Wolbachia-mediated resistance to Zika virus infection inAedes aegyptiis dominated by diverse transcriptional regulation and weak evolutionary pressures

Abstract

AbstractA promising candidate for arbovirus control and prevention relies on replacing arbovirus-susceptibleAedes aegyptipopulations with mosquitoes that have been colonized by the intracellular bacteriumWolbachiaand thus have a reduced capacity to transmit arboviruses. This reduced capacity to transmit arboviruses is mediated through a phenomenon referred to as pathogen blocking. Pathogen blocking has primarily been proposed as a tool to control dengue virus (DENV) transmission, however it works against a range of viruses, including Zika virus (ZIKV). Despite years of research, the molecular mechanisms underlying pathogen blocking still need to be better understood. Here, we used RNA-seq to characterize mosquito gene transcription dynamics inAe. aegyptiinfected with thewMel strain ofWolbachiathat are being released by the World Mosquito Program in Medellín, Colombia. Comparative analyses using ZIKV-infected, uninfected tissues, and mosquitoes withoutWolbachiarevealed that the influence ofwMel on mosquito gene transcription is multifactorial. Importantly, becauseWolbachialimits, but does not completely prevent, replication of ZIKV and other viruses in coinfected mosquitoes, there is a possibility that these viruses could evolve resistance to pathogen blocking. Therefore, to understand the influence ofWolbachiaon within-host ZIKV evolution, we characterized the genetic diversity of molecularly barcoded ZIKV virus populations replicating inWolbachia-infected mosquitoes and found that within-host ZIKV evolution was subject to weak purifying selection and, unexpectedly, loose anatomical bottlenecks in the presence and absence ofWolbachia. Together, these findings suggest that there is no clear transcriptional profile associated withWolbachia-mediated ZIKV restriction, and that there is no evidence for ZIKV escape from this restriction in our system.Author SummaryWhenWolbachiabacteria infectAedes aegyptimosquitoes, they dramatically reduce the mosquitoes’ susceptibility to infection with a range of arthropod-borne viruses, including Zika virus (ZIKV). Although this pathogen-blocking effect has been widely recognized, its mechanisms remain unclear. Furthermore, becauseWolbachialimits, but does not completely prevent, replication of ZIKV and other viruses in coinfected mosquitoes, there is a possibility that these viruses could evolve resistance toWolbachia-mediated blocking. Here, we use host transcriptomics and viral genome sequencing to examine the mechanisms of ZIKV pathogen blocking byWolbachiaand viral evolutionary dynamics inAe. aegyptimosquitoes. We find complex transcriptome patterns that do not suggest a single clear mechanism for pathogen blocking. We also find no evidence thatWolbachiaexerts detectable selective pressures on ZIKV in coinfected mosquitoes. Together our data suggest that it may be difficult for ZIKV to evolve Wolbachia resistance, perhaps due to the complexity of the pathogen blockade mechanism.