Glycoside analogs of beta-galactosylceramide, a novel class of small molecule antiviral agents that inhibit HIV-1 entry

The interaction between HIV gp120 and galactose-containing cell surface glycolipids such as GalCer or Gb(3) is known to facilitate HIV binding to both CD4(+) as well as CD4(-) cells. In an effort to develop small molecule HIV-1 entry inhibitors with improved solubility and efficacy, we have synthesized a series of C-glycoside analogs of GalCer and tested their anti HIV-1 activity. The analogs were tested for gp120 binding using a HIV-1 (IIIB) V3-loop specific peptide. Two of the six analogs that interfered with gp120 binding also inhibited HIV Env-mediated cell-to-cell fusion and viral entry in the absence of any significant cytotoxicity. Analogs with two side chains did not show inhibition of fusion and/or infection under identical conditions. The inhibition of virus infection seen by these compounds was not coreceptor dependent, as they inhibited CXCR4, CCR5 as well as dual tropic viruses. These compounds showed inhibition of HIV entry at early steps in viral infection since the compounds were inactive if added post viral entry. Temperature-arrested state experiments showed that the compounds act at the level of virus attachment to the cells likely at a pre-CD4 engagement step. These compounds also showed inhibition of VSV glycoprotein-pseudotyped virus. The results presented here show that the glycoside derivatives of GalCer with simple side chains may serve as a novel class of small molecule HIV-1 entry inhibitors that would be active against a number of HIV isolates as well as other enveloped viruses.     

HIV co-receptor inhibitors as novel class of anti-HIV drugs

Entry inhibitors constitute a new class of drugs to treat infection by human immunodeficiency virus type 1 (HIV-1). The first member of this class, enfuvirtide, previously known as T-20 and targeting gp41, has now been licensed for therapeutic use. Several other entry inhibitors are in various stages of pre-clinical or clinical development. In this review we focus on the chemokine receptor inhibitors targeting CCR5 and CXCR4 that are the main HIV co-receptors for viral entry.     

Oral CCR5 inhibitors: will they make it through?

The therapeutic armamentarium against HIV has recently gained a drug belonging to a novel class of antiretrovirals, the entry inhibitors. The last decade has driven an in-depth knowledge of the HIV entry process, unravelling the multiple engagements of the HIV envelope proteins with the cellular receptorial complex that is composed of a primary receptor (CD4) and a co-receptor (CCR5 or CXCR4). The vast majority of HIV-infected subjects exhibit biological viral variants that use CCR5 as a co-receptor. Individuals with a mutated CCR5 gene, both homo- and heterozygotes, appear to be healthy. For these and other reasons, CCR5 represents an appealing target for treatment intervention, although certain challenges can not be ignored. Promising small-molecule, orally bioavailable CCR5 antagonists are under development for the treatment of HIV-1 infection.     

Oral CCR5 inhibitors: will they make it through?

The therapeutic armamentarium against HIV has recently gained a drug belonging to a novel class of antiretrovirals, the entry inhibitors. The last decade has driven an in-depth knowledge of the HIV entry process, unravelling the multiple engagements of the HIV envelope proteins with the cellular receptorial complex that is composed of a primary receptor (CD4) and a co-receptor (CCR5 or CXCR4). The vast majority of HIV-infected subjects exhibit biological viral variants that use CCR5 as a co-receptor. Individuals with a mutated CCR5 gene, both homo- and heterozygotes, appear to be healthy. For these and other reasons, CCR5 represents an appealing target for treatment intervention, although certain challenges can not be ignored. Promising small-molecule, orally bioavailable CCR5 antagonists are under development for the treatment of HIV-1 infection.     

作用于HIV gp120的进入抑制剂研究进展

HIV-1病毒为包膜病毒,其感染靶细胞的第一步是由HIV包膜蛋白表面亚基gp120与靶细胞上的CD4分子和辅助受体（趋化因子受体CCR5或CXCR4等）结合,导致gp41的构型发生改变,启动病毒包膜与靶细胞膜的融合。与gp120相结合的一些抗体、蛋白、多糖、多肽和小分子化合物,都可能影响HIV-1病毒包膜和靶细胞膜融合的过程,从而起到抗HIV-1病毒的作用。该文对近年来以HIV gp120为靶点的HIV进入抑制剂的研究进展进行综述。     

