Can mosquito ‘birth control’ fight disease?

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A protein in mosquitos that is critical to the process of producing viable eggs could pave the way for “mosquito birth control,” researchers report.

Depending on where you live, the buzz of a nearby mosquito can be a nuisance, or it can be deadly. Worldwide, more than 500 million people suffer from diseases the blood-feeding insects transmit, including malaria, Dengue Fever, Zika, and West Nile. Nearly a million deaths are attributed to mosquito-borne illnesses each year.

When researchers selectively blocked the activity of the protein—which they named Eggshell Organizing Factor 1, or EOF-1—in female mosquitoes, the mosquitos laid eggs with defective egg shells, leading to the death of the embryos inside.

In the report, which appears in PLOS Biology, the team shows that EOF-1 exists only in mosquitoes. Therefore, any drug they would develop to render the protein dysfunctional would only affect mosquitoes and no other organisms.

The team is hopeful the approach might offer a way to interrupt mosquito egg formation and reduce mosquito populations in areas of human disease transmission without harming beneficial insects such as honey bees.

“We specifically looked for genes that were unique to mosquitoes and then tested for their functional role in eggshell synthesis,” says Jun Isoe, a research scientist in the lab of Roger Miesfeld, a professor and head of the chemistry and biochemistry department at the University of Arizona. “We think there are other discoveries to be made using this same species-directed approach.”

Pinpointing the protein

Isoe first used a bioinformatics approach to search for and identify genes that are unique to mosquitoes. Researchers had not known about the function of the genes. The research team then created small RNA molecules that specifically inhibit each of the proteins the genes code for. Known as RNA interference, or RNAi, the technique works by suppressing messenger RNA molecules that serve as blueprints for proteins.

Focusing on the previously identified candidate genes one at a time, researchers injected the RNAi molecules into female mosquitoes right before a blood meal. Only female mosquitoes bite because they need a blood meal to produce eggs; the males visit flowers to drink nectar. Once a female mosquito has had a blood meal, her follicles develop and it takes three days to lay eggs.

The researchers screened each individual mosquito for viable offspring. Out of the 40 mosquito-specific genes the team tested, they found only one, the EOF-1 gene, disrupted eggshell formation and led to the death of the mosquito embryo.

A female mosquito needs a second blood meal in order to produce next the batch of fertilized eggs. Usually, the effects of RNAi injection last only through one egg-laying cycle, but in the case of EOF-1, the researchers were surprised that treated females could no longer produce viable eggs for the rest of their two- to three-week life span, even after three consecutive blood meals.

“This lasting effect makes the EOF-1 protein a very attractive target for drugs,” Miesfeld says.

Images the researchers obtained through electron microscopy revealed that when mosquitoes are deficient in the EOF-1 protein, the females lay eggs with abnormal-looking egg shells. Although the exact function of the protein remains unclear, Isoe and Miesfeld believe that EOF-1 might act as a master switch at the onset of the insects’ ability to produce viable eggs in response to a blood meal.

Based on these results, the team envisions a strategy using small molecule drugs that selectively interfere with mosquito EOF-1 in areas of the world where mosquito-borne human diseases are prevalent, resulting in eggs that never hatch into larvae.

Targeted approach

“We think this strategy may have a much lower chance of harming other organisms than what is being used today,” Miesfeld says. “Since the days of DDT, we have known that mosquito population control works to reduce the incidence of human disease. This could be a next-generation tool that could be applied to bed nets and other areas frequented by mosquitoes.”

Of the more than almost 3,500 species of mosquitoes buzzing across all continents except Antarctica, three genera stand out as carriers of human disease: Mosquitoes of the genus Aedes transmit Yellow Fever, Dengue, Chikungunya, and Zika viruses; Culex mosquitoes spread West Nile virus; and Anopheles mosquitoes carry malaria. To ensure that disruption of EOF-1 was not specific to lab-bred mosquitoes, Isoe tested it on a strain of Aedes aegypti mosquitoes from wild populations in the Tucson area and found it affected their eggs similarly.

“The inhibitors currently available to control mosquitoes have been used for so long that the pests are becoming resistant to them,” Miesfeld says. “Our idea is to knock their populations down to a level where you can break the cycle of disease transmission between mosquitoes and humans.”

As a first step toward turning the discovery into an application that could be commercialized, the team has filed a provisional patent on the species-specific discovery process.

Source: University of Arizona