Infection of chimpanzee peripheral blood mononuclear cells by human immunodeficiency virus type 1 requires cooperative interaction between multiple variable regions of gp120.

We have recently reported the isolation and molecular cloning of a human immunodeficiency virus type 1 isolate (HIV-1 DH125) that exhibits rapid replication kinetics and marked cytopathicity in both human and chimpanzee peripheral blood mononuclear cells (PBMC). To identify the viral determinants responsible for infectivity of chimpanzee PBMC, chimeric viruses containing the following components were constructed: (i) the entire envelope gene; (ii) gp120 sequences; (iii) gp41 sequences; and (iv) individual or various combinations of the gp120 variable regions of HIV-1 DH125 inserted into the backbone of another HIV-1 isolate (HIV-1 AD8), which is unable to infect chimpanzee PBMC. Analyses of virus replication kinetics in human and chimpanzee PBMC revealed that gp120 contains determinants which confer infectivity for chimpanzee PBMC and that the capacity to establish such an infection requires the cooperative interaction between multiple variable regions of the HIV-1 DH125 gp120.     

Importance of the V1/V2 loop region of simian-human immunodeficiency virus envelope glycoprotein gp120 in determining the strain specificity of the neutralizing antibody response

Plasma samples from individuals infected with human immunodeficiency virus type 1 (HIV-1) are known to be highly strain specific in their ability to neutralize HIV-1 infectivity. Such plasma samples exhibit significant neutralizing activity against autologous HIV-1 isolates but typically exhibit little or no activity against heterologous strains, although some cross-neutralizing activity can develop late in infection. Monkeys infected with the simian-human immunodeficiency virus (SHIV) clone DH12 generated antibodies that neutralized SHIV DH12, but not SHIV KB9. Conversely, antibodies from monkeys infected with the SHIV clone KB9 neutralized SHIV KB9, but not SHIV DH12. To investigate the role of the variable loops of the HIV-1 envelope glycoprotein gp120 in determining this strain specificity, variable loops 1 and 2 (V1/V2), V3, or V4 were exchanged individually or in combination between SHIV DH12 and SHIV KB9. Despite the fact that both parental viruses exhibited significant infectivity and good replication in the cell lines examined, 3 of the 10 variable-loop chimeras exhibited such poor infectivity that they could not be used further for neutralization assays. These results indicate that a variable loop that is functional in the context of one particular envelope background will not necessarily function within another. The remaining seven replication-competent chimeras allowed unambiguous assignment of the sequences principally responsible for the strain specificity of the neutralizing activity present in SHIV-positive plasma. Exchange of the V1/V2 loop sequences conferred a dominant loss of sensitivity to neutralization by autologous plasma and a gain of sensitivity to neutralization by heterologous plasma. Substitution of V3 or V4 had little or no effect on the sensitivity to neutralization. These data demonstrate that the V1/V2 region of HIV-1 gp120 is principally responsible for the strain specificity of the neutralizing antibody response in monkeys infected with these prototypic SHIVs.     

Evidence for a functional interaction between the V1/V2 and C4 domains of human immunodeficiency virus type 1 envelope glycoprotein gp120.

The domains of the human immunodeficiency virus type 1 (HIV-1) envelope glycoprotein that are required for envelope function have been partially characterized. Little is known, however, about the nature of the interactions between these domains. To identify regions of the HIV-1 envelope glycoprotein that are involved in interactions necessary for proper envelope function, we constructed a series of 14 envelope recombinants between the env genes of two HIV-1 isolates. The envelope chimeras were examined for their ability to induce syncytia, to be proteolytically processed, and to function during a spreading viral infection. Our results demonstrate that the exchange between the two isolates of the first and second hypervariable regions (V1/V2) of gp120 results in defects in envelope glycoprotein processing, syncytium formation, and infectivity. Long-term passage of cultures infected with virus bearing a V1/V2 chimeric envelope glycoprotein leads to the emergence of a revertant virus with replication characteristics comparable to those of the wild type. Analysis of the revertant indicated that an Ile-->Met change in the C4 region of gp120 (between hypervariable regions V4 and V5) is responsible for the revertant phenotype. This single amino acid change restores infectivity without significantly affecting gp160 processing, CD4 binding, or the levels of virion-associated gp120. While the Ile-->Met change in C4 greatly enhances the fusogenic potential of the V1/V2 chimeric envelope glycoprotein, it has a detrimental effect on syncytium formation when analyzed in the context of the wild-type envelope. These results suggest that an interaction required for proper envelope glycoprotein function occurs between the V1/V2 and C4 regions of gp120.     

