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Intellectual disability - microarray and sequencing v5.161 | FEM1C |
Achchuthan Shanmugasundram changed review comment from: This gene should be rated RED as there is only one clear case of intellectual disability reported in literature. PMID:36336956 reported a 9 year-old boy with severe global developmental delay, lack of speech, pyramidal signs and limb ataxia and identified with a heterozygous de novo missense variant c.376G>C (p.Asp126His) in the FEM1C gene. Cognitive assessment performed at 9 years of age showed that he has moderate intellectual disability. De novo variant in the same residue (p.Asp126Val) has also been associated with an uncharacterised developmental disorder in PMID:28135719. An additional case with a diagnostically reported de novo variant in this gene and a compatible phenotype including intellectual disability and ataxia was identified in the internal Genomics England Clinical Variant Archive (CVA) by the Diagnostic Discovery initiative. This gene has not yet been associated with relevant phenotypes in OMIM or in Gene2Phenotype. Sources: Literature; to: PMID:36336956 reported a 9 year-old boy with severe global developmental delay, lack of speech, pyramidal signs and limb ataxia and identified with a heterozygous de novo missense variant c.376G>C (p.Asp126His) in the FEM1C gene. Cognitive assessment performed at 9 years of age showed that he has moderate intellectual disability. De novo variant in the same residue (p.Asp126Val) has also been associated with an uncharacterised developmental disorder in PMID:28135719. An additional case with a diagnostically reported de novo variant in this gene and a compatible phenotype including intellectual disability and ataxia was identified in the internal Genomics England Clinical Variant Archive (CVA) by the Diagnostic Discovery initiative. 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 v5.161 | FEM1C |
Achchuthan Shanmugasundram changed review comment from: This gene should be rated RED as there is only one clear case of intellectual disability reported in literature. PMID:36336956 reported a 9 year-old boy with severe global developmental delay, lack of speech, pyramidal signs and limb ataxia and identified with a heterozygous de novo missense variant c.376G>C (p.Asp126His) in the FEM1C gene. Cognitive assessment performed at 9 years of age showed that he has moderate intellectual disability. De novo variant in the same residue (p.Asp126Val) has also been associated with an uncharacterised developmental disorder in PMID:28135719. This gene has not yet been associated with relevant phenotypes in OMIM or in Gene2Phenotype. Sources: Literature; to: This gene should be rated RED as there is only one clear case of intellectual disability reported in literature. PMID:36336956 reported a 9 year-old boy with severe global developmental delay, lack of speech, pyramidal signs and limb ataxia and identified with a heterozygous de novo missense variant c.376G>C (p.Asp126His) in the FEM1C gene. Cognitive assessment performed at 9 years of age showed that he has moderate intellectual disability. De novo variant in the same residue (p.Asp126Val) has also been associated with an uncharacterised developmental disorder in PMID:28135719. An additional case with a diagnostically reported de novo variant in this gene and a compatible phenotype including intellectual disability and ataxia was identified in the internal Genomics England Clinical Variant Archive (CVA) by the Diagnostic Discovery initiative. 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 v5.2 | FEM1C |
Achchuthan Shanmugasundram gene: FEM1C was added gene: FEM1C was added to Intellectual disability - microarray and sequencing. Sources: Literature Mode of inheritance for gene: FEM1C was set to MONOALLELIC, autosomal or pseudoautosomal, NOT imprinted Publications for gene: FEM1C were set to 36336956 Phenotypes for gene: FEM1C were set to Intellectual disability, MONDO:0001071 Review for gene: FEM1C was set to RED Added comment: This gene should be rated RED as there is only one clear case of intellectual disability reported in literature. PMID:36336956 reported a 9 year-old boy with severe global developmental delay, lack of speech, pyramidal signs and limb ataxia and identified with a heterozygous de novo missense variant c.376G>C (p.Asp126His) in the FEM1C gene. Cognitive assessment performed at 9 years of age showed that he has moderate intellectual disability. De novo variant in the same residue (p.Asp126Val) has also been associated with an uncharacterised developmental disorder in PMID:28135719. 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 v3.1720 | PTPA |
