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Intellectual disability - microarray and sequencing v5.451 | MADD | Sarah Leigh Phenotypes for gene: MADD were changed from Neurodevelopmental disorder with dysmorphic facies, impaired speech and hypotonia, 619005; DEEAH syndrome, 619004 to DEEAH syndrome, OMIM:619004; deeah syndrome, MONDO:0033561: Neurodevelopmental disorder with dysmorphic facies, impaired speech and hypotonia, OMIM:619005; neurodevelopmental disorder with dysmorphic facies, impaired speech, and hypotonia, MONDO:0033562 | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v5.442 | MADD | Sarah Leigh edited their review of gene: MADD: Added comment: Comments from Karen Stals (Royal Devon and Exeter Hospital), 4 Dec 2023: Apnoea a presenting feature in 13/14 patients with MADD-related disorder with biallelic MADD variants in Schneeberger et al 2020 PMID: 32761064. Identified biallelic variants in this gene in a patient with a consistent phenotype.; Changed rating: GREEN; Changed publications to: 32761064 | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v3.1593 | ALKBH8 |
Konstantinos Varvagiannis edited their review of gene: ALKBH8: Added comment: Please consider upgrade to green rating. 2 additional relevant families reported in literature, as summarized below. While affected individuals from 3 (of the 4 total) families with the disorder were homozygous for truncating variants in the last exon (potentially corresponding to hypomorphic / incomplete LoF rather than null alleles), a more recent publication describes 2 sibs homozygous for a missense SNV with demonstrated loss-of-function in the context of normal protein levels. ----- Saad et al (2020 - PMID: 33544954) report 2 sibs, born to consanguineous parents from Egypt homozygous for an ALKBH8 frameshift variant. Both exhibited global DD and ID (proband IQ of 51 / Stanford Binet test, sib: 42 using Weschler scale). There was no history of seizures. Family based exome sequencing of both sibs and parents revealed homozygosity for NM_001301010.1:c.1684delC [p.(Arg562Alafs*56))] within a region of AOH. As the authors note this variant also occurred in the last exon of the gene, likely escaping NMD and based on previous evidence from Monnies et al, hypothesize that truncating variants in the last exon represent hypomorphic alleles encoding for a partially functional protein, while protein truncating variants in earlier exons may be null alleles. Maddirevula et al (2021 - PMID: 34757492) describe the phenotype of 2 sibs, homozygous for a missense variant. Features included severe DD and ID, microcephaly, facial dysmorphism and epilepsy (the latter limited to the elder one). Exome with autozygome analysis identified homozygosity for a missense variant (NM_138775.2:c.1874G>A / p.Arg625His) with Sanger for confirmation / segregation studies.LC-MS/MS using tRNA isolated from LCLs from the affected individual, a carrier parent and controls revealed complete loss of ALKBH8-dependent tRNA posttranscriptional modifications, the results being suggestive of abrogation of the catalytic activities of both MT and Ox domains. The protein was detected at low levels in LCLs from control and patient samples, a finding that was also supported by immunoblot analysis suggesting that the observed loss-of-function is not mediated by loss of the protein.; Changed rating: GREEN; Changed publications to: 33544954, 34757492 |
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Intellectual disability - microarray and sequencing v3.1561 | CDK9 |
Konstantinos Varvagiannis changed review comment from: There are 4 studies reporting on the phenotype associated with biallelic CDK9 pathogenic variants. DD and ID are part of the phenotype which appears to be relatively consistent. CDK9 encodes Cyclin-dependent kinase 9. There are 4 missense variants reported to date - one of which recurrent (NM_001261.3:c.673C>T / p.Arg225Cys) - with studies for 3 variants suggesting a LoF effect (loss of kinase activity) [Ref4]. Animal models also provide some supporting evidence [discussed Ref4]. Consider inclusion in the current panel (probably with green rating) as well as other possibly relevant ones. Details provided below. [1]----- Shaheen et al (2016 - PMID: 26633546) studied patients with apparently novel phenotypes with positive family history consistent with AR inheritance mode due to consanguinity. After autozygome analysis the authors determined the shared autozygome (ROH >1 Mb / Axiom SNP Chip) in families with multiple affected individuals. This analysis was followed by whole exome/genome sequencing. Using this approach, they managed to map the phenotype of interest to a single novel locus in some families, which was also the case in a large consanguineous family with 2 similarly affected cousins (11DG0424, 11DG1630). Within a 20 Mb region of homozygosity, followed by WES in a single affected individual and Sanger confirmation with compatible segregation studies in parents and 10 unaffected sibs, the authors identified a homozygous CDK9 missense SNV (NM_001261.3:c.673C>T / p.Arg225Cys) responsible for this phenotype. In silico predictions were concordant in favor of a deleterious effect. Features (detailed in the suppl.) included global DD (2/2), severe ID (1/1), cerebral and (mild) cerebellar atrophy (2/2), microcephaly (2/2), ocular anomalies (2/2, coloboma in 2/2, congenital cataract 2/2, etc), heart defects (2/2, PDA in both, ASD), variable genitourinary anomalies (2/2 incl. hydronephrosis, VUR reflux/recurrent UTIs, kidney atrophy, abn. genitalia in 1), abnormalities of the limbs (2/2, bilateral talipes equinovarus : 2/2) or the skeleton (1/2 - butterfly vertebrae). One was reported to have some degree of growth delay (<10th centile for length, <5th for weight and OFC). There was no hearing defect reported (large ears in 1/2). Overall, the authors used the term CHARGE-like phenotype. [2]----- Maddirevula et al (2019 - PMID: 30237576) performed autozygome and exome analysis of individuals with suspected Mendelian disorders. They reported 3 individuals (18DG0161, 18DG0162, 18DG0165) born to 3 different consanguineous families (information in fig2) from Qatar, homozygous for CDK9 p.Arg225Cys. All presented a CHARGE-like phenotype with features ophtalmologic findings (3/3 - abnormal ERG in one, congenital cataracts the other, visual impairment in the 3rd, though NO evidence of coloboma in at least two), heart defect (2/3 had VSD), choanal atresia (3/3), retarded growth/FTT (1/3) or global DD (3/3 - in suppl. table 1), (genito)urinary anomalies (1/3 - dysplastic atrophic kidney) or ear anomalies (3/3 - preauricular tags 2/3, bilateral deafness 1/3, bilat.ossicular anomalies 1/3). Other features incl. epilepsy (2/3), brain MRI abnormalities (2/3), facial asymmetry in one, vertebral segmentation defect in 1/3. [3]----- Hu et al (2019 - PMID: 29302074) performed WES/WGS in 404 consanguineous families from Iran, having 2 or more offspring with ID. In this context they reported 2 females and a male (III:1,4,3 belonging to fam. M9100018 - details in suppl. text) born to first cousin parents from Iran. Features included DD (3/3 - walking at 3y, words at 4y), moderate ID (3/3 - WAIS-IV IQ of 40-43), short stature (3/3 below 3rd %le). Vision and hearing were normal. All three were homozygous for a missense SNV (NM_001261:c.280C>T, p.Arg94Cys) which was ultrarare in ExAC, with severa in silico tools in favor of a deleterious effect. The authors commented that CDK9 is the catalytic core of transcription elongation factor p-TEFb essential for transcription elongation of numerous genes, Cdk9/Cyclin T1 complex may participate in neuronal differentiation, CDK9-cyclinK in maintenance of genomic integrity, with the protein encoded also interacted with AF4/FMR2. In addition the gene was commented to have ubiquitous expression with high protein expression in glial and neuronal cells of the cortex (based on Uniprot and Human Protein Atlas). [4]----- Nishina et al (2021 - PMID: 33640901) described an 8 y.o. male with facial asymmetry, ear/hearing anomalies (microtia, preauricular tags, bilateral hearing loss), ocular/vision anomalies (blepharophimosis, lacrimal obstruction, eyelid