趋化因子受体 CCR5 亲合短肽的筛选

趋化因子受体 5 (CCR5) 是 HIV-1 与宿主细胞结合的辅助因子之一,其功能缺失或被 CCR5 拮抗剂封闭则会阻止 HIV-1 感染细胞 . 为得到与 CCR5 特异结合的肽类拮抗剂,采用噬菌体展示技术,以稳定表达 CCR5 的 CHO 细胞 (CHO/CCR5) 作为靶标,通过噬菌体随机 12 肽库筛选与 CCR5 特异结合的多肽;经过四轮筛选后,挑选 20 个阳性噬菌体克隆进行测序,从中得到 11 个含有 AFDWTFVPSLIL 序列的小分子肽 . 含该序列的噬菌体能与抗人 CCR5 单抗 (2D7) 竞争性结合 CCR5 ,且合成肽 AFDWTFVPSLIL 对趋化因子 RANTES 与 CHO/CCR5 的结合具有明显的抑制作用,初步证明该小肽与 CCR5 具有特异性结合作用 .     

RANTES衍生物与HIV-1进入抑制剂

HIV-1-1进入抑制剂的研究是近年来艾滋病药物研发领域的新热点,其中最受关注的是以CCR5为靶点的新药研发。CCR5是病毒进入细胞的主要辅助受体,在HIV-1进入宿主细胞过程中起着非常重要的作用。作为CCR5的天然配体,CC类的趋化因子RANTES、MIP-1α和MIP-1β都是极具潜力的HIV-1抑制剂,特别是有关对RANTES的定向设计的研究尤为引人关注,其目的是设计出一种既有很强的抗病毒能力而又不引发炎症反应的HIV-1拮抗剂。就RANTES衍生物应用于抑制HIV进入细胞方面的研究进行了综述。     

基于趋化因子受体5靶点的HIV-1治疗研究进展

随着人类免疫缺陷病毒(HIV-1)感染在全球的蔓延及耐药株的出现,寻求有效的治疗方法成为当务之急。趋化因子受体5(Chemokine receptor 5,CCR5)是HIV-1侵入靶细胞的主要辅助受体之一。目前已发现许多CCR5拮抗剂,其中一些化合物已进入临床试验或应用;以CCR5为靶点的基因治疗亦取得了一定的进展。本综述以CCR5为靶点的药物和基因治疗两方面的研究进展进行总结。     

细胞内表达CCR5Delta32蛋白对HIV-1感染抑制作用的研究

人CCR5Delta32突变个体能有效抵制HIV-1感染,主要是由于该个体淋巴细胞内表达的CCR5Delta32突变蛋白能通过反式显性失活效应(TDN)抑制细胞表面HIV-1辅受体CCR5和CXCR4的产生．通过构建CCR5Delta32慢病毒载体,体外转染人外周血单个核细胞(PBMCs),研究细胞内表达CCR5Delta32蛋白对HIV-1感染的抑制作用．结果表明,表达CCR5Delta32蛋白的人PBMCs对HIV-1 R5、X4及R5X4毒株感染均具有显著的抑制作用．这些工作为后续的AIDS基因治疗研究奠定了基础．     

MCP-1及其在相关疾病中的治疗措施

单核细胞趋化蛋白1(MCP-1)属于趋化因子的CC亚家族,MCP-1与其受体CCR2相结合,参与了多种炎性疾病的发生。该从抑制MCP-1的表达、MCP-1的拮抗剂、CCR2的拮抗剂、DNA疫苗几方面综述了针对MCP-1的治疗措施。     

人RANTES基因克隆及其体外表达

1995年,Cocchi等[1]发现RANTES、MIP-1α和MIP-1β等β-趋化因子具有抗HIV-1感染活性.1997年,Feng等[2]和Deng等[3]证实β-趋化因子受体CXCR4和CCR5分别是HIV-1侵染T淋巴细胞和巨噬细胞的辅助受体(co-receptor).T淋巴细胞嗜性(T-tropism)分离株被称为X4毒株,巨噬细胞嗜性(M-tropism)分离株则被称为R5毒株[4].RANTES与CCR5有着高度的亲和力,二者的结合可对HIV-1的细胞附着产生空间位阻效应,并下调CCR5在细胞表面的表达.这一结果使RANTES抗HIV-1感染机制在分子水平上得到合理的解释.最近,Garzino-Demo等[5]证明,β-趋化因子的诱导分泌与HIV-1感染后疾病进程的控制有着密切的关系,而且人群中β-趋化因子水平存在着显著的个体差异,表明β-趋化因子对艾滋病具有潜在的预防和治疗价值.为此,我们在克隆人RAN-TES基因的基础上,在体外转录与翻译系统中实现了该基因的表达,有利于今后进一步开展艾滋病的基因治疗.     

