The chemokine receptor, CCR5

The chemokine receptor, CCR5, is a G protein coupled receptor responsible for some of the effects of the chemokines CCL3, CCL4 and CCL5. It is also one of the co-receptors for the entry of human immunodeficiency virus-1 (HIV-1) into cells. Regulation of CCR5 number on cells is, therefore, important for determining the infection rate by HIV-1.     

Rescue of HIV-1 receptor function through cooperation between different forms of the CCR5 chemokine receptor

Interaction of the human immunodeficiency virus (HIV-1) envelope glycoproteins with the CCR5 chemokine receptor, a G-protein-coupled receptor, triggers a membrane fusion process and virus entry. Cooperation for HIV-1 receptor activity was observed when two forms of CCR5 were coexpressed, either the wild-type (WT) receptor and a defective mutant with deletion of the amino-terminal (NT) extracellular domain or the latter deltaNT mutant and a human-mouse CCR5 chimera bearing the NT domain from human CCR5. Cooperation was most efficient when the two forms of CCR5 were in a 1:1 ratio. It was not observed between the CCR5 deltaNT mutant and a chimeric receptor (5444) in which the NT domain of CCR5 was in the context of another G-protein-coupled receptor, the HIV-1 receptor CXCR4. These results suggested that physical association between two forms of CCR5 was required for their cooperation. Coimmunoprecipitation experiments in transfected cell lysates indeed showed that the deltaNT CCR5 mutant formed oligomeric complexes with the WT CCR5 or the HMMM chimera but not with the CXCR4-derived chimera 5444. These observations suggest that the formation of CCR5 oligomers is a constitutive process independent from activation by chemokine ligands. The interaction of HIV-1 with independent subunits of CCR5 oligomers could favor the local recruitment of fusiogenic proteins and the formation of a fusion pore.     

pH-independent endocytic cycling of the chemokine receptor CCR5

Following agonist activation, the chemokine receptor CCR5 is internalised through clathrin-coated pits and delivered to recycling endosomes. Subsequently, ligand- free and resensitised receptors are recycled to the cell surface. Currently little is known of the mechanisms regulating resensitisation and recycling of this G-protein coupled receptor. Here we show that raising the pH of endocytic compartments, using bafilomycin A, monensin or NH(4)Cl, does not significantly affect CCR5 endocytosis, recycling or dephosphorylation. By contrast, these reagents inhibited recycling of another well-characterised G protein coupled receptor, the beta(2)-adrenergic receptor, following agonist-induced internalisation. CCR5-bound RANTES (CCL5) and MIP-1beta (CCL4) only exhibit pH-dependent dissociation at pH < 4.0, below the values normally found in endocytic organelles. Although receptor-agonist dissociation is not dependent on low pH, the subsequent degradation of released chemokine is inhibited in the presence of reagents that raise endosomal pH. Our data show that exposure to low pH is not required for RANTES or MIP-1beta dissociation from CCR5, or for recycling of internalised CCR5 to the cell surface.     

Interaction of soluble CD4 with the chemokine receptor CCR5

The chemokine receptor CCR5 is constitutively associated with the T cell co-receptor CD4 in plasma cell membranes. The CD4-CCR5 complex exhibits distinct binding properties for macrophage inflammatory protein 1beta (MIP-1beta) and enhanced G-protein signaling as compared with those of CCR5 alone. Here we report that recombinant soluble CD4, when refolded into its dimeric form, allosterically modulates CCR5 and decreases the affinity for its natural ligand MIP-1beta. Monomeric soluble CD4 had little inhibitory effect on CCR5. In contrast, the two-domain amino-terminal fragment of soluble CD4 was able to completely inhibit the interaction of CCR5 with MIP-1beta. Thus, we suggest that various conformational states of CD4 exist, which differ markedly with regard to inhibiting the interaction of CCR5 with its ligand MIP-1beta. R5-tropic HIV-1 glycoprotein 120, but not interleukin-16, the natural agonist, or X4-tropic glycoprotein 120, inhibited MIP-1beta binding to CCR5 in the presence of monomeric and dimeric soluble CD4.     