Konstantinos Varvagiannis gene: PTPA was added gene: PTPA was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: PTPA was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: PTPA were set to 36073231 Phenotypes for gene: PTPA were set to Intellectual disability; Parkinsonism Penetrance for gene: PTPA were set to Complete Review for gene: PTPA was set to AMBER Added comment: Biallelic PTPA pathogenic variants lead to a form of ID with later-onset parkinsonism based on 4 individuals from 2 families in the literature. Affected individuals were homozygous for missense variants demonstrated to result to reduced mRNA and protein levels as well as PP2A complex activation. Drosophila studies support an age-dependent locomotor dysfunction. Variants in other PP2A-complex-related genes also lead to NDDs. Summary provided below. There is currently no associated phenotype in OMIM, G2P, PanelApp Australia or SysNDD. Consider inclusion in relevant panels (ID, Parkinsonism/movement disorders, etc) with amber rating pending further reports. ------ Fevga, Tesson et al (2022 - PMID: 36073231) describe the features of 4 individuals, from 2 unrelated families, with biallelic pathogenic PTPA variants. These presented with normal or delayed early milestones, learning disability and ID (mild to moderate) followed by progressive signs of parkinsonism (at the age of 11 yrs in 2 sibs, 15 yrs in another individual). Motor symptoms were responsive to levodopa and later to deep brain stimulation. Linkage analysis in one consanguineous family followed by exome revealed homozygosity for a missense PTPA variant (NM_178001:c.893T>G/p.Met298Arg). Exome sequencing in affected subjects from the 2nd family revealed homozygosity for a further missense variant (c.512C>A/p.Ala171Asp). There were no other candidate variants for the phenotype following parental / segregation studies. Role of the gene: As the authors discuss, PTPA (or PPP2R4) is ubiquitously expressed in all tissues incl. brain and encodes a phosphotyrosyl phosphatase activator of the dimeric form of protein phosphatase-2A (PP2A). PP2A in turn, is the major Ser/Thr phosphatase in brain targeting a large number of proteins involved in diverse functions. Activation of PP2A is dependent on its methylation, which is negatively regulated by the PP2A-specific methylesterase (PME-1). By binding to PME-1, PTPA counteracts the negative influence of the former on PP2A. Pathogenic variants in genes encoding subunits/regulators of the PP2A complex (e.g. PPP2R1A or PPP2CA) are associated with neurodevelopmental disorders. Variant studies: Upon overexpression of wt and both variants in a HEK-293 cell line the authors demonstrated that both variants resulted in significantly reduced mRNA and protein levels (which for Ala171Asp were attributed to increased proteasomal degradation). Both variants were shown to result in impaired PP2A complex activation compared to wt. Drosophila / animal models: Pan-neuronal RNAi-mediated knockdown of ptpa in Drosophila resulted in an age-dependent locomotor dysfunction, reversible with L-DOPA treatment. Previous studies in mice suggest cognitive/electrophysiological impairments upon downregulation of PP2A activity in transgenic mice. Sources: Literature |
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Intellectual disability - microarray and sequencing v3.1478 | SPRED2 |
Zornitza Stark gene: SPRED2 was added gene: SPRED2 was added to Intellectual disability. Sources: Literature Mode of inheritance for gene: SPRED2 was set to BIALLELIC, autosomal or pseudoautosomal Publications for gene: SPRED2 were set to 34626534 Phenotypes for gene: SPRED2 were set to developmental delay; intellectual disability; cardiac defects; short stature; skeletal anomalies; a typical facial gestalt Review for gene: SPRED2 was set to GREEN gene: SPRED2 was marked as current diagnostic Added comment: PMID: 34626534 Homozygosity for three different variants c.187C>T (p.Arg63∗), c.299T>C (p.Leu100Pro), and c.1142_1143delTT (p.Leu381Hisfs∗95) were identified in four subjects from three families. All variants severely affected protein stability, causing accelerated degradation, and variably perturbed SPRED2 functional behaviour. The clinical phenotype of the four affected individuals included developmental delay, intellectual disability, cardiac defects, short stature, skeletal anomalies, and a typical facial gestalt as major features, without the occurrence of the distinctive skin signs characterizing Legius syndrome. Sources: Literature |
