Antigenic implications of human immunodeficiency virus type 1 envelope quaternary structure: oligomer-specific and -sensitive monoclonal antibodies.

A majority of monoclonal antibodies (mAbs) raised against soluble oligomeric human immunodeficiency virus type 1 isolate IIIB (HIV-1IIIB) envelope (env) glycoprotein reacted with conformational epitopes within the gp120 or gp41 subunits. Of 35 mAbs directed against gp41, 21 preferentially reacted with oligomeric env. A subset of these mAbs reacted only with env oligomers (oligomer-specific mAbs). In contrast, only 1 of 27 mAbs directed against the gp120 subunit reacted more strongly with env oligomers than with monomers, and none were oligomer-specific. However, 50% of anti-gp120 mAbs preferentially recognized monomeric env, suggesting that some epitopes in gp120 are partially masked or altered by intersubunit contacts in the native env oligomer. Two mAbs to oligomer-dependent epitopes in gp41 neutralized HIV-1IIIB and HIV-1SF2, and binding of these mAbs to env was blocked by preincubation with HIV-1-positive human serum. Thus, immunization with soluble, oligomeric env elicits antibodies to conserved, conformational epitopes including a newly defined class of neutralizing antibodies that bind to oligomer-specific epitopes in gp41, and may also minimize the production of antibodies that preferentially react with monomeric env protein.     

Localization of B-cell stimulatory activity of HIV-1 to the carboxyl terminus of gp41

Patients with AIDS are known to have B-cell hyperactivity. We have previously demonstrated that an extract of HIV-1 could induce differentiation of peripheral blood B lymphocytes of healthy volunteers into immunoglobulin-secreting cells. In an attempt to delineate the B-cell stimulatory subregion in HIV-1, we have investigated the influences of native glycoproteins and recombinant proteins of the envelope. The complete envelope glycoprotein, gp160 and a recombinant protein in the carboxyl terminal region of gp41 termed PE-8 were effective in inducing terminal differentiation of normal peripheral blood B lymphocytes and did so in a T-lymphocyte-dependent manner. The activity was not present in the native exterior envelope glycoprotein, gp120 and several other recombinant proteins, viz PE-2 an PE-3, which are in the amino terminal region of gp120 or in env-9, a protein in the junctional region of gp120 and gp41. Polyclonal and monoclonal antibodies directed to diverse regions of the envelope abrogated the influence of gp160. The PE-8-induced B-cell differentiation was abrogated by goat anti-gp160 antibody but not by goat anti-gp120 antibody or monoclonal antibody to the amino terminal of gp41. These studies suggest that a putative polyclonal B-cell stimulatory epitope of HIV-1 is located in the carboxyl end of the envelope glycoprotein.     

Human immunodeficiency virus-infected T cells and monocytes are killed by monoclonal human anti-gp41 antibodies coupled to ricin A chain

Two human monoclonal antibodies specific for the envelope glycoprotein (gp), gp41, of the human immunodeficiency virus were conjugated to deglycosylated ricin A chain. These immunotoxins killed human immunodeficiency virus-infected H9 (T cell) and U937 (monocyte) cell lines but were nontoxic to the uninfected cell lines or to class II-positive Daudi cells. Specific killing of infected H9 cells could be completely blocked by recombinant gp160 and partially blocked by unconjugated anti-gp41 antibody but was not blocked by recombinant gp120 or human IgG demonstrating specificity for gp41. The specific toxicity of the immunotoxins for infected U937 cells was markedly potentiated by chloroquine.     

Bispecific antibody targeting of human immunodeficiency virus type 1 (HIV-1) glycoprotein 41 to human macrophages through the Fc IgG receptor I mediates neutralizing effects in HIV-1 infection.

Human monocyte-derived macrophages that express the CD4 molecule and the Fc receptor for IgG (Fc gamma R) play a major role in the pathogenesis of human immunodeficiency virus (HIV) infection. To explore this possibility further, human monoclonal antibody to glycoprotein 41 (gp41) was produced, and a heterobifunctional antibody composed of F(ab') x F(ab')2 fragments of monoclonal anti-gp41 and anti-Fc gamma RI 22.2 were constructed. Both antibodies were analyzed for neutralizing effects, and the role of the CD4 molecule in HIV infection was studied with human monocyte-derived macrophages. The bispecific antibody exhibited strong neutralizing properties, in contrast to the monoclonal anti-gp41 antibody. Moreover, in the presence of monoclonal anti-Leu-3a antibody, viral production was completely inhibited. These findings demonstrate the necessity of the CD4 molecule in HIV infection of human macrophages and emphasize the usefulness of such heterobifunctional antibody directed to virus and monocyte-derived macrophage Fc receptors in prevention of HIV infection.     

