Genetic Dissection of Budding Yeast PCNA Mutations Responsible for the Regulated Recruitment of Srs2 Helicase.

DNA-damage tolerance (DDT) is a mechanism by which eukaryotes bypass replication-blocking lesions to resume DNA synthesis and maintain cell viability. In Saccharomyces cerevisiae, DDT is mediated by sequential ubiquitination and sumoylation of proliferating cell nuclear antigen (PCNA, encoded by ) at the K164 residue. Deletion of or , encoding two ubiquitin ligases required for PCNA ubiquitination, results in severe DNA-damage sensitivity, which can be rescued by inactivation of encoding a DNA helicase that inhibits undesired homologous recombination. In this study, we isolated DNA-damage resistant mutants from Δ cells and found that one of them contained a mutation, which could rescue both Δ and Δ DNA-damage sensitivity in a 2-dependent and PCNA sumoylation-independent manner. Pol30-A171D abolished physical interaction with Srs2 but not another PCNA-interacting protein Rad30; however, Pol30-A171 is not located in the PCNA-Srs2 interface. The PCNA-Srs2 structure was analyzed to design and create mutations in the complex interface, one of which, , resulted in phenotypes reminiscent of . This study allows us to conclude that, unlike other PCNA-binding proteins, Srs2 interacts with PCNA through a partially conserved motif, and the interaction can be strengthened by PCNA sumoylation, which turns Srs2 recruitment into a regulated process. It is known that budding yeast PCNA sumoylation serves as a ligand to recruit a DNA helicase Srs2 through its tandem receptor motifs that prevent unwanted homologous recombination (HR) at replication forks, a process known as salvage HR. This study reveals detailed molecular mechanisms, in which constitutive PCNA-PIP interaction has been adapted to a regulatory event. Since both PCNA and Srs2 are highly conserved in eukaryotes, from yeast to human, this study may shed light to investigation of similar regulatory mechanisms.