Functional role of the V1/V2 region of human immunodeficiency virus type 1 envelope glycoprotein gp120 in infection of primary macrophages and soluble CD4 neutralization.

We have examined the influence of the V1/V2 region of the human immunodeficiency virus type 1 (HIV-1) gp120 on certain biologic properties of the virus. We observed that on the genomic background of the T-cell-line-tropic strain, HIV-1SF2mc, both the V1 and V2 domains of the macrophage-tropic strain, HIV-1SF162mc, in addition to the required V3 domain, are necessary to attain full macrophage tropism. Furthermore, the V2 domain modulates the sensitivity of HIV-1 to soluble CD4 neutralization. Structural studies of recombinant and mutant envelope glycoproteins suggest that the function of the V1/V2 region is to interact with the V3 domain and confer on the envelope gp120 of HIV-1SF2mc a conformation more similar to that of the macrophage-tropic strain HIV-1SF162mc. The conformation of the envelope gp120 appears to be strain specific and plays an important role in determining HIV-1 tissue tropism and sensitivity to soluble CD4 neutralization.     

An Envelope Modification That Renders a Primary, Neutralization-Resistant Clade B Human Immunodeficiency Virus Type 1 Isolate Highly Susceptible to Neutralization by Sera from Other Clades

SF162 is a primary (PR), non-syncytium-inducing, macrophagetropic human immunodeficiency virus type 1 (HIV-1) clade B isolate which is resistant to antibody-mediated neutralization. Deletion of the first or second hypervariable envelope gp120 region (V1 or V2 loop, respectively) of this virus does not abrogate its ability to replicate in peripheral blood mononuclear cells and primary macrophages, nor does it alter its coreceptor usage profile. The mutant virus with the V1 loop deletion, SF162ΔV1, remains as resistant to antibody-mediated neutralization as the wild-type virus SF162. In contrast, the mutant virus with the V2 loop deletion, SF162ΔV2, exhibits enhanced susceptibility to neutralization by certain monoclonal antibodies whose epitopes are located within the CD4-binding site and conserved regions of gp120. More importantly, SF162ΔV2 is now up to 170-fold more susceptible to neutralization than SF162 by sera collected from patients infected with clade B HIV-1 isolates. In addition, it becomes susceptible to neutralization by sera collected from patients infected with clade A, C, D, E, and F HIV-1 isolates. These findings suggest that the V2, but not the V1, loop of SF162 shields an as yet unidentified region of the HIV envelope rich in neutralization epitopes and that the overall structure of this region appears to be conserved among clade B, C, D, E, and F HIV-1 PR isolates.     

Induction and Characterization of Neutralizing Antibodies against a Human Immunodeficiency Virus Type 1 Primary Isolate

Chimpanzees infected with the primary isolate DH012 mount potent neutralizing antibodies. This DH012 neutralizing activity is highly strain specific. Immune sera from guinea pigs immunized with recombinant DH012 gp120 could also neutralize this primary isolate. The neutralizing activity in chimpanzee and guinea pig sera against wild-type DH012 appears to be independent of a linear epitope in the V3 region of gp120. Interestingly, the neutralization escape mutant derived from growing DH012 in the presence of the potent neutralizing chimpanzee serum is at least 50-fold more sensitive than wild-type DH012 to neutralization by guinea pig immune sera. The unusually potent neutralizing activity against the DH012 neutralization-resistant virus is due to the presence of anti-V3 antibodies in guinea pig sera. These results suggested that recombinant gp120 could induce neutralizing antibodies against primary isolate DH012. The V3 of wild-type DH012 is poorly immunogenic in infected chimpanzees and is not accessible to neutralizing V3 antibodies. It is likely that this cryptic V3 region became exposed when the virus escaped the neutralizing activity of the chimpanzee serum.     

