Abstract
Alternative splicing (AS) provides a potent mechanism for increasing protein diversity and modulating gene expression levels. How alternate splice sites are selected by the splicing machinery and how AS is integrated into gene regulation networks remain important questions of eukaryotic biology. Here we report that polypyrimidine tract-binding protein 1 (Ptbp1/PTB/hnRNP-I) controls alternate 5′ and 3′ splice site (5′ss and 3′ss) usage in a large set of mammalian transcripts. A top scoring event identified by our analysis was the choice between competing upstream and downstream 5′ss (u5′ss and d5′ss) in the exon 18 of the Hps1 gene. Hps1 is essential for proper biogenesis of lysosome-related organelles and loss of its function leads to a disease called type 1 Hermansky-Pudlak Syndrome (HPS). We show that Ptbp1 promotes preferential utilization of the u5′ss giving rise to stable mRNAs encoding a full-length Hps1 protein, whereas bias towards d5′ss triggered by Ptbp1 down-regulation generates transcripts susceptible to nonsense-mediated decay (NMD). We further demonstrate that Ptbp1 binds to pyrimidine-rich sequences between the u5′ss and d5′ss and activates the former site rather than repressing the latter. Consistent with this mechanism, u5′ss is intrinsically weaker than d5′ss, with a similar tendency observed for other genes with Ptbp1-induced u5′ss bias. Interestingly, the brain-enriched Ptbp1 paralog Ptbp2/nPTB/brPTB stimulated the u5′ss utilization but with a considerably lower efficiency than Ptbp1. This may account for the tight correlation between Hps1 with Ptbp1 expression levels observed across mammalian tissues. More generally, these data expand our understanding of AS regulation and uncover a post-transcriptional strategy ensuring co-expression of a subordinate gene with its master regulator through an AS-NMD tracking mechanism.
Highlights
Eukaryotes rely on post-transcriptional control of their gene expression programs to a remarkable extent
A prevalent posttranscriptional mechanism regulating mRNA abundance involves coupling between alternative splicing (AS) and nonsense-mediated decay (NMD), a Mammalian gene expression is extensively controlled at the post-transcriptional level and understanding of the underlying mechanisms can provide important biomedical insights
After confirming functionality of this approach with training RNA sequencing (RNA-seq) datasets from neuroblastoma CAD and fibrosarcoma L929 cells (Fig. S1 and Tables S1 and S2) we repeated the analysis for our RNA-seq datasets obtained for CAD cells transfected with control siRNA, Ptbp1-specific siRNAs or a mixture of siRNAs against Ptbp1 and its brain-enriched paralog Ptbp2 with a largely overlapping AS regulation preferences [26,36,37]
Summary
Eukaryotes rely on post-transcriptional control of their gene expression programs to a remarkable extent. Distinct AS patterns include singular and mutually exclusive cassette exons, alternative 59- and 39-terminal exons, intron retention events, and alternate 59 and 39 splice site (59ss and 39ss) choice [1,5] Of these, the latter two categories (A5C and A3C), involve alternative utilization of exonic termini and constitute a major part of tissuespecific AS programs [6,7]. HnRNP binding between u59ss and d59ss alternatives could theoretically bias A5C towards the u59ss by either repressing the d59ss, stimulating the u59ss or both It is generally unclear which of these three possibilities is realized in natural contexts since most published studies on A5C regulation mechanisms rely largely on recombinant or/and in vitro approaches [11,12,13]
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