Abstract

Aedes aegypti mosquitoes infected with the wMel strain of Wolbachia are being released into natural mosquito populations in the tropics as a way of reducing dengue transmission. High temperatures adversely affect wMel, reducing Wolbachia density and cytoplasmic incompatibility in some larval habitats that experience large temperature fluctuations. We monitored the impact of a 43.6°C heatwave on the wMel infection in a natural population in Cairns, Australia, where wMel was first released in 2011 and has persisted at a high frequency. Wolbachia infection frequencies in the month following the heatwave were reduced to 83% in larvae sampled directly from field habitats and 88% in eggs collected from ovitraps, but recovered to be near 100% four months later. Effects of the heatwave on wMel appeared to be stage-specific and delayed, with reduced frequencies and densities in field-collected larvae and adults reared from ovitraps but higher frequencies in field-collected adults. Laboratory experiments showed that the effects of heatwaves on cytoplasmic incompatibility and density are life stage-specific, with first instar larvae being the most vulnerable to temperature effects. Our results indicate that heatwaves in wMel-infected populations will have only temporary effects on Wolbachia frequencies and density once the infection has established in the population. Our results are relevant to ongoing releases of wMel-infected Ae. aegypti in several tropical countries.

Highlights

  • Aedes aegypti mosquitoes with novel Wolbachia infections are increasingly being deployed for disease control [1]

  • Mosquitoes infected with Wolbachia bacteria are being released in the tropics to replace natural mosquito populations and suppress dengue transmission

  • Aedes aegypti mosquitoes with the wMel strain of Wolbachia were first released in Cairns, Australia in 2011 and releases were expanded to the entire city and surrounding suburbs

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Summary

Introduction

Aedes aegypti mosquitoes with novel Wolbachia infections are increasingly being deployed for disease control [1]. These programs rely on cytoplasmic incompatibility induced by Wolbachia, where uninfected females produce few or no viable offspring when mated to Wolbachiainfected males. Populations replaced with Wolbachia-infected mosquitoes can lead to reduced arbovirus transmission without mosquito population suppression [8]. Mosquitoes with the wAlbB infection have been released for population replacement in Malaysia [9] and for population suppression in Australia [10], Singapore (https://www.nea.gov.sg/corporatefunctions/resources/research/wolbachia-aedes-mosquito-suppression-strategy/projectwolbachia-singapore) and the USA (https://verily.com/projects/interventions/debug/). Wolbachia infections should remain at high frequencies in populations and at a high density within individual mosquitoes. It is vital to understand the factors that can affect the stability of Wolbachia infections in populations

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