Tag Archive | Honeybee Survival

Fungus fights mites that harm honey bees

Jun7

By Scott Weybright, College of Agricultural, Human, and Natural Resource Sciences

PULLMAN, Wash. – A new fungus strain could provide a chemical-free method for eradicating mites that kill honey bees, according to a study published this month in Scientific Reports.

A team led by Washington State University entomologists bred a strain of Metarhizium, a common fungus found in soils around the world, to work as a control agent against varroa mites. Unlike other strains of Metarhizium, the one created by the WSU research team can survive in the warm environments common in honey bee hives, which typically have a temperature of around 35 Celsius (or 95 F).

“We’ve known that metarhizium could kill mites, but it was expensive and didn’t last long because the fungi died in the hive heat,” said Steve Sheppard, professor in WSU’s Department of Entomology and corresponding author on the paper. “Our team used directed evolution to develop a strain that survives at the higher temperatures. Plus, Jennifer took fungal spores from dead mites, selecting for virulence against varroa.”

Jennifer Han, a post-doctoral researcher at WSU, led the breeding program along with WSU assistant research professors Nicholas Naeger and Brandon Hopkins. Paul Stamets, owner and founder of Olympia-based business Fungi Perfecti, also contributed to the paper. Stamets is a fungi expert, well-known for using several species in applications ranging from medicine to biocontrol.

Varroa destructor mites, small parasites that live on honey bees and suck their “blood,” play a large role in Colony Collapse Disorder, which causes beekeepers to lose 30-50% of their hives each year. The mites feed on bees, weakening their immune systems and making them more susceptible to viruses.

The main tools beekeepers use to fight varroa are chemicals, such as miticides, but the tiny pests are starting to develop resistance to those treatments, Naeger said.

Metarhizium is like a mold, not a mushroom. When spores land on a varroa mite, they germinate, drill into the mite, and proliferate, killing it from the inside out. Bees have high immunity against the spores, making it a safe option for beekeepers.

Stamets, who did some of the initial testing with Metarhizium that showed the fungus couldn’t survive hive temperatures, was impressed by the work done by the WSU researchers.

“Science progresses through trial and error, and my technique wasn’t economical because of the hive heat,” he said. “But Jennifer did enormous amounts of culture work to break through that thermal barrier with this new strain. It’s difficult to really appreciate the Herculean effort it took to get this.”https://www.youtube.com/embed/LIfTsPikxqU?version=3&rel=1&fs=1&autohide=2&showsearch=0&showinfo=1&iv_load_policy=1&wmode=transparent

Han and Naeger screened more than 27,000 mites for levels of infection to get the new strain.

“It was two solid years of work, plus some preliminary effort,” Han said. “We did real-world testing to make sure it would work in the field, not just in a lab.”

This is the second major finding to come from WSU’s research partnership with Stamets involving bees and fungi. The first involved using mycelium extract that reduced virus levels in honey bees.

“It’s providing a real one-two punch, using two different fungi to help bees fight varroa,” Stamets said. “The extracts help bee immune systems reduce virus counts while the Metarhizium is a potentially great mite biocontrol agent.”

The next step is to seek approval from the Environmental Protection Agency to use Metarhizium on hives used in agriculture. The team must also finalize delivery methods for beekeepers to apply the fungus in hives.

“We hope in 10 years that, rather than chemical miticides, Metarhizium is widely used to control Varroa mites,” Sheppard said. “And that the mite problem for beekeepers has been significantly reduced.”

The team thinks the methods they developed to evolve Metarhizium for varroa control could be used to improve biocontrol agents in other crop systems as well.

The majority of the funding for this work came from private donations from individuals and foundations. Additional funding came from Washington State Department of Agriculture (WSDA) Specialty Crop Block Grant K2531 and the USDA National Institute of Food and Agriculture, Hatch 1007314.

Close up of honey bee on a honeycomb with mites on its back
Varroa mites seen living on a honey bee. Mites weaken bees’ immune systems, transmit viruses, and siphon off nutrients. Photo by Scott Bauer, USDA Agricultural Research Service.

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Honeybee Gut Health Could be Key to Colony Survival

Feb4

AUSTIN, Texas — Honeybee populations have sharply declined around the world in recent years, confounding scientists and posing a grave threat to agriculture.

Now, University of Texas researchers may have discovered a way to reverse the trend.

Writing in the new issue of the journal Science, the team wrote that it had genetically engineered strains of bacteria that live in honeybee guts; there, they pump out medicines that protect the bees from Varroa mites and deformed wing virus — two chief culprits of colony collapse, a phenomenon that occurs when the majority of worker bees in a colony disappear.

