Abstract

The broad objectives of the work are to understand the functions of thymidylate synthase (TS) and other nucleotide, RNA and DNA-modifying enzymes. TS is an important drug target, since it provides the sole de novo pathway for synthesis of an essential DNA nucleotide. TS is the best characterized of the class of proteins that catalyze methyl transfer reactions in pyrimidine biosynthesis. Insights into the mechanism of TS have been applied to the study of related enzymes, such as the dUMP and dCMP hydroxymethylases, and DNA and RNA cytosine methyltransferases, and have deepened our understanding of general principles of catalysis of two-substrate reactions. The mechanism of TS will be investigated at a very detailed level by determining crystal structures of TS variants, generated by mutagenesis, in binary and ternary complexes with substrate, cofactor, or their analogs. Structures will be related to the results of kinetic and functional assays. A saturation mutagenesis approach will be used to define the roles of the approximately 25 conserved residues in the active site cavity. In this approach, a synthesized L. casei TS gene with strategically placed restriction sites is used to make all substitutions of the natural amino acids at a given site. Mutants of residues shown to have a role in the chemical steps following ternary complex formation will be made in E. coli TS for crystallographic study, since E. coli ternary complex crystal structures can be determined to ad least 2 Angstrom units resolution. Mutations which impair catalysis at different points in the multistep reaction will be used to isolate structures of new reaction intermediates by crystallography. The mechanism for hydride transfer in TS will be studied by determining the structure of SP01 dUMP-hydroxymethylase. This enzyme is structurally and mechanistically closely related to TS, but does not undergo the hydride transfer step. The enzyme will be crystallized and its structure determined by MIR methods. The crystal structure of tRNA pseudouridine synthase I, which modifies a uridine base in an E. Coli tRNA, will be determined from already grown crystals that diffract to 1.35 Angstrom units resolution. MIR and MAD phasing techniques will be used to solve the structure. The protein will also be crystallized as a complex with a tRNA inhibitor. The mechanism of pseudouridine synthase will be investigated by mutagenesis of residues chosen based on the crystal structures.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA041323-18
Application #
6626564
Study Section
Molecular and Cellular Biophysics Study Section (BBCA)
Program Officer
Lees, Robert G
Project Start
1985-12-01
Project End
2003-12-31
Budget Start
2003-01-01
Budget End
2003-12-31
Support Year
18
Fiscal Year
2003
Total Cost
$258,512
Indirect Cost

  Institution

Name
University of California San Francisco
Department
Biochemistry
Type
Schools of Medicine
DUNS #
094878337
City
San Francisco
State
CA
Country
United States
Zip Code
94143

  Publications

Newby, Zachary; Lee, Tom T; Morse, Richard J et al. (2006) The role of protein dynamics in thymidylate synthase catalysis: variants of conserved 2'-deoxyuridine 5'-monophosphate (dUMP)-binding Tyr-261. Biochemistry 45:7415-28
Birdsall, David L; Finer-Moore, Janet; Stroud, Robert M (2003) The only active mutant of thymidylate synthase D169, a residue far from the site of methyl transfer, demonstrates the exquisite nature of enzyme specificity. Protein Eng 16:229-40
Gonzalez-Pacanowska, Dolores; Ruiz-Perez, Luis M; Carreras-Gomez, Maria Angeles et al. (2003) The structural roles of conserved Pro196, Pro197 and His199 in the mechanism of thymidylate synthase. Protein Eng 16:607-14
Stroud, Robert M; Finer-Moore, Janet S (2003) Conformational dynamics along an enzymatic reaction pathway: thymidylate synthase, ""the movie"". Biochemistry 42:239-47
Finer-Moore, Janet S; Santi, Daniel V; Stroud, Robert M (2003) Lessons and conclusions from dissecting the mechanism of a bisubstrate enzyme: thymidylate synthase mutagenesis, function, and structure. Biochemistry 42:248-56
Fritz, Timothy A; Liu, Lu; Finer-Moore, Janet S et al. (2002) Tryptophan 80 and leucine 143 are critical for the hydride transfer step of thymidylate synthase by controlling active site access. Biochemistry 41:7021-9
Kawase, S; Cho, S W; Rozelle, J et al. (2000) Replacement set mutagenesis of the four phosphate-binding arginine residues of thymidylate synthase. Protein Eng 13:557-63
Variath, P; Liu, Y; Lee, T T et al. (2000) Effects of subunit occupancy on partitioning of an intermediate in thymidylate synthase mutants. Biochemistry 39:2429-35
Morse, R J; Kawase, S; Santi, D V et al. (2000) Energetic contributions of four arginines to phosphate-binding in thymidylate synthase are more than additive and depend on optimization of ""effective charge balance"". Biochemistry 39:1011-20
Stout, T J; Tondi, D; Rinaldi, M et al. (1999) Structure-based design of inhibitors specific for bacterial thymidylate synthase. Biochemistry 38:1607-17

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