X-ray structure and mechanism of RNA polymerase II stalled at an antineoplastic monofunctional platinum-DNA adduct

Wang, Dong; Zhu, Guangyu; Huang, Xuhui; Lippard, Stephen J.

doi:10.1073/pnas.1002565107

Cited by 122 publications

(123 citation statements)

References 40 publications

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“…Finally (state 3 to state 4), the transition base rotates to the canonical position of posttranslocation state, which allows full base pairing with the incoming NTP. The intermediate state's identity is consistent with previous translocation intermediate structures trapped either by α-amanitin or DNA damage (13,37), in which the TN base is located on top of the BH.…”

Section: Resultssupporting

confidence: 74%

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Millisecond dynamics of RNA polymerase II translocation at atomic resolution

Silva

Weiss

Avila

et al. 2014

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

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144

199

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Transcription is a central step in gene expression, in which the DNA template is processively read by RNA polymerase II (Pol II), synthesizing a complementary messenger RNA transcript. At each cycle, Pol II moves exactly one register along the DNA, a process known as translocation. Although X-ray crystal structures have greatly enhanced our understanding of the transcription process, the underlying molecular mechanisms of translocation remain unclear. Here we use sophisticated simulation techniques to observe Pol II translocation on a millisecond timescale and at atomistic resolution. We observe multiple cycles of forward and backward translocation and identify two previously unidentified intermediate states. We show that the bridge helix (BH) plays a key role accelerating the translocation of both the RNA:DNA hybrid and transition nucleotide by directly interacting with them. The conserved BH residues, Thr831 and Tyr836, mediate these interactions. To date, this study delivers the most detailed picture of the mechanism of Pol II translocation at atomic level.Markov state model | molecular dynamics | trigger loop T he RNA polymerase is the central component of gene expression in all living organisms, transferring genetic information from DNA to RNA. In eukaryotes, the RNA polymerase II (Pol II) enzyme is responsible for transcribing DNA into messenger RNA. In the past decade, a number of X-ray crystallographic structures of Pol II have been obtained at different stages of the transcription process, providing a static picture of how this complex machine performs its function (1, 2). Transcription is a multistep process consisting of initiation, elongation, and termination, where elongation is composed of consecutive nucleotide addition cycles (NACs). In each NAC, the NTP substrate first diffuses into Pol II active site through the secondary channel (3-5) or alternatively the main channel (6). Upon correct NTP binding to the Pol II active site, the trigger loop (TL) conformation switches from an inactive open state to an active closed state (7). The closure of the active site subsequently facilitates the catalysis of the nucleotide addition reaction (7), followed by release of the pyrophosphate ion (PPi). To proceed to the next NAC, Pol II must translocate from a pretranslocation state, in which the active site is still occupied by the newly added nucleotide at 3′-RNA, to a posttranslocation state. During translocation, the template DNA and RNA must move by exactly one register, once again creating a free insertion site (i site) (1,2,5,(8)(9)(10)(11)(12)(13).Although static snapshots of X-ray structures of Pol II pretranslocation and posttranslocation states are valuable, the dynamics underlying the fundamental RNA polymerase translocation mechanism remain poorly understood (14). Two models of translocation have been proposed based on structural, biochemical, and genetic approaches. On one hand, for single subunit T7 RNAP, PPi release is suggested to be mechanically coupled to the opening motion of the O-helix (co...

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Section: Resultssupporting

confidence: 74%

“…To proceed to the next NAC, Pol II must translocate from a pretranslocation state, in which the active site is still occupied by the newly added nucleotide at 3′-RNA, to a posttranslocation state. During translocation, the template DNA and RNA must move by exactly one register, once again creating a free insertion site (i site) (1,2,5,(8)(9)(10)(11)(12)(13).…”

mentioning

confidence: 99%

Millisecond dynamics of RNA polymerase II translocation at atomic resolution

Silva

Weiss

Avila

et al. 2014

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

Self Cite

144

199

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“…A structural analysis of RNA pol II stalled at a site-specific pyriplatin lesion suggested that, by increasing the steric bulk of the N-heterocyclic ligand, it might be possible to increase transcription inhibition and consequential cytotoxicity [32]. From a panel of different N-heterocyclic ligands, Am, a series of complexes having the formula cis-[Pt(NH 3 ) 2 Cl(Am)] + was prepared [33].…”

Section: Monofunctional Platinum Anti-cancer Agents (A) Pyriplatin: Rmentioning

confidence: 99%

Third row transition metals for the treatment of cancer

Johnstone

Suntharalingam

Lippard

2015

Phil. Trans. R. Soc. A.

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102

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Platinum compounds are a mainstay of cancer chemotherapy, with over 50% of patients receiving platinum. But there is a great need for improvement. Major features of the cisplatin mechanism of action involve cancer cell entry, formation mainly of intrastrand cross-links that bend and unwind nuclear DNA, transcription inhibition and induction of cell-death programmes while evading repair. Recently, we discovered that platinum cross-link formation is not essential for activity. Monofunctional Pt compounds such as phenanthriplatin, which make only a single bond to DNA nucleobases, can be far more active and effective against a range of tumour types. Without a cross-link-induced bend, monofunctional complexes can be accommodated in the major groove of DNA. Their biological mechanism of action is similar to that of cisplatin. These discoveries opened the door to a large family of heavy metal-based drug candidates, including those of Os and Re, as will be described.

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“…Aligning the structures of 5caC-paused pol II elongation complex with several recent bulky DNA lesionarrested complexes reveals new insights into pol II pausing and arrest upon DNA modifications/ lesions. 12,17,26,29 Intriguingly, the iC1 transition template base in these 5caC-paused or bulky DNA lesion-arrested structures are all accommodated "above the bridge helix," representing a common translocation checkpoint for a variety of endogenous DNA modifications and DNA lesions. 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.…”

mentioning

confidence: 99%

“…12,17,26,29 Intriguingly, the iC1 transition template base in these 5caC-paused or bulky DNA lesion-arrested structures are all accommodated "above the bridge helix," representing a common translocation checkpoint for a variety of endogenous DNA modifications and DNA lesions. 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.…”

mentioning

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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X-ray structure and mechanism of RNA polymerase II stalled at an antineoplastic monofunctional platinum-DNA adduct

Cited by 122 publications

References 40 publications

Millisecond dynamics of RNA polymerase II translocation at atomic resolution

Millisecond dynamics of RNA polymerase II translocation at atomic resolution

Third row transition metals for the treatment of cancer

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

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