HIV-1 gp41 contains two sites for interaction with several proteins on the helper T-lymphoid cell line, H9

The immunosuppressive domain of the transmembrane envelope protein gp41 of HIV-1 binds to human monocytes and B cells

The induction of the acquired immunodeficiency syndrome by the human immunodeficiency virus-1 (HIV-1) is a complex process which is not yet understood in full detail. Still open is the question whether the highly conserved so-called immunosuppressive (Isu) domain in the transmembrane envelope (TM) protein gp41 of HIV-1 is actively participating in immunopathogenesis. Inactivated virus particles, recombinant gp41 and peptides corresponding to the Isu domain have been reported to inhibit lymphocyte proliferation, as well as to alter cytokine release and gene expression. Here we demonstrate, using fluorescence-activated cell sorting and competition experiments, that homopolymers of the Isu peptide of HIV-1 are binding specifically to human peripheral blood mononuclear cells, mainly to monocytes and B cells. These data suggest that a putative receptor might be involved in the immunomodulatory effects observed previously.

The transmembrane proteins contribute to immunodeficiencies induced by HIV-1 and other retroviruses

Many microorganisms including retroviruses suppress the immune system of the infected host in order to maintain infection. Unfortunately, it is still unclear how retroviruses induce immunosuppression. There is increasing evidence of a common mechanism based on their transmembrane envelope proteins. This review therefore summarizes evidence of the involvement of the transmembrane envelope proteins in the immunopathogenesis of different retroviruses including HIV-1. Mutations in the immunosuppressive (isu) domain of the transmembrane envelope protein of several retroviruses abrogate the immunosuppressive activities in vitro and in vivo. Most importantly, virus sequences with such abrogating mutations were never found in HIV-1-infected individuals despite the fact that the mutated viruses are replication-competent. However, there is also evidence for additional, perhaps even divergent, strategies for each retrovirus. For example, in contrast to many other retroviruses, the HIV directly interacts with immune cells and infects them. In addition, HIV uses several accessory proteins to evade the immune response. Furthermore, the possible contribution of the transmembrane envelope proteins of endogenous retroviruses to immunosuppression when expressed on tumor cells or in the placenta is analyzed.

The transmembrane protein of the human endogenous retrovirus--K (HERV-K) modulates cytokine release and gene expression

Numerous copies of endogenous retroviruses are present in the genome of mammals including man. Although most of them are defective, some, e.g., the human endogenous retroviruses HERV-K, were found to be expressed under certain physiological conditions. For instance, HERV-K is expressed in germ cell tumours and melanomas as well as in the placenta. Most exogenous retroviruses including the human immunodeficiency virus HIV-1 induce severe immunodeficiencies and there is increasing evidence that the transmembrane envelope (TM) proteins of these retroviruses may be involved. We show here that HERV-K particles released from a human teratocarcinoma cell line, a recombinant TM protein and a peptide corresponding to a highly conserved so-called immunosuppressive domain in the TM protein of HERV-K inhibit the proliferation of human immune cells, induce modulation of the expression of numerous cytokines, and modulate the expression of cellular genes as detected by a microarray analysis. The changes in cytokine release and gene expression induced by the TM protein of HERV-K are similar to those found previously induced by the TM protein of HIV-1. These data suggest that the mechanism of immunosuppression may be similar for different retroviruses and that the expression of the TM protein in tumours and in the placenta may suppress immune responses and thus prevent rejection of the tumour and the embryo.

Single mutations in the transmembrane envelope protein abrogate the immunosuppressive property of HIV-1

Background

The mechanism by which HIV-1 induces AIDS is still unknown. Previously, synthetic peptides corresponding to the conserved immunosuppressive (isu) domain in gp41 of HIV-1 had been shown to inhibit proliferation and to modulate cytokine expression of immune cells. The question is, whether the viral gp41 can do the same.

Results

We show for the first time that two trimeric forms of glycosylated gp41 released from transfected human cells modulated expression of cytokines and other genes in human PBMCs in the same manner, but at least seven hundred-fold stronger compared to that induced by the isu peptide. Single amino acid substitutions in the isu domain of gp41 introduced by site-directed mutagenesis abrogated this property. Furthermore, replication-competent HIV-1 with a mutation in the isu domain of gp41 did not modulate the cytokine expression, while wild-type virus did. Interestingly, most of the abrogating mutations were not reported in viral sequences derived from infected individuals, suggesting that mutated non-immunosuppressive viruses were eliminated by immune responses. Finally, immunisation of rats with gp41 mutated in the isu domain resulted in increased antibody responses compared with the non-mutated gp41. These results show that non-mutated gp41 is immunosuppressive in immunisation experiments, i.e. in vivo, and this has implications for the vaccine development.

Conclusions

These findings indicate that the isu domain of gp41 modulates cytokine expression in vitro and suppresses antibody response in vivo and therefore may contribute to the virus induced immunodeficiency.

HIV-1 glycoprotein 41 ectodomain induces activation of the CD74 protein-mediated extracellular signal-regulated kinase/mitogen-activated protein kinase pathway to enhance viral infection

Besides mediating the viral entry process, the human immunodeficiency virus (HIV-1) envelope protein gp41 can bind to many host cell components and regulate cell functions. Using a yeast two-hybrid system, we screened a human bone marrow cDNA library and identified a novel gp41-binding protein, CD74 (the MHC class II-associated invariant chain). Here, we report possible biological effects mediated by interaction between gp41 and CD74. We found that HIV-1 gp41 could bind directly to host CD74 in HIV-1-infected cells, and the peptide 6358 derived from gp41 loop region (aa 597-611) could effectively block the gp41-CD74 interaction. As a result of this binding, recombinant soluble gp41 and gp41 peptide 6358 activated the CD74-mediated ERK/MAPK pathway and significantly enhanced HIV-1 infection in vitro. Conversely, the enhancing effect could be suppressed by the recombinant CD74 extracellular domain. These results reveal a novel mechanism underlying gp41 mediation of HIV-1 infection and replication.

Interaction of HIV-1 gp41 core with NPF motif in Epsin: implication in endocytosis of HIV

The human immunodeficiency virus, type 1 (HIV-1), gp41 core plays an important role in fusion between viral and target cell membranes. We previously identified an HIV-1 gp41 core-binding motif HXXNPF (where X is any amino acid residue). In this study, we found that Asn, Pro, and Phe were the key residues for gp41 core binding. There are two NPF motifs in Epsin-1-(470-499), a fragment of Epsin, which is an essential accessory factor of endocytosis that can dock to the plasma membrane by interacting with the lipid. Epsin-1-(470-499) bound significantly to the gp41 core formed by the polypeptide N36(L8)C34 and interacted with the recombinant soluble gp41 containing the core structure. A synthetic peptide containing the Epsin-1-(470-499) sequence could effectively block entry of HIV-1 virions into SupT1 T cells via the endocytosis pathway. These results suggest that interaction between Epsin and the gp41 core, which may be present in the target cell membrane, is probably essential for endocytosis of HIV-1, an alternative pathway of HIV-1 entry into the target cell.