趋化因子共受体在1型人免疫缺陷病毒感染中的作用

1型人免疫缺陷病毒(HIV-1)感染靶细胞是一个包含病毒膜蛋白和细胞膜受体相互作用的多极化过程,CCR5和CXCR4作为趋化因子受体参与这一过程,并且是M嗜性和T嗜性HIV-1感染的重要共受体。文章总结了作者在HIV-1共受体方面的工作,对趋化因子受体作为新的治疗HIV-1感染的工具的最新进展做了简要综述。     

小鼠CCR5基因在活体内表达受迟发型超敏反应的调节

趋化因子(chemokine)在机体的免疫监视和慢性炎症反应中起着重要作用。β-趋化因子受体5(CCR5)是巨噬细胞嗜性(M-tropic)HIV-1进入靶细胞的一个重要辅助因子。作用在成功克隆一新的趋化因子受体5(muCCR5)中研究了该基因在小鼠活体内的表达。结果表明,muCCR5 cDNA全长2888 bp,ORF为     

病毒性趋化因子vMIP2的表达、纯化及生物活性研究

趋化因子受体如CCR5和CXCR4是HIV侵入细胞的辅助受体,趋化因子与其受体的结合可以抑制HIV感染细胞.近年来在疱疹病毒8(Human herpesvirus 8, HHV8)基因组中发现与人趋化因子有较高同源性的开放阅读框,分别命名为vMIP1、vMIP2和vMIP3.研究发现vMIP2与多种人趋化因子受体有高亲和力.本研究在大肠杆菌中表达出融合蛋白TrxA- vMIP2,用亲和层析的方法对其纯化.纯化产物用肠激酶酶切后,经离子交换层析纯化出目的蛋白vMIP2.体外活性研究表明纯化的vMIP2 可以有效地抑制R5和X4 HIV-1在人外周血单核细胞上的复制.     

The seventh transmembrane domain of cc chemokine receptor 5 is critical for MIP-1beta binding and receptor activation: role of MET 287

CC chemokine receptor 5 (CCR5) is a high-affinity receptor for macrophage inflammatory protein (MIP)-1beta and functions as the major coreceptor for entry of macrophage-tropic (M-tropic) human immunodeficiency virus type 1 (HIV-1). To evaluate the role of transmembrane domains (TM) in the receptor function of CCR5, the seventh transmembrane domain (TM7) was examined in a series of chimeric receptor constructs including CCR5TM (CCR5 backbone/CCR5 TM7 replaced with CCR1 TM7) and mutants of CCR5TM. The CCR5TM chimera exhibited a dramatic reduction in receptor activation, as well as little or no MIP-1beta binding. Further mutational analysis revealed that Met 287 in TM7 of CCR5 is a critical molecular determinant for both MIP-1beta binding and receptor activation. Interestingly, all of the chimeric/mutated receptors were biologically active in an HIV-1 coreceptor fusion assay, demonstrating that chemokine binding is independent of HIV-1 coreceptor activity.     

Donor- and ligand-dependent differences in C-C chemokine receptor 5 reexpression

N-terminal modifications of the chemokine RANTES bind to C-C chemokine receptor 5 (CCR5) and block human immunodeficiency virus type 1 (HIV-1) infection with greater efficacy than native RANTES. Modified RANTES compounds induce rapid CCR5 internalization and much slower receptor reexpression than native RANTES, suggesting that receptor sequestration is one mode of anti-HIV activity. The rates of CCR5 internalization and reexpression were compared using the potent n-nonanoyl (NNY)-RANTES derivative and CD4(+) T cells derived from donors with different CCR5 gene polymorphisms. NNY-RANTES caused even more rapid receptor internalization and slower reexpression than aminooxypentane (AOP)-RANTES. Polymorphisms in the promoter and coding regions of CCR5 significantly affected the receptor reexpression rate after exposure of cells to NNY-RANTES. These observations may be relevant for understanding the protective effects of different CCR5 genotypes against HIV-1 disease progression.     

Structural basis for the interaction of CCR5 with a small molecule, functionally selective CCR5 agonist

The chemokine receptor CCR5 is an attractive target for HIV-1 drug development, as individuals whose cells lack surface CCR5 expression are highly resistant to HIV-1 infection. CCR5 ligands, such as CCL5/RANTES, effectively inhibit HIV-1 infection by competing for binding opportunities to the CCR5 and inducing its internalization. However, the inherent proinflammatory activity of the chemotactic response of CCR5 ligands has limited their clinical use. In this study, we found that a novel small molecule, functionally selective CCR5 agonist, 2,2-dichloro-1-(triphenylphosphonio)vinyl formamide perchlorate (YM-370749), down-modulates CCR5 from the cell surface without inducing a chemotactic response and inhibits HIV-1 replication. In molecular docking studies of YM-370749 and a three-dimensional model of CCR5 based on the rhodopsin crystal structure as well as binding and functional studies using various CCR5 mutants, the amino acid residues necessary for interaction with YM-370749 were marked. These results provide a structural basis for understanding the activation mechanism of CCR5 and for designing functionally selective agonists as a novel class of anti-HIV-1 agents.     