dermoids, duane-like anomaly, congenital cataracts, retinal dystrophy), cleft lip and palate, abnormalities of the limbs (finger contractures with associated absence of creases, cutaneous syndactyly, etc). Other features included cardiac dysrhythmia and undescended testes. Development was delayed with associated ID (walking 3y, words 7y, at 10y: could count to 20, 4 word sentences). There was no evidence of coloboma or choanal atresia. Trio exome sequencing revealed that the child was compound htz for 2 missense SNVs (NM_001261.3:c.862G>A / p.Ala288Thr and c.907C>T /p.Arg303Cys) with Sanger confirmation. These were ultrarare/not present in gnomAD. Both lied in the protein kinase catalytic domain of CDK9, with high conservation across different species and in silico predictions in favor of deleterious effect. In vitro studies in HEK293 cells demonstrated that the kinase activity for both variants was significantly reduced compared to wt. Kinase activity was also reduced for the Arg225Cys variant (reported in Refs 1 & 2). The authors briefly discuss evidence from zebrafish (regulates larval morphogenesis incl. brain, heart, eye, blood vessels) and mouse models. In the latter complete LoF is lethal while heterozygous LoF is associated with abnormal morphology of heart, skin and epididymis (PMIDs cited by the authors : 27715402, 30100824). Sources: Literature; to: There are 4 studies reporting on the phenotype associated with biallelic CDK9 pathogenic variants. DD and ID are part of the phenotype which appears to be relatively consistent. CDK9 encodes Cyclin-dependent kinase 9. There are 4 missense variants reported to date - one of which recurrent (NM_001261.3:c.673C>T / p.Arg225Cys) - with studies for 3 variants suggesting a LoF effect (loss of kinase activity) [Ref4]. Animal models also provide some supporting evidence [discussed Ref4]. Consider inclusion in the current panel (probably with green rating) as well as other possibly relevant ones. Details provided below. [1]----- Shaheen et al (2016 - PMID: 26633546) studied patients with apparently novel phenotypes with positive family history consistent with AR inheritance due to consanguinity. Using autozygome analysis the authors determined the shared autozygome (ROH >1 Mb / Axiom SNP Chip) in families with multiple affected individuals. This analysis was followed by whole exome/genome sequencing. Using this approach, they managed to map the phenotype of interest to a single novel locus in some families, which was also the case in a large consanguineous family with 2 similarly affected cousins (11DG0424, 11DG1630). Within a 20 Mb region of homozygosity, followed by WES in a single affected individual and Sanger confirmation with compatible segregation studies in parents and 10 unaffected sibs, the authors identified a homozygous CDK9 missense SNV (NM_001261.3:c.673C>T / p.Arg225Cys) responsible for this phenotype. In silico predictions were concordant in favor of a deleterious effect. Features (detailed in the suppl.) included global DD (2/2), severe ID (1/1), cerebral and (mild) cerebellar atrophy (2/2), microcephaly (2/2), ocular anomalies (2/2, coloboma in 2/2, congenital cataract 2/2, etc), heart defects (2/2, PDA in both, ASD), variable genitourinary anomalies (2/2 incl. hydronephrosis, VUR/recurrent UTIs, kidney atrophy, abn. genitalia in 1), abnormalities of the limbs (2/2, bilateral talipes equinovarus : 2/2) or the skeleton (1/2 - butterfly vertebrae). One was reported to have some degree of growth delay (<10th centile for length, <5th for weight and OFC). There was no hearing defect reported (large ears in one case). Overall, the authors used the term CHARGE-like for this phenotype. [2]----- Maddirevula et al (2019 - PMID: 30237576) performed autozygome and exome analysis of individuals with suspected Mendelian disorders. They reported 3 individuals (18DG0161, 18DG0162, 18DG0165) born to 3 different consanguineous families (information in fig2) from Qatar, homozygous for CDK9 p.Arg225Cys. All presented a CHARGE-like phenotype with ophthalmologic findings (3/3 - abnormal ERG in one, congenital cataracts the other, visual impairment in the 3rd, though NO evidence of coloboma in at least two of them), heart defect (2/3 with VSD), choanal atresia (3/3), retarded growth/FTT (1/3) or global DD (3/3 - in suppl. table 1), (genito)urinary anomalies (1/3 - dysplastic atrophic kidney) or ear anomalies (3/3 - preauricular tags in 2/3, bilateral deafness 1/3, bilateral ossicular anomalies 1/3). Other features incl. epilepsy (2/3), brain MRI abnormalities (2/3), facial asymmetry in one, vertebral segmentation defect in 1/3. [3]----- Hu et al (2019 - PMID: 29302074) performed WES/WGS in 404 consanguineous families from Iran, having 2 or more offspring with ID. In this context they reported 2 females and a male (III:1,4,3 belonging to fam. M9100018 | suppl. text) born to first cousin parents from Iran. Features included DD (3/3 - walking at 3y, words at 4y), moderate ID (3/3 - WAIS-IV IQ of 40-43), short stature (3/3 below 3rd %le). Vision and hearing were normal. All three were homozygous for a missense SNV (NM_001261:c.280C>T, p.Arg94Cys) which was ultrarare in ExAC, with several in silico tools in favor of a deleterious effect. The authors commented that CDK9 is the catalytic core of transcription elongation factor p-TEFb essential for transcription elongation of numerous genes, Cdk9/Cyclin T1 complex may participate in neuronal differentiation, CDK9-cyclinK in maintenance of genomic integrity, with the protein encoded also interacting with AF4/FMR2. In addition the gene was commented to have ubiquitous expression with high protein expression in glial and neuronal cells of the cortex (based on Uniprot and Human Protein Atlas). [4]----- Nishina et al (2021 - PMID: 33640901) described an 8 y.o. male with facial asymmetry, ear/hearing anomalies (microtia, preauricular tags, bilateral hearing loss), ocular/vision anomalies (blepharophimosis, lacrimal obstruction, eyelid dermoids, duane-like anomaly, congenital cataracts, retinal dystrophy), cleft lip and palate, abnormalities of the limbs (finger contractures with associated absence of creases, cutaneous syndactyly, etc). Other features included cardiac dysrhythmia and undescended testes. Development was delayed with ID (walking 3y, words 7y, at 10y: could count to 20, 4 word sentences). There was no evidence of coloboma or choanal atresia. Trio exome revealed that the child was compound htz for 2 missense SNVs (NM_001261.3:c.862G>A / p.Ala288Thr and c.907C>T /p.Arg303Cys) with Sanger confirmation. These were ultrarare/not present in gnomAD. Both lied in the protein kinase catalytic domain of CDK9, with high conservation across different species and in silico predictions in favor of deleterious effect. In vitro studies in HEK293 cells demonstrated that the kinase activity for both variants was significantly reduced compared to wt. Kinase activity was also reduced for the Arg225Cys variant (reported in Refs 1 & 2). The authors briefly discuss evidence from zebrafish (regulates larval morphogenesis incl. brain, heart, eye, blood vessels) and mouse models. In the latter complete LoF is lethal while heterozygous LoF is associated with abnormal morphology of heart, skin and epididymis (PMIDs cited : 27715402, 30100824). Sources: Literature |
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Intellectual disability - microarray and sequencing v3.1561 | CDK9 |
