Different types of interaction between PCNA and PIP boxes contribute to distinct cellular functions of Y-family DNA polymerases.

Translesion DNA synthesis (TLS) by the Y-family DNA polymerases Polη, Polι and Polκ, mediated via interaction with proliferating cell nuclear antigen (PCNA), is a crucial pathway that protects human cells against DNA damage. We report that Polη has three PCNA-interacting protein (PIP) boxes (PIP1, 2, 3) that contribute differentially to two distinct functions, stimulation of DNA synthesis and promotion of PCNA ubiquitination. The latter function is strongly associated with formation of nuclear Polη foci, which co-localize with PCNA. We also show that Polκ has two functionally distinct PIP boxes, like Polη, whereas Polι has a single PIP box involved in stimulation of DNA synthesis. All three polymerases were additionally stimulated by mono-ubiquitinated PCNA in vitro. The three PIP boxes and a ubiquitin-binding zinc-finger of Polη exert redundant and additive effects in vivo via distinct molecular mechanisms. These findings provide an integrated picture of the orchestration of TLS polymerases.

The vital role of polymerase ζ and REV1 in mutagenic, but not correct, DNA synthesis across benzo[a]pyrene-dG and recruitment of polymerase ζ by REV1 to replication-stalled site.

The DNA synthesis across DNA lesions, termed translesion synthesis (TLS), is a complex process influenced by various factors. To investigate this process in mammalian cells, we examined TLS across a benzo[a]pyrene dihydrodiol epoxide-derived dG adduct (BPDE-dG) using a plasmid bearing a single BPDE-dG and genetically engineered mouse embryonic fibroblasts (MEFs). In wild-type MEFs, TLS was extremely miscoding (>90%) with G → T transversions being predominant. Knockout of the Rev1 gene decreased both the TLS efficiency and the miscoding frequency. Knockout of the Rev3L gene, coding for the catalytic subunit of pol ζ, caused even greater decreases in these two TLS parameters; almost all residual TLS were error-free. Thus, REV1 and pol ζ are critical to mutagenic, but not accurate, TLS across BPDE-dG. The introduction of human REV1 cDNA into Rev1(-/-) MEFs restored the mutagenic TLS, but a REV1 mutant lacking the C terminus did not. Yeast and mammalian three-hybrid assays revealed that the REV7 subunit of pol ζ mediated the interaction between REV3 and the REV1 C terminus. These results support the hypothesis that REV1 recruits pol ζ through the interaction with REV7. Our results also predict the existence of a minor REV1-independent pol ζ recruitment pathway. Finally, although mutagenic TLS across BPDE-dG largely depends on RAD18, experiments using Polk(-/-) Polh(-/-) Poli(-/-) triple-gene knockout MEFs unexpectedly revealed that another polymerase(s) could insert a nucleotide opposite BPDE-dG. This indicates that a non-Y family polymerase(s) can insert a nucleotide opposite BPDE-dG, but the subsequent extension from miscoding termini depends on REV1-polζ in a RAD18-dependent manner.

Overlapping in short motif sequences for binding to human REV7 and MAD2 proteins.

Polζ, a DNA polymerase specialized for translesion DNA synthesis (TLS), is comprised of two subunits, the REV3 catalytic subunit and the REV7 accessory subunit. The human REV7 (hREV7) protein is known to interact with hREV3, hREV1 (another TLS protein) and some other proteins such as ADAM9 (a disintegrin and metalloprotease) and ELK-1 (an Ets-like transcription factor). hREV7 is alternatively termed hMAD2L2, because its primary sequence shows 26% identity to that of hMAD2 that plays crucial roles in spindle assembly checkpoint (SAC) via interactions with hMAD1 or hCDC20. Here, we have investigated the molecular basis for the interactions of hREV7/MAD2L2 and hMAD2 with their binding partners. Our results showed that a short sequence of hREV3 is necessary and sufficient for interaction with hREV7. Surprisingly, hMAD2 also binds to the hREV7-binding sequence in hREV3, whereas hMAD2 does not bind to a similar sequence in ADAM9 or ELK-1 and hREV7 does not bind to the hMAD2-binding sequence in hMAD1 or hCDC20. We discuss how hREV7 and hMAD2 recognize their binding partners, and how hREV3 and hREV7 might be involved in SAC.

Interaction with DNA polymerase eta is required for nuclear accumulation of REV1 and suppression of spontaneous mutations in human cells.

