Researchers at Oregon State University have learned that a specific wavelength range of blue fluorescent light set bees abuzz. This research is important because bees have a nearly $15 billion dollar impact on the U.S. economy; almost 100 commercial crops would vanish without bees to transfer the pollen grains needed for reproduction.
“The blue fluorescence just triggered a crazy response in the bees, told them they must go to it,” said the study co-author, Oksana Ostroverkhova. “It’s not just their vision, it’s something behavioral that drives them.”
The findings are a powerful tool for assessing and manipulating bee populations; for example, if a farmer needed to attract large numbers of bees for a couple of weeks to get his or her crop pollinated.
“Blue is broad enough wavelength-wise that we needed to figure out if it mattered to the bees if the light emitted by the sunlight-illuminated trap was more toward the purple end or the green end. And yes, it mattered,” Ostroverkhova said. “What’s also important is now we’ve created traps ourselves using stage lighting filters and fluorescent paint; we’re not just reliant on whatever traps come in a box. We’ve learned how to use commercially available materials to create something that’s very deployable.”
Fluorescent light is what’s seen when a fluorescent substance absorbs ultraviolet rays or some other type of lower-wavelength radiation and then immediately emits it as higher-wavelength visible light, just like a poster whose ink glows when hit by the UV rays of a blacklight.
Bees, like humans, have “trichromatic” vision. They have three types of photoreceptors in their eyes. Both people and bees have blue and green receptors. However, the third type for people is red while the third kind for bees is ultraviolet – electromagnetic energy of a lower wavelength that’s just outside the range of human vision.
Flowers’ vibrant colors and patterns – some of them detectable only with UV sight – are a way of helping pollinators like bees find nectar, a sugar-rich fluid produced by plants. Bees get energy from nectar and protein from pollen, and in the process of seeking food they transfer pollen from a flower’s male anther to its female stigma.
Building on her earlier research, Ostroverkhova, a physicist in OSU’s College of Science, set out to determine if green fluorescence was attractive to bees like blue. She also wanted to learn whether all wavelengths of blue fluorescence were equally attractive, or if the drawing power tended toward the green or violet edge of the blue range.
In field conditions that provided the opportunity to use wild bees of a variety of species (most bee-vision studies have been done in labs and used captive-reared honeybees) Ostroverkhova designed a collection of bee traps – some non-fluorescent, others fluorescent via sunlight – that her entomology collaborators set up in the field.
Under varying conditions with a diverse set of landscape background colors, blue fluorescent traps proved the most popular by a landslide.
Researchers examined responses to traps designed to selectively stimulate either the blue or the green photoreceptor using sunlight-induced fluorescence with wavelengths of 420 to 480 nanometers and 510 to 540 nanometers, respectively. They found that selective excitation of the green photoreceptor type was not attractive, in contrast to that of the blue.
“And when we selectively highlighted the blue photoreceptor type, we learned the bees preferred blue fluorescence in the 430- to 480-nanometer range over that in the 400-420 region,” Ostroverkhova said.
Reprinted from an Oregon State University news release.