Somatic hypermutation of Ig genes enables B cells of the germinal center to generate high-affinity immunoglobulin variants. Key intermediates in somatic hypermutation are deoxyuridine lesions, introduced by activation-induced cytidine deaminase. These lesions can be processed further to abasic sites by uracil DNA glycosylase. Mutagenic replication of deoxyuridine, or of its abasic derivative, by translesion synthesis polymerases is hypothesized to underlie somatic hypermutation.Rev1 is a translesion synthesis polymerase that in vitro incorporates uniquely deoxycytidine opposite deoxyuridine and abasic residues. To investigate a role of Rev1 in mammalian somatic hypermutation we have generated mice deficient for Rev1. Although Rev1−/− mice display transient growth retardation, proliferation of Rev1−/− LPS-stimulated B cells is indistinguishable from wild-type cells. In mutated Ig genes from Rev1−/− mice, C to G transversions were virtually absent in the nontranscribed (coding) strand and reduced in the transcribed strand. This defect is associated with an increase of A to T, C to A, and T to C substitutions. These results indicate that Rev1 incorporates deoxycytidine residues, most likely opposite abasic nucleotides, during somatic hypermutation. In addition, loss of Rev1 causes compensatory increase in mutagenesis by other translesion synthesis polymerases.
The Y family DNA polymerase Rev1 has been proposed to play a regulatory role in the replication of damaged templates. To elucidate the mechanism by which Rev1 promotes DNA damage bypass, we have analyzed the progression of replication on UV light-damaged DNA in mouse embryonic fibroblasts that contain a defined deletion in the N-terminal BRCT domain of Rev1 or that are deficient for Rev1. We provide evidence that Rev1 plays a coordinating role in two modes of DNA damage bypass, i.e., an early and a late pathway. The cells carrying the deletion in the BRCT domain are deficient for the early pathway, reflecting a role of the BRCT domain of Rev1 in mutagenic translesion synthesis. Rev1-deficient cells display a defect in both modes of DNA damage bypass. Despite the persistent defect in the late replicational bypass of fork-blocking (6-4)pyrimidine-pyrimidone photoproducts, overall replication is not strongly affected by Rev1 deficiency. This results in almost completely replicated templates that contain gaps encompassing the photoproducts. These gaps are inducers of DNA damage signaling leading to an irreversible G 2 arrest. Our results corroborate a model in which Rev1-mediated DNA damage bypass at postreplicative gaps quenches irreversible DNA damage responses.Unrepaired DNA damage usually leads to an arrest of replicative polymerases. Nonetheless, prokaryotic and eukaryotic cells display progression of replication on damaged templates, allowing replication to be completed and averting replication fork collapse (12). Direct bypass of the fork-blocking lesion, permitting replication to proceed with little delay, would be an attractive mechanism to release an arrested replicon. Several early studies using bacteria and mammalian cells, however, have indicated that replicating cells exposed to UV light initially synthesize smaller DNA strands than undamaged cells (reviewed in reference 32). At a later stage, these molecules are converted into DNA of high molecular weight, possibly via late, postreplicative, filling of the lesion-containing gap by socalled postreplication repair. The presence of single-stranded gaps in both sister chromatids behind a replication fork was recently visualized by electron microscopy on DNA of UVexposed budding yeast Saccharomyces cerevisiae (34).Damage avoidance and translesion synthesis are two pathways that allow cells to replicate damaged templates (3, 12). Damage avoidance (also called template switching-dependent synthesis) uses the undamaged sister chromatid as a template. This can be achieved by replication fork regression or by strand invasion with the sister chromatid and results in error-free bypass of DNA lesions (7, 65). Translesion synthesis, on the other hand, is characterized by insertion of a nucleotide opposite the lesion by specialized DNA polymerases of the Y family (48). The reduced stringency of the active site and a lack of proofreading activity of translesion synthesis polymerases imply that translesion synthesis is an inherently mutagenic process.The Y family poly...
Rev1 is a deoxycytidyl transferase associated with DNA translesion synthesis (TLS). In addition to its catalytic domain, Rev1 possesses a so-called BRCA1 C-terminal (BRCT) domain. Here, we describe cells and mice containing a targeted deletion of this domain. Rev1B/B mice are healthy, fertile and display normal somatic hypermutation. Rev1B/B cells display an elevated spontaneous frequency of intragenic deletions at Hprt. In addition, these cells were sensitized to exogenous DNA damages. Ultraviolet-C (UV-C) light induced a delayed progression through late S and G2 phases of the cell cycle and many chromatid aberrations, specifically in a subset of mutant cells, but not enhanced sister chromatid exchanges (SCE). UV-C-induced mutagenesis was reduced and mutations at thymidine–thymidine dimers were absent in Rev1B/B cells, the opposite phenotype of UV-C-exposed cells from XP-V patients, lacking TLS polymerase η. This suggests that the enhanced UV-induced mutagenesis in XP-V patients may depend on error-prone Rev1-dependent TLS. Together, these data indicate a regulatory role of the Rev1 BRCT domain in TLS of a limited spectrum of endogenous and exogenous nucleotide damages during a defined phase of the cell cycle.