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Intellectual disability - microarray and sequencing v3.1300 | IMPDH2 | Arina Puzriakova Added comment: Comment on list classification: New gene added by Zornitza Stark. This gene is not yet associated with a relevant phenotype in OMIM or G2P, but sufficient unrelated cases with relevant phenotype to rate Green at the next GMS review. Neurodevelopmental delay is an early feature that may be evident prior to other manifestations (plausible that other cases may develop dystonic signs later in life) and so inclusion on this panel is warranted. | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v3.1034 | NEUROD2 |
Arina Puzriakova gene: NEUROD2 was added gene: NEUROD2 was added to Intellectual disability. Sources: Literature Q2_21_rating tags were added to gene: NEUROD2. Mode of inheritance for gene: NEUROD2 was set to MONOALLELIC, autosomal or pseudoautosomal, NOT imprinted Publications for gene: NEUROD2 were set to 16504944; 30323019; 33438828 Phenotypes for gene: NEUROD2 were set to Developmental and epileptic encephalopathy 72, OMIM:618374 Review for gene: NEUROD2 was set to GREEN Added comment: NEUROD2 is associated with a relevant phenotype in OMIM (MIM# 618374), but is not yet listed in Gene2Phenotype. - PMID: 30323019 (2019) - Two unrelated children with refractory early-infantile epileptic encephalopathy. Developmental delay (DD) preceded onset of seizures in both cases, with signs of DD becoming evident at 2-4 months and seizures arising at 5 months of age. Patient 1 became seizure-free after introducing a ketogenic diet at 16 months; however, an EEG at 22 months remained abnormal and she continues to have severe GDD with no independent sitting, walking or speaking at the chronological age of 3 years and 2 months. Patient 2 became seizure-free when a vagal nerve stimulator (VNS) was placed at 16 months of age. He displayed significant improvement on EEG and subsequently began regaining neurodevelopmental milestones. WES revealed different de novo variants in the NEUROD2 gene (P1: c.388G>C, p.E130Q; P2: c.401T>C, p.M134T, respectively). Knockdown of the neurod2 in Xenopus tropicalis tadpoles resulted in abnormal swimming behaviour and progressive seizures followed by periods of immobility. Overexpression of wild-type human NEUROD2 in tadpoles induced non-neuronal cells to differentiate into neurons - on the other hand, overexpression of the mutant alleles failed to to cause any (p.E130Q) or a comparable degree (p.M134T) of ectopic neuronal induction as seen with the wild-type protein. - Conference poster (Genomics of Rare Disease 2021) - 'Neuronal Differentiation Factor 2 (NEUROD2) Pathogenic Variant as a Molecular Aetiology of Infantile Spasm ' by Sakpichaisakul et al, QSNICH, Thailand - In a 15 month-old female with infantile spasm, trio exome sequencing revealed a de novo variant in NEUROD2 (c.388G>C, p.E130Q). She was born of non-consanguineous healthy parents with no family history of epilepsy. Poor eye contact and no social smile were noted in the first few months, followed by the first infantile spasm at 5 months of age. This was initially controlled by combined vigabatrin and prednisolone therapy - however relapsing seizures were detected at 15 months. Sequential treatment with vigabatrin following prednisolone resulted in cessation of seizures, and subsequently regaining of neurodevelopmental milestones (sitting without support, grabbing objects without pincer grasp and speaking one single word) ----- Cases without seizures - - PMID: 33438828 (2021) - Adolescent (14 yrs old) with GDD but without seizures who was found to have a novel de novo NEUROD2 missense variant (c.488 T > C, p.L163P). An additional individual (12 yrs) with DD and a different missense NEUROD2 (c.703G>A, p.A235T) was also identified, but lacking parental samples for segregation analysis. Functional analysis in Xenopus laevis revealed that injection of the p.L163P mRNA variant resulted in a defective ability to induce ectopic neurons in tadpoles as compared with wild-type NEUROD2 mRNA, while the p.A235T variant functioned similarly to wild-type. Sources: Literature |
