Modification of the Spike Protein for Vaccines against Enveloped RNA Viruses.

Most vaccines work by inducing neutralizing antibodies that target the viral envelope. Enveloped RNA viruses have evolved mechanisms for surface glycoproteins to evade host immune responses, which exhibit substantial variability, even among different strains. Natural infection and vaccines using native forms of surface proteins may induce broadly neutralizing antibodies, yet with low and ineffective levels. Class I membrane-fusion proteins of enveloped RNA viruses, HIV-1, influenza A virus, SARS-CoV-2, yield a stable conformation (so-called "pre-fusion") in providing fusion between viral and host cell membranes. Modified viral surface proteins that are based on these features induce neutralizing antibodies with activity available against a broad spectrum of circulating strains and make it possible to overcome the difficulties associated with escape/variability of viral antigen.

[Modification of the Spike Protein for Vaccines against Enveloped RNA Viruses].

Most vaccines work by inducing neutralizing antibodies that target the viral envelope. Enveloped RNA viruses have evolved mechanisms for surface glycoproteins to evade host immune responses, which exhibit substantial variability, even among different strains. Natural infection and vaccines using native forms of surface proteins may induce broadly neutralizing antibodies, yet with low and ineffective levels. Class I membrane-fusion proteins of enveloped RNA viruses, HIV-1, influenza A virus, SARS-CoV-2, yield a stable conformation (so-called "pre-fusion") in providing fusion between viral and host cell membranes. Modified viral surface proteins that are based on these features induce neutralizing antibodies with activity available against a broad spectrum of circulating strains and make it possible to overcome the difficulties associated with escape/variability of viral antigen.

[Requirements for the Induction of Broadly Neutralizing Antibodies against HIV-1 by Vaccination].

A study of the induction of broadly neutralizing antibodies (bNAbs) in HIV-infected patients and vaccinated subjects revealed the main criteria for the formation of bNAbs (the duration of exposure to a viral antigen, the effect of the diversity of HIV variants, and the removal of barriers associated with the Env-dependent defense mechanisms of HIV-1). Modified trimers of the HIV-1 envelope protein (Env) exposed on virus-like particles (VLP) have unique properties: they (i) modulate the exposure of binding sites (bs) of the CD4 receptor and co-receptor; (ii) create steric restrictions for contact with bNAbs; (iii) increase the Env presentation density, thus enhancing the immune response; (iv) form stable trimers that do not induce off-target immune responses; and (v) allow additional modifications to their structure and construction of a platform with immunostimulating molecules. Immunization using a heterologous subtype-cross prime-boost regime with modified trimeric Env is capable of inducing somatic hypermutation levels necessary for the formation of bNAbs.

[VLP vaccines and effects of HIV-1 Env protein modifications on their antigenic properties].

An ideal protective HIV-1 vaccine can elicit broadly neutralizing antibodies, capable of preventing HIV transmission. The strategies of designing vaccines include generation of soluble recombinant proteins which mimic the native Env complex and are able to enhance the immunogenicity of gp120. Recent data indicate that the cytoplasmic tail (CT) of the Env protein has multiple functions, which can affect the early steps of infection, as well as viral assembly and antigenic properties. Modifications in the CT can be used to induce conformational changes in functional regions of gp120 and to stabilize the trimeric structure, avoiding immune misdirection and induction of non-neutralizing antibody responses. Env-trimers with modified CTs in virus-like particles (VLPs) are able to induce antibodies with broad spectrum neutralizing activity and high avidity and have the potential for developing an effective vaccine against HIV.

An amphipathic sequence in the cytoplasmic tail of HIV-1 Env alters cell tropism and modulates viral receptor specificity.

The human immunodeficiency virus type 1 (HIV-1) 92UG046 Env protein, obtained from a CD4-independent HIV-1 primary isolate (Zerhouni et al., 2004), has the ability to initiate an infection in HeLa cells expressing CD4 when carrying the full-length (FL) Env, but uses CD8 molecules for receptor-mediated entry when carrying a truncated Env (CT84). To determine whether a specific length or structure in the cytoplasmic tail (CT) is responsible for this alteration of tropism, we compared a series of Env constructs with different CT truncations and the presence or absence of an amphipathic alpha- helical sequence. We found that truncated constructs containing the alpha-helical LLP-2 structure in their CT domains conferred a switch from CD4 to CD8 tropism. The results support the conclusion that the structure of the CT domain can play an important role in determining receptor specificity.

Prevention of HIV-1 infection by platinum triazines.

To identify and explore the activity of compounds which may act as anti-HIV virucidal agents, we have investigated platinum compounds, especially those containing N-donor aromatic ligands. After screening over 70 related agents, including N-donor aromatic ligands and metal precursors, we have identified a novel class of platinum(II) complexes with 2-pyridyl-1,2,4-triazine derivatives and Pt(II) formulations with these derivatives (ptt compounds) as having the highest anti-HIV activity. The maximum activity was observed when the agents were added immediately post-infection. The ptt agents did not block cell fusion activity of HIV-1 Env proteins in cells bearing CD4X4 or CD4R5 receptors, indicating a lack of interaction with the Env protein. The ptt compounds exhibit low toxicity for human epithelial cells, and are thus promising candidates for use as microbicides or antiviral agents against HIV.