Human immunodeficiency virus type 1 envelope gp120 is cleaved after incubation with recombinant soluble CD4.

Human immunodeficiency virus type 1 (HIV-1) infects human CD4+ cells by a high-affinity interaction between its envelope glycoprotein gp120 and the CD4 molecule on the cell surface. Subsequent virus entry into the cells involves other steps, one of which could be cleavage of the gp120 followed by virus-cell fusion. The envelope gp120 is highly variable among different HIV-1 isolates, but conserved amino acid sequence motifs that contain potential proteolytic cleavage sites can be found. Following incubation with a soluble form of CD4, we demonstrate that gp120 of highly purified HIV-1 preparations is, without addition of exogenous proteinase, cleaved most likely in the V3 loop, yielding two proteins of 50 and 70 kDa. The extent of gp120 proteolysis is HIV-1 strain dependent and correlates with the recombinant soluble CD4 sensitivity to neutralization of the particular strain. The origin of the proteolytic activity in the virus preparations remains unclear. The results support the hypothesis that cleavage of gp120 is required for HIV infection of cells.     

Characterization of a discontinuous human immunodeficiency virus type 1 gp120 epitope recognized by a broadly reactive neutralizing human monoclonal antibody.

While one hypervariable, linear neutralizing determinant on the human immunodeficiency virus type 1 (HIV-1) gp120 envelope glycoprotein has been well characterized, little is known about the conserved, discontinuous gp120 epitopes recognized by neutralizing antibodies in infected individuals. Here, the epitope recognized by a broadly reactive neutralizing monoclonal antibody (F105) derived from an HIV-1-infected patient was characterized by examining the effects of changes in conserved gp120 amino acids on antibody reactivity. The F105 epitope was disrupted by changes in gp120 amino acids 256 and 257, 368 to 370, 421, and 470 to 484, which is consistent with the discontinuous nature of the epitope. Three of these regions are proximal to those previously shown to be important for CD4 binding, which is consistent with the ability of the F105 antibody to block gp120-CD4 interaction. Since F105 recognition was more sensitive to amino acid changes in each of the four identified gp120 regions than was envelope glycoprotein function, replication-competent mutant viruses that escaped neutralization by the F105 antibody were identified. These studies identify a conserved, functional HIV-1 gp120 epitope that is immunogenic in man and may serve as a target for therapeutic or prophylactic intervention.     

Cryptic nature of envelope V3 region epitopes protects primary monocytotropic human immunodeficiency virus type 1 from antibody neutralization.

Characterization of biological and immunological properties of human immunodeficiency virus type 1 (HIV-1) is critical to developing effective therapies and vaccines for AIDS. With the use of a novel CD4+ T-cell line (PM-1) permissive to infection by both monocytotropic (MT) and T-cell-tropic virus types, we present a comparative analysis of the immunological properties of a prototypic primary MT isolate of HIV-1 strain JR-CSF (MT-CSF) with those of a T-cell-tropic variant (T-CSF) of the same virus, which emerged spontaneously in vitro. The parental MT-CSF infected only PM-1 cells and was markedly resistant to neutralization by sera from HIV-1-infected individuals, rabbit antiserum to recombinant MT-CSF gp120, and anti-V3 monoclonal antibodies. The T-CSF variant infected a variety of CD4+ T-cell lines, contained positively charged amino acid substitutions in the gp120 V3 region, and was highly sensitive to antibody neutralization. Neutralization and antibody staining of T-CSF-expressing cells were significantly inhibited by HIV-1 V3 peptides; in contrast, the MT strain showed only weak V3-specific binding of polyclonal and monoclonal antibodies. Exposure of PM-1 cells to a mixture of both viruses in the presence of human anti-HIV-1 neutralizing antiserum resulted in infection with only MT-CSF. These results demonstrate that although the V3 region of MT viruses is immunogenic, the target epitopes in the V3 principal neutralizing domain on the membrane form of the MT envelope appear to be cryptic or hidden from blocking antibodies.     

