Abstract

Fundamental studies of structure-function relationships of the HIV Protease (HIV PR) will be undertaken with the goal of increasing our understanding of this therapeutically important enzyme. Highly optimized total chemical synthesis will be used to prepare both HIV PR as well as a series of synthetic analogues of the enzyme. These analogues will be rationally designed using molecular modeling to probe the important structure-function relationships implicit in the enzyme's proposed mode of action. Throughout this program the fundamental structural and thermodynamic impact of these modifications will be gauged in a number of ways. The complete 2D-NMR assignment of an appropriately isotopically labeled synthetic enzyme will be undertaken and subsequently used as a structural fingerprint by which to routinely compare analogues. Furthermore, it is anticipated that thermodynamic and kinetic measurements will be made on all synthetic enzymes, again these quantities will be compared with the native enzyme. In addition, X-ray crystallography will be performed on selected analogues. The dynamic nature of the NMR experiment is ideally suited to the study of the flap movements which apparently occur upon substrate binding. The proposed role of Water301 in the catalytic mechanism will be evaluated by site- specific replacement of peptide bonds thought to be involved in H-bonding interactions with substrates/inhibitors through this water molecule. The ionization state of the catalytically active Asp25, Asp125 side chains will be directly determined by single-atom labeling with 13C as an NMR reporter group. Rules governing substrate specificity will be deduced, and will be tested by construction of analog PR molecules with space filling and/or charge modifying geometrically-constrained moieties introduced into the P1 and P1' specificity pockets. The fundamental knowledge resulting from these studies of HIV PR will be important for the understanding of related clinically-relevant enzymes, such as the other retroviral proteases, and of cell-encoded aspartyl proteinases such as renin.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM048897-02
Application #
2186413
Study Section
AIDS and Related Research Study Section 4 (ARRD)
Project Start
1993-08-01
Project End
1996-07-31
Budget Start
1994-08-01
Budget End
1995-07-31
Support Year
2
Fiscal Year
1994
Total Cost
Indirect Cost

  Institution

Name
Scripps Research Institute
Department
Type
DUNS #
City
La Jolla
State
CA
Country
United States
Zip Code
92037

  Publications

Lu, W; Randal, M; Kossiakoff, A et al. (1999) Probing intermolecular backbone H-bonding in serine proteinase-protein inhibitor complexes. Chem Biol 6:419-27
Lu, W; Starovasnik, M A; Kent, S B (1998) Total chemical synthesis of bovine pancreatic trypsin inhibitor by native chemical ligation. FEBS Lett 429:31-5
Muir, T W; Dawson, P E; Kent, S B (1997) Protein synthesis by chemical ligation of unprotected peptides in aqueous solution. Methods Enzymol 289:266-98
Lu, W; Qasim, M A; Laskowski Jr, M et al. (1997) Probing intermolecular main chain hydrogen bonding in serine proteinase-protein inhibitor complexes: chemical synthesis of backbone-engineered turkey ovomucoid third domain. Biochemistry 36:673-9
Muir, T W; Dawson, P E; Fitzgerald, M C et al. (1996) Probing the chemical basis of binding activity in an SH3 domain by protein signature analysis. Chem Biol 3:817-25
Dawson, P E; Muir, T W; Clark-Lewis, I et al. (1994) Synthesis of proteins by native chemical ligation. Science 266:776-9
Baca, M; Kent, S B (1993) Catalytic contribution of flap-substrate hydrogen bonds in ""HIV-1 protease"" explored by chemical synthesis. Proc Natl Acad Sci U S A 90:11638-42