An enzyme-linked immunosorbent assay (ELISA) to determine Simian Varicella Virus antibody titers in infected rhesus monkeys (Macaca mulatta).

BACKGROUND: Simian varicella virus (SVV) is a primate herpesvirus that causes a natural varicella-like disease in Old World monkeys and may cause epizootics in facilities housing nonhuman primates. SVV infection of nonhuman primates is used as an experimental model to investigate varicella pathogenesis and to develop antiviral strategies. METHODS: An indirect enzyme-linked immunosorbent assay (ELISA) was developed to detect SVV antibodies in infected rhesus macaque monkeys. RESULTS: An ELISA determined SVV antibody titers following experimental infection. SVV IgG was detected by day 14 post-infection and remained elevated for at least 84 days. CONCLUSIONS: The SVV ELISA is a safe and rapid approach to confirm SVV seropositivity and to determine SVV antibody titers in naturally and experimentally SVV-infected monkeys. In addition to being a useful diagnostic assay to rapidly confirm acute disease or past SVV infection, the SVV ELISA is a valuable epidemiological tool to determine the incidence of SVV in non-human primate facilities.

Insertion of foreign genes into the simian varicella virus genome by Tn7-mediated site-specific transposition.

A Tn7-transposition approach was utilized for site-specific insertion of foreign genes into the genome of simian varicella virus (SVV), the causative agent of simian varicella in nonhuman primates. The severe acute respiratory syndrome coronavirus (SARS-CoV-2) nucleocapsid (N) gene and receptor binding domain (RBD) of the spike gene were inserted into the ORF 14 region of the SVV genome cloned into a bacterial artificial chromosome and then transfected into Vero cells to generate the infectious recombinant SVV (rSVV). The rSVV replicated efficiently in infected Vero cells and expressed the N and RBD antigens as indicated by immunoblot and immunofluorescence assays. Tn7-mediated transposition provides a rapid and efficient method for constructing rSVVs which may be evaluated as live-attenuated 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 SIVMAC251/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 SIVMAC251/CX1 challenged macaques.

The simian varicella virus ORF A is expressed in infected cells but is non-essential for replication in cell culture.

The simian varicella virus (SVV) genome encodes ORF A, a truncated homolog of SVV ORF 4. The SVV ORF A was expressed as a 1.0-kb transcript in SVV-infected Vero cells. The ORF A promoter was active in infected Vero cells and was stimulated by the SVV immediate-early gene ORF 62 product (IE62), a viral transactivator of SVV genes. The SVV ORF A did not transactivate SVV IE, early, or late gene promoters in transfected Vero cells and was unable to augment IE62-mediated transactivation of SVV promoters. A SVV mutant lacking ORF A replicated as efficiently as wild-type SVV in infected Vero cells, indicating that ORF A expression is not essential for in vitro replication.

Comparative Analysis of the Simian Varicella Virus and Varicella Zoster Virus Genomes.

Varicella zoster virus (VZV) and simian varicella virus (SVV) cause varicella (chickenpox) in children and nonhuman primates, respectively. After resolution of acute disease, the viruses establish latent infection in neural ganglia, after which they may reactivate to cause a secondary disease, such as herpes zoster. SVV infection of nonhuman primates provides a model to investigate VZV pathogenesis and antiviral strategies. The VZV and SVV genomes are similar in size and structure and share 70-75% DNA homology. SVV and VZV DNAs are co-linear in gene arrangement with the exception of the left end of the viral genomes. Viral gene expression is regulated into immediate early, early, and late transcription during in vitro and in vivo infection. During viral latency, VZV and SVV gene expression is limited to transcription of a viral latency-associated transcript (VLT). VZV and SVV are closely related alphaherpesviruses that likely arose from an ancestral varicella virus that evolved through cospeciation into species-specific viruses.

Simian varicella virus: molecular virology.

