Scientists in the United Kingdom discovered the crucial role played by conical cells observed on the petals of some plants. These cells have a sticky quality that help bees grip flowers, especially during high winds.
The surface of flower petals is best viewed under an electron microscope, which enhances their stunning structure. According to Dr. Beverly Glover, the study’s lead author, “Many of our common garden flowers have beautiful conical cells if you look closely – roses have rounded conical petal cells while petunias have really long cells, giving petunia flowers an almost velvety appearance, particularly visible in the dark-colored varieties.”
Glover’s team had already discovered that, when offered snapdragons with conical cells and a mutant variety without these cells, bees prefer the former because the conical cells help them grip the flower. “It’s a bit like Velcro, with the bee claws locking into the gaps between the cells,” she explained.
Compared with many garden flowers, however, snapdragons have very complicated flowers. Bees have to land on a vertical face and pull open a heavy lip to reach the nectar, so Glover was not surprised that grip helps. But she wanted to discover how conical cells help bees visiting much simpler flowers.
“Many of our garden flowers, like petunias, roses and poppies, are very simple saucers with nectar in the bottom, so we wanted to find out why having conical cells to provide grip would be useful for bees landing on these flowers. We hypothesised that maybe the grip helped when the flowers blow in the wind.”
Using two types of petunia, one with conical cells and a mutant line with flat cells, Glover observed as a group of bumblebees that had never seen petunias before foraged in a large box containing both types of flower, and discovered they preferred the conical-celled flowers.
They the research team devised a way of mimicking the way flowers move in the wind. “We used a lab shaking platform that we normally use to mix liquids, and put the flowers on that. As we increased the speed of shaking, mimicking increased wind speed, the bees increased their preference for the conical-celled flowers,” she says.
The results, Glover says, give ecologists a deeper insight into the extraordinarily subtle interaction between plant and pollinator. “Nobody knew what these cells were for, and now we have a good answer that works for pretty much all flowers,” she concluded. “It’s easy to look at flowers from a human perspective, but when you put yourself into the bee’s shoes you find hidden features of flowers can be crucial to foraging success.”