Konstantinos Varvagiannis gene: CDK9 was added gene: CDK9 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: CDK9 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: CDK9 were set to 26633546; 30237576; 29302074; 33640901 Phenotypes for gene: CDK9 were set to Global developmental delay; Intellectual disability; Abnormality of vision; Congenital cataract; Iris coloboma; Abnormal heart morphology; Choanal atresia; Abnormality of the ear; Preauricular skin tag; Hearing impairment; Abnormality of the genitourinary system; Abnormality of limbs; Abnormality of the vertebrae; Abnormality of nervous system morphology; Seizures Penetrance for gene: CDK9 were set to Complete Review for gene: CDK9 was set to GREEN Added comment: There are 4 studies reporting on the phenotype associated with biallelic CDK9 pathogenic variants. DD and ID are part of the phenotype which appears to be relatively consistent. CDK9 encodes Cyclin-dependent kinase 9. There are 4 missense variants reported to date - one of which recurrent (NM_001261.3:c.673C>T / p.Arg225Cys) - with studies for 3 variants suggesting a LoF effect (loss of kinase activity) [Ref4]. Animal models also provide some supporting evidence [discussed Ref4]. Consider inclusion in the current panel (probably with green rating) as well as other possibly relevant ones. Details provided below. [1]----- Shaheen et al (2016 - PMID: 26633546) studied patients with apparently novel phenotypes with positive family history consistent with AR inheritance mode due to consanguinity. After autozygome analysis the authors determined the shared autozygome (ROH >1 Mb / Axiom SNP Chip) in families with multiple affected individuals. This analysis was followed by whole exome/genome sequencing. Using this approach, they managed to map the phenotype of interest to a single novel locus in some families, which was also the case in a large consanguineous family with 2 similarly affected cousins (11DG0424, 11DG1630). Within a 20 Mb region of homozygosity, followed by WES in a single affected individual and Sanger confirmation with compatible segregation studies in parents and 10 unaffected sibs, the authors identified a homozygous CDK9 missense SNV (NM_001261.3:c.673C>T / p.Arg225Cys) responsible for this phenotype. In silico predictions were concordant in favor of a deleterious effect. Features (detailed in the suppl.) included global DD (2/2), severe ID (1/1), cerebral and (mild) cerebellar atrophy (2/2), microcephaly (2/2), ocular anomalies (2/2, coloboma in 2/2, congenital cataract 2/2, etc), heart defects (2/2, PDA in both, ASD), variable genitourinary anomalies (2/2 incl. hydronephrosis, VUR reflux/recurrent UTIs, kidney atrophy, abn. genitalia in 1), abnormalities of the limbs (2/2, bilateral talipes equinovarus : 2/2) or the skeleton (1/2 - butterfly vertebrae). One was reported to have some degree of growth delay (<10th centile for length, <5th for weight and OFC). There was no hearing defect reported (large ears in 1/2). Overall, the authors used the term CHARGE-like phenotype. [2]----- Maddirevula et al (2019 - PMID: 30237576) performed autozygome and exome analysis of individuals with suspected Mendelian disorders. They reported 3 individuals (18DG0161, 18DG0162, 18DG0165) born to 3 different consanguineous families (information in fig2) from Qatar, homozygous for CDK9 p.Arg225Cys. All presented a CHARGE-like phenotype with features ophtalmologic findings (3/3 - abnormal ERG in one, congenital cataracts the other, visual impairment in the 3rd, though NO evidence of coloboma in at least two), heart defect (2/3 had VSD), choanal atresia (3/3), retarded growth/FTT (1/3) or global DD (3/3 - in suppl. table 1), (genito)urinary anomalies (1/3 - dysplastic atrophic kidney) or ear anomalies (3/3 - preauricular tags 2/3, bilateral deafness 1/3, bilat.ossicular anomalies 1/3). Other features incl. epilepsy (2/3), brain MRI abnormalities (2/3), facial asymmetry in one, vertebral segmentation defect in 1/3. [3]----- Hu et al (2019 - PMID: 29302074) performed WES/WGS in 404 consanguineous families from Iran, having 2 or more offspring with ID. In this context they reported 2 females and a male (III:1,4,3 belonging to fam. M9100018 - details in suppl. text) born to first cousin parents from Iran. Features included DD (3/3 - walking at 3y, words at 4y), moderate ID (3/3 - WAIS-IV IQ of 40-43), short stature (3/3 below 3rd %le). Vision and hearing were normal. All three were homozygous for a missense SNV (NM_001261:c.280C>T, p.Arg94Cys) which was ultrarare in ExAC, with severa in silico tools in favor of a deleterious effect. The authors commented that CDK9 is the catalytic core of transcription elongation factor p-TEFb essential for transcription elongation of numerous genes, Cdk9/Cyclin T1 complex may participate in neuronal differentiation, CDK9-cyclinK in maintenance of genomic integrity, with the protein encoded also interacted with AF4/FMR2. In addition the gene was commented to have ubiquitous expression with high protein expression in glial and neuronal cells of the cortex (based on Uniprot and Human Protein Atlas). [4]----- Nishina et al (2021 - PMID: 33640901) described an 8 y.o. male with facial asymmetry, ear/hearing anomalies (microtia, preauricular tags, bilateral hearing loss), ocular/vision anomalies (blepharophimosis, lacrimal obstruction, eyelid dermoids, duane-like anomaly, congenital cataracts, retinal dystrophy), cleft lip and palate, abnormalities of the limbs (finger contractures with associated absence of creases, cutaneous syndactyly, etc). Other features included cardiac dysrhythmia and undescended testes. Development was delayed with associated ID (walking 3y, words 7y, at 10y: could count to 20, 4 word sentences). There was no evidence of coloboma or choanal atresia. Trio exome sequencing revealed that the child was compound htz for 2 missense SNVs (NM_001261.3:c.862G>A / p.Ala288Thr and c.907C>T /p.Arg303Cys) with Sanger confirmation. These were ultrarare/not present in gnomAD. Both lied in the protein kinase catalytic domain of CDK9, with high conservation across different species and in silico predictions in favor of deleterious effect. In vitro studies in HEK293 cells demonstrated that the kinase activity for both variants was significantly reduced compared to wt. Kinase activity was also reduced for the Arg225Cys variant (reported in Refs 1 & 2). The authors briefly discuss evidence from zebrafish (regulates larval morphogenesis incl. brain, heart, eye, blood vessels) and mouse models. In the latter complete LoF is lethal while heterozygous LoF is associated with abnormal morphology of heart, skin and epididymis (PMIDs cited by the authors : 27715402, 30100824). Sources: Literature |
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Intellectual disability - microarray and sequencing v3.1520 | PAN2 |
Konstantinos Varvagiannis gene: PAN2 was added gene: PAN2 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: PAN2 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: PAN2 were set to 29620724; https://doi.org/10.1038/s41431-022-01077-y Phenotypes for gene: PAN2 were set to Global developmental delay; Intellectual disability; Sensorineural hearing impairment; Abnormality of the genitourinary system; Abnormality of the cardiovascular system; Abnormality of blood and blood-forming tissues; EEG abnormality; Seizures; Anorectal anomaly; Abnormality of the skeletal system; Abnormality of the eye; Abnormality of head or neck Penetrance for gene: PAN2 were set to Complete Review for gene: PAN2 was set to AMBER Added comment: 1. Maddirevula et al (2018 - PMID: 29620724) first reported on the phenotype associated with biallelic pathogenic variants in PAN2. This concerned a male (15DG2222) born to consanguineous parents and exhibiting MCA, dysmorphic features and global DD (age of 34 m). Features incl. imperforate anus, metopic craniosynostosis, scoliosis, CHD (PFO, PDA, VSD), renal anomalies (duplicated collecting system) and abnormalities of the eye (posterior embryotoxon, maculopathy). As the other 411 individuals from the cohort, the child had 1st-tier testing genetic testing using a dysmorphology/skeletal dysplasia panel of 296 genes. Subsequent autozygome analysis (Axiom genotyping platform) was used to identify ROH (authors state "segregating within the family", in pedigree the proband was the single affected person and single child). WES revealed a PAN2 indel. [NM_001166279.1:c.3162delC / p.