Hypoxia inhibits the expression of the CCR5 chemokine receptor in macrophages

Hypoxia, a decrease in oxygen tension occurring in pathological tissues, has a profound effect on macrophage functions. Here, we provide the first evidence that hypoxia inhibits CCR5 chemokine receptor expression in mouse macrophages. CCR5 was constitutively expressed in macrophages and upregulated by IFNgamma. Hypoxia downregulated both constitutive and IFNgamma-induced CCR5 mRNA and protein. Reoxygenation of hypoxic cells reverted CCR5 inhibition. CCR5 upregulation by IL-10, LPS, and IL-4 was also antagonized by hypoxia. CCR5 inhibition may be a way to retain/concentrate recruited macrophages at hypoxic sites or a feedback mechanism to control the autocrine activation of macrophages which produce CCR5 ligands.     

Sequence evolution of the CCR5 chemokine receptor gene in primates.

The chemokine receptor CCR5 can serve as a coreceptor for M-tropic HIV-1 infection and both M-tropic and T-tropic SIV infection. We sequenced the entire CCR5 gene from 10 nonhuman primates: Pongo pygmaeus, Hylobates leucogenys, Trachypithecus francoisi, Trachypithecus phayrei, Pygathrix nemaeus, Rhinopithecus roxellanae, Rhinopithecus bieti, Rhinopithecus avunculus, Macaca assamensis, and Macaca arctoides. When compared with CCR5 sequences from humans and other primates, our results demonstrate that: (1) nucleotide and amino acid sequences of CCR5 among primates are highly homologous, with variations slightly concentrated on the amino and carboxyl termini; and (2) site Asp13, which is critical for CD4-independent binding of SIV gp120 to Macaca mulatta CCR5, was also present in all other nonhuman primates tested here, suggesting that those nonhuman primate CCR5s might also bind SIV gp120 without the presence of CD4. The topologies of CCR5 gene trees constructed here conflict with the putative opinion that the snub-nosed langurs compose a monophyletic group, suggesting that the CCR5 gene may not be a good genetic marker for low-level phylogenetic analysis. The evolutionary rate of CCR5 was calculated, and our results suggest a slowdown in primates after they diverged from rodents. The synonymous mutation rate of CCR5 in primates is constant, about 1.1 x 10(-9) synonymous mutations per site per year. Comparisons of Ka and Ks suggest that the CCR5 genes have undergone negative or purifying selection. Ka/Ks ratios from cercopithecines and colobines are significantly different, implying that selective pressures have played different roles in the two lineages.     

Evidence for CD4-enchanced signaling through the chemokine receptor CCR5

The chemokine receptor CCR5 is constitutively associated with the T cell co-receptor CD4 in plasma cell membranes, but the physiological role of this interaction has not been elucidated. Here we show that detergent-solubilized, purified CCR5 can directly associate with purified soluble fragments of the extracellular portion of CD4. We further demonstrate that the physical association of CCR5 and CD4 in membrane vesicles results in the formation of a receptor complex that exhibits macrophage inflammatory protein 1beta (MIP-1beta) binding properties that are distinct from CCR5. The affinity of the CD4-CCR5 complex for MIP-1beta was 3.5-fold lower than for CCR5, but the interaction of CD4 and CCR5 resulted in a receptor complex that exhibited enhanced G-protein signaling as compared with CCR5 alone. MIP-1beta-induced G-protein activation was further increased by simultaneous stimulation of CD4 with its natural agonist, interleukin-16. Thus, the physical association of CD4 and CCR5 results in receptor cross-talk with allosteric CD4-dependent regulation of the binding and signaling properties of CCR5. Although the precise physiological role of the CD4 effects on CCR5-mediated signaling remains unknown, one can speculate that the cross-talk is a component of mechanisms involved in the fine tuning of immune system cell responses.     

Mechanisms of internalization and recycling of the chemokine receptor, CCR5.

