RESUMO
Meiotic homologous chromosomes synapse and undergo crossing over (CO). In many eukaryotes, both synapsis and crossing over require the induction of double stranded breaks (DSBs) and subsequent repair via homologous recombination. In these organisms, two key proteins are recombinases RAD51 and DMC1. Recombinase-modulators HOP2 and MND1 assist RAD51 and DMC1 and also are required for synapsis and CO. We have investigated the hop2-1 phenotype in Arabidopsis during the segregation stages of both meiosis and mitosis. Despite a general lack of synapsis during prophase I, we observed extensive, stable interconnections between nonhomologous chromosomes in diploid hop2-1 nuclei in first and second meiotic divisions. Using γH2Ax as a marker of unrepaired DSBs, we detected γH2AX foci from leptotene through early pachytene but saw no foci from mid-pachytene onward. We conclude that the bridges seen from metaphase I onward are due to mis-repaired DSBs, not unrepaired ones. Examining haploids, we found that wild type haploids produce only univalents, but hop2-1 haploids like hop2-1 diploids have illegitimate connections stable enough to produce bridged chromosomes during segregation. Our results suggest that HOP2 has a significant active role in preventing repairs that use nonhomologous chromosomes during meiosis. We also found evidence that HOP2 plays a role in preventing illegitimate repair of radiation-induced DSBs in rapidly dividing petal cells. We conclude that HOP2 in Arabidopsis plays both a positive role in promoting synapsis and a separable role in preventing DSB repair using nonhomologous chromosomes. SIGNIFICANCE STATEMENT : The fidelity of homologous recombination (HR) during meiosis is essential to the production of viable gametes and for maintaining genome integrity in vegetative cells. HOP2 is an important protein for accurate meiotic HR in plants. We have found evidence of high levels of illegitimate repairs between nonhomologous chromosomes during meiosis and in irradiated petal cells in hop2-1 mutants, suggesting a role for HOP2 beyond its established role in synapsis and crossing over.