Chimeric nucleases that are hybrids between a nonspecific DNA cleavage domain and a zinc finger DNA recognition domain were tested for their ability to find and cleave their target sites in living cells. Both engineered DNA substrates and the nucleases were injected into Xenopus laevis oocyte nuclei, in which DNA cleavage and subsequent homologous recombination were observed. Specific cleavage required two inverted copies of the zinc finger recognition site in close proximity, reflecting the need for dimerization of the cleavage domain. Cleaved DNA molecules were activated for homologous recombination; in optimum conditions, essentially 100% of the substrate recombined, even though the DNA was assembled into chromatin. The original nuclease has an 18-amino-acid linker between the zinc finger and cleavage domains, and this enzyme cleaved in oocytes at paired sites separated by spacers in the range of 6 to 18 bp, with a rather sharp optimum at 8 bp. By shortening the linker, we found that the range of effective site separations could be narrowed significantly. With no intentional linker between the binding and cleavage domains, only binding sites exactly 6 bp apart supported efficient cleavage in oocytes. We also showed that two chimeric enzymes with different binding specificities could collaborate to stimulate recombination when their individual sites were appropriately placed. Because the recognition specificity of zinc fingers can be altered experimentally, this approach holds great promise for inducing targeted recombination in a variety of organisms.Procedures and reagents that allow the directed alteration of genes in situ constitute a powerful toolbox for experimental genetics and potentially for agricultural and therapeutic applications. In many organisms, however, and particularly in higher eukaryotes, the efficiency of recombination between an introduced DNA and the homologous chromosomal target is discouragingly low. For example, such events typically occur in mammalian cells at a frequency of only about 1 for each 10 6 cells treated (3, 31). We are interested in developing procedures that would substantially improve the frequency of gene targeting.A major impediment to efficient gene replacement is the status of the chromosomal target. Increasing the number of target sequences has little or no effect on targeting efficiency (54, 60). In contrast, making an intentional double-strand break (DSB) in the target DNA increases the yield of specific homologous recombination events up to 1,000-fold or more (10,11,14,44,46). It is believed that exonucleases act at broken ends to generate single-stranded tails that are recombinagenic in any of several pathways. In particular, the singlestrand annealing mechanism (33), by which homologous recombination involving exogenous DNA usually occurs in higher eukaryotes (53), cannot proceed unless both the donor and target have ends (5, 48).Whatever the mechanism of recombination, it is clear that the frequency of targeted recombination can be substantially improved by i...
