Abstract
Eukaryotic gene expression involves tight coordination between transcription and pre–mRNA splicing; however, factors responsible for this coordination remain incompletely defined. Here, we explored the genetic, functional, and biochemical interactions of a likely coordinator, Npl3, an SR-like protein in Saccharomyces cerevisiae that we recently showed is required for efficient co-transcriptional recruitment of the splicing machinery. We surveyed the NPL3 genetic interaction space and observed a significant enrichment for genes involved in histone modification and chromatin remodeling. Specifically, we found that Npl3 genetically interacts with both Bre1, which mono-ubiquitinates histone H2B as part of the RAD6 Complex, and Ubp8, the de-ubiquitinase of the SAGA Complex. In support of these genetic data, we show that Bre1 physically interacts with Npl3 in an RNA–independent manner. Furthermore, using a genome-wide splicing microarray, we found that the known splicing defect of a strain lacking Npl3 is exacerbated by deletion of BRE1 or UBP8, a phenomenon phenocopied by a point mutation in H2B that abrogates ubiquitination. Intriguingly, even in the presence of wild-type NPL3, deletion of BRE1 exhibits a mild splicing defect and elicits a growth defect in combination with deletions of early and late splicing factors. Taken together, our data reveal a connection between Npl3 and an extensive array of chromatin factors and describe an unanticipated functional link between histone H2B ubiquitination and pre–mRNA splicing.
Highlights
Pre-mRNA splicing is a critical step in gene expression in which non-coding introns are removed from pre-mRNA and proteincoding exons are ligated together
Having recently shown that the Npl3 protein is involved in the recruitment of splicing factors to chromatin-associated transcripts, we performed a systematic screen for genetically interacting factors
We identified factors that influence the ubiquitin modification of histone H2B, a mark involved in transcription initiation and elongation
Summary
Pre-mRNA splicing is a critical step in gene expression in which non-coding introns are removed from pre-mRNA and proteincoding exons are ligated together. This process is performed by the spliceosome, a dynamic ribonucleoprotein particle that, in yeast, consists of 5 snRNAs and over 80 proteins that cooperate to recognize and splice target mRNAs [1]. While much has been learned about the molecular mechanisms of pre-mRNA splicing from in vitro systems [6], a full understanding of the regulation of spliceosome assembly and catalysis will require an appreciation of the complex landscape of the chromatinized template, along which splicing occurs
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