Bees exposed to a neonicotinoid pesticide fly only a third of the distance that unexposed bees are able to achieve.
Flight behaviour is crucial for determining how bees forage, so reduced flight performance from pesticide exposure could lead to colonies going hungry and pollination services being impacted.
Foraging bees are essential pollinators for the crops we eat and the wildflowers in our countryside, gardens and parks. Any factor compromising bee flight performance could therefore impact this pollination service.
Exposure to neonicotinoids may provide a hyperactive ‘buzz’ but ultimately impair individual endurance. Daniel Kenna
A study by Imperial College London researchers, published today in the journal Ecology and Evolution, reveals how exposure to a common class of neurotoxic pesticide, a neonicotinoid, reduces individual flight endurance (distance and duration) in bumblebees.
The study shows that bees exposed to the neonicotinoid imidacloprid in doses they would encounter in fields fly significantly shorter distances and for less time than bees not exposed, which could reduce the area in which colonies can forage for food by up to 80 percent.
Intriguingly, exposed bees seemed to enter a hyperactive-like state in which they initially flew faster than unexposed bees and therefore may have ‘worn themselves out’.
The Tortoise and the Hare
First author of the study Daniel Kenna, from the Department of Life Sciences at Imperial, said: “Neonicotinoids are similar to nicotine in the way they stimulate neurons, and so a ‘rush’ or hyperactive burst of activity does make sense. However, our results suggest there may be a cost to this initial rapid flight, potentially through increased energy expenditure or a lack of motivation, in the form of reduced flight endurance.
“Our findings take on an interesting parallel to the story of the ‘Tortoise and the Hare’. As the famous fable states, ‘slow and steady wins the race’. Little did Aesop know that this motto may be true for bumblebees in agricultural landscapes. Just like the Hare, being speedier does not always mean you reach your goal quicker, and in the case of bumblebees, exposure to neonicotinoids may provide a hyperactive ‘buzz’ but ultimately impair individual endurance.”
The team tested the bees’ flight using an experimental ‘flight mill’ – a spinning apparatus with long arms connected to magnets. The bees had a small metal disc attached to their backs, which allowed the researchers to attach bees temporarily to the magnetic arm. As the bees flew in circles, the team were able to accurately measure how far they flew and how fast under a controlled environment.
Limiting the foraging area
Not only could this reduce the abundance, diversity, and nutritional quality of food available to a colony affecting its development, but it could also limit the pollination service bees provide. Dr Richard Gill
Lead author Dr Richard Gill, also from the Department of Life Sciences at Imperial, commented: “Previous studies from our group and others have shown that bee foragers exposed to neonicotinoid pesticides bring back less food to the colony. Our study on flight performance under pesticide exposure provides a potential mechanism to explain these findings.
“The negative effects of pesticide exposure on flight endurance have the potential to reduce the area that colonies can forage for food. Exposed foraging bees may find themselves unable to reach previously accessible resources, or incapable of returning to the nest following exposure to contaminated flowers.
“Not only could this reduce the abundance, diversity, and nutritional quality of food available to a colony affecting its development, but it could also limit the pollination service bees provide.”
‘Pesticide exposure affects flight dynamics and reduces flight endurance in bumblebees’ by Daniel Kenna, Hazel Cooley, Ilaria Pretelli, Ana Ramos Rodrigues, Steve D. Gill, Richard J. Gill is published in Ecology and Evolution.
Article text (excluding photos or graphics) © Imperial College London.
Photos and graphics subject to third party copyright used with permission or © Imperial College London.
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