HO endonuclease-induced double-strand breaks in Saccharomyces cerevisiae can undergo recombination by two distinct and competing pathways. In a plasmid containing a direct repeat, in which one repeat is interrupted by an HO endonuclease cut site, gap repair yields gene conversions while single-strand annealing produces deletions. Consistent with predictions of the single-strand annealing mechanism, deletion formation is not accompanied by the formation of a reciprocal recombination product. Deletions are delayed 60 min when the distance separating the repeats is increased by 4.4 kb. Moreover, the rate of deletion formation corresponds to the time at which complementary regions become single stranded. Gap repair processes are independent of distance but are reduced in rad52 mutants and in Gl-arrested cells.In both mitotic and meiotic cells, double-strand breaks (DSBs) can initiate homologous recombination events. In the yeast Saccharomyces cerevisiae, this process has been characterized by analyzing the outcome of repair of DSBs induced by X rays, transformation of linear substrates into cells, and introduction of site-specific lesions in both mitotic and meiotic cells (1,18,36,37,44,54 1A) proposes that a DSB or gap is repaired by a gene conversion event involving the concerted participation of both broken ends, which invade and copy DNA from an intact, homologous donor copy. More recent considerations have prompted a modification of this model to include the creation of extensive single-stranded regions by 5'-to-3' exonucleolytic digestion of the DSB (55,63). This model predicts that gene conversion can occur both with and without an accompanying crossing over and that these two products occur with equal frequencies (Fig. 1A).Similar recombination events have been described for mammalian cells. Linearized DNA molecules can be used to effect site-directed gene replacement (13,27,50) and gap repair of transformed DNA (2). Recently, a system that carries out gap repair in vitro has been developed; however, some of the products obtained had not been predicted by a simple gap repair model (15). A number of studies of recombination in mammalian cells suggest that there is an alternative pathway of recombination, termed single-strand annealing (SSA, Fig. 1B) (3,6,(21)(22)(23)61). In this pathway (Fig. 1B), deletions are formed between sequences in direct orientation. A DSB produced between the directly repeated sequences is attacked by a 5'-to-3' exonuclease whose degradation produces complementary single strands which then anneal. This mechanism also accounts for products resembling gene conversions that have arisen by the interaction of several DNA molecules (22 (29)(30)(31).With yeast, the molecular events associated with recombinational repair of DSBs can be observed in vivo by physically monitoring DNA after the synchronous induction of a DSB. With mitotic cells, it has been possible to carry out a detailed analysis of DSB repair by using two highly efficient site-specific endonucleases: the HO endonuclease, whic...