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Intellectual disability - microarray and sequencing v3.639 | MORC2 | Arina Puzriakova Added comment: Comment on list classification: Though signs suggestive of neuropathy were observed in the cohort presented by Sacoto et al (PMID:32693025), these were not the predominant feature of the disease presentation or the primary indication for diagnostic testing. Inclusion on this panel would be of value for detecting such cases, and so this gene should be promoted to Green at the next GMS panel update (added 'for-review' tag) | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing v3.369 | PRKD1 |
Arina Puzriakova changed review comment from: Gene included previously in context of publication by Sifrim et al. (2016) (PMID: 27479907). However, re-evaluation of this paper showed that only two of the three patients had ID, which may possibly be associated with microcephaly. The two individuals carried a c.1774G>A and c.896T>G variant, respectively; however, a third patient also harbouring the c.1774G>A variant did not display any neuropsychological signs (or microcephaly) at 4.86 years (see supplementary table 12). A recent report (PMID: 32817298, 2020) describes two additional unrelated cases with de novo variants, c.1774G>C and c.1808G>A, respectively. These patients shared cardiac and ectodermal abnormalities, as with the previously described patients; however, mental development was normal in both individuals.; to: Gene included previously in context of publication by Sifrim et al. (2016) (PMID: 27479907). However, re-evaluation of this paper showed that only two of the three patients had ID, which may possibly be associated with microcephaly. The two individuals carried a c.1774G>A and c.896T>G variant, respectively; however, a third patient also harbouring the c.1774G>A variant did not display any neuropsychological signs (or microcephaly) at 4.86 years (see supplementary table 12, and figure 3). A recent report (PMID: 32817298, 2020) describes two additional unrelated cases with de novo variants, c.1774G>C and c.1808G>A, respectively. These patients shared cardiac and ectodermal abnormalities, as with the previously described patients; however, mental development was normal in both individuals. |
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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 v2.1143 | AFF3 |
Konstantinos Varvagiannis changed review comment from: Voisin et al. (2019 - https://doi.org/10.1101/693937) report on 10 individuals with de novo missense AFF3 variants affecting a 9-amino-acid sequence (degron) important for the protein's degradation and summarize the phenotype of an additional individual previously described by Steichen-Gersdorf et al. (2008 - PMID: 18616733) with a 500 kb affecting only AFF3 (LAF4) and removing also this sequence. The phenotype of missense variants consisted of kidney anomalies, mesomelic dysplasia, seizures, hypertrichosis, intellectual disability and pulmonary problems and was overlapping with that of the deletion. [10 of 11 subjects exhibited severe developmental epileptic encephalopathy]. 9 probands harbored missense variants affecting the codon 258 while one individual had a variant affecting codon 260 [c.772G>T or p.Ala258Ser (x2), c.772G>A or p.Ala258Thr (x6), c.773C>T or p.Ala258Val (x1) and c.779T>G or p.