Dissecting the neutralizing antibody specificities of broadly neutralizing sera from human immunodeficiency virus type 1-infected donors

Attempts to elicit broadly neutralizing antibody responses by human immunodeficiency virus type 1 (HIV-1) vaccine antigens have been met with limited success. To better understand the requirements for cross-neutralization of HIV-1, we have characterized the neutralizing antibody specificities present in the sera of three asymptomatic individuals exhibiting broad neutralization. Two individuals were infected with clade B viruses and the third with a clade A virus. The broadly neutralizing activity could be exclusively assigned to the protein A-reactive immunoglobulin G (IgG) fraction of all three donor sera. Neutralization inhibition assays performed with a panel of linear peptides corresponding to the third hypervariable (V3) loop of gp120 failed to inhibit serum neutralization of a panel of HIV-1 viruses. The sera also failed to neutralize chimeric simian immunodeficiency virus (SIV) and HIV-2 viruses displaying highly conserved gp41-neutralizing epitopes, suggesting that antibodies directed against these epitopes likely do not account for the broad neutralizing activity observed. Polyclonal IgG was fractionated on recombinant monomeric clade B gp120, and the neutralization capacities of the gp120-depleted samples were compared to that of the original polyclonal IgG. We found that the gp120-binding antibody population mediated neutralization of some isolates, but not all. Overall, the data suggest that broad neutralization results from more than one specificity in the sera but that the number of these specificities is likely small. The most likely epitope recognized by the monomeric gp120 binding neutralizing fraction is the CD4 binding site, although other epitopes, such as the glycan shield, cannot be excluded.     

Emergence of viruses resistant to neutralization by V3-specific antibodies in experimental human immunodeficiency virus type 1 IIIB infection of chimpanzees.

Emergence in two chimpanzees of human immunodeficiency virus type 1 (HIV-1) IIIB variants resistant to neutralization by the preexisting antibody is described. Viruses isolated from the HIV-1 IIIB gp120-vaccinated and -challenged animal were more resistant to neutralization by the chimpanzee's own serum than viruses isolated from the naive infected animal, indicating immune pressure as the selective mechanism. However, all reisolated viruses were 16- to 256-fold more neutralization resistant than the inoculum virus to antibodies binding to the third variable domain (V3) of the HIV-1 external envelope. Early chimpanzee serum samples that neutralized the inoculum strain but not the reisolated viruses were found to bind an HIV-1 IIIB common nonapeptide (IQRGPGRAF) derived from the gp120 isolate-specific V3 domain shown to induce isolate-specific neutralization in other animals. Amplification of the V3 coding sequence by polymerase chain reaction and subsequent sequence analysis of the neutralization-resistant variants obtained from in vivo-infected animals indicated that early resistance to neutralization by an HIV-1 IIIB monoclonal antibody (0.5 beta) was conferred by changes outside the direct binding site for the selective neutralizing antibody. The reisolated neutralization-resistant isolates consisted of the lower-replication-competent virus subpopulations of the HIV-1 IIIB stock, as confirmed by biological and sequence analyses. In vitro passage of the HIV-1 IIIB stock through chimpanzee and human peripheral blood mononuclear cell cultures void of HIV-specific antibody resulted in homogenic amplification of the more-replication-competent subpopulation preexisting in the original viral stock, suggesting a role for the immune system in suppressing the more-replication-competent viruses.     