Effect of the cytoplasmic domain of the simian immunodeficiency virus envelope protein on incorporation of heterologous envelope proteins and sensitivity to neutralization.

In addition to the viral envelope (Env) proteins, host cell-derived proteins have been reported to be present in human immunodeficiency virus and simian immunodeficiency virus (SIV) envelopes, and it has been postulated that they may play a role in infection. We investigated whether the incorporation of host cell proteins is affected by the structure and level of incorporation of viral Env proteins. To compare the cellular components incorporated into SIV particles and how this is influenced by the structure of the cytoplasmic domain, we compared SIV virions with full-length and truncated Env proteins. The levels of HLA-I and HLA-II molecules were found to be significantly (15- to 25-fold) higher in virions with full-length Env than in those with a truncated Env. Virions with a truncated Env were also found to be less susceptible to neutralization by specific antibodies against HLA-I or HLA-II proteins. We also compared the level of incorporation into SIV virions of a coexpressed heterologous viral glycoprotein, the influenza virus hemagglutinin (HA) protein. We found that SIV infection of cells expressing influenza virus HA resulted in the production of phenotypically mixed SIV virions containing influenza virus HA as well as SIV envelope proteins. The HA proteins were more effectively incorporated into virions with full-length Env than in virions with truncated Env. The phenotypically mixed particles with full-length Env, containing higher levels of HA, were sensitive to neutralization with anti-HA antibody, whereas virions with truncated Env proteins and containing lower levels of HA were more resistant to neutralization by anti-HA antibody. In contrast, SIV virions with truncated Env proteins were found to be highly sensitive to neutralization by antisera to SIV, whereas virions with full-length Env proteins were relatively resistant to neutralization. These results indicate that the cytoplasmic domain of SIV Env affects the incorporation of cellular as well as heterologous viral membrane proteins into the SIV envelope and may be an important determinant of the sensitivity of the virus to neutralizing antibodies.

Induction of immune responses to SIV antigens by mucosally administered vaccines.

In an attempt to develop an immunization strategy to induce mucosal and circulatory antibodies against SIV antigens, we have investigated the potential of attenuated recombinant vaccinia virus to deliver SIV antigens (gp160 of SIVmac239) to mucosal surfaces of mice. After systemic or mucosal (intragastric, intranasal, or intrarectal) immunization with vaccinia virus-SIV Env recombinants the immune responses against the envelope glycoprotein of SIV, as well as against vaccinia virus antigens, were assessed by ELISA of serum, saliva, and intestinal and vaginal secretions. All immunization routes induced specific antibody titers against gp160 in both serum and external secretions. Recall responses against SIV were found to be acquired after administration of SIVmac239 Env and Gag antigens in a virus-like particle (VLP) form by the same mucosal routes as those used for the priming with recombinant vaccinia virus. The results obtained demonstrate the potential of vaccinia virus recombinants to elicit a primary immune response at mucosal surfaces, which could be enhanced by delivering the same antigen in the form of VLPs.

Immunogenicity of full length and truncated SIV envelope proteins.

We have compared the immunogenicity of the full-length (FL) SIV envelope (Env) protein and a truncated (T) form of the Env protein which has a short cytoplasmic tail. The Env(T) protein was previously shown to be more fusogenic than Env(FL), has a higher level of incorporation into virus-like particles (VLPs) and membrane vesicles, and expands the viral host range. We have found that mice immunized with VLPs which contained an equal amount of Env(FL) or Env(T) produced similar titres of neutralizing antibody. Comparison of immune responses between animals that received DNA vaccines encoding Env(T) vs. Env (FL) by epidermal delivery demonstrated that a higher level of specific antibody was elicited by Env(T) than Env(FL). This result correlated with a higher level of expression of pCMVEnv(T) than pCMVEnv(FL) observed in vitro. DNA immunization combined with VLP boosting elicited a similar level of neutralizing antibody with both forms of Env proteins. These data indicate that the immunogenicity of Env(FL) and Env(T) is similar, and that either form of Env protein appears to be potentially suitable for use in further development of vaccine preparations.

Development of a rubella virus DNA vaccine.

Two rubella virus DNA vaccines were constructed from a cDNA clone of the rubella virus genomic RNA, one which contained the coding sequences for all three virion proteins (C, E2 and E1) and one which contained the two envelope glycoproteins (E2 and E1). When used to immunize mice via gene gun delivery, both constructs induced an antibody response of equivalent titer to that induced by rubella virus that persisted for at least seven months. A booster injection given four weeks after the initial injection increased antibody titers by over thirty-fold. The antibody response in DNA vaccine-injected mice was directed primarily against the E1 glycoprotein, as was the case in rubella virus-injected mice, and neutralizing activity was detected. These DNA vaccines are thus prototypes for a nonreplicating rubella virus vaccine that could be used in specialized circumstances.

