HIV-1 Resistance to CCR5 Antagonists Associated with Highly Efficient Use of CCR5 and Altered Tropism on Primary CD4
            <sup>+</sup>
            T Cells

Pfaff, Jennifer M.; Wilen, Craig B.; Harrison, Jessamina E.; Demarest, James F.; Lee, Benhur; Doms, Robert W.; Tilton, John C.

doi:10.1128/jvi.00374-10

Cited by 58 publications

(79 citation statements)

References 56 publications

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“…Late fusion events occur at similar rates in different viral isolates, so it is likely that the differences we observed in entry kinetics reflect changes in the kinetics of binding to CD4, CCR5, or both (29). Increased coreceptor affinity accelerates viral fusion; because CCR5 antagonist-resistant HIV-1 uses the drug-bound CCR5, the V3 loop mutations that confer resistance must increase gp120 affinity for the antagonist-coreceptor complex (36,40,44,54,59). A clonal analysis of env sequences from Sub07 and Sub57, however, demonstrated that even after the virus acquired the capacity to use the drug-coreceptor complex, resistance mutations continued to accumulate.…”

Section: Discussionmentioning

confidence: 99%

HIV-1 Clinical Isolates Resistant to CCR5 Antagonists Exhibit Delayed Entry Kinetics That Are Corrected in the Presence of Drug

Putcharoen

Lee

Henrich

et al. 2012

J Virol

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HIV CCR5 antagonists select for env gene mutations that enable virus entry via drug-bound coreceptor. To investigate the mechanisms responsible for viral adaptation to drug-bound coreceptor-mediated entry, we studied viral isolates from three participants who developed CCR5 antagonist resistance during treatment with vicriviroc (VCV), an investigational small-molecule CCR5 antagonist. VCV-sensitive and -resistant viruses were isolated from one HIV subtype C-and two subtype B-infected participants; VCV-resistant isolates had mutations in the V3 loop of gp120 and were cross-resistant to TAK-779, an investigational antagonist, and maraviroc (MVC). All three resistant isolates contained a 306P mutation but had variable mutations elsewhere in the V3 stem. We used a virus-cell ␤-lactamase (BlaM) fusion assay to determine the entry kinetics of recombinant viruses that incorporated full-length VCV-sensitive and -resistant envelopes. VCV-resistant isolates exhibited delayed entry rates in the absence of drug, relative to pretherapy VCV-sensitive isolates. The addition of drug corrected these delays. These findings were generalizable across target cell types with a range of CD4 and CCR5 surface densities and were observed when either populationderived or clonal envelopes were used to construct recombinant viruses. V3 loop mutations alone were sufficient to restore virus entry in the presence of drug, and the accumulation of V3 mutations during VCV therapy led to progressively higher rates of viral entry. We propose that the restoration of pre-CCR5 antagonist therapy HIV entry kinetics drives the selection of V3 loop mutations and may represent a common mechanism that underlies the emergence of CCR5 antagonist resistance. Human immunodeficiency virus entry is a competition at the target cell membrane between viral inactivation and successful binding to CD4 and a coreceptor, either CCR5 or CXCR4 (16,30,32,33,37,38). Engagement of receptor and coreceptor by gp120 and the subsequent rearrangement of gp41, the HIV fusion glycopeptides, leads to fusion (18,21,29,57,60,63). Smallmolecule antagonists that bind CCR5 and inhibit gp120-CCR5 binding through an allosteric mechanism have been developed (9,23,51,53,56,61). Maraviroc (MVC) is an FDA-approved CCR5 antagonist, and vicriviroc (VCV) is an investigational compound whose development has been halted (10, 47).HIV can escape CCR5 antagonism through the outgrowth of preexisting CXCR4-using populations or by the selection of resistance mutations (2, 52, 58). Mutations in the third hypervariable loop (V3 loop) of HIV-1 gp120 most commonly cause CCR5 antagonist resistance, but no canonical sites or amino acid substitutions have been identified; resistance mutations from one isolate generally do not confer resistance when transferred into unrelated env backbones (12, 17, 24, 26, 27, 34-36, 49, 54). This varied nature of HIV CCR5 antagonist genotypic resistance contrasts with resistance patterns established in other antiretroviral drug classes, for which canonical mutations (M184V in r...

