An essential role for REV3 in mammalian cell survival: absence of REV3 induces p53-independent embryonic death

The REV3 gene of budding yeast encodes the catalytic subunit of DNA polymerase zeta that carries out translesion DNA synthesis. While REV3-null yeast mutants are viable and exhibit normal growth, Rev3-deficient mice die around midgestation of embryogenesis, which is accompanied by massive apoptosis of cells within the embryo proper. We have investigated whether REV3 is required for the survival of mouse cells and whether the embryonic lethality caused by REV3 deficiency can be rescued by introduction of a Rev3 transgene or by inactivation of p53, the cellular gatekeeper that regulates DNA damage-induced apoptosis. We show that Rev3(-/-) blastocysts were unable to survive and grow in culture but expression of a Rev3 transgene restored their outgrowth. Moreover, Rev3 transgene expression suppressed the apoptosis in E7.5 Rev3(-/-) embryos. The Rev3(-/-) embryonic lethality, however, was not rescued by either Rev3 transgene expression or p53 deficiency. These results reveal an essential role for REV3 in the survival and growth of mammalian cells and suggest that Rev3(-/-) embryonic death occurs in a p53-independent pathway.     

Immortalized mouse cell lines that lack a functional Rev3 gene are hypersensitive to UV irradiation and cisplatin treatment

The catalytic subunit of polymerase zeta is encoded from the Rev3 gene. The enzyme is conserved through eukaryotic evolution and its main function appears to be translesion synthesis (TLS) over damaged bases that stall DNA replication. In non-vertebrate cells, inactivation of polymerase zeta results in a moderate hypersensitivity to DNA damage but no proliferative defect in the absence of exogenous damage. Mouse embryos that lack Rev3 however have a severe growth defect and are aborted at midgestation. This has suggested that polymerase zeta may be involved in vital processes in mammalian cells. Here we describe the establishment of immortalized mouse fibroblast cell lines that lack a functional Rev3 gene. These were established from homozygously Rev3-targeted mouse embryos that were also heterozygously targeted at the p53 locus, but the cell lines lost the wild type p53 allele during transformation. Cell lines in which the Rev3 gene is targeted on both alleles grow more slowly than control lines and the deficiency is also associated with an increased frequency of cells at the G2/M phase of the cell cycle and augmented apoptosis. Targeted cells are hypersensitive to UV irradiation and cisplatin treatment and arrest at the S or G2/M phase of the cell cycle if exposed to these treatments. Thus, although vital for murine embryonic development, polymerase zeta activity is not essential for continuous proliferation of transformed mammalian cells that lack p53. It does, however, appear to play an important role in allowing mammalian cells to tolerate DNA damage.     

DNA repair: DNA polymerase zeta and Rev1 break in

DNA polymerase zeta and Rev1 play key roles in replication past DNA lesions. New work shows that the yeast checkpoint kinase Mec1 recruits a complex consisting of polymerase zeta and Rev1 to DNA double-strand breaks. This study highlights the role of polymerases that mediate translesion synthesis in the response to DNA double-strand breaks.     

DNA polymerase zeta （pol ζ） in higher eukaryotes

Most current knowledge about DNA polymerase zeta （pol ζ） comes from studies of the enzyme in the budding yeast Saccharomyces cerevisiae, where pol ζ consists of a complex of the catalytic subunit Rev3 with Rev7, which associates with Revl. Most spontaneous and induced mutagenesis in yeast is dependent on these gene products, and yeast pol can mediate translesion DNA synthesis past some adducts in DNA templates. Study of the homologous gene products in higher eukaryotes is in a relatively early stage, but additional functions for the eukaryotic proteins are already apparent. Suppression of vertebrate REV3L function not only reduces induced point mutagenesis but also causes larger-scale genome instability by raising the frequency of spontaneous chromosome translocations. Disruption of Rev3L function is tolerated in Drosophila, Arabidopsis, and in vertebrate cell lines under some conditions, but is incompatible with mouse embryonic development. Functions for REV3L and REV7（MAD2B） in higher eukaryotes have been suggested not only in translesion DNA synthesis but also in some forms of homologous recombination, repair of interstrand DNA crosslinks, somatic hypermutation of immunoglobulin genes and cell-cycle control. This review discusses recent developments in these areas.     

