The interaction of CD4 with HIV-1 gp120

CD4 is an integral cell surface glycoprotein that is able to enhance T cell specific antigen responses when it interacts with its physiological ligand, class II major histocompatibility (MHC) molecules. In addition, CD4 is a specific cell-surface receptor for the human immunodeficiency virus-1 (HIV-1). Infection by HIV-1 is initiated by the binding of the envelope glycoprotein, gp120, to the first domain of CD4. The binding of CD4 to class II MHC is inhibited by gp120, one possible mechanism for immunosuppression in AIDS patients. In addition, the CD4/gp120 interaction may directly inhibit T cell function. Recently we have synthesized small molecules (CPFs) that specifically inhibit this interaction. CPFs bind to gp120 and prevent the binding of gp120 to CD4, and also inhibit the infectivity of HIV-1.     

Potency of HIV-1 envelope glycoprotein gp120 antibodies to inhibit the interaction of DC-SIGN with HIV-1 gp120

The interaction of DC-SIGN with gp120 provides an attractive target for intervention of HIV-1 transmission. Here, we have investigated the potency of gp120 antibodies to inhibit the DC-SIGN-gp120 interaction. We demonstrate that although the V3 loop is not essential for DC-SIGN binding, antibodies against the V3 loop partially inhibit DC-SIGN binding, suggesting that these antibodies sterically hinder DC-SIGN binding to gp120. Polyclonal antibodies raised against non-glycosylated gp120 inhibited both low and high avidity DC-SIGN-gp120 interactions in contrast to polyclonal antibodies raised against glycosylated gp120. Thus, glycans present on gp120 may prevent the generation of antibodies that block the DC-SIGN-gp120 interactions. Moreover, the polyclonal antibodies against non-glycosylated gp120 efficiently inhibited HIV-1 capture by both DC-SIGN transfectants and immature dendritic cells. Therefore, non-glycosylated gp120 may be an attractive immunogen to elicit gp120 antibodies that block the binding to DC-SIGN. Furthermore, we demonstrate that DC-SIGN binding to gp120 enhanced CD4 binding, suggesting that DC-SIGN induces conformational changes in gp120, which may provide new targets for neutralizing antibodies.     

HIV-1 gp120 and immune network

It has been demonstrated that the immunodominant V3 loop of HIV-1 gp120 and its flanking regions bear sequence and structural homology to the framework and complementarity-determining regions of human immunoglobulins. It has been proposed that the Ig-like domain of gp120 might encode idiotypes and in this way permit HIV-1 entry into the immune regulatory network. This notion is strongly supported by results demonstrating that the anti-V3 loop and anti-Ig antibodies of healthy individuals share complementary structure and that V3 reactive antibodies are present in HIV-negative sera. This might be the mechanism by which HIV induces immunological abnormalities, and it should be taken into consideration in AIDS vaccine development.     

Modulation of CD4 lateral interaction with lymphocyte surface molecules induced by HIV-1 gp120

CD4, a lymphocyte surface glycoprotein, serves as co-receptor for antigen with the T cell receptor (TCR). It is also the lymphocyte receptor for HIV by binding the gp120 viral envelope protein. Interaction of gp120 with CD4 is crucial for viral infection, but is not sufficient to allow viral entry into cells. Recombinant gp120 alters CD4⁺ T cell responsiveness to activation stimuli. To express its co-receptor function fully, CD4 must be laterally associated with the TCR and CD45 to form multi-receptor complexes competent to transduce potent activation signals. Here, we examine the possibility that gp120/CD4 binding alters lateral associations of CD4 with other lymphocyte surface molecules, and that assembly of abnormal multi-molecular complexes is involved in the gp120-induced CD4⁺ T cell dysfunction and in viral entry. In the absence of gp120, CD4 displayed high association with CD3, CD5, CD45RC, CD25, CD28, CD44, and CD53; weak association with CD2, CD38, CD45RB, CD62L, and CD26; and no association with CD45RA, CD45RO, CD11b, CD11a, CD54, CD7, CD48, CD98, CD59, CD55, HLA class I and class II molecules. Treatment with gp120 significantly increased CD4 association with CD3, CD45RA, CD45RB, CD59, CD38, CD26, and HLA class I, and decreased that with CD45RC. Specificity of these results were assessed at various levels. First, gp120 did not influence lateral associations displayed by other molecules, such as HLA class II. Second, the Leu3 mAb, which binds CD4 on a site overlapping the gp120 binding site, did not elicit the same CD4 lateral associations as gp120, and finally, a direct gp120/CD4 interaction was needed to induce the lateral associations, as shown by the observation that blocking the gp120/CD4 binding by the Leu3 mAb inhibited the gp120-induced associations. These results can be interpreted in several ways. gp120/CD4 interaction could trigger an inside-out signal responsible for the associations, or gp120 could induce steric modifications of CD4 that increase its affinity for the associating molecules. Alternatively, these molecules may interact directly with gp120, bridging them with CD4. It is also possible that the associations may be mediated by additional components, interacting with both gp120 and the associating surface molecule. The last hypothesis is likely for CD59, whose gp120-induced association with CD4 required the presence of serum in the co-capping assay. Since both CD59 and gp120 bind complement, the observed association could be mediated by complement components.     

