Benjamin Erickson scite author profile

The function of human TFIIH-associated Cdk7 in RNA polymerase II (Pol II) transcription and C-terminal domain (CTD) phosphorylation was investigated in analogue-sensitive Cdk7 as/as mutant cells where the kinase can be inhibited without disrupting TFIIH. We show that both Cdk7 and Cdk9/PTEFb contribute to phosphorylation of Pol II CTD Ser5 residues on transcribed genes. Cdk7 is also a major kinase of CTD Ser7 on Pol II at the c-fos and U snRNA genes. Furthermore, TFIIH and recombinant Cdk7-CycH-Mat1 as well as recombinant Cdk9-CycT1 phosphorylated CTD Ser7 and Ser5 residues in vitro. Inhibition of Cdk7 in vivo suppressed the amount of Pol II accumulated at 5 ends on several genes including c-myc, p21, and glyceraldehyde-3-phosphate dehydrogenase genes, indicating reduced promoter-proximal pausing or polymerase "leaking" into the gene. Consistent with a 5 pausing defect, Cdk7 inhibition reduced recruitment of the negative elongation factor NELF at start sites. A role of Cdk7 in regulating elongation is further suggested by enhanced histone H4 acetylation and diminished histone H4 trimethylation on lysine 36-two marks of elongation-within genes when the kinase was inhibited. Consistent with a new role for TFIIH at 3 ends, it was detected within genes and 3-flanking regions, and Cdk7 inhibition delayed pausing and transcription termination.Dynamic modification of the RNA polymerase II (Pol II) C-terminal domain (CTD) by phosphorylation and dephosphorylation plays important roles in controlling both transcription and cotranscriptional RNA processing (9, 31). There are 52 heptad repeats with the consensus sequence Y 1 S 2 P 3 T 4 S 5 P 6 S 7 in the human CTD that can be phosphorylated cotranscriptionally on serines 2, 5, and 7 (S2, S5, and S7, respectively) (6, 31). S5 phosphorylation normally occurs early in the transcription cycle coincident with initiation, whereas S2 phosphorylation predominates later, during elongation and termination (13,20). The complex pattern of heptad repeat phosphorylation serves in part to control binding of partner proteins, including elongation factors, RNA processing factors (31), and chromatin modifiers (25, 39). Ser5 phosphorylation enhances cotranscriptional mRNA capping (17), and Ser2 facilitates 3Ј-end formation by cleavage/polyadenylation (1, 4, 29). Ser7 phosphorylation has been specifically implicated in formation of U snRNA 3Ј ends but is also found on mRNA coding genes (10) (6). Exactly how S2, S5, and S7 phosphorylation affect initiation, elongation, and termination remains poorly understood.It is generally thought that the positive transcription elongation factor PTEFb (Cdk9/cyclin T [CycT]) is the principal S2 kinase and that Cdk7 associated with TFIIH is the principal S5 kinase (31,32,38). How Cdk7 affects CTD phosphorylation on metazoan genes in vivo is still an unresolved question, and the S7 kinase is yet to be identified. In the only previous investigation of Cdk7 effects on CTD phosphorylation at the site of transcription in a multicellular organism, phospho-S5 and t...

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Gene-specific RNA polymerase II phosphorylation and the CTD code

Kim

Erickson

Luo

et al. 2010

Nat Struct Mol Biol

198

253

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Dynamic phosphorylation of the RNA polymerase II CTD repeats (YS2PTS5PS7) is coupled to transcription and may act as a “code” that controls mRNA synthesis and processing. To examine the "code" in budding yeast, we mapped genome-wide CTD S2, 5 and 7 phosphorylations (PO4) and compared them with the CTD-associated termination factors, Nrd1 and Pcf11. CTD-PO4 dynamics are not scaled to the size of the gene. At 5’ ends, the onset of S2-PO4 is delayed by about 450 bases relative to S5-PO4, regardless of gene length. Phospho-CTD dynamics are gene-specific, with high S5/7-PO4 at the 5' end being characteristic of well-expressed genes with nucleosome-occupied promoters. Furthermore, the CTD kinases Kin28 and Ctk1 profoundly affect pol II distribution along genes in a highly gene-specific way. The "code" is therefore written differently on different genes, probably under the control of promoters. S7-PO4 is enriched on introns and at sites of Nrd1 accumulation suggesting that this modification may function in splicing and Nrd1 recruitment. Nrd1 and Pcf11 frequently co-localized, suggesting functional overlap between these terminators. Surprisingly, Pcf11 is also recruited to centromeres and pol III transcribed genes.

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Effects of Transcription Elongation Rate and Xrn2 Exonuclease Activity on RNA Polymerase II Termination Suggest Widespread Kinetic Competition

et al. 2015

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Summary The torpedo model of transcription termination asserts that the exonuclease Xrn2 attacks the 5′PO4-end exposed by nascent RNA cleavage and chases down the RNA polymerase. We tested this mechanism using a dominant-negative human Xrn2 mutant and found that it delayed termination genome-wide. Xrn2 nuclease inactivation caused strong termination defects downstream of most poly(A) sites and modest delays at some histone and U snRNA genes suggesting that the torpedo mechanism is not limited to poly(A) site-dependent termination. A central untested feature of the torpedo model is that there is kinetic competition between the exonuclease and the pol II elongation complex. Using pol II rate mutants, we found that slow transcription robustly shifts termination upstream, and fast elongation extends the zone of termination further downstream. These results suggest that kinetic competition between elongating pol II and the Xrn2 exonuclease is integral to termination of transcription on most human genes.

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Control of RNA Pol II Speed by PNUTS-PP1 and Spt5 Dephosphorylation Facilitates Termination by a “Sitting Duck Torpedo” Mechanism

et al. 2019

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mRNA Decapping Factors and the Exonuclease Xrn2 Function in Widespread Premature Termination of RNA Polymerase II Transcription

et al. 2012

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Summary We report a function of human mRNA decapping factors in control of transcription by RNA polymerase II. Decapping proteins Edc3, Dcp1a and Dcp2 and the termination factor, TTF2, co-immunoprecipitate with Xrn2, the nuclear 5′-3′ exonuclease “torpedo” that facilitates transcription termination at the 3′ ends of genes. Dcp1a, Xrn2 and TTF2 localize near transcription start sites (TSSs) by ChIP-seq. At genes with 5′ peaks of paused pol II, knockdown of decapping or termination factors, Xrn2 and TTF2, shifted polymerase away from the TSS toward upstream and downstream distal positions. This re-distribution of pol II is similar in magnitude to that caused by depletion of the elongation factor Spt5. We propose that coupled decapping of nascent transcripts and premature termination by the “torpedo” mechanism is a widespread mechanism that limits bidirectional pol II elongation. Regulated co-transcriptional decapping near promoter-proximal pause sites followed by premature termination could control productive pol II elongation.

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