Peptides from the principal neutralizing and CD4-binding domain: similar immunoreactive properties and structure pattern]

The human immunodeficiency virus (HIV) proteins gp120 and gp41 are the principal immune target in HIV infection. One of the most important trends in the study of AIDS is linked to the mapping of sites involving in the binding to the cell receptor CD4 and in the induction of virus-neutralizing antibodies (VNA). Recent studies have revealed that gp120 as the major domain contains inducing type-specific BNA (PND) and a binding region with CD4 (CD4-BR). PND is located in the hypervariable loop of gp120 (residues 301-336 for a BRU strain), and CD4-BR is in the conservation area (residues 410-450). By using the synthetic fragments from these areas (BRU and MN strains) and HIV-infected persons' sera, the authors established that the immune response to PND and CD4-BR is somewhat interrelated: there is a synchronized response of HIV antibodies to peptides from the two regions in ELISA (r = 0.82). For analysis of this phenomenon, experiments with cross-linked immunoreactivity of rabbit antisera to peptides from PND and CD4-BR with homologous and heterologous peptides were performed by applying three control peptides from HIV and hepatitis B virus. It has been found that there is a cross reactivity between rabbit anti-PND (MN, BRU) and anti-CD4-BR abs. Peptide homological analysis revealed common structural elements for PND and CD4-BR despite significant differences in their proposed functions. There is a large amount of positively charged aa within both PND and CD4-BR which may be involved in gp120-CD4 interaction. Acetylation of Lys residues resulted in complete loss of peptide reactivity.     

Human immunodeficiency virus-infected monocyte-derived macrophages express surface gp120 and fuse with CD4 lymphoid cells in vitro: a possible mechanism of T lymphocyte depletion in vivo.

Monocyte-derived macrophages (MDM) infected in vitro with a macrophage-tropic strain of human immunodeficiency virus (HIV) fused with uninfected, CD4-expressing T lymphoblastoid cells, but not with a subclone of these cells lacking surface CD4. Infected MDM also fused with uninfected autologous and heterologous MDM. Recombinant soluble CD4 protein (rsCD4) (10 micrograms/ml) and full-length recombinant glycosylated gp120 (20 micrograms/ml) each inhibited fusion by 94-99%; the inhibition was dose-dependent. The N-terminal portion of gp120 did not inhibit syncytium formation. Fusion was also inhibited by a monoclonal antibody to an epitope which binds gp120 (S3.5), but not by antibody to an epitope not involved in gp120 binding (OKT4). HIV-infected MDM specifically bound fluorescein-conjugated rsCD4, and virus could be visualized budding from the surface of these cells. HIV-infected MDM express viral gp120 on their surface and fuse with CD4-bearing cells in a fashion similar to lymphoid cells. Macrophages may contribute to CD4 lymphocyte depletion in vivo by this fusion mechanism.     

Binding to CD4 of synthetic peptides patterned on the principal neutralizing domain of the HIV-1 envelope protein.

The interaction between the viral envelope protein gp120 and the cellular surface antigen CD4 is a key event in HIV-1 infection. Reciprocal high affinity binding sites have been located in the first domain of CD4 and in the carboxy-terminal region of gp120, respectively. Upon infection, the membranes of the target cells fuse; sites of CD4 and gp120, distinct from their high affinity binding sites, play a role in the post-binding events leading to syncytia formation. We have studied the interactions of CD4 with gp120 and gp120-derived peptides using an in vitro assay based on immobilized recombinant soluble CD4 (sCD4). In this system CD4 binds to recombinant soluble gp120 and to anti-receptor peptides derived from the high affinity CD4-binding site of gp120, as well as to peptides corresponding to the principal neutralizing domain (PND) of the envelope protein, i.e., to the domain required for HIV-1-mediated syncytium formation. Competition experiments performed using epitope-specific mAbs and a variety of peptides indicated that PND-derived peptides are specifically recognized by a CD4 site adjacent to, but distinct from, the high affinity gp120-binding site of CD4. Synthetic peptides patterned on the PND of different viral isolates were retained onto sCD4-based affinity columns at different extent; some of the structural requirements for binding were analyzed. Studies performed on CD4+ T-cells showed that PND-derived peptides also interact with CD4 in its native membrane-bound conformation. These results indicate that a direct contact takes place between CD4 and the gp120 domain participating in HIV-induced syncytia formation.     