Identification of the HIV-1 gp41 core-binding motif--HXXNPF

The HIV-1 gp41 core, a six-helix bundle formed between the N- and C-terminal heptad repeats, plays a critical role in fusion between the viral and target cell membranes. Using N36(L8)C34 as a model of the gp41 core to screen phage display peptide libraries, we identified a common motif, HXXNPF (X is any of the 20 natural amino acid residues). A selected positive phage clone L7.8 specifically bound to N36(L8)C34 and this binding could be blocked by a gp41 core-specific monoclonal antibody (NC-1). JCH-4, a peptide containing HXXNPF motif, effectively inhibited HIV-1 envelope glycoprotein-mediated syncytium-formation. The epitope of JCH-4 was proven to be linear and might locate in the NHR regions of the gp41 core. These data suggest that HXXNPF motif may be a gp41 core-binding sequence and HXXNPF motif-containing molecules can be used as probes for studying the role of the HIV-1 gp41 core in membrane fusion process.

Antibodies against heat shock proteins and cholesterol in HIV infection

This review summarizes data on the presence and function of different heat shock proteins (Hsp) in the HIV virions and the infected cells. A 60 kD heat shock protein-like molecule is present in the envelope of the human immunodeficiency virus type 1 which can specifically interact with the transmembrane glycoprotein gp41. The role of cholesterol in the so-called cholesterol-rich lipid raft where HIV is budding from the infected cells as well as the consequential insertion of cholesterol into the envelope of HIV virion are also discussed. Natural antibodies against 60 kD (Hsp60) and 70 kD (Hsp70) families of Hsp and cholesterol can be detected in most healthy individuals. HIV infection results in a sharp increase in the serum concentration of anti-Hsp70 and cholesterol antibodies whereas no difference in the concentration of anti-Hsp60 antibodies can be detected. Highly active antiretroviral therapy leads to normalization of the levels of both anti-Hsp70 and anti-cholesterol antibodies.

ELDKWA-epitope-specific monoclonal antibodies inhibit HIV env-mediated syncytium formation

Recent studies demonstrated that the N- and C-domains of HIV-1 gp41 are involved in virus-mediated membrane fusion resulting in HIV-entry into target cells. Synthetic N- and C-domain peptides, such as DP107 and DP178, potently inhibit membrane fusion induced by both laboratory-adapted strains and primary isolates of HIV-1. Monoclonal antibody (mAb) 2F5 recognizing ELDKWA-epitope on the gp41 C-domain has shown broad neutralizing activity to many HIV stains even primary isolates. To test the neutralizing mechanism of the ELDKWA-epitope-specific antibody, mAbs with predefined ELDKWA-epitope-specificity were induced by synthetic epitope-peptide instead of a natural or recombinant gp41 bearing this epitope. All of five mAbs were identified to recognize ELDKWA-epitope on recombinant soluble gp41 in ELISA-assay. In flow cytometry analysis, four out of five mAbs could bind to HIV-Env+ CHO-WT cells and such binding could be inhibited by ELDKWA-epitope peptide, which suggests that these mAbs could recognize native envelope protein expressed on cell membranes. Interestingly, two out of five mAbs could inhibit membrane fusion between the CXCR4- and CD4-expressing 3T3.T4.CXCR4 cells and HIV-Env+ CHO-WT cells in a dose-dependent manner, consistent with their potent binding capability to HIV-Env+ CHO-WT cells. Parren et al. (1998) suggested that neutralization of HIV-1 by antibody may be determined primarily by occupancy of sites and spatial obstruction which blocks virus entry. Based on this theory, a model was suggested to explain the neutralizing activities of mAbs against the epitope ELDKWA.

Immunogenicity and specificity of the candidate multi-epitope-vaccines against HIV-1

The failure of some candidate HIV-1 vaccines may result from inducing very weak neutralization activity against representative primary viral isolates. Based on our hypothesis that epitope-vaccine may be a new strategy to induce high levels of neutralizing antibodies against HIV-1, we designed two candidate multi-epitope-vaccines, EP1 [C-G-(ELDKWA-GPGRAFY)2-K] and EP2 (CG-GPGRAFY-G-ELDKWA-G-RILAVERYLKD), containing three neutralizing epitopes (GPGRAFY, ELDKWA and RILAVERYLKD) on HIV-1 envelope protein, and expected them to induce epitope-specific antibodies of predefined epitope-specificity. The two peptides were conjugated to carrier protein bovine serum albumin (BSA) and used for immunization of rabbits. Proteins were purified from the rabbit sera induced by both candidate multi-epitope-vaccines (EP1-BSA and EP2-BSA) through affinity chromatography with epitope-peptide-conjugated sepharose-column, and identified as antibodies in silver-staining and immunoblotting. These antibodies were demonstrated to recognize three neutralizing epitopes on peptides and the recombinant gp41 in ELISA-assay and immunoblotting. These results indicated that both candidate multi-epitope-vaccines could induce high levels of antibodies of predefined epitope-specificity which recognized a few of neutralizing epitopes on peptides and protein, providing experimental evidence for the new strategy to develop an effective neutralizing-antibody-based multi-epitope-vaccine against HIV-1.

Characterization of interaction between C-domain on HIV-1 gp41 and the putative receptor protein p62

Based on the fact that the binding of HIV-1 gp41 to the putative cellular receptor protein p62 could be inhibited by the C-domain peptide of gp41, we wanted to confirm the interaction of the C-domain with p62 and to characterize the receptor-binding site on the C-domain. We attempted to isolate the putative receptor protein p62 from cell lysates of the human B cell line Raji by affinity chromatography using sepharose-columns which were conjugated with three different peptides of the C-domain respectively. A protein of 62 kDa was isolated by peptide (NP2)-sepharose-column, while none of the proteins was identified in eluates of the other two overlapped peptides of C-domain, indicating that HIV-1 gp41 by the region aa635-664 of C-domain binds to the putative receptor protein p62. Besides, CD spectroscopy analysis revealed that only a NP2 peptide could induce significant conformational change of P62. In addition, the interaction between P62 and three peptides of the C-domain was characterized by the surface plasma resonance (SPR) measurement. It was indicated that only the NP2 peptide significantly inhibited the interaction between rsgp41 and the putative receptor P62, confirming that the protein p62 may serve as a potential receptor for gp41 binding, and the peptide NP2 contains an integrate binding site for gp41 binding to p62.

