The long term goal of this research is to obtain a fundamental understanding how DNA repair glycosylases catalyze the hydrolysis of damaged pyrimidine and purine bases from DNA. The immediate goal of this proposal is to understand the mechanism and catalysis of the pyrimidine specific enzyme, uracil DNA glycosylase (UDG) from E. coli. UDG is of health related interest because of its role in removing premutagenic uracil bases from DNA, and is also a viable target for anti-viral drugs, because of its essential role in viral latency/reactivation cycles and viral DNA replication.
The specific aims of this research are to i) elucidate the complete kinetic and thermodynamic mechanism of the UDG reaction ii) determine the structures for enzyme-bound substrate and products, iii) establish the chemical basis for the 1012-fold catalytic power of UDG, and iv) determine the transition-state structure for enzymatic and nonenzymatic hydrolysis of uracil from DNA. The microscopic steps along the reaction pathway will be characterized using rapid kinetic methods, including the suggested key step in uracil recognition-the """"""""flipping out"""""""" of the base from the DNA helix. A novel fluorescence assay has been developed for much of this kinetic work. The structures of the enzyme-bound DNA substrate and products will be solved by X-ray crystallography, as we have already done for the free enzyme. The chemical mechanism of the enzymatic reaction will be examined by mutagenesis of conserved active-site residues seen in our partial crystal structure of the free enzyme. The damaging effects of these mutations on the microscopic kinetic steps, binding parameters, and the pH-rate profiles will be quantified. Thus, the catalytic roles of these residues and their pKa values will be suggested. Heteronuclear NMR spectroscopy will then be used directly to determine the side-chain pKa values of key groups identified by mutagenesis, establishing a thermodynamic framework for the proton transfers involved in the reaction. The transition-state structure will be characterized on the basis of dual-label competitive isotope effect measurements. For the isotope effect work, a new and efficient method for the enzymatic synthesis of isotopically labeled deoxyuridine- containing DNA will be used. The enzymatic isotope effects and transition-state will them be compared with the water and acid-catalyzed hydrolysis of uracil from isotopically labeled DNA. It is anticipated that this work will provide a basic understanding of the factors that contribute to stabilization of the enzymatic transition-state for hydrolysis of pyrimidine bases from DNA.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM056834-04
Application #
6351230
Study Section
Biochemistry Study Section (BIO)
Program Officer
Marino, Pamela
Project Start
1998-02-01
Project End
2001-03-31
Budget Start
2001-02-01
Budget End
2001-03-31
Support Year
4
Fiscal Year
2001
Total Cost
$38,875
Indirect Cost
Name
University of MD Biotechnology Institute
Department
Type
Organized Research Units
DUNS #
City
Baltimore
State
MD
Country
United States
Zip Code
21202
Weiser, Brian P; Rodriguez, Gaddiel; Cole, Philip A et al. (2018) N-terminal domain of human uracil DNA glycosylase (hUNG2) promotes targeting to uracil sites adjacent to ssDNA-dsDNA junctions. Nucleic Acids Res 46:7169-7178
Rodriguez, Gaddiel; Esadze, Alexandre; Weiser, Brian P et al. (2017) Disordered N-Terminal Domain of Human Uracil DNA Glycosylase (hUNG2) Enhances DNA Translocation. ACS Chem Biol 12:2260-2263
Weiser, Brian P; Stivers, James T; Cole, Philip A (2017) Investigation of N-Terminal Phospho-Regulation of Uracil DNA Glycosylase Using Protein Semisynthesis. Biophys J 113:393-401
Esadze, Alexandre; Rodriguez, Gaddiel; Weiser, Brian P et al. (2017) Measurement of nanoscale DNA translocation by uracil DNA glycosylase in human cells. Nucleic Acids Res 45:12413-12424
Esadze, Alexandre; Rodriguez, Gaddiel; Cravens, Shannen L et al. (2017) AP-Endonuclease 1 Accelerates Turnover of Human 8-Oxoguanine DNA Glycosylase by Preventing Retrograde Binding to the Abasic-Site Product. Biochemistry 56:1974-1986
Seamon, Kyle J; Bumpus, Namandjé N; Stivers, James T (2016) Single-Stranded Nucleic Acids Bind to the Tetramer Interface of SAMHD1 and Prevent Formation of the Catalytic Homotetramer. Biochemistry 55:6087-6099
Cravens, Shannen L; Stivers, James T (2016) Comparative Effects of Ions, Molecular Crowding, and Bulk DNA on the Damage Search Mechanisms of hOGG1 and hUNG. Biochemistry 55:5230-42
Hansen, Erik C; Ransom, Monica; Hesselberth, Jay R et al. (2016) Diverse fates of uracilated HIV-1 DNA during infection of myeloid lineage cells. Elife 5:
Cravens, Shannen L; Schonhoft, Joseph D; Rowland, Meng M et al. (2015) Molecular crowding enhances facilitated diffusion of two human DNA glycosylases. Nucleic Acids Res 43:4087-97
Seamon, Kyle J; Sun, Zhiqiang; Shlyakhtenko, Luda S et al. (2015) SAMHD1 is a single-stranded nucleic acid binding protein with no active site-associated nuclease activity. Nucleic Acids Res 43:6486-99

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