Modelling Reveals Kinetic Advantages of Co-Transcriptional Splicing

Messenger RNA splicing is an essential and complex process for the removal of intron sequences. Whereas the composition of the splicing machinery is mostly known, the kinetics of splicing, the catalytic activity of splicing factors and the interdependency of transcription, splicing and mRNA 3′ end formation are less well understood. We propose a stochastic model of splicing kinetics that explains data obtained from high-resolution kinetic analyses of transcription, splicing and 3′ end formation during induction of an intron-containing reporter gene in budding yeast. Modelling reveals co-transcriptional splicing to be the most probable and most efficient splicing pathway for the reporter transcripts, due in part to a positive feedback mechanism for co-transcriptional second step splicing. Model comparison is used to assess the alternative representations of reactions. Modelling also indicates the functional coupling of transcription and splicing, because both the rate of initiation of transcription and the probability that step one of splicing occurs co-transcriptionally are reduced, when the second step of splicing is abolished in a mutant reporter

Genome-Wide Distribution of RNA-DNA Hybrids Identifies RNase H Targets in tRNA Genes, Retrotransposons and Mitochondria

During transcription, the nascent RNA can invade the DNA template, forming extended RNA-DNA duplexes (R-loops). Here we employ ChIP-seq in strains expressing or lacking RNase H to map targets of RNase H activity throughout the budding yeast genome. In wild-type strains, R-loops were readily detected over the 35S rDNA region, transcribed by Pol I, and over the 5S rDNA, transcribed by Pol III. In strains lacking RNase H activity, R-loops were elevated over other Pol III genes, notably tRNAs, SCR1 and U6 snRNA, and were also associated with the cDNAs of endogenous TY1 retrotransposons, which showed increased rates of mobility to the 5'-flanking regions of tRNA genes. Unexpectedly, R-loops were also associated with mitochondrial genes in the absence of RNase H1, but not of RNase H2. Finally, R-loops were detected on actively transcribed protein-coding genes in the wild-type, particularly over the second exon of spliced ribosomal protein genes

Global analysis of nascent RNA reveals transcriptional pausing in terminal exons

Pre-mRNA splicing is catalyzed by the spliceosome, which can assemble on pre-mRNA cotranscriptionally. However, whether splicing generally occurs during transcription has not been addressed. Indeed, splicing catalysis is expected to occur posttranscriptionally in yeast, where the shortness of terminal exons should leave insufficient time for splicing. Here, we isolate endogenous S. cerevisiae nascent RNA and determine gene-specific splicing efficiencies and transcription profiles, using high-density tiling microarrays. Surprisingly, we find that splicing occurs cotranscriptionally for the majority of intron-containing genes. Analysis of transcription profiles reveals Pol II pausing within the terminal exons of these genes. Intronless and inefficiently spliced genes lack this pause. In silico simulations of transcription and splicing kinetics confirm that this pausing event provides sufficient time for splicing before termination. The discovery of terminal exon pausing demonstrates functional coupling of transcription and splicing near gene ends

Pause locally, splice globally.

Most eukaryotic protein-coding transcripts contain introns, which vary in number and position along the transcript body. Intron removal through pre-mRNA splicing is tightly linked to transcription by RNA polymerase II as it translocates along each gene. Here, we review recent evidence that transcription and splicing are functionally coupled. We focus on how RNA polymerase II elongation rates impact splicing through local regulation and transcriptional pausing within genes. Emerging concepts of how splicing-related changes in elongation might be achieved are highlighted. We place the interplay between transcription and splicing in the context of chromatin where nucleosome positioning influences elongation, and histone modifications participate directly in the recruitment of splicing regulators to nascent transcripts

Introduction to Cotranscriptional RNA Splicing

The discovery that many intron-containing genes can be cotranscriptionally spliced has led to an increased understanding of how splicing and transcription are intricately intertwined. Cotranscriptional splicing has been demonstrated in a number of different organisms and has been shown to play roles in coordinating both constitutive and alternative splicing. The nature of cotranscriptional splicing suggests that changes in transcription can dramatically affect splicing, and new evidence suggests that splicing can, in turn, influence transcription. In this chapter, we discuss the mechanisms and consequences of cotranscriptional splicing and introduce some of the tools used to measure this process

CDK9 inhibitors define elongation checkpoints at both ends of RNA polymerase II–transcribed genes

Transcription through early-elongation checkpoints requires phosphorylation of negative transcription elongation factors (NTEFs) by the cyclin-dependent kinase (CDK)9. Using CDK9 inhibitors and global run-on sequencing (GRO-seq), we have mapped CDK9 inhibitor-sensitive checkpoints genome-wide in human (Homo sapiens) cells. Our data indicate that early-elongation checkpoints are a general feature of RNA polymerase (pol) II-transcribed human genes and occur independently of polymerase stalling. Pol II that has negotiated the early-elongation checkpoint can elongate in the presence of inhibitors but, remarkably, terminates transcription prematurely close to the terminal polyadenylation (poly(A)) site. Our analysis has revealed a hitherto-unsuspected poly(A)-associated elongation checkpoint, which has major implications for the regulation of gene expression. Interestingly, the pattern of modification of the carboxyl-terminal domain (CTD) of pol II terminated at this novel checkpoint largely mirrors the pattern normally found downstream of the poly(A) site, suggesting common mechanisms of termination