Inhibition of human immunodeficiency virus infection in monocytes by monoclonal antibodies against leukocyte adhesion molecules.

CD4 is the surface receptor for HIV envelope. Some evidence exists, however, that other cell surface receptors may be involved in viral entry subsequent to the initial binding of gp120 to CD4. Antibodies to leukocyte integrin LFA-1, a major component of intercellular adhesive interactions, have been shown to inhibit HIV-induced syncytia formation. Using a stringent system for in vitro HIV infection of human leukocytes, we examine the ability of some monoclonal antibodies (mAb) against various adhesion-related molecules to block or partially inhibit productive viral replication. HIV-1 infection of target monocytes or T cells by cell-free virus was blocked completely or partially by some mAb that prevent cell-cell interactions (CD4, HLA-DR, LFA-1, LFA-3), but not by others (ICAM-1, MAC-1, gp150.95, CD2, CD3, CD14). The capacity for mAb to block HIV infection appears to be epitope-specific, and does not relate to the ability to block homotypic adhesion. HIV transmission from infected cells was more difficult to block than was infection by cell-free virus. Adhesion molecules may be involved in facilitating early stages of HIV infection, following gp120/CD4 binding but prior to viral integration, in a manner distinct from cell-cell adhesion.     

Characterization of CD4 glycoprotein determinant-HIV envelope protein interactions: perspectives for analog and vaccine development

The CD4 surface determinant, previously associated as a phenotypic marker for helper/inducer subsets of T lymphocytes, has now been critically identified as the binding/entry protein for human immunodeficiency viruses (HIV). The human CD4 molecule is readily detectable on monocytes, T lymphocytes, and brain tissues. Soluble HIV (HTLV IIIB) envelope protein (gp120) binds native or recombinant CD4 with equal affinity estimated to be 4 to 8 nM kDa. All human tissue sources of CD4 bind radiolabeled gp120 to the same relative degree; however, the murine homologous protein, L3T4, does not bind the HIV envelope protein. Lack of sufficient recognition by the recombinant L3T4 molecule suggests divergence in the gp120-binding epitope. The binding of gp120 to CD4 is dependent upon intact sulfhydryl bonds within cysteine residues and glycosylation. Deglycosylated native gp120 is unable to bind CD4 under physiological conditions. Recombinant deglycosylated fragments cannot bind to the CD4 receptor, although they serve as immunogen for neutralizing antibody development. A number of synthetic peptides to putative critical domains of gp120 have been studied for their antagonism of native gp120 binding. Peptide T analogs or synthetic cogeners of Neuroleukin proposed to bind the CD4 determinant involved in gp120 binding had no competitive displacement of native gp120 binding as assessed by two independent methods that measure gp120 interaction with CD4. Recombinant C-terminal fragments, also containing other putative domains, did not displace native gp120 from CD4. Glycosylation appears to be critical in the maintenance of the structure of the binding domain of gp120. Native gp120 binding to CD4 is sufficient for the activation of cellular metabolism that alters target cell gene expression and differentiation, suggesting that the virus binding contributes to the activation of the host cell.     

Natural analogue peptides of an HIV-1 GP120 T-helper epitope antagonize response of GP120-specific human CD4 T-cell clones

Neutralizing antibodies and specific cytotoxic T lymphocytes (CTL) may contribute to controlling viral spread, and ideally, to virus clearance in HIV infection. Both effector mechanisms depend on specific CD4 T-helper (Th) cells. Nevertheless, HIV hypervariability facilitates appearance of escape mutants for antibodies and for CTL responses. Here we also show that natural mutations (i.e., from sequences of different HIV strains) in an immunodominant Th epitope recognized by human CD4 clones specific for the envelope glycoprotein gp120 escape CD4 T-cell recognition. Furthermore, several natural analogue peptides exert an antagonistic function by inhibiting proliferative response of T cells specific to gp120 with a wild-type sequence. If similar events occur in vivo, they may represent an additional escape mechanism for HIV. In fact, antagonism for CD4 Th response may occur during superinfection with a different strain, or with the appearance of a variant carrying a mutated antagonistic sequence. In both cases, impaired Th cell function could lead to reduced immune control of HIV infection by interfering with CTL and antibody response.     

