Abstract
Alternative splicing diversifies mRNA transcripts in human cells. While the spliceosome pairs exons with a high degree of accuracy, the rates of rare aberrant and non-canonical pre-mRNA splicing have not been evaluated at the nucleotide level to determine the quantity and identity of these events across splice junctions. Using ultra-deep sequencing the frequency of aberrant and non-canonical splicing events for three splice junctions flanking exon 7 of SMN1 were determined at single nucleotide resolution. After correction for background noise introduced by PCR amplification and sequencing steps, pre-mRNA splicing was shown to maintain a low overall rate of aberrant and non-canonically spliced events. Several previously unannotated splicing events across 3 exon|intron junctions in SMN1 were identified. Mutations within SMN exon 7 were shown to affect splicing fidelity by modulating RNA secondary structures, by altering the binding site of regulatory proteins and by changing the 5’ splice site strength. Mutations also create a truncated SMN1 exon 7 through the introduction of a de novo non-canonical 5’ splice site. The results from the ultra-deep sequencing approach highlight the impressive fidelity of pre-mRNA splicing and demonstrate that the immediate sequence context around splice sites is the main driving force behind non-canonical splice site pairing.
Highlights
Splicing is a complex process requiring hundreds of proteins to work in concert with proper regulation [1]
Many mRNA isoforms are generated from a single gene as a result of splicing regulation, which may be caused by systemic feedback or tissue-specific expression of splicing regulators [5,6]
Other alternative mRNA isoforms may be the result of erroneous splice site pairing, referred to as non-canonical splice sites, which may result in the generation of aberrant mRNA isoforms [7]
Summary
Splicing is a complex process requiring hundreds of proteins to work in concert with proper regulation [1]. A pre-mRNA transcript from a single gene can be alternatively spliced to generate many mRNA variants. Differential pre-mRNA processing contributes significantly to genetic variability. It is estimated that transcripts from ~86–88% of multi-exon genes undergo alternative splicing [2,3,4]. Many mRNA isoforms are generated from a single gene as a result of splicing regulation, which may be caused by systemic feedback or tissue-specific expression of splicing regulators [5,6]. Other alternative mRNA isoforms may be the result of erroneous splice site pairing, referred to as non-canonical splice sites, which may result in the generation of aberrant mRNA isoforms [7]. It has been shown that the most common form of non-
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