Cooperative motion of a key positively charged residue and metal ions for DNA replication catalyzed by human DNA Polymerase-η

Genna, Vito; Gaspari, Roberto; Peraro, Matteo Dal; Vivo, Marco De

doi:10.1093/nar/gkw128

Cited by 42 publications

(103 citation statements)

References 76 publications

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“…72 Recent computational investigations provided a rational for this conformational change, suggesting that in the "down" conformation, Arg61 stabilizes the formation of a catalytic complex for the polymerase reaction. 73 Remarkably, MD simulations of the activated pol−η show that Arg61 mainly adopts a "down" conformational state, rarely transitioning in the "up" conformational state, similar to what observed in the present study for CRISPR−Cas9 (Figures 3 and 5A, left panel). In CRISPR−Cas9, DNA cleavage assays by capillary electrophoresis have shown that the R976A mutation reduces the cleavage of the NTS.…”

Section: Journal Of Chemical Information and Modelingsupporting

confidence: 88%

“…13 The use of a recently developed accelerated MD methodology i.e., a Gaussian accelerated MD (GaMD)further enabled broad exploration of the conformational dynamics of the RuvC domain over longer time scales. As a result, an arginine finger is found to stably contact the scissile phosphate, as also observed in other Mg 2+ -aided phosphatases 70 and DNA/RNA two-metal aided enzymes, 55,[71][72][73]83 with the function of stabilizing the formation of a catalytically active complex. Overall, the agreement with the available experimental studies on CRISPR−Cas9 and the analogies found with other two-metal aided enzymes support the model proposed in the present study, offering a reliable description of the active site chemistry.…”

Section: ■ Conclusionsupporting

confidence: 63%

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Structure and Dynamics of the CRISPR–Cas9 Catalytic Complex

Palermo

2019

J. Chem. Inf. Model.

113

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CRISPR−Cas9 is a bacterial immune system with exciting applications for genome editing. In spite of extensive experimental characterization, the active site chemistry of the RuvC domainwhich performs DNA cleavageshas remained elusive. Its knowledge is key for structure-based engineering aimed at improving DNA cleavages. Here, we deliver an in-depth characterization by using quantum-classical (QM/MM) molecular dynamics (MD) simulations and a Gaussian accelerated MD method, coupled with bioinformatics analysis. We disclose a two-metal aided architecture in the RuvC active site, which is poised to operate DNA cleavages, in analogy with other DNA/RNA processing enzymes. The conformational dynamics of the RuvC domain further reveals that an "arginine finger" stably contacts the scissile phosphate, with the function of stabilizing the active complex. Remarkably, the formation of a catalytically competent state of the RuvC domain is only observed upon the conformational activation of the other nuclease domain of CRISPR−Cas9i.e., the HNH domainsuch allowing concerted cleavages of double stranded DNA. This structure is in agreement with the available experimental data and remarkably differs from previous models based on classical mechanics, demonstrating also that only quantum mechanical simulations can accurately describe the metal-aided active site in CRISPR−Cas9. This fully catalytic structurein which both the HNH and RuvC domains are prone to perform DNA cleavagesconstitutes a stepping-stone for understanding DNA cleavage and specificity. It calls for novel experimental verifications and offers the structural foundations for engineering efforts aimed at improving the genome editing capability of CRISPR−Cas9.

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Section: Journal Of Chemical Information and Modelingsupporting

confidence: 88%

Section: ■ Conclusionsupporting

confidence: 63%

Structure and Dynamics of the CRISPR–Cas9 Catalytic Complex

Palermo

2019

J. Chem. Inf. Model.

113

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“…Based on molecular dynamics (MD) simulations, a "hopping" model for PP i release was proposed, where a few positively charged residues along the exit channel form the hopping sites and facilitate the process of PP i release (18). Another MD simulation study of a Y-family DNA polymerase (human Pol ) suggested that a highly flexible and conserved arginine residue (Arg-61) acts concertedly with a third transient metal ion that forms an "exit shuttle" for the leaving PP i group (19). The actual PP i release should be a fast process if the channel connecting the internal active site to the external solvent is large enough for a PP i molecule to freely diffuse (49).…”

