Antigenicity and immunogenicity of HIV-1 consensus subtype B envelope glycoproteins

"Centralized" (ancestral and consensus) HIV-1 envelope immunogens induce broadly cross-reactive T cell responses in laboratory animals; however, their potential to elicit cross-reactive neutralizing antibodies has not been fully explored. Here, we report the construction of a panel of consensus subtype B (ConB) envelopes and compare their biologic, antigenic, and immunogenic properties to those of two wild-type Env controls from individuals with early and acute HIV-1 infection. Glycoprotein expressed from full-length (gp160), uncleaved (gp160-UNC), truncated (gp145), and N-linked glycosylation site deleted (gp160-201N/S) versions of the ConB env gene were packaged into virions and, except for the fusion defective gp160-UNC, mediated infection via the CCR5 co-receptor. Pseudovirions containing ConB Envs were sensitive to neutralization by patient plasma and monoclonal antibodies, indicating the preservation of neutralizing epitopes found in contemporary subtype B viruses. When used as DNA vaccines in guinea pigs, ConB and wild-type env immunogens induced appreciable binding, but overall only low level neutralizing antibodies. However, all four ConB immunogens were significantly more potent than one wild-type vaccine at eliciting neutralizing antibodies against a panel of tier 1 and tier 2 viruses, and ConB gp145 and gp160 were significantly more potent than both wild-type vaccines at inducing neutralizing antibodies against tier 1 viruses. Thus, consensus subtype B env immunogens appear to be at least as good as, and in some instances better than, wild-type B env immunogens at inducing a neutralizing antibody response, and are amenable to further improvement by specific gene modifications.     

Processing and routage of HIV glycoproteins by furin to the cell surface

Proteolytic activation of HIV-1 and HIV-2 envelope glycoprotein precursors (gp160 and gp140, respectively) occurs at the carboxyl side of a consensus motif consisting of the highly basic amino acid sequence. We have shown previously (Hallenberger et al., 1997) and confirmed in this report, that furin and PC7 can be considered as the putative physiological enzymes involved in the proteolytic activation of the HIV-1 and HIV-2 envelope precursors. In this study, we show by cell surface biotinylation and immunoprecipitation of the cell surface associated viral glycoproteins with antibodies that the mature viral envelope glycoproteins are correctly transported to the cell. membrane. Furthermore, we show that the uncleaved forms of the glycoproteins (gp160HIV-1 and gp140HIV-2) are also highly represented at the cell surface. First, transient expression of gp160 and gp140 into CV1, a cell line known to be inefficient in the proteolytic processing of the env gene, results in the expression of gp160 and gp140 at the cell surface. Moreover, HIV-1 infection of T cells also showed that gp160 is directed to the cell surface. In addition, we show that the precursor is not incorporated in the virus particle following the budding from the cell surface. Furthermore, a gp160 mutant (deficient for three carbohydrate sites on the gp41), shown to be poorly processed with the coexpressed endoproteases, is found to be transported as an uncleaved precursor to the cell surface. In contrast to HIV envelope glycoproteins, the influenza hemagglutinin precursor (HA0), that is thought to be matured by the furin-like enzymes as well, is found to be retained within the cell and is not able to reach the cell surface. Taken together, these results show that the proteolytic maturation of the viral envelope precursors of human immunodeficiency viruses type 1 and type 2 is not a prerequisite for cell surface targeting of the HIV glycoproteins. Implications of these results for antiviral immune response are discussed.     

Gp120 stability on HIV-1 virions and Gag-Env pseudovirions is enhanced by an uncleaved Gag core

Human immunodeficiency virus type-1 (HIV-1) particles incorporate a trimeric envelope complex (Env) made of gp120 (SU) and gp41 (TM) heterodimers. It has been previously established that soluble CD4 (sCD4) interaction leads to shedding of gp120 from viral particles, and that gp120 may also be easily lost from virions during incubation or particle purification procedures. In the design of HIV particle or pseudovirion-based HIV vaccines, it may be important to develop strategies to maximize the gp120 content of particles. We analyzed the gp120 retention of HIV-1 laboratory-adapted isolates and primary isolates following incubation with sCD4 and variations in temperature. NL4-3 shed gp120 readily in a temperature- and sCD4-dependent manner. Surprisingly, inactivation of the viral protease led to markedly reduced shedding of gp120. Gp120 shedding was shown to vary markedly between HIV-1 strains, and was not strictly determined by whether the isolate was adapted to growth on immortalized T cell lines or was a primary isolate. Pseudovirions produced by expression of codon-optimized gag and env genes also demonstrated enhanced gp120 retention when an immature core structure was maintained. Pseudovirions of optimal stability were produced through a combination of an immature Gag protein core and a primary isolate Env. These results support the feasibility of utilizing pseudovirion particles as immunogens for the induction of humoral responses directed against native envelope structures.     