Alkylpurine-DNA-N-glycosylase (APNG) null mice have been generated by homologous recombination in embryonic stem cells. The null status of the animals was confirmed at the mRNA level by reverse transcription-PCR and by the inability of cell extracts of tissues from the knockout (ko) animals to release 3-methyladenine (3-meA) or 7-methylguanine (7-meG) from 3 H-methylated calf thymus DNA in vitro. Following treatment with DNA-methylating agents, increased persistence of 7-meG was found in liver sections of APNG ko mice in comparison with wild-type (wt) mice, demonstrating an in vivo phenotype for the APNG null animals. Unlike other null mutants of the base excision repair pathway, the APNG ko mice exhibit a very mild phenotype, show no outward abnormalities, are fertile, and have an apparently normal life span. Neither a difference in the number of leukocytes in peripheral blood nor a difference in the number of bone marrow polychromatic erythrocytes was found when ko and wt mice were exposed to methylating or chloroethylating agents. These agents also showed similar growth-inhibitory effects in primary embryonic fibroblasts isolated from ko and wt mice. However, treatment with methyl methanesulfonate resulted in three-to fourfold more hprt mutations in splenic T lymphocytes from APNG ko mice than in those from wt mice. These mutations were predominantly singlebase-pair changes; in the ko mice, they consisted primarily of AT3TA and GC3TA transversions, which most likely are caused by 3-meA and 3-or 7-meG, respectively. These results clearly show an important role for APNG in attenuating the mutagenic effects of N-alkylpurines in vivo.Alkylpurine-DNA-N-glycosylase (APNG) is one of a growing list of enzymes responsible for the recognition and excision of altered bases in the first step of the base excision repair pathway (49, 56). In the simplest form of base excision repair, the resulting abasic site is then repaired by the sequential action of an apurinic-apyrimidinic (AP) endonuclease that generates a single-strand break, the removal of the 5Ј-terminal deoxyribose phosphate residue, insertion of a single nucleotide by DNA polymerase , and finally ligation of the repaired patch by DNA ligase I or XRCC1-DNA ligase III (55, 56).Mammalian APNGs have been shown to be active against a wide range of modified bases in vitro, many structurally unrelated to 3-methyladenine (3-meA), the substrate after which the enzyme was first named (32). In particular, APNG appears to be the only glycosylase in mammalian cells that can release hypoxanthine from DNA, a promutagenic base resulting from the spontaneous deamination of adenine (22,47). Likewise, the highly mutagenic adduct 1,N 6 -ethenoadenine (41), which is produced by metabolic products of the environmental hepatocarcinogens vinyl chloride and ethyl carbamate, is released by APNG (22, 48); indeed, according to one report, the recombinant human enzyme reacted 10-to 20-fold more efficiently with this adduct than with 3-meA in an in vitro assay (14). These results, together ...
Möbius syndrome (MBS) is a neurological disorder that is characterized by paralysis of the facial nerves and variable other congenital anomalies. The aetiology of this syndrome has been enigmatic since the initial descriptions by von Graefe in 1880 and by Möbius in 1888, and it has been debated for decades whether MBS has a genetic or a non-genetic aetiology. Here, we report de novo mutations affecting two genes, PLXND1 and REV3L in MBS patients. PLXND1 and REV3L represent totally unrelated pathways involved in hindbrain development: neural migration and DNA translesion synthesis, essential for the replication of endogenously damaged DNA, respectively. Interestingly, analysis of Plxnd1 and Rev3l mutant mice shows that disruption of these separate pathways converge at the facial branchiomotor nucleus, affecting either motoneuron migration or proliferation. The finding that PLXND1 and REV3L mutations are responsible for a proportion of MBS patients suggests that de novo mutations in other genes might account for other MBS patients.
In this study the role of nucleotide excision repair (NER) in protecting mouse embryonic stem (ES) cells against the genotoxic effects of UV-photolesions was analysed. Repair of cyclobutane pyrimidine dimers (CPD) in transcribed genes could not be detected whereas the removal of (6-4) photoproducts (6-4PP) was incomplete, already reaching its maximum (30%) 4 h after irradiation. Measurements of repair replication revealed a saturation of NER activity at UV doses >5 J/m2 while at a lower dose (2.5 J/m2) the repair kinetics were similar to those in murine embryonic fibroblasts (MEFs). Cytotoxic and mutagenic effects of photolesions were determined in ES cells differing in NER activity. ERCC1-deficient ES cells were hypermutable (10-fold) compared to wild-type cells, indicating that at physiologically relevant doses ES cells efficiently remove photolesions. The effect of the NER deficiency on cytoxicity was only 2-fold. Exposure to high UV doses (10 J/m2) resulted in a rapid and massive induction of apoptosis. Possibly, to avoid the accumulation of mutated cells, ES cells rely on the induction of a strong apoptotic response with a simultaneous shutting down of NER activity.
The replication of damaged DNA templates by translesion synthesis (TLS) is associated with mutagenesis and carcinogenesis. This perspective discusses the different levels at which TLS may be controlled and proposes a model for TLS of severely helix-distorting DNA lesions that includes a decisive role for the Rad9-Hus1-Rad1 DNA-damage-signaling clamp. The dual involvement of this clamp in both DNA-damage signaling and TLS may have profound implications in determining cellular responses to DNA damage.
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