(Ser1055Profs*4)]. There were no additional studies. Role of PAN2 and animal models discussed as below. --- 2. Reuter et al. (2022 - https://doi.org/10.1038/s41431-022-01077-y) describe the phenotype of 5 additional individuals - from 3 unrelated families (2 consanguineous) - harboring biallelic PAN2 variants. The authors review the phenotype of the previously described case. Features included DD (6/6), ID (4/5 with relevant age in the mild-moderate range, 1/5 had borderline IF), sensorineural hearing loss (5/6) and incompletely penetrant congenital anomalies of the heart (4/6 - TOF, septal defects, Ao root dilat), urinary malformations (4/6 - hypoplasia/agenesis, anovesical fistula), ophthalmological anomalies (2/6 - Rieger, posterior embryotoxon, etc). EEG anomalies or seizures were noted in 4/6. Craniofacial feat. in >=2/6 included cleft palate/bifid uvula, ptosis, hypertelorism, abn. of the nose, low-set ears, short neck. There was no comprehensive evaluation for skeletal dysplasia despite short stature/skeletal anomalies in multiple individuals. Hematological anomalies were reported in 2, possibly explained by another concurrent diagnosis (of GSD) in one individual. WGS was performed for 1 individual, and WES for 4 members of the 2nd family and the proband in the 3rd. ROH identified in all 3 families (1 non-consanguineous but from the same region of Italy) are mentioned in the suppl. Sanger sequencing for parents and affected/unaffected sibs was mentioned for the 2 families with solo WGS/WES. One individual had a dual - previously established - diagnosis (of SLC37A4-related GSD) not related to his NDD. There were no other candidate variants except for VUS or variants in 'genes of uncertain significance'. The majority of mammalian mature mRNAs have polyA tails, added during RNA processing. PAN2 encodes a subunit of the Pan2-Pan3 deadenylation complex which shortens mRNA 3' polyA tails, regulating mRNA stability/translation efficiency. Specifically Pan2 is the catalytic subunit, while the interaction with Pan3 mediates efficient mRNA binding. Deadenylation in cytoplasm is mostly carried out by the Pan2-Pan3 or Ccr4-Not compexes. While perturbations of mRNA metabolism/decay are established causes of NDD and ID. In particular, monoallelic variants in genes of Ccr4-Not complex (inc. CNOT1/2/3) already causative of NDDs. All affected individuals were homozygous for pLoF PAN2 variants, namely (NM_001166279.2): c.2335G>T / p.(Glu779*) [Fam1], c.3408dupT / p.(Glu1137*) [Fam2], c.574-2A>G / p.? [Fam3]. Variants were absent from gnomAD (where PAN2 has a pLI:0.94, o/e:0.19). There were no variant studies performed. The splicing variant is predicted in silico to abolish the splice-acceptor site, with in-frame skippling of ex5 which codes a repeat within the WD40 domain. Previous studies in yeast have shown that this domain is important for sensing the length of the polyA tail, with absence of this domain resulting in impaired deadenylation of 90A tails (similarly to complete Pan2 del) [cited PMID: 31104843]. Overall PAN2 loss-of-function is thought to be the underlying disease mechanism. Partial functional redundancy of Pan2/Pan3 (initiation of deadenylation) and Ccr4-Not complexes (further shortening of polyA) is speculated to mitigate consequences of PAN2 LoF in humans. In yeast Pan2Δ, Ccr4Δ and Pan2Δ/Ccr4Δ have been studied with more severe phenotypes in double mutants where ability to shorten mRNA polyA tails was abolished [cited PMID:11239395]. In yeast extracts lacking Pan2p and Pan3p, transcripts were polyadenylated to >90-200 adenosines [cited PMID: 9774670] Mouse mutants (MGI:1918984) had increased heart weight, increased eosinophil cell number while homozygosity for a stopgain allele (by ENU mutagenesis) was shown to result in embyonic lethality. Finally, given the presence of thrombocytopenia and anemia in 3 individuals (2 families) as well as the link between mRNA deadenylation and telomere disease, telomere length analyses from WGS data were performed (TelSeq/Expansion Hunter dn), but there was no evidence for telomeric shortening. --- Currently, there is no PAN2-related phenotype in OMIM/G2P/SysID/PanelApp Australia. --- Consider inclusion in the ID panel with amber rating [>3 individuals/families/variants, though variant studies not performed (NMD/splicing) and authors of 2nd study recognize possibility of additional/concurrent diagnoses in individuals from consanguineous families, possibility of missed dn variants due to singleton WGS/WES in 2 fam. Also the presumed deadenylation defect not studied to date]. Please consider adding this gene to other panels - eg. for sens. hearing loss (5/6 - 3 fam), urinary tract anomalies (4/6 - 4 fam), congenital (4/6 - 3fam), anorectal malformations (2/6 - 2 families, incl. fistula or imperforate anus), clefting (2/6 - 1 fam), hematological disorders, etc. For the time being, not added in epilepsy panel as some individuals had only EEG anomalies, few had also clinical seizures not necessarily requiring treatment. Sources: Literature |
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Intellectual disability - microarray and sequencing v3.1511 | MADD | Arina Puzriakova Mode of inheritance for gene: MADD was changed from to BIALLELIC, autosomal or pseudoautosomal | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v3.1510 | MADD | Arina Puzriakova Tag for-review was removed from gene: MADD. | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v3.1510 | MADD | Sarah Leigh commented on gene: MADD | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v3.1509 | MADD |
Arina Puzriakova Source Expert Review Green was added to MADD. Rating Changed from Amber List (moderate evidence) to Green List (high evidence) |
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Intellectual disability - microarray and sequencing v3.1217 | PIDD1 |
Konstantinos Varvagiannis changed review comment from: There is enough evidence to include this gene in the current panel with green rating. Biallelic PIDD1 pathogenic variants have been reported in 26 individuals (11 families) with DD (all), variable degrees of ID (mild to severe), behavioral (eg. aggression/self-mutilation in several, ADHD) and/or psychiatric abnormalities (ASD, psychosis in 5 belonging to 3 families), well-controlled epilepsy is some (9 subjects from 6 families) and MRI abnormalities notably abnormal gyration pattern (pachygyria with predominant anterior gradient) as well as corpus callosum anomalies (commonly thinning) in several. Dysmorphic features have been reported in almost all, although there has been no specific feature suggested. The first reports on the phenotype associated with biallelic PIDD1 mutations were made by Harripaul et al (2018 - PMID: 28397838) and Hu et al (2019 - PMID: 29302074) [both studies investigating large cohorts of individuals with ID from consanguineous families]. Sheikh et al (2021 - PMID: 33414379) provided details on the phenotype of 15 individuals from 5 families including those from the previous 2 reports and studied provided evidence on the role of PIDD1 and the effect of variants. Zaki et al (2021 - PMID: 34163010) reported 11 additional individuals from 6 consanguineous families, summarize the features of all subjects published in the literature and review the neuroradiological features of the disorder. PIDD1 encodes p53-induced death domain protein 1. The protein is part of the PIDDosome, a multiprotein complex also composed of the bipartite linker protein CRADD (also known as RAIDD) and the proform of caspase-2 and induces apoptosis in response to DNA damage. There are 5 potential PIDD1 mRNA transcript variants with NM_145886.4 corresponding to the longest. Similar to the protein encoded by CRADD, PIDD1 contains a death domain (DD - aa 774-893). Constitutive post-translational processing gives PIDD1-N, PIDD1-C the latter further processed into PIDD1-CC (by auto-cleavage). Serine residues at pos. 446 and 588 are involved in this autoprocessing generating PIDD1-C (aa 446-910) and PIDD1-CC (aa 774-893). The latter is needed for caspase-2 activation. Most (if not all) individuals belonged to consanguineous families of different origins and harbored pLoF or missense variants. Variants reported so far include : c.2587C>T; p.Gln863* / c.1909C>T ; p.Arg637* / c.2443C>T / p.Arg815Trp / c.2275-1G>A which upon trap assay was shown to lead to skipping of ex15 with direct splicing form exon14 to the terminal exon 16 (resulting to p.Arg759Glyfs*1 with exlcusion of the entire DD) / c.2584C>T; p.Arg862Trp / c.1340G>A; p.Trp447* / c.2116_2120del; p.Val706His*, c.1564_1565del; p.Gly602fs*26 Evidence so far provided includes: - Biallelic CRADD variants cause a NDD disorder and