Conformational properties of HIV-1 gp120/V3 immunogenic domains

Infection of target host cells by the human immunodeficiency virus-1 (HIV-1) is a multi-step process involving a series of conformational changes in the viral gp120 and gp41 proteins. Gp120 binding to the main cell receptor, CD4, on the surface of cells expressing this molecule, and interaction with the cell chemokine receptors CCR5 and CXCR4, are among the key events for HIV-1 infection. These steps are crucial for the virus and offer potential therapeutic targets. For this reason, understanding the structure and the physicochemical characteristics of the gp120 in relation to these interactions has drawn much attention. This review article focuses on the biologically important V3 region of the gp120 and summarizes the functional role, the sequence variation and the conformational features of V3 peptides, which are important for co-receptor selectivity, specificity and interaction. Synthetic V3 peptides have been extensively studied by NMR spectroscopy and X-ray crystallography, in solution or in solid state, in their free or bound form, and valuable information was generated with the aim to be exploited in the design of new, effective inhibitors of HIV-1 infection. The features of the potential gp120 interacting sites on the two chemokine co-receptors, CCR5 and CXCR4, are also discussed, and co-receptor blocking molecules under clinical trial are also reported.     

新型抗艾滋病药物——HIV进入抑制剂的研究进展

HIV与靶细胞融合的过程是药物干预的重要环节。融合过程主要由H IV包被蛋白表面亚基gp120和跨膜亚基gp41介导。H IV gp120与靶细胞上的CD4分子和辅助受体(趋化因子受体CCR5或CXCR4等)结合,导致gp41的构型发生改变,启动病毒包膜与靶细胞膜的融合。在融合过程中,病毒和靶细胞上的这些蛋白和受体均可作为药物的作用靶点,寻找抑制H IV进入靶细胞的药物用来治疗H IV感染和艾滋病。作用于gp41的肽类药物T-20已被美国FDA批准上市,表明继逆转录酶抑制剂和蛋白酶抑制剂后,H IV进入抑制剂作为第3类抗H IV药物开始在临床上应用。作为一种新机制的抗H IV药物,H IV进入抑制剂单独或与逆转录酶抑制剂和蛋白酶抑制剂联合应用,将有助于提高药物的疗效,降低毒副作用,并可望挽救对现有抗H IV药物耐药的艾滋病病人的生命。该文综述了近年来H IV进入抑制剂的研究进展。     

A simple screening system for anti-HIV drugs: syncytium formation assay using T-cell line tropic and macrophage tropic HIV env expressing cell lines--establishment and validation.

The first step in cellular entry of HIV involves binding of the viral envelope glycoprotein complex (gp120/gp41) to specific receptor molecules on the target cells. The cell-cell fusion (syncytium formation) between env expressing cells and CD4+ cells mimics the viral infection of the host cells. To search for anti-HIV substances preventing this process, we constructed the recombinant cell lines, HeLa/CD4/Lac-Z and HeLa/T-env/Tat for T-cell tropic (HIV-1(NL4-3)) system, and HOS/CD4/CCR5/Lac-Z and HeLa/M-env/Tat for macrophage tropic (HIV-1(SF162)) system. When each pair of cells were co-incubated for 20 hours, the multinuclear giant cells (syncytia) were formed and beta-galactosidase was expressed. These systems are less biohazardous because no infectious virus particles are used. Their validity in screening for anti-HIV substances which inhibit syncytium formation was confirmed using various known HIV entry inhibitors.     

Chemokine receptors in HIV-1 and SIV infection

Seven transmembrane segment (7TMS) receptors for chemokines and related molecules have been demonstrated to be essential, in addition to CD4, for HIV and SIV infection. The β-chemokine receptor CCR5 is the primary, perhaps sole, coreceptor for HIV-1 during the early and chronic phases of infection, and supports infection by most primary HIV-1 and many SIV isolates. Late-stage primary and laboratory-adapted HIV-1, HIV-2, and SIV isolates can use other 7TMS receptors. CXCR4 appears especially important in late-stage HIV infection; several related receptors can also be used. The specificity of SIV viruses is similar. Commonalities among these receptors, combined with analyses of mutated molecules, indicate that discrete, conformationally-dependent sites on the chemokine receptors determine their association with the third variable and conserved regions of viral envelope glycoproteins. These studies are useful for elucidating the mechanism and molecular determinants of HIV-1 entry, and of inhibitors to that entry.     