(Val260Gly) (x1) - NM_001025108.1 / NP_001020279.1]. The deletion removed exons 4-13. AFF1-4 are ALF transcription factor paralogs, components of the transcriptional super elongation complex regulating expression of genes involved in neurogenesis and development. Using HEK293T cells expressing FLAG-tagged AFF3 (and AFF4) wt or mutants, accumulation of mutated forms was shown upon immunoblot. Aff3+/- and/or -/- mice exhibit skeletal defects. These were more pronounced in homozygous mice which demonstrated also some elements in favor of kidney dysfunction and/or metabolic deregulation and possible neurological dysfunction (signs of impaired hearing and diminished grip strength). Homozygous mice had CNS anomalies (enlarged lateral ventricles and decreased corpus callosum size) similar to some affected individuals, although these were not observed in another Aff3-/- model. Knock-in mice modeling the microdeletion and the Ala258Thr variant displayed lower mesomelic limb deformities and early lethality respectively [cited PMIDs : 21677750, 25660031, knock-in model was part of the present study]. Accumulation of the protein in zebrafish (by overexpression of the human wt AFF3 mRNA), led to morphological defects. Reanalysis of transcriptome data from previously generated HEK293T cell lines knocked down for AFF2, AFF3 and AFF4 by shRNAs (study) suggested that these transcription factors are not redundant. Finally, CHOPS syndrome (#616368) due to mutations of AFF4 also leading to increased protein stability presents a partially overlapping phenotype (incl. cognitive impairment) to that of AFF3. ---- Shimizu et al. (8/2019 - PMID: 31388108) describe an additional individual with de novo AFF3 missense variant. The phenotype overlaps with that summarized by Voisin et al. incl. mesomelic dysplasia with additional skeletal anomalies, bilateral kidney hypoplasia and severe DD at the age of 2.5 years. Seizures and pulmonary problems were not observed. Although a different RefSeq is used the variant is among those also reported by Voisin et al. [NM_002285.2:c.697G>A (p.Ala233Thr) corresponding to NM_001025108.1:c.772G>A (p.Ala258Thr)]. ---- In G2P, AFF3 is associated with Skeletal dysplasia with severe neurological disease (disease confidence : probable / ID and seizures among the assigned phenotypes). There is no associated phenotype in OMIM. Some diagnostic laboratories include AFF3 in their ID panel (eg. among the many co-authors' affiliations GeneDx and Victorian Clinical Genetics - which was already listed as source for AFF3 in the current panel). ---- As a result this gene can be considered for upgrade to green (relevant phenotype and severity, sufficient cases, evidence for accumulation similar to AFF4, animal models, etc) or amber (pending publication of the article). [Review modified to add additional reference/case report]; to: Voisin et al. (2019 - https://doi.org/10.1101/693937) report on 10 individuals with de novo missense AFF3 variants affecting a 9-amino-acid sequence (degron) important for the protein's degradation and summarize the phenotype of an additional individual previously described by Steichen-Gersdorf et al. (2008 - PMID: 18616733) with a 500 kb deletion affecting only AFF3 (LAF4) and removing also this sequence. The phenotype of missense variants consisted of kidney anomalies, mesomelic dysplasia, seizures, hypertrichosis, intellectual disability and pulmonary problems and was overlapping with that of the deletion. [10 of 11 subjects exhibited severe developmental epileptic encephalopathy]. 9 probands harbored missense variants affecting the codon 258 while one individual had a variant affecting codon 260 [c.772G>T or p.Ala258Ser (x2), c.772G>A or p.Ala258Thr (x6), c.773C>T or p.Ala258Val (x1) and c.779T>G or p.(Val260Gly) (x1) - NM_001025108.1 / NP_001020279.1]. The deletion removed exons 4-13. AFF1-4 are ALF transcription factor paralogs, components of the transcriptional super elongation complex regulating expression of genes involved in neurogenesis and development. Using HEK293T cells expressing FLAG-tagged AFF3 (and AFF4) wt or mutants, accumulation of mutated forms was shown upon immunoblot. Aff3+/- and/or -/- mice exhibit skeletal defects. These were more pronounced in homozygous mice which demonstrated also some elements in favor of kidney dysfunction and/or metabolic deregulation and possible neurological dysfunction (signs of impaired hearing and diminished grip strength). Homozygous mice had CNS anomalies (enlarged lateral ventricles and decreased corpus callosum size) similar to some affected individuals, although these were not observed in another Aff3-/- model. Knock-in mice modeling the microdeletion and the Ala258Thr variant displayed lower mesomelic limb deformities and early lethality respectively [cited PMIDs : 21677750, 25660031, knock-in model was part of the present study]. Accumulation of the protein in zebrafish (by overexpression of the human wt AFF3 mRNA), led to morphological defects. Reanalysis of