Investigating the Link Between Mutations in MutS DNA Repair Protein and Lynch Cancer Syndrome

Abstract

The Mismatch Repair (MMR) pathway is responsible for correcting errors in DNA and is thus essential for maintaining genome stability in all living organisms. Several studies have shown that mutations causing defects in MMR protein structure and function lead to hypermutation. The increased level of mutations results in serious consequences for human health, highlighted by Lynch Syndrome (LS), a hereditary predisposition to colorectal and other cancers (1). The first protein in the MMR pathway, MutS, recognizes mispaired bases or short insertion‐deletion loops (IDLs) and utilizes its ATPase activity to initiate DNA repair (2). A long‐term study in the Hingorani laboratory examines cancer‐linked single amino acid mutants of the human MutS protein (using Thermus aquaticus MutS as a model system) in order to understand how the changes affect protein structure and function, and alter MMR. This work involves kinetic analysis of MutS activities, and related dynamic conformational changes in the protein as it utilizes ATP to work on DNA. The results will enable construction of a complete mechanism of action for each mutant protein, and help us determine whether the mutants are compromised in their ability to target mismatches, and/or bind and hydrolyze ATP, and/or undergo necessary conformational changes, and therefore understand why they disrupt DNA mismatch repair and give rise to Lynch Syndrome. My project focuses on fluorescence‐based stopped flow kinetic experiments to monitor the conformational changes of wild type MutS and several LS‐linked mutants as they bind +T insertion‐containing DNA and catalyze ATP hydrolysis. In addition to generating new information on each mutant, the findings will advance the proof‐of‐principle concept that detailed analysis of the structure, dynamics, and catalytic activities of individual MutS mutants is both feasible and can reveal critical information for understanding the molecular basis of Lynch Syndrome.Support or Funding InformationNational Institutes of Health R15 GM114743; The Beckman Scholars Program, Arnold and Mabel Beckman FoundationThis abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.