Defects in the gene encoding human Poleta result in xeroderma pigmentosum variant (XP-V), an inherited cancer-prone syndrome. Poleta catalyzes efficient and accurate translesion DNA synthesis (TLS) past UV-induced lesions. In addition to Poleta, human cells have multiple TLS polymerases such as Poliota, Polkappa, Polzeta and REV1. REV1 physically interacts with other TLS polymerases, but the physiological relevance of the interaction remains unclear. Here we developed an antibody that detects the endogenous REV1 protein and found that human cells contain about 60,000 of REV1 molecules per cell as well as Poleta. In un-irradiated cells, formation of nuclear foci by ectopically expressed REV1 was enhanced by the co-expression of Poleta. Importantly, the endogenous REV1 protein accumulated at the UV-irradiated areas of nuclei in Poleta-expressing cells but not in Poleta-deficient XP-V cells. UV-irradiation induced nuclear foci of REV1 and Poleta proteins in both S-phase and G1 cells, suggesting that these proteins may function both during and outside S phase. We reconstituted XP-V cells with wild-type Poleta or with Poleta mutants harboring substitutions in phenylalanine residues critical for interaction with REV1. The REV1-interaction-deficient Poleta mutant failed to promote REV1 accumulation at sites of UV-irradiation, yet (similar to wild-type Poleta) corrected the UV sensitivity of XP-V cells and suppressed UV-induced mutations. Interestingly however, spontaneous mutations of XP-V cells were only partially suppressed by the REV1-interaction deficient mutant of Poleta. Thus, Poleta-REV1 interactions prevent spontaneous mutations, probably by promoting accurate TLS past endogenous DNA lesions, while the interaction is dispensable for accurate Poleta-mediated TLS of UV-induced lesions.

Identification of a novel REV1-interacting motif necessary for DNA polymerase kappa function.

When a replicative DNA polymerase (Pol) is stalled by damaged DNA, a "polymerase switch" recruits specialized translesion synthesis (TLS) DNA polymerase(s) to sites of damage. Mammalian cells have several TLS DNA polymerases, including the four Y-family enzymes (Poleta, Poliota, Polkappa and REV1) that share multiple primary sequence motifs, but show preferential bypass of different DNA lesions. REV1 interacts with Poleta, Poliota, and Polkappa and therefore appears to play a central role during TLS in vivo. Here we have investigated the molecular basis for interactions between REV1 and Polkappa. We have identified novel REV1-interacting regions (RIRs) present in Polkappa, Poliota and Poleta. Within the RIRs, the presence of two consecutive phenylalanines (FF) is essential for REV1-binding. The consensus sequence for REV1-binding is denoted by x-x-x-F-F-y-y-y-y (x, no specific residue and y, no specific residue but not proline). Our results identify structural requirements that are necessary for FF-flanking residues to confer interactions with REV1. A Polkappa mutant lacking REV1-binding activity did not complement the genotoxin-sensitivity of Polk-null mouse embryonic fibroblast cells, thereby demonstrating that the REV1-interaction is essential for Polkappa function in vivo.

Effect of sequence context on Polζ-dependent error-prone extension past (6-4) photoproducts.

The (6-4) pyrimidine-pyrimidone photoproduct [(6-4)PP] is a major DNA lesion induced by ultraviolet radiation. (6-4)PP induces complex mutations opposite its downstream bases, in addition to opposite 3' or 5' base, as has been observed through a site-specific translesion DNA synthesis (TLS) assay. The mechanism by which these mutations occur is not well understood. To elucidate the mechanisms underlying mutagenesis induced by (6-4)PP, we performed an intracellular TLS assay using a replicative vector with site-specific T(thymidine)-T (6-4)PP. Rev3-/-p53-/- mouse embryonic fibroblast (MEF) cells (defective in Polζ) were almost completely defective in bypassing T-T (6-4)PP, whereas both Rev1-/- and Polh-/-Poli-/-Polk-/- MEF cells (defective in Polη, Polι, and Polκ) presented bypassing activity comparable to that of wild-type cells, indicating that Y-family TLS polymerases are dispensable for bypassing activity, whereas Polζ plays an essential role, probably at the extension step. Among all cells tested, misincorporation occurred most frequently just beyond the lesion (position +1), indicating that the Polζ-dependent extension step is crucial for (6-4)PP-induced mutagenesis. We then examined the effects of sequence context on T-T (6-4)PP bypass using a series of T-T (6-4)PP templates with different sequences at position +1 or -1 to the lesion, and found that the dependency of T-T (6-4)PP bypass on Polζ is not sequence specific. However, the misincorporation frequency at position +1 differed significantly among these templates. The misincorporation of A at position +1 occurred frequently when a purine base was located at position -1. These results indicate that Polζ-dependent extension plays a major role in inducing base substitutions in (6-4)PP-induced mutagenesis, and its fidelity is affected by sequence context surrounding a lesion.