a highly similar gyration pattern. - Confirmation of splicing effect (eg. for c.2275-1G>A premature stop in position 760) or poor expression (NM_145886.3:c.2587C>T; p.Gln863*). Arg815Trp did not affect autoprocessing or protein stability. - Abnormal localization pattern, loss of interaction with CRADD and failure to activate caspase-2 (MDM2 cleavage assay) [p.Gln863* and Arg815Trp] - Available expression data from GTEx (PIDD1 having broad expression in multiple tissues, but higher in brain cerebellum) as well as BrainSpan and PsychEncode studies suggesting high coexpression of PIDD1, CRADD and CASP2 in many regions in the developing human brain. - Variants in other genes encoding proteins interacting with PIDD1 (MADD, FADD, DNAJ, etc) are associated with NDD. Pidd-1 ko mice (ex3-15 removal) lack however CNS-related phenotypes. These show decreased anxiety but no motor anomalies. This has also been the case with Cradd-/- mice displaying no significant CNS phenotypes without lamination defects. There is currently no associated phenotype in OMIM, PanelApp Australia. PIDD1 is listed in the DD panel of G2P (PIDD1-relared NDD / biallelic / loss of function / probable) . SysID includes PIDD1 among the current primary ID genes. Overall the gene appears to be relevant for the epilepsy panel, panels for gyration and/or corpus callosum anomalies etc. Sources: Literature, Other; to: There is enough evidence to include this gene in the current panel with green rating. Biallelic PIDD1 pathogenic variants have been reported in 26 individuals (11 families) with DD (all), variable degrees of ID (mild to severe), behavioral (eg. aggression/self-mutilation in several, ADHD) and/or psychiatric abnormalities (ASD, psychosis in 5 belonging to 3 families), well-controlled epilepsy is some (9 subjects from 6 families) and MRI abnormalities notably abnormal gyration pattern (pachygyria with predominant anterior gradient) as well as corpus callosum anomalies (commonly thinning) in several. Dysmorphic features have been reported in almost all, although there has been no specific feature suggested. The first reports on the phenotype associated with biallelic PIDD1 mutations were made by Harripaul et al (2018 - PMID: 28397838) and Hu et al (2019 - PMID: 29302074) [both studies investigating large cohorts of individuals with ID from consanguineous families]. Sheikh et al (2021 - PMID: 33414379) provided details on the phenotype of 15 individuals from 5 families including those from the previous 2 reports and studied provided evidence on the role of PIDD1 and the effect of variants. Zaki et al (2021 - PMID: 34163010) reported 11 additional individuals from 6 consanguineous families, summarize the features of all subjects published in the literature and review the neuroradiological features of the disorder. PIDD1 encodes p53-induced death domain protein 1. The protein is part of the PIDDosome, a multiprotein complex also composed of the bipartite linker protein CRADD (also known as RAIDD) and the proform of caspase-2 and induces apoptosis in response to DNA damage. There are 5 potential PIDD1 mRNA transcript variants with NM_145886.4 corresponding to the longest. Similar to the protein encoded by CRADD, PIDD1 contains a death domain (DD - aa 774-893). Constitutive post-translational processing gives PIDD1-N, PIDD1-C the latter further processed into PIDD1-CC (by auto-cleavage). Serine residues at pos. 446 and 588 are involved in this autoprocessing generating PIDD1-C (aa 446-910) and PIDD1-CC (aa 774-893). The latter is needed for caspase-2 activation. Most (if not all) individuals belonged to consanguineous families of different origins and harbored pLoF or missense variants. Variants reported so far include : c.2587C>T; p.Gln863* / c.1909C>T ; p.Arg637* / c.2443C>T / p.Arg815Trp / c.2275-1G>A which upon trap assay was shown to lead to skipping of ex15 with direct splicing form exon14 to the terminal exon 16 (resulting to p.Arg759Glyfs*1 with exlcusion of the entire DD) / c.2584C>T; p.Arg862Trp / c.1340G>A; p.Trp447* / c.2116_2120del; p.Val706His*, c.1564_1565del; p.Gly602fs*26 Evidence so far provided includes: - Biallelic CRADD variants cause a NDD disorder and a highly similar gyration pattern. - Confirmation of splicing effect (eg. for c.2275-1G>A premature stop in position 760) or poor expression (NM_145886.3:c.2587C>T; p.Gln863*). Arg815Trp did not affect autoprocessing or protein stability. - Abnormal localization pattern, loss of interaction with CRADD and failure to activate caspase-2 (MDM2 cleavage assay) [p.Gln863* and Arg815Trp] - Available expression data from GTEx (PIDD1 having broad expression in multiple tissues, but higher in brain cerebellum) as well as BrainSpan and PsychEncode studies suggesting high coexpression of PIDD1, CRADD and CASP2 in many regions in the developing human brain. - Variants in other genes encoding proteins interacting with PIDD1 (MADD, FADD, DNAJ, etc) are associated with NDD. Pidd-1 ko mice (ex3-15 removal) lack however CNS-related phenotypes. These show decreased anxiety but no motor anomalies. This has also been the case with Cradd-/- mice displaying no significant CNS phenotypes without lamination defects. There is currently no associated phenotype in OMIM, PanelApp Australia. PIDD1 is listed in the DD panel of G2P (PIDD1-related NDD / biallelic / loss of function / probable) . SysID includes PIDD1 among the current primary ID genes. Overall the gene appears to be relevant for the epilepsy panel, panels for gyration and/or corpus callosum anomalies etc. Sources: Literature, Other |
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Intellectual disability - microarray and sequencing v3.1217 | PIDD1 |
Konstantinos Varvagiannis gene: PIDD1 was added gene: PIDD1 was added to Intellectual disability. Sources: Literature,Other Mode of inheritance for gene: PIDD1 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: PIDD1 were set to 28397838; 29302074; 33414379; 34163010 Phenotypes for gene: PIDD1 were set to Global developmental delay; Intellectual disability; Seizures; Autism; Behavioral abnormality; Psychosis; Pachygyria; Lissencephaly; Abnormality of the corpus callosum Penetrance for gene: PIDD1 were set to Complete Review for gene: PIDD1 was set to GREEN Added comment: There is enough evidence to include this gene in the current panel with green rating. Biallelic PIDD1 pathogenic variants have been reported in 26 individuals (11 families) with DD (all), variable degrees of ID (mild to severe), behavioral (eg. aggression/self-mutilation in several, ADHD) and/or psychiatric abnormalities (ASD, psychosis in 5 belonging to 3 families), well-controlled epilepsy is some (9 subjects from 6 families) and MRI abnormalities notably abnormal gyration pattern (pachygyria with predominant anterior gradient) as well as corpus callosum anomalies (commonly thinning) in several. Dysmorphic features have been reported in almost all, although there has been no specific feature suggested. The first reports on the phenotype associated with biallelic PIDD1 mutations were made by Harripaul et al (2018 - PMID: 28397838) and Hu et al (2019 - PMID: 29302074) [both studies investigating large cohorts of individuals with ID from consanguineous families]. Sheikh et al (2021 - PMID: 33414379) provided details on the phenotype of 15 individuals from 5 families including those from the previous 2 reports and studied provided evidence on the role of PIDD1 and the effect of variants. Zaki et al (2021 - PMID: 34163010) reported 11 additional individuals from 6 consanguineous families, summarize the features of all subjects published in the literature and review the neuroradiological features of the disorder. PIDD1 encodes p53-induced death domain protein 1. The protein is part of the PIDDosome, a multiprotein complex also composed of the bipartite linker protein CRADD (also known as RAIDD) and the proform of caspase-2 and induces apoptosis in response to DNA damage. There are 5 potential PIDD1 mRNA transcript variants with NM_145886.4 corresponding to the longest. Similar to the protein encoded by CRADD, PIDD1 contains a death domain (DD - aa 774-893). Constitutive post-translational processing gives PIDD1-N, PIDD1-C