DC-SIGN-mediated internalization of HIV is required for trans-enhancement of T cell infection

Fusion of the human immunodeficiency virus (HIV) to the plasma membrane of target cells is mediated by interaction of its envelope glycoprotein, gp120, with CD4 and appropriate chemokine receptors. gp120 additionally binds to DC-SIGN, a C-type lectin expressed on immature dendritic cells. This interaction does not result in viral fusion, but instead contributes to enhanced infection in trans of target cells that express CD4 and chemokine receptors. Here we show that DC-SIGN mediates rapid internalization of intact HIV into a low pH nonlysosomal compartment. Internalized virus retains competence to infect target cells. Removal of the DC-SIGN cytoplasmic tail reduced viral uptake and abrogated the trans-enhancement of T cell infection. We propose that HIV binds to DC-SIGN to gain access to an intracellular compartment that contributes to augmentation or retention of viral infectivity.     

Primary proliferative and cytotoxic T-cell responses to HIV induced in vitro by human dendritic cells.

In earlier studies, primary proliferative and cytotoxic T-cell (CTL) responses to influenza virus were produced in vitro by using mouse dendritic cells (DC) pulsed with virus or viral peptide as the stimulus for syngeneic T cells in 20-microliters hanging-drop cultures. We have now adapted this system for producing primary responses with cells from non-immune donors to produce primary proliferative and CTL responses to human immunodeficiency virus I (HIV) and to HIV peptides in vitro using cells from normal human peripheral blood. All donors in this study were laboratory personnel with no history of HIV infection. DC enriched from peripheral blood were exposed to HIV in vitro and small numbers were added to T lymphocytes in 20-microliters hanging drops. Proliferative responses to virus-infected DC were obtained after 3 days in culture. After 6 days, CTL were obtained that killed virus-infected autologous--but not allogeneic--phytohaemagglutinin (PHA)-stimulated blast cells. Proliferative and CTL responses were obtained using cells from 14 random donors expressing a spectrum of major histocompatibility complex (MHC) types but the CTL, once produced, showed killing restricted by the MHC class I type. Treatment of cultures with monoclonal antibody (mAb) to CD4-positive cells at the beginning of culture blocked the development of both proliferative and CTL responses, but treatment after 5 days had no effect on the CTL activity. Treatment with MCA to CD8-positive cells at the beginning of culture did not block proliferation significantly, but treatment either before or after the 5-day culture period blocked CTL responses. Collaboration between proliferating CD4-positive cells and CD8-positive cells may thus be required to produce CTL of the CD8 phenotype. DC exposed to HIV also produced CTL that killed autologous blast cells pulsed with gp120 envelope glycoprotein. However, DC infected with whole virus did not produce CTL that lysed target cells pulsed with a synthetic peptide, which included a known T-cell epitope of gp120 (representing amino acids 111-126). DC pulsed with gp120 were a poor stimulus for the development of CTL. In contrast, DC pulsed with the peptide (111-126) stimulated both proliferative and CTL responses. The latter killed not only target cells pulsed with the peptide itself or with gp120 but also killed virus-infected autologous blast cells. CTL were again obtained reproducibly with this peptide using donors expressing a spectrum of MHC types.(ABSTRACT TRUNCATED AT 400 WORDS)     

The effect of a single amino acid substitution within the V3 loop of HIV-1 gp120 on HLA-DR1-restricted CD4 T-cell recognition.

