Structural and Molecular Interactions of CCR5 Inhibitors with CCR5

Maeda, Kenji; Das, Debananda; Ogata-Aoki, Hiromi; Nakata, Hirotomo; Miyakawa, Taihei; Tojo, Yasushi; Norman, Rachael; Takaoka, Yousuke; Ding, Jianping; Arnold, Gail Ferstandig; Arnold, Eddy; Mitsuya, Hiroaki

doi:10.1074/jbc.m512688200

Cited by 151 publications

(202 citation statements)

References 34 publications

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“…This resistance pathway often, but not always, results in a virus that is resistant to multiple CCR5 antagonists (22,33,39,53,56). The CCR5 antagonists that have been used clinically all seem to bind to a hydrophobic region in the transmembrane helices of CCR5 and induce conformational alterations in the extracellular domains of the coreceptor that inhibit recognition by gp120 (13,31,32,46,52). These conformational alterations are similar though not identical as judged by the ability of these compounds to affect the binding of various conformation-dependent monoclonal antibodies to CCR5.…”

Section: Discussionmentioning

confidence: 99%

“…Interactions between gp120 and CCR5 occur in at least two distinct areas: (i) the bridging sheet and the stem of the V3 loop interact with sulfated tyrosine residues in the NЈ terminus of CCR5, and (ii) the crown of the V3 loop is thought to engage the extracellular loops (ECLs), particularly ECL2, of CCR5 (10-12, 14, 18, 28). Small-molecule CCR5 antagonists bind to a hydrophobic pocket in the transmembrane helices of CCR5 and exert their effects on HIV by altering the position of the ECLs, making them allosteric inhibitors of HIV infection (13,31,32,46,52). The conformational changes in CCR5 that are induced by CCR5 antagonists vary to some degree with different drugs, as evidenced by differential binding of antibodies and chemokines to various drug-bound forms of CCR5 (47,54).…”

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confidence: 99%

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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

Pfaff

Wilen

Harrison

et al. 2010

J Virol

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We previously reported on a panel of HIV-1 clade B envelope (Env) proteins isolated from a patient treated with the CCR5 antagonist aplaviroc (APL) that were drug resistant. These Envs used the APL-bound conformation of CCR5, were cross resistant to other small-molecule CCR5 antagonists, and were isolated from the patient's pretreatment viral quasispecies as well as after therapy. We analyzed viral and host determinants of resistance and their effects on viral tropism on primary CD4 ؉ T cells. The V3 loop contained residues essential for viral resistance to APL, while additional mutations in gp120 and gp41 modulated the magnitude of drug resistance. However, these mutations were context dependent, being unable to confer resistance when introduced into a heterologous virus. The resistant virus displayed altered binding between gp120 and CCR5 such that the virus became critically dependent on the N terminus of CCR5 in the presence of APL. In addition, the drug-resistant Envs studied here utilized CCR5 very efficiently: robust virus infection occurred even when very low levels of CCR5 were expressed. However, recognition of drug-bound CCR5 was less efficient, resulting in a Entry of human immunodeficiency virus (HIV) into target cells is a complex, multistep process that is initiated by interactions between the viral envelope (Env) protein gp120 and the host cell receptor CD4, which trigger conformational changes in gp120 that form and orient the coreceptor binding site (9,24). Upon binding to coreceptor, which is either CCR5 or CXCR4 for primary HIV isolates, Env undergoes further conformational changes resulting in insertion of the gp41 fusion peptide into the host cell membrane and gp41-mediated membrane fusion (8,15,26). Targeting stages of the HIV entry process with antiretroviral drugs is a productive method of inhibiting HIV replication, as demonstrated by the potent antiviral effects of small-molecule CCR5 antagonists and fusion inhibitors (23,35,49). As with other antiretroviral drugs, HIV can develop resistance to entry inhibitors, and a detailed understanding of viral and host determinants of resistance will be critical to the optimal clinical use of these agents.The coreceptor binding site that is induced by CD4 engagement consists of noncontiguous regions in the bridging sheet and V3 loop of gp120 (4,18,42,43,50). Interactions between gp120 and CCR5 occur in at least two distinct areas: (i) the bridging sheet and the stem of the V3 loop interact with sul-

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

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

Pfaff

Wilen

Harrison

et al. 2010

J Virol

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“…Similar to aplaviroc, SCH-C formed a hydrogen bond with Glu283 through its oxime-hydroxyl group, which could explain the dramatic loss of binding affinity when Glu283 was mutated to alanine. 16 The other terminal oxygen atom of Glu283 formed two intramolecular hydrogen bonds to the hydroxyl groups of Thr177 and Tyr108, respectively. The oxime-piperidine ring of the inhibitor fitted into a hydrophobic pocket created by the side chains of Glu172 and Arg274 that formed a salt link between each other.…”