The findings have “direct implications for bee health,” said Nancy Moran, a professor of integrative biology and the primary investigator on the study.

The stakes are high. Bees are a key player in the food chain. During a single day, a female bee may visit several hundred flowers, depositing pollen along the way; roughly a third of our food chain is the result of pollination. Austin alone has about 180 species of bees.

According to the American Beekeeping Federation, honeybees contribute nearly $20 billion each year to the value of U.S. crop production, and they play an enormous role in global food production. The California almond industry, for example, requires approximately 1.8 million colonies of honeybees to pollinate nearly one million acres of orchards.

But bee colonies have been beset by disease and die-offs. According to a national survey, beekeepers lost nearly 40% of their honeybee colonies during the 2018-19 winter, the highest rate reported since the survey began 13 years ago.

One of the suspects is the Varroa mite, a parasite spread in recent decades from East Asia to the U.S.

The mite is “considered the biggest problem in beekeeping today,” said Mary Reed, chief apiary inspector of the Texas Apiary Inspection Service, an arm of Texas A&M University, “The reason is that they can vector viruses. If we didn’t have honeybee viruses, the Varroa mite would just be considered a nuisance. If mite levels get too high, they can weaken the immune system of a single bee and of a whole colony.”

After feeding on a honey bee host, the adult female mite reproduces by crawling off her host into a cell with a bee larva. Offspring then alternate between feeding on the larva and defecating on the side of the cell. While the mites do not kill adult honeybees, they can weaken and shorten individuals’ lifespans and ultimately will kill the colony by outcompeting their host. And the mites are vectors of numerous viruses including deformed wing virus.

While the background causes of particular instances of colony collapse disorder remain “a contentious issue under investigation,” said Sean Leonard, a graduate student and lead author of the study, “mites are an increasingly severe problem” over the past couple of decades that are contributing to high bee mortality rates.

The UT team _ which involved at least eight other professors and students _ engineered one strain of bacteria to target the virus and another for the mites.

Engineering the bacteria to “knock down” genetic targets in bee bodies, Moran said, the researchers found that compared with control bees, the bees treated with the strain of bacteria targeting the virus were 36.5% more likely to survive to day 10. Meanwhile, Varroa mites feeding on another set of bees treated with the mite-targeting strain of bacteria were about 70% more likely to die by day 10 than mites feeding on control bees.

“This is the first time anyone has improved the health of bees by genetically engineering their microbiome,” Leonard said.

The team introduced modified bacteria to hundreds of bees in a laboratory setting. Sprayed with a sugar water solution containing the bacteria, the bees groomed one another and ingested the solution. The team found inoculating young worker bees with the engineered bacteria led the bees’ immune systems to be primed to protect them against deformed wing virus _ essentially acting as a vaccine _ and caused the mites’ own immune systems to fight against and ultimately kill them.

Writing an accompanying commentary in Science, Robert J. Paxton, a zoologist with the Institute for Biology at Martin Luther University Halle-Wittenberg in Germany, writes that the approach is “effective, long-term, potentially cheap, and easy to apply.”

The approach could “provide a solution to many of the honey bee’s woes” and provide a way “to dissect the molecular intricacies of honey bees and their societies,” Paxton said.

But there remain major hurdles to any widespread rollout of the bacteria as a vaccinelike solution.

Leonard said it remains an open question how the genetically engineered bacteria will perform in an actual hive, where social behavior among the bees could differ from inside the lab. “How they’ll perform in an actual hive we don’t know: it might be better or worse,” he said.

And because the bacteria are genetically modified, any manufacturer or distributor of the bacteria will first have to pass through regulatory hoops, Moran said.

“These species of bacteria occur only in honey bees,” said Moran. “They are not going to jump into butterflies or other insects or anything else. They’re very restricted. They aren’t going to invade the environment in some way that concerns people.”

The type of bacteria used are highly specialized to live in the bee gut, can’t survive for long outside of it and are protective for a virus that strikes only bees. Still, further research will be needed to determine the effectiveness and safety of the treatments in agricultural settings.

News about research like this is “always good to hear,” said Charles Reburn, co-owner of Bee Friendly Austin, which operates in Southwest Austin and sells bee hives, wax and honey.

Having worked with Texas A&M University researchers, “I know what it takes from initial study to getting something marketed,” he said. “It takes a lot to get out of the lab and into the field. If it comes to testing, sign me up.”

A Varroa mite, a common pest that can weaken bees and make them more susceptible to pathogens, feeds on a honeybee. University of Texas
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Reprinted from Austin American-Statesman, Texas which owns the copyright