the latter further processed into PIDD1-CC (by auto-cleavage). Serine residues at pos. 446 and 588 are involved in this autoprocessing generating PIDD1-C (aa 446-910) and PIDD1-CC (aa 774-893). The latter is needed for caspase-2 activation. Most (if not all) individuals belonged to consanguineous families of different origins and harbored pLoF or missense variants. Variants reported so far include : c.2587C>T; p.Gln863* / c.1909C>T ; p.Arg637* / c.2443C>T / p.Arg815Trp / c.2275-1G>A which upon trap assay was shown to lead to skipping of ex15 with direct splicing form exon14 to the terminal exon 16 (resulting to p.Arg759Glyfs*1 with exlcusion of the entire DD) / c.2584C>T; p.Arg862Trp / c.1340G>A; p.Trp447* / c.2116_2120del; p.Val706His*, c.1564_1565del; p.Gly602fs*26 Evidence so far provided includes: - Biallelic CRADD variants cause a NDD disorder and a highly similar gyration pattern. - Confirmation of splicing effect (eg. for c.2275-1G>A premature stop in position 760) or poor expression (NM_145886.3:c.2587C>T; p.Gln863*). Arg815Trp did not affect autoprocessing or protein stability. - Abnormal localization pattern, loss of interaction with CRADD and failure to activate caspase-2 (MDM2 cleavage assay) [p.Gln863* and Arg815Trp] - Available expression data from GTEx (PIDD1 having broad expression in multiple tissues, but higher in brain cerebellum) as well as BrainSpan and PsychEncode studies suggesting high coexpression of PIDD1, CRADD and CASP2 in many regions in the developing human brain. - Variants in other genes encoding proteins interacting with PIDD1 (MADD, FADD, DNAJ, etc) are associated with NDD. Pidd-1 ko mice (ex3-15 removal) lack however CNS-related phenotypes. These show decreased anxiety but no motor anomalies. This has also been the case with Cradd-/- mice displaying no significant CNS phenotypes without lamination defects. There is currently no associated phenotype in OMIM, PanelApp Australia. PIDD1 is listed in the DD panel of G2P (PIDD1-relared NDD / biallelic / loss of function / probable) . SysID includes PIDD1 among the current primary ID genes. Overall the gene appears to be relevant for the epilepsy panel, panels for gyration and/or corpus callosum anomalies etc. Sources: Literature, Other |
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Intellectual disability - microarray and sequencing v3.393 | MADD | Ivone Leong Tag for-review tag was added to gene: MADD. | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v3.393 | MADD | Ivone Leong Classified gene: MADD as Amber List (moderate evidence) | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v3.393 | MADD | Ivone Leong Added comment: Comment on list classification: Based on expert review provided by Konstantinos Varvagiannis and Zornitza Stark, there is enough evidence to support a gene-disease association. This gene has been promoted from Red to Amber and will be promoted to Green status at next panel review. | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v3.393 | MADD | Ivone Leong Gene: madd has been classified as Amber List (Moderate Evidence). | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v3.392 | MADD | Ivone Leong Publications for gene: MADD were set to | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v3.391 | MADD | Ivone Leong Phenotypes for gene: MADD were changed from to Neurodevelopmental disorder with dysmorphic facies, impaired speech and hypotonia, 619005; DEEAH syndrome, 619004 | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v3.239 | MADD | Konstantinos Varvagiannis reviewed gene: MADD: Rating: GREEN; Mode of pathogenicity: None; Publications: 28940097, 29302074, 32761064; Phenotypes: Global developmental delay / Intellectual disability / Seizures, Global developmental delay / Intellectual disability / Seizures / Abnormality of the endocrine system / Exocrine pancreatic insufficiency / Constipation / Diarrhea / Anemia / Thrombocytopenia / Abnormality of the autonomic nervous system; Mode of inheritance: BIALLELIC, autosomal or pseudoautosomal | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v3.170 | CNPY3 |
Konstantinos Varvagiannis gene: CNPY3 was added gene: CNPY3 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: CNPY3 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: CNPY3 were set to 29394991; 30237576 Phenotypes for gene: CNPY3 were set to Epileptic encephalopathy, early infantile, 60 (MIM 617929) Penetrance for gene: CNPY3 were set to Complete Review for gene: CNPY3 was set to GREEN Added comment: Biallelic CNPY3 mutations cause Epileptic encephalopathy, early infantile, 60 (MIM 617929). The phenotype including among others hypotonia, intractable seizures, DD and ID has been first reported by Mutoh et al (2018 - PMID: 29394991) in 3 subjects from 2 families. Evidence was provided for the role of the gene (incl. mouse model) and pathogenicity of the identified variants (resulting in LoF). Another subject with similar features of hypotonia, DD, intractable epilepsy, feeding problems has been described briefly by Maddirevula et al (2019 - PMID: 30237576). Sources: Literature |
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Intellectual disability - microarray and sequencing v3.170 | ABCA2 |
Konstantinos Varvagiannis gene: ABCA2 was added gene: ABCA2 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: ABCA2 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: ABCA2 were set to 30237576; 29302074; 31047799 Phenotypes for gene: ABCA2 were set to Intellectual developmental disorder with poor growth and with or without seizures or ataxia, 618808 Penetrance for gene: ABCA2 were set to Complete Review for gene: ABCA2 was set to GREEN Added comment: Biallelic pathogenic ABCA2 variants cause Intellectual developmental disorder with poor growth and with or without seizures or ataxia (MIM 618808). There are 3 relevant publications (01-07-2020) : - Maddirevula et al [2019 - PMID: 30237576] described briefly 2 unrelated subjects (16-2987, 16DG0071) both DD and seizures among other manifestations. - Hu et al [2019 - PMID: 29302074] reported 3 sibs (M8600615 - III:1-3) born to consanguineous parents (M8600615 - III:1-3) with DD/ID (formal confirmation of moderate ID, in those (2) evaluated). One also presented with seizures. - Aslam and Naz [2019 - PMID: 31047799] provided clinical details on 2 siblings born to consanguineous parents. ID was reported for the older sib but was absent in the younger one. Seizures were not part of the phenotype. All subjects harbored biallelic pLoF variants. N.B. : Steinberg et al [2015 - PMID: 25773295], within a cohort of patients with ALS, identified one with biallelic ABCA2 variants. As however Aslam and Naz comment, this person harbored a single pathogenic variant, with a second one rather unlikely to be pathogenic due to high allele frequency. Overall this gene can be considered for inclusion with green rating in both ID and epilepsy panels (each in >=3 unrelated individuals). Sources: Literature |
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Intellectual disability - microarray and sequencing v3.34 | ADAM22 | Rebecca Foulger commented on gene: ADAM22: PMID:30237576 (Maddirevula et al., 2019) searched their database of clinical exomes for homozygous variants and report an 18 year old male with Arg860* variant and recurrent seizures (Supplementary Table). His development was normal until 5 months when he had a slower gain of milestones. He has ID with severely delayed speech. Family history revealed ID and epilepsy in his old brother and in wider family. | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v3.3 | MADD | Zornitza Stark reviewed gene: MADD: Rating: GREEN; Mode of pathogenicity: None; Publications: 28940097; Phenotypes: Intellectual disability; Mode of inheritance: BIALLELIC, autosomal or pseudoautosomal; Current diagnostic: yes | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v2.1102 | DMXL2 |
