Coupling of Saccharomyces cerevisiae Early Meiotic Gene Expression to DNA Replication Depends Upon RPD3 and SIN3

Coupling of Saccharomyces cerevisiae Early Meiotic Gene Expression to DNA Replication Depends Upon RPD3 and SIN3

Teresa M. Lamb^a and Aaron P. Mitchell^a
^a Department of Microbiology and Institute of Cancer Research, Columbia University, New York, New York 10032

Corresponding author: Aaron P. Mitchell, Department of Microbiology, Columbia University, 701 W. 168th St., New York, NY 10032., apm4{at}columbia.edu (E-mail)

Communicating editor: J. RINE

It has been established that meiotic recombination and chromosomesegregation are inhibited when meiotic DNA replication is blocked.Here we demonstrate that early meiotic gene (EMG) expressionis also inhibited by a block in replication. Since early meioticgenes are required to promote meiotic recombination and DNAdivision, the low expression of these genes may contribute tothe block in meiotic progression. We have identified three Hur^-(HU reduced recombination) mutants that fail to couple meioticrecombination and gene expression with replication. One of thesemutations is in RPD3, a gene required to maintain meiotic generepression in mitotic cells. Complete deletions of RPD3 andthe repression adapter SIN3 permitted recombination and earlymeiotic gene expression when replication was inhibited withhydroxyurea (HU). Biochemical analysis showed that the Rpd3p-Sin3p-Ume6prepression complex does exist in meiotic cells. These observationssuggest that repression of early meiotic genes by SIN3 and RPD3is critical for the normal response to inhibited replication.A second response to inhibited replication has also been discovered.HU-inhibited replication reduced the accumulation of phospho-Ume6pin meiotic cells. Phosphorylation of Ume6p normally promotesinteraction with the meiotic activator Ime1p, thereby activatingEMG expression. Thus, inhibited replication may also reducethe Ume6p-dependent activation of EMGs. Taken together, ourdata suggest that both active repression and reduced activationcombine to inhibit EMG expression when replication is inhibited.

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