Project description:Multiple types of cellular stress induce RNA polymerase II (Pol II) to read through normal termination sites at mRNA genes, causing long downstream regions to be transcribed. We observed strong read-through transcription downstream of thousands of genes after heat shock. Additionally, the 3’ Pol II pause that normally occurs during termination was globally lost. Heat shock also increased phosphorylation of Tyr1 and Ser2 residues in the Pol II C-terminal domain (CTD) at the 3’ ends of genes, with smaller increases observed at genes with read-through transcription. We found that 3’ RNA cleavage, a key step of transcription termination, was defective at read-through genes after heat shock; however, the CPSF73 endonuclease responsible for cleavage remained at the 3’ ends of genes. Over-expressing an activator of CPSF73 activity, RBBP6, during heat shock rescued the loss of cleavage and attenuated read-through transcription. Our data suggest that heat shock alters Pol II speed, CTD phosphorylation, and CPSF73 activity via RBBP6, contributing to a multifaceted mechanism that enables transcription to continue far downstream of normal termination sites during cellular stress.

Project description:The so-called allosteric and torpedo models have been used for the past thirty years to explain how transcription terminates on protein-coding genes. The former invokes conformational changes in the transcription complex and the latter involves degradation of the downstream product of poly(A) signal (PAS) processing. Here, we describe a single mechanism incorporating features of both models. We show that CPSF73 is indispensable for transcriptional termination on protein-coding and its loss causes profound read-through genome-wide. CPSF73 functions upstream of allosteric modifications to the elongation complex that cause Pol II to slow down after the PAS. This state is enriched by rapid depletion of XRN2 and promoted by protein phosphatase 1 (PP1), the inhibition of which confers runaway read-through in the absence of XRN2. These allosteric changes facilitate XRN2-dependent termination, by aiding its capture of Pol II, rather than constituting a termination pathway in themselves. Our experiments unify the long-standing allosteric and torpedo models for transcriptional termination.

Project description:CPSF73 activation and 3’ Pol II pausing are lost during read-through transcription after heat shock

Project description:Termination is a ubiquitous phase in every transcription cycle but is incompletely understood and a subject of debate. We have used gene editing as a new approach to address its mechanism through engineered conditional depletion of the 5’-3’ exonuclease, Xrn2, or the polyadenylation signal (PAS) endonuclease, CPSF73. The ability to rapidly control Xrn2 reveals a clear and general role for it in co-transcriptional degradation of 3’ flanking region RNA and transcriptional termination. This defect is characterised genome-wide, at high resolution, using native elongating transcript sequencing (mNET-seq). An Xrn2 effect on termination requires prior RNA cleavage and we provide evidence for this by showing that catalytically inactive CPSF73 cannot restore termination to cells lacking functional CPSF73. Notably, Xrn2 plays no significant role in either Histone or snRNA gene termination even though both RNA classes undergo 3’ end cleavage. In sum, efficient termination on most protein-coding genes involves CPSF73 mediated RNA cleavage and co-transcriptional degradation of polymerase-associated RNA by Xrn2. However, as CPSF73 loss caused more extensive read-through transcription than Xrn2 elimination, it likely plays a more underpinning role in termination.

Project description:CPSF73 activation and 3’ Pol II pausing are lost during read-through transcription after heat shock [ChIP-seq]

Project description:CPSF73 activation and 3’ Pol II pausing are lost during read-through transcription after heat shock [RNA-seq]

Project description:Termination of protein-coding gene transcription by RNA polymerase II (Pol II) depends on endonucleolytic cleavage at the poly(A) site and the activity of a 5’->3’ “torpedo” exoribonuclease. Other Pol II transcripts also undergo endonucleolytic cleavage suggesting common themes for its termination. Nevertheless, many RNA polymerases employ intrinsic/allosteric termination that directly defines transcript 3’ ends. We have analysed termination of snRNA transcription in humans, which utilises the endoribonucleolytic integrator complex. Integrator is involved, but termination continues after its depletion. This implicates additional mechanisms and shows that endo- and 5’->3’ exonuclease activities are not necessarily a basis for all Pol II termination. Although the alternative process acts as a failsafe in the absence of integrator it contributes significantly to snRNA termination in the natural situation. Long-read sequencing reveals its products to have stochastic 3’ ends that are terminated before integrator cleavage, ruling out 5’->3’ exonuclease contribution(s) and supporting an allosteric/intrinsic mechanism. Termination of some snRNA transcription occurs at T-runs further indicating common principles between this mechanism and those used by other RNA polymerases.

