Cyclic HIV Protease Inhibitors:  Synthesis, Conformational Analysis, P2/P2‘ Structure−Activity Relationship, and Molecular Recognition of Cyclic Ureas

Cyclic HIV Protease Inhibitors:  Synthesis, Conformational Analysis, P2/P2‘ Structure−Activity Relationship, and Molecular Recognition of Cyclic Ureas

High-resolution X-ray structures of the complexes of HIV-1 protease (HIV-1PR) with peptidomimetic inhibitors reveal the presence of a structural water molecule which is hydrogen bonded to both the mobile flaps of the enzyme and the two carbonyls flanking the transition-state mimic of the inhibitors....

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Published in:Journal of medicinal chemistry Vol. 39; no. 18; pp. 3514 - 3525
Main Authors: Lam, Patrick Y. S, Ru, Yu, Jadhav, Prabhakar K, Aldrich, Paul E, DeLucca, George V, Eyermann, Charles J, Chang, Chong-Hwan, Emmett, George, Holler, Edward R, Daneker, Wayne F, Li, Liangzhu, Confalone, Pat N, McHugh, Robert J, Han, Qi, Li, Renhua, Markwalder, Jay A, Seitz, Steven P, Sharpe, Thomas R, Bacheler, Lee T, Rayner, Marlene M, Klabe, Ronald M, Shum, Linyee, Winslow, Dean L, Kornhauser, David M, Jackson, David A, Erickson-Viitanen, Susan, Hodge, C. Nicholas
Format: Journal Article
Language:English
Published: Washington, DC American Chemical Society 30-08-1996
Subjects:
AIDS/HIV
Animals
Antibiotics. Antiinfectious agents. Antiparasitic agents
Antiviral agents
Biological and medical sciences
HIV Protease Inhibitors - chemical synthesis
HIV Protease Inhibitors - pharmacology
human immunodeficiency virus
Humans
Medical sciences
Molecular Conformation
Pharmacology. Drug treatments
Structure-Activity Relationship
Urea - chemical synthesis
Urea - chemistry
Urea - pharmacology
HIV-1 virus
Nitrogen heterocycle
Modeling
Structure activity relation
Molecular model
Lentivirinae
Antiviral
Ureas
Chemical synthesis
Proteinases
Enzyme
Oral administration
Retroviridae
Enzyme inhibitor
Inhibitor enzyme complex
Bioavailability
In vitro
Virus
In vivo
Animal
Hydrolases
Human immunodeficiency virus
Pharmacokinetics
Glycol
Recognition
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Summary:High-resolution X-ray structures of the complexes of HIV-1 protease (HIV-1PR) with peptidomimetic inhibitors reveal the presence of a structural water molecule which is hydrogen bonded to both the mobile flaps of the enzyme and the two carbonyls flanking the transition-state mimic of the inhibitors. Using the structure−activity relationships of C 2-symmetric diol inhibitors, computed-aided drug design tools, and first principles, we designed and synthesized a novel class of cyclic ureas that incorporates this structural water and preorganizes the side chain residues into optimum binding conformations. Conformational analysis suggested a preference for pseudodiaxial benzylic and pseudodiequatorial hydroxyl substituents and an enantiomeric preference for the RSSR stereochemistry. The X-ray and solution NMR structure of the complex of HIV-1PR and one such cyclic urea, DMP323, confirmed the displacement of the structural water. Additionally, the bound and “unbound” (small-molecule X-ray) ligands have similar conformations. The high degree of preorganization, the complementarity, and the entropic gain of water displacement are proposed to explain the high affinity of these small molecules for the enzyme. The small size probably contributes to the observed good oral bioavailability in animals. Extensive structure-based optimization of the side chains that fill the S2 and S2‘ pockets of the enzyme resulted in DMP323, which was studied in phase I clinical trials but found to suffer from variable pharmacokinetics in man. This report details the synthesis, conformational analysis, structure−activity relationships, and molecular recognition of this series of C 2-symmetry HIV-1PR inhibitors. An initial series of cyclic ureas containing nonsymmetric P2/P2‘ is also discussed.
Bibliography:Abstract published in Advance ACS Abstracts, August 1, 1996.
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ISSN:0022-2623
1520-4804
DOI:10.1021/jm9602571