The availability of genome sequencing data in combination with knowledge of expressed genes via transcriptome and proteome data has greatly advanced our understanding of arthropod vectors of disease. Not only have we gained insight into vector biology, but also into their respective vector-pathogen interactions. By combining the strengths of postgenomic databases and reverse genetic approaches such as RNAi, the numbers of available drug and vaccine targets, as well as number of transgenes for subsequent transgenic or paratransgenic approaches, have expanded. These are now paving the way for in-field control strategies of vectors and their pathogens. Basic scientific questions, such as understanding the basic components of the vector RNAi machinery, is vital, as this allows for the transfer of basic RNAi machinery components into RNAi-deficient vectors, thereby expanding the genetic toolbox of these RNAi-deficient vectors and pathogens. In this review, we focus on the current knowledge of arthropod vector RNAi machinery and the impact of RNAi on understanding vector biology and vector-pathogen interactions for which vector genomic data is available on VectorBase.
The smallest RNA genome segment of African horsesickness virus (AHSV) encodes the nonstructural protein NS3 (24K). NS3 localizes in areas of plasma membrane disruption and is associated with events of viral release. Conserved features in all AHSV NS3 proteins include the synthesis of a truncated NS3A protein from the same open reading frame as that of NS3, a proline-rich region, a region of strict sequence conservation and two hydrophobic domains. To investigate whether these features are associated with the cytotoxicity of NS3 or altered membrane permeability, a series of mutants were constructed and expressed in the BAC-TO-BAC baculovirus-expression system. Our results indicate that mutations in either of the two hydrophobic domains do not prevent membrane targeting of the mutant proteins but abolish their membrane anchoring. This prevents their localization to the cell surface and obviates their cytotoxic effect. The cytotoxicity of NS3 is therefore dependent on its membrane topography and thus involves both hydrophobic domains. NS3 has many of the characteristics of lytic viral proteins that play a central role in viral pathogenesis through modifying membrane permeability.
Identification and characterisation of an early/late bi-directional promoter element of lumpy skin disease virus (LSDV) is described. The 56 bp element shows substantial structural similarities with other poxvirus promoters, providing further evidence that transcriptional elements are conserved within the Poxviridae. The relative strengths of the LSDV early and late promoters were compared to the vaccinia virus (VV) P7.5K and P11K promoters in transient expression assays. These transient assays also verified the temporally regulated nature of the promoter. Favourable expression levels suggest that the identified LSDV promoters could be used for expressing foreign genes in a recombinant LSDV system.
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