Viral variation has been proposed to play a role in the pathogenesis of human immunodeficiency virus type-1 (HIV-1) infection, and is an important consideration in vaccine design. During the course of an infection, isolates with sequence changes in CD8 T-cell and B-cell epitopes arise. To determine whether sequence variation within the V3 loop of HIV-1 gp120 affects HLA-DR beta 1*0101-restricted CD4 T-cell recognition, we have generated CD4 T-cell clones (TLC) specific to gp120 V3 loop peptides. Four HLA-DR beta 1*0101-restricted groups of TLC were defined by distinct patterns of responses to a panel of peptides, consistent with a highly diverse T-cell repertoire recognizing the 30 amino acid stretch (296-326) of the gp120 V3 loop. Nevertheless, a single residue change at position 311 was found to abolish the recognition of two of the four groups of TLC. This was not due to an effect of the residue at 311 on binding to major histocompatibility complex (MHC), because: (1) irrespective of the residue at 311, peptides competed well with the influenza haemagglutinin peptide 307-319 for binding to cell-bound DR1; and (2) R311-specific TLC were also HLA DR beta 1*0101 restricted. Instead, the substitution of arginine for serine at position 311 blocked the interaction of the peptide with the T-cell receptor. Thus, despite the diversity of the T-cell response to the V3 loop of HIV-1, a single amino acid change can have a considerable influence on the responding T-cell population. As residue 311 is one of the most variable of the V3 loop residues, these results suggest that CD4 recognition can also exert pressure on viral variation consistent with a role for these cells in antiviral immunity.     

HIV env glycoprotein shares a cross-reacting epitope with a surface protein present on activated human monocytes and involved in antigen presentation

A serological cross-reactivity between env gp120 glycoprotein of the human immunodeficiency virus (HIV) and a human cellular surface protein has been defined by a monoclonal antibody (M38) raised against HIV. The cellular antigen is a protein of ca. 80 kDa expressed on a small fraction of mononuclear cells in peripheral blood and in lymph nodes. The protein behaves as an activation antigen of the monocytic lineage since it is expressed by monocytes in plastic-adherent culture conditions and by interferon-gamma-treated monocytes and pro-monocytic U937 cells. The protein is involved in antigen presentation since the antibody efficiently inhibits the proliferation of responsive lymphocytes in autologous tetanus toxoid presentation assays. In the T lymphoblastoid line H9, the protein is present in very small amounts, is not induced by interferon-gamma and increases after HIV infection. Sera from lymphoadenopathy syndrome and acquired immunodeficiency syndrome (AIDS) patients fail to detect the cellular protein, although containing antibodies reacting with gp120. We propose that both viral and cellular structures recognized by the monoclonal antibody (mAb) are involved in interactions with CD4 molecules of T helper lymphocytes and that such molecular mimicry might be relevant in the pathology of HIV infection. This view is supported by the finding that BL/10T4, a CD4-specific mAb, binds to M38 neutralizing its interactions with HIV and with monocytes. mAb M38 thus behaves as the internal image of CD4. This single property would explain all its diverse binding characteristics.     

Induction of CD4+ T cell depletion in mice doubly transgenic for HIV gp120 and human CD4

It has been suggested that loss of uninfected T cells in HIV infection occurs because of lymphocyte activation resulting in cell death by apoptosis. To address the question of whether cross-linking of CD4/HIV gp120 complexes by antibodies were sufficient to induce T cell depletion in vivo, we developed an animal model of continuous interaction between human CD4 (hCD4), gp120 and anti-gp120 antibodies in the absence of other viral factors. Double-transgenic mice have been generated in which T cells express on their membrane hCD4 and secrete HIV gp120. Although these mice have hCD4/gp120 complexes present on the surface of T cells, they do not show gross immunological abnormalities, and they are able to produce anti-gp120 antibodies following immunization with denaturated gp120. However, double-transgenic mice with antibodies to gp120, when immunized with tetanus toxoid, mount an IgG response that is significantly lower than that of double-transgenic mice without antibodies to gp120. Furthermore, the presence of anti-gp120 antibodies leads to CD4⁺ T cell depletion and immunodeficiency in the absence of HIV infection. Thus, the antibody response to gp120 can lead to CD4⁺ T cell attrition in vivo.     

