New developments in rabies vaccination.

Current rabies vaccines are safe and, when administered properly, they are highly effective. In addition, they elicit long-lasting immunity, with virus-neutralising antibody titres persisting for years after vaccination. However, current regimens require multiple doses to achieve high neutralising titres and they are costly, which means that it is difficult for developing countries, where rabies deaths are highest, to implement widespread vaccination. New innovations are the only way to reduce rabies disease to acceptable rates. Numerous preclinical and clinical studies are under way, testing novel vaccines, adjuvants and injection methods. Research into the use of live vaccines and alternative vaccine vectors is ongoing, while attempts to develop DNA vaccines have so far failed to match the immunogenicity and neutralising capability of traditional vaccines. The development of molecular adjuvants that induce faster, stronger immune responses with less antigen has yielded exciting preclinical results and appears to edge us closer to a better rabies vaccine. However, steep challenges remain: molecular adjuvants require administration with live vaccines, and differences in species specificity of immune molecules complicate development. Over all, the array of research undertaken over the past decade is impressive and encouraging, but most new vaccines have yet to be tested in clinical trials, and the viability of such experimental vaccines in the global market remains to be seen. Only a vaccine that outperforms currently available vaccines in every area will have a chance at widespread adoption. Nevertheless, the authors are confident that some vaccine candidates will meet these criteria.

Les vaccins actuels contre la rage sont sûrs et très efficaces lorsqu'ils sont administrés correctement. En outre, ils confèrent une immunité durable, avec le maintien de titres neutralisants d'anticorps plusieurs années après la vaccination. Néanmoins, les régimes actuels nécessitent l'administration de plusieurs doses pour obtenir des titres élevés d'anticorps neutralisants et ils sont onéreux, de sorte que la vaccination à grande échelle est difficile à mettre en oeuvre dans les pays en développement, pourtant les plus touchés par la mortalité par rage. Seule l'adoption de solutions innovantes permettra de ramener l'incidence de la rage à un niveau acceptable. De nombreuses études précliniques et cliniques sont en cours, visant à tester les innovations en matière de vaccins, de modes d'injection et d'adjuvants. La recherche sur l'utilisation de vaccins à virus vivant et sur de nouveaux vecteurs vaccinaux se poursuit, alors que les tentatives de développement de vaccins à ADN n'ont pas réussi jusqu'à présent à obtenir un effet immunogène ou des capacités de neutralisation virale équivalents à ceux des vaccins traditionnels. Les résultats d'essais précliniques sur de nouveaux adjuvants moléculaires induisant une réponse immune plus rapide et plus puissante avec moins d'antigène sont extrêmement prometteurs et semblent annoncer l'imminence de meilleurs vaccins contre la rage. Il subsiste toutefois d'importantes difficultés : les adjuvants moléculaires ne peuvent être administrés qu'avec des vaccins vivants et les différences de spécificité d'espèce des molécules immunes rendent le développement plus complexe. Globalement, les efforts déployés depuis une décennie par la recherche sont impressionnants et encourageants mais la plupart des nouveaux vaccins doivent encore être soumis à des essais cliniques ; d'autre part la viabilité de ces vaccins expérimentaux dans le marché mondial reste à démontrer. Seul un vaccin capable de surpasser les performances des vaccins actuels dans chaque domaine aura une chance d'être largement adopté. Les auteurs estiment cependant que certains vaccins candidats pourront satisfaire à ces exigences.