Molecular Recognition of CCR5 by an HIV-1 gp120 V3 Loop

The binding of protein HIV-1 gp120 to coreceptors CCR5 or CXCR4 is a key step of the HIV-1 entry to the host cell, and is predominantly mediated through the V3 loop fragment of HIV-1 gp120. In the present work, we delineate the molecular recognition of chemokine receptor CCR5 by a dual tropic HIV-1 gp120 V3 loop, using a comprehensive set of computational tools predominantly based on molecular dynamics simulations and free energy calculations. We report, what is to our knowledge, the first complete HIV-1 gp120 V3 loop : CCR5 complex structure, which includes the whole V3 loop and the N-terminus of CCR5, and exhibits exceptional agreement with previous experimental findings. The computationally derived structure sheds light into the functional role of HIV-1 gp120 V3 loop and CCR5 residues associated with the HIV-1 coreceptor activity, and provides insights into the HIV-1 coreceptor selectivity and the blocking mechanism of HIV-1 gp120 by maraviroc. By comparing the binding of the specific dual tropic HIV-1 gp120 V3 loop with CCR5 and CXCR4, we observe that the HIV-1 gp120 V3 loop residues 13–21, which include the tip, share nearly identical structural and energetic properties in complex with both coreceptors. This result paves the way for the design of dual CCR5/CXCR4 targeted peptides as novel potential anti-AIDS therapeutics.     

Envelope glycoproteins from human immunodeficiency virus types 1 and 2 and simian immunodeficiency virus can use human CCR5 as a coreceptor for viral entry and make direct CD4-dependent interactions with this chemokine receptor.

Several members of the chemokine receptor family have recently been identified as coreceptors, with CD4, for entry of human immunodeficiency virus type 1 (HIV-1) into target cells. In this report, we show that the envelope glycoproteins of several strains of HIV-2 and simian immunodeficiency virus (SIV) employ the same chemokine receptors for infection. Envelope glycoproteins from HIV-2 use CCR5 or CXCR4, while those from several strains of SIV use CCR5. Our data indicate also that some viral envelopes can use more than one coreceptor for entry and suggest that some of these coreceptors remain to be identified. To further understand how different envelope molecules use CCR5 as an entry cofactor, we show that soluble purified envelope glycoproteins (SU component) from CCR5-tropic HIV-1, HIV-2, and SIV can compete for binding of iodinated chemokine to CCR5. The competition is dependent on binding of the SU glycoprotein to cell surface CD4 and implies a direct interaction between envelope glycoproteins and CCR5. This interaction is specific since it is not observed with SU glycoprotein from a CXCR4-tropic virus or with a chemokine receptor that is not competent for viral entry (CCR1). For HIV-1, the interaction can be inhibited by antibodies specific for the V3 loop of SU. Soluble CD4 was found to potentiate binding of the HIV-2 ST and SIVmac239 envelope glycoproteins to CCR5, suggesting that a CD4-induced conformational change in SU is required for subsequent binding to CCR5. These data suggest a common fundamental mechanism by which structurally diverse HIV-1, HIV-2, and SIV envelope glycoproteins interact with CD4 and CCR5 to mediate viral entry.     

A Synthetic Peptide Fragment Derived from RANTES is a Potent Inhibitor of HIV-1 Infectivity Despite a Surprising Lack of CCR5 Receptor Affinity

Summary CCR5 (CC-chemokine receptor 5) is a key co-receptor, in concert with CD4, for infectivity of HIV-1 (human immunodeficiency virus type-1) into healthy human cells, and RANTES, an endogenous ligand for CCR5, is a potent inhibitor of HIV-1 infectivity. In this structure-activity relationship (SAR) study, peptide fragments derived from RANTES were designed, synthesized and evaluated for their ability to inhibit HIV-1 infectivity. The goal was to determine the effect of peptide length on anti-HIV activity and to obtain an optimally sized RANTES peptide probe for further SAR studies. The analogue Ac[Ala^10,11]RANTES-(1–14)NH₂, AA14, was identified as an effective inhibitor of HIV-1 infectivity at 10 nM but despite the functional activity, surprisingly it did not exhibit any notable affinity for the CCR5 chemokine receptor. Further, increasing peptide size enhanced neither the inhibition of HIV-1 infectivity nor CCR5 receptor affinity. As a potent inhibitor of HIV-1 infectivity, the lead analogue most likely utilizes a different (and currently unknown) mechanism than interaction with CCR5 for anti-HIV activity.     

