Almost everywhere humans live on this planet, mosquitoes carry microbes that cause potentially deadly diseases, from West Nile virus to malaria. While chemical insecticides offer a line of defense, mosquito populations often grow resistant to them. So, it’s intriguing to learn that we may now have another ally in this important fight: a genetically engineered fungus!
Reporting in the journal Science, an international research team supported by NIH describes how this new approach might be used to combat malaria . A fungus called Metarhizium pingshaense is a natural enemy of the mosquito, but, by itself, it kills mosquitoes too slowly to control transmission of malaria. To make this fungus an even more efficient mosquito killer, researchers engineered it to carry a gene encoding a toxin, derived from a spider, that is deadly to insects. Tests of the souped-up fungus in a unique contained facility designed to simulate a West African village found it safely and rapidly killed insecticide-resistant mosquitoes, reducing their numbers by more than 99 percent within 45 days.
Mosquitoes are the deadliest animals in the world. More than 3.2 billion people—about half of all humans—are at risk for malaria, and more than 400,000 die each year from the disease. Other mosquito-borne illnesses, including Zika and dengue viruses, sicken millions more each year. By combining existing insect control strategies with the latest technical innovation, it should be possible to lower those numbers.
In the latest study, Raymond St. Leger and Brian Lovett, University of Maryland, College Park, teamed with Abdoulaye Diabate and colleagues from Institut de Recherche en Sciences de la Santé/Cente Muraz, Burkina Faso, West Africa. The researchers employed a strategy that’s been in use around the world for more than 100 years to control agricultural pests.
The approach involves the fungal species Metarhizium, which kills a variety of insects. Earlier studies had shown that spores from a specific Metarhizium strain could make a big enough dent in a mosquito population to raise the possibility of using the fungus to reduce infective bites among humans . But killing off the mosquitoes required very large quantities of fungal spores and usually took a couple of weeks.
Here’s where things turned innovative. To boost the fungus’s potency, St. Leger and colleagues used genetic engineering to add a toxin derived from the Australian Blue Mountains funnel-web spider. The toxin came with a major advantage: the U.S. Environmental Protection Agency (EPA) already has approved its use as a safe-and-effective insecticidal protein.
Besides giving the engineered fungus that ability to produce a spider toxin, the researchers added another clever element. They didn’t want the fungus to produce the toxin all the time—only after it comes in contact with a mosquito’s hemolymph, the insect equivalent of blood. So, they needed to insert a control switch, and the researchers knew just where to find the needed part.
Once inside a mosquito, the fungus naturally produces a structural protein called collagen that shields it from the insect’s immune system. A genetic switch that turns “on” when it detects an insect’s hemolymph controls that collagen production. To ensure that the spider toxin was produced at just the right time, the researchers hotwired their Metarhizium to begin producing it under the control of this same genetic switch.
The next step was to test this modified organism in a more natural, but controlled, environment. The researchers spent more than a year in Burkina Faso building a specialized facility called a MosquitoSphere. It’s similar to a very large greenhouse, but with mosquito netting instead of glass.
The MosquitoSphere has six separate compartments, four of which contain West African huts, along with native plants and breeding sites for mosquitoes. The researchers hung a black cotton sheet, previously soaked in sesame oil, on the wall of a hut in each of three chambers.
In one hut, the sesame oil contained genetically engineered fungal spores. In the second hut, the oil contained natural fungal spores. In the third hut, there were no spores at all. Then, they released 1,000 adult male and 500 adult female mosquitoes into each chamber and watched what happened over the next 45 days.
In the hut without spores, the mosquitoes established a stable population of almost 1,400. In the chamber with the natural spores, 450 mosquitoes survived. But, in the chamber with the engineered fungus, the researchers counted just 13 survivors—too few to sustain a viable population.
The researchers say they suspect the fungus would be relatively easy to contain in nature. It’s sticky and not easily airborne. The spores are also extremely sensitive to sunlight, making it difficult for them to travel far. Importantly, the fungus didn’t harm other beneficial insects, including honeybees.
Caution is warranted before considering the release of a genetically engineered organism into the wild. In the meantime, the genetically engineered fungus also will serve as a platform for continued technology development.
The system can be readily adapted to target mosquitoes or other insects , perhaps using different natural toxins if insects might grow resistant to Metarhizium just as they have to traditional insecticides. Interestingly, the researchers note that the engineered fungi appear to make mosquitoes sensitive to chemical insecticides again, suggesting that the two types of insect-killers might be used successfully in combination.
Caption: Immunofluorescence staining showing that the testes of Zika-free mice (left) are full of developing sperm (pink), while the testes of Zika-infected mice (right) contain very few sperm. Credit: Prabagaran Esakky, Washington University School of Medicine, St. Louis
Recent research has shown that the mosquito-borne Zika virus has the potential to cause serious health problems, including severe birth defects in humans. But the damaging effects of Zika might not end there: results of a new mouse study show that the virus may also have an unexpected negative—and possibly long-lasting—impact on male fertility.
In work published in the journal Nature, an NIH-funded research team found that Zika infections can persist for many weeks in the reproductive systems of male mice . As a result of this infection, levels of testosterone and other sex hormones drop, sperm counts fall, and, in some animals, the testicles shrink to 1/10th of their normal size, possibly irreversibly. All of this adds up to Zika-infected male mice that are significantly less fertile than their healthy counterparts—producing about a quarter as many viable offspring as normal when mated with female mice. While mice are certainly not humans, the results underscore the urgent need for additional research to examine the full spectrum of Zika’s health effects in men, women, and children of both sexes.