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
Summary
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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