Las actuales vacunas antirrábicas son seguras y, si se administran debidamente, muy eficaces. Además, inducen inmunidad duradera, con títulos de anticuerpos neutralizantes que subsisten años después de la vacunación. Sin embargo, los regímenes actuales resultan costosos y exigen dosis múltiples para lograr títulos de neutralización elevados, lo que dificulta a los países en desarrollo, que son los más golpeados por la rabia, la implantación generalizada de la vacunación. El único camino para reducir la rabia a niveles aceptables pasa por la innovación. Están en marcha numerosos estudios preclínicos y clínicos en los que se ensayan vacunas, adyuvantes y métodos de inyección novedosos. También sigue adelante la investigación sobre el uso de vacunas vivas y vectores vacunales alternativos, mientras que ninguna de las tentativas realizadas hasta la fecha con vacunas de ADN ha deparado niveles de inmunogenicidad y capacidad de neutralización equiparables a los de las vacunas tradicionales. La obtención de adyuvantes moleculares que inducen una respuesta inmunitaria más rápida y vigorosa en presencia de menos cantidad de antígeno ha dado resultados preclínicos muy interesantes y poco a poco parece acercarnos al logro de una mejor vacuna antirrábica. Subsisten, empero, arduas dificultades: los adyuvantes moleculares solo funcionan si se administran con vacunas vivas, y las diferencias existentes entre las especies en cuanto a la especificidad de las moléculas inmunitarias complican las labores de desarrollo. Globalmente, el conjunto de investigaciones emprendidas en el último decenio es impresionante y alentador, pero la mayoría de las nuevas vacunas aún deben pasar por la fase de ensayo clínico, y está por ver qué viabilidad tienen estas vacunas experimentales en el mercado mundial. Solo una vacuna que supere a las actuales en todos los aspectos tiene posibilidades de ser adoptada a gran escala. Pese a todo, los autores expresan su confianza en que algunas de las vacunas candidatas cumplan estos criterios.

Role of virus-induced neuropeptides in the brain in the pathogenesis of rabies.

Rabies virus (RABV) infection is characterized by the rapid neuronal spread of RABV into the CNS before a protective immune response is raised. Therefore, a typical feature of RABV infection is the paucity of inflammatory reactions in the brain. Here we examined whether the induction of immunosuppressive neuropeptides, in particular CGRP, may contribute to the ability of RABV to evade immune responses. RABV infection of mice caused a strong induction of calcitonin gene-related peptide (CGRP) in neurons and fibres in the neocortex as well as in the dentate gyrus and CA1 region of the hippocampus although RABV did not infect neurons in which CGRP expression was upregulated. Neuropeptide Y (NPY) or vasoactive intestinal peptide (VIP) expressing neurons also were not infected by RABV. In contrast, somatostatin neurons were infected by RABV. There was evidence for an RABV-induced increase of VIP and somatostatin but not of NPY. To test how CGRP expression is related to TNFalpha-induced enhancement of CNS innate and adaptive immunity during RABV infection, we used recombinant RABVs that contained either an active (SPBN-TNFalpha(+)) or an inactive (SPBN-TNFalpha(-)) TNFalpha gene. As compared to SPBN-TNFalpha(-), infection with SPBN-TNFalpha(+) attenuated the induction of CGRP but simultaneously enhanced induction of the invariant chain of MHC II, microglial activation and T cell infiltration. In conclusion, distinct neuropeptidergic neurons in the brain are remarkably spared from RABV infection suggesting a pivotal role of neuropeptides during CNS virus infection. Given the inhibitory effect of CGRP on antigen presentation, we propose that the strong RABV-induced upregulation of CGRP in the brain may contribute to the mechanism by which RABV escapes immune detection. Targeting the expression of neuropeptides, in particular CGRP, that are induced during RABV infection may open a new avenue for therapeutic intervention in human rabies.

Rhabdoviruses and the cellular ubiquitin-proteasome system: a budding interaction.

The matrix (M) proteins of vesicular stomatitis virus (VSV) and rabies virus (RV) play a key role in both assembly and budding of progeny virions. A PPPY motif (PY motif or late-budding domain) is conserved in the M proteins of VSV and RV. These PY motifs are important for virus budding and for mediating interactions with specific cellular proteins containing WW domains. The PY motif and flanking sequences of the M protein of VSV were used as bait to screen a mouse embryo cDNA library for cellular interactors. The mouse Nedd4 protein, a membrane-localized ubiquitin ligase containing multiple WW domains, was identified from this screen. Ubiquitin ligase Rsp5, the yeast homolog of Nedd4, was able to interact both physically and functionally with full-length VSV M protein in a PY-dependent manner. Indeed, the VSV M protein was multiubiquitinated by Rsp5 in an in vitro ubiquitination assay. To demonstrate further that ubiquitin may be involved in the budding process of rhabdoviruses, proteasome inhibitors (e.g., MG132) were used to decrease the level of free ubiquitin in VSV- and RV-infected cells. Viral titers measured from MG132-treated cells were reproducibly 10- to 20-fold lower than those measured from untreated control cells, suggesting that free ubiquitin is important for efficient virus budding. Last, release of a VSV PY mutant was not inhibited in the presence of MG132, signifying that the functional L domain of VSV is required for the inhibitory effect exhibited by MG132. These data suggest that the cellular ubiquitin-proteasome machinery is involved in the budding process of VSV and RV.