HIV-1 gp120 receptor on CD4-negative brain cells activates a tyrosine kinase.

Human immunodeficiency virus (HIV-1) infection in the human brain leads to characteristic neuropathological changes, which may result indirectly from interactions of the envelope glycoprotein gp120 with neurons and/or glial cells. We therefore investigated the binding of recombinant gp120 (rgp120) to human neural cells and its effect on intracellular signalling. Here we present evidence that rgp120, besides binding to galactocerebroside or galactosyl-sulfatide, specifically binds to a protein receptor of a relative molecular mass of approximately 180,000 Da (180 kDa) present on the CD4-negative glioma cells D-54, but not on Molt4 T lymphocytes. Binding of rgp120 to this receptor rapidly induced a tyrosine-specific protein kinase activity leading to tyrosine phosphorylation of 130- and 115-kDa proteins. The concentration of intracellular calcium was not affected by rgp120 in these cells. Our data suggest a novel signal transducing HIV-1 gp120 receptor on CD4-negative glial cells, which may contribute to the neuropathological changes observed in HIV-1-infected brains.     

Conformation of gp120 determines the sensitivity of HIV-1 DH012 to the entry inhibitor IC9564

The HIV-1 envelope glycoprotein gp120 is the key determinant for the anti-HIV-1 entry activity of IC9564. A T198P mutation in the gp120 of the HIV-1 primary isolate, DH012, drastically increases IC9564 sensitivity, which can be reversed by growing the virus in the presence of IC9564. The reversed resistant variants contain a P198S mutation that fully confers the drug-resistant phenotype. Although the amino acid residue at position 198 of gp120 can alter IC9564 sensitivity, results from this study suggest that T198 is not the direct target of the compound. The mutation at position 198 appears to affect the conformation of gp120 and subsequently decreases the accessibility of the drug target. This conformational effect is evidenced by the fact that the T198P mutation significantly increases the neutralizing activity of the conformational antibodies, 1b12 and 48d. On the other hand, the IC9564 escape variant with the P198S mutation is resistant to these conformational antibodies and highly sensitive to the potent neutralizing antiserum, C1206, which recognizes a conformational epitope involving the sequences from V1, V2, and V3 regions in gp120. Thus, results from this study indicate that the conformation of gp120 can be exploited by HIV-1 to escape IC9564.     

Structural requirements of glycosaminoglycans for their interaction with HIV-1 envelope glycoprotein gp120

Heparan sulfate proteoglycans are known to assist HIV-1 entry into host cells, mediated by the viral envelope glycoprotein gp120. We aimed to determine the general structural features of glycosaminoglycans that enable their binding to gp120, by surface plasmon resonance. Binding was found to be dependent on sequence type, size and sulfation patterns. HIV-1 gp120 prefers heparin and heparan sulfate (with at least 16 monomers in length) over chondroitin and dermatan. Sulfate groups were essential to promote this interaction. These results advance the understanding of the molecular-level requirements for virus attachment and cell entry.     

