Counteracting HIV-1 Protease Drug Resistance:  Structural Analysis of Mutant Proteases Complexed with XV638 and SD146, Cyclic Urea Amides with Broad Specificities

The long-term therapeutic benefit of HIV antiretroviral therapy is still threatened by drug-resistant variants. Mutations in the S1 subsite of the protease are the primary cause for the loss of sensitivity toward many HIV protease inhibitors, including our first-generation cyclic urea-based inhibito...

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Bibliographic Details
Published in:Biochemistry (Easton) 1998-10, Vol.37 (43), p.15042-15049
Main Authors: Ala, Paul J, Huston, Edward E, Klabe, Ronald M, Jadhav, Prabhakar K, Lam, Patrick Y. S, Chang, Chong-Hwan
Format: Article
Language:English
Subjects:
Amino Acid Substitution - genetics
Binding Sites - drug effects
Binding Sites - genetics
Drug Resistance, Microbial - genetics
HIV Protease - chemistry
HIV Protease - genetics
HIV Protease - pharmacology
HIV Protease Inhibitors - antagonists & inhibitors
HIV Protease Inhibitors - chemistry
HIV Protease Inhibitors - pharmacology
HIV-1 - drug effects
HIV-1 - enzymology
Human immunodeficiency virus 1
Humans
Macromolecular Substances
Models, Molecular
Mutagenesis, Site-Directed
Substrate Specificity
Urea - analogs & derivatives
Urea - antagonists & inhibitors
Urea - chemistry
Urea - pharmacology
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Summary:The long-term therapeutic benefit of HIV antiretroviral therapy is still threatened by drug-resistant variants. Mutations in the S1 subsite of the protease are the primary cause for the loss of sensitivity toward many HIV protease inhibitors, including our first-generation cyclic urea-based inhibitors DMP323 and DMP450. We now report the structures of the three active-site mutant proteases V82F, I84V, and V82F/I84V in complex with XV638 and SD146, two P2 analogues of DMP323 that are 8-fold more potent against the wild type and are able to inhibit a broad panel of drug-resistant variants [Jadhav, P. K., et al. (1997) J. Med. Chem. 40, 181−191]. The increased efficacy of XV638 and SD146 is due primarily to an increase in P2−S2 interactions:  30−40% more van der Waals contacts and two to four additional hydrogen bonds. Furthermore, because these new interactions do not perturb other subsites in the protease, it appears that the large complementary surface areas of their P2 substituents compensate for the loss of P1−S1 interactions and reduce the probability of selecting for drug-resistant variants.
ISSN:0006-2960
1520-4995
DOI:10.1021/bi980386e