Overexpression of cytochrome C by a recombinant rabies virus attenuates pathogenicity and enhances antiviral immunity.

The pathogenicity of individual rabies virus strains appears to correlate inversely with the extent of apoptotic cell death they induce and with the expression of rabies virus glycoprotein, a major inducer of an antiviral immune response. To determine whether the induction of apoptosis by rabies virus contributes to a decreased pathogenicity by stimulating antiviral immunity, we have analyzed these parameters in tissue cultures and in mice infected with a recombinant rabies virus construct that expresses the proapoptotic protein cytochrome c. The extent of apoptosis was strongly increased in primary neuron cultures infected with the recombinant virus carrying the active cytochrome c gene [SPBN-Cyto c(+)], compared with cells infected with the recombinant virus containing the inactive cytochrome c gene [SPBN-Cyto c(-)]. Mortality in mice infected intranasally with SPBN-Cyto c(+) was substantially lower than in SPBN-Cyto c(-)-infected mice. Furthermore, virus-neutralizing antibody (VNA) titers were significantly higher in mice immunized with SPBN-Cyto c(+) at the same dose. The VNA titers induced by these recombinant viruses paralleled their protective activities against a lethal rabies virus challenge infection, with SPBN-Cyto c(+) revealing an effective dose 20 times lower than that of SPBN-Cyto c(-). The strong increase in immunogenicity, coupled with the marked reduction in pathogenicity, identifies the SPBN-Cyto c(+) construct as a candidate for a live rabies virus vaccine.

Vaccinia virus-free recovery of vesicular stomatitis virus.

The advent of reverse-genetics represents a powerful new approach to elucidate aspects of negative-sense RNA virus replication. The reverse-genetics system established previously for vesicular stomatitis virus (VSV) required four plasmids encoding the nucleoprotein (N), phosphoprotein (P), polymerase (L), and the full-length, anti-genomic RNA. Transcription to yield the antigenomic RNA as well as the N, P, and L, mRNAs was initiated by bacteriophage T7 polymerase expressed from a recombinant Vaccinia virus. In this report, we describe the successful recovery of infectious VSV in the absence of Vaccinia virus. The N, P, and L genes of VSV were inserted downstream of both the T7 promoter and an internal ribosomal entry site (IRES element). T7 polymerase was expressed constitutively from BSR-T7/5 cells. RTPCR was used to confirm that the recovered VSV was derived from transfected DNA. Virion protein profile, CPE in tissue culture, and virus titer of the recombinant VSV were indistinguishable from those of parental VSV. Thus, the need for Vaccinia virus is eliminated with this system, making it an attractive, alternative approach for the recovery of infectious VSV from DNA.

Mechanisms of loss of foreign gene expression in recombinant vesicular stomatitis viruses.

We investigated the stability and mechanisms of loss of foreign gene expression in two recombinant vesicular stomatitis viruses (VSVs). A recombinant expressing the cellular CD4 protein exhibited remarkable stability of foreign gene expression. However, after 26 sequential passages, a mutant no longer expressing CD4 was recovered from the virus stock. Sequencing of the CD4 coding region in this mutant revealed a single nucleotide deletion causing a frameshift and termination of protein synthesis. A second VSV recombinant expressing the measles virus F protein grew poorly and exhibited extreme instability of expression of the F protein. Expression of F protein was lost rapidly through mutations of the upstream transcription termination site from (3')AUAC(5') to (3')AUAU(5'), as well as lengthening of the subsequent U(7) tract that is the template for poly(A) addition to VSV G mRNA. Such mutations resulted in fusion of the F mRNA to the 3' end of the G mRNA, making the F protein translation initiation codon inaccessible. We suggest that the VSV polymerase is error prone during replication of the U(7) tract, providing a rapid means for complete elimination of expression of proteins that are toxic to the virus life cycle.