The Polymerase Activity of Mammalian DNA Pol ζ Is Specifically Required for Cell and Embryonic Viability

DNA polymerase ζ (pol ζ) is exceptionally important for maintaining genome stability. Inactivation of the Rev3l gene encoding the polymerase catalytic subunit causes a high frequency of chromosomal breaks, followed by lethality in mouse embryos and in primary cells. Yet it is not known whether the DNA polymerase activity of pol ζ is specifically essential, as the large REV3L protein also serves as a multiprotein scaffold for translesion DNA synthesis via multiple conserved structural domains. We report that Rev3l cDNA rescues the genomic instability and DNA damage sensitivity of Rev3l-null immortalized mouse fibroblast cell lines. A cDNA harboring mutations of conserved catalytic aspartate residues in the polymerase domain of REV3L could not rescue these phenotypes. To investigate the role of REV3L DNA polymerase activity in vivo, a Rev3l knock-in mouse was constructed with this polymerase-inactivating alteration. No homozygous mutant mice were produced, with lethality occurring during embryogenesis. Primary fibroblasts from mutant embryos showed growth defects, elevated DNA double-strand breaks and cisplatin sensitivity similar to Rev3l-null fibroblasts. We tested whether the severe Rev3l^-/- phenotypes could be rescued by deletion of DNA polymerase η, as has been reported with chicken DT40 cells. However, Rev3l^-/- Polh^-/- mice were inviable, and derived primary fibroblasts were as sensitive to DNA damage as Rev3l^-/- Polh^+/+ fibroblasts. Therefore, the functions of REV3L in maintaining cell viability, embryonic viability and genomic stability are directly dependent on its polymerase activity, and cannot be ameliorated by an additional deletion of pol η. These results validate and encourage the approach of targeting the DNA polymerase activity of pol ζ to sensitize tumors to DNA damaging agents.     

Disruption of the Rev3l-encoded catalytic subunit of polymerase zeta in mice results in early embryonic lethality

Polymerase zeta (Pol zeta) is an error-prone DNA polymerase [1], which in yeast is involved in trans-lesion synthesis (TLS) and is responsible for most of the ultraviolet (UV) radiation-induced and spontaneous mutagenesis [2-4]. Pol zeta consists of three subunits: REV1, a deoxycytidyl-transferase [5]; REV7, of unclear function [6]; and REV3, the catalytic subunit. REV3 alone is sufficient to carry out TLS, but association with REV1 and REV7 enhances its activity [5, 7]. Experiments using human cells treated with UV radiation indicate also that mammalian Pol zeta is involved in TLS [7]. The peculiar mutagenic activity of Pol zeta [4,7,8] suggests a possible role in somatic hypermutation of immunoglobulin (Ig) genes [9]. Here, we report that, unlike in yeast where the REV3 gene is not essential for life [4], disruption of the mouse homologue (Rev3l) resulted in early embryonic lethality. In Rev3l(-/-) embryos, no haematopoietic cells other than erythrocytes could be identified in the yolk sac. Rev3l(-/-) haematopoietic precursors were unable to expand in vitro and no haematopoietic cells could be derived from the intraembryonic haematogenic compartment (splanchnopleura). Fibroblasts could not be derived from the Rev3l(-/-) embryos, and Rev3l(-/-) embryonic stem (ES) cells could not be obtained. This is the first evidence that an enzyme involved in TLS is critical for mammalian development.     

Disruption of the developmentally regulated Rev3l gene causes embryonic lethality

The REV3 gene encodes the catalytic subunit of DNA polymerase (pol) zeta, which can replicate past certain types of DNA lesions [1]. Saccharomyces cerevisiae rev3 mutants are viable and have lower rates of spontaneous and DNA-damage-induced mutagenesis [2]. Reduction in the level of Rev31, the presumed catalytic subunit of mammalian pol zeta, decreased damage-induced mutagenesis in human cell lines [3]. To study the function of mammalian Rev31, we inactivated the gene in mice. Two exons containing conserved DNA polymerase motifs were replaced by a cassette encoding G418 resistance and beta-galactosidase, under the control of the Rev3l promoter. Surprisingly, disruption of Rev3l caused mid-gestation embryonic lethality, with the frequency of Rev3l(-/-) embryos declining markedly between 9.5 and 12.5 days post coitum (dpc). Rev3l(-/-) embryos were smaller than their heterozygous littermates and showed retarded development. Tissues in many areas were disorganised, with significantly reduced cell density. Rev3l expression, traced by beta-galactosidase staining, was first detected during early somitogenesis and gradually expanded to other tissues of mesodermal origin, including extraembryonic membranes. Embryonic death coincided with the period of more widely distributed Rev3l expression. The data demonstrate an essential function for murine Rev31 and suggest that bypass of specific types of DNAlesions by pol zeta is essential for cell viability during embryonic development in mammals.     

