Attenuation of equine herpesvirus 1 through deletion of gE gene and its pathological evaluation in murine model.

Equine herpesvirus 1 (EHV1) infection is a global health problem in equines and the virus is responsible for abortions, respiratory disease and myeloencephalitis in horses. Disease management requires proper biosecurity and immunoprophylactic measures. Vaccines strengthening both arms of immunity are essential for proper control and there has been a continuous focus in this area for generation of better vaccines. Here we report construction of bacterial artificial chromosome (BAC) clone of EHV-1 strain Tohana for mutagenesis of the virus and generation of gE gene deletion mutant EHV1. The BAC clone was generated by inserting the mini-F plasmid replacing ORF71 of EHV1 and transforming into E. coli for generation of EHV1-BAC. The infectious virus was regenerated from EHV-1 BAC DNA in RK13 cells. To check utility of EHV1-BAC, we have generated mutant EHV1 by deleting the virulence-associated gE gene. The mutant virus (vToHΔgE) showed significantly reduced plaque size without affecting replication efficiency. Pathological evaluation of lesions in BALB/c mice infected with vToHΔgE revealed reduction in clinical signs and pathology in comparison to the wild-type virus. Generation of infectious BAC of EHV1 and its usage in construction of attenuated viruses shows potential of the technology for development of indigenous modified live vaccine for EHV1. Keywords: quine herpesvirus 1; bacterial artificial chromosome (BAC); mutation; glycoprotein E; vaccine.

Double and quadruple deletion mutant of EHV-1 is highly attenuated and induces optimal immune response.

Equid alphaherpesvirus 1 (EHV-1) infection causes significant health problems in equines. The EHV-1 infection leads to abortion storm in mares, respiratory disease and myeloencephalopathy. Despite the wide use of vaccines, the outbreaks of EHV-1 infections keep occurring globally, suggesting the need for the development of improved vaccines. Gene deletion attenuated mutant viruses could be a good candidate for the development of modified live vaccines. Here, we report the generation of mutant EHV-1 by deleting virulence (glycoprotein E & internal repeat 6; IR6) and immune evasive (pUL43 & pUL56) associated genes either individually or in combinations; and comprehensive evaluation of mutants through in vitro characterization followed by in vivo study in murine model to adjudge the attenuation of the virus and immune responses generated by mutants vis-à-vis wild type (wt) virus. The EHV-1 mutants with deletion of IR6 and gE genes (vToH-DMV) and four genes (i.e., gE, IR6, pUL43 and pUL56) (vToH-QMV) revealed a significant reduction in plaque size with minimal loss in replication efficiency in comparison to the wt virus. Further, in vivo studies showed virus attenuation adjudged through significant reduction in clinical signs, weight loss, gross and histopathological lesions in comparison to wt virus also revealed improved immune responses estimated through serum neutralization and flow cytometric analysis of CD4 + and CD8 + cell populations. Thus it can be concluded that EHV-1 mutants viz. vToH-DMV and vToH-QMV (novel combination) are promising vaccine candidates and qualify to be studied for adjudging the protective efficacy with wt virus challenge.

Protective efficacy of inactivated reverse genetics based equine influenza vaccine candidate adjuvanted with MontanideTM Pet Gel in murine model.

Equine influenza is a leading cause for respiratory illness in equines. Major control measures involve vaccination which requires continuous harmonization owing to antigenic drift. The present study focused on assessing the protective efficacy of an inactivated recombinant equine influenza virus (rgEIV) vaccine candidate adjuvanted with MontanideTM Pet Gel in murine model. The rgEIV was generated using reverse genetics by incorporating HA and NA segments from EIV/H3N8, clade 2-Florida sublineage in an A/WSN/33 /H1N1 backbone and inactivated by formalin. The vaccine was prepared by mixing inactivated rgEIV with MontanideTM Pet Gel adjuvant followed by intranasal inoculation into BALB/c mice intranasally. The immune responses and protective efficacy of the vaccine was evaluated by measurement of antibody titer, immunoglobulin subtyping, cytokines, clinical signs and pathological lesions after immunization and challenge with wild EIV. Serology and cytokine expression pattern indicated that the vaccine activated mixed Th1- and Th2-like responses of vaccine. Booster immunization stimulated strong antibody responses (HAI titre: 192 ± 28.6) at 42 days post immunization and the predominant antibody subtype was IgG1. Upregulation of interferon (IFN)-gamma, interleukin (IL)-12 and IL-2 levels indicates effective induction of Th1 type response. We found that vaccination has protected mice against equine influenza virus challenge as adjudged through a lack of nonappearance of visible clinical signs of disease, no loss of body weight loss, reduced pathology in the lungs and markedly reduced virus shedding from the respiratory tract. Therefore, we conclude that recombinant EIV vaccine candidate adjuvanted with MontanideTM Pet Gel could aid in quick harmonization of the vaccines through replacement of HA and NA genes for control of EIV outbreaks.