Expression and immunogenicity of human immunodeficiency virus type 1 Gag expressed by a replication-competent rhabdovirus-based vaccine vector.

A replication-competent rhabdovirus-based vector expressing human immunodeficiency virus type 1 (HIV-1) Gag protein was characterized on human cell lines and analyzed for the induction of a cellular immune response in mice. We previously described a rabies virus (RV) vaccine strain-based vector expressing HIV-1 gp160. The recombinant RV was able to induce strong humoral and cellular immune responses against the HIV-1 envelope protein in mice (M. J. Schnell et al., Proc. Natl. Acad. Sci. USA 97:3544-3549, 2000; J. P. McGettigan et al., J. Virol. 75:4430-4434, 2001). Recent research suggests that the HIV-1 Gag protein is another important target for cell-mediated host immune defense. Here we show that HIV-1 Gag can efficiently be expressed by RV on both human and nonhuman cell lines. Infection of HeLa cells with recombinant RV expressing HIV-1 Gag resulted in efficient expression of HIV-1 precursor protein p55 as indicated by both immunostaining and Western blotting. Moreover, HIV-1 p24 antigen capture enzyme-linked immunosorbent assay and electron microscopy showed efficient release of HIV-1 virus-like particles in addition to bullet-shaped RV particles in the supernatants of the infected cells. To initially screen the immunogenicity of this new vaccine vector, BALB/c mice received a single vaccination with the recombinant RV expressing HIV-1 Gag. Immunized mice developed a vigorous CD8(+) cytotoxic T-lymphocyte response against HIV-1 Gag. In addition, 26.8% of CD8(+) T cells from mice immunized with RV expressing HIV-1 Gag produced gamma interferon after challenge with a recombinant vaccinia virus expressing HIV-1 Gag. These results further confirm and extend the potency of RV-based vectors as a potential HIV-1 vaccine.

Viral vectors as potential HIV-1 vaccines.

Vaccine vectors based on recombinant viruses have great promise to play an important role in the development of an effective HIV-1 vaccine. Within the last 10 years a wide range of viruses have been investigated for their ability to express protein(s) from foreign pathogens and to induce specific immunological responses against these antigen(s) in vivo. Each viral vector has its own unique biological characteristics and thus far none of them has proven to be an ideal candidate as a vaccine vehicle for HIV-1. This review focuses on both replication competent and non-replication competent viral vectors as a potential HIV-1 vaccine. Other approaches for the development of an HIV-1 vaccine are reviewed elsewhere and are beyond the scope of this review.

Genetic engineering of live rabies vaccines.

Rabies virus is not a single entity but consists of a wide array of variants that are each associated with different host species. These viruses differ greatly in the antigenic makeup of their G proteins, the primary determinant of pathogenicity and major inducer of protective immunity. Due to this diversity, existing rabies vaccines have largely been targeted to individual animal species. In this report, a novel approach to the development of rabies vaccines using genetically modified, reverse-engineered live attenuated rabies viruses is described. This approach entails the engineering of vaccine rabies virus containing G proteins from virulent strains and modification of the G protein to further reduce pathogenicity. Strategies employed included exchange of the arginine at position 333 for glutamine and modification of the cytoplasmic domain. The recombinant viruses obtained were non-neuroinvasive when administered via a peripheral route. The ability to confer protective immunity depended largely upon conservation of the G protein antigenic structure between the vaccine and challenge virus, as well as on the route of immunization.

High level expression of a human rabies virus-neutralizing monoclonal antibody by a rhabdovirus-based vector.

Humans exposed to rabies virus must be promptly treated by passive immunization with anti-rabies antibody and active immunization with rabies vaccine. Currently, antibody prepared from pooled human serum or from immunized horses is utilized. However, neither of these reagents are readily available, entirely safe, or consistent in their biological activity. An ideal reagent would consist of a panel of human monoclonal antibodies. Such antibodies are now available, their only drawback being the cost of production. Using recombinant technology, we constructed a rabies virus-based vector which expresses high levels (approximately 60 pg/cell) of rabies virus-neutralizing human monoclonal antibody. The vector is a modified vaccine strain of rabies virus in which the rabies virus glycoprotein has been replaced with a chimeric vesicular stomatitis virus glycoprotein, and both heavy and light chain genes encoding a human monoclonal antibody have been inserted. This recombinant virus can infect a variety of mammalian cell lines and is non-cytolytic, allowing the use of cell culture technology routinely employed to produce rabies vaccines.

