Structural basis for drug and substrate specificity exhibited by FIV encoding a chimeric FIV/HIV protease

Lin, Ying‐Chuan; Perryman, Alex L.; Olson, Arthur J.; Torbett, Bruce E.; Elder, John H.; Stout, C.D.

doi:10.1107/s0907444911011681

Cited by 9 publications

(12 citation statements)

References 32 publications

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“…The 6s-98S FIV employed in this study produces a chimeric FIV/ HIV PR with six mutations (I37 32 V, N55 46 M, V59 50 I, I98 81 S, Q99 82 V, and P100 83 N) and is sensitive to the HIV-1 PR inhibitors LPV, DRV, and TL-3 both in in vitro assays of PR activity and in tissue culture infectivity studies. This chimera was previously shown to be sensitive to 200 nM LPV (25), so selection of drugresistant mutants employed an initial concentration of 100 nM LPV.…”

Section: Resultsmentioning

confidence: 99%

“…Infectious 6s-98S contains five substitutions for structurally equivalent residues of HIV-1 PR, including I37 32 V, N55 46 M, V59 50 I, Q99 82 V, and P100 83 N, and an additional I98 81 P-ϾS mutation (FIV numbering with equivalent HIV-1 numbering in superscript) with a replication capacity much better than that of the original chimeric FIV 6s mutant (I37 32 V, N55 46 M, V59 50 I, Q99 82 V, P100 83 N, and I98 81 P) emerged from a long-term culture. The structural location of I37 32 V is in the active core, whereas N55 46 M and V59 50 I are in the flap region. I98 81 S, Q99 82 V, and P100 83 N are in the 90s loop region (Fig.…”

Section: Methodsmentioning

confidence: 99%

“…The FIV and HIV-1 PRs have 27 identical residues and display distinct substrate and inhibitor specificities, and none of the current FDA-approved drugs against HIV-1 PR inhibit FIV PR. Of importance, nine of the aforementioned HIV-1 resistance mutations in HIV-1 PR, namely, V11I, K20I, V32I, I50V, I62V, I64L, A71I, N88D, and L90M, are already present in the equivalent positions of FIV PR (16 11 I, 25 20 I, 37 32 I, 59 50 (8,9), in essence making the feline enzyme the ultimate drug-resistant "mutant" enzyme. Rational design based on a comparison of the structures of the FIV and HIV-1 PRs led to the development of TL-3, a broad-based PR inhibitor capable of inhibiting FIV, SIV (simian immunodeficiency virus), HIV-1, and resistant HIV-1 mutants in cell culture (10)(11)(12)(13)(14)(15).…”

mentioning

confidence: 99%

“…We designed and expressed several chimeric FIV/HIV PRs that demonstrated HIV-like specificity by substituting as few as four amino acids (I37 32 V/N55 46 M/M56 47 I/V59 50 I) into FIV PR, causing the K i values for many HIV-1 PR inhibitors to drop from the high micromolar to the nanomolar range (21,22). The use of a cell-based FIV Gag-Pol expression system (23) further allowed assessment of the temporal processing of Gag polyprotein by chimeric PRs in the context of the natural substrate (24).…”

mentioning

confidence: 99%

“…However, the generation of infectious mutant viruses producing chimeric PR was problematic because of deleterious effects on the cleavage of the Gag polyprotein caused by certain substitutions. Once these problem residues were identified, we were able to generate an infectious mutant FIV producing FIV/ HIV chimeric PR with six mutations, i.e., I37 32 V in the active core, N55 46 M/V59 50 I in the flaps, and I98 81 H(S)/Q99 82 V/P100 83 N in the "90s loop" (25). The chimeric PR was sensitive to the potent HIV-1 PR inhibitors lopinavir (LPV) and darunavir (DRV) and the broad-based inhibitor TL-3, with 50% inhibitory concentrations (IC 50 s) of about 30 nM in vitro.…”

mentioning

confidence: 99%

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Selection of Drug-Resistant Feline Immunodeficiency Virus (FIV) Encoding FIV/HIV Chimeric Protease in the Presence of HIV-Specific Protease Inhibitors

