February 11, 2010
Mother Bats Expert At Saving Energy
New study shows wild female bats' temperature regulation strategy is flexible
In order to regulate their body temperature as efficiently as possible, wild female bats switch between two strategies depending on both the ambient temperature and their reproductive status. During pregnancy and lactation, they profit energetically from clustering when temperatures drop. Once they have finished lactating, they use torpor* to a greater extent, to slow their metabolic rate and drop their body temperature right down so that they expend as little energy as possible. These findings by Iris Pretzlaff, from the University of Hamburg in Germany, and colleagues, were just published online in Springer's journal Naturwissenschaften "“ The Science of Nature.
Pretzlaff and team investigated, for the first time in the wild, the thermoregulation strategies used by communally roosting Bechstein's bats during different periods of their reproductive cycle "“ pre-lactation, lactation, and post-lactation. They collected data from two maternity colonies roosting in deciduous forests near Wrzburg in Germany, predominantly in bat boxes. The authors measured ambient temperature over those three periods as well as the bats' metabolic rate by using respirometry (measuring the rate of oxygen consumption).
They found that the bats' metabolic rate was strongly influenced by the ambient temperature. However, by roosting in groups (social thermoregulation), the bats were able to regulate their body temperature more effectively, despite changes in daily ambient temperature.
The bats also used torpor to minimize energy expenditure, particularly post-lactation - more than twice as often than during the other two periods. This suggests that they predominantly use torpor once they can afford to do so without compromising offspring development and milk production. They also formed much smaller groups post-lactation when temperatures were lower because roosting in smaller groups reduces the risk of disturbances by conspecifics. This resulted in longer torpor bouts and therefore longer periods of energy saving.
The authors conclude: "We were able to demonstrate on wild Bechstein's bats, during different reproductive periods, the significance of behavioral and physiological flexibility for optimal thermoregulatory behavior. Our study also highlights the importance of field studies, where the animals can use their behavioral and physiological repertoire, which is often not possible under the generally more controlled regimes in laboratory studies."
Reference: Pretzlaff I et al (2010). Communally breeding bats use physiological and behavioral adjustments to optimize daily energy expenditure. Naturwissenschaften. DOI 10.1007/s00114-010-0647-1
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