Structural properties of HIV-1 Env fused with the 14-kDa vaccinia virus envelope protein

To gain insights into the structure-function relationship of the envelope (env) glycoprotein of the human immunodeficiency virus type 1 (HIV-1) we have generated a vaccinia virus (VV) recombinant (VV-14kENV) that expresses a fusion protein (14k-env) consisting of the VV 14-kDa envelope protein (110 amino acids) fused at the C-terminus with HIV-1 env protein (816 amino acids). The 14k-env protein displayed unique structural properties in virus-infected cells. This protein was recognized by 14 kDa-specific antisera as well as HIV-1 env antisera. It was not cleaved during virus infection of cultured cells of various origins, it was stable, it was not released to the medium, and it was not incorporated into virions. Instead of a predicted 174-kDa protein, two proteins of about 110 and 100 kDa were observed. The size reduction of the fusion protein was due to limited glycosylation (110 kDa) and formation of unglycosylated protein (100 kDa). The 14k-env protein formed oligomeric structures and was exposed on the cell surface after virus infection. When mice were inoculated with the recombinant virus that expresses the 14K-env fusion protein, humoral immune response against gp160 was observed. Our findings suggest that 14k-env protein might display novel immunogenic properties.     

The effects of 2-deoxyglucose and tunicamycin on the biosynthesis of the murine mammary tumor virus proteins, and on the assembly and release of the virus

The role of glycosylation in the biosynthesis, processing, and shedding of the murine mammary tumor virus (MuMTV) glycoproteins and in virus production was investigated in a clonal mammary tumor cell line, GR-3A, using two inhibitors of protein glycosylation, 2-deoxyglucose (2-DG) and tunicamycin (TM). It was found that both 2-DG and TM completely inhibited the synthesis of the MuMTV envelope precursor polyprotein, Pr70env, and, as a consequence, the synthesis of the viral glycoproteins gp52 and gp36. By contrast, the synthesis of Pr73gag, the polyprotein precursor of the internal structural proteins of the virus, was only inhibited by 10-15% by 2-DG and TM. Although 2-DG and TM blocked the synthesis of Pr70env, a new polypeptide, related to gp52 and gp36, with a mol wt of 60,000 (P60env) was found to be synthesized in the treated cells. The P60env molecules appeared to be degraded intracellularly since they were not found to (1) undergo site-specific cleavage; (2) accumulate inside the cell or on the cell surface; (3) be secreted into the culture medium; and (4) be incorporated into the virions produced during the drug treatment. In spite of the lack of gp52 and gp36 synthesis in the presence of TM and 2-DG, mature MuMTV particles containing the characteristic surface projections known to be composed of gp52 and gp36 continued to be assembled and released at a reduced rate for at least 30 hr. In addition, the buoyant density and the polypeptide composition of the particles were found to be identical to virions produced by untreated cells. Thus, the virions assembled and released during 2-DG and TM treatment were not defective. Our investigations into the origin of gp52 and gp36 in these particles revealed that both molecules were synthesized prior to 2-DG and TM treatment and continued to be incorporated, along with the newly synthesized viral core proteins, into budding virions during the drug treatment. Furthermore, we found that gp52 and P75env (an aberrant form of Pr70env) that were not incorporated into virions continued to be shed normally from the cell during drug treatment. In conclusion, our results suggest that MuMTV assembly is not dependent on the synchronized synthesis of the viral core and envelope polypeptides, and that the assembled virions contain the correct ratio of these polypeptides, even when their ratio in the cell varies.     

