Molecular structures of unbound and transcribing RNA polymerase III

Hoffmann, N.A.; Jakobi, Arjen J.; Moreno-Morcillo, María; Glatt, Sebastian; Kosiński, Jan; Hagen, Wim J. H.; Sachse, Carsten; Müller, Christoph W.

doi:10.1038/nature16143

Cited by 169 publications

(288 citation statements)

References 73 publications

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“…Electron microscopy analysis of free RNAPII in solution further supported the notion of a conformational flexible clamp, suggesting that Rpb4/7 shifts the equilibrium between the closed and collapsed state of the clamp to the closed state (9). Moreover, the clamp of RNAPIII could recently be imaged in two distinct conformations that differ in the orientation of the stalk and the opening of the DNA cleft (10). These data have led to the theory that the stalk influences the clamp position.…”

mentioning

confidence: 99%

TFE and Spt4/5 open and close the RNA polymerase clamp during the transcription cycle

Schulz

Gietl

Smollett

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Transcription is an intrinsically dynamic process and requires the coordinated interplay of RNA polymerases (RNAPs) with nucleic acids and transcription factors. Classical structural biology techniques have revealed detailed snapshots of a subset of conformational states of the RNAP as they exist in crystals. A detailed view of the conformational space sampled by the RNAP and the molecular mechanisms of the basal transcription factors E (TFE) and Spt4/5 through conformational constraints has remained elusive. We monitored the conformational changes of the flexible clamp of the RNAP by combining a fluorescently labeled recombinant 12-subunit RNAP system with single-molecule FRET measurements. We measured and compared the distances across the DNA binding channel of the archaeal RNAP. Our results show that the transition of the closed to the open initiation complex, which occurs concomitant with DNA melting, is coordinated with an opening of the RNAP clamp that is stimulated by TFE. We show that the clamp in elongation complexes is modulated by the nontemplate strand and by the processivity factor Spt4/5, both of which stimulate transcription processivity. Taken together, our results reveal an intricate network of interactions within transcription complexes between RNAP, transcription factors, and nucleic acids that allosterically modulate the RNAP during the transcription cycle.

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mentioning

confidence: 99%

TFE and Spt4/5 open and close the RNA polymerase clamp during the transcription cycle

Schulz

Gietl

Smollett

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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“…Similar to archaeal TFE, TFIIE can stimulate transcription in vitro from negatively supercoiled or partially pre-melted DNA templates [47,60], suggesting that TFE and TFIIE use a conserved mechanism. Likewise, the clamp of RNAPIII adopts open and closed conformations [16]. However, the clamp movement is less pronounced (change of 9 Å) as compared to the archaeal RNAP and RNAPII (change of 17 Å).…”

Section: Tfe Induces Clamp Openingmentioning

confidence: 98%

“…However, the clamp movement is less pronounced (change of 9 Å) as compared to the archaeal RNAP and RNAPII (change of 17 Å). In the RNAPIII system, subunits C82/34 are an integral part of the RNAP and, similar to subunits TFIIEα/β (RNAPII), span the DNA cleft [13,14,16], which is likely to restrict the flexibility of the clamp.…”

Section: Tfe Induces Clamp Openingmentioning

confidence: 99%

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Molecular Mechanisms of Transcription Initiation—Structure, Function, and Evolution of TFE/TFIIE-Like Factors and Open Complex Formation

Blombach

Smollett

Grohmann

et al. 2016

Journal of Molecular Biology

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Open complex formation is an important target for the regulation of transcription in all domains of life. We propose that TFE and the bacterial general transcription factor CarD, though structurally and evolutionary unrelated, show interesting parallels in their mechanism to enhance open complex formation. We argue that open complex formation is used as a way 3 to regulate transcription in all domains of life, and these regulatory mechanisms co-evolved with the basal transcription machinery.

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“…12,17,26,29 Intriguingly, the similar "above the bridge helix" translocation intermediates are also observed for non-damaged pausing and arrest complexes revealed by the structures of the a-amanitinarrested pol II complex 5,30 and the E. Coli RNAP pausing complex. 31 Another interesting example is revealed by a recent structure of the RNA pol III elongation complex, 32 in which the undamaged template iC1 nucleobase adopts a similar "above the bridge helix" position. Strikingly, this undamaged nucleobase is held at the "above the bridge helix" position through a specific hydrogen-bonding interaction with the pol III residue E506, the counterpart to the pol II Rpb2 Q531 residue that directly senses 5caC/5fC through specific hydrogenbonding interactions.…”

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confidence: 99%

RNA polymerase II acts as a selective sensor for DNA lesions and endogenous DNA modifications

Shin

Wang

2016

Transcription

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During transcription elongation, RNA polymerase II (pol II) travels along the DNA template across thousands to millions of nucleotides and accurately synthesizes the complementary RNA transcripts. Apart from its canonical function as a key enzyme for DNA-dependent RNA synthesis, pol II also functions as a selective sensor to recognize DNA lesions or epigenetic modifications.KEYWORDS DNA lesions; DNA modifications; epi-DNA recognition loop; RNA polymerase II; sensor RNA pol II is a key enzyme responsible for the first step of gene expression. During transcription, pol II reads along the template DNA strand and incorporates the matched nucleotide substrate for RNA transcripts synthesis. Maintenance of high pol II transcriptional fidelity is critical for fundamental biological processes and transcriptional errors contribute to aging and human diseases.1,2 At the transcription elongation phase, pol II transcriptional fidelity is maintained via at least three fidelity checkpoint steps: the nucleotide insertion step, the RNA transcript extension step, and the proofreading step.3 Several important motifs of pol II have been identified that contribute to transcriptional fidelity control. For example, the trigger loop (TL) of the Rpb 1 sub-unit is a highly conserved domain in various multi-subunit RNA polymerases that is responsible for positioning the substrate, rapid catalysis of phosphodiester bond formation, and substrate selection. [4][5][6][7] The TL undergoes a conformational change from an open, inactive state to a closed, active state in the presence of a matched NTP substrate, to seal off the active site and position the substrate to be poised for catalysis. 4 In addition, Rbp9, a small conserved subunit of pol II, also plays an important role in transcriptional proofreading.8 Furthermore, we also recently systematically examined the individual contributions of chemical interactions (such as hydrogen bonds and base stacking) and nucleic acid structural motifs in Pol II transcriptional fidelity control. 3,9,10

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Molecular structures of unbound and transcribing RNA polymerase III

Cited by 169 publications

References 73 publications

TFE and Spt4/5 open and close the RNA polymerase clamp during the transcription cycle

TFE and Spt4/5 open and close the RNA polymerase clamp during the transcription cycle

Molecular Mechanisms of Transcription Initiation—Structure, Function, and Evolution of TFE/TFIIE-Like Factors and Open Complex Formation

RNA polymerase II acts as a selective sensor for DNA lesions and endogenous DNA modifications

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