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Section: Discussionmentioning

confidence: 99%

HIV-1 Clinical Isolates Resistant to CCR5 Antagonists Exhibit Delayed Entry Kinetics That Are Corrected in the Presence of Drug

Putcharoen

Lee

Henrich

et al. 2012

J Virol

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“…HIV-1 resistance to such inhibitors is likely to entail unique escape mechanisms given that a host receptor, not a viral enzyme, is the drug target. Potential pathways of resistance to these inhibitors include coreceptor switching to CXCR4-using viruses (16), increased affinity and binding to CD4 and/or CCR5 (17,18), use of inhibitorbound conformations of CCR5 (19,20), and increased kinetics of membrane fusion (21). Although outgrowth of CXCR4-using virus remains a concern for the therapeutic administration of CCR5 antagonists and is why patients are screened for X4-tropic virus prior to starting a maraviroc regimen, de novo mutations altering coreceptor tropism do not appear to be the preferential pathway for resistance (22,23).…”

mentioning

confidence: 99%

HIV-1 Resistance to Maraviroc Conferred by a CD4 Binding Site Mutation in the Envelope Glycoprotein gp120

Ratcliff

Shi

Arts

2013

J Virol

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Maraviroc (MVC) is a CCR5 antagonist that inhibits HIV-1 entry by binding to the coreceptor and inducing structural alterations in the extracellular loops. In this study, we isolated MVC-resistant variants from an HIV-1 primary isolate that arose after 21 weeks of tissue culture passage in the presence of inhibitor. gp120 sequences from passage control and MVC-resistant cultures were cloned into NL4-3 via yeast-based recombination followed by sequencing and drug susceptibility testing. Using 140 clones, three mutations were linked to MVC resistance, but none appeared in the V3 loop as was the case with previous HIV-1 strains resistant to CCR5 antagonists. Rather, resistance was dependent upon a single mutation in the C4 region of gp120. Chimeric clones bearing this N425K mutation replicated at high MVC concentrations and displayed significant shifts in 50% inhibitory concentrations (IC 50 s), characteristic of resistance to all other antiretroviral drugs but not typical of MVC resistance. Previous reports on MVC resistance describe an ability to use a drug-bound form of the receptor, leading to reduction in maximal drug inhibition. In contrast, our structural models on K425 gp120 suggest that this resistant mutation impacts CD4 interactions and highlights a novel pathway for MVC resistance.

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“…Because of down regulation of CD4 by HIV-1, cells actively producing virus are seen as CD4/CD8 double-negative T cells (Kaiser et al 2007). In cell culture HIV-1 infects activated cells with much greater efficiency than quiescent cells (Korin and Zack 1998), with central and effector memory cells as the primary targets (Pfaff et al 2010). However, in vivo there appears to be a type of CD4 þ T cell that does not express surface activation markers but supports significant levels of infection, particularly in the gut mucosa (Veazey et al 2000;Brenchley et al 2004b;Li et al 2005;Mattapallil et al 2005;Mehandru et al 2007).…”

Section: Target Cells T-cell Subsetsmentioning

confidence: 99%

HIV-1 Pathogenesis: The Virus

Swanstrom

Coffin

2012

Cold Spring Harbor Perspectives in Medicine

104

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HIV-1 Resistance to CCR5 Antagonists Associated with Highly Efficient Use of CCR5 and Altered Tropism on Primary CD4 ⁺ T Cells

Cited by 58 publications

References 56 publications

HIV-1 Clinical Isolates Resistant to CCR5 Antagonists Exhibit Delayed Entry Kinetics That Are Corrected in the Presence of Drug

HIV-1 Clinical Isolates Resistant to CCR5 Antagonists Exhibit Delayed Entry Kinetics That Are Corrected in the Presence of Drug

HIV-1 Resistance to Maraviroc Conferred by a CD4 Binding Site Mutation in the Envelope Glycoprotein gp120

HIV-1 Pathogenesis: The Virus

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HIV-1 Resistance to CCR5 Antagonists Associated with Highly Efficient Use of CCR5 and Altered Tropism on Primary CD4 + T Cells

Cited by 58 publications

References 56 publications

HIV-1 Clinical Isolates Resistant to CCR5 Antagonists Exhibit Delayed Entry Kinetics That Are Corrected in the Presence of Drug

HIV-1 Clinical Isolates Resistant to CCR5 Antagonists Exhibit Delayed Entry Kinetics That Are Corrected in the Presence of Drug

HIV-1 Resistance to Maraviroc Conferred by a CD4 Binding Site Mutation in the Envelope Glycoprotein gp120

HIV-1 Pathogenesis: The Virus

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HIV-1 Resistance to CCR5 Antagonists Associated with Highly Efficient Use of CCR5 and Altered Tropism on Primary CD4 ⁺ T Cells