Characterization of an HIV-1 point mutant blocked in envelope glycoprotein cleavage

The envelope proteins of retroviruses are derived from a polypeptide precursor protein by cleavage adjacent to a cluster of basic amino acids. Site-specific mutagenesis was used to construct a mutant of the human immunodeficiency virus type 1 (HIV-1) in which the arginine residue at the carboxy-terminus of the gp120 was changed to a threonine residue. This single substitution was sufficient to abolish all detectable cleavage of the gp160 envelope precursor polypeptide as well as virus infectivity. The gp160 was produced in normal quantities from a biologically active clone of the mutant virus after transfection into cos-1 cells. The mutant gp160 contained N-linked oligosaccharide chains with mannose-rich cores similar to those of the gp160 produced by the wild-type clone. Immunofluorescence assays showed that gp160 was transported to the surface of transfected CD4+ HeLa cells. No envelope proteins of known size could be detected in the media of cells transfected with the mutant virus, suggesting that functional virions were not formed. Binding of the mutant gp160 to the CD4 receptor molecule was unimpaired. Despite this and the presence of gp160 on the cell surface, neither growth of mutant-transfected CD4+ HeLa cells nor cocultivation of transfected cos-1 cells with H9 cells resulted in significant syncytium formation. The data indicate that the carboxy-terminal arginine residue of HIV-1 gp120 is necessary for envelope protein cleavage and suggest cleavage is important in the virus life cycle in both functional virus release and membrane fusion.     

A leucine zipper motif in the cytoplasmic domain of gp41 is required for HIV-1 replication and pathogenesis in vivo.

A leucine zipper motif is conserved in the cytoplasmic domain of glycoprotein gp41 (gp41c) of all HIV-1 subtypes, but is not present in HIV-2 or SIV. The second leucine residue of the leucine zipper was mutated (L95R) to determine the role of this motif in HIV-1 replication and pathogenesis. The L95R mutant replicated to wild-type levels in activated peripheral blood mononuclear cells and CEMx174 cells. However, L95R replication was impaired in SupT1 cells and in the SCID-hu Thy/Liv mouse. Although the infectivity of wild-type virions and that of L95R mutant virions were equally sensitive to heat treatment, we found that L95R produced more defective virions, due to reduced surface expression and virion incorporation of the env glycoprotein. These results suggest that the L95 residue in the leucine zipper of gp41c of HIV-1 plays an important role in the env expression and virion incorporation that is required for viral replication and pathogenesis in the SCID-hu Thy/Liv mouse. The leucine zipper motif in gp41c may provide a novel anti-HIV-1 target.     

The cytoplasmic tail of HIV-1 gp160 contains regions that associate with cellular membranes

The HIV-1 envelope glycoprotein gp160 associates with cellular membranes via a discrete transmembrane domain. Unlike other retroviral envelope proteins, however, gp160 also forms a secondary association with the lipid bilayer mediated by one or more regions located in the cytoplasmic tail. We have expressed the full cytoplasmic tail sequence of gp160, as a fusion protein with the HSV-1 glycoprotein D signal sequence, transiently in a human embryonic kidney cell line. Our results show that in the absence of any defined transmembrane domain or stop transfer sequence, the protein corresponding to the cytoplasmic tail of HIV-1 gp160 formed stable interactions with cellular membranes that mediated its export to the cell surface.     

Recombinant proteins produced by vaccinia virus vectors can be incorporated within the virion (IMV form) into different compartments

Summary.  Vaccinia virus (VV) is one of the largest and most complex of animal viruses, with a virion that contains about 100 different polypeptides. Assembly of the viral proteins occurs in discrete cytoplasmic sites leading to formation of two infectious forms, an abundant (> 90%) intracellular mature virus (IMV) with an envelope, and a minor extracellular enveloped virus (EEV) with an extra membrane acquired from the trans-Golgi network. It has been shown that while EEV contains in the outer membrane cellular proteins probably acquired during virus release from cells, however, IMV exclude host proteins during assembly. Since VV recombinants (VVr) expressing genes of interest are candidates as potential vaccines against pathogens and cancer, it becomes important to know if VVr can acquire foreign proteins during morphogenesis. In this investigation we show that purified virions (IMVs) from VVr can incorporate foreign proteins into different sites in the virus particle. By sequential fractionation of virion compartments with detergents, we found foreign proteins in the lipid envelope (cytokine IL-12 and CS antigen of Plasmodium yoelii), as part of a protein matrix-like membrane (HIV-1 gp41 of env), or more closely associated with the core containing the DNA complexes (HIV-1 gp 160; a multiepitopic protein with the V3 loop of HIV-1 Env from different isolates, and β-galactosidase). Similar findings were observed with purified virions derived from the WR strain as well as from the highly attenuated modified vaccinia virus Ankara (MVA) strain. These observations should be taken into consideration when VVr are used in clinical trials or in other vaccination approaches. Received November 14, 2000 Accepted January 16, 2001     

