A systematic analysis of splicing variants identifies new diagnoses in the 100,000 Genomes Project

Blakes, Alexander J M; Wai, Htoo A.; Davies, Ian; Moledina, Hassan E; Ruiz, April; Thomas, Tessy; Bunyan, David J.; Thomas, N. Simon; Burren, Christine; Greenhalgh, Lynn; Lees, Melissa; Pichini, Amanda; Smithson, Sarah; Tavares, Ana Lisa Taylor; O′Donovan, Peter; Douglas, Andrew G.L.; Whiffin, Nicola; Baralle, Diana; Lord, Jenny

doi:10.1186/s13073-022-01087-x

Cited by 23 publications

(22 citation statements)

References 46 publications

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“…It seems that smaller deletion (one case of c.795-2A>T, 12bp deletion, and moderate delay with seizure onset at 2.5 months) causes phenotypes less severe than larger deletion (two cases of c.795-2A>G, 108bp deletion, severe delay with seizure onset at 0.5 or 0.35 month). Different changes at the same splice site (c.795-2A>T/G) could cause different molecular consequences enough for significant clinical differences, supporting a previous notion that the functional effect of splicing variants is on a continuum rather than binary ( 10 ). Similarly, c.1030-1G > A is predicted to result in skipping of the whole 81-bp Exon13, compared to a deletion of only 27bp caused by c.1030-1G>T. More drastic differences likely exist between c.1462-2A>G (12bp in-frame deletion) and c.1462-2A>T (86bp frameshift deletion), but unfortunately, no clinical data are available to assess the genotype–phenotype relationship.…”

Section: The Overall Profile Of Stxbp1 Canonical S...supporting

confidence: 64%

“…Our identified variant, STXBP1 NM_001032221.4:c.578+2T>C, is located at a canonical splice site and leads to abnormal splicing. In general, canonical splice variants, within 2bp of exon–intron junction, are widely annotated as “loss of function” (LoF) variants and are known to be strong diagnostic candidates in LoF disorders ( 10 ). For example, +2T>C variants have been frequently reported to cause human genetic disease and are routinely scored as pathogenic splicing mutations.…”

Section: The Overall Profile Of Stxbp1 Canonical S...mentioning

confidence: 99%

“…To obtain a comprehensive understanding of the genotype–phenotype relationship for STXBP1 splice variants, we compiled a list of 54 canonical and 203 non-canonical splice variants ( Supplementary Table 2 ) from the Clinvar database. We evaluated those variants through spliceAI, a deep neural network that accurately predicts splice sites based on pre-mRNA sequence, which proves to be a highly accurate and informative prediction tool for potential splicing changes ( 10 , 12 , 13 ). Most canonical splice variants (44 out of 54) cause frameshift insertion or deletion and thus disruptive changes in STXBP1 expression.…”

Section: The Overall Profile Of Stxbp1 Canonical S...mentioning

confidence: 99%

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Case report: A novel STXBP1 splice variant and the landscape of splicing-involved STXBP1-related disorders

et al. 2023

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STXBP1 variants are one of the most common genetic causes of neurodevelopmental disorders and epilepsy, wherein STXBP1-related disorders are characterized by neurodevelopmental abnormalities in 95% and seizures in 89% of affected patients. However, the spectrums of both genotype and phenotype are quite wide and diverse, with a high baseline variability even for recurrent STXBP1 variants. Until now, no clear genotype–phenotype correlations have been established and multiple disease mechanisms have been proposed for STXBP1-related disorders. Without an ascertained disease cause for many cases of STXBP1 variants, it is challenging to manage this disease in an effective manner and current symptom-based treatments are focused on seizure control only, which has a minimal impact on global development. A novel STXBP1 canonical splice variant, NM_001032221.4:c.578+2T>C, was reported in this study, together with detailed documentation of disease manifestations and treatment management. Further RNA expression analysis revealed abnormal intron retention and possible production of truncated STXBP1 proteins as a likely pathogenic mechanism. More importantly, the landscape of previously understudied STXBP1 splice variants and functional investigations was assessed for the first time to provide a context for the discussion of the complicated genotype–phenotype relationship of STXBP1-related disorders. Future cases of this disorder and a deeper mechanism-based understanding of its pathogenic cause are required for precision medicine and better disease management.

