Abstract
ABSTRACTDarunavir (DRV) has bimodal activity against HIV-1 protease, enzymatic inhibition and protease dimerization inhibition, and has an extremely high genetic barrier against development of drug resistance. We previously generated a highly DRV-resistant HIV-1 variant (HIVDRVRP51). We also reported that four amino acid substitutions (V32I, L33F, I54M, and I84V) identified in the protease of HIVDRVRP51 are largely responsible for its high-level resistance to DRV. Here, we attempted to elucidate the role of each of the four amino acid substitutions in the development of DRV resistance. We found that V32I is a key substitution, which rarely occurs, but once it occurs, it predisposes HIV-1 to develop high-level DRV resistance. When two infectious recombinant HIV-1 clones carrying I54M and I84V (rHIVI54M and rHIVI84V, respectively) were selected in the presence of DRV, V32I emerged, and the virus rapidly developed high-level DRV resistance. rHIVV32I also developed high-level DRV resistance. However, wild-type HIVNL4-3 (rHIVWT) failed to acquire V32I and did not develop DRV resistance. Compared to rHIVWT, rHIVV32I was highly susceptible to DRV and had significantly reduced fitness, explaining why V32I did not emerge upon selection of rHIVWT with DRV. When the only substitution is at residue 32, structural analysis revealed much stronger van der Waals interactions between DRV and I-32 than between DRV and V-32. These results suggest that V32I is a critical amino acid substitution in multiple pathways toward HIV-1’s DRV resistance development and elucidate, at least in part, a mechanism of DRV’s high genetic barrier to development of drug resistance. The results also show that attention should be paid to the initiation or continuation of DRV-containing regimens in people with HIV-1 containing the V32I substitution.
Highlights
Darunavir (DRV) has bimodal activity against HIV-1 protease, enzymatic inhibition and protease dimerization inhibition, and has an extremely high genetic barrier against development of drug resistance
The latest FDA-approved protease inhibitor (PI), darunavir (DRV), the only PI recommended for first-line therapy [3], has a favorable genetic barrier apparently because of its dual mechanism of action, (i) protease enzymatic inhibition activity and (ii) protease dimerization inhibition activity [4,5,6], and it currently represents the most widely used PI for treating HIV-1-infected individuals
Our group and others have previously reported that the selection of wild-type HIV-1 strains in the presence of each of eight FDA-approved protease inhibitors (PIs) readily gave HIV-1 variants resistant to each PI over 20 to 67 weeks [7,8,9,10, 15, 16]
Summary
Darunavir (DRV) has bimodal activity against HIV-1 protease, enzymatic inhibition and protease dimerization inhibition, and has an extremely high genetic barrier against development of drug resistance. When the only substitution is at residue 32, structural analysis revealed much stronger van der Waals interactions between DRV and I-32 than between DRV and V-32 These results suggest that V32I is a critical amino acid substitution in multiple pathways toward HIV-1’s DRV resistance development and elucidate, at least in part, a mechanism of DRV’s high genetic barrier to development of drug resistance. We demonstrate that one of the four critical amino acid substitutions, V32I, serves as a key substitution, which rarely occurs in in vitro selection attempts, but once it occurs, it predisposes HIV-1 to develop high-level DRV resistance. The present data explain the mechanisms of DRV’s high genetic barrier well and suggest that the initiation or continuation of DRVcontaining regimens in individuals harboring HIV-1 variants with a V32I substitution must be carefully considered and monitored
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