Investigation of the Stability of Yeast rad52 Mutant Proteins Uncovers Post-translational and Transcriptional Regulation of Rad52p

Investigation of the Stability of Yeast rad52 Mutant Proteins Uncovers Post-translational and Transcriptional Regulation of Rad52p

Erin N. Asleson^a and Dennis M. Livingston^a
^a Department of Biochemistry, Molecular Biology and Biophysics, University of Minnesota, Minneapolis, Minnesota 55455

Corresponding author: Dennis M. Livingston, University of Minnesota, 6-155 Jackson Hall, 321 Church St. SE, Minneapolis, MN 55455., livin001{at}umn.edu (E-mail)

Communicating editor: A. NICOLAS

We investigated the stability of the Saccharomyces cerevisiaeRad52 protein to learn how a cell controls its quantity andlongevity. We measured the cellular levels of wild-type andmutant forms of Rad52p when expressed from the RAD52 promoterand the half-lives of the various forms of Rad52p when expressedfrom the GAL1 promoter. The wild-type protein has a half-lifeof 15 min. rad52 mutations variably affect the cellular levelsof the protein products, and these levels correlate with themeasured half-lives. While missense mutations in the N terminusof the protein drastically reduce the cellular levels of themutant proteins, two mutations—one a deletion of aminoacids 210–327 and the other a missense mutation of residue235—increase the cellular level and half-life more thantwofold. These results suggest that Rad52p is subject to post-translationalregulation. Proteasomal mutations have no effect on Rad52p half-lifebut increase the amount of RAD52 message. In contrast to Rad52p,the half-life of Rad51p is >2 hr, and RAD51 expression is unaffectedby proteasomal mutations. These differences between Rad52p andRad51p suggest differential regulation of two proteins thatinteract in recombinational repair.

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