Determinants of Neutralization Resistance in the Envelope Glycoproteins of a Simian-Human Immunodeficiency Virus Passaged In Vivo

In vivo passage of a simian-human immunodeficiency virus (SHIV-89.6) generated a virus, SHIV-89.6P, that exhibited increased resistance to some neutralizing antibodies (G. B. Karlsson et al., J. Exp. Med. 188:1159-1171, 1998). Here we examine the range of human immunodeficiency virus type 1 (HIV-1) neutralizing antibodies to which the passaged virus became resistant and identify envelope glycoprotein determinants of antibody resistance. Compared with the envelope glycoproteins derived from the parental SHIV-89.6, the envelope glycoproteins of the passaged virus were resistant to antibodies directed against the gp120 V3 variable loop and the CD4 binding site. By contrast, both viral envelope glycoproteins were equally sensitive to neutralization by two antibodies, 2G12 and 2F5, that recognize poorly immunogenic structures on gp120 and gp41, respectively. Changes in the V2 and V3 variable loops of gp120 were necessary and sufficient for full resistance to the IgG1b12 antibody, which is directed against the CD4 binding site. Changes in the V3 loop specified complete resistance to a V3 loop-directed antibody, while changes in the V1/V2 loops conferred partial resistance to this antibody. The epitopes of the neutralizing antibodies were not disrupted by the resistance-associated changes. These results indicate that in vivo selection occurs for HIV-1 envelope glycoproteins with variable loop conformations that restrict the access of antibodies to immunogenic neutralization epitopes.     

Human immunodeficiency virus strains differ in their ability to infect CD4+ cells expressing the rat homolog of CXCR-4 (fusin).

A clade B strain of human immunodeficiency virus type 1 (HIV-1(LAI)) could infect CD4+ cells expressing human CXCR-4 (fusin) or its rat homolog with similar efficacy. By contrast, cells expressing rat CXCR-4 were not permissive to HIV-1(NDK) (clade D), HIV-2(ROD), or HIV-1(LAI) with chimeric envelope protein gp120 bearing the V3 domain from HIV-1(NDK). The reciprocal chimeric gp120 (HIV-1(NDK) with V3 from HIV-1(LAI)) could mediate infection of cells expressing either human or rat CXCR-4. Genetically divergent HIV strains have different requirements for interaction with the CXCR-4 coreceptor, and the gp120 V3 domain seems to be involved in this interaction.     

Neutralizing antibodies to an immunodominant envelope sequence do not prevent gp120 binding to CD4.

Animals immunized with the human immunodeficiency virus type 1 gp160 glycoprotein or certain recombinant envelope components develop potent virus-neutralizing activity. This activity is principally due to antibodies directed toward a hypervariable region of gp120 between cysteine residues 302 and 337 and is virus isolate specific. These antisera, as well as two neutralizing monoclonal antibodies directed against the same hypervariable sequence, do not appreciably block gp120 from binding CD4. In contrast, serum samples from infected humans possess high titers of antibodies that block gp120-CD4 binding; these titers approximately correlate with the serum neutralization titers. Our results suggest that there are at least two targets on the envelope glycoprotein for virus neutralization. The target responsible for the broader neutralizing activity of human serum may be a conserved region of gp120 involved in CD4 binding. The antibodies directed at the hypervariable region of the envelope inhibit a different step in virus infection which is subsequent to receptor binding. The extent to which these two different epitopes of gp120 may be involved in protection against human immunodeficiency virus infection is discussed.     

Human immunodeficiency virus type 1 neutralization by a single molecule of V3-targeted antibody

Human immunodeficiency virus type-1 (HIV-1) infection generally provokes antibody responses to the viral envelope glycoprotein. Two major regions of gp120, the third variable (V3) domain and the CD4-binding site, have been identified as neutralization targets. The precise mechanism of HIV-1 neutralization by antibodies against the V3 domain is still unknown. It is shown that by kinetic neutralization studies, one molecule of V3-targeted monoclonal antibody (0.5beta) is enough to neutralize one virion. This antibody, which neutralized more than 99% of the virus, inhibited the binding of the virus to cells by 42%. HIV-1 pseudotyped with G glycoprotein from vesicular stomatitis virus was also neutralized by 0.5beta, suggesting that the antibody did not inhibit the viral attachment but caused some alteration in the envelope. These results indicate that the antibody plays an additional role on steric change of the envelope involved in inhibition of viral entry.     