Rad18 regulates DNA polymerase kappa and is required for recovery from S-phase checkpoint-mediated arrest.

We have investigated mechanisms that recruit the translesion synthesis (TLS) DNA polymerase Polkappa to stalled replication forks. The DNA polymerase processivity factor PCNA is monoubiquitinated and interacts with Polkappa in cells treated with the bulky adduct-forming genotoxin benzo[a]pyrene dihydrodiol epoxide (BPDE). A monoubiquitination-defective mutant form of PCNA fails to interact with Polkappa. Small interfering RNA-mediated downregulation of the E3 ligase Rad18 inhibits BPDE-induced PCNA ubiquitination and association between PCNA and Polkappa. Conversely, overexpressed Rad18 induces PCNA ubiquitination and association between PCNA and Polkappa in a DNA damage-independent manner. Therefore, association of Polkappa with PCNA is regulated by Rad18-mediated PCNA ubiquitination. Cells from Rad18(-/-) transgenic mice show defective recovery from BPDE-induced S-phase checkpoints. In Rad18(-/-) cells, BPDE induces elevated and persistent activation of checkpoint kinases, indicating persistently stalled forks due to defective TLS. Rad18-deficient cells show reduced viability after BPDE challenge compared with wild-type cells (but survival after hydroxyurea or ionizing radiation treatment is unaffected by Rad18 deficiency). Inhibition of RPA/ATR/Chk1-mediated S-phase checkpoint signaling partially inhibited BPDE-induced PCNA ubiquitination and prevented interactions between PCNA and Polkappa. Taken together, our results indicate that ATR/Chk1 signaling is required for Rad18-mediated PCNA monoubiquitination. Recruitment of Polkappa to ubiquitinated PCNA enables lesion bypass and eliminates stalled forks, thereby attenuating the S-phase checkpoint.

Penicilliols A and B, novel inhibitors specific to mammalian Y-family DNA polymerases.

Penicilliols A (1) and B (2) are novel 5-methoxy-3(2H)-furanones isolated from cultures of a fungus (Penicillium daleae K.M. Zalessky) derived from a sea moss, and their structures were determined by spectroscopic analyses. These compounds selectively inhibited activities of eukaryotic Y-family DNA polymerases (pols) (i.e., pols eta, iota and kappa), and compound 1 was a stronger inhibitor than compound 2. Among mammalian Y-family pols, mouse pol iota activity was most strongly inhibited by compounds 1 and 2, with IC(50) values of 19.8 and 32.5 microM, respectively. On the other hand, activities of many other pols, such as A-family (i.e., pol gamma), B-family (i.e., pols alpha, delta and epsilon) or X-family (i.e., pols beta, lambda and terminal deoxynucleotidyl transferase), and some DNA metabolic enzymes, such as calf primase of pol alpha, human immunodeficiency virus type-1 (HIV-1) reverse transcriptase, human telomerase, T7 RNA polymerase, mouse IMP dehydrogenase (type II), human topoisomerases I and II, T4 polynucleotide kinase or bovine deoxyribonuclease I, are not influenced by these compounds. In conclusion, this is the first report on potent inhibitors of mammalian Y-family pols.

Initial crystallographic study of human PCNA in complex with a peptide containing the noncanonical PIP-box sequence of human DNA polymerase iota.

Human DNA polymerase iota (Poliota) is one of the Y-family DNA polymerases involved in translesion synthesis (TLS), which allows continued replication at damaged DNA templates. Poliota has a noncanonical PCNA-interacting protein box (PIP-box) within an internal region of the protein. Poliota activity is stimulated by PCNA binding through the noncanonical PIP-box. To clarify the interaction of PCNA with the noncanonical PIP-box of Poliota, PCNA and a Poliota peptide carrying the noncanonical PIP-box complex have been cocrystallized. The crystal belongs to space group C2, with unit-cell parameters a = 167.1, b = 68.7, c = 90.0 A, beta = 95.1 degrees . Structural analysis by molecular replacement is in progress.

Crystallographic study of G178S mutant of human proliferating cell nuclear antigen.