HIV-1 gp41 and type I interferon: sequence homology and biological as well as clinical implications

HIV-1 gp41-like human type I interferon (IFN) could inhibit lymphocyte proliferation and up-modulate MHC class I and II and ICAM-1 molecule expression. Sequence comparison indicates that a similar epitope RILAV-YLKD exists between N-domain of gp41 and two regions in IFN-alpha(aa29-35 and 113-129), IFN-beta (aa31-37 and 125-138) and IFN-omega (aa29-35 and 123-136), which was shown to form IFN-alpha/beta-receptor binding site. Weak sequence similarity was also found to exist in both regions on gp41 and type I IFN of murine and bovine. Experimental studies indicated that a common immunological epitope exists between gp41 and IFN-alpha and -beta. Antibodies against human IFN-alpha and -beta recognized the common immunological epitope and inhibited gp41-binding to the potential cellular receptor protein p45. Moreover, the polyclonal antibody to IFN-beta completely inhibited gp41-binding to human T, B cells and monocytic cells, while IFN-alpha could only inhibit this binding incompletely. It was interestingly observed that human IFN-beta after preincubating with cells could incompletely inhibit the binding of gp41 to human B cells and monocytic cells, and very weakly inhibit the binding to human T cells, indicating that the receptor for IFN-beta-binding may be involved in gp41 binding. This potential relationship may be based on the amino acid sequence homology in the receptor binding region between gp41 and IFN-beta. It was observed that the increased levels of antibodies against human IFN-alpha and -beta exist in HIV-1-infected individuals and are associated with the common epitope on gp41. Besides, several studies provided experimental evidence that the common immunological epitope could induce protective activity against HIV-1. The IFN-alpha-based vaccine has showed a significant reduction of disease progression in IFN-alpha-vaccine-treated HIV-infected patients. Recent experimental evidence indicates that gp41 and IFN-beta were involved in downregulation of CCR5 expression and induction of cell activation or signal transduction. Whether it may be performed by a similar mechanism is still to be investigated.

N- and C-domains of HIV-1 gp41: mutation, structure and functions

Recent studies demonstrated that the N- and C-domains of HIV-1 gp41 is involved in virus-mediated membrane fusion resulting in HIV-entry into the target cells. Up to now, viral mutation baffled many scientists to develop effective vaccines and drugs against HIV-1. To acquire more information of mutation of gp41 and to reveal the relationship of structure and function of the N- and C-domains, we compared and analyzed amino acid sequences of the gp41 ectodomain (aa 512-681) of 862 isolates from most HIV-1 clades (including A, B, C, D, E, F, G, H, I, J and O clades). A consensus sequence of the ectodomain with the highest frequency emerging on each position is constituted. The fusion domain and the N-domain belong to the most conserved regions in gp41, and most variable residues assemble partial to the C terminal of gp41. The hydrophobicity of each position is also calculated. The a and d positions in the N-domain for maintaining stabilization of the trimeric coiled coil interactions are highly conservative, and the e and g positions in the C-domain to retain the interaction show also highly conservative. The strange high conservation of the c residues may have an implication in the coiled coil structure. The highly conserved residues form the lining of the hydrophobic cavity and the deep cavity is an ideal target for small molecular inhibitors. On the C-terminal of the C-domain there is a highly conserved segment GIVQQQ. They are intimately involved in forming the three interfaces between neighboring helices. The function of the N- and C-domains, such as binding to the potential cellular receptor and inducing protective activities, are also discussed. These studies on the mutation, structure and functions of the N- and C-domains suggested that both domains become a new focus to develop effective vaccine and antiviral drugs in the new strategies.

Induction of monoclonal antibody with predefined ELNKWA epitope specificity by epitope vaccine

Since the hybridoma technique to produce monoclonal antibodies (MAbs) was discovered, thousands of MAbs with predefined protein specificity have been produced, and a natural or recombinant protein as antigen is necessary for inducing MAbs in the conventional hybridoma technique. To induce epitope-specific MAbs, we suggest an epitope vaccine as a new technique to induce MAbs with predefined epitope specificity. ELDKWA was identified as an important neutralizing epitope on HIV-1 gp41. The MAb 2F5, recognizing ELDKWA epitope, has shown broad neutralizing activity to many HIV strains, including primary isolates, but the mutant in ELNKWA epitope results in escape 2F5-based neutralization. To produce MAbs recognizing this mutated epitope for consideration of passive immunotherapy against the mutant bearing the ELNKWA epitope, MAbs with predefined ELNKWA epitope specificity were induced by synthetic epitope-peptide instead of a natural or recombinant gp41 bearing this epitope. Three MAbs were identified to recognize ELNKWA epitope on the synthetic epitope-peptide, and interestingly could bind the recombinant gp41 with ELDKWA epitope in an ELISA assay and immunoblotting analysis.

Human interferon-beta inhibits binding of HIV-1 gp41 to lymphocyte and monocyte cells and binds the potential receptor protein P50 for HIV-1 gp41

Previous findings have indicated that HIV-1 gp41 like human type I interferon (IFN) could inhibit lymphocyte proliferation and up-modulate MHC class I, II and ICAM-1 molecule expression, and a common epitope exists between gp41 and type I interferon (IFN-alpha and -beta) in the receptor binding regions. To clarify the relationship between human type I interferon and HIV-1 gp41, we tried to inhibit recombinant soluble gp41-binding to human T, B and monocyte cell lines by human IFN-alpha, -beta and -gamma. It was interestingly observed that IFN-beta after preincubating with cells could inhibit the binding of rsgp41 to H9, Raji and U937 cells (T, B and monocyte cell lines), while this binding could not be inhibited by another type I interferon (IFN-alpha) and a type II interferon (IFN-gamma). It was further examined whether human IFN-alpha and -beta bind to the gp41 binding protein P50. In ELISA-assay, the human IFN-beta, but not IFN-alpha, could bind to P50 which was identified as a potential cellular receptor protein for gp41-binding. By the affinity capillary electrophoresis (ACE) analysis, formation of stable IFN-beta-P50 complex was observed. These results indicate that IFN-beta binds the potential receptor protein P50. Based on these experimental evidences and previous studies, it was presumed that the potential cellular receptor protein P50 may be the 51 kDa subunit of human IFN-alpha/beta receptor, which needs to be verified in the future.

