The unconventional way mosquitoes process odors could help explain why they are so good at finding humans to bite
From The Brink (at
Boston University)
By Jessica Colarossi
August 18, 2022 -- If
you’ve ever sprayed yourself head to toe in bug repellent, yet still felt like
a mosquito magnet, it will come as no shock to you that mosquitoes are very,
very good at finding humans to bite. One key factor in this superpower is their
keen sense of smell, or olfaction, which relies on the olfactory system.
“Mosquitoes are highly
specialized,” says Meg Younger, a Boston University College of Arts &
Sciences assistant professor of biology who studies mosquito olfaction.
These relentless, buzzing creatures are designed to find us, bite us, use
proteins in our blood to reproduce—and repeat. Mosquitoes, as much as they feel
like a seasonal nuisance in the Northeast US, are deadly creatures that kill more people
than any other animal in the world. Depending where they live,
certain types of mosquitoes transmit diseases like malaria, West Nile virus,
Zika virus, dengue, eastern equine encephalitis, and others. And warmer, dry, and tropical climates battle
mosquitoes all year long.
Younger is working to
crack the code on how mosquitoes use their sense of smell to track us in order
to better understand how we can repel them more effectively. In a new
paper published in Cell, Younger and her colleagues
describe the unique and previously unknown way Aedes aegypti mosquitoes
process smell at the biological level; their findings are a departure from the
central theories that previously guided our understanding of insect
olfaction.
Aedes aegypti mosquitoes normally
inhabit warm, tropical climates, and have caused minor outbreaks of dengue in
southern states like Florida and Texas. But in recent years, they’ve been
spotted as far north as Connecticut, raising alarm bells about what to expect
as global temperatures continue to warm.
“This is part of why
this work is going to get more and more important,” says Younger, who began the
study while completing postdoctoral research with Leslie B. Vosshall at
The Rockefeller University, a biomedical research-focused institution in New
York.
How Smell Works
For humans, scents are
registered in the brain by a flow of communication that begins in the nose,
which is lined with special cells called olfactory sensory neurons. These neurons—which house sensory receptors,
specialized molecules that are stimulated by odor particles—act as detectors of
odor and as messengers to the brain.
“The central dogma in
olfaction is that sensory neurons, for us in our nose, each express one type of
olfactory receptor,” Younger says. This is the underlying organizational
principle of olfaction: one receptor to one neuron. For example, the smell of a
freshly baked apple pie is actually a chemical code created by different odor
molecules. As the distinct smell wafts into our noses, it triggers sensory
receptors that match the different odor molecules; corresponding neurons then
communicate to a brain region called the olfactory bulb—or the antenna lobe in
insects—where it maps the odor code.
According to the study
findings, Aedes aegypti mosquitoes’ olfactory system is
organized very differently, with multiple sensory receptors housed within one
neuron, a process called gene coexpression. This uniquely specialized olfactory system
could help explain why mosquitoes are so good at sniffing out humans to
bite.
“This is shockingly
weird,” says Younger, who initially thought her look into mosquito sensory
neurons would prove it to be like every other olfactory system, like in flies
and mice. The difference might seem technical, but it suggests that mosquitoes’
sense of smell is highly attuned to humans. “It’s not what we expected,” she
says.
Past research has found
that even eliminating entire receptors in mosquitoes that are used for decoding
carbon dioxide—a major chemical cue that they use to hunt humans—does not
interfere with them finding people. Younger’s latest study may indicate one
reason why.
In her lab at BU,
Younger is raising mosquitoes in incubators and using modern genetic tools to
understand olfaction in ways that were not possible a decade ago. For this
study, the researchers developed mosquitoes that would light up under the
microscope when exposed to certain smells—they expressed fluorescent proteins
that glow under the microscope, allowing the researchers to see chemical
responses to odorants. They also used CRISPR technology (which stands for clustered
regularly interspaced short palindromic repeats and is a genetic tool
created to edit DNA in living organisms) to label different groups of
sensory neurons, while preserving the function of the cell proteins.
All of the results
point to an olfactory system that is unconventional in the way that it
coexpresses sensory receptors within individual sensory neurons. This suggests
redundancy in the code for human odor—and possibly a stronger sense of smell
that draws mosquitoes to humans. The next step is figuring out what role
coexpression plays in driving the behaviors of Aedes aegypti mosquitoes.
“A compelling idea is
that it’s making them good at finding people,” Younger says. Her long-term goal
is to intervene i
n mosquito biting by
generating new, improved repellents, or attractants that are more appealing to
mosquitoes than human blood. “As we learn about how odor is encoded in their
olfactory system, we can create compounds that are more effective based on
their biology,” she says.
Until then, Younger
uses bug spray—brands with 15 to 25 percent DEET or picaridin tend to be rated
most effective—to protect herself from mosquitoes outdoors. Eventually, with
more and more research, she hopes there will be a better option.
This research received
support from the National Institutes of Health.
https://www.bu.edu/articles/2022/mosquitoes-have-a-bizarre-sense-of-smell/
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