Cooperation of Multiple CCR5 Coreceptors Is Required for Infections by Human Immunodeficiency Virus Type 1

105

The HIV envelope (Env) protein mediates entry into cells by binding CD4 and an appropriate coreceptor, which triggers structural changes in Env that lead to fusion between the viral and cellular membranes. The major HIV-1 coreceptors are the seven transmembrane domain chemokine receptors CCR5 and CXCR4. The type of coreceptor used by a virus strain is an important determinant of viral tropism and pathogenesis, and virus-receptor interactions can be therapeutic targets. However, Envs from many virus strains interact with CXCR4 and CCR5 with low affinity such that direct study of this important interaction is difficult if not impossible using standard cell-surface binding techniques. We have developed an approach that makes it possible to study ligand binding to membrane proteins, including Env-coreceptor interactions, using an optical biosensor. CCR5, CXCR4, and other membrane proteins were incorporated into retrovirus particles, which were purified and attached to the biosensor surface. Binding of conformationally sensitive antibodies as well as Env to these receptors was readily detected. The equilibrium dissociation constant for the interaction between an Env derived from the prototype HIV-1 strain IIIB for CXCR4 was approximately 500 nM, explaining the difficulty in measuring this interaction using standard equilibrium binding techniques. Retroviral pseudotypes represent easily produced, stable, homogenous structures that can be used to present a wide array of single and multiple membrane-spanning proteins in a native lipid environment for biosensor studies, thus avoiding the need for detergent solubilization, purification, and reconstitution. The approach should have general applicability and can be used to correlate Env-receptor binding constants to viral tropism and pathogenesis.

Section: Discussionsupporting

confidence: 79%

A biosensor assay for studying ligand-membrane receptor interactions: Binding of antibodies and HIV-1 Env to chemokine receptors

Hoffman

Canziani

et al. 2000

105

“…Numerous experimental variables may contribute to complementation efficiency, including the surface densities of each of the participating proteins, the binding affinities between gp120 and each receptor, the efficiencies of subunit interactions, etc. The findings of constitutive interactions between CD4 and coreceptors may have significance in this regard (14,31), as may the recent proposal that cooperative interactions involving multiple CCR5 molecules are required for the HIV-1 infection pathway (32). Also of note is that certain complementation effects were not uniformly noted; for example, LAV-BS complemented SF162 wild type for fusion with CXCR4-expressing targets cells (Fig.…”

Section: Discussionmentioning

confidence: 88%

Cooperative subunit interactions within the oligomeric envelope glycoprotein of HIV-1: Functional complementation of specific defects in gp120 and gp41

Salzwedel

Berger

2000

The envelope glycoprotein (Env) of HIV-1 is displayed on the surface of the virion or infected cell as an oligomer of multiple gp120͞gp41 complexes. We sought to unravel the relationships between this oligomeric structure and the requirements for sequential interactions with CD4 and coreceptor (CCR5 or CXCR4). We used a quantitative cell fusion assay to examine the effects of coexpressing pairs of Envs, each nonfunctional because of a specific defect in one of the essential properties. We observed efficient fusion activity upon coexpression of two Env variants, one containing a gp41 subunit with a mutated fusion peptide and the other containing a gp120 subunit with a mutated CD4 binding site or a mismatched coreceptor specificity. We also observed fusion upon coexpression of two Env variants with distinct gp120 defects, i.e., a CD4 binding site mutation and the incorrect coreceptor specificity determinants. Coimmunoprecipitation experiments verified the efficient formation of mixed oligomers, suggesting that the observed fusion reflected subunit complementation within the oligomeric complex. These results support a model in which cooperative subunit interactions within the Env oligomer result in concerted conformational changes upon receptor binding, resulting in activation for fusion. The implications of these findings for Env function and virus neutralization are discussed.T he envelope glycoprotein (Env) of HIV-1 mediates virus entry into target cells by catalyzing a complex series of receptor-binding events and associated conformational changes that result ultimately in fusion between the membranes of the virion and target cell. The biochemical outline of the fusion reaction has been established (reviewed in refs. 1-4). The external gp120 subunit must bind to two distinct receptors on the target cell: CD4 (the ''primary receptor'') and a specific chemokine receptor (the coreceptor, usually CCR5 or CXCR4). These receptor interactions trigger the transmembrane gp41 subunit to promote fusion via a process that is presumed to involve insertion of its N-terminal fusion peptide into the membrane of the target cell. A specific sequence of receptor interactions is required to activate the fusion reaction, as revealed by binding analyses with soluble gp120 (5-7), fusion and infectivity experiments with soluble CD4 (8, 9), high-resolution x-ray crystallographic structural determinations (10), and sitedirected mutagenesis studies (11). In the favored model, CD4 binding exposes, creates, or stabilizes the coreceptor binding determinants on gp120; interaction with coreceptor triggers additional conformational changes, leading to gp41 activation and consequent fusion.Env is first synthesized as a high molecular weight precursor designated gp160. The protein forms a homo-oligomer in the endoplasmic reticulum and is transported to the Golgi apparatus where processing by a host cell protease(s) occurs; the functional Env on the surface of both the infected cell and the virion is a homo-oligomer of multiple gp120͞gp41 noncova...