CD4-Induced Conformational Changes in the Human Immunodeficiency Virus Type 1 gp120 Glycoprotein: Consequences for Virus Entry and Neutralization

Human immunodeficiency virus type 1 (HIV-1) entry into target cells involves sequential binding of the gp120 exterior envelope glycoprotein to CD4 and to specific chemokine receptors. Soluble CD4 (sCD4) is thought to mimic membrane-anchored CD4, and its binding alters the conformation of the HIV-1 envelope glycoproteins. Two cross-competing monoclonal antibodies, 17b and CG10, that recognize CD4-inducible gp120 epitopes and that block gp120-chemokine receptor binding were used to investigate the nature and functional significance of gp120 conformational changes initiated by CD4 binding. Envelope glycoproteins derived from both T-cell line-adapted and primary HIV-1 isolates exhibited increased binding of the 17b antibody in the presence of sCD4. CD4-induced exposure of the 17b epitope on the oligomeric envelope glycoprotein complex occurred over a wide range of temperatures and involved movement of the gp120 V1/V2 variable loops. Amino acid changes that reduced the efficiency of 17b epitope exposure following CD4 binding invariably compromised the ability of the HIV-1 envelope glycoproteins to form syncytia or to support virus entry. Comparison of the CD4 dependence and neutralization efficiencies of the 17b and CG10 antibodies suggested that the epitopes for these antibodies are minimally accessible following attachment of gp120 to cell surface CD4. These results underscore the functional importance of these CD4-induced changes in gp120 conformation and illustrate viral strategies for sequestering chemokine receptor-binding regions from the humoral immune response.     

Functional and immunologic characterization of human immunodeficiency virus type 1 envelope glycoproteins containing deletions of the major variable regions.

Deletions of the major variable regions (V1/V2, V3, and V4) of the human immunodeficiency virus type 1 (HIV-1) gp120 exterior envelope glycoprotein were created to study the role of these regions in function and antigenicity. Deletion of the V4 region disrupted processing of the envelope glycoprotein precursor. In contrast, the deletion of the V1/V2 and/or V3 regions yielded processed exterior envelope glycoproteins that retained the ability to interact with the gp41 transmembrane glycoprotein and the CD4 receptor. Shedding of the gp120 exterior glycoprotein by soluble CD4 was observed for the mutant with the V3 deletion but did not occur for the V1/V2-deleted mutant. None of the deletion mutants formed syncytia or supported virus entry. Importantly, the affinity of neutralizing antibodies directed against the CD4-binding region for the multimeric envelope glycoprotein complex was increased dramatically by the removal of both the V1/V2 and V3 structures. These results indicate that, in addition to playing essential roles in the induction of membrane fusion, the major variable regions mask conserved neutralization epitopes of the HIV-1 gp120 glycoprotein from antibodies. These results explain the temporal pattern associated with generation of HIV-1-neutralizing antibodies following infection and suggest stratagems for eliciting improved immune responses to conserved gp120 epitopes.     

Mutations in human immunodeficiency virus type 1 gp41 affect sensitivity to neutralization by gp120 antibodies.