CCR5 is a G protein-coupled receptor that binds several natural chemokines but it is also a coreceptor for the entry of M tropic strains of HIV-1 into cells. Levels of CCR5 on the cell surface are important for the rate of HIV-1 infection and are determined by a number of factors including the rates of CCR5 internalization and recycling. Here we investigated the involvement of the actin cytoskeleton in the control of ligand-induced internalization and recycling of CCR5. Cytochalasin D, an actin depolymerizing agent, inhibited chemokine-induced internalization of CCR5 and recycling of the receptor in stably transfected CHO cells and in the monocytic cell line, THP-1. CCR5 internalization and recycling were inhibited by Toxin B and C(3) exoenzyme treatment in CHO and THP-1 cells, confirming activation of members of the RhoGTPase family by CCR5. The specific Rho kinase inhibitor Y27632, however, had no effect on CCR5 internalization or recycling. Ligand-induced activation of CCR5 leads to Rho kinase-dependent formation of focal adhesion complexes. These data indicate that CCR5 internalization and recycling are regulated by actin polymerization and activation of small G proteins in a Rho-dependent manner.     

Protein kinase Czeta mediates micro-opioid receptor-induced cross-desensitization of chemokine receptor CCR5

We have previously shown that the μ-opioid receptor (MOR) is capable of mediating cross-desensitization of several chemokine receptors including CCR5, but the biochemical mechanism of this process has not been fully elucidated. We have carried out a series of functional and biochemical studies and found that the mechanism of MOR-induced cross-desensitization of CCR5 involves the activation of PKCζ. Inhibition of PKCζ by its pseudosubstrate inhibitor, or its siRNA, or dominant negative mutants suppresses the cross-desensitization of CCR5. Our results further indicate that the activation of PKCζ is mediated through a pathway involving phosphoinositol-dependent kinase-1 (PDK1). In addition, activation of MOR elevates the phosphorylation level and kinase activity of PKCζ. The phosphorylation of PKCζ can be suppressed by a dominant negative mutant of PDK1. We observed that following MOR activation, the interaction between PKCζ and PDK1 is immediately increased based on the analysis of fluorescent resonance energy transfer in cells with the expression of PKCζ-YFP and PDK1-CFP. In addition, cells expressing PKCζ kinase motif mutants (Lys-281, Thr-410, Thr-560) fail to exhibit full MOR-induced desensitization of CCR5 activity. Taken together, we propose that upon DAMGO treatment, MOR activates PKCζ through a PDK1-dependent signaling pathway to induce CCR5 phosphorylation and desensitization. Because CCR5 is a highly proinflammatory receptor, and a critical coreceptor for HIV-1, these results may provide a novel approach for the development of specific therapeutic agents to treat patients with certain inflammatory diseases or AIDS.     

Allosteric model of maraviroc binding to CC chemokine receptor 5 (CCR5)

Maraviroc is a nonpeptidic small molecule human immunodeficiency virus type 1 (HIV-1) entry inhibitor that has just entered the therapeutic arsenal for the treatment of patients. We recently demonstrated that maraviroc binding to the HIV-1 coreceptor, CC chemokine receptor 5 (CCR5), prevents it from binding the chemokine CCL3 and the viral envelope glycoprotein gp120 by an allosteric mechanism. However, incomplete knowledge of ligand-binding sites and the lack of CCR5 crystal structures have hampered an in-depth molecular understanding of how the inhibitor works. Here, we addressed these issues by combining site-directed mutagenesis (SDM) with homology modeling and docking. Six crystal structures of G-protein-coupled receptors were compared for their suitability for CCR5 modeling. All CCR5 models had equally good geometry, but that built from the recently reported dimeric structure of the other HIV-1 coreceptor CXCR4 bound to the peptide CVX15 (Protein Data Bank code 3OE0) best agreed with the SDM data and discriminated CCR5 from non-CCR5 binders in a virtual screening approach. SDM and automated docking predicted that maraviroc inserts deeply in CCR5 transmembrane cavity where it can occupy three different binding sites, whereas CCL3 and gp120 lie on distinct yet overlapped regions of the CCR5 extracellular loop 2. Data suggesting that the transmembrane cavity remains accessible for maraviroc in CCL3-bound and gp120-bound CCR5 help explain our previous observation that the inhibitor enhances dissociation of preformed ligand-CCR5 complexes. Finally, we identified residues in the predicted CCR5 dimer interface that are mandatory for gp120 binding, suggesting that receptor dimerization might represent a target for new CCR5 entry inhibitors.     

