Infection of equine monocyte-derived macrophages with an attenuated equine infectious anemia virus (EIAV) strain induces a strong resistance to the infection by a virulent EIAV strain.

The Chinese attenuated equine infectious anemia virus (EIAV) vaccine has successfully protected millions of equine animals from EIA disease in China. Given that the induction of immune protection results from the interactions between viruses and hosts, a better understanding of the characteristics of vaccine strain infection and host responses would be useful for elucidating the mechanism of the induction of immune protection by the Chinese attenuated EIAV strain. In this study, we demonstrate in equine monocyte-derived macrophages (eMDM) that EIAVFDDV13, a Chinese attenuated EIAV strain, induced a strong resistance to subsequent infection by a pathogenic strain, EIAVUK3. Further experiments indicate that the expression of the soluble EIAV receptor sELR1, Toll-like receptor 3 (TLR3) and interferon ß (IFNß) was up-regulated in eMDM infected with EIAVFDDV13 compared with eMDM infected with EIAVUK3. Stimulating eMDM with poly I:C resulted in similar resistance to EIAV infection as induced by EIAVFDDV13 and was correlated with enhanced TLR3, sELR1 and IFNß expression. The knock down of TLR3 mRNA significantly impaired poly I:C-stimulated resistance to EIAV, greatly reducing the expression of sELR1 and IFNß and lowered the level of infection resistance induced by EIAVFDDV13. These results indicate that the induction of restraining infection by EIAVFDDV13 in macrophages is partially mediated through the up-regulated expression of the soluble viral receptor and IFNß, and that the TLR3 pathway activation plays an important role in the development of an EIAV-resistant intracellular environment.

An attenuated EIAV strain and its molecular clone strain differentially induce the expression of Toll-like receptors and type-I interferons in equine monocyte-derived macrophages.

Activations of endosomal TLRs include TLR3, TLR7/8, and TLR9 stimulates the production of cytokines, such as type I interferons (IFNs), and therefore involves in virus-host interactions. In the present study, two equine anemia virus (EIAV) strains EIAVFDDV13 and EIAVFDDV3-8, which showed different induction on protective immunity, were compared regarding their ability to regulate the expression of endosomal TLRs, as well as type I IFNs, after infection of equine monocyte-derived macrophages (eMDMs). Our results showed that EIAVFDDV13 dramatically up-regulated the expression of TLR3 and IFNß and less robustly up-regulated the expression of TRL9 and IFNα1, whereas EIAVFDDV3-8 induced significantly lower expression of type I IFN mRNA and protein and more strongly down-regulated the expression of TLR7 and TLR8. In addition, no significant differences in cell apoptosis were observed between these two strains. Given that the genomic variation of EIAVFDDV13 is considerably higher than that of molecular clone EIAVFDDV3-8, our results suggest that stronger TLR3 activation and increased INFß production induced by the multi-species strain are associated with an effective vaccine-elicited protective immune response.

[The application of single-genome amplification and sequencing in genomic analysis of an attenuated EIAV vaccine].

Our previous studies found that the Chinese attenuated EIAV vaccine was composed of a pool of quasispecies, which showed a complicated diversity called "multi-species". Further determining the viral composition of these species in the vaccine should improve the identification of predominant viruses in the vaccine and facilitate the analysis of in vivo evolution of EIAV and the vaccine. In this study, the comparison of fidelities in amplifying and sequencing the V3 to V5 fragment of EIAV envelope gp90 gene by either a single-genome amplification (SGA) approach or the traditional RT-PCR (bulk PCR) was performed. Results revealed that the diversities were 1.84% and 1.88% for SGA- and bulk PCR-derived sequences, respectively. Futher analysis revealed that beside the sequences highly homologous to those derived by the bulk PCR, nine of 73 sequences derived by SGA contained a deduced amino acid domain that was identical to the corresponding domain in the virulent strain LN40. In addition, sequences with deletion of one predicted amino acid residual was detected by using SGA The presence of these less populated sequences provided additional evidence for the "multi-species" hypothesis for the action mechanism of the EIAV vaccine. Furthermore, based on the analysis of sampling bias, Our results that the difference in copy number of each viral specie in the pool of quasispecies resulted in the inefficiency to amplify viral sequences that were in low population by bulk PCR. Therefore, the sequences amplified by bulk PCR could not correctly represent the composition of quasispecies. As an approach based on the amplification and sequencing single isolated genome, SGA significantly improved the weakness of bulk PCR and appeared its advantage in analysis of EIAV genome composition with high variety.