Summary: | DNA damage represents a major challenge to the faithful replication and transmission of genetic information from one generation to the next. Cells utilize a highly integrated network of pathways to detect and accurately repair DNA damage. Mutations arise when DNA damage persists undetected, unrepaired, or repaired improperly. Mutations are a driving force of carcinogenesis and therefore many of the DNA damage surveillance and repair mechanisms guard against the transformation of normal cells into cancer cells. Central to the detection and repair of DNA damage is the relocalization of DNA damage surveillance proteins to DNA damage where they assemble into subnuclear foci and are capable to producing a signal that the cell interprets to induce cellular modifications such as cycle arrest and DNA repair which are important DNA damage tolerance. In this work, I describe my quest to understand the mechanisms underlying the assembly, maintenance, and disassembly of these DNA damage-induced foci and how they affect DNA damage signaling in Saccharomyces cerevisiae. First, I describe phenotypic characterization of a novel mutation that impairs assembly of the 9-1-1 checkpoint clamp complex into foci. Second, I describe my work to further understand the roles of the histone phosphatase Pph3 and phosphorylated histone H2A in modulating DNA damage signaling. Third, I include my work to uncover the possible mechanism by which the helicase Srs2 works to enable termination of DNA damage signaling. In summary, this thesis documents my efforts to understand the cellular and molecular nature of DNA damage signaling and how signaling is turned off in coordination with DNA damage repair.
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