Eukaryotic cells repair DNA double-strand breaks (DSBs) by at least two pathways, homologous recombination (HR) and non-homologous end-joining (NHEJ).Rad54 participates in the first recombinational repair pathway while Ku proteins are involved in NHEJ. To investigate the distinctive as well as redundant roles of these two repair pathways, we analyzed the mutants RAD54 -/-, KU70 -/-and RAD54 -/-/KU70 -/-, generated from the chicken B-cell line DT40. We found that the NHEJ pathway plays a dominant role in repairing γ-radiation-induced DSBs during G 1 -early S phase while recombinational repair is preferentially used in late S-G 2 phase. RAD54 -/-/KU70 -/-cells were profoundly more sensitive to γ-rays than either single mutant, indicating that the two repair pathways are complementary. Spontaneous chromosomal aberrations and cell death were observed in both RAD54 -/-and RAD54 -/-/KU70 -/-cells, with RAD54 -/-/KU70 -/-cells exhibiting significantly higher levels of chromosomal aberrations than RAD54 -/-cells. These observations provide the first genetic evidence that both repair pathways play a role in maintaining chromosomal DNA during the cell cycle.
Yeast rad51 mutants are viable, but extremely sensitive to γ-rays due to defective repair of double-strand breaks. In contrast, disruption of the murine RAD51 homologue is lethal, indicating an essential role of Rad51 in vertebrate cells. We generated clones of the chicken B lymphocyte line DT40 carrying a human RAD51 transgene under the control of a repressible promoter and subsequently disrupted the endogenous RAD51 loci. Upon inhibition of the RAD51 transgene, Rad51 -cells accumulated in the G 2 /M phase of the cell cycle before dying. Chromosome analysis revealed that most metaphase-arrested Rad51 -cells carried isochromatid-type breaks. In conclusion, Rad51 fulfils an essential role in the repair of spontaneously occurring chromosome breaks in proliferating cells of higher eukaryotes.
The Rad51 protein, a eukaryotic homologue of Escherichia coli RecA, plays a central role in both mitotic and meiotic homologous DNA recombination (HR) in Saccharomyces cerevisiae and is essential for the proliferation of vertebrate cells. Five vertebrate genes, RAD51B, -C, and -D and XRCC2 and -3, are implicated in HR on the basis of their sequence similarity to Rad51 (Rad51 paralogs). We generated mutants deficient in each of these proteins in the chicken B-lymphocyte DT40 cell line and report here the comparison of four new mutants and their complemented derivatives with our previously reported rad51b mutant. The Rad51 paralog mutations all impair HR, as measured by targeted integration and sister chromatid exchange. Remarkably, the mutant cell lines all exhibit very similar phenotypes: spontaneous chromosomal aberrations, high sensitivity to killing by cross-linking agents (mitomycin C and cisplatin), mild sensitivity to gamma rays, and significantly attenuated Rad51 focus formation during recombinational repair after exposure to gamma rays. Moreover, all mutants show partial correction of resistance to DNA damage by overexpression of human Rad51. We conclude that the Rad51 paralogs participate in repair as a functional unit that facilitates the action of Rad51 in HR.Double-strand DNA breaks (DSBs) are produced by ionizing radiation (IR) and certain chemicals, and they likely occur frequently during DNA replication (21, 34). A single unrepaired DSB may stimulate cell cycle checkpoints and cause cell death (3, 25). Homologous recombination (HR) has emerged as a major DSB repair pathway in mammalian cells (29,35,44,65,66), as well as in the yeast Saccharomyces cerevisiae. Indeed, the analysis of radiosensitive yeast mutants has revealed a number of key genes involved in HR, which comprise the RAD52 epistasis group (2,32,54), and the HR pathway is conserved from yeast to humans (4,18,53,65). Although yeast is capable of proliferating at a reduced rate in the absence of functional HR, this repair pathway is essential for viability in cycling vertebrate cells for coping with DNA lesions arising during DNA replication (55,56,67,73). This species difference is probably due to the several-hundred-fold difference in genome size between vertebrates and yeast.ScRad51 is closely related to the Escherichia coli recombination protein RecA (5). Among the proteins of the Rad52 epistasis group, Rad51 has the highest degree of structural and functional conservation among all eukaryotes. The high degree of identity of ScRad51 with the human homolog (59% identity) and chicken homolog (59% identity) suggests that Rad51's function is conserved across eukaryotes. A central role for Rad51 in HR in vertebrates is supported by the finding that Rad51 deficiency (36, 55, 67), but not Rad52 or Rad54 deficiency, is lethal to cells (4,18,49,72). In vitro studies show that RecA and Rad51 form multimeric helical nucleoprotein filaments that are assembled on single-stranded DNA (ssDNA) (2). Recent work suggests that the preferred DNA substrat...