Induction of antibodies to the envelope protein of the human immunodeficiency virus by immunization with monoclonal anti-idiotypes.

Anti-idiotypes that possess the internal image of antigen can induce protective humoral immunity toward microbes. Herein we demonstrate antigen mimicry by monoclonal anti-idiotypes of a distinct epitope of the human immunodeficiency virus (HIV) envelope protein that is defined by a synthetic peptide. This peptide, corresponding to amino acid residues 503-535 (peptide 503-535) of HIV-1 IIIB gp160, induced antibodies in three mammalian species that interacted with HIV-1 gp120 and inhibited in vitro syncytium formation caused by HIV-1, IIIB and MN isolates. Three monoclonal anti-idiotypes were generated against rabbit anti-gp120 antibodies specific for peptide 503-535. These anti-idiotypes recognize an interspecies cross-reactive idiotype expressed on mouse, chimpanzee, baboon, rabbit, and human anti-gp120 antibodies specific for peptide 503-535. The interaction with the cross-reactive idiotype is inhibited by synthetic peptide and HIV-1 gp160. Furthermore, rabbits immunized with the monoclonal anti-idiotypes produced antibodies that also bind HIV-1 gp120 and gp160 and recognized the epitope defined by peptide 503-535.     

Characterization of recombinant gp120 and gp160 from HIV-1: binding to monoclonal antibodies and soluble CD4

We compared four preparations of recombinant HIV-1 envelope glycoprotein: mammalian (Chinese hamster ovary cells) gp120 (Celltech); baculovirus gp120 from American Biotechnologies Inc. (ABT) and from MicroGeneSys (MGS); and baculovirus gp160 (Institute of Virology, Oxford, UK). Each envelope glycoprotein binds to a neutralizing monoclonal antibody (MAb) directed against the V3 loop, confirming the integrity of this type-specific neutralization epitope. MGS gp120 binds abnormally well to a MAb which recognizes an epitope preferentially exposed on denatured gp120. Consistent with this finding, MGS gp120 binds to soluble CD4 (sCD4) with an affinity 50-100-fold lower than that of Celltech gp120. The affinity of Celltech gp120 from sCD4 is 2.3 nM, indistinguishable from that of gp120 extracted from HIV-1 virions. Baculovirus gp120 (ABT) and gp160 also have a high affinity for sCD4. A significant proportion of anti-gp120 antibodies in HIV-positive human sera recognize epitopes that are dependent on the mammalian glycosylation pattern, and a human HIV-positive serum inhibits the binding of mammalian gp120 to sCD4 five- to 10-fold more potently than it inhibits baculovirus gp120 binding to sCD4.     

Antibodies to the major merozoite surface coat protein of Plasmodium falciparum (gp195) in a human population living in a malaria-endemic area of the Philippines.

The seroprevalence of naturally acquired antibodies against Plasmodium falciparum merozoite surface protein gp195 was assessed in 726 individuals living in the Napsan region of Palawan in The Philippines. Antibodies against gp195 were detected using parasite-derived antigens in an enzyme-linked immunosorbent assay. The lowest seroprevalence of anti-gp195 antibodies (45%) was found in the 0-4-year-old age group. By 10-19 years of age, the seroprevalence of anti-gp195 antibodies had leveled off at approximately 90%. Anti-gp195 antibody titers were determined for 59 randomly selected individuals using parasite-derived gp195 and two yeast recombinant polypeptides corresponding to the N-terminal (195A) and C-terminal (p42) processing fragments of gp195. For each antigen, the lowest antibody titers were found in the 0-4-year-old age group. The 5-9-year-old age group had anti-gp195 antibody titers comparable with the older age groups. Immunoblotting experiments with parasite-derived gp195 revealed that all serum samples tested had detectable antibodies to the 195-kD gp195 precursor molecule and the 83-kD N-terminal processing fragment. Individuals with anti-gp195 titers greater than 1:400 had antibodies against both the N-terminal and C-terminal processing fragments of gp195. These results suggest that the gp195 C-terminal region may be less immunogenic than the N-terminal region when presented on the parasite surface during natural malaria infections.     