Induction of high level of specific antibody response to the neutralizing epitope ELDKWA on HIV-1 gp41 by peptide-vaccine

The monoclonal antibody 2F5 recognizing the neutralizing epitope ELDKWA on the C-domain could neutralize 90% of the investigated HIV-1 isolates. Low levels of ELDKWA-epitope-specific antibodies were observed in HIV-1-infected individuals. To induce high levels of antibodies to ELDKW-epitope, C-domain peptide (P2) was conjugated with a carrier peptide (KGGG)(7)-K (K/G). P2-K/G-conjugate induced high level of antibodies in mice by titer 1:25,600 to ELDKWA-epitope. P2-K/G-BSA-conjugate induced antibody response to ELDKWA-epitope (1:320-6400) in mice. The ELDKWA-epitope-specific antibodies of 19.8 and 34.6 microg/per milliliter serum were isolated from two rabbit antiserums (1:25,600). The levels of ELDKWA-epitope-specific antibodies induced in rabbits were greater than 1 microg/ml, a level considered to confer long-term protection. These results demonstrate the potential role of the C-domain peptide of gp41 to develop an effective ELDKWA-based epitope/peptide-vaccine against HIV-1.

Epitope-vaccine induces high levels of ELDKWA-epitope-specific neutralizing antibody

Based on the fact that mAb 2F5 recognizing ELDKWA-epitope on the C-domain of HIV-1 gp41 has significant neutralization potency against 90% of the investigated viruses of African, Asian, American and European strains, we attempted to characterise immunogenicity of the ELDKWA-epitope on an epitope-vaccine, and to produce ELDKWA-epitope-specific monoclonal antibodies (mAb) induced by the epitope-vaccine. The C-domain peptide (P2) and the ELDKWA-tetramer peptide [C-(ELDKWAG)4] were conjugated with BSA or P24-EC (GPKEPFRDYVDRFYK, a peptide of HIV-1 gag-protein P24, proved to be a good carrier peptide to induce an immune response to the hapten on the conjugates[18])by different methods. After the vaccination course, two P2-BSA peptide-vaccines both induced a strong antibody response against the P2-peptide by about 1:12800-25600 dilution, and a weak antibody response against the ELDKWA-epitope (1:1600-3200). The P2-P24EC and P2 (conjugated with itself) peptide-vaccines could also induce a weak antibody response against the ELDKWA-epitope (1:1600-3200), while an rgp160 subunit vaccine induced a very weak antibody response (1:400). Interestingly, the ELDKWA-tetramer epitope-vaccine [C-(ELDKWAG)4-BSA] could induce a strong antibody response against the ELDKWA-epitope (1:12800-25600), i.e. It increased the level of ELDKWA-antibody eight-fold, clearly better than the P2 peptide-vaccine, and much better than the rgp160 subunit vaccine, which indicates that the immunogenicities of the ELDKWA-epitope on the ELDKWA-tetramer peptide, the C-domain peptide and rgp160 are very different. These results suggest that the ELDKWA-epitope-vaccine may be a new strategy for inducing high levels of epitope-specific neutralizing antibodies against HIV-1. Using hybridoma-technique, a mouse monoclonal antibody recognizing the ELDKWA-epitope on ELDKWA-peptide and C-domain peptide was produced by immunization with the C-(ELDKWAG)4-BSA epitope-vaccine, which indicates a new way to produce an epitope-specific mAb, namely immunization with epitope-vaccine instead of a natural or recombinant protein immunogen.

HIV-2 transmembrane protein gp36 binds to the putative cellular receptor proteins P45 and P62

Based on the findings that two cellular proteins of 45 kDa (P45) and 62 kDa (P62) serve as the putative receptor molecules for binding of HIV-1 transmembrane protein gp41 to human T, B lymphocytes and monocytes, we examined whether HIV-2 gp36 and HIV-1 gp41 share the putative receptor proteins P45 and P62. In SPR-assay (SPR: surface plasmon resonance), the recombinant soluble gp36 (rsgp36: Env aa518-678 from clone ROD) like the recombinant soluble gp41 (rsgp41: Env aa539-684 from clone BH10) was binding to P45 and P62. By affinity capillary electrophoresis (ACE)-analysis, formation of stable rsgp36-P45 and rsgp36-P62 complexes were confirmed, and the interactions of rsgp36 with P45 and P62 is quite strong with a fast association rate and a slow dissociation rate. These results indicate that HIV-2 gp36 and HIV-1 gp41 have the common putative cellular receptor proteins P45 and P62, and the binding of gp36 to human lymphocytes and monocytes could be based on the interaction between gp36 and P45 and P62.

Epitope-vaccines: a new strategy to induce high levels of neutralizing antibodies against HIV-1

Based on the experimental evidence that gp120 subunit vaccine did not protect individuals from HIV-1 infection, we suggested that epitope-vaccines of HIV-1 gp41 may be a new strategy to induce high levels of neutralizing antibodies against HIV-1, and characterised immunogenicity of epitope-vaccines. Two epitopes, RILAVERYLKD-epitope (aa586-596) on the N-domain and ELDKWA-epitope (aa669-674) on the C-domain of gp41, were demonstrated by us and others to induce protective activity. After vaccination course, the RILAVERYLKD-dimer epitope-vaccine [C(RILAVERYLKDG)2-BSA] induced strong epitope-specific antibody response by about 1:25,600 dilution, and the ELDKWA-tetramer epitope-vaccine [C-(ELDKWAG)4-BSA] could yet induce strong antibody response to ELDKWA-epitope by 1:12,800-25,600 dilution of antisera in mice, while rgp41 subunit vaccine induced very weak antibody response to both epitopes (1:400). In rabbit experiments, the titres of ELDKWA-epitope-specific antibody induced by ELDKWA-epitope-vaccine [C-(ELDKWAG)4-BSA] reached to 1:6,400, while rgp41 subunit vaccine induced very weak antibody response to this epitope and to P1 and P2 peptides (1:400). Moreover, the ELDKWA-epitope-specific antibodies in mice and rabbit antisera induced by epitope-vaccine could very strongly interact with P2 peptide sequence-corresponding to the C-domain of gp41 (dilution by 1:25,600), and the RILAVERYLKD-epitope-specific antibodies in mice antisera induced by epitope-vaccine could also very strongly interact with P1 peptide sequence-corresponding to the N-domain of gp41 (dilution by 1:102,400). All these results provided experimental evidence that epitope-vaccine may be a new general strategy to induce high levels of neutralizing antibodies against HIV-1 or other viruses.

The C domain of HIV-1 gp41 binds the putative cellular receptor protein P62

OBJECTIVE

To characterize the binding of gp41 with the putative receptor protein P62.

