Abstract
SynopsisLittle is known about how songbirds modulate sleep during migratory periods. Due to the alternation of nocturnal endurance flights and diurnal refueling stopovers, sleep is likely to be a major constraint for many migratory passerine species. Sleep may help to increase the endogenous antioxidant capacity that counteracts free radicals produced during endurance flight and reduces energy expenditure. Here, we investigated the relationship between sleep behavior, food intake, and two markers of physiological condition—the amount of energy reserves and oxidative status—in two migratory songbird species, the garden warbler (Sylvia borin) and the whitethroat (Sylvia communis). In garden warblers, birds with high energy stores were more prone to sleep during the day, while this condition-dependent sleep pattern was not present in whitethroats. In both species, birds with low energy stores were more likely to sleep with their head tucked in the feathers during nocturnal sleep. Moreover, we found a positive correlation between food intake and the extent of energy reserves in garden warblers, but not in whitethroats. Finally, we did not find significant correlations between oxidative status and sleep, or oxidative status and energy stores. Despite our study was not comparative, it suggests that different species might use different strategies to manage their energy during stopover and, additionally, it raises the possibility that migrants have evolved physiological adaptations to deal with oxidative damage produced during migration.
Highlights
Twice a year, thousands of migratory bird species cover huge distances between their wintering and breeding grounds
We investigated the relationship between oxidative status, energy stores, food intake, and sleep in two migratory songbird species, the garden warbler and the whitethroat (Sylvia communis), at a Mediterranean stopover site during spring migration
In garden warblers and whitethroats we found no significant relationship between condition and either dROMs (LM: garden warbler, adjusted R21⁄4À0.016, condition: P 1⁄4 0.874; whitethroat, adjusted R21⁄4À0.001, condition: P 1⁄4 0.324) or antioxidant capacity (AOX) (LM: garden warbler, adjusted R21⁄40.008, condition: P 1⁄4 0.229; whitethroat, adjusted R2 1⁄4 0.011, condition: P 1⁄4 0.211) at capture (Fig. 1)
Summary
Thousands of migratory bird species cover huge distances between their wintering and breeding grounds. Migration is one of the most intense energy demanding life history stages, during which the highest mortality occurs (Sillett and Holmes 2002; Alerstam et al 2003) It is often associated with drastic physiological and behavioral changes other than the rapid gain and loss of energy stores. One group of molecules that might require clearance are the so-called reactive oxygen species (ROS) (Reimund 1994), atoms, or molecules with an unpaired electron Given their chemical nature, these metabolites are highly reactive with biological molecules (i.e., proteins, lipids, and DNA) and can cause serious damage to the organism (Kregel and Zhang 2007; Cooper-Mullin and McWilliams 2016; Skrip and McWilliams 2016). Allocates energy to, an antioxidant defense for the whole organism, it should be responsive to circulating ROS and may influence the oxidative status of the organism
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