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.

Widespread Transcriptional Readthrough Caused by Nab2 Depletion Leads to Chimeric Transcripts with Retained Introns.

Nascent RNA sequencing has revealed that pre-mRNA splicing can occur shortly after introns emerge from RNA polymerase II (RNA Pol II). Differences in co-transcriptional splicing profiles suggest regulation by cis- and/or trans-acting factors. Here, we use single-molecule intron tracking (SMIT) to identify a cohort of regulators by machine learning in budding yeast. Of these, Nab2 displays reduced co-transcriptional splicing when depleted. Unexpectedly, these splicing defects are attributable to aberrant "intrusive" transcriptional readthrough from upstream genes, as revealed by long-read sequencing. Transcripts that originate from the intron-containing gene's own transcription start site (TSS) are efficiently spliced, indicating no direct role of Nab2 in splicing per se. This work highlights the coupling between transcription, splicing, and 3' end formation in the context of gene organization along chromosomes. We conclude that Nab2 is required for proper 3' end processing, which ensures gene-specific control of co-transcriptional RNA processing.

TALE-directed local modulation of H3K9 methylation shapes exon recognition.

In search for the function of local chromatin environment on pre-mRNA processing we established a new tool, which allows for the modification of chromatin using a targeted approach. Using Transcription Activator-Like Effector domains fused to histone modifying enzymes (TALE-HME), we show locally restricted alteration of histone methylation modulates the splicing of target exons. We provide evidence that a local increase in H3K9 di- and trimethylation promotes inclusion of the target alternative exon, while demethylation by JMJD2D leads to exon skipping. We further demonstrate that H3K9me3 is localized on internal exons genome-wide suggesting a general role in splicing. Consistently, targeting of the H3K9 demethylase to a weak constitutive exon reduced co-transcriptional splicing. Together our data show H3K9 methylation within the gene body is a factor influencing recognition of both constitutive and alternative exons.

First exon length controls active chromatin signatures and transcription.

Here, we explore the role of splicing in transcription, employing both genome-wide analysis of human ChIP-seq data and experimental manipulation of exon-intron organization in transgenic cell lines. We show that the activating histone modifications H3K4me3 and H3K9ac map specifically to first exon-intron boundaries. This is surprising, because these marks help recruit general transcription factors (GTFs) to promoters. In genes with long first exons, promoter-proximal levels of H3K4me3 and H3K9ac are greatly reduced; consequently, GTFs and RNA polymerase II are low at transcription start sites (TSSs) and exhibit a second, promoter-distal peak from which transcription also initiates. In contrast, short first exons lead to increased H3K4me3 and H3K9ac at promoters, higher expression levels, accuracy in TSS usage, and a lower frequency of antisense transcription. Therefore, first exon length is predictive for gene activity. Finally, splicing inhibition and intron deletion reduce H3K4me3 levels and transcriptional output. Thus, gene architecture and splicing determines transcription quantity and quality as well as chromatin signatures.

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.