Analysis of spontaneous gene conversion tracts within and between mammalian chromosomes.

In the present study, we report the first characterization of gene conversion tract length, continuity and fidelity for pathways of gene targeting, ectopic and intrachromosomal homologous recombination using the same locus and mammalian somatic cell type. In this isogenic cell system, the vast majority of recombinants (>97%) are generated by homologous recombination and display a high degree of fidelity in the gene conversion process. Individual gene conversion tracts are highly likely to involve single, independent recombination events and proceed through a heteroduplex DNA intermediate. In all recombination pathways, gene conversion tracts are long, extending up to approximately 2 kb. Most gene conversion tracts are continuous in favor of donor region sequences, but in a small fraction of recombinants (15%), discontinuous gene conversion tracts are observed. In most cases, the recombination donor sequence is unaltered, although in two cases of intrachromosomal recombination, both recombination donor and recipient sequences bear gene conversion tracts. Overall, gene conversion events are similar, both qualitatively and quantitatively, for homologous recombination within and between mammalian chromosomes.

Altered DNA repair and recombination responses in mouse cells expressing wildtype or mutant forms of RAD51.

Rad51, a homolog of Esherichia coli RecA, is a DNA-dependent ATPase that binds cooperatively to single-stranded DNA forming a nucleoprotein filament, which functions in the strand invasion step of homologous recombination. In this study, we examined DNA repair and recombination responses in mouse hybridoma cells stably expressing wildtype Rad51, or Walker box lysine variants, Rad51-K133A or Rad51-K133R, deficient in ATP binding and ATP hydrolysis, respectively. A unique feature is the recovery of stable transformants expressing Rad51-K133A. Augmentation of the endogenous pool of Rad51 by over-expression of transgene-encoded wildtype Rad51 enhances cell growth and gene targeting, but has minimal effects on cell survival to DNA damage induced by ionizing radiation (IR) or mitomycin C (MMC). Whereas expression of Rad51-K133A impedes growth, in general, neither Rad51-K133A nor Rad51-K133R significantly affected survival to IR- or MMC-induced damage, but did significantly reduce gene targeting. Expression of wildtype Rad51, Rad51-K133A or Rad51-K133R did not affect the frequency of intrachromosomal homologous recombination. However, in both gene targeting and intrachromosomal homologous recombination, wildtype and mutant Rad51 transgene expression altered the recombination mechanism: in gene targeting, wildtype Rad51 expression stimulates crossing over, while expression of Rad51-K133A or Rad51-K133R perturbs gene conversion; in intrachromosomal homologous recombination, cell lines expressing wildtype Rad51, Rad51-K133A or Rad51-K133R display increased deletion formation by intrachromosomal homologous recombination. The results suggest that ATP hydrolysis by Rad51 is more important for some homologous recombination functions than it is for other aspects of DNA repair.

Gene repeat expansion and contraction by spontaneous intrachromosomal homologous recombination in mammalian cells.

Homologous recombination (HR) is important in repairing errors of replication and other forms of DNA damage. In mammalian cells, potential templates include the homologous chromosome, and after DNA replication, the sister chromatid. Previous work has shown that the mammalian recombination machinery is organized to suppress interchromosomal recombination while preserving intrachromosomal HR. In the present study, we investigated spontaneous intrachromosomal HR in mouse hybridoma cell lines in which variously numbered tandem repeats of the mu heavy chain constant (C mu) region reside at the haploid, chromosomal immunoglobulin mu heavy chain locus. This organization provides the opportunity to investigate recombination between homologous gene repeats in a well-defined chromosomal locus under conditions in which recombinants are conveniently recovered. This system revealed several features about the mammalian intrachromosomal HR process: (i) the frequency of HR was high (recombinants represented as much as several percent of the total of recombinants and non-recombinants); (ii) the recombination process appeared to be predominantly non-reciprocal, consistent with the possibility of gene conversion; (iii) putative gene conversion tracts were long (up to 13.4 kb); (iv) the recombination process occurred with precision, initiating and terminating within regions of shared homology. The results are discussed with respect to mammalian intrachromosomal HR involving interactions both within and between sister chromatids.