Impact of DNA polymerase ζ mutations on genotoxic thresholds of oxidative mutagens

Human functional genomics reveals toxicological mechanism underlying genotoxicants-induced inflammatory responses under low doses exposure

Understanding the toxicological mechanisms of chemicals is essential for accurate assessments of environmental health risks. Inflammation could play a critical role in the adverse health outcomes caused by genotoxicants; however, the toxicological mechanisms underlying genotoxicants-induced inflammatory response are still limited. Here, functional genomics CRISPR screens were performed to enhance the mechanistic understanding of the genotoxicants-induced inflammatory response at low doses exposure. Key genes and pathways associated with the activities of immune cells and the production of cytokines were identified by CRISPR screens of 6 model genotoxicants. Gene network analysis revealed that three genes (TLR10, HCAR2 and TRIM6) were involved in the regulation of neutrophil apoptosis and cytokine release, and TLR10 shared a similar functional pattern with HCAR2 and TRIM6. Furthermore, adverse outcome pathway (AOP) network analysis revealed that TLR10 was involved in the molecular initiating events (MIEs) or key events (KEs) in the inflammatory response AOPs of all the 6 genotoxicants, which provided mechanistic links between TLR10 and genotoxicants-induced inflammation and respiratory diseases. Finally, functional validation tests demonstrated that TLR10 exhibited inhibitory effects on genotoxicants-induced inflammatory responses in both epithelial and immune cells. This study highlights the powerful utility of the integration of CRISPR screen and AOP network analysis in illuminating the toxicological causal mechanisms of environmental chemicals.

The role of DNA polymerase ζ in benzo[a]pyrene-induced mutagenesis in the mouse lung

DNA polymerase zeta (Polζ) is a heterotetramer composed of the catalytic subunit Rev3l, Rev7 and two subunits of Polδ (PolD2/Pol31 and PolD3/Pol32), and this polymerase exerts translesion DNA synthesis (TLS) in yeast. Because Rev3l knockout results in embryonic lethality in mice, the functions of Polζ need further investigation in vivo. Then, we noted the two facts that substitution of leucine 979 of yeast Rev3l with methionine reduces Polζ replication fidelity and that reporter gene transgenic rodents are able to provide the detailed mutation status. Here, we established gpt delta mouse knocked in the constructed gene encoding methionine instead of leucine at residue 2610 of Rev3l (Rev3l L2610M gpt delta mice), to clarify the role of Polζ in TLS of chemical-induced bulky DNA adducts in vivo. Eight-week-old gpt delta mice and Rev3l L2610M gpt delta mice were treated with benzo[a]pyrene (BaP) at 0, 40, 80, or 160 mg/kg via single intraperitoneal injection. At necropsy 31 days after treatment, lungs were collected for reporter gene mutation assays. Although the gpt mutant frequency was significantly increased by BaP in both mouse genotypes, it was three times higher in Rev3l L2610M gpt delta than gpt delta mice after treatment with 160 mg/kg BaP. The frequencies of G:C base substitutions and characteristic complex mutations were significantly increased in Rev3l L2610M gpt delta mice compared with gpt delta mice. The BaP dose-response relationship suggested that Polζ plays a central role in TLS when protective mechanisms against BaP mutagenesis, such as error-free TLS, are saturated. Overall, Polζ may incorporate incorrect nucleotides at the sites opposite to BaP-modified guanines and extend short DNA sequences from the resultant terminal mismatches only when DNA is heavily damaged.

Effects of DNA polymerase kappa and mismatch repair on dose-responses of chromosome aberrations induced by three oxidative genotoxins in human cells

Genotoxic carcinogens are regulated under the policy that there is no threshold or safe dose. It has been pointed out, however, that self-defense mechanisms, such as detoxification, DNA repair, and error-free translesion synthesis, may protect chromosome DNA from genotoxic insults, thereby constituting practical threshold. In this study, we examined dose responses of chromosome aberrations induced by three oxidative genotoxins, that is, hydrogen peroxide (H₂ O₂ ), menadione and paraquat, with or without DNA polymerase kappa (Polκ) activities and mismatch repair capacities in human cells. Polκ is involved in translesion synthesis across DNA damage and mismatch repair is responsible for correction of base-base mismatch in DNA. Polκ activity of the cells was inactivated either by point mutations in the catalytically essential amino acids (catalytically dead or CD) or by deletion of the POLK gene (knockout or KO). In the absence of mismatch repair, frequencies of chromosome aberrations induced by H₂ O₂ and menadione were not significantly different among CD, KO, and the wild type (WT) cells. In the presence of mismatch repair, however, cytotoxicity and clastogenicity were enhanced and Polκ modulated the sensitivity of the cells. No-observed-genotoxic-effect-levels (NOGELs) for H₂ O₂ and menadione were CD = KO < WT cells. In contrast, the sensitivities of the cells to paraquat were not significantly affected by the status of mismatch repair or Polκ activity. The results suggest that mismatch repair and Polκ coordinately modulate NOGELs for the clastogenicity of H₂ O₂ and menadione and also that DNA lesion(s) responsible for paraquat-induced chromosome aberrations are different from those induced by H₂ O₂ and menadione. Environ. Mol. Mutagen. 61:193-199, 2020. © 2019 Wiley Periodicals, Inc.