DESIGN

HIV-1 gp41 binds several cellular proteins by two binding sites, one of which has been shown to bind to a putative receptor protein P45 (45 kDa). Based on this, an attempt was made to determine the relationship between the two binding sites and P62 (62 kDa).

METHODS

Using surface plasmon resonance (SPR) measurement, the interaction was measured between recombinant soluble gp41 (rsgp41, Env aa539-684) and protein P62. Inhibition of this interaction was attempted by the use of synthetic peptides (P1, aa583-599; P2, aa646-674) corresponding to the two binding sites in gp41. In addition, the direct binding of P62 to peptide P2 was examined in an enzyme-linked immunosorbent assay.

RESULTS

Using SPR measurement, the interaction between P62 and rsgp41 was confirmed, and the interaction was found to be inhibited by only the synthetic peptide P2 sequence that corresponds to the C domain of gp41; neither P1 nor a control peptide inhibited the interaction. Moreover, like rsgp41, P2 was able to bind P62 whereas P1 and another recombinant gp41 (aa567-648 that does not include the C domain) were not.

CONCLUSIONS

P62 bound rsgp41 and the synthetic peptide P2. This interaction could be inhibited only by P2. These results indicate that the C domain of HIV-1 gp41 binds P62.

Immunosuppression by retroviruses: implications for xenotransplantation

Retroviruses induce in the infected host an immunosuppression the severity of which depends on the viral load. A pronounced immunosuppression is induced by human and simian immunodeficiency viruses (HIV and SIV) ultimately leading to AIDS. It is very likely that HIV originated by trans-species transmission from primates. In contrast, SIVs are not pathogenic for their natural hosts probably as the result of virus-host coevolution. We have shown that a retroviral protein, the transmembrane envelope protein, may play an important role in retrovirus-induced immunosuppression and that all retroviruses share an evolutionarily highly conserved domain in this protein. We demonstrate that synthetic peptides corresponding to this domain of different retroviruses, including HIV, the baboon endogenous virus (BaEV), and different porcine endogenous retroviruses (PERVs), are immunosuppressive. We provide evidence that BaEV and different PERVs, including those able to grow in human cells, are immunosuppressive for lymphocytes of different species including human. This implies that xenotransplantation may result in a trans-species transmission of endogenous retroviruses derived from the donor animal. In analogy to HIV and SIV high-titer virus replication may cause an AIDS-like disease in the immunosuppressed human transplant recipient. Two additional points have to be considered: First, human anti-complement proteins produced by transgenic animals will also protect the virus and, second, the virus may be transmitted to other humans and thus increase its pathogenic potential.

HIV-1 envelope gp41 is a potent inhibitor of chemoattractant receptor expression and function in monocytes

HIV-1 uses CD4 and chemokine receptors as cofactors for cellular entry. The viral envelope transmembrane protein gp41 is thought to participate in viral fusion with CD4(+) cells. We investigated whether gp41 interacts with chemokine receptors on human monocytes by testing its effect on the capacity of cells to respond to chemokine stimulation. Monocytes preincubated with gp41 of the MN strain showed markedly reduced binding, calcium mobilization, and chemotaxis in response to a variety of chemokines as well as to the bacterial peptide fMLP. This generalized inhibition of monocyte activation by chemoattractants required the presence of CD4, since the effect of gp41 was only observed in CD4(+) monocytes and in HEK293 cells cotransfected with chemokine receptors and an intact CD4, but not a CD4 lacking its cytoplasmic domain. Confocal microscopy showed that gp41 caused internalization of CXCR4 in HEK293 cells provided they were also cotransfected with intact CD4. In addition, pretreatment of monocytes with protein kinase C inhibitors partially reversed the inhibitory effect of gp41. Thus, gp41, which had not previously been implicated as interacting with HIV-1 fusion cofactors, downregulates chemoattractant receptors on monocytes by a CD4-dependent pathway.

A common immunological epitope existing between HIV-1 gp41 and human interferon-alpha and -beta

Based on the similar effects that HIV-1 gp41 like human type I interferons (IFN-alpha and -beta) upregulated MHC expression and inhibited lymphocyte proliferation, we compared amino acid sequences of gp41 and human type I interferons (IFN-alpha and -beta), and found sequence-similarity existing between the immunosuppressive domain (aa583-599, LQARILAVERYLKDQQL) of HIV-1 gp41 and human IFN-alpha (region aa117-129) and IFN-beta (region aa128-134); besides, the immunosuppressive domain of HIV-1 gp41 shows sequence-homology with bovine and murine IFN-alpha and IFN-beta in the same region. We examined polyclonal antibodies to human IFN-alpha and IFN-beta respectively and found that both antibodies could recognize rsgp41 from two different sources. The polyclonal antibody to IFN-beta could bind to the immunosuppressive peptide (ISP, aa583-599, LQARILAVERYLKDQQL) of HIV-1 gp41, only when the ISP was coupled with carrier-protein, and inhibit, if preincubated with rsgp41, binding of rsgp41 to human H9 (T cells), Raji (B cells), and U937 (monocyte cells) completely. The polyclonal antibody to IFN-alpha could partially inhibit the binding of rsgp41 to U937 and Raji. These results indicate that a common immunological epitope exists between HIV-1 gp41 and human type I interferons.

HIV-1 gp41 by a common immunological epitope induces increased levels of antibodies against human interferon-beta in HIV-1 positive individuals

Based on our finding that a similar epitope exists between human IFN-beta (aa128-134) and HIV-1 gp41 (aa586-595), we examined 20 sera from healthy and 20 from HIV-1 infected individuals for IFN-beta antibody levels by ELISA. The levels of anti-IFN-beta antibody in sera from HIV-infected individuals were increased by about 160% in comparison with HIV-negative. We affinity-purified anti-gp41 antibodies from sera of HIV-1-infected individuals using rsgp41-sepharose column. One of three antibodies could recognize human IFN-beta in comparison with antibodies from serum of a healthy individual. A mouse antiserum to human IFN-beta recognized rsgp41 (recombinant soluble gp41 Env amino acid 539-684), while the normal mouse serum (pre-immune serum) did not bind to rspg41. These results indicate that a common immunological epitope exists between human IFN-beta and HIV-1 gp41. The sequence-similarity suggests that this common immunological epitope may be located in the region aa128-134 of human IFN-beta and the immunosuppressive domain (aa583-599) of HIV-1 gp41. The increased levels of antibodies against interferon-beta in HIV-1 positive individuals may be explained by a common immunological epitope on human IFN-beta and HIV-1 gp41.

