Priyanka N Bushana, Michelle A Schmidt, Michael J Rempe, Barbara A Sorg, Jonathan P Wisor
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引用次数: 0
摘要
非快速眼动睡眠(NREMS)伴随着脑葡萄糖利用率的降低。促成这种代谢变化可能是睡眠的一项核心功能。由于葡萄糖代谢的减少不可避免地伴随着涉及烟酰胺腺嘌呤二核苷酸(NAD)的下游氧化/还原反应的减速,我们假设 NAD 在生化水平上调节睡眠的动态平衡中发挥作用。我们采用了一种已知能改善小鼠神经系统结果测量的方案,即通过饮食摄入尼古丁酰胺核糖苷(NR)(一种 NAD 前体)。根据睡眠稳态数学模型(S 过程),长期(6-10 周)膳食补充 NR 可使小鼠在 NREMS 中度过的时间减少 17%,并加快睡眠需求的释放速度。这些研究结果表明,通过增加烟酰胺的供应量来提高氧化还原能力可以减少睡眠需求,并提高大脑皮层对高频振荡的能量需求能力。反过来,这项工作证明了氧化还原基质对与疲劳和睡眠驱动有关的大脑皮层电路特性的影响,从而表明氧化还原反应与整个睡眠-觉醒周期中大脑皮层网络事件的平衡动态有关。
Chronic dietary supplementation with nicotinamide riboside reduces sleep need in the laboratory mouse.
Non-rapid eye movement sleep (NREMS) is accompanied by a reduction in cerebral glucose utilization. Enabling this metabolic change may be a central function of sleep. Since the reduction in glucose metabolism is inevitably accompanied by deceleration of downstream oxidation/reduction reactions involving nicotinamide adenine dinucleotide (NAD), we hypothesized a role for NAD in regulating the homeostatic dynamics of sleep at the biochemical level. We applied dietary nicotinamide riboside (NR), a NAD precursor, in a protocol known to improve neurological outcome measures in mice. Long-term (6-10 weeks) dietary supplementation with NR reduced the time that mice spent in NREMS by 17 percent and accelerated the rate of discharge of sleep need according to a mathematical model of sleep homeostasis (Process S). These findings suggest that increasing redox capacity by increasing nicotinamide availability reduces sleep need and increases the cortical capacity for energetically demanding high-frequency oscillations. In turn, this work demonstrates the impact of redox substrates on cortical circuit properties related to fatigue and sleep drive, implicating redox reactions in the homeostatic dynamics of cortical network events across sleep-wake cycles.