Browsing by Author "Omar, Ruzaiq"

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    Open Access
    Comparison of the two lumpy skin disease virus vaccines, Neethling and Herbivac, and construction of a recombinant Herbivac-Rift Valley fever virus vaccine
    (2015) Omar, Ruzaiq; Williamson, Anna-Lise; Douglass, Nicola
    There are two broad aims to this project. The first aim is to compare and characterise two lumpy skin disease virus (LSDV) vaccines namely the vaccine based on attenuated Neethling LSDV (nLSDV) and Herbivac®LS (Herbivac). The second aim is to construct a recombinant LSDV expressing Rift Valley fever virus (RVFV) genes. An LSDV vaccine is critical for sustainable control of lumpy skin disease (LSD). There are four commercially available live attenuated vaccines for LSDV, nLSDV, Herbivac, Lumpyvax and the Kenyan strain sheeppox virus (KS-1). In this study Herbivac was characterised by comparing it to its parent, nLSDV. Growth curves of the two viral strains were conducted in cell culture as well as in embryonated hens’ eggs. No notable difference in the growth rate of the two strains could be detected when the viruses were grown in cell culture, however a notable difference was detected when the viruses were grown on the chick allantoic membranes (CAMs) of embryonated hens’ eggs. When grown on CAMs a faster growth rate was observed for nLSDV compared to Herbivac. nLSDV also killed the embryos at 4 d.p.i where Herbivac did not. The two strains were then further characterised through histological analysis of CAMs after infection with each of the viruses. Overall, higher levels of hyperplasia and hypertrophy were observed in CAMs infected with either nLSDV or Herbivac compared to uninfected CAMs. Herbivac-infected CAMs resulted in thicker chorionic membranes and larger pocks compared to nLSDV. RVFV and LSDV both contribute to the disease burden among cattle in Africa and the Arabian Peninsula. The main aim of this study was to construct a recombinant Herbivac which expresses immunogenic proteins of Rift Valley fever virus (Herbivac-RVFV). Herbivac-RVFV was designed to express specific RVFV genes selected for their antigenic properties. The genes selected are also representative of the genes from recent viral outbreaks in the horn of Africa. The selection of outbreak relevant RVFV genes involved phylogenetic analysis of all full length M-segment and NC gene sequences available on Genbank. Phylogenetic trees were constructed for M-segments and NC genes and groups identified which were highly representative of sequences from recent outbreaks of the virus. Consensus sequences were derived from these groups and included in the transfer vector. The phylogenetic analysis also revealed that the sequences of current RVFV vaccines are phylogenetically distant from viruses isolated from current outbreaks, although high levels of sequence conservation was maintained across all viral strains. This is the first study in which the RVFV genes coding for proteins that will induce a protective immune response (Gn and Gc, as well as the nucleocapsid (NC) gene) were selected so as to be representative of current outbreak strains of the virus. These genes were inserted between LSDV ORFs 49 and 50, a novel insertion site. The transfer vector also contained an eGFP marker gene and an ECO-GPT selection gene, located outside of the LSDV flanking sequences. This meant a two-step isolation procedure, first to isolate the recombinant containing the entire transfer vector with eGFP and ECO-GPT, and then to isolate a recombinant with only the RVFV genes and not eGFP and ECO-GPT. Transient expression of RVFV proteins in cells infected with Herbivac and then transfected with the transfer vector was confirmed via western blotting and immunofluorescence. Here the proteins Gn, Gc and NC were shown to be expressed. In the present study, a single crossover Herbivac-RVFV recombinant was isolated through multiple passaging of cell lysates, originally obtained from Herbivac-infected FBT cells transfected with the transfer vector, in the presence of mycophenolic-acid selection medium.
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    The Development of Dual Vaccines against Lumpy Skin Disease (LSD) and Bovine Ephemeral Fever (BEF)
    (2021-10-20) Douglass, Nicola; Omar, Ruzaiq; Munyanduki, Henry; Suzuki, Akiko; de Moor, Warren; Mutowembwa, Paidamwoyo; Pretorius, Alri; Nefefe, Tshifhiwa; Schalkwyk, Antoinette van; Kara, Pravesh; Heath, Livio; Williamson, Anna-Lise
    Dual vaccines (n = 6) against both lumpy skin disease (LSD) and bovine ephemeral fever (BEF) were constructed, based on the BEFV glycoprotein (G) gene, with or without the BEFV matrix (M) protein gene, inserted into one of two different LSDV backbones, nLSDV∆SOD-UCT or nLSDVSODis-UCT. The inserted gene cassettes were confirmed by PCR; and BEFV protein was shown to be expressed by immunofluorescence. The candidate dual vaccines were initially tested in a rabbit model; neutralization assays using the South African BEFV vaccine (B-Phemeral) strain showed an African consensus G protein gene (Gb) to give superior neutralization compared to the Australian (Ga) gene. The two LSDV backbones expressing both Gb and M BEFV genes were tested in cattle and shown to elicit neutralizing responses to LSDV as well as BEFV after two inoculations 4 weeks apart. The vaccines were safe in cattle and all vaccinated animals were protected against virulent LSDV challenge, unlike a group of control naïve animals, which developed clinical LSD. Both neutralizing and T cell responses to LSDV were stimulated upon challenge. After two inoculations, all vaccinated animals produced BEFV neutralizing antibodies ≥ 1/20, which is considered protective for BEF.
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    Influence of the Viral Superoxide Dismutase (SOD) Homologue on Lumpy Skin Disease Virus (LSDV) Growth, Histopathology and Pathogenicity
    (2020-11-07) Douglass, Nicola; Munyanduki, Henry; Omar, Ruzaiq; Gers, Sophette; Mutowembwa, Paidamwoyo; Heath, Livio; Williamson, Anna-Lise
    Lumpy skin disease is an important economic disease of cattle that is controlled by vaccination. This paper presents an investigation into the role of the lumpy skin disease virus (LSDV) superoxide dismutase (SOD) homologue on growth and histopathology of the virus both in vitro and in vivo. SOD homologue knock-out and knock-in recombinants (nLSDV∆SOD-UCT and nLSDVSODis-UCT, respectively) were constructed and compared to the Neethling vaccine (nLSDV) for growth in a permissive bovine cell line as well as on fertilized chick chorioallantoic membranes (CAMs). The infected CAMs were scored for histological changes. Deletion of the SOD homologue from LSDV reduced virus growth both in Madin-Darby bovine kidney (MDBK) cells as well as on CAMs. Furthermore, the knockout virus showed reduced inflammation in CAMs and more ballooning degeneration. A pilot experiment was performed in cattle to compare the lesions produced by the different LSDV constructs in the same animal. One animal developed a larger lesion to nLSDV∆SOD-UCT compared to both nLSDVSODis-UCT and nLSDV. Histological analysis of biopsies of these lesions shows less inflammation and necrosis associated with nLSDVSODis-UCT compared to nLSDV and nLSDV∆SOD-UCT. None of the vaccinated animals showed disseminated LSDV disease, indicating that the candidate vaccines are safe for further testing. Our results suggest that the SOD homologue may improve immunogenicity and reduce virulence.