Login

GPC Members Login
If you have any problems or have forgotten your login please contact [email protected]


Venus flytraps don't eat the insects that pollinate them

While most people are familiar with Venus flytraps and their snapping jaws, there is still a lot that scientists don't know about the biology of these carnivorous plants. Researchers have for the first time discovered which insects pollinate the rare plants in their native habitat - and discovered that the flytraps don't dine on these pollinator species.

Venus flytraps (Dionaea muscipula) are in a genus all their own, and are native to a relatively small area, restricted to within a 100-mile radius of Wilmington, N.C.

"These findings answer basic questions about the ecology of Venus flytraps, which is important for understanding how to preserve a plant that is native to such a small, threatened ecosystem," says Elsa Youngsteadt, a research associate at North Carolina State University and lead author of a paper on the work. "It also illustrates the fascinating suite of traits that help this plant interact with insects as both pollinators and prey."

"Everybody's heard of Venus flytraps, but nobody knew what pollinated them - so we decided to find out," says Clyde Sorenson, co-author of a paper describing the work and Alumni Distinguished Undergraduate Professor of Entomology at NC State.

To that end, researchers captured insects found on Venus flytrap flowers at several sites during the plant's five-week flowering season. The researchers identified each insect and checked to see if they were carrying Venus flytrap pollen - and, if they were carrying pollen, how much.

Out of about 100 types of insects found on the flowers, only a few were both common and carrying a lot of pollen: a green sweat bee (Augochlorella gratiosa), a checkered beetle (Trichodes apivorus) and the notch-tipped flower longhorn beetle (Typocerus sinuatus).

The researchers also retrieved prey from more than 200 flytraps at the study sites. The three most important pollinator species - despite being found so often on the flowers - were never found in the traps.

"One potential reason for this is the architecture of the plants themselves," Youngsteadt says. "Venus flytrap flowers are elevated on stems that stand fairly high above the snap traps of the plant, and we found that 87 percent of the flower-visiting individuals we captured - including all three of the most important species - could fly. But only 20 percent of the prey could fly. The pollinator species may simply be staying above the danger zone as they go from flower to flower, making them less likely to be eaten."

But other factors may also come into play.

"We know that the snap traps are different colors than the flowers, and may possibly lure different species," Sorenson says. "We don't yet know if they release different scents or other chemical signals that may also differentiate which portions of the plant are attractive to pollinators versus prey. That's one of the questions we plan to address moving forward."

Researchers also plan to investigate additional Venus flytrap sites to see if the plant relies on these same core pollinator species in other parts of its native range.

"We also want to learn more about the flytrap's pollination biology," says Rebecca Irwin, study co-author and a professor of applied ecology at NC State. "How much and what kind of nectar do they produce? How much pollen do they need to reproduce successfully?

"And we know that Venus flytraps need periodic fires in their native habitat in order to thrive, but how do these fire events - and their aftermath - affect the plant's reproductive success? There is still a lot to learn about these plants and their pollinators," Irwin says.

Read the paper: Venus Flytrap Rarely Traps Its Pollinators.

Article source: NC State.

Image credit: Elsa Youngsteadt

News

Giving seagrass its due

Seagrass meadows play a pivotal role in protecting coasts against rising sea levels.


Designing microbial communities to help plants battle nutritional stress

Plants and microbes engage in a diverse array of symbiotic relationships, but identifying the specific microbes or groups of microbes that contribute to plant health is extremely difficult. In work published in the open access journal PLOS Biology, researchers devised a general experimental scheme to identify and predict which small groups of bacterial species can help plants respond to phosphate starvation, a form of nutritional stress.


'Demographic compensation' may not save plants facing changing climate

An in-depth look at how plants respond to climate change shows mixed results for the phenomenon of "demographic compensation" as a way for plants to avoid severe population declines.