Konstantinos Varvagiannis changed review comment from: This gene can be considered for upgrade to green rating (ID and epilepsy with >=4 relevant individuals/families/variants and >=2 studies, role of the protein, effect of variants in most cases demonstrated, phenotypic similarities with other disorders affecting autophagy, some evidence from animal models, etc). Rare heterozygous variants disrupting DMXL2 (intragenic losses/gains, SNVs, CNVs affecting also additional genes) have been reported in individuals with variable neurodevelopmental disorders (ASD and ID) or psychiatric phenotypes [Costain et al. 2019 - PMID: 30732576 - summarized in Table 1]. (Highly) variable expressivity and possibly incomplete penetrance were proposed in the respective study. As a result evidence for ID/seizures due to monoallelic variants appears to be relatively limited. DD, ID and (probably) epilepsy appear however to be features in several individuals with biallelic pathogenic variants as summarized in the studies below. OMIM recently added a relevant entry with the DMXL2-associated phenotypes being the following: - Epileptic encephalopathy, early infantile, 81; EIEE81 - 618663 (AD) [based on refs 2,3] - ?Deafness, autosomal dominant 71 - 617605 (AD) [DD/ID/seizures are not part of the phenotype] - ?Polyendocrine-polyneuropathy syndrome - 616113 (AR) [based on ref1] DMXL2 is not associated with any phenotype in G2P. In SysID it is listed as a candidate ID gene based on the report by Tata et al (ref1). This gene is included in some gene panels for ID. [1] Tata el al. (2014 - PMID: 25248098) reported on 3 sibs born to consanguineous Senegalese parents, presenting with a progressive endocrine and neurodevelopmental disorder. Features incl. incomplete puberty, central hypothyroidism, abnormal glucose regulation, moderate ID (3/3) and peripheral polyneuropathy. Seizures were not part of the phenotype. Linkage analysis suggested 2 candidate regions on chromosomes 13 and 15 with a LOD score of 2.5. High throughput sequencing of genes within these regions (~500) in an affected member and parent revealed a 15 bp in-frame deletion of DMXL2 (NM_015263.4:c.5827_5841del / p.Asp1943_Ser1947del). Sanger sequencing of other affected and unaffected members supported AR inheritance. RT-qPCR demonstrated that DMXL2 mRNA levels in blood lymphocytes were significantly lower in homozygous patients compared to heterozygous or wt family members or controls. The authors demonstrated that the encoded protein (rabconnectin-3a) is a synaptic protein (expressed in exocytosis vesicles) at the ends of axons of GnRH producing neurons. Neuron-specific deletion of one allele in mice resulted in delayed puberty and very low fertility. Adult mice had lower number of GnRH neurons in hypothalamus. siRNA-mediated downregulation of Dmxl2 expression in an insulin-secreting cell line resulted in only slight insulin secretion in response to augmenting concentrations of glucose, providing evidence of involvement of the protein in control of regulated insulin secretion. ----------- [2] Maddirevula et al. (2019 - PMID: 30237576) reported briefly on a 36 months old boy, born to consanguineous parents, homozygous for a frameshift DMXL2 variant [individual 17-3220 | NM_001174117.1:c.4349_4350insTTACATGA or p.(Glu1450Aspfs*23)]. Features included focal seizures (onset at the age of 3m) with subsequent global DD, absent eye contact, cerebral atrophy and macrocephaly. This individual was identified following re-evaluation of exome data in a database of ~1550 exomes specifically for homozygous variants that would have been classified earlier as LP/P if the respective gene had sufficient evidence for association with a disorder. The family was not reported to have other affected members. As the authors noted, the boy was not known to have the multi-endocrine abnormalities reported by Tata et al. There are no additional information provided (eg. on confirmation of variants, etc). ----------- [3] Esposito et al. (2019 - PMID: 31688942) report on 3 sibling pairs (all 3 families unrelated) with biallelic DMXL2 mutations and summarize previous evidence on the gene and the DMXL2-related phenotypes. All presented a highly similar phenotype of Ohtahara syndrome (seizures with onset in the first days of life, tonic/myoclonic/occasionaly focal, burst-suppression upon EEG), profound DD/ID, quadriparesis, sensorineural hearing loss and presence of dysmorphic features. Sibs from 2 families presented evidence of peripheral polyneuropathy. Early brain MRIs revealed thin CC and hypomyelination in all, with later scans suggestive of gray and white matter shrinkage with leukoencephalopathy. None achieved developmental skills following birth with 5/6 deceased by the age of 9 years. Exome sequencing revealed biallelic DMXL2 variants in all, with compatible parental segregation studies (NM_015263.3): - Fam1 (2 sibs) : c.5135C>T (p.Ala1712Val) in trans with c.4478C>G (p.Ser1493*) - Fam2 (2 sibs) : homozygosity for c.4478C>A (p.Ser1493*) - Fam3 (2 sibs) : homozygosity for c.7518-1G>A Heterozygous parents (aged 39-59) did not exhibit hearing impairment [report of a single multigenerational family by Chen et al (2017 - PMID: 27657680) where a heterozygous missense variant segregated with hearing loss - respective OMIM entry: ?Deafness, autosomal dominant 71 - 617605]. In patients' fibroblasts, effect of the variants on mRNA/protein expression was demonstrated with mRNA expressed only in a patient from family 1, and degraded/absent for the 2 stopgain SNVs affecting codon 1493. Skipping of ex31 leading to frameshift/introduction of a PTC was shown for the splice variant (p.Trp2508Argfs*4 secondary to c.7518-1G>A). Protein was also absent upon western-blot. DMXL2 encodes a vesicular protein, DmX-Like protein 2 or rabconnectin-3a (cited Tata et al). The gene is expressed in brain ( https://www.gtexportal.org/home/gene/DMXL2 ). As Esposito et al comment, it is known to regulate the trafficking and activity of v-ATPase the latter having a role in acidifying intracellular organelles and promoting endosomal maturation (cited PMIDs : 25248098, 19758563, 22875945, 24802872). In line with this, staining of patients' fibroblasts using the acidotropic dye LysoTracker demonstrated increased signal, reversed by re-expression of DMXL2 protein. Overall an acidic shift in pH with impairment of lysosomal structures and function was suggested. The authors provided additional evidence for altered lysosomal function and associated autophagy with accumulation of autophagy receptors (eg p62) and substrates (polyubiquitinated proteins). Vacuolization and accumulation of atypical fusion-like structures was shown upon ultrastractural analysis. shRNA-mediated downregulation/silencing of Dmxl2 in mouse hippocampal neurons resulted also in altered lysosomal structures and defective autophagy. The neurons exhibited impaired neurite elongation and synapse formation. The authors suggest similarities with Vici syndrome, where biallelic EPG5 mutations result in autophagic defects and clinical manifestations of DD/ID/epilepsy. Dmxl2 homozygous ko mice display embryonic lethality with heterozygous mice displaying macrocephaly and corpus callosum dysplasia (cited PMIDs: 25248098, 30735494) .; to: This gene can be considered for upgrade to green rating (ID and epilepsy with >=4 relevant individuals/families/variants and >=2 studies, role of the protein, effect of variants in most cases demonstrated, phenotypic similarities with other disorders affecting autophagy, some evidence from animal models, etc). Rare heterozygous variants disrupting DMXL2 (intragenic losses/gains, SNVs, CNVs affecting also additional genes) have been reported in individuals with variable neurodevelopmental disorders (ASD and ID) or psychiatric phenotypes [Costain et al. 2019 - PMID: 30732576 - summarized in Table 1]. (Highly) variable expressivity and possibly incomplete penetrance were proposed in the respective study. As a result evidence for ID/seizures due to monoallelic variants appears to be relatively limited. DD, ID and (probably) epilepsy appear however to be features in several individuals with biallelic pathogenic variants as summarized in the studies below. OMIM recently added a relevant entry with the DMXL2-associated phenotypes being the following: - Epileptic encephalopathy, early infantile, 81; EIEE81 - 618663 (AR) [based on refs 2,3] - ?Deafness, autosomal dominant 71 - 617605 (AD) [DD/ID/seizures are not part of the