Association of human immunodeficiency virus type 1 envelope glycoprotein with particles depends on interactions between the third variable and conserved regions of gp120.

Many regions within the envelope of human immunodeficiency virus type 1 (HIV-1) that affect its structure and function have been identified. We have previously reported that the interaction of the second conserved (C2) and third variable (V3) regions of gp120 influences the ability of HIV-1 to establish a productive infection in susceptible cells. To better understand the basis for this interaction, we have conducted structure-function analyses of envelope expressed from molecular proviral clones of HIV-1 containing defined mutations in C2 and V3 that individually and in combination differentially affect envelope function. The substitution of a glutamine for an asparagine residue (Q-267) at a potential asparagine-linked glycosylation site in C2, which severely impairs virus infectivity, reduces intracellular processing of gp160 into gp120, the association of gp120 with virions, and the ability of gp120 to bind to the HIV-1 cell surface receptor protein, CD4. The change of an arginine to an isoleucine codon in V3 (I-308), in the presence of the Q-267 mutation, restores virus infectivity to near wild-type levels by increasing the amount of gp120 associated with virions as compared with the Q-267 mutant but does not compensate for the Q-267-induced processing defect. The I-308 change in the context of the wild-type HIV-1 has no affect on processing, association, or CD4 binding. These results indicate that the impaired infectivity of the Q-267 mutant virus is due to a marked reduction in the amount of virion gp120 and suggest that the interaction of C2 and V3 stabilizes the association of gp120 with gp41.     

Strain specificity and binding affinity requirements of neutralizing monoclonal antibodies to the C4 domain of gp120 from human immunodeficiency virus type 1.

The binding properties of seven CD4-blocking monoclonal antibodies raised against recombinant gp120 of human immunodeficiency virus type 1 strain MN (HIV-1MN) and two CD4-blocking monoclonal antibodies to recombinant envelope glycoproteins gp120 and gp160 of substrain IIIB of HIVLAI were analyzed. With a panel of recombinant gp120s from seven diverse HIV-1 isolates, eight of the nine antibodies were found to be strain specific and one was broadly cross-reactive. Epitope mapping revealed that all nine antibodies bound to epitopes located in the fourth conserved domain (C4) of gp120. Within this region, three distinct epitopes could be identified: two were polymorphic between HIV-1 strains, and one was highly conserved. Studies with synthetic peptides demonstrated that the conserved epitope, recognized by antibody 13H8, was located between residues 431 and 439. Site-directed mutagenesis of gp120 demonstrated that residue 429 and/or 432 was critical for the binding of the seven antibodies to gp120 from HIV-1MN. Similarly, residues 423 and 429 were essential for the binding of monoclonal antibody 5C2 raised against gp120 from HIV-1IIIB. The amino acids located at positions 423 and 429 were found to vary between strains of HIV-1 as well as between molecular clones derived from the MN and LAI isolates of HIV-1. Polymorphism at these positions prevented the binding of virus-neutralizing monoclonal antibodies and raised the possibility that HIV-1 neutralization serotypes may be defined on the basis of C4 domain sequences. Analysis of the binding characteristics of the CD4-blocking antibodies demonstrated that their virus-neutralizing activity was directly proportional to their gp120-binding affinity. These studies account for the strain specificity of antibodies to the C4 domain of gp120 and demonstrate for the first time that antibodies to this region can be as effective as those directed to the principal neutralizing determinant (V3 domain) in neutralizing HIV-1 infectivity.     

Generation and characterization of monoclonal antibodies to the putative CD4-binding domain of human immunodeficiency virus type 1 gp120.

