Effect of sleep loss on executive function and plasma corticosterone levels in an arctic-breeding songbird, the Lapland longspur (Calcarius lapponicus)

Sleep is a fundamental component of vertebrate life, although its exact functions remain unclear. Animals deprived of sleep typically show reduced neurobiological performance, health, and in some cases, survival. However, a number of vertebrate taxa exhibit adaptations that permit normal activities...

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Bibliographic Details
Published in:Hormones and behavior 2020-06, Vol.122, p.104764-104764, Article 104764
Main Authors: Hodinka, Brett L., Ashley, Noah T.
Format: Article
Language:English
Subjects:
Animals
Arctic Regions
Corticosterone
Corticosterone - blood
Executive function
Executive Function - physiology
Female
Lapland longspur
Male
Memory
Passeriformes - blood
Passeriformes - physiology
Reproduction - physiology
Seasons
Sleep - physiology
Sleep Deprivation - blood
Sleep Deprivation - physiopathology
Sleep Deprivation - psychology
Sleep Deprivation - veterinary
Sleep loss
Songbirds - blood
Songbirds - physiology
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Summary:Sleep is a fundamental component of vertebrate life, although its exact functions remain unclear. Animals deprived of sleep typically show reduced neurobiological performance, health, and in some cases, survival. However, a number of vertebrate taxa exhibit adaptations that permit normal activities even when sleep is reduced. Lapland longspurs (Calcarius lapponicus), arctic-breeding passerine birds, exhibit around-the-clock activity during their short breeding season, with an inactive period of ca. 4 h/day. Whether behavioral or physiological costs occur from sleep loss (SL) in this species is unknown. To assess the effects of SL, wild-caught male longspurs were placed in captivity (12L:12D) and trained for one month to successfully learn color association and spatial memory tasks. Birds were then placed in automated sleep fragmentation cages that utilize a moving wire to force movement every 1 min (60 arousals/h) during 12D (inactive period) or control conditions (during 12L; active period). After SL (or control) treatment, birds were presented with color association and spatial memory tasks a final time to assess executive function. Baseline plasma corticosterone concentration, body mass, and satiety were also measured. SL significantly elevated corticosterone levels and increased accuracy during color association recall but did not affect the overall time required to complete the task. SL had no effect upon spatial memory, body mass, or satiety. Taken together, these results suggest that Lapland longspurs exhibit a degree of behavioral, but not physiological, insensitivity to acute SL. Whether elevated plasma concentrations of corticosterone play a direct role in ameliorating cognitive deficits from SL require additional study. •Sleep fragmentation significantly elevated corticosterone levels.•Color association test accuracy was significantly greater in treatment individuals.•No effect of treatment on color association test completion time.•No effect of treatment on spatial learning test, body mass, or satiety.•Longspurs exhibited behavioral, but not physiological, resilience to sleep loss.
ISSN:0018-506X
1095-6867
DOI:10.1016/j.yhbeh.2020.104764