transcriptome data from previously generated HEK293T cell lines knocked down for AFF2, AFF3 and AFF4 by shRNAs (study) suggested that these transcription factors are not redundant. Finally, CHOPS syndrome (#616368) due to mutations of AFF4 also leading to increased protein stability presents a partially overlapping phenotype (incl. cognitive impairment) to that of AFF3. ---- Shimizu et al. (8/2019 - PMID: 31388108) describe an additional individual with de novo AFF3 missense variant. The phenotype overlaps with that summarized by Voisin et al. incl. mesomelic dysplasia with additional skeletal anomalies, bilateral kidney hypoplasia and severe DD at the age of 2.5 years. Seizures and pulmonary problems were not observed. Although a different RefSeq is used the variant is among those also reported by Voisin et al. [NM_002285.2:c.697G>A (p.Ala233Thr) corresponding to NM_001025108.1:c.772G>A (p.Ala258Thr)]. ---- In G2P, AFF3 is associated with Skeletal dysplasia with severe neurological disease (disease confidence : probable / ID and seizures among the assigned phenotypes). There is no associated phenotype in OMIM. Some diagnostic laboratories include AFF3 in their ID panel (eg. among the many co-authors' affiliations GeneDx and Victorian Clinical Genetics - which was already listed as source for AFF3 in the current panel). ---- As a result this gene can be considered for upgrade to green (relevant phenotype and severity, sufficient cases, evidence for accumulation similar to AFF4, animal models, etc) or amber (pending publication of the article). [Review modified to add additional reference/case report] |
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Intellectual disability - microarray and sequencing v2.1122 | TMX2 |
Konstantinos Varvagiannis edited their review of gene: TMX2: Added comment: A recent report by Vandervore, Schot et al. following the previous review (Am J Hum Genet. 2019 Nov 12 - PMID: 31735293), provides further evidence that biallelic TMX2 mutations cause malformations of cortical development, microcephaly, DD and ID and epilepsy. As a result this gene should probably be considered for inclusion in the ID/epilepsy panels with green rating. Overall, 14 affected subjects from 10 unrelated families are reported in the aforementioned study. The majority had severe DD/ID (failure to achieve milestones, absent speech/ambulation and signs of cerebral palsy) with few having a somewhat milder impairment. 12 (of the 14) presented with epilepsy (spasms, myoclonic seizures, focal seizures with/without generalization or generalized tonic-clonic seizures) with onset most often in early infancy. Upon brain MRI (in 12 individuals), 5 presented polymicrogyria, 2 others pachygyria, 4 with brain atrophy, etc. All individuals were found to harbor biallelic TMX2 mutations by exome sequencing while previous investigations in several had ruled out alternative causes (infections, metabolic or chromosomal anomalies). Missense variants, an in-frame deletion as well as pLoF (stopgain/frameshift) variants were reported. [NM_015959.3 used as ref below]. The effect of variants was supported by mRNA studies, eg. RT-qPCR/allele specific RT-qPCR. The latter proved reduced expression for a frameshift variant (c.391dup / p.Leu131Profs*6) most likely due to NMD. Total mRNA levels were also 23% lower in an individual compound htz for a missense variant and a stopgain one localized in the last exon (c.757C>T / p.Arg253*). As for the previously reported c.614G>A (p.Arg205Gln), affecting the last nucleotide of exon 6, total mRNA in skin fibroblasts from a homozygous individual was not significantly decreased. RNA-Seq however demonstrated the presence of 4 different transcripts (roughly 25% each), one representing the regular mRNA, one with intron 6 retention (also present at low levels in healthy individuals), one with loss of 11 nucleotides within exon 6 and a fourth one due to in-frame skipping of exon 6. *To the best of my understanding : Thioredoxin (TRX)-related transmembrane proteins (TMX) belong to the broader family of oxidoreductases of protein disulfide isomerase (PDI) having an important role in protein folding. Study of the data from the Allen Human Brain Atlas suggest relevant fetal expression also increasing during postnatal life. As RNA-seq was carried out for 2 individuals, GO analysis suggested