Development of recombinant varicella-zoster virus vaccines

Increased cellular immune responses and CD4+ T-cell proliferation correlate with reduced plasma viral load in SIV challenged recombinant simian varicella virus - simian immunodeficiency virus (rSVV-SIV) vaccinated rhesus macaques

Background

An effective AIDS vaccine remains one of the highest priorities in HIV-research. Our recent study showed that vaccination of rhesus macaques with recombinant simian varicella virus (rSVV) vector – simian immunodeficiency virus (SIV) envelope and gag genes, induced neutralizing antibodies and cellular immune responses to SIV and also significantly reduced plasma viral loads following intravenous pathogenic challenge with SIV_MAC251/CX1.

Findings

The purpose of this study was to define cellular immunological correlates of protection in rSVV-SIV vaccinated and SIV challenged animals. Immunofluorescent staining and multifunctional assessment of SIV-specific T-cell responses were evaluated in both Experimental and Control vaccinated animal groups. Significant increases in the proliferating CD4+ T-cell population and polyfunctional T-cell responses were observed in all Experimental-vaccinated animals compared with the Control-vaccinated animals.

Conclusions

Increased CD4+ T-cell proliferation was significantly and inversely correlated with plasma viral load. Increased SIV-specific polyfunctional cytokine responses and increased proliferation of CD4+ T-cell may be crucial to control plasma viral loads in vaccinated and SIV_MAC251/CX1 challenged macaques.

Recombinant varicella vaccines induce neutralizing antibodies and cellular immune responses to SIV and reduce viral loads in immunized rhesus macaques

The development of an effective AIDS vaccine remains one of the highest priorities in HIV research. The live, attenuated varicella-zoster virus (VZV) Oka vaccine, safe and effective for prevention of chickenpox and zoster, also has potential as a recombinant vaccine against other pathogens, including human immunodeficiency virus (HIV). The simian varicella model, utilizing simian varicella virus (SVV), offers an approach to evaluate recombinant varicella vaccine candidates. Recombinant SVV (rSVV) vaccine viruses expressing simian immunodeficiency virus (SIV) env and gag antigens were constructed. The hypothesis tested was that a live, attenuated rSVV-SIV vaccine will induce immune responses against SIV in the rhesus macaques and provide protection against SIV challenge. The results demonstrated that rSVV-SIV vaccination induced low levels of neutralizing antibodies and cellular immune responses to SIV in immunized rhesus macaques and significantly reduced viral loads following intravenous challenge with pathogenic SIVmac251-CX-1.

Recombinant simian varicella viruses expressing respiratory syncytial virus antigens are immunogenic

Recombinant simian varicella viruses (rSVVs) were engineered to express respiratory syncytial virus (RSV) antigens. The RSV surface glycoprotein G and second matrix protein M2 (22k) genes were cloned into the SVV genome, and recombinant viruses were characterized in vitro and in vivo. rSVVs were also engineered to express the membrane-anchored or secreted forms of the RSV-G protein as well as an RSV G lacking its chemokine mimicry motif (CX3C), which may have different effects on priming the host immune response. The RSV genes were efficiently expressed in rSVV/RSV-infected Vero cells as RSV-G and -M2 transcripts were detected by RT-PCR, and RSV antigens were detected by immunofluorescence and immunoblot assays. The rSVVs replicated efficiently in Vero cell culture. Rhesus macaques immunized with rSVV/RSV-G and rSVV/RSV-M2 vaccines produced antibody responses to SVV and RSV antigens. The results demonstrate that recombinant varicella viruses are suitable vectors for the expression of RSV antigens and may represent a novel vaccine strategy for immunization against both pathogens.

Recombinant simian varicella viruses induce immune responses to simian immunodeficiency virus (SIV) antigens in immunized vervet monkeys

The varicella-zoster virus (VZV) Oka vaccine offers potential as a recombinant vaccine against other pathogens. In this study, recombinant simian varicella viruses (rSVV) expressing simian immunodeficiency virus (SIV) envelope (env, gp130) and gag antigens were constructed. Expression of the SIV env and gag transcripts and antigens in rSVV-infected Vero cells was confirmed. The rSVV-SIVenv and rSVV-SIVgag viruses replicated as efficiently as wild-type SVV in cell culture. The immunogenicity of rSVV-SIVenv and rSVV-SIVgag was investigated in immunized vervet monkeys. Humoral immune responses to the SIV gp130 and gag antigens were detected as early as 4 weeks after the initial immunization with higher antibody titers following a booster immunization. Cellular immune responses against the SIV gp130 antigen were detected by ELISPOT assay. The rSVV established latent infection in neural ganglia. A subsequent study will evaluate the ability of rSVV vaccines expressing SIV antigens to protect nonhuman primates against simian AIDS.

