Ehrlichia ruminantium antigens and peptides induce cytotoxic T cell responses in vitro.

Since CD8+ T cells play an important role in resistance to infection with heartwater, effective vaccines against this disease will likely require identification of antigens that contain CD8+ T cell epitopes responsible for cytotoxic T lymphocyte (CTL) responses. With the use of the fluorescent antigen-transfected target cell (FATT)-CTL assay, IFN-γ ELISPOT and flow cytometry, peptides that induce CTL, proliferation of CD8 + T cells and IFN-γ production were identified as possible target antigens for vaccine development. Of particular relevance was the finding that different peptides from different antigens were able to elicit varied cytotoxic activities by immune peripheral blood mononuclear cells (PBMC) from heartwater immune tick-infected sheep. Several peptides derived from Erum0660, Erum2330, Erum2540, Erum2580 and Erum5000 induced CTL in immune sheep PBMC. Peptide Erum2540-6 was the only peptide that induced significant CTL, CD8+CD45RO+ and CD8+IFN-γ+ by PBMC from all three sheep, and Erum2540 and p2540-20 induced the highest % CTL response in all three outbred sheep. These results suggest that these epitopes may be of major importance in heartwater recombinant vaccine development.

African horse sickness virus serotype 4 antigens, VP1-1, VP2-2, VP4, VP7 and NS3, induce cytotoxic T cell responses in vitro.

It was shown in a previous study that proliferating CD8+ T cells could be detected in immune horse peripheral blood mononuclear cells (PBMC) when stimulated with African horse sickness virus serotype 4 (AHSV4). In this study the cytotoxicity of CD8+ T cells were tested by using the fluorescent antigen-transfected target cells-cytotoxic T lymphocytes (FATT-CTL) assay, for both the virus and its individual proteins expressed in Escherichia coli. This CTL assay measures the killing of viral protein expressing cells. AHSV proteins were successfully expressed in E. coli using the pET102/D-TOPO expression vector and the effector cells were stimulated with these recombinant proteins or with live viable virulent AHSV4. The AHSV genes were amplified and cloned into the pIRES-hrGFP II (pGFPempty) vector and these plasmid vectors encoding antigen-green fluorescent protein (GFP) fusion proteins were used to nucleofect PBMC, the target cells. The elimination of antigen-GFP expressing cells by CTL was quantified by flowcytometry. VP1-1, VP2-2, VP4, VP7 and NS3, antigen-specific CD8+ T cells resulted in cell lysis suggesting that CTL may play a role in the immune response induced against the AHSV4 vaccine strain.

Immune gene expression profiling of PBMC isolated from horses vaccinated with attenuated African horsesickness virus serotype 4.

Development of African horsesickness (AHS) subunit vaccines will have to include a rational approach that uses knowledge of how the virus interacts with the host immune system. The global in vivo immune response induced by attenuated AHSV serotype 4 in horses was characterised using transcriptome sequencing. PBMC were collected with 24h intervals for four days after inoculation and four days after a second boost, 21 days later. Transcriptome data were normalised to the day 0 naïve transcriptome and up- or down-regulated immune genes identified using the CLC workbench. Peak expression was observed 24h after each inoculation. Innate immunity was up-regulated after both inoculations and was characterised by type-1 interferon activation via the RIG-1/MDA5 pathway and the up-regulation of complement cascade components. After the second boost an adaptive immune response could be identified that included the production of cytokines indicative of T helper (Th)1, Th2 and Th17 responses.

Identification of Ehrlichia ruminantium proteins that activate cellular immune responses using a reverse vaccinology strategy.

Ehrlichia ruminantium is an obligate intracellular bacterial pathogen which causes heartwater, a serious tick-borne disease of ruminants throughout sub-Saharan Africa. The development of promising recombinant vaccines has been reported previously, but none has been as effective as immunisation with live organisms. In this study we have used reverse vaccinology to identify proteins that elicit an in vitro cellular immune response similar to that induced by intact E. ruminantium. The experimental strategy involved four successive steps: (i) in silico selection of the most likely vaccine candidate genes from the annotated genome; (ii) cloning and expression of the selected genes; (iii) in vitro screening of the expressed proteins for their ability to induce interferon-gamma (IFN-γ) production in E. ruminantium-immune lymphocytes; and (iv) further examination of the cytokine response profiles of those lymphocytes which tested positive for IFN-γ induction. Based on their overall cytokine induction profiles the recombinant proteins were divided into four distinct groups. Eleven recombinant proteins induced a cytokine profile that was similar to the recall immune response induced by immune peripheral blood mononuclear cells (PBMC) stimulated with intact E. ruminantium. This response comprised the upregulation of cytokines associated with adaptive cellular immune responses as well as innate immunity. A successful vaccine may therefore need to contain a combination of recombinant proteins which induce both immune pathways to ensure protection against heartwater.

A heterologous prime/boost immunisation strategy protects against virulent E. ruminantium Welgevonden needle challenge but not against tick challenge.

Heterologous prime/boost immunisation strategies using the Ehrlichia ruminantium 1H12 pCMViUBs_ORFs [Pretorius A, Collins NE, Steyn HC, Van Strijp F, Van Kleef M, Allsopp BA. Protection against heartwater by DNA immunisation with four Ehrlichia ruminantium open reading frames. Vaccine 2007;25(12):2316-24] were investigated in this study. All the animals immunised twice with a recombinant (r) DNA cocktail of four 1H12 pCMViUBs_ORFs followed by a r1H12 protein and those immunised 3x with 1H12 plasmid rDNA showed 100% protection against a virulent E. ruminantium Welgevonden needle challenge. In addition, 90% of the sheep immunised twice with rDNA and boosted with r1H12 lumpy skin disease virus (LSDV) survived. Only the lymphocytes isolated from the r1H12 protein boost group showed specific proliferation and increased interferon (IFN)-gamma expression. In contrast, only 20% protection was obtained in animals immunised with the rDNA prime/r1H12 protein boost when subjected to natural tick challenge in the field. Thus this heterologous prime/boost immunisation strategy had not conferred any significant protection against a field challenge.