DNA polymerase zeta is required for proliferation of normal mammalian cells

Unique among translesion synthesis (TLS) DNA polymerases, pol ζ is essential during embryogenesis. To determine whether pol ζ is necessary for proliferation of normal cells, primary mouse fibroblasts were established in which Rev3L could be conditionally inactivated by Cre recombinase. Cells were grown in 2% O(2) to prevent oxidative stress-induced senescence. Cells rapidly became senescent or apoptotic and ceased growth within 3-4 population doublings. Within one population doubling following Rev3L deletion, DNA double-strand breaks and chromatid aberrations were found in 30-50% of cells. These breaks were replication dependent, and found in G1 and G2 phase cells. Double-strand breaks were reduced when cells were treated with the reactive oxygen species scavenger N-acetyl-cysteine, but this did not rescue the cell proliferation defect, indicating that several classes of endogenously formed DNA lesions require Rev3L for tolerance or repair. T-antigen immortalization of cells allowed cell growth. In summary, even in the absence of external challenges to DNA, pol ζ is essential for preventing replication-dependent DNA breaks in every division of normal mammalian cells. Loss of pol ζ in slowly proliferating mouse cells in vivo may allow accumulation of chromosomal aberrations that could lead to tumorigenesis. Pol ζ is unique amongst TLS polymerases for its essential role in cell proliferation.     

Proliferating cell nuclear antigen promotes translesion synthesis by DNA polymerase zeta

DNA polymerase zeta (Pol zeta), a heterodimer of Rev3 and Rev7, is essential for DNA damage provoked mutagenesis in eukaryotes. DNA polymerases that function in a processive complex with the replication clamp proliferating cell nuclear antigen (PCNA) have been shown to possess a close match to the consensus PCNA-binding motif QxxLxxFF. This consensus motif is lacking in either subunit of Pol zeta, yet its activity is stimulated by PCNA. In particular, translesion synthesis of UV damage-containing DNA is dramatically stimulated by PCNA such that translesion synthesis rates are comparable with replication rates by Pol zeta on undamaged DNA. PCNA also stimulated translesion synthesis of a model abasic site by Pol zeta. Efficient PCNA stimulation required that PCNA was prevented from sliding off the damage-containing model oligonucleotide template-primer through the use of biotin-streptavidin bumpers or other blocks. Under those experimental conditions, facile bypass of the abasic site was also detected by DNA polymerase delta or eta (Rad30). The yeast DNA damage checkpoint clamp, consisting of Rad17, Mec3, and Ddc1, and an ortholog of human 9-1-1, has been implicated in damage-induced mutagenesis. However, this checkpoint clamp did not stimulate translesion synthesis by Pol zeta or by DNA polymerase delta.     

Rev1 is essential for DNA damage tolerance and non-templated immunoglobulin gene mutation in a vertebrate cell line

The majority of DNA damage-induced mutagenesis in the yeast Saccharomyces cerevisiae arises as a result of translesion replication. This process is critically dependent on the deoxycytidyl transferase Rev1p, which forms a complex with the subunits of DNA polymerase zeta, Rev3p and Rev7p. To examine the role of Rev1 in vertebrate mutagenesis and the DNA damage response, we disrupted the gene in DT40 cells. Rev1-deficient DT40 grow slowly and are sensitive to a wide range of DNA-damaging agents. Homologous recombination repair is likely to be intact as basal and damage induced sister chromatid exchange and immunoglobulin gene conversion are unaffected. How ever, the mutant cells show a markedly reduced level of non-templated immunoglobulin gene mutation, indicating a defect in translesion bypass. Furthermore, ultraviolet exposure results in marked chromosome breakage, suggesting that replication gaps created in the absence of Rev1 cannot be efficiently repaired by recombination. Thus, Rev1-dependent translesion bypass and mutagenesis is likely to be a trade-off for the ability to complete replication of a damaged template and thereby maintain genome integrity.     