The immunosuppressive peptide of HIV-1 gp41 like human type I interferons up-regulates MHC class I expression on H9 and U937 cells

Based on our findings that the immunosuppressive peptide (ISP, amino acids (aa) 583-599) of human immunodeficiency virus type 1 (HIV-1) gp41 shows sequence-similarity with human type I interferons (IFN-alpha and IFN-beta) and HIV-1 soluble gp41 (sgp41, aa 539-684) enhanced cell surface expression of major histocompatibility complex (MHC) class I molecule on human H9 (T cells), Raji (B cells) and U937 (monocytic cells) cells, we examined the effect of HIV-1 immunosuppressive peptide on the surface expression of MHC class I molecules on H9 and U937 cells. Flow cytometry analysis demonstrated that ISP-BSA (conjugate) could enhance MHC class I expression by about 40% on H9 cells and by about 45% on U937 cells, while monomer ISP (not conjugated) and EDCI-treated carrier protein (BSA-EDCI) did not increase the expression. By comparison, human type I interferons, IFN-alpha and IFN-beta, showed similar effects (enhanced the expression by about 40-60%) to ISP-BSA on the MHC class I expression on H9 and U937 cells. The results suggest that HIV-1 gp41 in a polymerized form by its immunosuppressive domain upregulates human MHC class I expression. The basis for this similar effect of HIV-1 gp41 and IFN-alpha and -beta, i.e. upregulation of MHC class I molecule expression, may be based on the sequence-similarity between these otherwise different molecules.

Pseudopeptide TASP inhibitors of HIV entry bind specifically to a 95-kDa cell surface protein

The template assembled synthetic peptide constructs (TASP), pentavalently presenting the tripeptide KPR or RPK, are potent and specific inhibitors of human immunodeficiency virus (HIV) infection by preventing viral entry into permissive cells. Here the 5[KPsi(CH2N)PR]-TASP construct, Psi(CH2N) for reduced peptide bond, was used in studies to demonstrate its specific binding to a 95-kDa cell surface protein ligand. Compared to its nonreduced 5[KPR]-TASP counterpart, the pseudopeptide 5[KPsi(CH2N)PR]-TASP manifested higher affinity to bind to its cell surface ligand, increased activity to inhibit HIV infection, and resistance to degradation when incubated in serum from an HIV-1 seropositive individual. In ligand blotting experiments, the biotin-labeled 5[KPsi(CH2N)PR]-TASP identified a single 95-kDa protein in crude cell extracts. This 95-kDa protein (p95) is expressed on the cell surface since surface iodination of cells resulted in its labeling, and moreover, following incubation of cells with the biotin-labeled 5[KPsi(CH2N)PR]-TASP, the p95.TASP complex was recovered by affinity chromatography using avidin-agarose. All anti-HIV TASP constructs but not their control derivatives affected the binding of biotin-labeled 5[KPsi(CH2N)PR]-TASP to p95, thus emphasizing the specific nature of this binding. Since 5[KPsi(CH2N)PR]-TASP does not interact with HIV-envelope glycoproteins, our results suggest that TASP inhibitors mediate directly or indirectly a block in HIV-mediated membrane fusion process by binding to the cell surface expressed p95.

Role of complement in HIV infection

In human plasma, HIV activates the complement system, even in the absence of specific antibodies. Complement activation would, however, be harmful to the virus if the reactions were allowed to go to completion, since their final outcome would be virolysis. This is avoided by complement regulatory molecules, which either are included in the virus membrane upon budding from the infected cells (e.g. DAF/CD55) or are secondarily attached to HIV envelope glycoproteins as in the case of factor H. By using this strategy of interaction with complement components, HIV takes advantage of human complement activation for enhancement of infectivity, for follicular localization, and for broadening its target cell range at the same time that it displays an intrinsic resistance against the lytic action of human complement. This intrinsic resistance to complement-mediated virolysis can be overcome by monoclonal antibodies inhibiting recruitment of human factor H to the virus surface, suggesting a new therapeutic principle.

Identification of a second site in HIV-1 gp41 mediating binding to cells

Previous studies by us and others showed that HIV-1 gp41 by the immunosuppressive domain (amino acids 583-599) could bind to human T, B and monocytic cells. Here, we characterize a region (amino acids 641-685) of HIV-1 gp41 that may be another site for gp41 binding. Besides peptides of the gp41 immunosuppressive domain, peptides of a second region (amino acids 641-685) could also inhibit rsgp41 (amino acids 539-684) binding to human cell lines U937 (monocytic cell line) and Raji (B cell line). An epitope (amino acids 669-674, ELDKWA) within this region is recognized by human monoclonal antibody 2F5. 2F5 shows broad-spectrum neutralizing capacity against HIV-1 laboratory strains and primary isolates (J. Virol. 1994, 68: 4031-4034; AIDS Res. Hum. Retrovir. 1994, 10: 1651-1658). We demonstrated by flow cytometry that mAb 2F5 could block gp41-binding to human cell lines H9 (T cells), Raji and U937, but the control mAb 4E10 that recognizes another region of gp41 (amino acids 686-728) and can not inhibit HIV infection, did not block this binding. These results indicate that the region (amino acids 641-685) of HIV-1 gp41 is the second site by which gp41 interacts with human cells, and suggest that the neutralization of HIV-1 infection by mAb 2F5 may be based on the fact that it blocks interaction of gp41 on virions with the gp41 binding molecules on human cells.

HIV-1 gp41 binding to human T- and B-lymphocytes and monocytes is modulated by phorbol myristate acetate (PMA)

HIV-1 gp41 independently of CD4 binds to human T cells, B cells and monocytic cells. Since PMA downmodulates CD4 (HIV receptor) expression and inhibits HIV-1 dependent syncytia formation, we wanted to examine whether PMA could affect gp41 binding protein expression on human cells. The strong binding of HIV-1 recombinant soluble gp41 (rsgp41; Env aa539-684) to monocytes (CD14+) and B-lymphocytes (CD19+) and B lymphoblastoid cells (Raji) could be clearly decreased by treating the cells with PMA for 48 h, while the weak binding to T lymphocytes was slightly increased by this treatment. The PMA inhibitory- and enhancing-effects could be avoided by pretreatment with staurosporine (protein kinase C inhibitor). The PMA treatment of Raji and U937 (monocytic) cells resulted in a 50-60% decrease of gp41 binding proteins (gp41bps) detectable in cell lysates of these cells in comparison with lysates of buffer-treated cells, while in the case of H9-cells PMA treatment resulted in an increase of available gp41bps by about 35% in comparison with buffer-treated H9. Staurosporine pre-treatment could prevent these effects of PMA. Further studies of rsgp41-eluates from these buffer-treated or PMA-treated cells demonstrated that PMA modulated mainly expression of rsgp41bps of 37, 45, 50 and 62 kDa. These results indicate that PMA exerts different effects on human T, B and monocytic cells. Production by and expression on cells of HIV-1 gp41bps appear to depend on protein kinase C, supporting that the four proteins on human cells may act as receptor proteins for HIV-1 gp41.