A panel of seven monoclonal antibodies against the relatively conserved CD4-binding domain on human immunodeficiency virus type 1 (HIV-1) gp120 was generated by immunizing mice with purified gp120. These monoclonal antibodies reacted specifically with gp120 in an enzyme-linked immunosorbent assay and Western blots (immunoblots). By using synthetic peptides as antigens in the immunosorbent assay, the epitopes of these seven monoclonal antibodies were mapped to amino acid residues 423 to 437 of gp120. Further studies with radioimmunoprecipitation assays showed that they cross-reacted with both gp120 and gp160 of diverse HIV-1 isolates (HTLV-IIIB, HTLV-IIIRF, HTLV-IIIAL, and HTLV-IIIWMJ). They also bound specifically to H9 cells infected with HTLV-IIIB, HTLV-IIIRF, HTLV-IIIAL, HTLV-IIIZ84, and HTLV-IIIZ34 in indirect immunofluorescence studies. In addition, they blocked effectively the binding of HIV-1 to CD4+ C8166 cells. Despite the similarity of these properties, the monoclonal antibodies differed in neutralizing activity against HTLV-IIIB, HTLV-IIIRF, and HTLV-IIIAL, as demonstrated in both syncytium-forming assays and infectivity assays. Our findings suggest that these group-specific monoclonal antibodies to the putative CD4-binding domain on gp120 are potential candidates for development of therapeutic agents against acquired immunodeficiency disease syndrome.     

Effects of second-site mutations on dominant interference by a human immunodeficiency virus type 1 envelope glycoprotein mutant.

We have demonstrated previously that a human immunodeficiency virus type 1 (HIV-1) envelope glycoprotein containing a Val-to-Glu substitution at the second amino acid of the transmembrane glycoprotein gp41 (termed the 41.2 mutant) dominantly interferes with wild-type envelope-mediated syncytium formation and virus infectivity. To understand the mechanism by which the 41.2 mutant exerts the dominant interfering phenotype and thereby determine further how the mutant might be used as an inhibitor of viral spread, additional mutations were made in the envelope gene, and the effects of these mutations on interference were determined. It was found that processing of the 41.2 mutant glycoprotein in gp120 and gp41 subunits and a functional CD4-binding domain are necessary for the interfering phenotype to be exhibited fully. However, neither a wild-type V3 loop nor the gp41 cytoplasmic tail is necessary for efficient interference. In addition, it was determined that the dominant interfering phenotype is not conferred exclusively by the glutamate substitution at amino acid 2 of gp41, since a substitution with a basic residue at this position also results in a dominant interfering envelope glycoprotein.     

Characterization of neutralizing monoclonal antibodies to linear and conformation-dependent epitopes within the first and second variable domains of human immunodeficiency virus type 1 gp120.

A number of linear and conformation-dependent neutralizing monoclonal antibodies (MAbs) have been mapped to the first and second variable (V1 and V2) domains of human immunodeficiency virus type 1 (HIV-1) gp120. The majority of these MAbs are as effective at neutralizing HIV-1 infectivity as MAbs to the V3 domain and the CD4 binding site. The linear MAbs bind to amino acid residues 162 to 171, and changes at residues 183/184 (PI/SG) and 191/192/193 (YSL/GSS) within the V2 domain abrogate the binding of the two conformation-dependent MAbs, 11/68b and CRA-4, respectively. Surprisingly, a change at residue 435 (Y/H or Y/S), in a region of gp120 near the CD4 binding site (M. Kowalski, J. Potz, L. Basiripour, T. Dorfman, W. C. Goh, E. Terwilliger, A. Dayton, C. Rosen, W. Haseltine, and J. Sodroski, Science 237:1351-1355, 1987; L. A. Lasky, G. M. Nakamura, D. H. Smith, C. Fennie, C. Shimasaki, E. Patzer, P. Berman, T. Gregory, and D. Capon, Cell 50:975-985, 1987; and U. Olshevsky, E. Helseth, C. Furman, J. Li, W. Haseltine, and J. Sodroski, J. Virol. 64:5701-5707, 1990), abrogated gp120 recognition by both of the conformation-dependent MAbs. However, both MAbs 11/68b and CRA-4 were able to bind to HIV-1 V1V2 chimeric fusion proteins expressing the V1V2 domains in the absence of C4, suggesting that residues in C4 are not components of the epitopes but that amino acid changes in C4 may affect the structure of the V1V2 domains. This is consistent with the ability of soluble CD4 to block 11/68b and CRA-4 binding to both native cell surface-expressed gp120 and recombinant gp120 and suggests that the binding of the neutralizing MAbs to the virus occurs prior to receptor interaction. Since the reciprocal inhibition, i.e., antibody inhibition of CD4-gp120 binding, was not observed, the mechanism of neutralization is probably not a blockade of virus-receptor interaction. Finally, we demonstrate that linear sequences from the V2 region are immunogenic in HIV-1-infected individuals, suggesting that the primary neutralizing response may be directed to both V2 and V3 epitopes.     

