Relationship of DNA double-strand breaks to synapsis in Drosophila

doi:10.1242/jcs.00614

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JCS ePress online publication date 10 Jun 2003
doi: 10.1242/jcs.00614

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Research Article

Relationship of DNA double-strand breaks to synapsis in Drosophila

Janet K. Jang, Dalia E. Sherizen, Rajal Bhagat, Elizabeth A. Manheim, and Kim S. McKim^*
^* Author for correspondence (e-mail: mckim{at}rci.rutgers.edu)

The relationship between synaptonemal complex formation (synapsis)and double-strand break formation (recombination initiation)differs between organisms. Although double-strand break creationis required for normal synapsis in Saccharomyces cerevisiaeand the mouse, it is not necessary for synapsis in Drosophilaand Caenorhabditis elegans. To investigate the timing of andrequirements for double-strand break formation during Drosophilameiosis, we used an antibody that recognizes a histone modificationat double-strand break sites, phosphorylation of HIS2AV ( ${gamma}$ -HIS2AV).Our results support the hypothesis that double-strand breakformation occurs after synapsis. Interestingly, we detecteda low (10-25% of wildtype) number of ${gamma}$ -HIS2AV foci in c(3)G mutants,which fail to assemble synaptonemal complex, suggesting thatthere may be both synaptonemal complex-dependent and synaptonemalcomplex-independent mechanisms for generating double-strandbreaks. Furthermore, mutations in Drosophila Rad54 (okr) andRad51 (spnB) homologs cause delayed and prolonged ${gamma}$ -HIS2AV staining,suggesting that double-strand break repair is delayed but noteliminated in these mutants. There may also be an interactionbetween the recruitment of repair proteins and phosphorylation.

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