NMR and CD studies on the conformation of a synthetic peptide containing epitopes of the human immunodeficiency virus 1 transmembrane protein gp41

CD and nmr characterizations are reported for the 23-mer peptide CMC3, corresponding to residues 577-599 of gp41, the transmembrane glycoprotein of the human immunodeficiency virus 1. Concentration, temperature, and pH dependencies of CD and nmr spectra are indicative of self-association with a consequent stabilization of secondary structural elements in water. The addition to the water solution of small amounts of trifluoroethanol induces a secondary structure, mostly due to the presence of helical elements. The amphipathic character of the helix and the presence of three hydrophobic 4/3 heptad repeats suggest that the peptide could be structured in a symmetric association of helices, such as in a coiled-coil structure. This behavior is discussed in terms of a possible role of this segment in the gp41 envelope oligomerization.

Soluble CD4 induces the binding of human immunodeficiency virus type 1 to cells via the V3 loop of glycoprotein 120 and specific sites in glycoprotein 41

We have previously reported that incubation of human immunodeficiency virus type 1 (HIV-1) at 4 degrees C with soluble CD4 (sCD4) does not block but increases the binding of virions to CD4-positive H9 cells. In this study, we investigated the mechanism of this effect. It appears that sCD4 can induce the binding of HIV-1IIIB to CD4-negative human cells and to H9 cells with downregulated expression of CD4 at both 4 and 37 degrees C. The binding is proportional to the amount of sCD4 associated with virions, and requires the presence of heparan sulfate proteoglycans on the surface of cells. Monoclonal antibody (MAb) 9284 directed at an epitope overlapping with a putative heparin binding motif in the V3 loop of gp120 almost completely blocked the sCD4-induced binding of virions, while MAbs recognizing other sites of V2 or V3 loops had no effect. The binding of sCD4-coated virions to cells was also inhibited by MAbs 50-69 and 98-6 directed at extracellular epitopes of gp41, whose exposure is increased on binding of sCD4 to virions. Therefore, sCD4 potentiates the binding of HIV-1IIIB virions to cells by inducing conformational changes that enable envelope gp120 and gp41 to interact with cell surface components other than the CD4 receptor.

HIV-1 gp41 selectively inhibits spontaneous cell proliferation of human cell lines and mitogen- and recall antigen-induced lymphocyte proliferation

Human immunodeficiency virus type 1 (HIV-1) transmembrane glycoprotein 41 (gp41) contains an immunosuppressive domain (Env amino acids 583-599). Previous studies by us and others using recombinant soluble gp41 (rsgp41; amino acids 539-684) and immunosuppressive peptide (1SP; a gp41 peptide, amino acids 583-599) have shown that HIV-1 gp41 by the immunosuppressive domain could bind to several proteins on human T, B and monocyte cell lines, and also to normal human peripheral blood mononuclear cells. In this study we demonstrated that HIV-1 rsgp41 could inhibit spontaneous cell proliferation of human T cell lines H9 and Jurkat, B cell lines Raji and Daudi, monocyte cell line U937, but could not inhibit cell proliferation of human fibroblast cell line HEF and green monkey kidney cell line Cos-1. HIV-1 rsgp41 could inhibit also concanavalin A (Con A)-, phytohaemagglutinin (PHA)- and tetanus toxoid (TT)-induced cell proliferation of normal human peripheral blood lymphocytes, with 50% inhibition at a concentration of 8 microM, but could not inhibit pokeweed mitogen (PWM)-induced lymphocyte proliferation. Furthermore, recombinant soluble gp36 of HIV-2 like HIV-1 rsgp41 could inhibit Con A-, but not PWM-induced lymphocyte proliferation. These results indicate that HIV-1 gp41-induced inhibition of proliferation is selective in so far as the effect of PWM is not altered while the effects of several other stimuli are.

HIV-1 rsgp41 depends on calcium for binding of human c1q but not for binding of gp120

Human immunodeficiency virus type 1 activates the complement cascade via the classical pathway by direct binding of C1q through specific sites in the TM surface protein, gp41. In this paper we investigated the divalent cation dependence of the interaction between HIV-1 gp41 and C1q or gp120. A solid phase radioimmunoassay was used to investigate the interaction between a recombinant soluble form of HIV-1 gp41 (rsgp41) and C1q and an enzyme linked immunoassay was used to investigate the interaction between rsgp41 and gp120. The interaction between C1q and rsgp41, but not between C1q and immune complexes, was dependent upon the presence of calcium. Calcium could not be replaced by larger cations such as strontium, barium, lead or smaller ions such as magnesium and manganese. Zinc increased binding to 22% of binding achieved with calcium. The interaction between rsgp41 and gp120 was not dependent upon the presence of divalent ions. Thus, calcium is required for the interaction between rsgp41 and C1q, whereas the interaction between rsgp41 and gp120 is independent of divalent cations.

Proteinase-resistant factors in human erythrocyte membranes mediate CD4-dependent fusion with cells expressing human immunodeficiency virus type 1 envelope glycoproteins

Murine CD4+ cells are resistant to human immunodeficiency virus type 1 (HIV-1) entry and to fusion with cells expressing HIV-1 envelope glycoproteins (Env). The role of human-specific factors in Env/CD4-mediated fusion is shown by the ability of transient cell hybrids formed between CD4+ murine cells and human HeLa cells to fuse with Env+ cells. Fusion events were observed when other human cells, including erythrocytes, were substituted for HeLa cells in the hybrids. Experiments with erythrocyte ghosts showed that the factors allowing Env/CD4-mediated fusion are located in the plasma membrane. These factors were fully active after extensive digestion of erythrocytes with proteinase K or pronase. Nonprotein components of human plasma membranes, possibly glycolipids, could therefore be required for Env/CD4-mediated fusion and virus entry.