Structure-based design, synthesis, and characterization of dual hotspot small-molecule HIV-1 entry inhibitors

Cellular infection by HIV-1 is initiated with a binding event between the viral envelope glycoprotein gp120 and the cellular receptor protein CD4. The CD4-gp120 interface is dominated by two hotspots: a hydrophobic gp120 cavity capped by Phe43(CD4) and an electrostatic interaction between residues Arg59(CD4) and Asp368(gp120). The CD4 mimetic small-molecule NBD-556 (1) binds within the gp120 cavity; however, 1 and related congeners demonstrate limited viral neutralization breadth. Herein, we report the design, synthesis, characterization, and X-ray structures of gp120 in complex with small molecules that simultaneously engage both binding hotspots. The compounds specifically inhibit viral infection of 42 tier 2 clades B and C viruses and are shown to be antagonists of entry into CD4-negative cells. Dual hotspot design thus provides both a means to enhance neutralization potency of HIV-1 entry inhibitors and a novel structural paradigm for inhibiting the CD4-gp120 protein-protein interaction.     

Effects of HIV-1 entry inhibitors in combination

Inhibiting the HIV-1 entry process offer a new therapeutic target and the hope to potentialize our current treatments against wild-type or drug-resistant viruses. Several inhibitors of CD4, co-receptor CCR5 or CXCR4 and fusion are at various levels of clinical development. How best to use this class of drugs in our therapeutic arsenal remains to be defined. It is likely that these compounds will not be used as monotherapy. Therefore, it is important to evaluate how these drugs will interact among themselves as well as with antiretrovirals from other classes. Drug interactions can range from synergy to antagonism depending on factors including binding affinity, drug concentrations, and pharmacokinetics. In the case of entry inhibitors, one must also consider that the entry of HIV-1 into the cell is a multi-step process that involve cumulative events which are interdependent. Furthermore, polymorphism both in the coreceptors and in gp120, the density of coreceptors, and the binding site of the drug may also affect efficacy. Therefore it is difficult to predict how blocking one step of the process will affect the subsequent one without carefully studying interactions of each potential combination in an in vitro system. So far, studies of interactions between fusion inhibitors and coreceptor inhibitors have shown a high level of synergy. Similar studies performed with two co-receptor inhibitors have shown results varying from synergy to high antagonism depending on the viral isolate and the compounds used. In the following chapter, we will review some concepts of mechanisms that may affect these interactions.     

A novel class of HIV-1 inhibitors that targets the viral envelope and inhibits CD4 receptor binding

BMS-378806 is a prototype of a new class of small molecule HIV-1 inhibitors that blocks viral attachment to cells. This compound exhibits potent inhibitory activity against a panel of HIV-1 laboratory and clinical isolates (M- and T-tropic), selective for HIV-1 and inactive against HIV-2, SIV and a panel of other viruses. BMS-378806 exhibits no significant cytotoxicity and displays many attractive pharmacological properties such as low protein binding, minimal serum effect on anti-HIV-1 potency, good oral bioavailability in animal species and a clean safety profile in initial animal toxicology studies. The compound binds to gp120 and blocks the attachment of the HIV-1 envelope protein to cellular CD4 receptors via a specific and competitive mechanism. BMS-378806 binds directly to gp120 at an approximately 1:1 stoichiometry, with a binding affinity similar to that of soluble CD4. Further confirmation that this class of compounds targets the envelope in infected cells was obtained through the isolation of resistant variants and the mapping of resistance substitutions to the HIV-1 envelope. In particular, two substitutions, M426L and M475I, are situated at or near the CD4 binding pocket of gp120. Recombinant HIV-1 carrying these two substitutions demonstrated significantly reduced susceptibility to inhibition. Using these HIV-1 gp120 resistant variants and gp120/CD4 contact site mutants, the potential BMS-378806 target site was localized to a specific region within the CD4 binding pocket of gp120. Together, the data show that BMS-378806 is the first of a new class of HIV inhibitors with the potential to become a valued addition to our current repertoire of antiretroviral drugs.     

Anti-HIV activity and conformational studies of peptides derived from the C-terminal sequence of SDF-1

The entry of the human immunodeficiency virus type 1 (HIV-1) into target cells requires the interaction of viral envelope glycoprotein, gp120, with the human CD4 glycoprotein and a chemokine receptor, usually CCR5 or CXCR4. The natural ligand for CXCR4 is the chemokine SDF-1 that inhibits entry and replication of X4 HIV-1 strains. SDF-1 is produced in two forms, SDF-1alpha (68 residues) and SDF-1beta (72 residues); the difference between them lies in the additional four C-terminal amino acids in the SDF-1beta sequence. Despite the relevance of the N-terminal site in determining the SDF anti HIV-1 activity, SDF-1beta has a stronger activity than SDF-1alpha. Here we demonstrate that a synthetic peptide mapped on the C-terminus of SDF-1beta presents inhibitory activity, whereas an analogue reproducing the C-terminal trait of SDF-1alpha does not show any activity. The opposite biological effect of the two peptides correlates with the type of interaction they each have with heparin and chondroitin sulfate.