4r66 Citations

Substrate-induced DNA polymerase β activation.

Beard WA, Shock DD, Batra VK, Prasad R, Wilson SH
J Biol Chem 289 31411-22 (2014)
Related entries: 4r63, 4r64, 4r65

Cited: 22 times
EuropePMC logo PMID: 25261471

Abstract

DNA polymerases and substrates undergo conformational changes upon forming protein-ligand complexes. These conformational adjustments can hasten or deter DNA synthesis and influence substrate discrimination. From structural comparison of binary DNA and ternary DNA-dNTP complexes of DNA polymerase β, several side chains have been implicated in facilitating formation of an active ternary complex poised for chemistry. Site-directed mutagenesis of these highly conserved residues (Asp-192, Arg-258, Phe-272, Glu-295, and Tyr-296) and kinetic characterization provides insight into the role these residues play during correct and incorrect insertion as well as their role in conformational activation. The catalytic efficiencies for correct nucleotide insertion for alanine mutants were wild type ∼ R258A > F272A ∼ Y296A > E295A > D192A. Because the efficiencies for incorrect insertion were affected to about the same extent for each mutant, the effects on fidelity were modest (<5-fold). The R258A mutant exhibited an increase in the single-turnover rate of correct nucleotide insertion. This suggests that the wild-type Arg-258 side chain generates a population of non-productive ternary complexes. Structures of binary and ternary substrate complexes of the R258A mutant and a mutant associated with gastric carcinomas, E295K, provide molecular insight into intermediate structural conformations not appreciated previously. Although the R258A mutant crystal structures were similar to wild-type enzyme, the open ternary complex structure of E295K indicates that Arg-258 stabilizes a non-productive conformation of the primer terminus that would decrease catalysis. Significantly, the open E295K ternary complex binds two metal ions indicating that metal binding cannot overcome the modified interactions that have interrupted the closure of the N-subdomain.

Articles - 4r66 mentioned but not cited (1)

  1. Substrate-induced DNA polymerase β activation. Beard WA, Shock DD, Batra VK, Prasad R, Wilson SH. J Biol Chem 289 31411-31422 (2014)


Reviews citing this publication (3)

  1. Oxidant and environmental toxicant-induced effects compromise DNA ligation during base excision DNA repair. Çağlayan M, Wilson SH. DNA Repair (Amst) 35 85-89 (2015)
  2. New structural snapshots provide molecular insights into the mechanism of high fidelity DNA synthesis. Freudenthal BD, Beard WA, Wilson SH. DNA Repair (Amst) 32 3-9 (2015)
  3. Reprint of "Oxidant and environmental toxicant-induced effects compromise DNA ligation during base excision DNA repair". Çağlayan M, Wilson SH. DNA Repair (Amst) 36 86-90 (2015)

Articles citing this publication (18)

  1. Time-lapse crystallography snapshots of a double-strand break repair polymerase in action. Jamsen JA, Beard WA, Pedersen LC, Shock DD, Moon AF, Krahn JM, Bebenek K, Kunkel TA, Wilson SH. Nat Commun 8 253 (2017)
  2. DNA polymerase β uses its lyase domain in a processive search for DNA damage. Howard MJ, Rodriguez Y, Wilson SH. Nucleic Acids Res 45 3822-3832 (2017)
  3. Modulating the DNA polymerase β reaction equilibrium to dissect the reverse reaction. Shock DD, Freudenthal BD, Beard WA, Wilson SH. Nat Chem Biol 13 1074-1080 (2017)
  4. Bypass of a 5',8-cyclopurine-2'-deoxynucleoside by DNA polymerase β during DNA replication and base excision repair leads to nucleotide misinsertions and DNA strand breaks. Jiang Z, Xu M, Lai Y, Laverde EE, Terzidis MA, Masi A, Chatgilialoglu C, Liu Y. DNA Repair (Amst) 33 24-34 (2015)
  5. Mechanisms of telomerase inhibition by oxidized and therapeutic dNTPs. Sanford SL, Welfer GA, Freudenthal BD, Opresko PL. Nat Commun 11 5288 (2020)
  6. Role of Conformational Motions in Enzyme Function: Selected Methodologies and Case Studies. Narayanan C, Bernard DN, Doucet N. Catalysts 6 81 (2016)
  7. Mechanisms of nucleotide selection by telomerase. Schaich MA, Sanford SL, Welfer GA, Johnson SA, Khoang TH, Opresko PL, Freudenthal BD. Elife 9 e55438 (2020)
  8. Insertion of oxidized nucleotide triggers rapid DNA polymerase opening. Kim T, Freudenthal BD, Beard WA, Wilson SH, Schlick T. Nucleic Acids Res 44 4409-4424 (2016)
  9. Molecular basis for the faithful replication of 5-methylcytosine and its oxidized forms by DNA polymerase β. Howard MJ, Foley KG, Shock DD, Batra VK, Wilson SH. J Biol Chem 294 7194-7201 (2019)
  10. A guardian residue hinders insertion of a Fapy•dGTP analog by modulating the open-closed DNA polymerase transition. Smith MR, Shock DD, Beard WA, Greenberg MM, Freudenthal BD, Wilson SH. Nucleic Acids Res 47 3197-3207 (2019)
  11. Exploring the mechanism of DNA polymerases by analyzing the effect of mutations of active site acidic groups in Polymerase β. Matute RA, Yoon H, Warshel A. Proteins 84 1644-1657 (2016)
  12. Mapping Functional Substrate-Enzyme Interactions in the pol β Active Site through Chemical Biology: Structural Responses to Acidity Modification of Incoming dNTPs. Batra VK, Oertell K, Beard WA, Kashemirov BA, McKenna CE, Goodman MF, Wilson SH. Biochemistry 57 3934-3944 (2018)
  13. Structural basis for the D-stereoselectivity of human DNA polymerase β. Vyas R, Reed AJ, Raper AT, Zahurancik WJ, Wallenmeyer PC, Suo Z. Nucleic Acids Res 45 6228-6237 (2017)
  14. Structures of human DNA polymerases ν and θ expose their end game. Beard WA, Wilson SH. Nat Struct Mol Biol 22 273-275 (2015)
  15. DNA polymerase β nucleotide-stabilized template misalignment fidelity depends on local sequence context. Howard MJ, Cavanaugh NA, Batra VK, Shock DD, Beard WA, Wilson SH. J Biol Chem 295 529-538 (2020)
  16. Altered Nucleotide Insertion Mechanisms of Disease-Associated TERT Variants. Welfer GA, Borin VA, Cortez LM, Opresko PL, Agarwal PK, Freudenthal BD. Genes (Basel) 14 281 (2023)
  17. Transitions in DNA polymerase β μs-ms dynamics related to substrate binding and catalysis. DeRose EF, Kirby TW, Mueller GA, Beard WA, Wilson SH, London RE. Nucleic Acids Res 46 7309-7322 (2018)
  18. Mechanism of Deoxyguanosine Diphosphate Insertion by Human DNA Polymerase β. Varela FA, Freudenthal BD. Biochemistry 60 373-380 (2021)


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