We investigated whether glucocorticoids [i.e., corticosterone (Cort) in rats] released during sleep deprivation (SD) affect regional brain glycogen stores in 34-day-old Long-Evans rats. Adrenalectomized (with Cort replacement; Adxϩ) and intact animals were sleep deprived for 6 h beginning at lights on and then immediately killed by microwave irradiation. Brain and liver glycogen and glucose and plasma glucose levels were measured. After SD in intact animals, glycogen levels decreased in the cerebellum and hippocampus but not in the cortex or brain stem. By contrast, glycogen levels in the cortex of Adxϩ rats increased by 43% (P Ͻ 0.001) after SD, while other regions were unaffected. Also in Adxϩ animals, glucose levels were decreased by an average of 28% throughout the brain after SD. Intact sleep-deprived rats had elevations of circulating Cort, blood, and liver glucose that were absent in intact control and Adxϩ animals. Different responses between brain structures after SD may be due to regional variability in metabolic rate or glycogen metabolism. Our findings suggest that the elevated glucocorticoid secretion during SD causes brain glycogenolysis in response to energy demands. sleep homeostasis; corticosterone; blood glucose; liver glycogen and glucose; glycogen metabolism THE DRIVE TO SLEEP is tightly regulated. Homeostatic sleep regulation increases subsequent sleep intensity and/or duration after periods of wakefulness. One physiological marker of homeostasis is reflected in the proportional relationship between the intensity of EEG slow-wave activity (SWA; in the delta power range 0.5-4.0 Hz) during non-rapid eye movement (NREM) sleep and the amount of prior wakefulness (5, 12). There is evidence that this homeostatic regulation is mediated by adenosine (reviewed in Refs. 3, 34). The release of adenosine is thought to modulate SWA intensity as a function of sleep need in response to decreases in metabolic supply (3). According to this hypothesis, a progressive depletion of glycogen stores during wakefulness causes transient decreases in cellular energy charge, resulting in increased adenosine. The function of sleep, therefore, would be to replenish brain glycogen stores during NREM sleep when glycogen synthesis would prevail.Glycogen stores, the largest energy reserve in the brain, are regulated by glycogen phosphorylase and glycogen synthase. Increased levels of cAMP activate glycogenolysis and inhibit glycogen synthesis. Increased neuronal activity enhances glycogen turnover (reviewed in Ref. 48), whereas reduced activity increases glycogen levels (8,23,28,41). Excitatory neurotransmitters such as norepinephrine, serotonin, and histamine, released maximally during waking hours, potentiate glycogenolysis. In the brain, glycogen can be mobilized locally and rapidly in response to energy deficits (reviewed in Ref. 11) and normal physiological conditions (e.g., sensory stimulation; Refs. 27, 43).Recent studies have explored the relationship between brain glycogen and sleep by measuring glycogen (14,16,25...
