The metabolic cost of flight and aerobic efficiency in the rose chafer, Protaetia cuprea (Cetoniinae)

Abstract

Rose chafer beetles (Protetia cuprea) are pollinators as well as agricultural pests, flying between flowers and trees while foraging for pollen and fruits. Calculating the energy they expend on flying during foraging activity faces the challenge of measuring the metabolic rate (MR) of free-flying insects in an open space. We overcame this challenge by using the bolus injection of 13C Na-bicarbonate technique to measure their metabolic energy expenditure while flying in a large flight arena. Concurrently, we tracked the insects with high-speed cameras to extract their flight trajectory, from which we calculated the mechanical power invested in flying for each flight bout. We found that the chemical (metabolic) energy input converted to mechanical flight energy output at a mean efficiency of 10.4 ± 5.2 %, with a trend of increased efficiency in larger conspecifics (efficiency scaled with body mass to the power of 1.4). The transition during summer from a diet of pollen to that of fruits may affect the energy budget available for foraging. Starved P. cuprea, feeding on apples ad libitum, increased their body mass by an average of 6% in two hours. According to our calculations such a meal can power a 630-meter flight (assuming a carbohydrate assimilation efficiency of 90%). The high cost of aerial locomotion is inherent to the foraging behaviour of rose chafers, explaining their short flight bouts followed by prolonged feeding activity. The ability to measure both flight and its energetic cost is crucial for obtaining realistic estimates for the cost of locomotion.