Rabies virus-based vectors expressing human immunodeficiency virus type 1 (HIV-1) envelope protein induce a strong, cross-reactive cytotoxic T-lymphocyte response against envelope proteins from different HIV-1 isolates.

Novel viral vectors that are able to induce both strong and long-lasting immune responses may be required as effective vaccines for human immunodeficiency virus type 1 (HIV-1) infection. Our previous experiments with a replication-competent vaccine strain-based rabies virus (RV) expressing HIV-1 envelope protein from a laboratory-adapted HIV-1 strain (NL4-3) and a primary HIV-1 isolate (89.6) showed that RV-based vectors are excellent for B-cell priming. Here we report that cytotoxic T-lymphocyte (CTL) responses against HIV-1 gp160 are induced by recombinant RVs. Our results indicated that a single inoculation of mice with an RV expressing HIV-1 gp160 induced a solid and long-lasting memory CTL response specific for HIV-1 envelope protein. Moreover, CTLs from immunized mice were not restricted to the homologous HIV-1 envelope protein and were able to cross-kill target cells expressing HIV-1 gp160 from heterologous HIV-1 strains. These studies further suggest promise for RV-based vectors to elicit a persistent immune response against HIV-1 and their potential utility as efficacious anti-HIV-1 vaccines.

A recombinant rabies virus expressing vesicular stomatitis virus glycoprotein fails to protect against rabies virus infection.

To investigate the importance of the rabies virus (RV) glycoprotein (G) in protection against rabies, we constructed a recombinant RV (rRV) in which the RV G ecto- and transmembrane domains were replaced with the corresponding regions of vesicular stomatitis virus (VSV) glycoprotein (rRV-VSV-G). We were able to recover rRV-VSV-G and found that particle production was equal to rRV. However, the budding of the chimeric virus was delayed and infectious titers were reduced 10-fold compared with the parental rRV strain containing RV G. Biochemical analysis showed equal replication rates of both viruses, and similar amounts of wild-type and chimeric G were present in the respective viral particles. Additional studies were performed to determine whether the immune response against rRV-VSV-G was sufficient to protect against rabies. Mice were primed with rRV or rRV-VSV-G and challenged with a pathogenic strain of RV 12 days later. Similar immune responses against the internal viral proteins of both viruses indicated successful infection. All mice receiving the rRV vaccine survived the challenge, whereas immunization with rRV-VSV-G did not induce protection. The results confirm the crucial role of RV G in an RV vaccine.

Reinvestigation of the role of the rabies virus glycoprotein in viral pathogenesis using a reverse genetics approach.

The rabies virus glycoprotein (G) gene of the highly neuroinvasive and neurotropic strains SHBRV-18, CVS-N2c, and CVS-B2c was introduced into the non-neuroinvasive and less neurotropic SN-10 strain to provide further insight into the role of G in the pathogenesis of rabies. Phenotypic analyses of the recombinant viruses revealed, as expected, that the neurotropism of a particular rabies virus strain was a function of its G. Nevertheless, the pathogenicity of the recombinant viruses was, in every case, markedly lower than that of the wild-type viruses suggesting that while the G dictates neurotropism, other viral attributes are also important in pathogenesis. The low pathogenicity of the recombinant viruses is at least in part due to a strong increase in transcription activity. On the other hand, the production of infectious virus by the R-SHB18 recombinant virus-infected cells was significantly delayed by comparison with SHBRV-18 wild-type virus infected-cells. Replacement of the R-SHB18 G cytoplasmic domain, transmembrane domain, and stem region with its SN-10 G counterparts neither results in a significant increase in budding efficiency nor an increase in pathogenicity. These results suggest that an optimal match of the cytoplasmic domain of G with the matrix protein may not be sufficient for maximal virus budding efficiency, which is evidently a major factor of virus pathogenicity. Our studies indicate that to maintain pathogenicity, the interactions between various structural elements of rabies virus must be highly conserved and the expression of viral proteins, in particular the G protein, must be strictly controlled.