Identification of three N-linked glycans in the V4–V5 region of HIV-1 gp 120, dispensable for CD4-binding and fusion activity of gp 120

Summary Site-directed mutagenesis was used to study the biological significance of three N-linked glycans (linked to Asn 406, Asn 448, and Asn 463), situated in the CD4-binding region of gp120. Mutagenesis was carried out in a phage M13 system, and the mutatedenv genes were inserted into recombinant vaccinia virus (r-vaccinia virus). To evaluate if the level of expression affected the biological phenotype of mutant gp 120, we expressed the envelope glycoproteins using either a weak (7.5 K) or a strong (11 K) promoter of vaccinia virus. The expression of mutatedenv proteins was analyzed after infecting CD4-expressing HeLa cells with the r-vaccinia virus, by monitoring the ability of the infected cells to generate CD4-dependent syncytia.Env gene products lacking all three glycans as well asenv gene products lacking different permutations of one or two glycans were analyzed. All mutated gp 120 species had the expected electrophoretical mobility as anticipated from elimination of one, two, and three N-linked glycans, respectively. Moreover, all mutantenv gene products demonstrated the same capacity to induce formation of syncytia, irrespective of using the weak or strong promoter for expression. These data indicate that the three N-linked glycans studied are dispensable for HIVenv gene products to function in CD4-binding and the subsequent fusion step.     

Enhanced HIV-1 envelope-tumor protection by a recombinant vaccinia virus expressing anchored HIV-1 gp120 lacking gp41

A recombinant vaccinia virus (rvv) expressing, human immunodeficiency virus type 1 (HIV-1) external envelope glycoprotein, gp120, fused to a non-cleavable transmembrane protein, vvE13, elicited protection against a tumor cell line expressing HIV-1 full length envelope glycoprotein, gp160, in mice. Mice vaccinated with vvE13 exhibited a decreased incidence of tumor development and significantly smaller tumors in comparison to mice vaccinated with rvv gp160, vvE1, or a thymidine kinase minus (TK-) rvv, vSC11, or phosphate-buffered saline (PBS) injected controls. vvE13 and vvE1 also delayed tumor development, compared to vSC11 and PBS-injected controls; however, a statistical correlation could not be demonstrated due to the development of tumors in so few animals. Specificity toward HIV-1 envelope glycoprotein, was shown, since HIV-1 envelope-tumor prevention (incidence for vvE13 and size for vvE1 and vvE13 and delay for vvE1 and vvE13) was statistically superior with HIV-1 envelope expressing tumors compared to parenteral tumors. The vvE13 recombinant vaccinia virus expressing the HIV-1 envelope glycoprotein gp120 fused to a non-cleavable transmembrane protein elicits superior protection against tumors expressing the gp160 envelope glycoprotein, as compared to vvE1 expressing gp160.     

Recombination property of the HIV-1 gp120 gene

Using a chimeric primer consisting of the nucleotide sequence derived from the HIV-1 envelope gene coding for the second conserved region of gp120, and the highly conserved sequence derived from the human immunoglobulin gene coding for the VHIII domain, it has been identified in sera of AIDS patients HIV-1 field isolates carrying the complete and active Chi recombination hot spot (GCTGGTGG). The recombination between the HIV-1 gene coding for the central portion of gp120 and the bacterial gene coding for the clp protease was also demonstrated in vivo. These results point out serious concern that vectored AIDS vaccine candidates carrying the HIV-1 env gene on viral and bacterial vectors could become the source of potentially new infectious diseases rather than an effective instrument for AIDS prevention.     

Evidence that the HIV-1 coat protein gp120 causes neuronal apoptosis in the neocortex of rat via a mechanism involving CXCR4 chemokine receptor

Upregulation of voltage-dependent outward rectifying K+ (Kv) channels has been reported in activated microglia. Since beta-amyloid peptide (A beta) is known to activate microglia, we tested whether the exposure of cultured rat microglia to A beta fragment 25-35 (A beta 25-35) induced the Kv current. A beta 25-35 in 5-200 nM concentration range significantly increased Kv current density, while there was small change in inward rectifying K+ current density. The full length A beta peptide (A beta 1-42) also increased Kv current. However, the control peptide, A beta 35-25, did not induce Kv current. Most of the Kv current induced by A beta was specifically blocked by the presence of antisense deoxyoligonucleotides against Kv1.3, and Kv1.5. Thus, it is concluded that we have identified Kv1.3 and Kv1.5 as the channel types expressed in A beta-treated microglia.     