that the most deregulated clusters of genes are implicated in post-translational protein modifications (as would be expected for PDIs), membranes and synapse while pathway analysis suggested that relevant categories were inhibited eg. nervous system development/function and cell growth/proliferation/survival. Upon transfection of HEK293T cells, exogenous TMX2 was shown to co-localize with calnexin (CNX) to the (ER) mitochondria-associated-membrane. Mass-spectrometry based analysis of co-immunoprecipitated proteins confirmed interaction with CNX but also other regulators of calcium homeostasis, mitochondrial membrane components and respiratory chain NADH dehydrogenase. Study of the mitochondrial activity of TMX2-deficient fibroblasts suggested reduced respiratory reserve capacity, compensated by increased glycolytic activity. TMX2 occurs in both reduced and oxidized monomeric form. It also forms (homo)dimers with the ratio of dimers/monomers increasing under conditions of oxidative stress. Variant TMX2 increased propensity to form dimers, thus mimicking increased oxidative state. This was observed under stress but also under native conditions. ---------; Changed rating: GREEN |
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Intellectual disability - microarray and sequencing v2.996 | AFF3 |
Konstantinos Varvagiannis changed review comment from: Voisin et al. (2019 - https://doi.org/10.1101/693937) report on 10 individuals with de novo missense AFF3 variants affecting a 9-amino-acid sequence (degron) important for the protein's degradation and summarize the phenotype of an additional individual previously described by Steichen-Gersdorf et al. (2008 - PMID: 18616733) with a 500 kb affecting only AFF3 (LAF4) and removing also this sequence. The phenotype of missense variants consisted of kidney anomalies, mesomelic dysplasia, seizures, hypertrichosis, intellectual disability and pulmonary problems and was overlapping with that of the deletion. [10 of 11 subjects exhibited severe developmental epileptic encephalopathy]. 9 probands harbored missense variants affecting the codon 258 while one individual had a variant affecting codon 260 [c.772G>T or p.Ala258Ser (x2), c.772G>A or p.Ala258Thr (x6), c.773C>T or p.Ala258Val (x1) and c.779T>G or p.(Val260Gly) (x1) - NM_001025108.1 / NP_001020279.1]. The deletion removed exons 4-13. AFF1-4 are ALF transcription factor paralogs, components of the transcriptional super elongation complex regulating expression of genes involved in neurogenesis and development. Using HEK293T cells expressing FLAG-tagged AFF3 (and AFF4) wt or mutants, accumulation of mutated forms was shown upon immunoblot. Aff3+/- and/or -/- mice exhibit skeletal defects. These were more pronounced in homozygous mice which demonstrated also some elements in favor of kidney dysfunction and/or metabolic deregulation and possible neurological dysfunction (signs of impaired hearing and diminished grip strength). Homozygous mice had CNS anomalies (enlarged lateral ventricles and decreased corpus callosum size) similar to some affected individuals, although these were not observed in another Aff3-/- model. Knock-in mice modeling the microdeletion and the Ala258Thr variant displayed lower mesomelic limb deformities and early lethality respectively [cited PMIDs : 21677750, 25660031, knock-in model was part of the present study]. Accumulation of the protein in zebrafish (by overexpression of the human wt AFF3 mRNA), led to morphological defects. Reanalysis of transcriptome data from previously generated HEK293T cell lines knocked down for AFF2, AFF3 and AFF4 by shRNAs (study) suggested that these transcription factors are not redundant. Finally, CHOPS syndrome (#616368) due to mutations of AFF4 also leading to increased protein stability presents a partially overlapping phenotype (incl. cognitive impairment) to that of AFF3. ---- In G2P, AFF3 is associated with Skeletal dysplasia with severe neurological disease (disease confidence : probable / ID and seizures among the assigned phenotypes). There is no associated phenotype in OMIM. Some diagnostic laboratories include AFF3 in their ID panel (eg. among the many co-authors' affiliations GeneDx and Victorian Clinical Genetics - which was already listed as source for AFF3 in the current panel). ---- As a result this gene can be considered for upgrade