Recombinant rabies virus as potential live-viral vaccines for HIV-1.

Recombinant, replication-competent rabies virus (RV) vaccine strain-based vectors were developed expressing HIV type I (HIV-1) envelope glycoprotein (gp160) from both a laboratory-adapted (CXCR4-tropic) and a primary (dual-tropic) HIV-1 isolate. An additional transcription stop/start unit within the RV genome was used to express HIV-1 gp160 in addition to the other RV proteins. The HIV-1 gp160 protein was stably and functionally expressed, as indicated by fusion of human T cell lines after infection with the recombinant RVs. Inoculation of mice with the recombinant RVs expressing HIV-1 gp160 induced a strong humoral response directed against the HIV-1 envelope protein after a single boost with recombinant HIV-1 gp120 protein. Moreover, high neutralization titers up to 1:800 against HIV-1 could be detected in the mouse sera. These data indicate that a live recombinant RV, a rhabdovirus, expressing HIV-1 gp160 may serve as an effective vector for an HIV-1 vaccine.

Recombinant vesicular stomatitis virus expressing respiratory syncytial virus (RSV) glycoproteins: RSV fusion protein can mediate infection and cell fusion.

The genes encoding the respiratory syncytial virus (RSV) attachment (G) and fusion (F) envelope glycoproteins were expressed separately as additional genes in recombinant vesicular stomatitis viruses (VSV). Cells infected with the VSV-RSV F recombinant formed large syncytia illustrating the fusion activity of F in absence of other RSV proteins. Both F and G glycoproteins were expressed at the cell surface and incorporated into virions. Incorporation of these proteins did not require cytoplasmic tail sequences of VSV G. Using a compound, ammonium chloride, that raises the endosomal pH, we showed that presence of the RSV F glycoprotein in the envelope of recombinant VSV allowed for infectivity through a low-pH-independent pathway. Recombinant VSV expressing RSV glycoproteins could be useful as an RSV vaccine.

Generation of mucosal cytotoxic T cells against soluble protein by tissue-specific environmental and costimulatory signals.

We compared peripheral and mucosal primary CD8 T cell responses to inflammatory and noninflammatory forms of antigen in a T cell-adoptive transfer system. Immunization with the soluble antigen, ovalbumin (ova), administered i.p. or orally without adjuvant, activated nonmucosal CD8 T cells but did not induce cytotoxic activity. However, after activation, the transferred cells entered the intestinal mucosa and became potent antigen-specific killers. Thus, exogenous intact soluble protein entered the major histocompatibility complex class I antigen presentation pathway and induced mucosal cytotoxic T lymphocytes. Moreover, distinct costimulatory requirements for activation of peripheral versus mucosal T cells were noted in that the CD28 ligand, B7-1, was critical for activated mucosal T cell generation but not for activation of peripheral CD8 T cells. The costimulator, B7-2, was required for optimum activation of both populations. Infection with a new recombinant vesicular stomatitis virus encoding ovalbumin induced lytic activity in mucosal as well as peripheral sites, demonstrating an adjuvant effect of inflammatory mediators produced during virus infection. Generation of antiviral cytotoxic T lymphocytes was also costimulation-dependent. The results indicated that induction of peripheral tolerance via antigen administration may not extend to mucosal sites because of distinct costimulatory and inflammatory signals in the mucosa.

Requirement for a non-specific glycoprotein cytoplasmic domain sequence to drive efficient budding of vesicular stomatitis virus.

The cytoplasmic domains of viral glycoproteins are often involved in specific interactions with internal viral components. These interactions can concentrate glycoproteins at virus budding sites and drive efficient virus budding, or can determine virion morphology. To investigate the role of the vesicular stomatitis virus (VSV) glycoprotein (G) cytoplasmic and transmembrane domains in budding, we recovered recombinant VSVs expressing chimeric G proteins with the transmembrane and cytoplasmic domains derived from the human CD4 protein. These unrelated foreign sequences were capable of supporting efficient VSV budding. Further analysis of G protein cytoplasmic domain deletion mutants showed that a cytoplasmic domain of only 1 amino acid did not drive efficient budding, whereas 9 amino acids did. Additional studies in agreement with the CD4-chimera experiments indicated the requirement for a short cytoplasmic domain on VSV G without the requirement for a specific sequence in that domain. We propose a model for VSV budding in which a relatively non-specific interaction of a cytoplasmic domain with a pocket or groove in the viral nucleocapsid or matrix proteins generates a glycoprotein array that promotes viral budding.