Inefficient formation of a complex among CXCR4, CD4 and gp120 in U937 clones resistant to X4 gp120-gp41-mediated fusion

Certain subclones (designated as minus clones) of the promonocytic U937 cell line do not support efficient infection and fusion mediated by T cell line adapted (TCLA) X4 HIV-1 gp120-gp41 (Env) although the CXCR4 and CD4 concentrations at their surfaces are similar to those at the surfaces of clones susceptible to HIV-1 entry (plus clones) (H. Moriuchi et al., J. Virol. 71, 9664-9671, 1997). To test the hypothesis that inefficient formation of gp120-CD4-CXCR4 complexes could contribute to the mechanism of resistance to Env-mediated fusion in the minus clones, we incubated plus and minus cells with HIV-1 LAI gp120 and coimmunoprecipitated CD4 by using anti-CXCR4 antibodies. The gp120 induced inefficient coimmunoprecipitation of CD4 in the minus clones but not in the plus ones. Overexpression of CD4 resulted in significant restoration of the minus clones' susceptibility to fusion in parallel with an increase in the amount of the gp120-CD4-CXCR4 complexes. These results not only suggest that the resistance to TCLA X4 HIV-1 entry in the U937 minus clones is due to the inability of these cells to efficiently form complexes among CD4, gp120, and CXCR4, but also provide a direct evidence for the correlation between fusion and the cell surface concentration of the complexes among CXCR4, CD4, and gp120. These data and similar recent observations in macrophages suggest that inefficient complex formation among CXCR4, CD4, and gp120 could be a general mechanism of cell resistance to gp120-gp41-mediated fusion and a major determinant of HIV-1 evolution in vivo.     

HIV-1 gp120 induces NFAT nuclear translocation in resting CD4+ T-cells

The replication of human immunodeficiency virus (HIV) in CD4+ T-cells is strongly dependent upon the state of activation of infected cells. Infection of sub-optimally activated cells is believed to play a critical role in both the transmission of virus and the persistence of CD4+ T-cell reservoirs. There is accumulating evidence that HIV can modulate signal-transduction pathways in a manner that may facilitate replication in such cells. We previously demonstrated that HIV gp120 induces virus replication in resting CD4+ T cells isolated from HIV-infected individuals. Here, we show that in resting CD4+ T-cells, gp120 activates NFATs and induces their translocation into the nucleus. The HIV LTR encodes NFAT recognition sites, and NFATs may play a critical role in promoting viral replication in sub-optimally activated cells. These observations provide insight into a potential mechanism by which HIV is able to establish infection in resting cells, which may have implications for both transmission of HIV and the persistence of viral reservoirs.     

Antibody repertoire against HIV-1 gp120 triggered in nude and normal mice by GM-CSF/gp120 immunization

Granulocyte-macrophage colony stimulating factor (GM-CSF) facilitates the induction of primary immune responses by activating and recruiting antigen-presenting cells (APC), which efficiently present antigen determinants to Th cells. We have derived a functional GM-CSF/gp120 chimeric protein that, following immunization in soluble, adjuvant-independent form in normal mice, triggers highly specific, high affinity anti-gp120 antibodies. In contrast, nude mice respond with mutated, polyreactive, low affinity antibodies that mature further and increase in affinity in T cell-reconstituted nude mice. Anti-gp120 antibody production in nude mice is mediated principally by GM-CSF/gp120-triggered IL-4 production, since neutralizing anti-IL-4 abrogates the in vivo response. The anti-gp120 antibody response in normal, nude and T cell-reconstituted nude mice is encoded at a remarkably high frequency by the VH81X and VH7183 genes, a family used notably during fetal life and, when expressed at the adult stage, associated with autoimmune disease. We conclude that HIV gp120 binds and selects a subpopulation of developing B cells expressing a set of VH genes associated with immunodeficiency and autoimmunity.     