Discovery of small-molecule human immunodeficiency virus type 1 entry inhibitors that target the gp120-binding domain of CD4

The interaction between human immunodeficiency virus type 1 (HIV-1) gp120 and the CD4 receptor is highly specific and involves relatively small contact surfaces on both proteins according to crystal structure analysis. This molecularly conserved interaction presents an excellent opportunity for antiviral targeting. Here we report a group of pentavalent antimony-containing small molecule compounds, NSC 13778 (molecular weight, 319) and its analogs, which exert a potent anti-HIV activity. These compounds block the entry of X4-, R5-, and X4/R5-tropic HIV-1 strains into CD4(+) cells but show little or no activity in CD4-negative cells or against vesicular stomatitis virus-G pseudotyped virions. The compounds compete with gp120 for binding to CD4: either immobilized on a solid phase (soluble CD4) or on the T-cell surface (native CD4 receptor) as determined by a competitive gp120 capture enzyme-linked immunosorbent assay or flow cytometry. NSC 13778 binds to an N-terminal two-domain CD4 protein, D1/D2 CD4, immobilized on a surface plasmon resonance sensor chip, and dose dependently reduces the emission intensity of intrinsic tryptophan fluorescence of D1/D2 CD4, which contains two of the three tryptophan residues in the gp120-binding domain. Furthermore, T cells incubated with the compounds alone show decreased reactivity to anti-CD4 monoclonal antibodies known to recognize the gp120-binding site. In contrast to gp120-binders that inhibit gp120-CD4 interaction by binding to gp120, these compounds appear to disrupt gp120-CD4 contact by targeting the specific gp120-binding domain of CD4. NSC 13778 may represent a prototype of a new class of HIV-1 entry inhibitors that can break into the gp120-CD4 interface and mask the gp120-binding site on the CD4 molecules, effectively repelling incoming virions.     

The viral envelope gene is involved in macrophage tropism of a human immunodeficiency virus type 1 strain isolated from brain tissue.

Human immunodeficiency virus type 1 (HIV-1) strains isolated from the central nervous system (CNS) may represent a subgroup that displays a host cell tropism different from those isolated from peripheral blood and lymph nodes. One CNS-derived isolate, HIV-1SF128A, which can be propagated efficiently in primary macrophage culture but not in any T-cell lines, was molecularly cloned and characterized. Recombinant viruses between HIV-1SF128A and the peripheral blood isolate HIV-1SF2 were generated in order to map the viral gene(s) responsible for the macrophage tropism. The env gene sequences of the two isolates are about 91.1% homologous, with variations scattered mainly in the hypervariable regions of gp120. Recombinant viruses that have acquired the HIV-1SF128A env gene display HIV-1SF128A tropism for macrophages. Furthermore, the gp120 variable domains, V1, V2, V4, and V5, the CD4-binding domain, and the gp41 fusion domain are not directly involved in determining macrophage tropism.     

