The Rev3 gene of Saccharomyces cerevisiae encodes the catalytic subunit of DNA polymerase that is implicated in mutagenic translesion synthesis of damaged DNA. To investigate the function of its mouse homologue, we have generated mouse embryonic stem cells and mice carrying a targeted disruption of Rev3. Although some strain-dependent variation was observed, Rev3 ؊/؊ embryos died around midgestation, displaying retarded growth in the absence of consistent developmental abnormalities. Rev3 ؊/؊ cell lines could not be established, indicating a cell-autonomous requirement of Rev3 for long-term viability. Histochemical analysis of Rev3 ؊/؊ embryos did not reveal aberrant replication or cellular proliferation but demonstrated massive apoptosis in all embryonic lineages. Although increased levels of p53 are detected in Rev3 ؊/؊ embryos, the embryonic phenotype was not rescued by the absence of p53. A significant increase in double-stranded DNA breaks as well as chromatid and chromosome aberrations was observed in cells from Rev3 ؊/؊ embryos. The inner cell mass of cultured Rev3 ؊/؊ blastocysts dies of a delayed apoptotic response after exposure to a low dose of N-acetoxy-2-acetylaminofluorene. These combined data are compatible with a model in which, in the absence of polymerase , double-stranded DNA breaks accumulate at sites of unreplicated DNA damage, eliciting a p53-independent apoptotic response. Together, these data are consistent with involvement of polymerase in translesion synthesis of endogenously and exogenously induced DNA lesions.In cancer genetics, the paradigm holds the sequential mutation of a series of oncogenes and tumor suppressor genes responsible for the evolutionary development of a normal cell into a fully malignant, metastasizing tumor (67). Most mutations are induced by nucleotide damage, originating from endogenous sources or inflicted by exogenous agents (49). Nucleotide damage that is not removed by DNA repair proteins generally leads to an arrest of the replication fork, due to the rigidity of the replicative polymerases, preventing incorporation of a nucleotide opposite a damaged template (51). To escape this arrest, cells possess multiple pathways that enable the completion of DNA replication despite the presence of replication-blocking DNA damage (3, 9).Considerable progress has recently been made in identifying the actors in translesion synthesis, a pathway implicated in replicating damaged DNA. In both prokaryotes and eukaryotes, multiple polymerases have been identified that are capable of replicating DNA templates containing a variety of lesions. This enables the completion of replication and therefore safeguards cellular survival, albeit frequently at the expense of the introduction of mutations. Based on sequence homology and activity in vitro, most of the polymerases associated with translesion synthesis belong to the newly recognized Y superfamily of DNA polymerases (16,21,30,32,57,70). The heterodimeric Saccharomyces cerevisiae polymerase , comprised of the REV3 catalytic subun...