Proliferating cell nuclear antigen (PCNA) is an evolutionarily conserved protein that forms a ring-shaped homotrimer that functions as a sliding clamp for DNA replication. The rev6-1 mutation of Saccharomyces cerevisiae, which inactivates both translesion DNA synthesis and damage-avoidance pathways while having little effect on normal cell growth, has a G178S substitution in the PCNA protein. Human PCNA protein carrying the G178S substitution was crystallized. Two crystal forms were obtained under similar conditions. Crystal forms I and II belong to space groups P2(1), with unit-cell parameters a = 84.1, b = 130.2, c = 97.8 A, beta = 113.4 degrees , and P2(1)2(1)2(1), with unit-cell parameters a = 68.1, b = 100.2, c = 131.2 A, respectively. Structural analyses by molecular replacement are now in progress.

Hypersensitivity of mouse embryonic fibroblast cells defective for DNA polymerases η, ι and κ to various genotoxic compounds: Its potential for application in chemical genotoxic screening.

Genotoxic agents cause modifications of genomic DNA, such as alkylation, oxidation, bulky adduct formation, and strand breaks, which potentially induce mutations and changes to the structure or number of genes. Majority of point mutations are generated during error-prone bypass of modified nucleotides (translesion DNA synthesis, TLS); however, when TLS fails, replication forks stalled at lesions eventually result in more lethal effects, formation of double-stranded breaks (DSBs). Here we compared sensitivities to various compounds among mouse embryonic fibroblasts derived from wild-type and knock-out mice lacking one of the three Y-family TLS DNA polymerases (Polη, Polι, and Polκ) or all of them (TKO). The compounds tested in this study include genotoxins such as methyl methanesulfonate (MMS) and nongenotoxins such as ammonium chloride. We found that TKO cells exhibited the highest sensitivities to most of the tested genotoxins, but not to the non-genotoxins. In order to quantitatively evaluate the hypersensitivity of TKO cells to different chemicals, we calculated ratios of half-maximal inhibitory concentration for WT and TKO cells. The ratios for 9 out of 10 genotoxins ranged from 2.29 to 5.73, while those for 5 nongenotoxins ranged from 0.81 to 1.63. Additionally, the two markers for DNA damage, ubiquitylated proliferating cell nuclear antigen and γ-H2AX after MMS treatment, were accumulated in TKO cells more greatly than in WT cells. Furthermore, following MMS treatment, TKO cells exhibited increased frequency of sister chromatid exchange compared with WT cells. These results indicated that the hypersensitivity of TKO cells to genotoxins resulted from replication fork stalling and subsequent DNA double-strand breaks, thus demonstrating that TKO cells should be useful for evaluating chemical genotoxicity.

Integrating S-phase checkpoint signaling with trans-lesion synthesis of bulky DNA adducts.

Bulky adducts are DNA lesions generated in response to environmental agents including benzo[a]pyrene (a combustion product) and solar ultraviolet radiation. Error-prone replication of adducted DNA can cause mutations, which may result in cancer. To minimize the detrimental effects of bulky adducts and other DNA lesions, S-phase checkpoint mechanisms sense DNA damage and integrate DNA repair with ongoing DNA replication. The essential protein kinase Chk1 mediates the S-phase checkpoint, inhibiting initiation of new DNA synthesis and promoting stabilization and recovery of stalled replication forks. Here we review the mechanisms by which Chk1 is activated in response to bulky adducts and potential mechanisms by which Chk1 signaling inhibits the initiation stage of DNA synthesis. Additionally, we discuss mechanisms by which Chk1 signaling facilitates bypass of bulky lesions by specialized Y-family DNA polymerases, thereby attenuating checkpoint signaling and allowing resumption of normal cell cycle progression.

Somatic hypermutation of immunoglobulin genes in Rad18 knockout mice.

Somatic hypermutation (SHM) of immunoglobulin (Ig) genes is triggered by the activity of activation-induced cytidine deaminase (AID). AID induces DNA lesions in variable regions of Ig genes, and error-prone DNA repair mechanisms initiated in response to these lesions introduce the mutations that characterize SHM. Error-prone DNA repair in SHM is proposed to be mediated by low-fidelity DNA polymerases such as those that mediate trans-lesion synthesis (TLS); however, the mechanism by which these enzymes are recruited to AID-induced lesions remains unclear. Proliferating cell nuclear antigen (PCNA), the sliding clamp for multiple DNA polymerases, undergoes Rad6/Rad18-dependent ubiquitination in response to DNA damage. Ubiquitinated PCNA promotes the replacement of the replicative DNA polymerase stalled at the site of a DNA lesion with a TLS polymerase. To examine the potential role of Rad18-dependent PCNA ubiquitination in SHM, we analyzed Ig gene mutations in Rad18 knockout (KO) mice immunized with T cell-dependent antigens. We found that SHM in Rad18 KO mice was similar to wild-type mice, suggesting that Rad18 is dispensable for SHM. However, residual levels of ubiquitinated PCNA were observed in Rad18 KO cells, indicating that Rad18-independent PCNA ubiquitination might play a role in SHM.

