Pathogenic Abnormal Splicing Due to Intronic Deletions that Induce Biophysical Space Constraint for Spliceosome Assembly.

TitlePathogenic Abnormal Splicing Due to Intronic Deletions that Induce Biophysical Space Constraint for Spliceosome Assembly.
Publication TypeJournal Article
Year of Publication2019
AuthorsBryen, SJ, Joshi, H, Evesson, FJ, Girard, C, Ghaoui, R, Waddell, LB, Testa, AC, Cummings, B, Arbuckle, S, Graf, N, Webster, R, MacArthur, DG, Laing, NG, Davis, MR, Lührmann, R, Cooper, ST
JournalAm J Hum Genet
Volume105
Issue3
Pagination573-587
Date Published2019 Sep 05
ISSN1537-6605
Abstract

A precise genetic diagnosis is the single most important step for families with genetic disorders to enable personalized and preventative medicine. In addition to genetic variants in coding regions (exons) that can change a protein sequence, abnormal pre-mRNA splicing can be devastating for the encoded protein, inducing a frameshift or in-frame deletion/insertion of multiple residues. Non-coding variants that disrupt splicing are extremely challenging to identify. Stemming from an initial clinical discovery in two index Australian families, we define 25 families with genetic disorders caused by a class of pathogenic non-coding splice variant due to intronic deletions. These pathogenic intronic deletions spare all consensus splice motifs, though they critically shorten the minimal distance between the 5' splice-site (5'SS) and branchpoint. The mechanistic basis for abnormal splicing is due to biophysical constraint precluding U1/U2 spliceosome assembly, which stalls in A-complexes (that bridge the 5'SS and branchpoint). Substitution of deleted nucleotides with non-specific sequences restores spliceosome assembly and normal splicing, arguing against loss of an intronic element as the primary causal basis. Incremental lengthening of 5'SS-branchpoint length in our index EMD case subject defines 45-47 nt as the critical elongation enabling (inefficient) spliceosome assembly for EMD intron 5. The 5'SS-branchpoint space constraint mechanism, not currently factored by genomic informatics pipelines, is relevant to diagnosis and precision medicine across the breadth of Mendelian disorders and cancer genomics.

DOI10.1016/j.ajhg.2019.07.013
Alternate JournalAm. J. Hum. Genet.
PubMed ID31447096
PubMed Central IDPMC6731365
Grant ListUM1 HG008900 / HG / NHGRI NIH HHS / United States