to green (relevant phenotype and severity, sufficient cases, evidence for accumulation similar to AFF4, animal models, etc) or amber (pending publication of the article).; to: Voisin et al. (2019 - https://doi.org/10.1101/693937) report on 10 individuals with de novo missense AFF3 variants affecting a 9-amino-acid sequence (degron) important for the protein's degradation and summarize the phenotype of an additional individual previously described by Steichen-Gersdorf et al. (2008 - PMID: 18616733) with a 500 kb affecting only AFF3 (LAF4) and removing also this sequence. The phenotype of missense variants consisted of kidney anomalies, mesomelic dysplasia, seizures, hypertrichosis, intellectual disability and pulmonary problems and was overlapping with that of the deletion. [10 of 11 subjects exhibited severe developmental epileptic encephalopathy]. 9 probands harbored missense variants affecting the codon 258 while one individual had a variant affecting codon 260 [c.772G>T or p.Ala258Ser (x2), c.772G>A or p.Ala258Thr (x6), c.773C>T or p.Ala258Val (x1) and c.779T>G or p.(Val260Gly) (x1) - NM_001025108.1 / NP_001020279.1]. The deletion removed exons 4-13. AFF1-4 are ALF transcription factor paralogs, components of the transcriptional super elongation complex regulating expression of genes involved in neurogenesis and development. Using HEK293T cells expressing FLAG-tagged AFF3 (and AFF4) wt or mutants, accumulation of mutated forms was shown upon immunoblot. Aff3+/- and/or -/- mice exhibit skeletal defects. These were more pronounced in homozygous mice which demonstrated also some elements in favor of kidney dysfunction and/or metabolic deregulation and possible neurological dysfunction (signs of impaired hearing and diminished grip strength). Homozygous mice had CNS anomalies (enlarged lateral ventricles and decreased corpus callosum size) similar to some affected individuals, although these were not observed in another Aff3-/- model. Knock-in mice modeling the microdeletion and the Ala258Thr variant displayed lower mesomelic limb deformities and early lethality respectively [cited PMIDs : 21677750, 25660031, knock-in model was part of the present study]. Accumulation of the protein in zebrafish (by overexpression of the human wt AFF3 mRNA), led to morphological defects. Reanalysis of transcriptome data from previously generated HEK293T cell lines knocked down for AFF2, AFF3 and AFF4 by shRNAs (study) suggested that these transcription factors are not redundant. Finally, CHOPS syndrome (#616368) due to mutations of AFF4 also leading to increased protein stability presents a partially overlapping phenotype (incl. cognitive impairment) to that of AFF3. ---- Shimizu et al. (8/2019 - PMID: 31388108) describe an additional individual with de novo AFF3 missense variant. The phenotype overlaps with that summarized by Voisin et al. incl. mesomelic dysplasia with additional skeletal anomalies, bilateral kidney hypoplasia and severe DD at the age of 2.5 years. Seizures and pulmonary problems were not observed. Although a different RefSeq is used the variant is among those also reported by Voisin et al. [NM_002285.2:c.697G>A (p.Ala233Thr) corresponding to NM_001025108.1:c.772G>A (p.Ala258Thr)]. ---- In G2P, AFF3 is associated with Skeletal dysplasia with severe neurological disease (disease confidence : probable / ID and seizures among the assigned phenotypes). There is no associated phenotype in OMIM. Some diagnostic laboratories include AFF3 in their ID panel (eg. among the many co-authors' affiliations GeneDx and Victorian Clinical Genetics - which was already listed as source for AFF3 in the current panel). ---- As a result this gene can be considered for upgrade to green (relevant phenotype and severity, sufficient cases, evidence for accumulation similar to AFF4, animal models, etc) or amber (pending publication of the article). [Review modified to add additional reference/case report] |
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Intellectual disability - microarray and sequencing | GNS | BRIDGE consortium edited their review of GNS | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing | GNS | BRIDGE consortium edited their review of GNS | |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Intellectual disability - microarray and sequencing | GNS | BRIDGE consortium reviewed GNS |