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Section: The Overall Profile Of Stxbp1 Canonical S...supporting

confidence: 64%

Section: The Overall Profile Of Stxbp1 Canonical S...mentioning

confidence: 99%

Section: The Overall Profile Of Stxbp1 Canonical S...mentioning

confidence: 99%

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Case report: A novel STXBP1 splice variant and the landscape of splicing-involved STXBP1-related disorders

et al. 2023

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“…Splicing is a key process in eukaryotic cells and its disruption is one of the main molecular causes of rare genetic diseases [ 33 , 34 ]. Disturbances in the splicing could lead to the introduction of a premature stop codon or variations in the protein structure due to in-frame changes.…”

Section: Discussionmentioning

confidence: 99%

Improving Hereditary Hemorrhagic Telangiectasia Molecular Diagnosis: A Referral Center Experience

Aguilera

Padró-Miquel

Esteve-Garcia

et al. 2023

Genes

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Background: Hereditary hemorrhagic telangiectasia (HHT) is a rare vascular disease inherited in an autosomal dominant manner. Disease-causing variants in endoglin (ENG) and activin A receptor type II-like 1 (ACVRL1) genes are detected in more than 90% of the patients undergoing molecular testing. The identification of variants of unknown significance is often seen as a challenge in clinical practice that makes family screening and genetic counseling difficult. Here, we show that the implementation of cDNA analysis to assess the effect of splice site variants on mRNA splicing is a powerful tool. Methods: Gene panel sequencing of genes associated with HHT and other arteriovenous malformation-related syndromes was performed. To evaluate the effect of the splice site variants, cDNA analysis of ENG and ACVRL1 genes was carried out. Results: three novel splice site variants were identified in ENG (c.68-2A > T and c.1311+4_1311+8del) and ACVLR1 (c.526-6C > G) genes correspondingly in three individuals with HHT that met ≥ 3 Curaçao criteria. All three variants led to an aberrant splicing inducing exon skipping (ENG:c.68-2A > T and ACVRL1:c.526-6C > G) or intron retention (ENG:c.1311+4_1311+8del) allowing the confirmation of the predicted effect on splicing and the reclassification from unknown significance to pathogenic/likely pathogenic of two of them. Conclusions: RNA analysis should be performed to assess and/or confirm the impact of variants on splicing. The molecular diagnosis of HHT patients is crucial to allow family screening and accurate genetic counseling. A multidisciplinary approach including clinicians and geneticists is crucial when dealing with patients with rare diseases.

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“…The most promising interpretation strategies have so far been hypothesis-driven approaches rather than searching for statistical enrichment in non-coding sequence. For SNVs, these included the identification of non-coding variants affecting the so-called gene body, where rare (de novo) variants affected, for instance, sequences of the UTRs disrupting the wild-type translation start site [96,97] or (de novo) variants in introns, where they introduced cryptic splice sites leading to abnormal splicing and the inclusion of poison exons [98][99][100]. For non-coding structural variants, the molecular mechanism leading to disease has mainly been the dysregulation of spatial 3D-organization [101] and gene regulation, for instance, through the disruption of topological-associated domain structures [102][103][104].…”

Section: From Exomes To Genomes-from Coding To Non-coding Variantsmentioning

confidence: 99%

The Genetics of Intellectual Disability

2023

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Intellectual disability (ID) has a prevalence of ~2–3% in the general population, having a large societal impact. The underlying cause of ID is largely of genetic origin; however, identifying this genetic cause has in the past often led to long diagnostic Odysseys. Over the past decades, improvements in genetic diagnostic technologies and strategies have led to these causes being more and more detectable: from cytogenetic analysis in 1959, we moved in the first decade of the 21st century from genomic microarrays with a diagnostic yield of ~20% to next-generation sequencing platforms with a yield of up to 60%. In this review, we discuss these various developments, as well as their associated challenges and implications for the field of ID, which highlight the revolutionizing shift in clinical practice from a phenotype-first into genotype-first approach.

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A systematic analysis of splicing variants identifies new diagnoses in the 100,000 Genomes Project

Cited by 23 publications

References 46 publications

Case report: A novel STXBP1 splice variant and the landscape of splicing-involved STXBP1-related disorders

Case report: A novel STXBP1 splice variant and the landscape of splicing-involved STXBP1-related disorders

Improving Hereditary Hemorrhagic Telangiectasia Molecular Diagnosis: A Referral Center Experience

The Genetics of Intellectual Disability

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