Translesion replication of benzo[a]pyrene and benzo[c]phenanthrene diol epoxide adducts of deoxyadenosine and deoxyguanosine by human DNA polymerase iota.

Human DNA polymerase iota (poliota) is a Y-family polymerase whose cellular function is presently unknown. Here, we report on the ability of poliota to bypass various stereoisomers of benzo[a]pyrene (BaP) diol epoxide (DE) and benzo[c]phenanthrene (BcPh) DE adducts at deoxyadenosine (dA) or deoxyguanosine (dG) bases in four different template sequence contexts in vitro. We find that the BaP DE dG adducts pose a strong block to poliota-dependent replication and result in a high frequency of base misincorporations. In contrast, misincorporations opposite BaP DE and BcPh DE dA adducts generally occurred with a frequency ranging between 2 x 10(-3) and 6 x 10(-4). Although dTMP was inserted efficiently opposite all dA adducts, further extension was relatively poor, with one exception (a cis opened adduct derived from BcPh DE) where up to 58% extension past the lesion was observed. Interestingly, another human Y-family polymerase, polkappa, was able to extend dTMP inserted opposite a BaP DE dA adduct. We suggest that poliota might therefore participate in the error-free bypass of DE-adducted dA in vivo by predominantly incorporating dTMP opposite the damaged base. In many cases, elongation would, however, require the participation of another polymerase more specialized in extension, such as polkappa.

Analysis of translesion replication across an abasic site by DNA polymerase IV of Escherichia coli.

Unrepaired replication-blocking DNA lesions are bypassed by specialized DNA polymerases, members of the Y super-family. In Escherichia coli the major lesion bypass DNA polymerase is pol V, whereas the function of its homologue, pol IV, is not fully understood. In vivo analysis showed that pol V has a major role in bypass across an abasic site analog, with little or no involvement of pol IV. This can result from the inability of pol IV to bypass the abasic site, or from in vivo regulation of its activity. In vitro analysis revealed that purified pol IV, in the presence of the beta subunit DNA sliding clamp, and the gamma complex clamp loader, bypassed a synthetic abasic site with very high efficiency, reaching 73% in 2 min. Bypass was observed also in the absence of the processivity proteins, albeit at a 10- to 20-fold lower rate. DNA sequence analysis revealed that pol IV skips over the abasic site, producing primarily small deletions. The RecA protein inhibited bypass by pol IV, but this inhibition was alleviated by single-strand binding protein (SSB). The fact that the in vitro bypass ability of pol IV is not manifested under in vivo conditions suggests the presence of a regulatory factor, which might be involved in controlling the access of the bypass polymerases to the damaged site in DNA.

Sequence context-dependent replication of DNA templates containing UV-induced lesions by human DNA polymerase iota.

Humans possess four Y-family polymerases: pols eta, iota, kappa and the Rev1 protein. The pivotal role that pol eta plays in protecting us from UV-induced skin cancers is unquestioned given that mutations in the POLH gene (encoding pol eta), lead to the sunlight-sensitive and cancer-prone xeroderma pigmentosum variant phenotype. The roles that pols iota, kappa and Rev1 play in the tolerance of UV-induced DNA damage is, however, much less clear. For example, in vitro studies in which the ability of pol iota to bypass UV-induced cyclobutane pyrimidine dimers (CPDs) or 6-4 pyrimidine-pyrimidone (6-4PP) lesions has been assayed, are somewhat varied with results ranging from limited misinsertion opposite CPDs to complete lesion bypass. We have tested the hypothesis that such discrepancies might have arisen from different assay conditions and local sequence contexts surrounding each UV-photoproduct and find that pol iota can facilitate significant levels of unassisted highly error-prone bypass of a T-T CPD, particularly when the lesion is located in a 3'-A[T-T]A-5' template sequence context and the reaction buffer contains no KCl. When encountering a T-T 6-4PP dimer under the same assay conditions, pol iota efficiently and accurately inserts the correct base, A, opposite the 3'T of the 6-4PP by factors of approximately 10(2) over the incorporation of incorrect nucleotides, while incorporation opposite the 5'T is highly mutagenic. Pol kappa has been proposed to function in the bypass of UV-induced lesions by helping extend primers terminated opposite CPDs. However, we find no evidence that the combined actions of pol iota and pol kappa result in a significant increase in bypass of T-T CPDs when compared to pol iota alone. Our data suggest that under certain conditions and sequence contexts, pol iota can bypass T-T CPDs unassisted and can efficiently incorporate one or more bases opposite a T-T 6-4PP. Such biochemical activities may, therefore, be of biological significance especially in XP-V cells lacking the primary T-T CPD bypassing enzyme, pol eta.