Assembly and release of SIV env proteins with full-length or truncated cytoplasmic domains.

We have used recombinant vaccinia viruses expressing full-length or truncated gag or env genes of SIVmac239 to investigate the requirements for assembly of SIV proteins. We observed that assembly of virus-like particles (VLPs) was found to be 3- to 5-fold higher with full-length Env than with the truncated forms, or than VLPs containing only Gag proteins, in primary monkey cells or various human cell lines. When cells expressing Env proteins in the absence of Gag were examined by immunoelectron microscopy, clusters of Env protein and membrane vesicles containing Env proteins were observed at cell surfaces. A low level of vesicles was released from cells expressing full-length Env, but about a 10-fold higher level was released in cells expressing a truncated form of Env [Env733(t)] in which the cytoplasmic domain is only 17 amino acids in length. Another truncated protein, Env718(t), with a short cytoplasmic tail of 3 aa, was also incorporated into VLPs at a 10-fold higher level than the full-length Env protein and was more efficiently released in vesicles. The mature SU and TM proteins were predominantly incorporated into VLPs with full-length Env, but both cleaved and uncleaved precursor proteins were present in VLPs with truncated Env as well as in Env and Env(t) vesicles. A more prominent layer of spikes was seen by electron microscopy in VLPs with truncated Env than in VLPs containing full-length Env. These results indicate that truncated Env proteins have the ability to self-associate on the cell surface and are assembled into a more closely packed array than full-length Env, which could explain the preferential incorporation of Env proteins with short cytoplasmic tails into virions.

Highly immunogenic human immunodeficiency viruslike particles are produced by recombinant vaccinia virus-infected cells.

CV-1 cells were infected with two recombinant vaccinia viruses carrying the gag gene with deletion of 231 bp from 3' terminus (strain vC5) and env gene (strain vE234L) of human immunodeficiency virus type 1 (HIV-1). Both recombinant proteins synthesized in the cells (p50gag and gp160/120env) were localized predominantly in cell membranes; however, some amount of p50 was found in cell nuclei. Thin-section immunoelectron microscopy showed accumulation of viruslike particles undistinguished from immature HIV-1 virions in the culture medium of the cells infected with vC5. The similar particles containing gag and env proteins were produced into the culture medium when the cells were coinfected with vC5 and vE234L strains. The particles contained heterogeneous cellular RNA, but no virus-specific RNA as shown by Northern blot hybridization. Immunization of the rabbits with purified viruslike particles produced virus-specific antibodies against gag and env proteins. The titer of antibodies was significantly higher than after immunization with cell lysate or recombinant proteins purified from the infected cells. Highly immunogenic HIV-1-like particles containing gag and env proteins but no virus-specific RNA are good candidates for potential vaccine.

[Formation of virus-like particles by HIV-1 Gag proteins, expressed by a recombinant vaccinia virus]. / Obrazovanie virusopodobnykh chastits belkov Gag VICh-1, ékspressiruemym rekombinantnym virusom ospovaktsiny.

Monkey kidney cells CV-1 were infected with recombinant vaccinia virus carrying HIV-1 gag gene with a deletion of 230 nucleotide pairs from the 3'-terminus. The main gene product detected in the lysates of infected cells was the gag precursor rp50. The protein was accumulated on the cell membranes suggesting that it had a myristylated N-terminus, and was cleaved by a recombinant virus specific protease with the formation of two proteins, p17 and p24 corresponding in molecular masses to mature gag proteins. Virus-like particles similar to immature HIV virions were budding from the surface of infected cells. They look like the ring of optically dense material covered with a lipid bilayer, of the same size (100-120 nm) and of the same density in a sucrose gradient (1.16-1.18 g/ml) as HIV-1 virions. The particles contained rp50 and cellular heterogeneous RNA. Thus, the unprocessed gag precursor with deleted 77 amino acid residues from the C-terminus is able to form virus-like particles in the absence of env proteins and virus-specific RNA, and these particles are budding from the cell surface. The question about the use of extracellular Gag-particles for AIDS diagnostic work and construction of vaccines is discussed.

Intracellular localization of recombinant vaccinia virus produced HIV antigens and their use for confirmation of HIV seropositivity.

Recombinant vaccinia strains vC5 and vE234L expressing the rp50 and rgp160/rgp120 recombinant proteins were used in immunoblot and immunofluorescence assays. No false reactions were found, although 30 sera giving false reactivity with gag or env encoded proteins in a commercial immunoblot assay were included into the test panel. We recommend the recombinant protein-based assay for confirmation and discrimination of HIV seropositivity.