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    Biochemical Characterization of Eight Genetic Variants of Human DNA Polymerase κ Involved in Error-Free Bypass across Bulky <i>N</i><sup>2</sup>‑Guanyl DNA Adducts

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    DNA polymerase (pol) κ, one of the Y-family polymerases, has been shown to function in error-free translesion DNA synthesis (TLS) opposite the bulky <i>N</i><sup>2</sup>-guanyl DNA lesions induced by many carcinogens such as polycyclic aromatic hydrocarbons. We analyzed the biochemical properties of eight reported human pol κ variants positioned in the polymerase core domain, using the recombinant pol κ (residues 1–526) protein and the DNA template containing an <i>N</i><sup>2</sup>-CH<sub>2</sub>(9-anthracenyl)­G (<i>N</i><sup>2</sup>-AnthG). The truncation R219X was devoid of polymerase activity, and the E419G and Y432S variants showed much lower polymerase activity than wild-type pol κ. In steady-state kinetic analyses, E419G and Y432S displayed 20- to 34-fold decreases in <i>k</i><sub>cat</sub>/<i>K</i><sub>m</sub> for dCTP insertion opposite G and <i>N</i><sup>2</sup>-AnthG compared to that of wild-type pol κ. The L21F, I39T, and D189G variants, as well as E419G and Y432S, displayed 6- to 22-fold decreases in <i>k</i><sub>cat</sub>/<i>K</i><sub>m</sub> for next-base extension from C paired with <i>N</i><sup>2</sup>-AnthG, compared to that of wild-type pol κ. The defective Y432S variant had 4- to 5-fold lower DNA-binding affinity than wild-type, while a slightly more efficient S423R variant possessed 2- to 3-fold higher DNA-binding affinity. These results suggest that R219X abolishes and the E419G, Y432S, L21F, I39T, and D189G variations substantially impair the TLS ability of pol κ opposite bulky <i>N</i><sup>2</sup>-G lesions in the insertion step opposite the lesion and/or the subsequent extension step, raising the possibility that certain nonsynonymous pol κ genetic variations translate into individual differences in susceptibility to genotoxic carcinogens

    Biochemical Characterization of Eight Genetic Variants of Human DNA Polymerase κ Involved in Error-Free Bypass across Bulky <i>N</i><sup>2</sup>‑Guanyl DNA Adducts

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    DNA polymerase (pol) κ, one of the Y-family polymerases, has been shown to function in error-free translesion DNA synthesis (TLS) opposite the bulky <i>N</i><sup>2</sup>-guanyl DNA lesions induced by many carcinogens such as polycyclic aromatic hydrocarbons. We analyzed the biochemical properties of eight reported human pol κ variants positioned in the polymerase core domain, using the recombinant pol κ (residues 1–526) protein and the DNA template containing an <i>N</i><sup>2</sup>-CH<sub>2</sub>(9-anthracenyl)­G (<i>N</i><sup>2</sup>-AnthG). The truncation R219X was devoid of polymerase activity, and the E419G and Y432S variants showed much lower polymerase activity than wild-type pol κ. In steady-state kinetic analyses, E419G and Y432S displayed 20- to 34-fold decreases in <i>k</i><sub>cat</sub>/<i>K</i><sub>m</sub> for dCTP insertion opposite G and <i>N</i><sup>2</sup>-AnthG compared to that of wild-type pol κ. The L21F, I39T, and D189G variants, as well as E419G and Y432S, displayed 6- to 22-fold decreases in <i>k</i><sub>cat</sub>/<i>K</i><sub>m</sub> for next-base extension from C paired with <i>N</i><sup>2</sup>-AnthG, compared to that of wild-type pol κ. The defective Y432S variant had 4- to 5-fold lower DNA-binding affinity than wild-type, while a slightly more efficient S423R variant possessed 2- to 3-fold higher DNA-binding affinity. These results suggest that R219X abolishes and the E419G, Y432S, L21F, I39T, and D189G variations substantially impair the TLS ability of pol κ opposite bulky <i>N</i><sup>2</sup>-G lesions in the insertion step opposite the lesion and/or the subsequent extension step, raising the possibility that certain nonsynonymous pol κ genetic variations translate into individual differences in susceptibility to genotoxic carcinogens
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