Project description:We have generated single-nucleotide resolution, nascent transcription profiles from HeLa cells by developing Native Elongation Transcript sequencing technology for mammalian chromatin (mNET-seq). Our extensive data sets provide a substantial resource to study mammalian nascent transcript profiles. We reveal unanticipated phosphorylation states for RNA polymerase II C-terminal domain (Pol II CTD) at both gene ends. We also observe that following 5’ splice site cleavage by the spliceosome, upstream exon transcripts are tethered to Pol II CTD phosphorylated on the serine 5 position (S5P) which is accumulated over downstream exons. We further show that depletion of termination factors substantially reduces Pol II pausing at gene ends leading to termination defects. Remarkably termination factors play an additional promoter role by restricting non-productive RNA synthesis and redistributing Pol II CTD S2P to promoters. These data demonstrate that CTD phosphorylation is more dynamic and variably distributed across mammalian transcription units than previously envisaged. To monitor nascent RNA within the mammalian Pol II complex, and its association with different CTD phosphorylation states, we employed mNET-seq methodology on HeLa cells, complemented with direct sequencing of chromatin-bound RNA (ChrRNA-seq). mNET-seq was preformed using the antibodies 8WG16, CMA602, CMA603 and CMA601, which are specific for unphosphorylated CTD, Ser2 phosphorylation, Ser5 phosphorylation and all CTD isoforms, respectively. In another experiment, to evaluate the effect of transcription termination factors in nascent RNA production by Pol II, mNET-seq and complemented with ChrRNA-seq was preformed on HeLa cells transfected with siRNA against PTBP1, CPSF73, CstF64+CstF64tau or Xrn2, and the gene profiles were compared with profiles from HeLa transfected with siRNA for Luciferase generated by the same protocol.

Project description:The exonuclease torpedo Xrn2 loads onto nascent RNA 5’-PO4 ends and chases down pol II to promote termination downstream of polyA sites. We report that Xrn2 is recruited to pre-initiation complexes and “travels” to 3’ ends of genes. Mapping of 5’-PO4 ends in nascent RNA identified Xrn2 loading sites stabilized by an active site mutant, Xrn2(D235A). Xrn2 loading sites are ~2-20 bases downstream of where CPSF73 cleaves at polyA sites and histone 3’ ends. We propose that processing of all mRNA 3’ ends comprises cleavage and limited 5’-3’ trimming by CPSF73 followed by hand-off to Xrn2. A similar hand-off occurs at tRNA 3’ ends where co-transcriptional RNAseZ cleavage generates novel Xrn2 substrates. Exonuclease-dead Xrn2 increased transcription in 3’ flanking regions by inhibiting polyA site-dependent termination. Surprisingly, the mutant Xrn2 also rescued transcription in promoter-proximal regions to the same extent as in 3’ flanking regions. eNET-seq revealed Xrn2-mediated degradation of sense and anti-sense nascent RNA within a few bases of the TSS where 5’-PO4 ends may be generated by decapping or endonucleolytic cleavage. These results suggest that a major fraction of pol II complexes terminate prematurely close to the start site under normal conditions by an Xrn2-mediated torpedo mechanism.

Project description:Ambient temperature is one of the most important environment factors that direct all organisms for morphogenesis, metabolisms and growth. Plants have evolved efficient mechanisms adapting temperature fluctuation such as heat stress response (HSR). Although transcriptional regulatory network of plant HSR has been established, little is known on the genome-wide transcriptional changes within first several minutes upon heat shock (HS). To precisely measure the very first wave of transcriptional response to HS, we investigated the nascent RNA and mature mRNA from plant leaf tissue exposure to 5-min HS treatment using global run-on sequencing (GRO-seq) and RNA sequencing (RNA-seq) methods. We found that only a small group of genes were both up- or down-regulated at nascent RNA and mRNA levels. Primed plants that already exposed to a mild heat stress induced a more drastic transcriptomic alteration than naïve plants which had not experienced a heat stress. Group A1 HEAT SHOCK TRANSCRIPTION FACTORs (HsfA1s) are the major transcription factors in charge of the very early transcriptional HSR. Within 5-minute HS, we also observed that: 1) Engaged RNA polymerase II (Pol II) was accumulated downstream of transcription start sites; 2) 5' pause-release is a rate limiting step for induction of some heat shock protein genes; 3) A good number of genes switched transcription modes; 4) Pervasive read-through was induced at terminators. Plants' HSR is transcriptionally very quick. GRO-seq is sensitive and robust to detect quick response to HS. Heat stress memory takes place at multiple steps of transcription cycles such as Pol II recruitment, 5' pausing, elongation and termination.