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Program Project in Structural Cell Biology of DNA Repair Machines: Project 5: DNA MisMatch Repair (MMR)
Performance Sites
Department of Biochemistry
Duke University Medical Center
Durham, North Carolina 27710
Ludwig Institute for Cancer Research
UC San Diego School of Medicine
La Jolla, CA 92093-0660
Key Personnel
| Name | Organization | Role on Project |
|---|
|
Paul L. Modrich
| Duke University Medical Center | Project Leader/Senior Scientist |
|
Lorena S. Beese
| Duke University Medical Center | Senior Investigator |
|
Richard D. Kolodner
| UC San Diego School of Medicine | Senior Investigator |
Links to web sites:
SBDR Project 5 Abstract
Mismatch repair is a major contributor to genome stability, and defects
in the mammalian pathway are associated with a strong predisposition to
tumor development. Despite the importance of this system in mutation
avoidance, our understanding of its molecular nature is limited. The
goals of this project are to establish the conformations and structures
of multi-protein and multi-proteinDNA complexes that are the key
intermediates in triggering the MutS- and MutL-dependent responses to
mismatched base pairs and certain types of DNA damage. Our goals are
five-fold: (1) Overexpression systems will be developed for production
of molecular complexes and truncated polypeptides for structural
analysis in collaboration with the Expression-Molecular Biology (EMB)
Core. (2) The conformations and dynamics of multi-protein and
multi-protein DNA assemblies involved in the initiation step of
mismatch repair will be addressed by single particle electron
microscopy and small angle X-ray scattering. The latter studies will
exploit the high temporal resolution of the Structural Cell Biology
(SCB) Synchrotron Beamline and the SCB Core. (3) The structural basis
for the recognition of base-base mispairs, insertion/deletion mispairs,
and damaged DNA substrates by eukaryotic MutS(alpha) and MutL(alpha) will be
addressed by X-ray crystallography. (4) Since the initiation of
mismatch repair depends on assembly of multi-protein-DNA complexes
(MutS MutL DNA in the bacterial system and MutS(alpha) MutL(alpha) PCNA
DNA in the eukaryotic reaction) these multi-protein and
multi-protein-DNA assemblies will be examined using X-ray
crystallography. (5) The structural studies above will reveal residues
at protein-protein interfaces as well as those that may be involved in
conformational transitions. The significance of these residues will be
subjected to biological validation by analysis of the phenotypic
consequences of genetic alteration of these residues and by examination
of selected mutant proteins at the biochemical level. Supporting
genetic and biochemical studies will be pursued under funding already
available to the Kolodner and Modrich laboratories and will be
leveraged to provide powerful Program interactions in a sustainable
structural biology cycle where structurally identified interfaces are
tested in vivo by mutational analyses. Furthermore, the expected
results will contribute directly to Program interactions with Project 1
(on PCNA as a molecular adaptor), Project 2 (on transcription coupled
repair) and Project 4 (on homologous recombination) plus comparative
ATP-driven conformational switching with Project 1 (ligase), Project 3
(Rad51), and Project 3 (Rad50).
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