Abstract

The long range goal of this project is to develop and apply theoretical methods which will allow the accurate simulation of the structures and free energies of nucleic acids and their non- covalent and covalent adducts with other molecules. A major objective of the next period of grant support is the extension and application of free energy perturbation, molecular dynamics, quantum mechanical and distance geometry methodologies to a wide variety of systems involving DNA and RNA. Studies on DNA-anticancer drugs may lead to new insights into drug design. Studies of carcinogenic DNA adducts could give insight into what makes them carcinogenic. The process of recognition of sites of DNA by small molecules should allow the design of molecules which interact with specific sites on DNA. These methodologies should enable a more accurate representation of the conformational equilibria and free energies for the basis of biophysical processes of nucleic acids (e.g. double helix formation, bulge formation, A leads to B leads to Z transition energetics, sequence dependent DNA and RNA dynamics and equilibria). They also should allow quantitative calculations and predictions of relative free energies of associations of small molecules to DNA and RNA. They will allow a more accurate representation of structures and energies of DNA-covalent adduct formation. The calculation will give new and quantitative insight into the nature of DNA recognition by proteins. Important spinoffs of these studies may be new insights into the biological consequence of nucleic acid interactions with other molecules.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA025644-10
Application #
3166981
Study Section
Biophysics and Biophysical Chemistry A Study Section (BBCA)
Project Start
1980-01-01
Project End
1990-12-31
Budget Start
1989-01-01
Budget End
1989-12-31
Support Year
10
Fiscal Year
1989
Total Cost
Indirect Cost

  Institution

Name
University of California San Francisco
Department
Type
Schools of Pharmacy
DUNS #
073133571
City
San Francisco
State
CA
Country
United States
Zip Code
94143

  Publications

Wang, Junmei; Kang, Xinshan; Kuntz, Irwin D et al. (2005) Hierarchical database screenings for HIV-1 reverse transcriptase using a pharmacophore model, rigid docking, solvation docking, and MM-PB/SA. J Med Chem 48:2432-44
Tonelli, Marco; Ulyanov, Nikolai B; Billeci, Todd M et al. (2003) Dynamic NMR structures of [Rp]- and [Sp]-phosphorothioated DNA-RNA hybrids: is flexibility required for RNase H recognition? Biophys J 85:2525-38
Reyes, C M; Kollman, P A (2000) Structure and thermodynamics of RNA-protein binding: using molecular dynamics and free energy analyses to calculate the free energies of binding and conformational change. J Mol Biol 297:1145-58
Kollman, P A; Massova, I; Reyes, C et al. (2000) Calculating structures and free energies of complex molecules: combining molecular mechanics and continuum models. Acc Chem Res 33:889-97
Reyes, C M; Kollman, P A (2000) Investigating the binding specificity of U1A-RNA by computational mutagenesis. J Mol Biol 295:6-Jan
Cheatham 3rd, T E; Cieplak, P; Kollman, P A (1999) A modified version of the Cornell et al. force field with improved sugar pucker phases and helical repeat. J Biomol Struct Dyn 16:845-62
Konerding, D E; Cheatham 3rd, T E; Kollman, P A et al. (1999) Restrained molecular dynamics of solvated duplex DNA using the particle mesh Ewald method. J Biomol NMR 13:119-31
Reyes, C M; Kollman, P A (1999) Molecular dynamics studies of U1A-RNA complexes. RNA 5:235-44
Srinivasan, J; Miller, J; Kollman, P A et al. (1998) Continuum solvent studies of the stability of RNA hairpin loops and helices. J Biomol Struct Dyn 16:671-82
Cheatham 3rd, T E; Srinivasan, J; Case, D A et al. (1998) Molecular dynamics and continuum solvent studies of the stability of polyG-polyC and polyA-polyT DNA duplexes in solution. J Biomol Struct Dyn 16:265-80

Showing the most recent 10 out of 52 publications