Abstract
ABSTRACTBluetongue is one of the major infectious diseases of ruminants and is caused by bluetongue virus (BTV), an arbovirus existing in nature in at least 26 distinct serotypes. Here, we describe the development of a vaccine platform for BTV. The advent of synthetic biology approaches and the development of reverse genetics systems has allowed the rapid and reliable design and production of pathogen genomes which can be subsequently manipulated for vaccine production. We describe BTV vaccines based on “synthetic” viruses in which the outer core proteins of different BTV serotypes are incorporated into a common tissue-culture-adapted backbone. As a means of validation for this approach, we selected two BTV-8 synthetic reassortants and demonstrated their ability to protect sheep against virulent BTV-8 challenge. In addition to further highlight the possibilities of genome manipulation for vaccine production, we also designed and rescued a synthetic BTV chimera containing a VP2 protein, including regions derived from both BTV-1 and BTV-8. Interestingly, while the parental viruses were neutralized only by homologous antisera, the chimeric proteins could be neutralized by both BTV-1 and BTV-8 antisera. These data suggest that neutralizing epitopes are present in different areas of the BTV VP2 and likely “bivalent” strains eliciting neutralizing antibodies for multiple strains can be obtained.IMPORTANCE Overall, this vaccine platform can significantly reduce the time taken from the identification of new BTV strains to the development and production of new vaccines, since the viral genomes of these viruses can be entirely synthesized in vitro. In addition, these vaccines can be brought quickly into the market because they alter the approach, but not the final product, of existing commercial products.
Highlights
Overall, this vaccine platform can significantly reduce the time taken from the identification of new bluetongue virus (BTV) strains to the development and production of new vaccines, since the viral genomes of these viruses can be entirely synthesized in vitro
We obtained DNA plasmids containing commercially synthesized genomic segments encoding VP2 and VP5 of the reference strains of BTV-1 to -26
Cells were transfected using homologous Seg-2 and Seg-6 from each serotype, in addition to plasmids containing genomic segments forming the “backbone” of the synthetic viruses (Seg-1, -3, -4, -5, -7, -8, -9, and -10) encoding the remaining structural, enzymatic, and nonstructural proteins from BTV-1. This strategy was successful for the rescue of 16 different BTV serotypes, resulting in the generation of the following synthetic BTV viruses: B1BTV-1VP2/VP5, B1BTV-2VP2/VP5, B1BTV-3VP2/VP5, B1BTV-4VP2/VP5, B1BTV-6VP2/VP5, B1BTV-8VP2/VP5, B1BTV-9VP2/VP5, B1BTV-11VP2/VP5, B1BTV-13VP2/VP5, B1BTV17VP2/VP5, B1BTV-20VP2/VP5, B1BTV-21VP2/VP5, B1BTV-22VP2/VP5, B1BTV-23VP2/VP5, B1BTV-25VP2/VP5, and B1BTV-26VP2/VP5
Summary
This vaccine platform can significantly reduce the time taken from the identification of new BTV strains to the development and production of new vaccines, since the viral genomes of these viruses can be entirely synthesized in vitro. These vaccines can be brought quickly into the market because they alter the approach, but not the final product, of existing commercial products. Serotypes are determined primarily by differences in the outer capsid protein VP2, which mediates viral entry into the cell and is the target for neutralizing antibodies in infected animals [8,9,10,11,12,13]. Since 1998, outbreaks caused by various BTV serotypes have been increasingly observed in Northern Africa and Europe [21,22,23]
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