Competition between replicative and translesion polymerases during homologous recombination repair in Drosophila

In metazoans, the mechanism by which DNA is synthesized during homologous recombination repair of double-strand breaks is poorly understood. Specifically, the identities of the polymerase(s) that carry out repair synthesis and how they are recruited to repair sites are unclear. Here, we have investigated the roles of several different polymerases during homologous recombination repair in Drosophila melanogaster. Using a gap repair assay, we found that homologous recombination is impaired in Drosophila lacking DNA polymerase zeta and, to a lesser extent, polymerase eta. In addition, the Pol32 protein, part of the polymerase delta complex, is needed for repair requiring extensive synthesis. Loss of Rev1, which interacts with multiple translesion polymerases, results in increased synthesis during gap repair. Together, our findings support a model in which translesion polymerases and the polymerase delta complex compete during homologous recombination repair. In addition, they establish Rev1 as a crucial factor that regulates the extent of repair synthesis.     

Mammalian polymerase ζ is essential for post-replication repair of UV-induced DNA lesions

DNA polymerase ζ is believed to be an essential constituent of DNA damage tolerance, comprising several pathways that allow the replication of DNA templates containing unrepaired damage. We wanted to better define the role of polymerase ζ in DNA damage tolerance in mammalian cells. To this aim we have investigated replication of ultraviolet light-damaged DNA templates in mouse embryonic fibroblasts deficient for Rev3, the catalytic subunit of polymerase ζ. We found that Rev3 is important for a post-replication repair pathway of helix-distorting [6-4]pyrimidine-pyrimidone photoproducts and, to a lesser extent, of cyclobutane pyrimidine dimers. Unlike its partner Rev1, Rev3 appears not to be involved in an immediate translesion synthesis pathway at a stalled replication fork. The deficiency of Rev3^?/? MEFs in post-replication repair of different photoproducts contributes to the extreme sensitivity of these cells to UV light.     

Overexpression of DNA polymerase zeta reduces the mitochondrial mutability caused by pathological mutations in DNA polymerase gamma in yeast

In yeast, DNA polymerase zeta (Rev3 and Rev7) and Rev1, involved in the error-prone translesion synthesis during replication of nuclear DNA, localize also in mitochondria. We show that overexpression of Rev3 reduced the mtDNA extended mutability caused by a subclass of pathological mutations in Mip1, the yeast mitochondrial DNA polymerase orthologous to human Pol gamma. This beneficial effect was synergistic with the effect achieved by increasing the dNTPs pools. Since overexpression of Rev3 is detrimental for nuclear DNA mutability, we constructed a mutant Rev3 isoform unable to migrate into the nucleus: its overexpression reduced mtDNA mutability without increasing the nuclear one.     

Distinct roles for Rev1p and Rev7p during translesion synthesis in Saccharomyces cerevisiae

Translesion synthesis (TLS) in Saccharomyces cerevisiae requires at least Rev1p and polymerase zeta (Pol zeta), a complex of the Rev3 polymerase and its accessory factor Rev7p. Although their precise role(s) are poorly characterized, in vitro studies suggest that each protein contributes to TLS in a manner dependent on the particular lesion and surrounding DNA sequence. In the present study, strand segregation analysis is used to attempt to identify the role(s) of the Rev1 and Rev7 proteins during TLS. This assay uses double-stranded plasmids containing a genetic marker opposite to a replication blocking lesion (N-2-acetylaminofluorene; AAF) to measure TLS quantitatively and qualitatively in vivo. The AAF adduct is localized within a repetitive sequence in a manner that allows the formation of misaligned primer-template replication intermediates. Elongation from a misaligned intermediate fixes a frameshift mutation (slipped TLS), while extension of the correctly aligned lesion terminus yields error-free (non-slipped) TLS. The results indicate that there is a strong requirement for Rev7p during Pol zeta-mediated TLS measured in vivo. Furthermore, Rev1p is needed only for non-slipped TLS; slipped TLS remains efficient in its absence, revealing a previously uncharacterized Rev1p activity similar to Escherichia coli UmuDC function. Specifically, this activity is required for elongation from a correctly aligned lesion terminus.     