Human monoclonal antibody that recognizes the V3 region of human immunodeficiency virus gp120 and neutralizes the human T-lymphotropic virus type IIIMN strain.

We describe a human IgG1 monoclonal antibody (N701.9b) derived by Epstein-Barr virus transformation of B cells from a human immunodeficiency virus-seropositive asymptomatic donor. This antibody was shown to recognize the principal neutralizing domain contained within the V3 region of gp120 of the MN strain of human immunodeficiency virus and MN-like strains, as determined by binding to the PB-1 fragment of MN gp120 and to synthetic peptides corresponding to the V3 region of MN and related virus strains. The epitope identified by monoclonal antibody N701.9b was mapped to a segment of V3 containing at least 7 amino acids (amino acids 316-322), which is located in the "tip" and "right" side of the V3 loop of the MN strain. Furthermore, this antibody manifested potent type-specific fusion-inhibitory activity against the MN strain but not against the IIIB or RF virus strains. This antibody also neutralized four virus isolates that had MN-like V3 region sequences and failed to neutralize three other strains containing unrelated V3 region sequences. Our findings confirm that the V3 region stimulates type-specific neutralizing antibody during natural human immunodeficiency virus infection in humans. The potential clinical use of this antibody is discussed.     

Limited or no protection by weakly or nonneutralizing antibodies against vaginal SHIV challenge of macaques compared with a strongly neutralizing antibody

To guide vaccine design, we assessed whether human monoclonal antibodies (MAbs) b12 and b6 against the CD4 binding site (CD4bs) on HIV-1 gp120 and F240 against an immundominant epitope on gp41 could prevent vaginal transmission of simian HIV (SHIV)-162P4 to macaques. The two anti-gp120 MAbs have similar monomeric gp120-binding properties, measured in vitro, but b12 is strongly neutralizing and b6 is not. F240 is nonneutralizing. Applied vaginally at a high dose, the strongly neutralizing MAb b12 provided sterilizing immunity in seven of seven animals, b6 in zero of five animals, and F240 in two of five animals. Compared with control animals, the protection by b12 achieved statistical significance, whereas that caused by F240 did not. For two of three unprotected F240-treated animals there was a trend toward lowered viremia. The potential protective effect of F240 may relate to the relatively strong ability of this antibody to capture infectious virions. Additional passive transfer experiments also indicated that the ability of the administered anti-gp120 MAbs to neutralize the challenge virus was a critical influence on protection. Furthermore, when data from all of the experiments were combined, there was a significant increase in the number of founder viruses establishing infection in animals receiving MAb b6, compared with other nonprotected macaques. Thus, a gp120-binding, weakly neutralizing MAb to the CD4bs was, at best, completely ineffective at protection. A nonneutralizing antibody to gp41 may have a limited capacity to protect, but the results suggest that the central focus of HIV-1 vaccine research should be on the induction of potently neutralizing antibodies.     

Protection of neutralization epitopes in the V3 loop of oligomeric human immunodeficiency virus type 1 glycoprotein 120 by N-linked oligosaccharides in the V1 region

The V3 region of the human immunodeficiency virus type 1 envelope protein gp120 constitutes a potential neutralization target, but the oligosaccharide of one conserved N-glycosylation site in this region protects it from neutralizing antibodies. Here, we determined whether N-linked glycans of other gp120 domains were also involved in protection of V3 neutralization epitopes. Two molecular clones of HIV-1, one lacking three N-linked glycans of the V1 region (HIV-1(3N/V1)) and another lacking three N-linked glycans of the C2 region (HIV-1(3N/C2)), were created and characterized. gp120 from both mutated viral clones had higher electrophoretic mobilities than gp120 from wild-type virus, confirming loss of N-linked glycans. Wild-type virus and both mutant clones replicated equally well in established T cell lines and all three viruses were able to utilize CXCR4 but not CCR5 as a coreceptor. The induced mutations increased gp120 affinity for CXCR4 but caused no corresponding increase in viral ability to replicate in T cell lines. HIV-1(3N/V1) was neutralized at about 25 times lower concentrations of an antibody to the V3 region than were wild-type virus and HIV-1(3N/C2). Soluble, monomeric gp120 from HIV-1(3N/V1) and wild type virus had identical avidity for the V3 antibody, indicating that the V1 glycans were able to shield V3 only in oligomeric but not monomeric gp120. In conclusion, one or more N-linked glycans of gp120 V1 is engaged in protection of the V3 region from potential neutralizing antibodies, and this effect is dependent on the oligomeric organization of gp120/gp41.     