Identification of chemokine receptor CCR4 antagonist

The present study reports the identification and hits to leads optimization of chemokine receptor CCR4 antagonists. Compound 12 is a high affinity, non-cytotoxic antagonist of CCR4 that blocks the functional activity mediated by the receptor.     

Gene conversion between mammalian CCR2 and CCR5 chemokine receptor genes: a potential mechanism for receptor dimerization

The chemokine receptor genes of the CCR cluster on human chromosome 3p21 play important roles in humoral and cellular immune responses. Several of these receptors have been shown to influence human immunodeficiency virus infection and progression to AIDS, and their homologues may play a role in feline immunodeficiency virus infection. We report the isolation and sequencing of a 150-kb domestic cat BAC clone containing the feline CCR genes CCR1, CCR2, CCR3, and CCR5 to further analyze these four receptor genes within the family Felidae. Comparative and phylogenetic analyses reveal evidence for historic gene conversion between the adjacent CCR2 and CCR5 genes in the Felidae and in three independent mammalian orders (Primates, Cetartiodactyla, and Rodentia), resulting in higher than expected levels of sequence similarity between the two paralogous genes within each order. The gene conversion was restricted to the structural (transmembrane) domains of the CCR2 and CCR5 genes. We also discovered a recent gene conversion event between the third extracellular loop of CCR2 and CCR5 genes that was fixed in Asian lions and found at low frequency in African lions (Panthera leo), suggesting that this domain may have an important functional role. Our results suggest that ongoing parallel gene conversion between CCR2 and CCR5 promotes receptor heterodimerization in independent evolutionary lineages and offers an effective adaptive strategy for gene editing and coevolution among interactive immune response genes in mammals.     

Exploration of bivalent ligands targeting putative mu opioid receptor and chemokine receptor CCR5 dimerization

Modern antiretroviral therapies have provided HIV-1 infected patients longer lifespans and better quality of life. However, several neurological complications are now being seen in these patients due to HIV-1 associated injury of neurons by infected microglia and astrocytes. In addition, these effects can be further exacerbated with opiate use and abuse. One possible mechanism for such potentiation effects of opiates is the interaction of the mu opioid receptor (MOR) with the chemokine receptor CCR5 (CCR5), a known HIV-1 co-receptor, to form MOR–CCR5 heterodimer. In an attempt to understand this putative interaction and its relevance to neuroAIDS, we designed and synthesized a series of bivalent ligands targeting the putative CCR5–MOR heterodimer. To understand how these bivalent ligands may interact with the heterodimer, biological studies including calcium mobilization inhibition, binding affinity, HIV-1 invasion, and cell fusion assays were applied. In particular, HIV-1 infection assays using human peripheral blood mononuclear cells, macrophages, and astrocytes revealed a notable synergy in activity for one particular bivalent ligand. Further, a molecular model of the putative CCR5–MOR heterodimer was constructed, docked with the bivalent ligand, and molecular dynamics simulations of the complex was performed in a membrane-water system to help understand the biological observation.     

Phenolic derivatives from Wigandia urens with weak activity against the chemokine receptor CCR5

Three compounds, 2,3-dihydroxy-4-methoxy-6,6,9-trimethyl-6H-dibenzo[b,d]pyran (1), 8-methoxy-2-methyl-2-(4-methyl-3-pentenyl)-2H-1-benzopyran-6-ol (2) and 4-methoxy-3-(3-methyl-2-butenyl)-benzoic acid (3), have been isolated from Wigandia urens. The structures of compounds 1, 2 and 3 were determined from spectroscopic data and showed activity in a CCR5 assay with IC(50) values of 33, 46 and 26 muM respectively.     