Simian varicella virus (SVV) is a primate herpesvirus that is closely related to varicella-zoster virus (VZV), the causative agent of varicella (chickenpox) and herpes zoster (shingles). Epizootics of simian varicella occur sporadically in facilities housing Old World monkeys. This review summarizes the molecular properties of SVV. The SVV and VZV genomes are similar in size, structure, and gene arrangement. The 124.5 kilobase pair (kbp) SVV genome includes a 104.7 kbp long component covalently linked to a short component, which includes a 4.9 kbp unique short segment flanked by 7.5 kbp inverted repeat sequences. SVV DNA encodes 69 distinct open reading frames, three of which are duplicated within the viral inverted repeats. The viral genome is coordinately expressed, and immediate early (IE), early, and late genes have been characterized. Genetic approaches have been developed to create SVV mutants, which will be used to study the role of SVV genes in viral pathogenesis, latency, and reactivation. In addition, SVV expressing foreign genes are being investigated as potential recombinant varicella vaccines.

Cloning the simian varicella virus genome in E. coli as an infectious bacterial artificial chromosome.

Simian varicella virus (SVV) is closely related to human varicella-zoster virus and causes varicella and zoster-like disease in nonhuman primates. In this study, a mini-F replicon was inserted into a SVV cosmid, and infectious SVV was generated by co-transfection of Vero cells with overlapping SVV cosmids. The entire SVV genome, cloned as a bacterial artificial chromosome (BAC), was stably propagated upon serial passage in E. coli. Transfection of pSVV-BAC DNA into Vero cells yielded infectious SVV (rSVV-BAC). The mini-F vector sequences flanked by loxP sites were removed by co-infection of Vero cells with rSVV-BAC and adenovirus expressing Cre-recombinase. Recombinant SVV generated using the SVV-BAC genetic system has similar molecular and in vitro replication properties as wild-type SVV. To demonstrate the utility of this approach, a SVV ORF 10 deletion mutant was created using two-step Red-mediated recombination. The results indicate that SVV ORF 10, which encodes a homolog of the HSV-1 virion VP-16 transactivator protein, is not essential for in vitro replication but is required for optimal replication in cell culture.

The simian varicella virus uracil DNA glycosylase and dUTPase genes are expressed in vivo, but are non-essential for replication in cell culture.

Neurotropic herpesviruses express viral deoxyuridine triphosphate nucleotidohydrolase (dUTPase) and uracil DNA glycosylase (UDG) enzymes which may reduce uracil misincorporation into viral DNA, particularly in neurons of infected ganglia. The simian varicella virus (SVV) dUTPase (ORF 8) and UDG (ORF 59) share 37.7% and 53.9% amino acid identity, respectively, with varicella-zoster virus (VZV) homologs. Infectious SVV mutants defective in either dUTPase (SVV-dUTPase(-)) or UDG (SVV-UDG(-)) activity or both (SVV-dUTPase(-)/UDG(-)) were constructed using recA assisted restriction endonuclease cleavage (RARE) and a cosmid recombination system. Loss of viral dUTPase and UDG enzymatic activity was confirmed in CV-1 cells infected with the SVV mutants. The SVV-dUTPase(-), SVV-UDG(-), and SVV-dUTPase(-)/UDG(-) mutants replicated as efficiently as wild-type SVV in cell culture. SVV dUTPase and UDG expression was detected in tissues derived from acutely infected animals, but not in tissues derived from latently infected animals. Further studies will evaluate the pathogenesis of SVV dUTPase and UDG mutants and their potential as varicella vaccines.

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.

Recombinant varicella-zoster virus vaccines as platforms for expression of foreign antigens.

Varicella-zoster virus (VZV) vaccines induce immunity against childhood chickenpox and against shingles in older adults. The safety, efficacy, and widespread use of VZV vaccines suggest that they may also be effective as recombinant vaccines against other infectious diseases that affect the young and the elderly. The generation of recombinant VZV vaccines and their evaluation in animal models are reviewed. The potential advantages and limitations of recombinant VZV vaccines are addressed.