Mouse monoclonal antibody 5-21-3 recognizes a contiguous, conformation-dependent epitope and maps to a hydrophilic region in HIV-1 gp41.

Mouse monoclonal antibody 5-21-3 is mapped to an epitope within a hydrophilic region of HIV-1 gp41 between amino acids 642 and 665 (numbering by Meyers et al. based on HXB2 isolate). The epitope is formed from amino acids within the sequence IHSLIEESQNQQEKNEQELLELDK; however, antibody 5-21-3 is unable to recognize the epitope-forming sequence when it is presented to the antibody in the form of a short (642-665) synthetic polypeptide. The epitope apparently is partially formed when additional native sequence of varying length is added to the amino and/or carboxy ends of the epitope-forming sequence, and 5-21-3 binds these larger synthetic polypeptides to varying degrees depending on the position and length of the flanking sequences. The 5-21-3 epitope apparently is formed from contiguous amino acids which require a specific, conformation-dependent, secondary structure for proper epitope formation. Binding preferences exhibited by 5-21-3 toward synthetic polypeptides and recombinant proteins may reflect the conformational nature of the epitope in disrupted HIV which elicited formation of the monoclonal.     

Characterization of a monoclonal antibody specific for the HIV-1 precursor glycoprotein

HIV-1 infected Molt4-T4 cells provide an efficient system for the production of cellular precursor gp160 of HIV envelope glycoproteins, gp120 and gp41. The precursor gp160 was purified on an immuno-affinity column containing antibodies from sera of HIV-1-seropositive patients. The precursor gp160 was then isolated by preparative polyacrylamide gel electrophoresis. Two out of four Balb/c mice, immunized with these purified preparations of gp160, developed specific circulating antibodies. A hybridoma cell line was subsequently isolated producing monoclonal antibody KL49/19 (IgG1, K) specific for gp160. This monoclonal antibody can specifically immunoprecipitate gp160, existing in HIV-1-infected cells. In an immunoblotting assay, it identifies mainly gp160 and shows a slight affinity for the mature glycoprotein, gp120. The monoclonal antibody is probably directed against an epitope in the polypeptide residue of gp160 since it can recognize a deglycosylated polypeptide of molecular weight 90,000, a product of gp160 digestion by endoglycosidase H (Endo H). It does not cross-react with any protein of HIV-2 by immunoblot or immunoprecipitation assays. By virtue of its specificity, the monoclonal antibody KL49/19 might provide a powerful probe with which to detect gp160 in cells which might partially express the HIV-1 genes.     

Monoclonal antibodies to the extracellular domain of HIV-1IIIB gp160 that neutralize infectivity, block binding to CD4, and react with diverse isolates.

Ten monoclonal antibodies prepared against a soluble, recombinant form of gp160, derived from the IIIB isolate of HIV-1, were characterized. Four of the antibodies neutralized HIV-1IIIB infectivity in vitro, three blocked the binding of recombinant gp120 to CD4, three were reactive with gp41, and one preferentially reacted with an epitope on gp120 within the gp160 precursor. All three CD4 blocking antibodies bound to distinct epitopes, with one mapping to the C1 domain, one mapping to the C4 domain, and one reactive with a conformation-dependent, discontinuous epitope. Of these, the antibody reactive with the discontinuous epitope exhibited neutralizing activity against homologous and heterologous strains of HIV-1. The binding of these monoclonal antibodies to a panel of seven recombinant gp120s prepared from diverse isolates of HIV-1 was measured, and monoclonal antibodies with broad cross reactivity were identified. The epitopes recognized by 7 of the 10 monoclonal antibodies studied were localized by their reactivity with synthetic peptides and with fragments of gp120 expressed as fusion proteins in a lambda gt-11 gp160 epitope library.     

Immunogenicity and epitope mapping of a recombinant soluble gp160 of the human immunodeficiency virus type 1 envelope glycoprotein.