Mutagenesis in eukaryotes dependent on DNA polymerase zeta and Rev1p

DNA polymerase zeta (Pol zeta) and Rev1p carry out translesion replication in budding yeast, Saccharomyces cerevisiae, and are jointly responsible for almost all base pair substitution and frameshift mutations induced by DNA damage in this organism. In addition, Pol zeta is responsible for the majority of spontaneous mutations in yeast and has been proposed as the enzyme responsible for somatic hypermutability. Pol zeta, a non-processive enzyme that lacks a 3' to 5' exonuclease proofreading activity, is composed of Rev3p, the catalytic subunit, and a second subunit encoded by REV7. In keeping with its role, extension by Pol zeta is relatively tolerant of abnormal DNA structure at the primer terminus and is much more capable of extension from terminal mismatches than yeast DNA polymerase alpha (Pol alpha). Rev1p is a bifunctional enzyme that possesses a deoxycytidyl transferase activity that incorporates deoxycytidyl opposite abasic sites in the template and a second, at present poorly defined, activity that is required for the bypass of a variety of lesions as well as abasic sites. Human homologues of the yeast REV1 and REV3 have been identified and, based on the phenotype of cells producing antisense RNA to one or other of these genes, their products appear also to be employed in translation replication and spontaneous mutagenesis. We suggest that Pol zeta is best regarded as a replication enzyme, albeit one that is used only intermittently, that promotes extension at forks the progress of which is blocked for any reason, whether the presence of an unedited terminal mismatch or unrepaired DNA lesion.     

Multiple roles of Rev3, the catalytic subunit of polzeta in maintaining genome stability in vertebrates

Translesion DNA synthesis (TLS) and homologous DNA recombination (HR) are two major postreplicational repair (PRR) pathways. The REV3 gene of Saccharomyces cerevisiae encodes the catalytic subunit of DNA polymerase zeta, which is involved in mutagenic TLS. To investigate the role of REV3 in vertebrates, we disruped the gene in chicken DT40 cells. REV3(-/-) cells are sensitive to various DNA-damaging agents, including UV, methyl methanesulphonate (MMS), cisplatin and ionizing radiation (IR), consistent with its role in TLS. Interestingly, REV3(-/-) cells showed reduced gene targeting efficiencies and significant increase in the level of chromosomal breaks in the subsequent M phase after IR in the G(2) phase, suggesting the involvement of Rev3 in HR-mediated double-strand break repair. REV3(-/-) cells showed significant increase in sister chromatid exchange events and chromosomal breaks even in the absence of exogenous genotoxic stress. Furthermore, double mutants of REV3 and RAD54, genes involved in HR, are synthetic lethal. In conclusion, Rev3 plays critical roles in PRR, which accounts for survival on naturally occurring endogenous as well as induced damages during replication.     

ATR homolog Mec1 controls association of DNA polymerase zeta-Rev1 complex with regions near a double-strand break

DNA polymerase zeta (Polzeta) and Rev1 contribute to the bypassing of DNA lesions, termed translesion DNA synthesis (TLS). Polzeta consists of two subunits, one encoded by REV3 (the catalytic subunit) and the other encoded by REV7. Rev1 acts as a deoxycytidyl transferase, inserting dCMP opposite lesions. Polzeta and Rev1 have been shown to operate in the same TLS pathway in the budding yeast Saccharomyces cerevisiae. Here, we show that budding yeast Polzeta and Rev1 form a complex and associate together with double-strand breaks (DSBs). As a component of the Polzeta-Rev1 complex, Rev1 plays a noncatalytic role in the association with DSBs. In budding yeast, the ATR-homolog Mec1 plays a central role in the DNA-damage checkpoint response. We further show that Mec1-dependent phosphorylation promotes the Polzeta-Rev1 association with DSBs. Rev1 association with DSBs requires neither the function of the Rad24 checkpoint-clamp loader nor the Rad6-Rad18-mediated ubiquitination of PCNA. Our results reveal a novel role of Mec1 in the localization of the Polzeta-Rev1 complex to DNA lesions and highlight a linkage of TLS polymerases to the checkpoint response.     

Mouse Rev1 protein interacts with multiple DNA polymerases involved in translesion DNA synthesis

Pol kappa and Rev1 are members of the Y family of DNA polymerases involved in tolerance to DNA damage by replicative bypass [translesion DNA synthesis (TLS)]. We demonstrate that mouse Rev1 protein physically associates with Pol kappa. We show too that Rev1 interacts independently with Rev7 (a subunit of a TLS polymerase, Pol zeta) and with two other Y-family polymerases, Pol iota and Pol eta. Mouse Pol kappa, Rev7, Pol iota and Pol eta each bind to the same approximately 100 amino acid C-terminal region of Rev1. Furthermore, Rev7 competes directly with Pol kappa for binding to the Rev1 C-terminus. Notwithstanding the physical interaction between Rev1 and Pol kappa, the DNA polymerase activity of each measured by primer extension in vitro is unaffected by the complex, either when extending normal primer-termini, when bypassing a single thymine glycol lesion, or when extending certain mismatched primer termini. Our observations suggest that Rev1 plays a role(s) in mediating protein-protein interactions among DNA polymerases required for TLS. The precise function(s) of these interactions during TLS remains to be determined.