Characterization of autoantibodies to the CD4 molecule in human immunodeficiency virus infection

Autoantibodies to the CD4 protein, which serves as a receptor for the human immunodeficiency virus (HIV) on the surface of target cells, were found in patients with different stages of HIV disease. Using recombinant soluble CD4 (rCD4) antigen in a enzyme-linked immunosorbent assay (ELISA), we detected serum anti-CD4 antibodies in approximately 20% of HIV-1 infected patients and 13% of HIV-2 infected patients. There was no correlation between the presence of anti-CD4 antibodies and the stage of HIV disease, serum IgG concentration, number of peripheral blood CD4 positive lymphocytes, or CD4/CD8 lymphocyte ratios in HIV-1 infected patients. Immunoaffinity purified anti-CD4 antibody failed to bind to CD4 positive cells using flow cytometric analysis. However, this antibody could weakly bind to CD4 positive cells that had been preincubated with purified recombinant gp120 (rgp120). In addition, using an ELISA system, we found that the binding of purified patient anti-CD4 antibody to rCD4 was increased in the presence of rgp120. Similar increased binding was observed with the anti-CD4 monoclonal antibody OKT4, but not with anti-Leu3a. These data suggest that a conformational change in the C-terminal domains of CD4 may be induced by gp120 binding and could lead to development of anti-CD4 antibodies.     

A highly selected panel of anti-CD4 antibodies fails to induce anti-idiotypic antisera mediating human immunodeficiency virus neutralization.

Anti-CD4 antibodies directed to the N terminus of CD4 can inhibit human immunodeficiency virus (HIV) infection. Therefore, it has been proposed that some of these reagents may contain idiotypic determinants which conformationally model the binding site expressed on gp120. In this report, we have selected a panel of anti-CD4 monoclonal antibodies as idiotypic mimics of gp120 by employing cross-blocking techniques, and CD4 epitope mapping using site-directed mutagenesis. These studies suggest that only 4 out of the original panel of 12 would be expected to represent suitable candidates for modelling the gp120 binding site. Nevertheless, anti-idiotypic antisera raised against these antibodies failed to inhibit gp120 binding to CD4. This negative result may reflect the incomplete modelling of the virus binding site by anti-CD4, or the lack of internal image antibody in the anti-idiotypic preparations. Alternatively, the binding site on gp120 may not be accessible to antibody neutralization, excluding the possibility of an idiotypic vaccine to HIV based on anti-CD4 antibody as surrogate antigen.     

AIDS pathogenesis: HIV envelope and its interaction with cell proteins

The immune deficiency induced by HIV has its origin in the interaction of the outer envelope glycoprotein gp120/gp41 with receptors present on human immunocytes. Virus binding to cells, virus entry and subsequent compartmentalization resulting in productive infection depends on the interaction of gp120/gp41 with CD4 and other accessory molecules. Gp120 and HIV are markedly immunosuppressive of T-cell responses and, in addition, HIV can functionally delete antigen responsiveness of T cells. Abolition of CD4 binding, by denaturation of gp120, allows study of T-cell epitopes in gp120 and shows the denatured molecule is highly immunogenic even in naive subjects (F. Manca, unpublished). The gp120-binding site of CD4 is shared with MHC class II molecules and the reaction of antibodies within this region of CD4 induces conformational changes that may be significant for virus entry into cells or for syncytial formation. The HIV envelope contains sites of sequence homology with monomorphic human MHC class II sites that do not appear to be naturally immunogenic in humans. In addition to the properties of gp120, it is hypothesized that HIV envelope may also represent an 'alloepitope' of class II to the human T-cell repertoire, and is therefore able to induce a chronic allogeneic response not dissimilar to experimentally induced GVHD. These features are of potential importance both for primary vaccination against HIV, and for the long-term treatment of HIV seropositive patients. Induction of effective T-cell responses to gp120 require use of a denatured or otherwise modified product lacking CD4-binding capacity. The potential distortion of the TCR repertoire by the class-II-homologous and CD4-interactive sequences must be assessed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of CD4-independent HIV receptors on spermatozoa

