Professor Gregory Lanzaro, a molecular geneticist at the UC Davis School of Veterinary Medicine leads the University of California Malaria Initiative. The team believes it can harness gene drive in the fight against malaria in São Tomé and Príncipe.

On a muggy evening in July on the island of Príncipe, part of a volcanic archipelago 200 miles off the West African mainland, 11,000 mosquitoes dusted in fluorescent green powder flew together into the heavy equatorial air, tiny volunteers in the service of science.

Over the next 10 nights, another group of volunteers, human ones, sat outside their houses in villages nestled in the rainforest, keeping their arms and legs exposed in the damp dark, waiting for the faint tickle of a mosquito in search of blood. Once one alighted, they switched on a headlamp and used a rubber tube attached to a glass vial to suck the insect up and seal it in a cup.

The mosquitoes were raised from larvae, dusted green, then set free, by an international team of scientists who are trying to bring cutting-edge genetic science to an ancient fight — that against malaria, the most deadly mosquito-borne disease.

For each of the 10 mornings after the mosquito release, the scientists fanned out along the northeastern coast of this remote island, collecting cups humming with mosquitoes. They then took the insects to a makeshift lab in their hotel suite in the island’s one town, Santo Antonio, where they slid them under the light of a fluorescent microscope. Twelve of the 253 mosquitoes that had been caught glimmered with tiny particles of the green powder that clung to their scaly bodies.

The recaptured green mosquitoes offered insight into how far they flew and the size of the mosquito population, clues to the dynamics of malaria in this country. And they moved the scientists one step closer to their goal: replacing the mosquitoes that live here now with ones they have genetically modified so that they can no longer transmit the malaria parasite.

Their idea is to release a small colony of genetically modified mosquitoes, just the way they did with the green-dusted ones, to mate with wild ones. The gene engineering technology they are using could, in just a few generations — a matter of months when it comes to mosquitoes — make every member of the species that transmits malaria here, the Anopheles coluzzii, effectively immune to the parasite.

This team, working with a project called the University of California Malaria Initiative, has already successfully engineered the Anopheles coluzzii to block the parasite in a lab. And the scientists believe they can harness gene drive, a process in which an inherited trait spreads swiftly throughout a population, so that all the species’s offspring will carry it, not just half, which is the way inheritance normally works.

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