Normal immunoglobulin gene somatic hypermutation in Pol kappa-Pol iota double-deficient mice.

Somatic hypermutation (SHM) occurs in the variable region of immunoglobulin genes in germinal center B cells where it plays an important role in affinity maturation of the T cell-dependent immune response. Although the precise mechanism of SHM is still unknown, it has been suggested that error-prone DNA polymerases (Pol) are involved in SHM. Poliota is a member of the error-prone Y-family of DNA polymerases which exhibit translesion synthesis activity in vitro and are highly mutagenic when replicating on non-damaged DNA templates. In BL2 cell line stimulated to induce SHM, the induction is Poliota-dependent. However, in 129-derived strains of mice deficient in Poliota, SHM is normal. One possible explanation for this discrepancy is that a Poliota deficiency in mice might be compensated for by another error-prone DNA polymerase, such as Polkappa, which also belongs to the Y-family of DNA polymerases. Although SHM in Polkappa-deficient mice is normal, their deficiency might be compensated for by Poliota. In this study, we generated Polkappa-Poliota double-deficient mice and examined them for SHM. We found that the double-deficient mice had the normal SHM frequency and profile, rendering them indistinguishable from Polkappa-deficient mice and thus conclude that Poliota and Polkappa are dispensable for SHM in mice.

The absence of DNA polymerase kappa does not affect somatic hypermutation of the mouse immunoglobulin heavy chain gene.

During the immune response to T cell-dependent antigen, somatic hypermutation (SHM) is introduced into immunoglobulin (Ig) genes. The variable region is the target for SHM and it is here that DNA lesions are introduced and mutations are generated. It has been suggested that error-prone DNA polymerase(s) may play an important role in this mutagenesis phase. Recently, DNA polymerase kappa (Polkappa), which belongs to the Y-family of DNA polymerases, was identified. Since a hot spot of SHMs (RGYW motif) is also a hot spot of mutations by human Polkappa, this enzyme was suggested to be an SHM instigator. In order to address the question whether Polkappa is involved in SHM, we immunized Polkappa-deficient mice and analyzed the SHM of the Ig heavy chain gene. We found that the SHM frequency and spectrum were indistinguishable between the Polkappa knockout mice and control mice. These results suggested that Polkappa is not essential for this process.

Different sets of translesion synthesis DNA polymerases protect from genome instability induced by distinct food-derived genotoxins.

DNA lesions, induced by genotoxic compounds, block the processive replication fork but can be bypassed by specialized translesion synthesis (TLS) DNA polymerases (Pols). TLS safeguards the completion of replication, albeit at the expense of nucleotide substitution mutations. We studied the in vivo role of individual TLS Pols in cellular responses to benzo[a]pyrene diolepoxide (BPDE), a polycyclic aromatic hydrocarbon, and 4-hydroxynonenal (4-HNE), a product of lipid peroxidation. To this aim, we used mouse embryonic fibroblasts with targeted disruptions in the TLS-associated Pols η, ι, κ, and Rev1 as well as in Rev3, the catalytic subunit of TLS Polζ. After exposure, cellular survival, replication fork progression, DNA damage responses (DDR), and the induction of micronuclei were investigated. The results demonstrate that Rev1, Rev3, and, to a lesser extent, Polη are involved in TLS and the prevention of DDR and of DNA breaks, in response to both agents. Conversely, Polκ and the N-terminal BRCT domain of Rev1 are specifically involved in TLS of BPDE-induced DNA damage. We furthermore describe a novel role of Polι in TLS of 4-HNE-induced DNA damage in vivo. We hypothesize that different sets of TLS polymerases act on structurally different genotoxic DNA lesions in vivo, thereby suppressing genomic instability associated with cancer. Our experimental approach may provide a significant contribution in delineating the molecular bases of the genotoxicity in vivo of different classes of DNA-damaging agents.