by Fryns and Hendrickx ( PMID:9297446). ----------- Cited by the previous article, a further case of ZNF462 disruption due to translocation was previously published in the literature (same individual - Talisetti et al. PMID: 14564155 / Ramocki et al. PMID: 12825074). Profound ID was among the features of this individual although the translocation disrupted also a further ID gene (ASXL2). ----------- In ClinVar 8 variants have been submitted as pathogenic/likely pathogenic although a phenotype is provided only for 3 variants published by Weiss et al.(submitting lab participating in PMID: 28513610 / SCV000494060.1 corresp. to Fam.1 / SCV000494061.1 - Fam.2 / SCV000494062.1 - Fam. 3). ----------- Several individuals with de novo coding variants in ZNF462 have been reported in the context of larger cohorts (some with ID as a principal feature). http://denovo-db.gs.washington.edu/denovo-db/QueryVariantServlet?searchBy=Gene&target=ZNF462 ----------- In Decipher apart from the DDD study participants DDD4K.03663 and DDD4K.03792 (appearing in the denovo-db) with LoF and abnormality of the nervous system, several further individuals have been submitted. 2 of these subjects, harbored a de novo LoF (submitted as pathogenic) and had ID as a feature. ---------- ZNF462 is included in the DD panel of G2P, associated with Craniofacial anomalies, corpus callosum dysgenesis, ptosis, and developmental delay [Disease confidence: probable / Global DD (but not ID) among the phenotypes assigned to this entry]. This gene is not associated with any phenotype in OMIM. ---------- ZNF462 is included in gene panels for ID offered by diagnostic laboratories (incl. Radboudumc). ---------- As a result this gene can be considered for inclusion in the ID panel probably as amber (or green if the current evidence is thought to be sufficient). Sources: Literature, Radboud University Medical Center, Nijmegen |
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| Intellectual disability - microarray and sequencing v2.584 | PITRM1 |
Konstantinos Varvagiannis gene: PITRM1 was added gene: PITRM1 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: PITRM1 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: PITRM1 were set to 26697887; 29764912; 29383861 Phenotypes for gene: PITRM1 were set to Intellectual disability; Ataxia Penetrance for gene: PITRM1 were set to Complete Review for gene: PITRM1 was set to GREEN gene: PITRM1 was marked as current diagnostic Added comment: Biallelic pathogenic variants in PITRM1 seem to be associated with a phenotype of DD/ID and spinocerebellar ataxia. 6 individuals from 3 unrelated families have been reported. PMID: 26697887 reports on 2 individuals from a consanguineous Norwegian family homozygous for a missense variant (NM_014889.2:c.548G> or p.Arg183Gln). PMID: 29764912 reports on 2 consanguineous Palestinian families each with 2 affected boys. All affected individuals for both families were homozygous for a further missense variant (p.Thr931Met). The boys from one Palestinian family appeared to be more severely affected - compared to the sibs from the other family with the same variant - due to a concurrent X-chromosome rearrangement. Pathogenicity is supported by extensive functional studies performed in both articles as well as an additional one (PMID: 29383861) on Arg183Gln. PITRM1 is included in gene panels for ID offered by (few) diagnostic laboratories. The gene is not associated with any phenotype in OMIM nor in G2P. As a result, PITRM1 can be considered for inclusion in the ID panel as green (or amber). Sources: Literature |
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| Intellectual disability - microarray and sequencing v2.551 | NUDT2 |
Konstantinos Varvagiannis gene: NUDT2 was added gene: NUDT2 was added to Intellectual disability. Sources: Literature,Expert Review Mode of inheritance for gene: NUDT2 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: NUDT2 were set to 27431290; 30059600 Phenotypes for gene: NUDT2 were set to Muscular hypotonia; Global developmental delay; Intellectual disability Penetrance for gene: NUDT2 were set to Complete Review for gene: NUDT2 was set to AMBER Added comment: PMID: 27431290 reports briefly on 2 sibs from a consanguineous Saudi family, as part of a cohort of 337 patients investigated for intellectual disability. Both were homozygous for a nonsense NUDT2 mutation [NM_001161.4:c.34C>T or p.Arg12Ter / rs148119952]. The common features included hypotonia, global developmental delay (first words at 2.5 years, sitting at 2-2.5 years,walking achieved by 4 years - valid for both sibs) and intellectual disability. No other candidate variants were found in the exome. PMID: 30059600 is a further report on 5 individuals from 3 consanguineous families from Saudi Arabia. All presented with low birth weight and height, poor suck, hypotonia, motor and language delay and borderline intelligence. All patients were homozygous for the same nonsense variant (Arg12Ter) which seems to be a founder mutation in Saudi Arabia. As truncating NUDT2 variants have a combined allele frequency of 0.02% in gnomAD (no homozygotes in the database) the authors comment that most of the other LoF variants observed are in the second - and last - exon of the gene (thus probably escaping NMD) and downstream of its catalytic domain. As a result this gene can be considered for inclusion in the ID panel probably as amber (single founder mutation - the degree of intellectual disability appears to be more severe in the first report but borderline in the subsequent) or green. Sources: Literature, Expert Review |
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| Intellectual disability - microarray and sequencing v2.468 | ARG1 | Louise Daugherty Source Victorian Clinical Genetics Services was added to ARG1. | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Intellectual disability - microarray and sequencing | ARG1 | BRIDGE consortium edited their review of ARG1 | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Intellectual disability - microarray and sequencing | ARG1 | BRIDGE consortium edited their review of ARG1 | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| Intellectual disability - microarray and sequencing | ARG1 | BRIDGE consortium reviewed ARG1 | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||