A cosmid-based system for inserting mutations and foreign genes into the simian varicella virus genome

Simian varicella is a natural varicella-like disease of nonhuman primates. The etiologic agent, simian varicella virus (SVV), is genetically related to varicella-zoster virus (VZV) and SVV infection of nonhuman primates is a useful model to investigate VZV pathogenesis and latency. In this study, we report development of a cosmid-based genetic system to generate SVV mutant viruses. SVV subgenomic DNA fragments (32-38kb) that span the viral genome were cloned into cosmid vectors. Co-transfection of Vero cells with four overlapping cosmid clones representing the entire SVV genome resulted in recombination and generation of infectious virus. SVV mutants were produced by manipulation of one cosmid and substitution into the genetic system. This genetic approach was used to insert a site-specific mutation within the SVV open reading frame 14 which encodes the nonessential glycoprotein C gene. In a subsequent experiment, the green fluorescent protein (GFP) gene was inserted into the SVV genome within ORF 14. These SVV mutants replicate as efficiently as wild-type SVV in cell culture. This cosmid-based genetic system will be useful to investigate the effect of viral mutations on SVV pathogenesis and latency and also to develop and evaluate recombinant varicella vaccines that express foreign antigens.

Simian varicella: a model for human varicella-zoster virus infections

Simian varicella virus (SVV) causes a natural varicella-like disease in nonhuman primates. Epizootics of simian varicella occur sporadically in facilities housing Old World monkeys. SVV is antigenically and genetically related to varicella-zoster virus (VZV), the etiologic agent of varicella (chickenpox) and herpes zoster (shingles) in humans. The SVV and VZV genomes are similar in size and structure, share 70%-75% DNA homology and are co-linear with respect to gene organisation. Simian varicella is a highly contagious disease characterised by fever and vesicular skin rash and may progress to pneumonia and hepatitis. Infected monkeys may resolve the disease within 2 weeks although epizootics are sometimes associated with high morbidity and mortality. SVV, like VZV, establishes life-long latent infection, as indicated by detection of viral DNA within neural ganglia. Subsequently, SVV may reactivate to cause secondary disease and spread of the virus to susceptible monkeys. The relatedness of VZV and SVV and the similarities in the clinical symptoms and pathogenesis of human and simian varicella make SVV infection of nonhuman primates an excellent animal model to investigate VZV pathogenesis and latency, and to evaluate potential antiviral strategies.

Immunogenicity of a recombinant varicella-zoster virus gE-IE63 fusion protein, a putative vaccine candidate against primary infection and zoster reactivation

The varicella-zoster virus (VZV) envelope glycoprotein E (gE) and immediate early protein 63 (IE63) are well known targets for specific humoral and cell-mediated immune responses during VZV infection and latency, respectively. The present study evaluated the immunogenicity of an engineered chimeric recombinant gE-IE63 (recgE-IE63) protein secreted from CHO cells, wherein a soluble form of gE, deleted of its anchor and cytoplasmic domains was fused to IE63. Guinea pig vaccinations with adjuvanted recgE-IE63 elicited a strong and specific humoral immune response directed to each counterpart. Sera from recgE-IE63-immunized animals neutralized cell-free VZV. This neutralizing capacity was dependent only on the recgE moiety as serum depletions on recgE-immobilized sepharose totally abolished VZV neutralization. The cell-mediated immune response induced by recgE-IE63 was evaluated in lymphoproliferation assays. An antigen-specific proliferative response was demonstrated after lymphocyte stimulation with recIE63 but not with recgE. We conclude that recombinant chimeric recgE-IE63 induced both humoral and cell-mediated immune responses and thus could constitute a putative subunit vaccine candidate against VZV primary infection and zoster reactivation.