July 6, 2018
Do you ever feel as if you have been singled out in a crowd—the only one to return home from outdoor activities with itchy, red welts rising all over your body? Well, we hate to say so, but it’s true: Mosquitos remember the taste and smell of human blood, according to researchers at the Frain Life Science Institute at Virginia Tech, and they often pick on people whose blood tastes the sweetest to them.
That’s the bad news. The good news, based on a recent study, is that, if you swat determinedly at the mosquitoes around you, they will remember the unpleasant sensation—and stay away from you in the future.
Indeed, the Virginia Tech study—published last January in the journal Current Biology—found that the pesky insects have much larger and longer memories than we could have imagined. The researchers found that mosquitoes can learn rapidly and remember the smells of the tastiest hosts. Dopamine is a key mediator of this process. Mosquitoes use this information and incorporate it with other stimuli to develop preferences for a particular vertebrate host species, and, within that population, certain individuals
However, the study also proved that even if an individual is deemed delicious-smelling, a mosquito’s preference can shift if that person’s smell is associated with an unpleasant sensation. Hosts who swat at mosquitoes or perform other defensive behaviors may be abandoned, no matter how sweet.
Clément Vinauger, an assistant professor of Biochemistry in the College of Agriculture and Life Sciences; and Chloé Lahondère, a research assistant professor in the Department of Biochemistry, demonstrated that mosquitoes exhibit a trait known as aversive learning by training female Aedes aegypti mosquitoes to associate odors (including human body odors) with unpleasant shocks and vibrations.
Twenty-four hours later, the same mosquitoes were assessed in a Y-maze olfactometer in which they had to fly upwind and choose between the once-preferred human body odor and a control odor. The mosquitoes avoided the human body odor—suggesting that they had been successfully trained.
By taking a multidisciplinary approach and using cutting-edge techniques, including CRISPR gene editing and RNA interference (RNAi), the scientists also were able to identify that dopamine is a key mediator of aversive learning in mosquitoes.
They targeted specific parts of the brain involved in olfactory integration by fitting mosquitoes with helmets that allowed for brain activity recordings and observations. By placing mosquitoes in an insect flight simulator and exposing the mosquitoes to various smells, including human body odors, the scientists observed how the insects, trained or not, reacted. What they saw is that the neural activity in the brain region where olfactory information is processed was modulated by dopamine in such a way that odors were easier to discriminate, and potentially learn, by the mosquitoes.
“Unfortunately, there is no way of knowing exactly what attracts a mosquito to a particular human. Individuals are made up of unique molecular cocktails that include combinations of more than 400 chemicals,” said Lahondère. “However, we now know that mosquitoes are able to learn odors emitted by their host and avoid those that were more defensive.”
“Understanding these mechanisms of mosquito learning and preferences may provide new tools for mosquito control,” said Vinauger. “For example, we could target mosquitoes’ ability to learn and either impair it or exploit it to our advantage.”
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