A role for Xrcc2 in the early stages of mouse development.

Xrcc2 is one of a family of five Rad51-like genes with important roles in the repair of DNA damage by homologous recombination (HR) in mammals. We have shown previously that loss of Xrcc2 in mice results in severe but variable developmental defects and embryonic lethality, potentially linked to excessive apoptosis. To look at the causes of lethality, and possibly to allow Xrcc2-/- mice to survive to birth, we have produced double knockout mice deficient in either the p53 oncoprotein or Ataxia telangiectasia mutated (Atm). Overall we show that the excessive apoptosis observed in Xrcc2-/- embryos is p53-dependent, and that loss of p53 can restore growth capacity to Xrcc2-/- fibroblasts in culture, but that it cannot rescue the embryonic lethality. Additionally, although the Xrcc2-/- Trp53-/- embryos show a near-normal morphology they remain relatively small in size. Loss of Atm in an Xrcc2-/- embryo has little effect, suggesting that response to loss of HR capacity is not mediated through the Atm kinase in the early stages of mouse development. Further, as seen by reduced expression of the early developmental marker, Delta-like1, the normal developmental programme is perturbed in Xrcc2-/- embryonic tissues, particularly during neurogenesis and somitogenesis. Taken together our data suggest that the accumulation of spontaneous damage in HR-deficient embryos has severe consequences for the development and survival of mammals due to the unregulated loss of cells important to the developmental programme.

The involvement of key DNA repair pathways in the formation of chromosome rearrangements in embryonic stem cells.

It is vital that embryonic stem (ES) cells, which give rise to the diverse tissues of the mature organism, maintain genetic stability. To understand mechanisms for the prevention and causation of chromosomal instability, we have used spectral karyotyping (SKY) to analyse ES cells from wild-type and repair-gene knockout mice. We chose cells deficient in Ku70 (DNA end joining), Xrcc2 (gene conversion), Ercc1 (single-strand annealing) and Csb (transcription-coupled repair) to represent potentially-important DNA repair pathways, plus an Xpc-deficient line to examine loss of global nucleotide excision repair (NER). Spontaneous and radiation (X-ray or alpha-particle)-induced chromosome changes were assessed to measure the influence of different levels of damage severity on response. We show that most repair pathways (except for global NER) protect against chromosome changes induced by ionizing radiations, while only homology-dependent pathways protect against spontaneous chromosomal change in ES cells. However, for a given level of damage, the prevalence of different types of changes alters in the different repair-deficient lines. Thus, loss of Ercc1, Csb or Ku70 leads to increased fragment formation, but loss of Xrcc2 promotes exchanges between chromosomes. Strikingly, we found that loss of the Csb gene function specifically protects ES cells from complex exchanges, suggesting a role for transcription-associated events in complex exchange formation.

Homologous recombination deficiency leads to profound genetic instability in cells derived from Xrcc2-knockout mice.

DNA damage such as double-strand breaks presents severe difficulties for the cell to repair, especially if genetic stability is to be preserved. Recombination of the damaged DNA molecule with an undamaged homologous sequence provides a potential mechanism for the high-fidelity repair of such damage, and genes encoding homologous recombination (HR) proteins have been identified in mammalian cells. Xrcc2 is a protein with homology to Rad51, the core component of HR, but with a nonredundant role in damage repair. Here, we make the first study of the consequences of knocking out one or both copies of the Xrcc2 gene in mouse cells. In addition to growth arrest and sensitivity to agents causing severe DNA damage, we show that order-of-magnitude higher levels of chromosomal alterations are sustained in primary or immortal Xrcc2(-/-) embryonic fibroblasts. Using spectral karyotyping, we find that aneuploidy and complex chromosome exchanges, including an unexpectedly high frequency of homologue exchanges, are hallmarks of Xrcc2 deficiency. In addition, we find evidence for mild haploinsufficiency of Xrcc2. These responses are linked to several indicators of reduced HR in Xrcc2(-/-) cells, including a 30-fold reduction in gene conversion and reduced levels of Rad51-focus formation and of sister-chromatid exchange. Our data have similarities to recent studies of the disruption of breast cancer-predisposing (Brca) genes in mouse cells and are contrasted to analyses of cells carrying disruptions of genes in the other main pathway for double-strand break repair, nonhomologous end joining.

Pathway utilization in response to a site-specific DNA double-strand break in fission yeast.

We have examined the genetic requirements for efficient repair of a site-specific DNA double-strand break (DSB) in Schizosaccharomyces pombe. Tech nology was developed in which a unique DSB could be generated in a non-essential minichromosome, Ch(16), using the Saccharomyces cerevisiae HO-endonuclease and its target site, MATa. DSB repair in this context was predominantly through interchromosomal gene conversion. We found that the homologous recombination (HR) genes rhp51(+), rad22A(+), rad32(+) and the nucleotide excision repair gene rad16(+) were required for efficient interchromosomal gene conversion. Further, DSB-induced cell cycle delay and efficient HR required the DNA integrity checkpoint gene rad3(+). Rhp55 was required for interchromosomal gene conversion; however, an alternative DSB repair mechanism was used in an rhp55Delta background involving ku70(+) and rhp51(+). Surprisingly, DSB-induced minichromosome loss was significantly reduced in ku70Delta and lig4Delta non-homologous end joining (NHEJ) mutant backgrounds compared with wild type. Furthermore, roles for Ku70 and Lig4 were identified in suppressing DSB-induced chromosomal rearrangements associated with gene conversion. These findings are consistent with both competitive and cooperative interactions between components of the HR and NHEJ pathways.