Section: Binding Modes Of Aplaviroc and Sch-c With Ccr5mentioning

confidence: 99%

Binding modes of CCR5-targetting HIV entry inhibitors: Partial and full antagonists

Wang¹,

Duan²

2008

Journal of Molecular Graphics and Modelling

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Since the CC-chemokine receptor 5 (CCR5) was identified as a major coreceptor for human immunodeficiency virus type 1 (HIV-1) entry into a host cell, CCR5-targetting HIV entry inhibitors have been developed and some of them are currently in clinical trials. Most of these inhibitors also inhibit the physiological chemokine reaction function of CCR5, which is so far considered to be safe to patients based on the observation that individuals that naturally lack CCR5 do not show apparent health problems. Nevertheless, to minimize the toxicity and side effects, it would be ideal to preserve the chemokine receptor activity. In this work, we simulated the flexible docking of two small molecule inhibitors to CCR5 in a solvated phospholipid bilayer environment. One of the inhibitors, aplaviroc has a unique feature of preserving two of the natural chemokine ligands binding to CCR5 and subsequent activation whereas the other one, SCH-C fully blocks chemokine-CCR5 interactions. Our results revealed significantly different binding modes of these two inhibitors although both established extensive interaction networks with CCR5. Comparison of the different binding modes suggests that avoiding the deep insertion of inhibitors into the transmembrane helix bundle may be able to preserve chemokine-CCR5 interactions. These results could help design HIV coreceptor activity-specific inhibitors.

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“…[13][14][15][16] The binding site for most, if not all, CCR5 antagonists appears to be a lipophilic pocket near the interface of the extracellular loops (ECLs) and transmembrane helices of CCR5. 17,18 CCR5 antagonists are believed to exert their antiviral effects by altering the conformation of CCR5 rather than by directly competing with the HIV envelope glycoprotein (Env) for binding to the coreceptor, making them allosteric inhibitors. 19 With the recent approval of maraviroc for the treatment of HIV infection, it will be important to determine viral and host factors that influence the efficacy of these agents.…”

Section: Introductionmentioning

confidence: 99%

HIV Type 1 from a Patient with Baseline Resistance to CCR5 Antagonists Uses Drug-Bound Receptor for Entry

Tilton

Amrine-Madsen

Miamidian

et al. 2010

AIDS Research and Human Retroviruses

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CCR5 antagonists are a new class of antiretroviral drugs that block viral entry by disrupting interactions between the viral envelope (Env) glycoprotein and coreceptor. During the CCR100136 (EPIC) Phase IIb study of the CCR5 antagonist aplaviroc (APL) in treatment-naive individuals, a patient was identified who harbored virus strains that exhibited partial resistance to APL at the time of virologic failure. Retrospectively, it was found that APL resistance was present at baseline as well. To investigate the mechanism of APL resistance in this patient, we cloned HIV-1 env genes from plasma obtained at baseline and after virologic failure. Approximately 85% of cloned Envs were functional, and all exhibited partial resistance to APL. All Envs were R5-tropic, were partially resistant to other CCR5 antagonists including maraviroc on cells with high CCR5 expression, but remained sensitive to the fusion inhibitor enfuvirtide. Competition studies with natural CCR5 ligands revealed that the mechanism of drug resistance entailed the use of the drug-bound conformation of CCR5 by the Env proteins obtained from this individual. The degree of drug resistance varied between Env clones, and also varied depending on the cell line used or the donor from whom the primary T cells were obtained. Thus, both virus and host factors contribute to CCR5 antagonist resistance. This study shows that R5 HIV-1 strains resistant to CCR5 inhibitors can arise in patients, confirming a mechanism of resistance previously characterized in vitro. In addition, some patients can harbor CCR5 antagonist-resistant viruses prior to treatment, which may have implications for the clinical use of this new class of antiretrovirals.

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Structural and Molecular Interactions of CCR5 Inhibitors with CCR5

Cited by 151 publications

References 34 publications

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

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

Binding modes of CCR5-targetting HIV entry inhibitors: Partial and full antagonists

HIV Type 1 from a Patient with Baseline Resistance to CCR5 Antagonists Uses Drug-Bound Receptor for Entry

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Structural and Molecular Interactions of CCR5 Inhibitors with CCR5

Cited by 151 publications

References 34 publications

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

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

Binding modes of CCR5-targetting HIV entry inhibitors: Partial and full antagonists

HIV Type 1 from a Patient with Baseline Resistance to CCR5 Antagonists Uses Drug-Bound Receptor for Entry

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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

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