Lin

Happer

Elder

2013

J Virol

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An infectious chimeric feline immunodeficiency virus (FIV)/HIV strain carrying six HIV-like protease (PR) mutations (I37V/ N55M/V59I/I98S/Q99V/P100N) was subjected to selection in culture against the PR inhibitor lopinavir (LPV), darunavir (DRV), or TL-3. LPV selection resulted in the sequential emergence of V99A (strain S-1X), I59V (strain S-2X), and I108V (strain S-3X) mutations, followed by V37I (strain S-4X). Mutant PRs were analyzed in vitro, and an isogenic virus producing each mutant PR was analyzed in culture for LPV sensitivity, yielding results consistent with the original selection. The 50% inhibitory concentrations (IC 50 s) for S-1X, S-2X, S-3X, and S-4X were 95, 643, 627, and 1,543 nM, respectively. The primary resistance mutations, V99 82 A, I59 50 V, and V37 32 I, are consistent with the resistance pattern developed by HIV-1 under similar selection conditions. While resistance to LPV emerged readily, similar PR mutations causing resistance to either DRV or TL-3 failed to emerge after passage for more than a year. However, a G37D mutation in the nucleocapsid (NC) was observed in both selections and an isogenic G37D mutant replicated in the presence of 100 nM DRV or TL-3, whereas parental chimeric FIV could not. An additional mutation, L92V, near the PR active site in the folded structure recently emerged during TL-3 selection. The L92V mutant PR exhibited an IC 50 of 50 nM, compared to 35 nM for 6s-98S PR, and processed the NC-p2 junction more efficiently, consistent with increased viral fitness. These findings emphasize the role of mutations outside the active site of PR in increasing viral resistance to active-site inhibitors and suggest additional targets for inhibitor development.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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confidence: 99%

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Selection of Drug-Resistant Feline Immunodeficiency Virus (FIV) Encoding FIV/HIV Chimeric Protease in the Presence of HIV-Specific Protease Inhibitors

Lin

Happer

Elder

2013

J Virol

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TheAutoDocksuite at 30

et al. 2020

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The AutoDock suite provides a comprehensive toolset for computational ligand docking and drug design and development. The suite builds on 30 years of methods development, including empirical free energy force fields, docking engines, methods for site prediction, and interactive tools for visualization and analysis. Specialized tools are available for challenging systems, including covalent inhibitors, peptides, compounds with macrocycles, systems where ordered hydration plays a key role, and systems with substantial receptor flexibility. All methods in the AutoDock suite are freely available for use and reuse, which has engendered the continued growth of a diverse community of primary users and third‐party developers.

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Virtual screening with AutoDock Vina and the common pharmacophore engine of a low diversity library of fragments and hits against the three allosteric sites of HIV integrase: participation in the SAMPL4 protein–ligand binding challenge

Perryman

Santiago

Forli

et al. 2014

J Comput Aided Mol Des

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To rigorously assess the tools and protocols that can be used to understand and predict macromolecular recognition, and to gain more structural insight into three newly-discovered allosteric binding sites on a critical drug target involved in the treatment of HIV infections, the Olson and Levy labs collaborated on the SAMPL4 challenge. This computational blind challenge involved predicting protein-ligand binding against the three allosteric sites of HIV integrase (IN), a viral enzyme for which two drugs (that target the active site) have been approved by the FDA. Positive control cross-docking experiments were utilized to select 13 receptor models out of an initial ensemble of 41 different crystal structures of HIV IN. These 13 models of the targets were selected using our new “Rank Difference Ratio” metric. The first stage of SAMPL4 involved using Virtual Screens to identify 62 active, allosteric IN inhibitors out of a set of 321 compounds. The second stage involved predicting the binding site(s) and crystallographic binding mode(s) for 57 of these inhibitors. Our team submitted four entries for the first stage that utilized: 1) AutoDock Vina plus visual inspection; 2) a new Common Pharmacophore Engine; 3) BEDAM replica exchange re-scoring simulations, and a Consensus approach that combined the predictions of all three strategies. Even with the SAMPL4’s very challenging compound library that displayed a significantly lower amount of structural diversity than most of the libraries that are conventionally employed in prospective Virtual Screens, these approaches produced hit rates of 24%, 25%, 34%, and 27%, respectively, on a set with 19% declared binders. Our only entry for the second stage challenge was based on the results of AD Vina plus visual inspection, and it ranked third place overall according to several different metrics provided by the SAMPL4 organizers. The successful results displayed by these approaches highlight the utility of the computational structure-based drug discovery tools and strategies that are being developed to advance the goals of the newly-created, multi-institution, NIH-funded center called the “HIVE” (for HIV Interaction and Viral Evolution Center).

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Structural basis for drug and substrate specificity exhibited by FIV encoding a chimeric FIV/HIV protease

Cited by 9 publications

References 32 publications

Selection of Drug-Resistant Feline Immunodeficiency Virus (FIV) Encoding FIV/HIV Chimeric Protease in the Presence of HIV-Specific Protease Inhibitors

Selection of Drug-Resistant Feline Immunodeficiency Virus (FIV) Encoding FIV/HIV Chimeric Protease in the Presence of HIV-Specific Protease Inhibitors

TheAutoDocksuite at 30

Virtual screening with AutoDock Vina and the common pharmacophore engine of a low diversity library of fragments and hits against the three allosteric sites of HIV integrase: participation in the SAMPL4 protein–ligand binding challenge

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