TATA-binding Protein and Transcription Factor IIB Induce Transcript Slipping during Early Transcription by RNA Polymerase II

Gilman, Benjamin; Drullinger, Linda F.; Kugel, Jennifer F.; Goodrich, James A.

doi:10.1074/jbc.m900019200

Cited by 10 publications

(12 citation statements)

References 27 publications

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“…In addition, the E51R:R66E double mutant did not produce the 11-nt transcript in the presence of CpA (lane 10). Like results reported recently with a similar system, slippage was greatly reduced by priming with the CpA dinucleotide (44). We conclude that the defect in transcriptional activity of mutations in residues Glu-51 and Arg-66 is independent of the ability to recognize the start site.…”

Section: Change-of-charge Mutants In Minimal Promotersupporting

confidence: 68%

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Minimal Promoter Systems Reveal the Importance of Conserved Residues in the B-finger of Human Transcription Factor IIB

Thompson

Glaser

Foley

et al. 2009

Journal of Biological Chemistry

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The "B-finger" of transcription factor IIB (TFIIB) is highly conserved and believed to play a role in the initiation process. We performed alanine substitutions across the B-finger of human TFIIB, made change-of-charge mutations in selected residues, and substituted the B-finger sequence from other organisms. Mutant proteins were examined in two minimal promoter systems (containing only RNA polymerase II, TATAbinding protein, and TFIIB) and in a complex system, using TFIIB-immunodepleted HeLa cell nuclear extract (NE). Mutations in conserved residues located on the sides of the B-finger had the greatest effect on activity in both minimal promoter systems, with mutations in residues Glu-51 and Arg-66 eliminating activity. The double change-of-charge mutant (E51R: R66E) did not show activity in either minimal promoter system. Mutations in the nonconserved residues at the tip of the B-finger did not significantly affect activity. However, all of the mutations in the B-finger showed at least 25% activity in the HeLa cell NE. Chimeric proteins, containing B-finger sequences from species with conserved residues on the side of the B-finger, showed wild-type activity in a minimal promoter system and in the HeLa cell NE. However, chimeric proteins whose sequence showed divergence on the sides of the B-finger had reduced activity. Transcription factor IIF (TFIIF) partially restored activity of the inactive mutants in the minimal promoter system, suggesting that TFIIF in HeLa cell NE helps to rescue the inactive mutations by interacting with either the B-finger or another component of the initiation complex that is influenced by the B-finger.The RNA polymerase II (RNAP II) 2 initiation complex is extremely complicated and, thus, very difficult to meaningfully dissect. Genes that are transcribed into mRNA by RNAP II generally require five general transcription factors (TFs), designated TFIIB, TFIID, TFIIE, TFIIF, and TFIIH (reviewed in Refs. 1-5). However, arguments have been made to include the "elongation" factor TFIIS (6) and the mediator complex (7) in the list of "general" transcription factors. RNAP II and most of the TFs are multimeric protein complexes. If all proteins contained in the yeast (Saccharomyces cerevisiae) RNAP II initiation complex were considered, the count of ϳ60 polypeptides would have a mass of ϳ3 MDa (8). The high resolution crystal structure of yeast RNAP II has provided invaluable insight into the topology of the RNAP II transcription initiation complex (9). Furthermore, the crystal structures of bacterial RNAP (10, 11) and RNAP from an archaeal organism (12) establish that RNAP from all three domains of life (Bacteria, Archaea, and Eukarya) show high conservation of overall structure. However, many mechanistic details of the transcription process have yet to be determined.TFIIB functions as a single polypeptide with a two-domain structure. The C-terminal domain of TFIIB (cTFIIB) contains an imperfect direct repeat motif. The co-crystal structure of cTFIIB with the DNA-bound TATA-binding protein ...

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Section: Change-of-charge Mutants In Minimal Promotersupporting

confidence: 68%

“…The major transcript from this promoter is a 10-nt G-less RNA. Longer and shorter minor transcripts are also present, indicating the "slippage" of the transcription complex that has been documented by others (43,44) and is dependent upon the presence of TBP and TFIIB (44).…”

Section: Resultsmentioning

confidence: 94%

Minimal Promoter Systems Reveal the Importance of Conserved Residues in the B-finger of Human Transcription Factor IIB

Thompson

Glaser

Foley

et al. 2009

Journal of Biological Chemistry

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“…Candidate macromolecules include RNA polymerase binding factors. Interestingly, recent studies revealed that transcript slippage during initiation by human RNA polymerase II can be induced by the TATA-binding protein and transcription factor TFIIB [9 •• ]. Other potential signals are factors that control transcription pausing, particularly during transcription elongation.…”

Section: Discussionmentioning

confidence: 99%

“…The mechanism apparently involves one or more rounds of a one-base upstream shift of the transcript so that the same nucleotide in the template specifies multiple residues in the transcript [7,8]. It has also been shown that reiterative transcription can occur within dinucleotide [9 •• ,10] and trinucleotide [11] repeat sequences in the template, apparently via two-base and three-base upstream shifts of the transcript, respectively. Reiterative transcription can occur during initiation, elongation, or termination and result in transcripts that are immediately released from the transcription complex [12,13 •• ] or are extended by normal elongation after a switch to nonreiterative nucleotide addition [14,15 •• ].…”

Section: Introductionmentioning

confidence: 99%

Regulation of gene expression by reiterative transcription

Turnbough¹

2011

Current Opinion in Microbiology

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Gene regulation involves many different types of transcription control mechanisms, including mechanisms based on reiterative transcription in which nucleotides are repetitively added to the 3′ end of a nascent transcript due to upstream transcript slippage. In these mechanisms, reiterative transcription is typically modulated by interactions between RNA polymerase and its nucleoside triphosphate substrates without the involvement of regulatory proteins. This review describes the current state of knowledge of gene regulation involving reiterative transcription. It focuses on the methods by which reiterative transcription is controlled and emphasizes the different fates of transcripts produced by this reaction. The review also includes a discussion of possible new and fundamentally different mechanisms of gene regulation that rely on conditional reiterative transcription.

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“…16 Several studies suggest a role for TFIIB in promoter escape by pol II. 11,14,17,18 In early pol II transcription, short DNA-RNA hybrids are unstable and are transiently ejected from the enzyme (abortive transcription initiation). It has been proposed that the TFIIB B-finger/B-reader loop stabilizes the short RNA transcripts with pol II until the growing RNA reaches seven nucleotides and TFIIB is triggered to release from the initiation apparatus as pol II enters the productive elongation complex (promoter escape).…”

mentioning

confidence: 99%