A group of temperature-sensitive mutants of Moloney leukemia virus which is defective in cleavage of env precursor polypeptide in infected cells also induces hind-limb paralysis in newborn CFW/D mice

A group of temperature sensitive mutants of Moloney murine leukemia virus (MoMuLV) designated as ts1, ts7, and ts11 rapidly and invariably induce hind-limb paralysis ranging from 28 to 52 days postinjection of neonatal CFW/D mice. These temperature-sensitive mutants are defective in the processing of the precursor of the env protein, gPr80env in infected cells, resulting in the accumulation of gPr80env in the infected cell and production of virions with reduced amounts of gp70, p15E, and p12E when compared to that of the wild-type virion. In contrast, two nonparalytogenic ts mutants, ts3 and ts10, like the wild-type virus, show normal processing of gPr80env in infected cells and production of virions with a similar amount of env proteins to that of the wild-type virion.     

Effects of Mutations in Constant Regions 3 and 4 of Envelope of Simian Immunodeficiency Virus

Twenty-six mutant forms of simian immunodeficiency virus strain mac239 were constructed with changes in constant region 4 (C4) of env. Twenty-four of these had a single amino acid change, one had changes in two amino acids, and one had a deletion of eight amino acids. The effects of these mutations on viral replication, gp160 processing, and binding of env protein to soluble CD4 receptor were analyzed. The C4 region was relatively sensitive to sequence changes since only 11 of the 26 mutants replicated appreciably. Eight of the 15 mutants that were replication incompetent exhibited grossly defective processing of the gp160 env precursor; these mutations likely resulted in global effects on gp160 structure. Six of the replication incompetent mutants exhibited normal or near normal gp160 processing and binding of any protein to sCD4 and thus were probably blocked at some step subsequent to binding of virus to its CD4 receptor Only one of the C4 mutations, 441W → R, resulted in greatly decreased binding to sCD4 while retaining normal processing of gp160. The equivalent residue in HIV-1 has similarly been shown previously to be important for binding of HIV-1 to the CD4 receptor. Since a W → S mutation at position 441 in C4 of SIVmac239 affected both gp160 processing and sCD4 binding, it is not clear whether the 441 tryptophan is actually important for contacting CD4 or for maintaining an appropriate configuration. Mutations within a highly conserved GGDPE sequence in C3 of SIVmac239 specifically affected CD4 binding, which is also similar to previous findings with HIV-1. These results demonstrate similar sequence requirements in SIVmac and HIV-1 env for binding CD4, but they raise doubts as to whether C4 sequences are directly involved in the binding.     

Cytotoxic T lymphocyte responses to vaccinia virus antigens but not HIV-1 subtype E envelope protein seen in HIV-1 seronegative Thais

The HIV-1 prime boost phase I/II vaccine trial using a recombinant canarypox vector, vCP1521, containing subtype E env (gp120), and subtype B env (gp41), gag and protease has started in Thailand. We have demonstrated that although 4 from 15 human immunodeficiency virus type 1 (HIV-1) seronegative Individuals showed cytotoxic T lymphocyte (CTL) responses to vaccinia virus antigens, none of them showed specific CTL responses to subtype E Env after in vitro stimulation. This preliminary study suggests that specific CTL responses to subtype E envelope detected in HIV-1 seronegative Individuals after vaccination should be considered as specific responses to the immunization.     

Purification and characterization of a Shiga toxin A subunit-CD4 fusion protein cytotoxic to human immunodeficiency virus-infected cells.

In a previous paper, we reported that a chimeric toxin composed of the enzymatic domain of the Shiga toxin A polypeptide (StxA1) genetically fused to the human CD4 (hCD4) molecule selectively kills cells infected with human immunodeficiency virus type 1 (HIV-1). Although other hCD4-containing chimeras cytotoxic to HIV-infected cells have been developed, there is limited information regarding their receptor binding and internalization. Therefore, the goals of this study were to purify the StxA1-hCD4 fusion protein, identify the receptor(s), and investigate the cytosolic trafficking route used by the chimeric toxin. Sufficient quantities of the StxA1-hCD4 hybrid were isolated for this investigation by using the pET expression and purification system. Cos-1 cells were rendered sensitive to the StxA1-hCD4 chimera by transfection with the env gene, which encodes HIV-1 envelope glycoproteins. The entry and translocation pathway used by the StxA1-hCD4 hybrid toxin was investigated by assessing the protective capacities of chemical reagents which interfere with microfilament movement, acidification of endosomes, and the integrity of the Golgi apparatus. Our findings indicated that the chimera uses HIV-1 glycoprotein gp120, and perhaps gp41, as a receptor which directs its entry through receptor cycling. Uptake is pH independent, and the StxA1-hCD4 hybrid is apparently translocated to the Golgi complex as with other bipartite toxins.     