Rationale of using the dual chemokine receptor CCR2/CCR5 inhibitor cenicriviroc for the treatment of COVID-19

Coronavirus Disease 2019 (COVID-19), caused by Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2), has created a global pandemic infecting over 230 million people and costing millions of lives. Therapies to attenuate severe disease are desperately needed. Cenicriviroc (CVC), a C-C chemokine receptor type 5 (CCR5) and C-C chemokine receptor type 2 (CCR2) antagonist, an agent previously studied in advanced clinical trials for patients with HIV or nonalcoholic steatohepatitis (NASH), may have the potential to reduce respiratory and cardiovascular organ failures related to COVID-19. Inhibiting the CCR2 and CCR5 pathways could attenuate or prevent inflammation or fibrosis in both early and late stages of the disease and improve outcomes of COVID-19. Clinical trials using CVC either in addition to standard of care (SoC; e.g., dexamethasone) or in combination with other investigational agents in patients with COVID-19 are currently ongoing. These trials intend to leverage the anti-inflammatory actions of CVC for ameliorating the clinical course of COVID-19 and prevent complications. This article reviews the literature surrounding the CCR2 and CCR5 pathways, their proposed role in COVID-19, and the potential role of CVC to improve outcomes.     

4,4-Disubstituted cyclohexylamine based CCR5 chemokine receptor antagonists as anti-HIV-1 agents

A series of 4,4-disubstituted cyclohexylamine based CCR5 antagonists has been designed and synthesized. Their antiviral structure–activity relationship has been extensively explored.     

Structure modeling of the chemokine receptor CCR5: implications for ligand binding and selectivity

The G-protein coupled receptor CCR5 is the main co-receptor for macrophage-tropic HIV-1 strains. I have built a structural model of the chemokine receptor CCR5 and used it to explain the binding and selectivity of the antagonist TAK779. Models of the extracellular (EC) domains of CCR5 have been constructed and used to rationalize current biological data on the binding of HIV-1 and chemokines. Residues spanning the transmembrane region of CCR5 have been modeled after rhodopsin, and their functional significance examined using the evolutionary trace method. The receptor cavity shares six residues with CC-chemokine receptors CCR1 through CCR4, while seven residues are unique to CCR5. The contribution of these residues to ligand binding and selectivity is tested by molecular docking simulations of TAK779 to CCR1, CCR2, and CCR5. TAK779 binds to CCR5 in the cavity formed by helices 1, 2, 3, and 7 with additional interactions with helices 5 and 6. TAK779 did not dock to either CCR1 or CCR2. The results are consistent with current site-directed mutagenesis data and with the observed selectivity of TAK779 for CCR5 over CCR1 and CCR2. The specific residues responsible for the observed selectivity are identified. The four EC regions of CCR5 have been modeled using constrained simulated annealing simulations. Applied dihedral angle constraints are representative of the secondary structure propensities of these regions. Tertiary interactions, in the form of distance constraints, are generated from available epitope mapping data. Analysis of the 250 simulated structures provides new insights to the design of experiments aimed at determining residue-residue contacts across the EC domains and for mapping CC-chemokines on the surface of the EC domains.     

Heterodimerization is mainly responsible for the dominant negative activity of amino-terminally truncated rat androgen receptor forms

Rat androgen receptor (rAR) mutants devoid of the amino-terminal transactivation domain are able to behave as dominant negative regulators of wild-type rAR. To address the underlying mechanisms of the trans-dominant negative action, we have examined the roles of the DNA-binding domain (DBD) and the ligand-binding domain (LBD) in this process. Transactivation experiments in CV-1 cells complemented by electrophoretic mobility shift assays revealed that the dominant negative receptor forms repress the function of wild-type rAR mainly through heterodimer formation, rather than through competition for binding to cognate DNA elements. Heterodimerization of receptor forms containing LBDs may take place even in the absence of specific DNA binding.