In vivo alteration of humoral responses to HIV-1 envelope glycoprotein gp120 by antibodies to the CD4-binding site of gp120

The binding of antibodies to the CD4-binding site (CD4bs) of the HIV-1 envelope glycoprotein gp120 has been shown to induce gp120 to undergo conformational changes that can expose and/or shield specific epitopes on gp120. Here, we study alterations in the antigenicity and immunogenicity of gp120 when complexed with human monoclonal antibodies (mAbs) specific for the CD4bs of gp120. The data showed that gp120 bound by anti-CD4bs mAbs had enhanced reactivity with mAbs to the V3 and N-terminal regions, but not with mAb to the C terminus. Moreover, mice immunized with the gp120/anti-CD4bs mAb complexes produced higher titers of gp120-specific serum IgG and IgA than mice immunized with uncomplexed gp120 or other gp120/mAb complexes. Notably, the enhanced antibody production was directed against V3 and correlated with better exposure of V3 on the gp120/anti-CD4bs mAb complexes. The higher antibody reactivity was evident against the homologous V3(LAI) peptide, but not against heterologous V3 peptides. Potent neutralization activity against HIV-1(LAI) was also observed in the sera from mice immunized with gp120/anti-CD4bs mAb complexes, although the sera exhibited poor neutralizing activities against other viruses tested. These results indicate that the anti-CD4bs antibodies alter the antigenicity and immunogenicity of gp120, leading to enhanced production of anti-gp120 antibodies directed particularly against the V3 region.     

Factors limiting the immunogenicity of HIV-1 gp120 envelope glycoproteins

Efficient immune responses to HIV-1 gene products are essential elements to the development and design of an effective vaccine. Ideally, both humoral and cellular responses will be optimally elicited. It is therefore important to elucidate any factors that might limit the immunogenicity of HIV-1 proteins that are likely to be included in an effective vaccine. Since the HIV-1 exterior envelope glycoprotein gp120 is a major target for neutralizing antibodies, it is a virtual certainty that this gene product will be a component of any vaccine that seeks to elicit neutralizing antibody responses from the host humoral immune system. We report here the testing of several HIV-1 gp120 variants derived from a primary isolate that appears deficient in eliciting immune responses at both the level of CD4+ help and consequently in the generation of high-affinity IgG antibody responses in small animals. Factors limiting an effective immune response include (a) envelope glycoprotein strain variation decreasing functional T-cell help, (b) alteration of the glycosylation patterns of gp120 by expression in different cell types, and (c) the native structure of gp120 itself, which may limit the elicitation of effective T-cell help during natural infection or during parenteral immunization in adjuvant. Such limiting factors and others should be considered in the design and testing of gp120-based immunogens in small animals and possibly in primates as well.     

gp120mAb对gp120抑制大鼠海马脑片CA1区LTP作用的研究

目的探讨人类免疫缺陷病毒Ⅰ型(HIV-1)的包膜糖蛋白gp120特异抗体gp120mAb对gp120引起大鼠海马脑片CA1区的突触传递及可塑性变化的影响.方法应用离体脑片记录技术,记录大鼠海马CA1区的兴奋性突触后电位(EPSP),研究gp120mAb对gp120抑制高频电刺激Schaffer侧支引起的鼠海马长时程增强效应(LTP)作用的影响.结果gp120对高频电刺激(HFS,100 Hz,1 000 ms×2,串间隔20秒,共2次)Schaffer侧支引起的大鼠海马CA1区LTP产生抑制作用,而对其基础EPSP没有影响.用浓度为200 pmol/L的gp120灌流脑片,可引起LTP的维持发生抑制.这种抑制作用可被gp120特异抗体gp120mAb(50 ng/ml)所拮抗.结论gp120mAb可能是通过拮抗gp120抑制海马CA1区的LTP诱发和维持而参与艾滋病痴呆(HIV-1 associated dementia,HAD)的形成.     

Expression and purification of glutathione S-transferase-tagged HIV-1 gp120: no evidence of an interaction with CD26

We describe the use of a new baculovirus expression vector to enable the secretion of the major surface glycoprotein of HIV-1 (gp120) fused to the carboxy-terminus of the widely used affinity tag glutathione S-transferase. The secreted protein can be purified in a single step with the minimum of denaturation on immobilised glutathione and is as active as the parental molecule in binding CD4. We use this molecule in a variety of assay formats to examine the gp120 interaction with CD26, a reported auxiliary molecule in the HIV entry process. We find no evidence of a CD26-gp120 interaction in the absence or presence of CD4.