The Toll pathway is important for an antiviral response in Drosophila

206

228

Honey bee colony losses are triggered by interacting stress factors consistently associated with high loads of parasites and/or pathogens. A wealth of biotic and abiotic stressors are involved in the induction of this complex multifactorial syndrome, with the parasitic mite Varroa destructor and the associated deformed wing virus (DWV) apparently playing key roles. The mechanistic basis underpinning this association and the evolutionary implications remain largely obscure. Here we narrow this research gap by demonstrating that DWV, vectored by the Varroa mite, adversely affects humoral and cellular immune responses by interfering with NF-κB signaling. This immunosuppressive effect of the viral pathogen enhances reproduction of the parasitic mite. Our experimental data uncover an unrecognized mutualistic symbiosis between Varroa and DWV, which perpetuates a loop of reciprocal stimulation with escalating negative effects on honey bee immunity and health. These results largely account for the remarkable importance of this mite-virus interaction in the induction of honey bee colony losses. The discovery of this mutualistic association and the elucidation of the underlying regulatory mechanisms sets the stage for a more insightful analysis of how synergistic stress factors contribute to colony collapse, and for the development of new strategies to alleviate this problem.Apis mellifera | Varroa destructor | deformed wing virus | mutualistic symbiosis | honeybee colony losses

supporting

confidence: 74%

A mutualistic symbiosis between a parasitic mite and a pathogenic virus undermines honey bee immunity and health

Prisco

Annoscia

Margiotta

et al. 2016

206

228

“…aegypti in the presence of wMelPop (5,12), has been shown to play a role in the control of dengue dissemination in Ae. aegypti (13,14). A general role of immune up-regulation in pathogen inhibition is also supported by the knockdown of the major immune gene TEP1, which partially rescues the inhibitory effect of the presence of wMelPop on Plasmodium berghei development in transiently infected Anopheles gambiae (15).…”

mentioning

confidence: 76%

WolbachiastrainwMel induces cytoplasmic incompatibility and blocks dengue transmission inAedes albopictus

Blagrove

Arias-Goeta

Failloux

et al. 2011

286

260

Wolbachia inherited bacteria are able to invade insect populations using cytoplasmic incompatibility and provide new strategies for controlling mosquito-borne tropical diseases, such as dengue. The overreplicating wMelPop strain was recently shown to strongly inhibit the replication of dengue virus when introduced into Aedes aegypti mosquitoes, as well as to stimulate chronic immune upregulation. Here we show that stable introduction of the wMel strain of Drosophila melanogaster into Aedes albopictus, a vector of dengue and other arboviruses, abolished the transmission capacity of dengue virus-challenged mosquitoes. Immune up-regulation was observed in the transinfected line, but at a much lower level than that previously found for transinfected Ae. aegypti. Transient infection experiments suggest that this difference is related to Ae. albopictus immunotolerance of Wolbachia, rather than to the Wolbachia strain used. This study provides an example of strong pathogen inhibition in a naturally Wolbachia-infected mosquito species, demonstrating that this inhibition is not limited to naturally naïve species, and suggests that the Wolbachia strain is more important than host background for viral inhibition. Complete bidirectional cytoplasmic incompatibility was observed with WT strains infected with the naturally occurring Ae. albopictus Wolbachia, and this provides a mechanism for introducing wMel into natural populations of this species.

“…In their original host Drosophila, some strains of Wolbachia could induce resistance to various viruses such as Drosophila C virus, cricket paralysis virus, Nora virus, flock house virus, and West Nile virus (37)(38)(39). Drosophila synergistically uses several pathways to control viral infections (40)(41)(42). Recently, some strains of Wolbachia were successfully introduced into various mosquito species such as Ae.…”

Section: Discussionmentioning

confidence: 99%

Wolbachiauses a host microRNA to regulate transcripts of a methyltransferase, contributing to dengue virus inhibition inAedes aegypti

Zhang

Hussain

O'Neill

et al. 2013

186

201

The endosymbiont Wolbachia is common among insects and known for the reproductive manipulations it exerts on hosts as well as inhibition of virus replication in their hosts. Recently, we showed that Wolbachia uses host microRNAs to manipulate host gene expression for its efficient maintenance in the dengue mosquito vector, Aedes aegypti . Cytosine methylation is mediated by a group of proteins called DNA (cytosine-5) methyltransferases, which are structurally and functionally conserved from prokaryotes to eukaryotes. The biological functions of cytosine methylation include host defense, genome stability, gene regulation, developmental promotion of organs, and lifespan regulation. Ae. aegypti has only one DNA methyltransferase gene ( AaDnmt2 ) belonging to the cytosine methyltransferase family 2, which is the most deeply conserved and widely distributed gene among metazoans. Here, we show that in mosquitoes the introduced endosymbiont, Wolbachia , significantly suppresses expression of AaDnmt2 , but dengue virus induces expression of AaDnmt2 . Interestingly, we found that aae-miR-2940 microRNA, which is exclusively expressed in Wolbachia -infected mosquitoes, down-regulates the expression of AaDnmt2 . Reversely, overexpression of AaDnmt2 in mosquito cells led to inhibition of Wolbachia replication, but significantly promoted replication of dengue virus, suggesting a causal link between this Wolbachia manipulation and the blocking of dengue replication in Wolbachia -infected mosquitoes. In addition, our findings provide an explanation for hypomethylation of the genome in Wolbachia -infected Ae. aegypti.