Dynamics of MutS–Mismatched DNA Complexes Are Predictive of Their Repair Phenotypes
Autor: | Dorothy A. Erie, Vanessa DeRocco, Ruoyi Qiu, Keith Weninger, Lauryn E. Sass |
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Rok vydání: | 2014 |
Předmět: |
congenital
hereditary and neonatal diseases and abnormalities DNA Repair Kinetics Mutant 7. Clean energy Biochemistry Article chemistry.chemical_compound Bacterial Proteins INDEL Mutation Predictive Value of Tests MutS-1 Fluorescence Resonance Energy Transfer Thermus Genetics Transition (genetics) Thermus aquaticus biology biology.organism_classification MutS DNA Mismatch-Binding Protein Phenotype Förster resonance energy transfer chemistry Biophysics DNA mismatch repair DNA Signal Transduction |
Zdroj: | Biochemistry |
ISSN: | 1520-4995 0006-2960 |
DOI: | 10.1021/bi401429b |
Popis: | MutS recognizes base-base mismatches and base insertions/deletions (IDLs) in newly replicated DNA. Specific interactions between MutS and these errors trigger a cascade of protein-protein interactions that ultimately lead to their repair. The inability to explain why different DNA errors are repaired with widely varying efficiencies in vivo remains an outstanding example of our limited knowledge of this process. Here, we present single-molecule Förster resonance energy transfer measurements of the DNA bending dynamics induced by Thermus aquaticus MutS and the E41A mutant of MutS, which is known to have error specific deficiencies in signaling repair. We compared three DNA mismatches/IDLs (T-bulge, GT, and CC) with repair efficiencies ranging from high to low. We identify three dominant DNA bending states [slightly bent/unbent (U), intermediately bent (I), and significantly bent (B)] and find that the kinetics of interconverting among states varies widely for different complexes. The increased stability of MutS-mismatch/IDL complexes is associated with stabilization of U and lowering of the B to U transition barrier. Destabilization of U is always accompanied by a destabilization of B, supporting the suggestion that B is a "required" precursor to U. Comparison of MutS and MutS-E41A dynamics on GT and the T-bulge suggests that hydrogen bonding to MutS facilitates the changes in base-base hydrogen bonding that are required to achieve the U state, which has been implicated in repair signaling. Taken together with repair propensities, our data suggest that the bending kinetics of MutS-mismatched DNA complexes may control the entry into functional pathways for downstream signaling of repair. |
Databáze: | OpenAIRE |
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