Templated nucleoside triphosphate binding to a noncatalytic site on RNA polymerase regulates transcription

Kennedy, Scott R.; Erie, Dorothy A.

doi:10.1073/pnas.1011274108

Cited by 17 publications

(24 citation statements)

References 55 publications

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“…There is a strong correlation between the stable sequestration of the cognate NTP in the RNAP II active site and the magnitude of the incoming NTP effect on the pre- to post-translocated border transition in the exonuclease III assay [20,36], showing that the post-translocated state is stabilized by binding of the cognate NTP in the active site [8]. Alternatively, the apparent stimulation of translocation might reflect an allosteric effect of the incoming NTP previously proposed for mammalian RNAP II [4,37] and Ec RNAP [6,7,38]. …”

Section: Resultsmentioning

confidence: 99%

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Molecular dynamics and mutational analysis of the catalytic and translocation cycle of RNA polymerase

et al. 2012

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BackgroundDuring elongation, multi-subunit RNA polymerases (RNAPs) cycle between phosphodiester bond formation and nucleic acid translocation. In the conformation associated with catalysis, the mobile “trigger loop” of the catalytic subunit closes on the nucleoside triphosphate (NTP) substrate. Closing of the trigger loop is expected to exclude water from the active site, and dehydration may contribute to catalysis and fidelity. In the absence of a NTP substrate in the active site, the trigger loop opens, which may enable translocation. Another notable structural element of the RNAP catalytic center is the “bridge helix” that separates the active site from downstream DNA. The bridge helix may participate in translocation by bending against the RNA/DNA hybrid to induce RNAP forward movement and to vacate the active site for the next NTP loading. The transition between catalytic and translocation conformations of RNAP is not evident from static crystallographic snapshots in which macromolecular motions may be restrained by crystal packing.ResultsAll atom molecular dynamics simulations of Thermus thermophilus (Tt) RNAP reveal flexible hinges, located within the two helices at the base of the trigger loop, and two glycine hinges clustered near the N-terminal end of the bridge helix. As simulation progresses, these hinges adopt distinct conformations in the closed and open trigger loop structures. A number of residues (described as “switch” residues) trade atomic contacts (ion pairs or hydrogen bonds) in response to changes in hinge orientation. In vivo phenotypes and in vitro activities rendered by mutations in the hinge and switch residues in Saccharomyces cerevisiae (Sc) RNAP II support the importance of conformational changes predicted from simulations in catalysis and translocation. During simulation, the elongation complex with an open trigger loop spontaneously translocates forward relative to the elongation complex with a closed trigger loop.ConclusionsSwitching between catalytic and translocating RNAP forms involves closing and opening of the trigger loop and long-range conformational changes in the atomic contacts of amino acid side chains, some located at a considerable distance from the trigger loop and active site. Trigger loop closing appears to support chemistry and the fidelity of RNA synthesis. Trigger loop opening and limited bridge helix bending appears to promote forward nucleic acid translocation.

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Section: Resultsmentioning

confidence: 99%

“…Two models have been put forward for translocation. In one model, incoming NTP substrates act as allosteric effectors driving forward translocation [3-7]. In another model, thermally driven oscillations of RNAP elements stimulate nucleic acids to slide forward [8-11].…”

Section: Introductionmentioning

confidence: 99%

Molecular dynamics and mutational analysis of the catalytic and translocation cycle of RNA polymerase

et al. 2012

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“…Second, the location of a templated, non-hydrolysable NTP analog present in a conformation not thought to efficiently support catalysis has been interpreted as a pre-insertion (PI) site [25]. Third biochemical data from kinetic analyses on RNAP and Pol II examining next-nucleotide-dependent substrate effects on transcription have been interpreted to support pre-loading of substrates base-pairing with the DNA template in positions downstream of the active site [26-28]. Binding of substrates in downstream templated positions may allosterically affect msRNAP activity without necessarily transferring those exact substrates to the active site.…”

Section: Substrate Selection and Catalysis By Pol IImentioning

confidence: 99%

Basic mechanisms of RNA polymerase II activity and alteration of gene expression in Saccharomyces cerevisiae

Kaplan

2013

Biochimica et Biophysica Acta (BBA) - Gene Regulatory Mechanism

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Transcription by RNA Polymerase II (Pol II), and all RNA polymerases for that matter, may be understood as comprising two cycles. The first cycle relates to the basic mechanism of the transcription process wherein Pol II must select the appropriate nucleoside triphosphate (NTP) substrate complementary to the DNA template, catalyze phosphodiester bond formation, and translocate to the next position on the DNA template. Performing this cycle in an iterative fashion allows the synthesis of RNA chains that can be over one million nucleotides in length in some larger eukaryotes. Overlaid upon this enzymatic cycle, transcription may be divided into another cycle of three phases: initiation, elongation, and termination. Each of these phases has a large number of associated transcription factors that function to promote or regulate the gene expression process. Complicating matters, each phase of the latter transcription cycle are coincident with cotranscriptional RNA processing events. Additionally, transcription takes place within a highly dynamic and regulated chromatin environment. This chromatin environment is radically impacted by active transcription and associated chromatin modifications and remodeling, while also functioning as a major platform for Pol II regulation. This review will focus on our basic knowledge of the Pol II transcription mechanism, and how altered Pol II activity impacts gene expression in vivo in the model eukaryote Saccharomyces cerevisiae.

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“…In addition, a non-templated NTP site was observed [47], but its functional significance remains unclear. Further, a DNA-templated NTP site at position + 2, downstream of the active site, was proposed based on kinetic studies [65,66], but was detected neither biochemically nor structurally thus far.…”

Section: Nucleotide Selection and Additionmentioning

confidence: 99%

Structural basis of transcription elongation

Martínez-Rucobo

Cramer

2013

Biochimica et Biophysica Acta (BBA) - Gene Regulatory Mechanism

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For transcription elongation, all cellular RNA polymerases form a stable elongation complex (EC) with the DNA template and the RNA transcript. Since the millennium, a wealth of structural information and complementary functional studies provided a detailed three-dimensional picture of the EC and many of its functional states. Here we summarize these studies that elucidated EC structure and maintenance, nucleotide selection and addition, translocation, elongation inhibition, pausing and proofreading, backtracking, arrest and reactivation, processivity, DNA lesion-induced stalling, lesion bypass, and transcriptional mutagenesis. In the future, additional structural and functional studies of elongation factors that control the EC and their possible allosteric modes of action should result in a more complete understanding of the dynamic molecular mechanisms underlying transcription elongation. This article is part of a Special Issue entitled: RNA polymerase II Transcript Elongation.

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Templated nucleoside triphosphate binding to a noncatalytic site on RNA polymerase regulates transcription

Cited by 17 publications

References 55 publications

Molecular dynamics and mutational analysis of the catalytic and translocation cycle of RNA polymerase

Molecular dynamics and mutational analysis of the catalytic and translocation cycle of RNA polymerase

Basic mechanisms of RNA polymerase II activity and alteration of gene expression in Saccharomyces cerevisiae

Structural basis of transcription elongation

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