The human immunodeficiency virus 1 envelope glycoprotein is synthesized as a precursor, gp160, which is subsequently cleaved to generate the external gp120 and the transmembrane gp41. Both of these cleavage products are known to mediate critical functions of the virus. In order to define the best strategy for the development of a vaccine against human immunodeficiency virus 1, it could be important to map the crucial epitopes on gp160. This entire gp160 is uneasy to purify because it is readily subjected to proteolytic cleavage. Furthermore, it is anchored on the cell membrane and needs detergent treatment for purification. We thus used a recombinant gp160 which was engineered to remove the cleavage sites between gp120 and gp41 and the hydrophobic transmembrane in order to investigate the murine immune response. We selected a panel of 8 monoclonal antibodies which recognize different epitopes on the immunizing recombinant soluble gp160. The reactivity of the monoclonal antibodies was checked on virus-derived gp160, gp120, and gp41. Three antibodies reacted only with gp120 but the others were shown to react with gp41 epitopes or with discontinuous epitopes bridging gp120 and gp41. One subregion of these epitopes was located using a synthetic peptide corresponding to the sequence of gp41. This epitope is apparently part of an immunodominant site since it is recognized by three different monoclonal antibodies. We used competitive inhibition experiments to map the epitopes on recombinant gp160; therefore, the results are probably indicative of the folding of the recombinant soluble gp160 used for immunization.     

Monoclonal antibodies that bind to the core of fusion-active glycoprotein 41

The heptad repeat regions HR1 and HR2 of HIV-1 gp41 can associate to form heterooligomers through helical coil-coil interactions that are believed to play a key role in virus-induced membrane fusion. The HR1/HR2 complex was proposed to be the core structure of the fusion-active conformation of gp41. Here, we show that two human monoclonal antibodies, Fab-d and 50-69, specifically recognize the putative fusion-active conformation of gp41. Fab-d binding requires the interaction between the HR1 and HR2 regions of gp41. The reactivity of human monoclonal antibody 50-69 to the C terminus of the HR1 sequence is dependent on the helical structure of HR1. It appears that HR2 is able to interact with HR1 and, subsequently, induce an epitope in HR1 that is required for 50-69 binding. Mutations that disrupt the helical structure of HR1 significantly compromise Fab-d and 50-69 binding. Although the epitopes are not identical, the ability of Fab-d to partially compete with 50-69 binding suggests a close proximity of the two epitopes. Antibodies that are able to interact with the core of the putative fusion-active gp41 may be useful in further unveiling the mechanism of HIV-induced membrane fusion.     

Neutralization of divergent human immunodeficiency virus type 1 variants and primary isolates by IAM-41-2F5, an anti-gp41 human monoclonal antibody.

The antiviral characteristics of monoclonal antibody IAM-41-2F5 (2F5) were determined in cell culture. The antibody had been previously shown to bind a specific sequence, ELDKWA, within the external domain of the gp41 envelope glycoprotein human immunodeficiency virus type 1 (HIV-1). Selection by 2F5 of recombinant phage from an epitope library confirmed the identification of the antibody's binding determinant. The antibody was found to be capable of neutralizing a broad range of lymphoid cell culture-adapted HIV-1 variants as well as HIV-1 primary isolates. Sequence analysis of the latter showed that neutralization was related to the presence of the antibody binding site. From kinetic measurements using an epitope-containing peptide or gp41, the half-time of dissociation for 2F5 was determined to be 122 min for the peptide and 156 min for gp41. The region of gp41 expressing this sequence exhibits greater conservation among HIV-1 isolates than do the variable domains of gp120.     

Anti-CD4 anti-idiotype antibodies in volunteers immunized with rgp160 of HIV-1 or infected with HIV-1.