Section: Tablementioning

confidence: 99%

“…Because the translocation step is kinetically "invisible" in rate measurements, a direct measurement of translocation by a polymerase has been sadly lacking until Malinen et al (17) monitored RNA polymerase (RNAP) translocation along its DNA substrate using fluorescent base analogs and revealed fast translocation rates after incorporation of various nucleotides, with half-lives (t1 ⁄ 2 ) between 7 and 12 ms. Although atomic level details of PP i release by polymerases are still elusive (18,19), it is generally thought to be fast (1,2) with only few exceptions after mismatched or modified nucleotides are incorporated (20 -22). Our recent measurements of the rates of polymerization and pyrophosphate release by HIVRT in single turnover experiments with DNA templates showed that pyrophosphate (PP i ) dissociation was fast after nucleotide incorporation so that it did not contribute to enzyme specificity (k cat /K m ).…”

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confidence: 99%

Rate-limiting Pyrophosphate Release by HIV Reverse Transcriptase Improves Fidelity

Liu

Gong

Johnson

2016

Journal of Biological Chemistry

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Previous measurements of the rates of polymerization and pyrophosphate release with DNA templates showed that pyrophosphate (PP) dissociation was fast after nucleotide incorporation so that it did not contribute to enzyme specificity (k/K). Here, kinetic parameters governing nucleotide incorporation and PP release were determined using an RNA template. Compared with a DNA template of the same sequence, the rate of chemistry increased by up to 10-fold (250 versus 24 s), whereas the rate of PP release decreased to approximately 58 s so that PP release became the rate-limiting step. During processive nucleotide incorporation, the first nucleotide (TTP) was incorporated at a fast rate (152 s), whereas the rates of incorporation of remaining nucleotides (CGTCG) were much slower with an average rate of 24 s, suggesting that sequential incorporation events were limited by the relatively slow PP release step. The accompanying paper shows that slow PP release allows polymerization and RNase H to occur at comparable rates. Although PP release is the rate-determining step, it is not the specificity-determining step for correct incorporation based on our current estimates of the rate of reversal of the chemistry step (3 s). In contrast, during misincorporation, PP release became extremely slow, which we estimated to be ∼0.002 s These studies establish the mechanistic basis for DNA polymerase fidelity during reverse transcription and provide a free energy profile. We correct previous underestimates of discrimination by including the slow PP release step. Our current estimate of 2.4 × 10 is >20-fold greater than estimated previously.

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“…Further parallels can also be made between the PfA-M17 system and the diverse enzymes that operate via the conserved two-metal ion mechanism (with associated basic residue). A particularly striking similarity is observed between the human DNA Polymerase-η (Pol-η) and PfA-M17; Pol-η operates via a highly dynamic and cooperative process that involves transient recruitment of a third metal ion (60). The conserved basic residue of Pol-η, Arg61, is highly flexible, and specific conformations of Arg61 (sampled as part of a large equilibrium ensemble) serve to recruit incoming substrate, facilitate the reaction, and act as an exit shuttle (60).…”

Section: Discussionmentioning

confidence: 99%

A metal-dependent switch moderates activity of the hexameric M17 aminopeptidases

Drinkwater

Yang

Riley

et al. 2018

Preprint

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18M17 aminopeptidases possess a conserved hexameric arrangement throughout all kingdoms 19 of life. Of particular interest is the M17 from Plasmodium falciparum (PfA-M17), which is a 20 validated antimalarial drug target. Herein we have examined PfA-M17 using an integrated 21 structural biology and biochemical approach to provide the first description of the fundamental role 22 of oligomerisation. We found that, rather than operating as discrete units, the active sites of the 23PfA-M17 hexamer are linked by a dynamic loop, which operates cooperatively to regulate activity. 24Further, we characterised motions in key surface loops that moderate access to the central catalytic 25cavity. Based on our new understanding of the dynamics inherent to PfA-M17, we propose a novel 26 mechanism that would allow exquisite control of enzyme function in response to cellular signals, 27and go on to discuss how, through divergent evolution, this mechanism might have developed to 28 moderate key differences in M17 function across species. 29 30 Introduction: 31

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Cooperative motion of a key positively charged residue and metal ions for DNA replication catalyzed by human DNA Polymerase-η

Cited by 42 publications

References 76 publications

Structure and Dynamics of the CRISPR–Cas9 Catalytic Complex

Structure and Dynamics of the CRISPR–Cas9 Catalytic Complex

Rate-limiting Pyrophosphate Release by HIV Reverse Transcriptase Improves Fidelity

A metal-dependent switch moderates activity of the hexameric M17 aminopeptidases

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