Published online: 17 May 2007; | doi:10.1038/news070514-19 / http://www.nature.com/news/2007/070514/full/070514-19.html
Mosquito genome leaves researchers itching for more
As a second mosquito species is sequenced, news@nature.com looks back to see what these genomes do for science. / Heidi Ledford
What's new?


| Aedes aegypti looks different and has a much different genome to its malaria-carrying cousin. James Gathany, CDC |
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Today scientists officially release the genome sequence of one of humanity's least beloved neighbours: the mosquito
Aedes aegypti. A preliminary analysis of the sequence is published online in the journal
Science,
opening the floodgates on a variety of different research approaches
aimed at controlling the insect and the diseases it carries.
Wait - this sounds awfully familiar. Didn't they already do this?They sequenced the
Anopheles gambiae genome four and a half years ago. That was a totally different mosquito.
Are they really so different?The key distinction between the two is that a bite from a female
A. gambiae can give you malaria, whereas a bite from
A. aegypti could give you yellow fever or dengue. They also look very different.
The
two mosquitoes diverged in evolution about 150 million years ago. "They
are about as different as you can get in the mosquito world," says
David Severson, a biologist at the University of Notre Dame in Indiana
who participated in both sequencing projects. "They've had a long time
to go off and do their own thing."
During that time, the
A. aegypti genome swelled to 1.38 billion base pairs, five times the size of
A. gambiae's genome (a third the size of the human genome). But the two mosquitoes have approximately the same number of genes.
What have researchers managed to do with the A. gambiae sequence so far?Researchers have taken a variety of different strategies for using the
A. gambiae
genome sequence to further their attempts to control malaria. For
example, molecular entomologist Flaminia Catteruccia of Imperial
College London has been trawling through the
A. gambiae genome
in search of genes responsible for sex determination. Her ultimate goal
is to flood wild mating populations with sexually active but
genetically sterile male mosquitoes.
Meanwhile,
Liangbiao Zheng of Yale University in New Haven, Connecticut, has been
using the sequence to study the interactions between the mosquito and
the malaria parasite. The hope is to use information about how the
parasite evades the mosquito's immune defences to find ways to bolster
A. gambiae's
defences against malaria. Zheng and his colleagues have found several
key genes that regulate the mosquito's response to infection. They are
also comparing strains of
A. gambiae that vary in their degree
of resistance to the parasite, in the hope of finding the genetic
regions responsible for increased or decreased immunity.
Has anyone worked out how to stop the mozzies from biting humans?Some have focused their research on this, yes, with an eye to developing new insect repellents or to creating
A. gambiae
strains that can't hone in on their next human meal. Several studies
have surveyed the genome for possible olfactory genes and have come up
with a list of new targets.
Has any of this translated into practical applications?It
will be a long time before most of these findings can make the
lab-to-field leap. "It isn't like 'We have the genome so now we can
solve everything'," says Vishvanath Nene, a researcher at the J. Craig
Venter Institute who worked on the
A. aegypti genome. "But we are a step closer."
One
technology that could make this leap soon is a method that uses gene
expression patterns to determine whether a mosquito is resistant to
insecticides. The traditional way of screening for insecticide
resistance relied on testing individual mosquitoes against many, many
individual herbicides. Using gene expression instead would speed up the
process.
Are there other mosquito genomes out there too?Early drafts of a genome sequence from
Culex pipiens, the mosquito that carries elephantiasis and West Nile disease, are available.
And are there more to sequence?Lots.
There are about 3,500 species of mosquitoes, in three subfamilies -
Anophelinae, Culicinae and Toxorhynchitinae. The three sequenced
mozzies mentioned above fall into the first two subfamilies. Of them,
only
C. pipiens is common in North America or Europe.
There's actually more work to be done on
A. gambiae
too. The genome they sequenced turns out to have come from a lab strain
that was actually a hybrid of two common subspecies. So now they have
to sequence them individually to get the full picture.
What about other insects?A
motley crew of other unpleasant bloodsucking disease-carriers is
already crowding the sequencing pipeline. At various stages in the
sequencing process are: the deer tick, a scourge particularly in the
United States because it can carry the bacterium that causes Lyme
disease; the body louse, which can cause epidemic typhus; two different
sand flies that can transmit leishmaniasis; and the tsetse fly, which
can spread African sleeping sickness.
References- Nene V., et al. Science, doi:10.1126/science.1138878 (2007).
- Holt R. A., et al. Science,
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