A Synthetic Peptide Fragment Derived from RANTES is a Potent Inhibitor of HIV-1 Infectivity Despite a Surprising Lack of CCR5 Receptor Affinity

CCR5 (CC-chemokine receptor 5) is a key co-receptor, in concert with CD4, for infectivity of HIV-1 (human immunodeficiency virus type-1) into healthy human cells, and RANTES, an endogenous ligandfor CCR5, is a potent inhibitor of HIV-1 infectivity. In this structure-activity relationship (SAR) study, peptide fragments derived from RANTES were designed, synthesized and evaluated fortheir ability to inhibit HIV-1 infectivity. The goal was to determine the effect of peptide length on anti-HIV activity and to obtain an optimally sized RANTES peptide probe for further SAR studies. The analogue Ac[Ala^10,11]RANTES-(1–14)NH₂, AA14, was identified as an effective inhibitor of HIV-1 infectivity at 10 nM but despite the functional activity, surprisingly it did not exhibit any notable affinity for the CCR5 chemokine receptor. Further, increasing peptide size enhanced neither the inhibition of HIV-1 infectivity nor CCR5 receptor affinity. As a potent inhibitor of HIV-1 infectivity,the lead analogue most likely utilizes a different (and currentlyunknown) mechanism than interaction with CCR5 for anti-HIV activity.     

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.     

Structural and molecular interactions of CCR5 inhibitors with CCR5

We have characterized the structural and molecular interactions of CC-chemokine receptor 5 (CCR5) with three CCR5 inhibitors active against R5 human immunodeficiency virus type 1 (HIV-1) including the potent in vitro and in vivo CCR5 inhibitor aplaviroc (AVC). The data obtained with saturation binding assays and structural analyses delineated the key interactions responsible for the binding of CCR5 inhibitors with CCR5 and illustrated that their binding site is located in a predominantly lipophilic pocket in the interface of extracellular loops and within the upper transmembrane (TM) domain of CCR5. Mutations in the CCR5 binding sites of AVC decreased gp120 binding to CCR5 and the susceptibility to HIV-1 infection, although mutations in TM4 and TM5 that also decreased gp120 binding and HIV-1 infectivity had less effects on the binding of CC-chemokines, suggesting that CCR5 inhibition targeting appropriate regions might render the inhibition highly HIV-1-specific while preserving the CC chemokine-CCR5 interactions. The present data delineating residue by residue interactions of CCR5 with CCR5 inhibitors should not only help design more potent and more HIV-1-specific CCR5 inhibitors, but also give new insights into the dynamics of CC-chemokine-CCR5 interactions and the mechanisms of CCR5 involvement in the process of cellular entry of HIV-1.     

Suppression of CCR5- but not CXCR4-tropic HIV-1 in lymphoid tissue by human herpesvirus 6.

HIV-1 infects target cells via a receptor complex formed by CD4 and a chemokine receptor, primarily CCR5 or CXCR4 (ref. 1). Commonly, HIV-1 transmission is mediated by CCR5-tropic variants, also designated slow/low, non-syncytia-inducer or macrophage-tropic, which dominate the early stages of HIV-1 infection and frequently persist during the entire course of the disease. In contrast, HIV-1 variants that use CXCR4 are typically detected at the later stages, and are associated with a rapid decline in CD4+ T cells and progression to AIDS (refs. 2,7-11). Disease progression is also associated with the emergence of concurrent infections that may affect the course of HIV disease by unknown mechanisms. A lymphotropic agent frequently reactivated in HIV-infected patients is human herpesvirus 6 (HHV-6), which has been proposed as a cofactor in AIDS progression. Here we show that in human lymphoid tissue ex vivo, HHV-6 affects HIV-1 infection in a coreceptor-dependent manner, suppressing CCR5-tropic but not CXCR4-tropic HIV-1 replication, as shown with both uncloned viral isolates and isogenic molecular chimeras. Furthermore, we demonstrate that HHV-6 increases the production of the CCR5 ligand RANTES ('regulated upon activation, normal T-cell expressed and secreted'), the most potent HIV-inhibitory CC chemokine, and that exogenous RANTES mimics the effects of HHV-6 on HIV-1, providing a mechanism for the selective blockade of CCR5-tropic HIV-1. Our data suggest that HHV-6 may profoundly influence the course of HIV-1 infection.