“…It is thought that HIV requires the engagement of several (about four to six) CCR5 molecules to form a fusion pore (31). We postulate that RAPA reduction of CCR5 density could prevent R5 HIV virions from engaging a minimum number of CCR5s required for effective fusion.…”

Section: Discussionmentioning

confidence: 99%

Reduction of CCR5 with low-dose rapamycin enhances the antiviral activity of vicriviroc against both sensitive and drug-resistant HIV-1

Heredia

Latinovic

Gallo

et al. 2008

Vicriviroc (VCV) is a chemokine (C-C motif) receptor 5 (CCR5)antagonist with potent anti-HIV activity that currently is being evaluated in phase III clinical trials. In the present study, donor CCR5 density (CCR5 receptors/CD4 lymphocytes) inversely correlated with VCV antiviral activity (Spearman's correlation test; r ‫؍‬ 0.746, P ‫؍‬ 0.0034). Low doses of the transplant drug rapamycin (RAPA) reduced CCR5 density and enhanced VCV antiviral activity. In drug interaction studies, the RAPA/VCV combination had considerable antiviral synergy (combination indexes of 0.1-0.04) in both multicycle and single-cycle infection of lymphocytes. The synergy between RAPA and VCV translated into dose reduction indexes of 8-to 41-fold reductions for RAPA and 19-to 658-fold reductions for VCV. RAPA enhanced VCV antiviral activity against both B and non-B clade isolates, potently suppressing clade G viruses with reported reduced sensitivities to VCV and to the licensed CCR5 antagonist maraviroc. Importantly, RAPA reduction of CCR5 density in lymphocytes sensitized VCV-resistant strains to VCV, inhibiting virus production by ϳ 90%. We further demonstrated the role of CCR5 density on VCV activity against resistant virus in donor lymphocytes and in cell lines expressing varying CCR5 densities. Together, these results suggest that low doses of RAPA may increase the durability of VCV-containing regimens in patients by enhancing VCV viral suppression, by allowing the use of lower doses of VCV with reduced potential for toxicity, and by controlling emerging VCV-resistant variants.chemokine receptor 5 antagonists ͉ coreceptor density ͉ HIV resistance ͉ vicriviroc resistance ͉ maraviroc H ighly active antiretroviral therapy (HAART) has improved treatment of HIV-1 infected individuals considerably (1). However, the success of current therapies is limited by the emergence of drug-resistant strains, the need for sustained adherence to complex regimens, and the potential for drug toxicity (2, 3). The two new antiretroviral classes of integrase and entry inhibitors may help overcome some of the current limitations of HAART (4, 5). Entry inhibitors are especially attractive because they target HIV at the earliest step of the viral cycle and are effective against strains resistant to inhibitors of protease and reverse transcriptase. Entry inhibitors interfere with HIV binding to CD4 receptor (attachment inhibitors) or chemokine (C-C motif) receptor 5 (CCR5)/chemokine (C-X-C-motif) receptor 4 (CXCR4) coreceptors (coreceptor antagonists) or by preventing fusion between cellular and viral membranes (fusion inhibitors) (5). Currently, the fusion inhibitor T-20 (enfuvirtide) and the CCR5 antagonist maraviroc (Selzentry) are the only licensed entry inhibitors (6, 7). The CCR5 antagonist vicriviroc (VCV) presently is in phase III clinical trials (8). Coreceptor CCR5 antagonists inhibit CCR5-tropic HIV-1 (referred to as ''R5 HIV-1'') strains, which are responsible for most transmissions and generally are present throughout the course of infection. In nor...