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Biological rhythms in Aedes aegypti mosquitoes

Aedes aegypti mosquitoes are found globally and also act as the primary vector of Zika, dengue, and Chikungunya viruses, for which there are limited treatment options and no vaccines available. The use of insecticides as the main control strategy against diseases transmitted by this mosquito, is increasingly challenged by emerging resistance. Thus, there is a dire need for the development of novel approaches informed by an improved understanding of mosquito biology, to control mosquito populations and, ultimately, disease transmission. Rhythmic biological processes in mosquitoes help optimize resource exploitation by coordinating behaviors and physiology with fluctuating environmental conditions. Such synchronization enables organisms to adjust their physiology, metabolism, and behavior to predictable external cycles. In mosquitoes, circadian rhythmicity has been demonstrated in their biting and oviposition behavior, as well as their locomotor activity. However, little is known regarding how responses to long-range host cues are modulated by the circadian system. Here we show that both antennal sensitivity and olfactory behavior are time-of-day and odor-specific in Ae. aegypti females. Global transcriptomic analysis in whole heads of Ae. aegypti females reveal chemosensory genes differentially expressed throughout the day, providing insight into the molecular mechanisms behind daily variations in olfactory sensitivity and behaviors. We additionally show an odor-induced activation of mosquito behavior. Mosquito locomotion and behavior are also mediated by physiological state, and activity decreases after blood-feeding. Since the central clock components have been shown in other organisms to be redox-sensitive, we explored the role that diet heme plays in mediating behavioral changes following blood ingestion using artificial blood diets. We found that the transcription of the timekeeping gene period is reduced in the head immediately after feeding on a meal containing hemoglobin, but peripheral period transcription is reduced throughout the course of digestion following ingestion of a protein meal independent of hemoglobin inclusion. Overall, our results show that Ae. aegypti behavioral rhythms mediated by rhythmic gene expression are plastic and susceptible to external host cues and host blood digestion. This work can be leveraged for future studies investigating mosquito host-seeking and blood digestion to identify novel targets for vector control. / Doctor of Philosophy / Female mosquitoes rely on blood-feeding in order to produce eggs, but can unfortunately act as vectors of disease if they transmit pathogens when biting. Insecticides are currently our strongest main tool for controlling mosquito disease vectors such as Aedes aegypti, the yellow fever mosquito. However, increasing cases of insecticide resistance present new challenges in vector control, and new strategies to prevent vector-borne disease are needed. The Ae. aegypti mosquito is found globally and transmits Zika, dengue, and Chikungunya viruses, for which there are limited treatment options and no vaccines available. Mosquitoes exhibit rhythms in their gene expression and behaviors such as biting and activity patterns, in order to optimize energy efficiency and coordinate their biology and behaviors with daily fluctuations in the environment. However, it is unknown how their responses to human host odor cues are modulated by their central timekeeping system in the brain. Mosquitoes primarily find a human host via their sense of smell, or olfaction. Odor molecules in the air, emitted by humans, can be detected by mosquitoes' antennae. Here we show that both antennal sensitivity and behavioral responses to odors are time of day and odor-specific in Ae. aegypti females. We quantified gene transcripts in whole heads of Ae. aegypti females as a measure of gene expression, which revealed that genes involved in odor detection are expressed differently throughout the day, providing insight into the molecular mechanisms behind behavioral observations. We also show that mosquito behavior can be activated by odor exposure, and that their behavioral patterns can be influenced for multiple days following exposure. Mosquito behavior is also influenced by blood-feeding, which reduces mosquito activity and flight. Time-keeping genes in the fly brain have been shown to be sensitive to oxidative stress. Blood contains the protein hemoglobin, which can lead to oxidative stress when digested. Using artificial blood diets that allowed us to include or exclude hemoglobin in the meal, we found that the transcription of the timekeeping gene period is reduced in the head immediately after feeding on a diet containing hemoglobin, but is reduced in the rest of the body throughout the course of digestion following ingestion of a protein meal, whether hemoglobin was included or not. This work can be leveraged for future studies investigating mosquitoes' rhythms in host-seeking and blood digestion to identify new effective targets for vector control.

Identiferoai:union.ndltd.org:VTETD/oai:vtechworks.lib.vt.edu:10919/112698
Date03 June 2021
CreatorsEilerts, Diane Francine
ContributorsBiochemistry, Vinauger, Clément, Tu, Zhijian, Gillaspy, Glenda E., Paulson, Sally L.
PublisherVirginia Tech
Source SetsVirginia Tech Theses and Dissertation
Detected LanguageEnglish
TypeDissertation
FormatETD, application/pdf
RightsIn Copyright, http://rightsstatements.org/vocab/InC/1.0/

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