Primary in vitro immunization with multimeric synthetic peptides of HIV-1 envelope glycoproteins: generation of neutralizing human monoclonal antibodies

Peripheral blood lymphocytes from healthy HIV-1 seronegative donors were immunized in vitro with the following synthetic peptides: (i) an octameric poly-L-lysine conjugated peptide of the HIV-1MN V3 loop and (ii) a resin bound synthetic peptide aa642-665 of HIV-1 gp41. Lymphoblastoid cell lines (LCL) were obtained by immortalization with Epstein-Barr virus (EBV). We produced four LCL secreting human monoclonal antibodies (HuMoAbs) of the IgM isotype: three were directed against the V3 domain (FC10, FC81 and CF41) and one against aa642-665 (CA45C). Two of these HuMoAbs (FC81 and CA45C) reacted to viral surface antigen on HIV-1-infected cells. All the HuMoAbs inhibited 40-53% of cell fusion induced by HIV-1-infected H9 cells at 5 micrograms/ml. They also neutralized, at lower concentrations, cell-free infection with HIV-1MN, HIV-1IIIB and four primary clinical HIV-1 isolates. No enhancing activity of the HuMoAbs in the presence of complement was observed. The results presented here show the feasibility of generating neutralizing human monoclonal antibodies against HIV-1 by primary in vitro immunization with selected synthetic peptides of HIV-1 envelope glycoproteins. This approach has provided tools for further studies of synergistic neutralization assays, and generated potential immunoglobulin candidates for passive immunotherapy.

Peptides corresponding to a predictive alpha-helical domain of human immunodeficiency virus type 1 gp41 are potent inhibitors of virus infection

To define the role of the human immunodeficiency virus type 1 (HIV-1) envelope proteins in virus infection, a series of peptides were synthesized based on various regions of the HIV-1 transmembrane protein gp41. One of these peptides, DP-178, corresponding to a region predictive of alpha-helical secondary structure (residues 643-678 of the HIV-1LAI isolate), has been identified as a potent antiviral agent. This peptide consistently blocked 100% of virus-mediated cell-cell fusion at < 5 ng/ml (IC90 approximately 1.5 ng/ml) and gave an approximately 10 times reduction in infectious titer of cell-free virus at approximately 80 ng/ml. The inhibitory activity was observed at peptide concentrations approximately 10(4) to 10(5) times lower than those at which cytotoxicity and cytostasis were detected. Peptide-mediated inhibition is HIV-1 specific in that approximately 10(2) to 10(3) times more peptide was required for inhibition of a human immunodeficiency virus type 2 isolate. Further experiments showed that DP-178 exhibited antiviral activity against both prototypic and primary HIV-1 isolates. As shown by PCR analysis of newly synthesized proviral DNA, DP-178 blocks an early step in the virus life cycle prior to reverse transcription. Finally, we discuss possible mechanisms by which DP-178 may exert its inhibitory activity.

Factors involved in entry of the human immunodeficiency virus type 1 into permissive cells: lack of evidence of a role for CD26

It has been proposed recently that the cell surface peptidase CD26 acts in concert with CD4, the human immunodeficiency virus (HIV) primary receptor molecule, to mediate HIV entry into permissive cells. We have failed to detect significant levels of CD26 cell surface expression and enzymatic activity in a number of commonly propagated human CD4+ cell lines, although CD26 mRNA was present at very low levels, as detected by reverse transcription PCR. No relationship existed between the expression of CD26 and the ability of these cells to be infected with HIV or to fuse to form syncytia. We have tested two inhibitors of CD26 enzymatic activity and several anti-CD26 monoclonal antibodies and found that they inhibit neither HIV infection nor HIV-induced syncytium formation. NIH 3T3 cells stably transfected with the cDNAs for human CD4 and CD26 expressed these molecules at the cell surface and had CD26 enzymatic activity. Inoculation of the double transfectants with HIV did not result in virus entry above the background level, as verified by PCR amplification of viral DNA. We were unable to recover infectious virus from the HIV-inoculated NIH 3T3 double transfectants either by transfer of supernatants or by cocultivation with human CD4+ indicator cells. Moreover, the transfectants did not fuse with HIV-infected cells to form syncytia, nor were syncytia observed in HIV-inoculated cultures. These results are inconsistent with the CD26 molecule being a cofactor for entry of HIV in CD4+ cells.

HIV-1 gp41 binding proteins and antibodies to gp41 could inhibit enhancement of human Raji cell MHC class I and II expression by gp41

Based on our findings, that HIV-1 soluble gp41 could bind to several proteins on the human, T, B and monocyte cells independently of CD4, we examined the effect of HIV-1 soluble gp41 (sgp41;Env amino acids 539-684) on surface expression of MHC I and II, ICAM-1 and CD21 molecules on human Raji cells. Flow cytometry (FACS) analysis demonstrated that sgp41 could selectively enhance MHC class I and II expression on Raji cells, but did not increase expression of other cell surface antigens, such as, CD21 and CD54 (ICAM-1). Soluble gp41 could also enhance MHC class I and II expression on another human B cell line, Bjab. The sgp41-dependent enhancement of the MHC class I and II expression on Raji cells is time- and dose-dependent. The sgp41 enhancement effect on the MHC antigen expression could be inhibited by the sgp41-binding proteins of 45, 49 and 62 kD (isolated from Raji-lysate) which could inhibit the spg41-binding to Raji cells. Interestingly, this sgp41-dependent enhancement of the MHC class I and II expression could also be inhibited by two mAbs to HIV-1 gp41, but not by a third mAb binding to a different site on gp41. These results demonstrate that HIV-1 sgp41 can selectively enhance the human Raji cell MHC class I and II antigen expression and this enhancement effect could be inhibited by the sgp41-binding proteins and anti-gp41 antibodies, and suggest that the sgp41-dependent enhancement is mediated by its binding to Raji membrane proteins of 45, 49 and 62 kD.

HIV-1 gp41 binds to two proteins in cell culture supernatant of human B cell line Raji and monocyte cell line U937

Based on our findings that HIV-1 gp41 can bind independently of CD4 to the human T cell line H9, B cell line Raji and monocytic cell line U937, as well as human peripheral blood mononuclear cells preferentially to B lymphocytes and monocytes, we examined whether soluble protein for HIV-1 gp41 binding exists in the cell culture supernatant of Raji and U937. Using HIV-1 recombinant soluble gp41 (sgp41; Env amino acid 539-684) attached to sepharose beads, the cell culture supernatants of Raji and U937 were absorbed. By SDS-PAGE of sgp41-eluates of these cell culture supernatants three protein bands of 70, 75 and 92kD were stained with Coomassie blue. By Western blot (ligand blot) analysis using sgp41, two protein bands of 70 and 75kD were observed in sgp41-eluates from Raji and U937 cell culture supernatants. These sgp41-eluates could inhibit the sgp41 binding to Raji and U937 cells. Our data indicate that Raji and U937 cells produce two soluble binding proteins for HIV-1 gp41.