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How does a virus hijack insect sperm to control disease vectors and pests?

A new study reveals how viral proteins from symbiotic bacteria cause sterility in insects
7 March 2024
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fluorescent image of testes with red spots everywhere
Wolbachia and a virus that it carries can cause sterility in male insects by hijacking their sperm messenger molecules - tagged with red fluorescence in this image of Drosophila testes - preventing the insects from fertilizing eggs of females that do not have the same combination of bacteria and virus. Credit: Rupinder Kaur/Penn State

A widespread bacteria called Wolbachia and a virus that it carries can cause sterility in male insects by hijacking their sperm, preventing them from fertilizing eggs of females that do not have the same combination of bacteria and virus. A new study led by microbiome researchers at Penn State has uncovered how this microbial combination manipulates sperm, which could lead to refined techniques to control populations of agricultural pests and insects that carry diseases like Zika and dengue to humans.

The study is published in the March 8 issue of the journal Science.

Wolbachia is the most widespread bacteria in animals and lives symbiotically within the reproductive tissues of about 50% of insect species, including some mosquitos and flies,” said Seth Bordenstein, professor of biology and entomology, director of the One Health Microbiome Center at Penn State, and one of the leaders of the research team. “Wolbachia has genes from a virus called prophage WO integrated into its genome. These genes — cifA and cifB —allow the bacteria to remarkably manipulate sperm and quickly spread through an insect population for their own good.”

When a male and female insect that both have Wolbachia mate, they successfully reproduce and pass on the bacteria. But when a male with Wolbachia mates with a female with no Wolbachia, the sperm are rendered lethal to the fertilized eggs, succumbing them to death. This system cunningly increases the proportion of offspring with Wolbachia and the virus in the next generation, because females with the bacteria successfully reproduce more frequently than females without.

This system is being used in several ongoing pilot studies across the world to control insect pests and the harmful viral diseases they carry. For example, to control a population of agricultural or human pests that do not have the bacteria, scientists release males with Wolbachia in order to crash the population.

“One of Wolbachia’s superpowers is that it blocks pathogenic RNA viruses such as Zika, dengue, and chikungunya virus, so mosquitos with Wolbachia do not pass these viruses on to people when they bite,” Bordenstein said. “So, releases of both male and female mosquitos with Wolbachia in an area where it isn’t already present leads to replacement of the population with mosquitos that can no longer pass on a viral disease. The World Mosquito Program is now using Wolbachia to control viruses in 11 countries. With this study, we reveal the underlying mechanics of how this process works so we can fine-tune the technique to expand its scope in vector control measures.”

Wolbachia’s prophage WO genes code for proteins that interfere with normal development of sperm cells. These proteins impact a critical transformation during sperm development, when the sperm’s genome is repackaged and the sperm changes from a canoe-shape into a more refined needle-like shape.

“This shape change is incredibly important to the success of sperm, and any interference can impact the sperm’s ability to travel in the female reproductive tract and successfully fertilize the egg,” said Rupinder Kaur, assistant research professor of biology and entomology at Penn State and the other leader of the research team. “The transition is highly conserved in almost everything from insects to humans. Defects in this process can also cause male sterility in humans.”
 

According to the researchers, sperm is particularly prone to DNA damage and repair during this transition. In this study, they found that sperm exposed to Wolbachia, or the Cif proteins alone, had an elevated level of DNA damage at this stage. The DNA damage, if not repaired in a timely fashion, can result in abnormal sperm genome packaging, male infertility, and embryonic inviability.

“These results confirmed the impact of Wolbachia and Cif proteins at this stage of sperm development, but we still wanted to know what was happening at earlier stages to trigger these changes,” Kaur said.  “We conducted a series of tests to explore the structure and biochemical function of the Cif proteins and found that they can cleave messenger molecules called long non-coding RNA, which sets the stage to interfere with downstream development and function of the sperm.”

The researchers used fruit flies with Wolbachia to test the potential link between the bacteria and long non-coding RNA. They found that Wolbachia—or the Cif proteins alone—reduced the amount of these RNAs. Additionally, mutant flies with reduced expression of these RNAs in conjunction with Wolbachia had elevated levels of embryonic inviability because it augmented the defective transition process of sperm development. So, Kaur explained, the virus proteins control sperm by depleting the long non-coding RNAs required for a normal sperm function.

“Long non-coding RNAs do not make any proteins themselves, but they can have profound impacts on regulating the function of other genes required for sperm development,” Bordenstein said. “By altering this non-coding part of the genome, we found that Cif proteins start impacting sperm right from the earliest stages of development. Wolbachia’s prophage WO genes act like master puppeteers, manipulating sperm development in a way that allows their genes and the symbiotic bacteria to quickly spread through arthropod populations.”

Because the process of sperm development looks similar across the animal kingdom, the researchers said that knowledge of this process could lend insight into sterility challenges in humans as well as inform new control methods of harmful insect populations.

“Now that we have reverse engineered this process, we can fine tune methods of population control with Wolbachia that are already in use,” Kaur said. “We plan to take advantage of this knowledge to augment currently existing disease vector and pest control methods, and perhaps emulate the technique without Wolbachia or virus proteins in the long-term.”

In addition to Bordenstein and Kaur, the research team includes Angelina McGarry, research technologist II at Penn State; J. Dylan Shropshire, assistant professor at Lehigh University; and Brittany Leigh, a postdoctoral researcher at Vanderbilt University at the time of the research.

Funding from the National Institutes of Health, the U.S. National Science Foundation and Penn State supported this research.

Media Contacts
Seth Bordenstein
Huck Chair in Microbiome Sciences; Professor of Biology and Entomology
Rupinder Kaur
Assistant Research Professor of Biology and Entomology
Gail McCormick
Science Writer