Sister chromatid exchange (SCE) frequency is a commonly used index of chromosomal stability in response to environmental or genetic mutagens. However, the mechanism generating cytologically detectable SCEs and, therefore, their prognostic value for chromosomal stability in mitotic cells remain unclear. We examined the role of the highly conserved homologous recombination (HR) pathway in SCE by measuring SCE levels in HR-defective vertebrate cells. Spontaneous and mitomycin C-induced SCE levels were significantly reduced for chicken DT40 B cells lacking the key HR genes RAD51 and RAD54 but not for nonhomologous DNA end-joining (NHEJ)-defective KU70 ؊/؊ cells. As measured by targeted integration efficiency, reconstitution of HR activity by expression of a human RAD51 transgene restored SCE levels to normal, confirming that HR is the mechanism responsible for SCE. Our findings show that HR uses the nascent sister chromatid to repair potentially lethal DNA lesions accompanying replication, which might explain the lethality or tumorigenic potential associated with defects in HR or HR-associated proteins.Symmetrical exchanges between newly replicated chromatids and their sisters can be visualized cytologically in vertebrate cells if the DNA of one chromatid is labelled with 5-bromodeoxyuridine (BUdR) during synthesis. Sister chromatid exchanges (SCEs) can be induced by various genotoxic treatments (10), suggesting that SCEs reflect a DNA repair process. Cytological assessment of SCE levels in peripheral blood lymphocytes is used as an index of the mutagenic potential of environmental factors. More importantly, ϳ10 SCEs occur spontaneously in normally cycling human cells (5, 8), suggesting a link between SCE and DNA replication. Elevated spontaneous SCE levels are observed in cells from Bloom syndrome patients (9), in mouse cells that lack poly(ADP-ribose) polymerase (29) or KU70 (15), and in hamster cells with defects in XRCC1 (28), but the causal relationships between these enzymes and SCE are not clear.While the phenomenon of SCE has long been established (27) and many observations about the induction of SCEs have been made, their molecular basis remains obscure. SCE is intimately associated with DNA replication, and eukaryotic cells exposed to DNA-damaging agents in G 2 show elevated SCE levels only after completing a subsequent replication cycle (32). Homologous recombination (HR) was suggested as one of the mechanisms responsible (13,14). While HR occurs between sister chromatids in yeast as a means to replicate around UV-induced lesions (12), it has not been considered constitutively active during metazoan mitosis, perhaps because of the predominance of the nonhomologous DNA end-joining (NHEJ) pathway (30). In addition, the lack of recombinational repair mutants precluded direct testing of HR's involvement in SCE, so other models evolved. It was proposed that SCEs result from strand switching at stalled replication forks (20). Another model involved topoisomerase II action at coincident breaks at replication for...