Three closely related molecular human immunodeficiency virus type 1 (HIV-1) clones, with differential neutralization phenotypes, were generated by cloning of an NcoI-BamHI envelope (env) gene fragment (HXB2R nucleotide positions 5221 to 8021) into the full-length HXB2 molecular clone of HIV-1 IIIB. These env gene fragments, containing the complete gp120 coding region and a major part of gp41, were obtained from three different biological clones derived from a chimpanzee-passaged HIV-1 IIIB isolate. Two of the viruses thus obtained (4.4 and 5.1) were strongly resistant to neutralization by infection-induced chimpanzee and human polyclonal antibodies and by HIV-1 IIIB V3-specific monoclonal antibodies and weakly resistant to soluble CD4 and a CD4-binding-site-specific monoclonal antibody. The third virus (6.8) was sensitive to neutralization by the same reagents. The V3 coding sequence and the gp120 amino acid residues important for the discontinuous neutralization epitope overlapping the CD4-binding site were completely conserved among the clones. However, the neutralization-resistant clones 4.4 and 5.1 differed from neutralization-sensitive clone 6.8 by two mutations in gp41. Exchange experiments confirmed that the 3' end of clone 6.8 (nucleotides 6806 to 8021; amino acids 346 to 752) conferred a neutralization-sensitive phenotype to both of the neutralization-resistant clones 4.4 and 5.1. From our study, we conclude that mutations in the extracellular portion of gp41 may affect neutralization sensitivity to gp120 antibodies.     

Expression and characterization of genetically engineered human immunodeficiency virus-like particles containing modified envelope glycoproteins: implications for development of a cross-protective AIDS vaccine.

Noninfectious human immunodeficiency virus type 1 (HIV-1) viruslike particles containing chimeric envelope glycoproteins were expressed in mammalian cells by using inducible promoters. We engineered four expression vectors in which a synthetic oligomer encoding gp120 residues 306 to 328 (amino acids YNKRKRIHIGP GRAFYTTKNIIG) from the V3 loop of the MN viral isolate was inserted at various positions within the endogenous HIV-1LAI env gene. Expression studies revealed that insertion of the heterologous V3(MN) loop segment at two different locations within the conserved region 2 (C2) of gp120, either 173 or 242 residues away from the N terminus of the mature subunit, resulted in the secretion of fully assembled HIV-like particles containing chimeric LAI/MN envelope glycoproteins. Both V3 loop epitopes were recognized by loop-specific neutralizing antibodies. However, insertion of the V3(MN) loop segment into other regions of gp120 led to the production of envelope-deficient viruslike particles. Immunization with HIV-like particles containing chimeric envelope proteins induced specific antibody responses against both the autologous and heterologous V3 loop epitopes, including cross-neutralizing antibodies against the HIV-1LAI and HIV-1MN isolates. This study, therefore, demonstrates the feasibility of genetically engineering optimized HIV-like particles capable of eliciting cross-neutralizing antibodies.     

Intrapatient alterations in the human immunodeficiency virus type 1 gp120 V1V2 and V3 regions differentially modulate coreceptor usage, virus inhibition by CC/CXC chemokines, soluble CD4, and the b12 and 2G12 monoclonal antibodies

We studied human immunodeficiency virus type 1 (HIV-1) chimeric viruses altering in their gp120 V1V2 and V3 envelope regions to better map which genetic alterations are associated with specific virus phenotypes associated with HIV-1 disease progression. The V1V2 and V3 regions studied were based on viruses isolated from an individual with progressing HIV-1 disease. Higher V3 charges were linked with CXCR4 usage, but only when considered within a specific V1V2 and V3 N-linked glycosylation context. When the virus gained R5X4 dual tropism, irrespective of its V3 charge, it became highly resistant to inhibition by RANTES and highly sensitive to inhibition by SDF-1alpha. R5 viruses with higher positive V3 charges were more sensitive to inhibition by RANTES, while R5X4 dualtropic viruses with higher positive V3 charges were more resistant to inhibition by SDF-1alpha. Loss of the V3 N-linked glycosylation event rendered the virus more resistant to inhibition by SDF-1alpha. The same alterations in the V1V2 and V3 regions influenced the extent to which the viruses were neutralized with soluble CD4, as well as monoclonal antibodies b12 and 2G12, but not monoclonal antibody 2F5. These results further identify a complex set of alterations within the V1V2 and V3 regions of HIV-1 that can be selected in the host via alterations of coreceptor usage, CC/CXC chemokine inhibition, CD4 binding, and antibody neutralization.