SummaryThe RNAi pathway confers antiviral immunity in insects. Virus-specific siRNA responses are amplified via the reverse transcription of viral RNA to viral DNA (vDNA). The nature, biogenesis, and regulation of vDNA are unclear. We find that vDNA produced during RNA virus infection of Drosophila and mosquitoes is present in both linear and circular forms. Circular vDNA (cvDNA) is sufficient to produce siRNAs that confer partially protective immunity when challenged with a cognate virus. cvDNAs bear homology to defective viral genomes (DVGs), and DVGs serve as templates for vDNA and cvDNA synthesis. Accordingly, DVGs promote the amplification of vDNA-mediated antiviral RNAi responses in infected Drosophila. Furthermore, vDNA synthesis is regulated by the DExD/H helicase domain of Dicer-2 in a mechanism distinct from its role in siRNA generation. We suggest that, analogous to mammalian RIG-I-like receptors, Dicer-2 functions like a pattern recognition receptor for DVGs to modulate antiviral immunity in insects.
Bovine leukemia virus (BLV) is an oncogenic deltaretrovirus that infects cattle worldwide. In Uruguay, it is estimated that more than 70% of dairy cattle are infected, causing serious economic losses due to decreased milk production, increased calving interval, and livestock losses due to lymphosarcoma. Several attempts to develop vaccine candidates that activate protective immune responses against BLV were performed, but up to date, there is no vaccine that ensures efficient protection and/or decreased viral transmission. The development and application of new vaccines that effectively control BLV infection represent a major challenge for countries with a high prevalence of infection. In this study, we generated two Drosophila melanogaster S2 stable cell lines capable of producing BLV virus-like particles (BLV-VLPs). One of them, BLV-VLP1, expressed both Gag and Env wild-type (Envwt) full-length proteins, whereas BLV-VLP2 contain Gag together with a mutant form of Env non-susceptible to proteolytic maturation by cellular furin type enzymes (EnvFm). We showed that Envwt is properly cleaved by cellular furin, whereas EnvFm is produced as a full-length gp72 precursor, which undergoes some partial cleavage. We observed that said mutation does not drastically affect its expression or its entry into the secretory pathway of S2 insect cells. In addition, it is expressed on the membrane and retains significant structural motifs when expressed in S2 insect cells. Morphology and size of purified BLV-VLPs were analyzed by transmission electron microscopy and dynamic light scattering, showing numerous non-aggregated and approximately spherical particles of variable diameter (70–200 nm) as previously reported for retroviral VLPs produced using different expression systems. Furthermore, we identified two N-glycosylation patterns rich in mannose in EnvFm protein displayed on VLP2. Our results suggest that the VLPs produced in Drosophila S2 cells could be a potential immunogen to be used in the development of BLV vaccines that might contribute, in conjunction with other control strategies, to reduce the transmission of the virus.
The siRNA pathway is the primary antiviral defense mechanism in invertebrates and plants. The systemic nature of this defense mechanism is one of its more fascinating characteristics and the recognition and transport of double-stranded RNA (dsRNA) of viral origin is required for the systemic activity of the siRNA pathway. Indeed, cellular internalization of dsRNA from the environment is a widespread phenomenon among insects. Here we aimed to identify cell surface proteins that bind to extracellular dsRNA and mediate its internalization. To this end, we developed a novel co-immunoprecipitation protocol that we followed with proteomics analysis. Among the hits from our screens was Hsc70-4, a constitutively expressed member of the heat shock protein family that has been implicated in clathrin-mediated endocytosis. We found that silencing Hsc70-4 impaired dsRNA internalization. Surprisingly, despite lacking a predicted transmembrane domain, Hsc70-4 localizes to the cell membrane and this localization was preserved when Hsc70-4 was expressed in mammalian cells, suggesting a conserved role at the cell surface. Furthermore, Hsc70-4 shows a previously undescribed dsRNA-specific binding capacity. Our results show that Hsc70-4 is a key element of the dsRNA internalization process and its detailed study may facilitate the development of RNA interference (RNAi)-based technologies for pest and vector borne disease control.
The Drosophila immune system distinguishes live -and potentially harmful bacteria -from harmless dead bacteria using a novel splice variant of the receptor PGRP-LC.Distinguishing self from non-self is critical for mounting an appropriate immune response. This historical concept by Janeway 1 was the framework for immune discrimination between host and microorganism. However, it was insufficient to explain the finely-tuned discrimination between harmful vs. non-harmful microorganisms or between infection and colonization.Similarly, it could not explain how the immune system could discriminate between living and dead microorganisms. The fact that the same microbial-associated molecular patterns (MAMPs) are shared among microorganisms regardless of pathogenicity or viability is still an unsolved quandary in innate immunity. In this issue of Nature Immunology a paper by Neyen et al. 2 suggests a resolution of this quandary.The innate immune response is a tightly regulated process that consists of different phases. Firstly, there's recognition of ligands e.g. MAMPs. This is followed by activation of genes involved in host defense (antimicrobial peptides, inflammatory cytokines, chemokines). Finally the response ends with the resolution phase. One of the principles that governs the immune response in all organisms is that once the threat has passed, the immune system must downregulate activation (resolution) to avoid over reaction that can lead to the death of the host 3 . In insects, the Immune Deficiency pathway (IMD) has a principal role in responses toGram negative (Gram -) bacterial infection by activating NF-kB-like genes controlling the expression of antimicrobial peptides among others 4, 5 . In contrast to vertebrates, Drosophila's sensing of Grambacteria does not rely on recognition of lipopolysaccharide (LPS) but rather in the
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