Energetic and Dynamic Analysis of Inhibitor Binding to Drug-Resistant HIV-1 Proteases: A Dissertation

Abstract

HIV-1 protease is a very important drug target for AIDS therapy. Nine protease inhibitors have been proved by FDA and used in AIDS treatment. Due to the high replication rate and the lack of fidelity of the HIV-1 reverse transcriptase, HIV-1 virus developed various drug-resistant variants. Although experimental methods such as crystallography and isothermal titration calorimetry provide structural and thermodynamic data on drug-resistant variants, they are unable to discern the mechanism by which the mutations confer resistance to inhibitors. Understanding the drug-resistance mechanism is crucial for developing new inhibitors more tolerant to the drug-resistant mutations. Computational methods such as free energy calculations and molecular dynamic simulations can provide insights to the drug resistance mechanism at an atomic level. In this thesis, I have focused on the elucidation of the energetic and dynamics of key drug-resistant variants of HIV-1 protease. Two multi-drug resistant variants, in comparison with wild-type HIV-1 protease were used for the comparisons: Flap+ (L10I, G48V, I54V, and V82A) which contains a combination of flap and active site mutations and ACT (V82T, I84V) that only contains active site mutations. In Chapter II, I applied free energy simulations and decomposition methods to study the differential mechanism of resistance to the two variants, Flap+ and ACT, to the recently FDA-approved protease inhibitor darunavir (DRV). In this study, the absolute and relative binding free energies of DRV with wild-type protease and the two protease variants were calculated with MM-PB/GBSA and thermodynamic integration methods, respectively. And the