A Molecular Genetic Dissection of the Evolutionarily Conserved N Terminus of Yeast Rad52

A Molecular Genetic Dissection of the Evolutionarily Conserved N Terminus of Yeast Rad52

Uffe H. Mortensen^a, Naz Erdeniz^a, Qi Feng^a, and Rodney Rothstein^a
^a Department of Genetics and Development, College of Physicians and Surgeons, Columbia University, New York, New York 10032-2704

Corresponding author: Rodney Rothstein, College of Physicians and Surgeons, Columbia University, 701 W. 168th St., New York, NY 10032-2704., rothstein{at}cancercenter.columbia.edu (E-mail)

Communicating editor: M. LICHTEN

Rad52 is a DNA-binding protein that stimulates the annealingof complementary single-stranded DNA. Only the N terminus ofRad52 is evolutionarily conserved; it contains the core activityof the protein, including its DNA-binding activity. To identifyamino acid residues that are important for Rad52 function(s),we systematically replaced 76 of 165 amino acid residues inthe N terminus with alanine. These substitutions were examinedfor their effects on the repair of ${gamma}$ -ray-induced DNA damage andon both interchromosomal and direct repeat heteroallelic recombination.This analysis identified five regions that are required forefficient ${gamma}$ -ray damage repair or mitotic recombination. Two regions,I and II, also contain the classic mutations, rad52-2 and rad52-1,respectively. Interestingly, four of the five regions containmutations that impair the ability to repair ${gamma}$ -ray-induced DNAdamage yet still allow mitotic recombinants to be produced atrates that are similar to or higher than those obtained withwild-type strains. In addition, a new class of separation-of-functionmutation that is only partially deficient in the repair of ${gamma}$ -raydamage, but exhibits decreased mitotic recombination similarto rad52 null strains, was identified. These results suggestthat Rad52 protein acts differently on lesions that occur spontaneouslyduring the cell cycle than on those induced by ${gamma}$ -irradiation.

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