Differential Roles for DNA Polymerases Eta,Zeta, and REV1 in Lesion Bypass of Intrastrand versus Interstrand DNA Cross-Links

Translesion DNA synthesis (TLS) is a process whereby specialized DNA polymerases are recruited to bypass DNA lesions that would otherwise stall high-fidelity polymerases. We provide evidence that TLS across cisplatin intrastrand cross-links is performed by multiple translesion DNA polymerases. First, we determined that PCNA monoubiquitination by RAD18 is necessary for efficient bypass of cisplatin adducts by the TLS polymerases eta (Polη), REV1, and zeta (Polζ) based on the observations that depletion of these proteins individually leads to decreased cell survival, cell cycle arrest in S phase, and activation of the DNA damage response. Second, we showed that in addition to PCNA monoubiquitination by RAD18, the Fanconi anemia core complex is also important for recruitment of REV1 to stalled replication forks in cisplatin treated cells. Third, we present evidence that REV1 and Polζ are uniquely associated with protection against cisplatin and mitomycin C-induced chromosomal aberrations, and both are necessary for the timely resolution of DNA double-strand breaks associated with repair of DNA interstrand cross-links. Together, our findings indicate that REV1 and Polζ facilitate repair of interstrand cross-links independently of PCNA monoubiquitination and Polη, whereas RAD18 plus Polη, REV1, and Polζ are all necessary for replicative bypass of cisplatin intrastrand DNA cross-links.Maintenance of genomic integrity involves the activation of cell cycle checkpoints coupled with DNA repair. Despite these sophisticated mechanisms to remove DNA lesions prior to DNA replication, replication forks may inevitably encounter nonrepaired lesions that block high fidelity polymerases, potentially leading to replication fork instability, gaps in replicated DNA, and the generation of DNA double-strand breaks (DSBs). In order to preserve replication fork stability by allowing replication through polymerase blocking lesions, template DNA containing a damaged base or abasic site can be replicated through the actions of specialized translesion DNA synthesis (TLS) polymerases (61). A key event in the regulation of TLS is the monoubiquitination of PCNA, a homotrimeric protein that functions as an auxiliary factor for DNA polymerases (28, 31, 57, 60). The RAD6 (E2)-RAD18 (E3) complex specifically monoubiquitinates PCNA on Lys-164 in response to replication fork stalling. This event is thought to operate as a molecular switch from normal DNA replication to the TLS pathway based on the observations that association of Y-family TLS polymerases with monoubiquitinated PCNA is strengthened through the cooperative binding of one or more ubiquitin-binding domains (UBM or UBZ) plus a PCNA-interacting domain (6, 25).Extensive biochemical evidence suggests that replication through a large variety of lesions requires the sequential action of two TLS polymerases (44). The Y-family polymerase eta (Polη) plays a key role in the efficient and error-free bypass of cyclobutane pyrimidine (TT) dimers, one of the major lesions resulting from exposure to UV radiation (45). In contrast, Polη can only insert a nucleotide directly opposite other lesions and requires an additional TLS polymerase, such as Polζ, to extend beyond the insertion (45). Polζ is comprised of the REV3 catalytic subunit that shares homology with B-family polymerases plus the REV7 accessory subunit (34). Polζ is unusual compared to other TLS polymerases due to the fact that it is relatively efficient at extending beyond mispaired primer termini and nucleotides inserted opposite a variety of DNA lesions, although this may occur in a potentially mutagenic manner (45). Genetic evidence in yeast suggest that Polζ activity is regulated by the Y family REV1 polymerase (21). In addition to a UBM domain that directly interacts with monoubiquitinated PCNA, REV1 possesses an N-terminal BRCT motif that directly contacts PCNA and potentially other proteins (24, 25). In addition, REV1 possesses a unique protein interaction domain in its carboxy terminus that interacts with the Polζ accessory subunit, REV7, and other TLS polymerases, including Polη and the Polζ catalytic subunit, REV3 (1, 18, 23, 40, 58). The characterization of these protein-protein interaction domains has led to the proposal that REV1 facilitates polymerase switching from a polymerase that directly inserts a nucleotide opposite a damaged base and Polζ, which subsequently performs the extension step beyond the inserted nucleotide opposite the damaged base (21).In addition to facilitating direct lesion bypass and filling in postreplicative gaps in DNA, REV1 and Polζ may also play an important role in the repair of interstrand cross-links (46, 63). Deletion of REV1, REV3, or REV7 in chicken DT40 cells leads to remarkable hypersensitivity to a wide variety of genotoxic stresses, most notably cisplatin and other DNA cross-linking agents such as mitomycin C (MMC) (38, 41, 55, 56). The genetic epistasis observed between REV1, REV3, and the Fanconi anemia (FA) complementation group C (FANCC) gene for cisplatin sensitivity further implicates TLS in the interstrand cross-link repair pathway (38). Current models suggest that when two replication forks converge upon an interstrand cross-link, the MUS81-EME1 endonuclease recognizes and cleaves the resulting branched DNA structure by making an incision at one side of the interstrand cross-link creating a replication-associated DSB (26). The XPF-ERCC1 endonuclease uncouples the cross-linked cDNA strands by making an incision on the other side of the interstrand cross-link (37). Recent biochemical evidence suggests that Polζ performs DNA synthesis opposite the DNA strand containing the residual cross-link and this process may be necessary to prepare the daughter strand for subsequent homologous recombination repair of the replication-associated DSB (46).Agents that introduce intra- and interstrand cross-links are widely used in cancer chemotherapy, and thus understanding the means by which cells repair or cope with these lesions will be instrumental in identifying novel mechanisms leading to drug resistance and designing new agents refractory to DNA damage tolerance mechanisms. Polη, REV1, and Polζ have all been implicated in mediating TLS past cisplatin intrastrand cross-links since lowering their expression increases sensitivity and reduces cisplatin-induced mutagenesis in human cancer cells (2, 5, 12, 42, 62). Furthermore, biochemical and structural analyses of Polη identified this polymerase as being capable of efficiently inserting dCTP opposite the 3′dG of a 1,2-d(GpG) cisplatin intrastrand cross-link (3). Here, we demonstrate that RAD18, Polη, and REV1 all localized to sites of replication stress marked by PCNA and γ-H2AX foci after treatment of cells with cisplatin. However, REV1 focus formation is specifically dependent upon both RAD18 and a functional FA core complex, suggesting FA core proteins are also necessary for directing REV1 to cisplatin-induced stalled replication forks. In addition, depletion of RAD18, Polη, REV1, or Polζ proteins lead to the induction of cellular responses indicative of inefficient lesion bypass of cisplatin adducts. Unexpectedly, we found that REV1- or Polζ-depleted cells displayed a greater loss in cell viability and the accumulation of chromosome aberrations and failed to resolve DSBs after cisplatin treatment. These results lead us to hypothesize that REV1 and Polζ may be necessary for the repair of cisplatin interstrand cross-links in addition to performing lesion bypass of cisplatin intrastrand cross-links. In agreement with this concept, we found that REV1 and Polζ-depleted cells were uniquely hypersensitive to MMC, accumulated greater numbers of chromosome aberrations, and failed to resolve replication-associated DSBs induced by MMC treatment.Together our findings support a model where replicative bypass of cisplatin intrastrand cross-links requires cooperation of multiple TLS polymerases in mammalian cells and is triggered by PCNA monoubiquitination. Our results also provide evidence that REV1 and Polζ facilitate repair of interstrand cross-links in human cells, and this process is likely independent of PCNA monoubiquitination.