HIV-1 gp120 Binding to Dendritic Cell Receptors Mobilize the Virus to the Lymph Nodes,but the Induced IL-4 Synthesis by FcεRI+ Hematopoietic Cells Damages the Adaptive Immunity – a Review,Hypothesis, and Implications

HIV-1 is equipped with the envelope gp160 glycoprotein for interaction with Langerhans cells (LCs) and dendritic cells (DCs), the members of the innate immune system, which confront the virus at the portal of virus entry in the human body. These cells are equipped with receptors by which they bind and endocytose the virus. The gp120 glycoprotein is used for binding to CD4 receptor and CCR5 co-receptor of T helper 2 (Th2) cells and the virions shed gp120 is able to induce FcepsilonRI+ hematopoietic cells to produce IL-4, which inactivate the host adaptive immune response. The properties of gp120s various functional domains are analyzed together with the regulatory viral proteins, which are involved in the damage to T and B cells during HIV-1 replication. The interaction of HIV-1 virions through their gp120 with LCs and DCs at the portal of virus entry will be discussed. A hypothesis will be presented that the understanding of the role of the different functional domains of gp120 in the life cycle of the virus and during AIDS will help in the design of approaches to prevent and abrogate HIV-1 infection and AIDS.     

Engineering of noninfectious HIV-1-like particles containing mutant gp41 glycoproteins as vaccine candidates that allow vaccinees to be distinguished from HIV-1 infectees.

Many AIDS vaccine candidates under development may elicit immune responses similar to those observed in and used to screen human immunodeficiency virus type 1 (HIV-1)-infected individuals. Therefore, it is important to develop vaccine candidates that incorporate antigenic markers and allow vaccinees to be distinguished from HIV-1 infectees. To this end, we introduced a series of mutations into and in the vicinity of the major immunodominant region (MIR) of gp41 (residues 598-609), a domain recognized by almost all HIV-1 infectees, and evaluated whether HIV-1-like particles incorporating such mutant glycoproteins could be expressed in mammalian cells. Results indicated that although up to three consecutive amino acids could be replaced within MIR without significantly affecting particle formation or gp160 processing, deletions within MIR impaired envelope processing. Replacement of HIV-1 MIR by part or most of the corresponding domain from other lentiviruses markedly decreased or abolished gp160 processing. Synthetic peptides corresponding to a mutated MIR incorporating three amino acid replacements were not recognized by a panel of sera from HIV-1 infectees, suggesting that HIV-1-like particles with this type of mutation represent potential candidate vaccines that could allow vaccinees to be distinguished from HIV-1 infectees.     

Novel single-round PCR and cloning of full-length envelope genes of HIV-1 may yield new insight into biomolecular antibacterial drug development

Nested or semi-nested polymerase chain reaction (PCR) with a 'hot start' is the preferred amplification method for full-length, in-frame envelope genes (gp160) of the human immunodeficiency virus type 1 (HIV-1). This generally follows an extensive screening process. This paper describes an effective single-round PCR method and cloning process for HIV-1 gp160 from clinical samples, and cell and tissue cultures developed during the early stages of construction of a molecular HIV-1 vaccine. The amplification method and cloning process are adaptable to full-length HIV-1, HIV-2, and other viral production processes. Also described within, is one solution to the most-often extensive screening process for inserts containing full-length, in-frame gp160. Of note, was a perceived toxicity of gp160 to bacteria during the culturing and the scaling-up process that created the extensive screening process. The toxicity association was not found with the individual gp160 genes, the gp120 or the gp41 gene, with other viral regions similar or larger in molecular weight to gp160, or with other non-gp160 full-length genes of HIV-1 such as pol and gag genes. The HIV-1 gp160 toxicity issue may provide insight towards the development of the next generation of novel biomolecular drugs against bacterial infections.