Construction of a novel virus that targets HIV-1-infected cells and controls HIV-1 infection.

We describe a recombinant vesicular stomatitis virus lacking its glycoprotein gene and expressing instead the HIV-1 receptor CD4 and a coreceptor, CXCR4. This virus was unable to infect normal cells but did infect, propagate on, and kill cells that were first infected with HIV-1 and therefore had the HIV membrane fusion protein on their surface. Killing of HIV-1-infected cells controlled HIV infection in a T cell line and reduced titers of infectious HIV-1 in the culture by as much as 10(4)-fold. Such a targeted virus could have therapeutic value in reducing HIV viral load. Our results also demonstrate a general strategy of targeting one virus to the envelope protein of another virus to control infection.

High-efficiency incorporation of functional influenza virus glycoproteins into recombinant vesicular stomatitis viruses.

We derived recombinant vesicular stomatitis virus (VSV) expressing either influenza virus hemagglutinin (HA) or neuraminidase (NA) glycoproteins from extra genes inserted in the viral genome. The HA protein was expressed from a site downstream of the VSV glycoprotein (G) gene, while NA protein was expressed from a site upstream of the VSV G gene. The HA protein was expressed at lower levels than the VSV G protein, while the NA protein was expressed at higher levels, as expected from the gradient of VSV transcription that follows the gene order. The HA and NA proteins were transported to the cell surface and were functional as demonstrated by hemadsorption, hemolysis, and NA assays. Biochemical analysis showed that both HA and NA proteins were incorporated into VSV particles at high levels, although there was a preference for incorporation of the VSV G protein over either of the influenza virus proteins. Immunoelectron microscopy of the recombinants showed that the particles derived from the recombinants were mosaics carrying both the VSV G protein and the influenza virus membrane glycoproteins. These results extend earlier studies showing incorporation of the cellular glycoprotein CD4 and two other viral glycoproteins into VSV particles. Our results indicate that there is significant space in the VSV membrane that can accommodate foreign membrane proteins and that the foreign protein can represent as much as 35% of the total protein in the viral envelope. Incorporation of foreign proteins into VSV virions can, in many cases, occur passively in the absence of specific incorporation signals.

Specific targeting to CD4+ cells of recombinant vesicular stomatitis viruses encoding human immunodeficiency virus envelope proteins.

We generated replication-competent, recombinant vesicular stomatitis viruses (VSVs) expressing the human immunodeficiency virus (HIV) envelope protein or an HIV-VSV chimeric envelope protein in which the cytoplasmic domain of the HIV envelope protein was replaced with that from the VSV glycoprotein (G). These recombinants were generated with HIV type 1 (HIV-1) envelopes from both laboratory and primary isolates of HIV-1. The replication-competent recombinant viruses were stable and expressed the foreign proteins at high levels from extra transcription units in VSV. The foreign proteins were processed appropriately and transported to the cell surface. The incorporation of HIV gp120 into VSV particles was demonstrated biochemically only for the construct expressing the chimeric envelopes containing the VSV G cytoplasmic domain. The incorporation of the chimeric HIV envelope protein into the membrane of the recombinant VSV was also demonstrated by electron microscopy with gold-conjugated antibodies. To determine whether specific infection of CD4-positive cells could be demonstrated for these recombinants, we neutralized VSV infectivity due to VSV glycoprotein with anti-VSV serum. The neutralized recombinants expressing the chimeric envelope were able to infect only HeLa cells expressing CD4, and this CD4-specific infectivity was neutralized with anti-HIV serum. This assay also detected a 100-fold-lower titer of CD4-specific infectivity for the VSV recombinant expressing the wild-type HIV envelope. Our results illustrate that it is possible to express functional HIV envelopes from the VSV genome and target the recombinant virus to an alternative receptor. The recombinants may also prove useful as HIV vaccines.