Recently, the scientific community has realized that the adult mosquito gut microbiota (the microbes that are living in the gut of the mosquito) contributes to modulate the transmission of mosquito-borne pathogens. However, the role of the microbiota of larvae in influencing adult traits has remained under explored.
This question is particularly important for Aedes aegypti, a major vector of arboviruses such as dengue, yellow fever, Zika and chikungunya viruses. In sub-Saharan Africa, Ae. aegypti exists in an urban form and a forest form, and the larval breeding sites differ between the two. Whereas the urban form develops in human-made containers such as used tires and discarded items, the forest form develops in natural breeding sites such as rock pools and tree holes.
Researchers from the Institut Pasteur and CNRS, in collaboration with scientific teams from IRD, University Claude Bernard Lyon 1, and CIRMF in Gabon, observed differences in the gut microbiota of Ae. aegypti larvae breeding in the forest or in the urban environment. Back to the lab, they demonstrated that differential bacterial exposure during the development of Ae. aegypti larvae can have “carry-over” effects on adult traits related to a mosquito’s ability to be a successful vector of arboviruses. Thus, exposure to different bacteria during development results in variation in the speed at which that larvae develop, the size of adult mosquitoes, immune activity of adults, as well as susceptibility to dengue virus.
As explained by Laura Dickson, first author of the study and researcher at the Institut Pasteur, “this discovery is highly significant because it provides the first empirical proof of principle that bacteria in the aquatic environment can modulate the ability of adult mosquitoes to transmit human pathogens.” According to Louis Lambrechts, researcher at CNRS, head of the Insect-Virus Interactions group at the Institut Pasteur and coordinator of the study, “our discovery calls for an increased appreciation of the role of larval ecology in the transmission of mosquito-borne pathogens.”
These findings represent an important first step toward a more comprehensive understanding of how the environment shapes the risk of vector-borne disease. Improved knowledge on the bacteria found in natural larval breeding sites and their consequence at the adult stage could lead to new disease control strategies. For instance, this could be done by targeting the breeding sites where mosquito larvae are most likely to become efficient vectors of arboviruses. An alternative could be to directly manipulate the bacteria in breeding sites to reduce the ability of mosquitoes emerging from these sites to transmit human pathogens.