Analysis of Conditional Mutations in the Saccharomyces cerevisiae MLH1 Gene in Mismatch Repair and in Meiotic Crossing Over

Analysis of Conditional Mutations in the Saccharomyces cerevisiae MLH1 Gene in Mismatch Repair and in Meiotic Crossing Over

Juan Lucas Argueso^a, Daniel Smith^a, James Yi^a, Marc Waase^a, Sumeet Sarin^a, and Eric Alani^a
^a Department of Molecular Biology and Genetics, Cornell University, Ithaca, New York 14853-2703

Corresponding author: Eric Alani, Cornell University, 459 Biotechnology Bldg., Ithaca, NY 14853-2703., eea3{at}cornell.edu (E-mail)

Communicating editor: L. S. SYMINGTON

In mismatch repair (MMR), members of the MLH gene family havebeen proposed to act as key molecular matchmakers to coordinatemismatch recognition with downstream repair functions that resultin mispair excision. Two members of this gene family, MLH1 andMLH3, have also been implicated in meiotic crossing over. Thesediverse roles suggest that a mutational analysis of MLH genescould provide reagents required to identify interactions betweengene products and to test whether the different roles ascribedto a subset of these genes can be separated. In this reportwe show that in Saccharomyces cerevisiae the mlh1 ${Delta}$ mutation confersinviability in pol3-01 strain backgrounds that are defectivein the Pol ${delta}$ proofreading exonuclease activity. This phenotypewas exploited to identify four mlh1 alleles that each confera temperature-sensitive phenotype for viability in pol3-01 strains.In three different mutator assays, strains bearing conditionalmlh1 alleles displayed wild-type or nearly wild-type mutationrates at 26°. At 35°, these strains exhibited mutationrates that approached those observed in mlh1 ${Delta}$ mutants. The mutatorphenotype exhibited in mlh1-I296S strains was partially suppressedat 35° by EXO1 overexpression. The mlh1-F228S and -I296Smutations conferred a separation-of-function phenotype in meiosis;both mlh1-F228S and -I296S strains displayed strong defectsin meiotic mismatch repair but showed nearly wild-type levelsof crossing over, suggesting that the conditional mutationsdifferentially affected MLH1 functions. These genetic studiessuggest that the conditional mlh1 mutations can be used to separatethe MMR and meiotic crossing-over functions of MLH1 and to identifyinteractions between MLH1 and downstream repair components.

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