PROBLEM: Human immunodeficiency virus (HIV) has been demonstrated to bind and enter into the spermatozoa facilitating the transmission into urogenital cells. However, spermatozoa has been reported to be devoid of the conventional CD4 receptors for HIV. This suggests that there exists an alternate modality of HIV entry into spermatozoa using receptors other than CD4. Present communication describes the identification of HIV receptors on the spermatozoa. METHOD OF STUDY: The sperm proteins were solubilized using Triton X-100 and subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis followed by Western blot analysis, using cell-free HIV or gp120 envelope glycoprotein as a probe. HIV or gp120 bound protein band was then visualized by using alkaline phosphatase (AP) labeled anti-gp120 antibody as well as by using anti-gp120 antibody and subsequently by AP-labeled anti-rabbit gamma globulin. RESULTS: The results obtained demonstrate for the first time that cell-free HIV and gp120 protein bind specifically to 160 kDa sperm protein that could be the receptor for HIV entry into spermatozoa. CONCLUSION: A 160 kDa sperm protein could be the CD4-independent HIV receptor for HIV to bind and enter into the spermatozoa. Further characterization of this 160 kDa HIV receptor on sperm will provide an insight in understanding the mechanism and probable mode of intervention or prevention of HIV transmission at the initial stage of infection.     

Synthetic peptides from a conserved region of gp120 induce broadly reactive anti-HIV responses.

In our efforts to identify products that might be used for active immunotherapy in human immunodeficiency virus (HIV) infection, we have studied synthetic peptides derived from the CD4 attachment site of gp120. Two peptides have emerged with particularly interesting properties. The first (B138) is linear and spans the envelope residues 421-438; the second (1005/45) encompasses amino acids 418-445 and is cyclized by way of a disulphide bond joining its terminal cysteines. Both species have been shown to inhibit syncytial formation in a conventional bioassay, B138 being the most efficient. Both peptides elicit high titres of anti-peptide antibodies in immunized mice, rabbits and goats, with titres exceeding 1:10(5) in many cases. A substantial portion of this response is directed against gp120 as determined by enzyme-linked immunosorbent assay (ELISA). Analysis by flow cytometry has demonstrated that the antisera are broadly reactive with multiple diverse strains of HIV. The anti-gp120 activity of the anti-peptide antiserum was further confirmed by radioimmuno-precipitation (RIP) assays. Furthermore, RIP analysis and inhibition experiments in a GD4-gp120 binding assay have revealed that anti-peptide sera contain antibodies directed against the CD4 attachment site on gp120 and interfere with this receptor-ligand interaction.     

Enhancement of Human Immunodeficiency Virus (HIV) Replication in Human Monocytes by Low Titres of Anti-HIV Antibodies in Vitro

Low concentrations of serum obtained from a patient with acquired immunodeficiency syndrome (AIDS) enhanced the replication of human immunodeficiency virus type 1 (HIV-1) in a particular subclone of the CD-4-positive monocytoid cell line U937 clone 2. Cells of this subclone have a high expression of Fc receptors and a considerable degree of Fc-mediated phagocytic activity. IgG purified from the serum was also able to enhance the replication. These results indicate that low concentrations of human anti-HIV antibody may enhance HIV replication on human monocyte-macrophages. Furthermore, two mouse IgG1 monoclonal antibodies against gp120, the envelope glycoprotein of HIV-1, also induced enhancement at low concentrations. The binding of radiolabelled gp120 to the cells was increased at the same low concentrations. Antibodies against envelope glycoproteins may cause enhancement of HIV infection. Both normal and enhanced replication of HIV were completely inhibited by the masking of the binding site of CD4 molecules with F(ab')2 fragments of anti-CD4 antibody. Moreover, CD4-positive, Fc gamma RI-negative K562 cells and mouse macrophages failed to show any infection in the presence of antibody. These results suggest that CD4 molecules on the cell surface are necessary to cause enhancement of infection of HIV on monocyte-macrophages.     

Human trophoblast cells express CD4 and are permissive for productive infection with HIV-1.