phenotype] - ?Polyendocrine-polyneuropathy syndrome - 616113 (AR) [based on ref1] DMXL2 is not associated with any phenotype in G2P. In SysID it is listed as a candidate ID gene based on the report by Tata et al (ref1). This gene is included in some gene panels for ID. [1] Tata el al. (2014 - PMID: 25248098) reported on 3 sibs born to consanguineous Senegalese parents, presenting with a progressive endocrine and neurodevelopmental disorder. Features incl. incomplete puberty, central hypothyroidism, abnormal glucose regulation, moderate ID (3/3) and peripheral polyneuropathy. Seizures were not part of the phenotype. Linkage analysis suggested 2 candidate regions on chromosomes 13 and 15 with a LOD score of 2.5. High throughput sequencing of genes within these regions (~500) in an affected member and parent revealed a 15 bp in-frame deletion of DMXL2 (NM_015263.4:c.5827_5841del / p.Asp1943_Ser1947del). Sanger sequencing of other affected and unaffected members supported AR inheritance. RT-qPCR demonstrated that DMXL2 mRNA levels in blood lymphocytes were significantly lower in homozygous patients compared to heterozygous or wt family members or controls. The authors demonstrated that the encoded protein (rabconnectin-3a) is a synaptic protein (expressed in exocytosis vesicles) at the ends of axons of GnRH producing neurons. Neuron-specific deletion of one allele in mice resulted in delayed puberty and very low fertility. Adult mice had lower number of GnRH neurons in hypothalamus. siRNA-mediated downregulation of Dmxl2 expression in an insulin-secreting cell line resulted in only slight insulin secretion in response to augmenting concentrations of glucose, providing evidence of involvement of the protein in control of regulated insulin secretion. ----------- [2] Maddirevula et al. (2019 - PMID: 30237576) reported briefly on a 36 months old boy, born to consanguineous parents, homozygous for a frameshift DMXL2 variant [individual 17-3220 | NM_001174117.1:c.4349_4350insTTACATGA or p.(Glu1450Aspfs*23)]. Features included focal seizures (onset at the age of 3m) with subsequent global DD, absent eye contact, cerebral atrophy and macrocephaly. This individual was identified following re-evaluation of exome data in a database of ~1550 exomes specifically for homozygous variants that would have been classified earlier as LP/P if the respective gene had sufficient evidence for association with a disorder. The family was not reported to have other affected members. As the authors noted, the boy was not known to have the multi-endocrine abnormalities reported by Tata et al. There are no additional information provided (eg. on confirmation of variants, etc). ----------- [3] Esposito et al. (2019 - PMID: 31688942) report on 3 sibling pairs (all 3 families unrelated) with biallelic DMXL2 mutations and summarize previous evidence on the gene and the DMXL2-related phenotypes. All presented a highly similar phenotype of Ohtahara syndrome (seizures with onset in the first days of life, tonic/myoclonic/occasionaly focal, burst-suppression upon EEG), profound DD/ID, quadriparesis, sensorineural hearing loss and presence of dysmorphic features. Sibs from 2 families presented evidence of peripheral polyneuropathy. Early brain MRIs revealed thin CC and hypomyelination in all, with later scans suggestive of gray and white matter shrinkage with leukoencephalopathy. None achieved developmental skills following birth with 5/6 deceased by the age of 9 years. Exome sequencing revealed biallelic DMXL2 variants in all, with compatible parental segregation studies (NM_015263.3): - Fam1 (2 sibs) : c.5135C>T (p.Ala1712Val) in trans with c.4478C>G (p.Ser1493*) - Fam2 (2 sibs) : homozygosity for c.4478C>A (p.Ser1493*) - Fam3 (2 sibs) : homozygosity for c.7518-1G>A Heterozygous parents (aged 39-59) did not exhibit hearing impairment [report of a single multigenerational family by Chen et al (2017 - PMID: 27657680) where a heterozygous missense variant segregated with hearing loss - respective OMIM entry: ?Deafness, autosomal dominant 71 - 617605]. In patients' fibroblasts, effect of the variants on mRNA/protein expression was demonstrated with mRNA expressed only in a patient from family 1, and degraded/absent for the 2 stopgain SNVs affecting codon 1493. Skipping of ex31 leading to frameshift/introduction of a PTC was shown for the splice variant (p.Trp2508Argfs*4 secondary to c.7518-1G>A). Protein was also absent upon western-blot. DMXL2 encodes a vesicular protein, DmX-Like protein 2 or rabconnectin-3a (cited Tata et al). The gene is expressed in brain ( https://www.gtexportal.org/home/gene/DMXL2 ). As Esposito et al comment, it is known to regulate the trafficking and activity of v-ATPase the latter having a role in acidifying intracellular organelles and promoting endosomal maturation (cited PMIDs : 25248098, 19758563, 22875945, 24802872). In line with this, staining of patients' fibroblasts using the acidotropic dye LysoTracker demonstrated increased signal, reversed by re-expression of DMXL2 protein. Overall an acidic shift in pH with impairment of lysosomal structures and function was suggested. The authors provided additional evidence for altered lysosomal function and associated autophagy with accumulation of autophagy receptors (eg p62) and substrates (polyubiquitinated proteins). Vacuolization and accumulation of atypical fusion-like structures was shown upon ultrastractural analysis. shRNA-mediated downregulation/silencing of Dmxl2 in mouse hippocampal neurons resulted also in altered lysosomal structures and defective autophagy. The neurons exhibited impaired neurite elongation and synapse formation. The authors suggest similarities with Vici syndrome, where biallelic EPG5 mutations result in autophagic defects and clinical manifestations of DD/ID/epilepsy. Dmxl2 homozygous ko mice display embryonic lethality with heterozygous mice displaying macrocephaly and corpus callosum dysplasia (cited PMIDs: 25248098, 30735494) . |
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Intellectual disability - microarray and sequencing v2.845 | ACTL6B |
Rebecca Foulger commented on gene: ACTL6B: Karaca et al, 2015 (PMID:26539891) report a homozygous variant (NM_016188: c.G893A; p.R298Q) in two siblings BAB6569 and BAB6570 with severe ID, microcephaly, seizures and some autistic behavioral pattern (BAB6570 appears in the text but not table 1). Sajan et al., 2017 (PMID:27171548) report a homozygous stoploss variant in ACTL6B: c.1279delT (p.X427D) in an ASD case from the DDD study (PMID:25533962) but no other clinical or EEG data was provided. Maddirevula et al 2019 (PMID:30237576) searched their database on exomes in search of homozygous variants that could be linked to diseases. They identified the homozygous variant NM_016188.4:c.999T>A:p.(Cys333*) in a 13 year old girl (individual 17-1447) with phenotype global developmental delay, vs hyperekplexia, and basal ganglia abnormalities. |
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Intellectual disability - microarray and sequencing v2.839 | UFC1 | Rebecca Foulger commented on gene: UFC1: Maddirevula et al 2019 (PMID:30237576) searched their database on exomes in search of homozygous variants that could be linked to diseases. They identified the NM_016406.3:c.317C>T:p.(Thr106Ile) variant in UFC1 in two cases with global DD and progressive microcephaly (17-3196 and 17-3892). Both of these cases were published in Nahorski et al, 2018 (PMID:29868776, Table 1). | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v2.836 | UFM1 | Rebecca Foulger commented on gene: UFM1: Maddirevula et al 2019 (PMID:30237576) searched their database on exomes in search of homozygous variants that could be linked to diseases. They identified the NM_016617.3:c.241C>T:p.(Arg81Cys) variant in one case with global DD and progressive microcephaly (10DG0945). This case was published in Nahorski et al, 2018 (PMID:29868776, Table 1) so does not offer an additional case. | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v2.468 | MADD |
Louise Daugherty gene: MADD was added gene: MADD was added to Intellectual disability. Sources: Victorian Clinical Genetics Services Mode of inheritance for gene: MADD was set to |