New! Sign up for our free email newsletter.
Science News
from research organizations

A smelling bee? Deadly mite would be a favorite to win

Date:
June 3, 2015
Source:
Michigan State University
Summary:
If there were an international smelling bee, a deadly mite would be a favorite to win. New research has revealed that Varroa mites, the most-serious threat to honeybees worldwide, are infiltrating hives by smelling like bees.
Share:
FULL STORY

If there were an international smelling bee, a deadly mite would be a favorite to win.

New research has revealed that Varroa mites, the most-serious threat to honeybees worldwide, are infiltrating hives by smelling like bees.

The Michigan State University-led study, appearing in the current issue of Biology Letters, shows that being able to smell like their hostess reduces the chance that the parasite is found and killed.

The parasites were originally found on Asian honeybees. The invasive species, however, revealed their versatility when they began infesting and killing European honeybees.

"The mites from Asian honeybees, or the original host, are more efficient in mimicking both Asian and European honeybees," said Zachary Huang, MSU entomologist and one of the papers' lead authors. "This remarkable adaptability may explain their relatively recent host shift from Asian to European honeybees."

Chemical camouflage isn't a new weapon in insects' arsenals. Bolas spiders, for example, emit not one but three chemicals to emulate a sex pheromone to attract moths to eat. However, fooling socially sophisticated insects, such as honeybees, requires the faux scents to be spot-on.

That's because the complex society of bees comprises tens of thousands of individuals divided by a sophisticated caste system. So, the mites aren't simply tricking a solitary bee collecting pollen from a flower; they're fooling an entire society. The stealthy mites do this by not only by being able to smell like bees, but also by effectively emitting the specific scents of small, individual colonies.

"They are essentially getting through the door and reaching the inner sanctum by using bees' own complex communication codes against them," Huang said.

The codes in which they communicate are hydrocarbons, the simplest of organic compounds. By tweaking the proportions of these chemical colognes, the mites give off the correct scents to fool their enemies.

Specifically, it's the cuticular hydrocarbons, compounds released from hair-shaft glands, that emit scents that differentiate queens from fertile and infertile workers; it's the smell that invokes acceptance or triggers aggression.

Huang and his team showed that mites are able to change their surface chemicals to an entirely different species of honeybees. Further, they also revealed that the mites were able to make these changes rather quickly -- adapting in days rather than evolving over generations.

"Our study challenged the mites' ability to modify their hydrocarbons," Huang. "Conversely, bees are adapting to detect these invaders. Our results give a clear illustration of an arms race between the parasites and the host bees based on chemical mimicry and its detection."


Story Source:

Materials provided by Michigan State University. Note: Content may be edited for style and length.


Journal Reference:

  1. Y. Le Conte, Z. Y. Huang, M. Roux, Z. J. Zeng, J.- P. Christides, A.- G. Bagneres. Varroa destructor changes its cuticular hydrocarbons to mimic new hosts. Biology Letters, 2015; 11 (6): 20150233 DOI: 10.1098/rsbl.2015.0233

Cite This Page:

Michigan State University. "A smelling bee? Deadly mite would be a favorite to win." ScienceDaily. ScienceDaily, 3 June 2015. <www.sciencedaily.com/releases/2015/06/150603124346.htm>.
Michigan State University. (2015, June 3). A smelling bee? Deadly mite would be a favorite to win. ScienceDaily. Retrieved December 22, 2024 from www.sciencedaily.com/releases/2015/06/150603124346.htm
Michigan State University. "A smelling bee? Deadly mite would be a favorite to win." ScienceDaily. www.sciencedaily.com/releases/2015/06/150603124346.htm (accessed December 22, 2024).

Explore More

from ScienceDaily

RELATED STORIES