Development of a cricket paralysis virus-based system for inducing RNA interference-mediated gene silencing in Diaphorina citri

Abstract

Diaphorina citri, the Asian citrus psyllid, is the insect vector of the phloem-limited bacterium ‘Candidatus Liberibacter asiaticus’, which causes the most devastating citrus disease worldwide: Huanglongbing (HLB). An efficient cure for HLB is still not available and the management of the disease is restricted to the use of pesticides, antibiotics and eradication of infected plants. Plant- and insect-infecting viruses have attracted increasing attention for their potential to manipulate traits in insects, especially insect vectors of plant pathogens. However, so far there are no insect virus-based vectors available for use in D. citri. Cricket paralysis virus (CrPV) is a well-studied insect-infecting dicistrovirus with a wide host range and has been used as a model in previous translational studies. In this work, we demonstrate for the first time that CrPV is infectious and pathogenic to D. citri. We show that specific amino acid mutations in the CrPV primary cleavage DvExNPGP motif resulted in a viral mutant that was attenuated compared to wild-type CrPV during infection of either Drosophila cells line or adult D. citri insects. This attenuated CrPV mutant was then used as the backbone for engineering a recombinant CrPV-based vector to specifically alter D. citri gene expression via the RNA interference (RNAi) pathway, a technology called Virus Induced Gene Silencing (VIGS). As proof-of-concept, we engineered recombinant CrPV-based vectors carrying nucleotide sequences derived from a previously reported D. citri target gene: the inhibitor of apoptosis gene (IA). RT-qPCR analysis of insects either microinjected or fed with the recombinant CrPV mutants showed decreased IA gene expression as soon as viral replication was detected, indicating that the engineered CrPV-based VIGS system enables functional gene silencing in D. citri. This novel insect virus-based tool is easily amenable to genomic modification and represents a technical advance for understanding interactions between insect virus-based VIGS systems and D. citri.