The European collaborative study of HIV-infected pregnant women in Europe now indicates a 13% risk of fetal HIV infection (originally thought to be about 30%, and possibly higher in some countries). Several reports suggest trans-placental passage. However, the detailed mechanisms associated with such vertical transmission have not yet been clarified. We have examined the possibility that HIV enters placental tissue from maternal blood via binding to CD4 and Fc receptors (FcR) at the trophoblast level, allowing intraplacental infection. Here we report the detection of several FcR with distinct localization in the placental villus as well as CD4 surface expression on human trophoblast cells. In addition, we show that trophoblastic cells interact specifically with the gp120/gp160 viral envelope protein. By their tissue localization, these receptors could be responsible for the entry of HIV into the fetal placental cells. Furthermore, purified placental cells can be directly infected by HIV in vitro, and the infection is inhibited by soluble CD4. This suggests a crucial role of the CD4 receptor but an additional way of entry cannot be excluded. Such an in vitro model may be suitable for further studies concerning placental HIV transmission and its prevention.     

Structure-based,targeted deglycosylation of HIV-1 gp120 and effects on neutralization sensitivity and antibody recognition

The human immunodeficiency virus (HIV-1) exterior envelope glycoprotein, gp120, mediates receptor binding and is the major target for neutralizing antibodies. Primary HIV-1 isolates are characteristically more resistant to broadly neutralizing antibodies, although the structural basis for this resistance remains obscure. Most broadly neutralizing antibodies are directed against functionally conserved gp120 regions involved in binding to either the primary virus receptor, CD4, or the viral coreceptor molecules that normally function as chemokine receptors. These antibodies are known as CD4 binding site (CD4BS) and CD4-induced (CD4i) antibodies, respectively. Inspection of the gp120 crystal structure reveals that although the receptor-binding regions lack glycosylation, sugar moieties lie proximal to both receptor-binding sites on gp120 and thus in proximity to both the CD4BS and the CD4i epitopes. In this study, guided by the X-ray crystal structure of gp120, we deleted four N-linked glycosylation sites that flank the receptor-binding regions. We examined the effects of selected changes on the sensitivity of two prototypic HIV-1 primary isolates to neutralization by antibodies. Surprisingly, removal of a single N-linked glycosylation site at the base of the gp120 third variable region (V3 loop) increased the sensitivity of the primary viruses to neutralization by CD4BS antibodies. Envelope glycoprotein oligomers on the cell surface derived from the V3 glycan-deficient virus were better recognized by a CD4BS antibody and a V3 loop antibody than were the wild-type glycoproteins. Absence of all four glycosylation sites rendered a primary isolate sensitive to CD4i antibody-mediated neutralization. Thus, carbohydrates that flank receptor-binding regions on gp120 protect primary HIV-1 isolates from antibody-mediated neutralization.     

Human immunodeficiency virus type 1 gp120 C5 region mimics the HLA class I α1 peptide-binding domain

Molecular mimicry of major histocompatibility (MHC) antigens by viral glycoproteins has been suggested as one of the possible mechanisms of induction of an autoimmune response by human immunodeficiency viruses. A monoclonal antibody (M38) was previously shown to bind to both human immunodeficiency virus type 1 (HIV-1) gp120 and β-2 microglobulin-free HLA class I heavy chains encoded by an HLA C allele. Using HLA C recombinant proteins and synthetic peptides, the M38 class I binding site was mapped to a stretch of 44 amino acids of the al domain. The amino acid residues recognized are clustered in two non-contiguous regions at positions 66-69 (KYKR) and 79-82 (RKLR) shared by almost all HLA C alleles. On HIV-1 gp120, M38 binds to two non-contiguous sequences (KYK and KAKR) at positions 490-492 and 505-508 located at the edges of a large hydrophobic region that is apparently involved in binding the transmembrane glycoprotein gp41. The C-terminal gp120 M38-reactive region (KAKR) lies within the immunodominant sequence APTKAKRRVVQREKR, against which the majority of HIV-infected individuals produce antibodies. The results indicate that a functionally important region of HIV-1 gp120 shares similar amino acid sequence motifs with the antigen recognition site of most HLA class I C alleles. The molecular mimicry may be the basis for autoimmune responses in HIV infection.