We examined the sera of volunteers vaccinated with recombinant gp160 of human immunodeficiency virus type 1 (HIV-1) and control volunteers for the presence of anti-(anti-gp160 idiotype) antibodies which antigenically mimic gp160 and, therefore, bind to CD4 on human cells. Anti-CD4 antibodies were detected in the sera of 3 of 5 rgp160 recipients and 1 of 5 controls by indirect immunofluorescence using CD4-transfected HeLa cells or enzyme-linked immunosorbent assay (ELISA) using recombinant soluble CD4 as the solid phase. The control volunteer who was positive subsequently developed antibodies to HIV-1 by Western blot analysis. The anti-CD4 antibodies detected in the sera of the rgp160 vaccinees and the control volunteer appeared to be anti-idiotypic in nature, reacting with a paratope expressed on goat anti-gp160 antibodies but not on antibodies from normal goat serum. Binding to either transfected CD4+ HeLa cells or blotted anti-gp160 serum could be inhibited by preincubating the anti-CD4 serum with soluble CD4, or preincubating the cells or blotted anti-gp160 serum with recombinant gp160. Anti-CD4 antibodies were initially detectable only after the antibody response to gp160 began to decrease in the vaccinees, and the HIV-1-infected volunteer mounted a detectable anti-HIV-1 antibody response only after a decline in the anti-CD4 antibodies in his serum. These data strongly suggest that anti-CD4 antibodies which are anti-idiotypic to a paratope expressed on anti-gp160 antibodies are generated in response to both vaccination with rgp160 and infection with HIV-1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Monoclonal antibodies to HTLV-III451 gp41: delineation of an immunoreactive conserved epitope in the transmembrane region of divergent isolates of HIV-1

We report on the development of monoclonal antibodies directed against the transmembrane portion of the envelope of HTLV-III451 gp41. One of these monoclonal antibodies, designated M71/2B4, was found to cross-react with transmembrane proteins from other independent isolates of HIV-1, namely IIIB, MN, and RF. Thus, this monoclonal antibody identifies an epitope located in a region of gp41 that is conserved among all these isolates. To identify this conserved region a series of E. coli recombinant proteins were screened in immunoblot with M71/2B4. From these results the epitope recognized by this antibody appears to map at the amino terminus of gp41, in the region indicated between the cleavage site with gp120 (aa 508) and the HindIII site (aa647).     

A conserved region at the COOH terminus of human immunodeficiency virus gp120 envelope protein contains an immunodominant epitope.

A highly immunogenic epitope from a conserved COOH-terminal region of the human immunodeficiency virus (HIV) gp120 envelope protein has been identified with antisera from HIV-seropositive subjects and a synthetic peptide (SP-22) containing 15 amino acids from this region (Ala-Pro-Thr-Lys-Ala-Lys-Arg-Arg-Val-Val-Gln-Arg-Glu-Lys-Arg). Peptide SP-22 absorbed up to 100% of anti-gp120 antibody reactivity from select HIV+ patient sera in immunoblot assays and up to 79% of serum anti-gp120 antibody reactivity in competition RIA. In RIA, 45% of HIV-seropositive subjects had antibodies that bound to peptide SP-22. Human anti-SP-22 antibodies that bound to and were eluted from an SP-22 affinity column reacted with gp120 in RIA and immunoblot assays but did not neutralize HIV or inhibit HIV-induced syncytium formation in vitro, even though these antibodies comprised 70% of all anti-gp120 antibodies in the test serum. In contrast, the remaining 30% of SP-22 nonreactive anti-gp120 antibodies did not react with gp120 in immunoblot assays but did not react in RIA and neutralized HIV in vitro. Thus, approximately 50% of HIV-seropositive patients make high titers of nonneutralizing antibodies to an immunodominant antigen on gp120 defined by SP-22. Moreover, the COOH terminus of gp120 contains the major antigen or antigens identified by human anti-gp120 antibodies in immunoblot assays.     

Characterization of the secreted, native gp120 and gp160 of the human immunodeficiency virus type 1

We have previously shown that the cell line 6D5(451) chronically infected with the HIV-1 isolate HTLV-III(451), secretes the HIV-1 envelope glycoproteins gp120 and gp160 in the extracellular medium. The HTLV-III(451) gp120 and gp160 were purified by sequential affinity chromatographic steps using a monoclonal antibody to HIV-1 gp41 and an anti-HIV-1-positive human serum. Amino acid sequence analysis of gp120 and gp160 showed the loss of the signal peptide. Digestion of the purified gp120 and gp160 with endoglycosidases revealed that both proteins are heavily glycosylated and contain complex carbohydrates, in contrast to the intracellular form of gp160 which has been shown to contain mannose-rich immature sugars. Competitive binding analysis showed that while both gp120 and gp160 bind CD4, the affinity of gp160 was five times lower than that of gp120. Both gp120 and gp160 inhibited syncytia formation by HIV-1-infected cells when mixed with CD4+ cells. Furthermore, both gp120 and gp160 had strong mitogenic effects on the T cells from HIV-1-infected gibbons but not on cells from uninfected gibbons.