Identification of the HIV-1 gp41 core-binding motif in the scaffolding domain of caveolin-1

The human immunodeficiency virus, type 1 (HIV-1) gp41 core plays an important role in fusion between viral and target cell membranes. A single chain polypeptide, N36(L8)C34, which forms a six-helix bundle in physiological solution, can be used as a model of gp41 core. Here we identified from a 12-mer phage peptide library a positive phage clone displaying a peptide sequence with high binding activity to the HIV-1 gp41 core. The peptide sequence contains a putative gp41-binding motif, PhiXXXXPhiXPhi (X is any amino acid residue, and Phi is any one of the aromatic amino acid residues Trp, Phe, or Tyr). This motif also exists in the scaffolding domain of caveolin-1 (Cav-1), a known gp41-binding protein. Cav-1-(61-101) and Cav-1-(82-101), two recombinant fusion proteins containing the Cav-1 scaffolding domain, bound significantly to the gp41 expressed in mammalian cells and interacted with the polypeptide N36(L8)C34. These results suggest that the scaffolding domain of Cav-1 may bind to the gp41 core via the motif. This interaction may be essential for formation of fusion pore or endocytosis of HIV-1 and affect the pathogenesis of HIV-1 infection. Further characterization of the gp41 core-binding motifs may shed light on the alternative mechanism by which HIV-1 enters into the target cell.     

Functional interaction of constant and variable domains of human immunodeficiency virus type 1 gp120.

A previously reported amino acid substitution within the second conserved domain of the human immunodeficiency virus type 1 (HIV-1) gp120 envelope results in the production of noninfectious particles. Molecular characterization of spontaneous revertant viruses, which arose during long-term cocultures of this env mutant, revealed that an amino acid change within another region of gp120 could functionally compensate for the mutation and restore infectivity. In the current study, we have introduced a conservative amino acid substitution at this second-site revertant codon and observed a marked reduction in HIV-1 infectivity. During the passage of this defective virus in cocultures, yet another revertant appeared which contained an amino acid change within a variable region of gp120 which restored infectivity to near wild-type levels. These results, in combination with other point mutations that have been introduced into the HIV-1 envelope, suggest that at least three discrete regions of gp120 may interact during the establishment of a productive viral infection. This critical step occurs subsequent to the adsorption of virions to the cell surface and either prior to or concomitant with the fusion of viral and cellular membranes.     

Identification of the optimal DC-SIGN binding site on human immunodeficiency virus type 1 gp120

Human immunodeficiency virus type 1 (HIV-1) envelope (gp120) binding to DC-SIGN, a C-type lectin that can facilitate HIV infection in cis and in trans, is largely dependent on high-mannose-content moieties. Here, we delineate the N-linked glycosylation (N-glycan) sites in gp120 that contribute to optimal DC-SIGN binding. Soluble DC-SIGN was able to block 2G12 binding to gp120, but not vice versa, suggesting that DC-SIGN binds to a more flexible combination of N-glycans than 2G12. Consistent with this observation, HIV strain JRCSF gp120 prebound to 2G12 was 10-fold more sensitive to mannan competition than gp120 that was not prebound in a DC-SIGN cell surface binding assay. The analysis of multiple mutant forms of the 2G12 epitope revealed one triple glycosylation mutant form, termed 134mut (carrying N293Q, N382Q, and N388Q mutations), that exhibited a significant increase in sensitivity to both mannan competition and endoglycosidase H digestion compared to that of the 124mut form (carrying N293Q, N328Q, and N388Q mutations) and wild-type gp120 in a DC-SIGN binding assay. Importantly, no such differences were observed when binding to Galanthus nivalis was assessed. The 134mut form of gp120 also exhibited decreased binding to DC-SIGN in the context of native envelope spikes on a virion, and virus bearing 134mut exhibited less efficient DC-SIGN-mediated infection in trans. Significantly, 124mut and 134mut differed by only one glycosylation site mutation in each construct, and both 124mut and 134mut viruses exhibited wild-type levels of infectivity when used in a direct infection assay. In summary, while DC-SIGN can bind to a flexible combination of N-glycans on gp120, its optimal binding site overlaps with specific N-glycans within the 2G12 epitope. Conformationally intact envelopes that are DC-SIGN binding deficient can be used to probe the in vivo biological functions of DC-SIGN.