Yeast Mre11 functions with Rad50 and Xrs2 in a complex that has pivotal roles in homologous recombination (HR) and non-homologous end-joining (NHEJ) DNA double-strand break (DSB) repair pathways. Vertebrate Mre11 is essential. Conditionally, MRE11 null chicken DT40 cells accumulate chromosome breaks and die upon Mre11 repression, showing frequent centrosome amplification. Mre11 deficiency also causes increased radiosensitivity and strongly reduced targeted integration frequencies. Mre11 is, therefore, crucial for HR and essential in mitosis through its role in chromosome maintenance by recombinational repair. Surprisingly perhaps, given the role of Mre11 in yeast NHEJ, disruption of NHEJ by deletion of KU70 greatly exacerbates the effects of MRE11 deficiency, revealing a significant Mre11-independent component of metazoan NHEJ.
The highly conserved Saccharomyces cerevisiae Rad51 protein plays a central role in both mitotic and meiotic homologous DNA recombination. Seven members of the Rad51 family have been identified in vertebrate cells, including Rad51, Dmc1, and five Rad51-related proteins referred to as Rad51 paralogs, which share 20 to 30% sequence identity with Rad51. In chicken B lymphocyte DT40 cells, we generated a mutant with RAD51B/ RAD51L1, a member of the Rad51 family, knocked out. RAD51B؊/؊ cells are viable, although spontaneous chromosomal aberrations kill about 20% of the cells in each cell cycle. Rad51B deficiency impairs homologous recombinational repair (HRR), as measured by targeted integration, sister chromatid exchange, and intragenic recombination at the immunoglobulin locus. RAD51B؊/؊ cells are quite sensitive to the cross-linking agents cisplatin and mitomycin C and mildly sensitive to ␥-rays. The formation of damage-induced Rad51 nuclear foci is much reduced in RAD51B ؊/؊ cells, suggesting that Rad51B promotes the assembly of Rad51 nucleoprotein filaments during HRR. These findings show that Rad51B is important for repairing various types of DNA lesions and maintaining chromosome integrity. Double-strand DNA breaks (DSBs) occur during DNA replication and are produced by ionizing radiation. Since DSBs are so deleterious to the cell, it is not surprising that there are two DSB repair pathways: nonhomologous end joining (NHEJ) and homologous recombination repair (HRR). Repair of DSBs by HRR requires the presence of homologous duplex DNA elsewhere in the genome, i.e., either a homologous chromosome or, more likely, a sister chromatid. NHEJ simply acts to process and ligate broken ends without a requirement for extensive homology. These pathways are conserved from the yeast Saccharomyces cerevisiae to humans (5,8,9,19,49,53,64). While HRR is the primary mechanism of DSB repair in yeast, vertebrate cells use both the NHEJ and HRR pathways extensively (28,34,35,44). The analysis of radiosensitive yeast mutants has revealed a number of genes involved in HRR, which comprise the RAD52 epistasis group (reviewed in references 4, 29, and 51).Among the members of the RAD52 epistasis group, the structure and function of Rad51 have been conserved to a remarkable degree among all eukaryotes. Rad51 is structurally and functionally related to the Escherichia coli recombination protein RecA (reviewed in reference 32). The functional forms of both RecA and Rad51 are multimeric helical nucleoprotein filaments that form on single-stranded DNA ends produced at DSBs (41). These filaments are involved in the search for homologous sequence, DNA pairing, and strand exchange. Recombination intermediates produced in this way are then processed further in reactions that involve DNA synthesis, branch migration, resolution of Holliday junctions, and ligation (reviewed in reference 4). The conservation of the RAD52 epistasis group genes from yeast to vertebrate cells suggests that the basic mechanism of HRR is maintained during evolution. Howe...
Prevalence and Spectrum of Germline Mutations of the p53 Gene among Patients with Sarcoma
New germline mutations of the p53 gene are rare among patients with "sporadic" sarcoma but may be common in patients with sarcoma whose background includes either multiple primary cancers or a family history of cancer. Diverse mutations of this gene were associated with an increased likelihood of cancer; hence, the entire gene should be considered a target for heritable mutation. It appears that the group of patients with cancer who carry germline mutations of the p53 gene is more diverse than is suggested by the clinical definition of the Li-Fraumeni syndrome. The identification of carriers could be of substantial clinical importance.
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