Time-restricted feeding reveals a role for neural respiratory clocks in optimizing daily ventilatory-metabolic coupling in mice.

IF 4.2 2区医学 Q1 ENDOCRINOLOGY & METABOLISM

American journal of physiology. Endocrinology and metabolism Pub Date : 2024-07-01 Epub Date: 2024-06-05 DOI:10.1152/ajpendo.00111.2024

Aaron A Jones, Gabriella M Marino, Deanna M Arble

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引用次数: 0

Abstract

The master circadian clock, located in the suprachiasmatic nuclei (SCN), organizes the daily rhythm in minute ventilation (V̇e). However, the extent that the daily rhythm in V̇e is secondary to SCN-imposed O₂ and CO₂ cycles (i.e., metabolic rate) or driven by other clock mechanisms remains unknown. Here, we experimentally shifted metabolic rate using time-restricted feeding (without affecting light-induced synchronization of the SCN) to determine the influence of metabolic rate in orchestrating the daily V̇e rhythm. Mice eating predominantly at night exhibited robust daily rhythms in O₂ consumption (V̇o₂), CO₂ production (V̇co₂), and V̇e with similar peak times (approximately ZT18) that were consistent with SCN organization. However, feeding mice exclusively during the day separated the relative timing of metabolic and ventilatory rhythms, resulting in an approximately 8.5-h advance in V̇co₂ and a disruption of the V̇e rhythm, suggesting opposing circadian and metabolic influences on V̇e. To determine if the molecular clock of cells involved in the neural control of breathing contributes to the daily V̇e rhythm, we examined V̇e in mice lacking BMAL1 in Phox2b-expressing respiratory cells (i.e., BKOP mice). The ventilatory and metabolic rhythms of predominantly night-fed BKOP mice did not differ from wild-type mice. However, in contrast to wild-type mice, exclusive day feeding of BKOP mice led to an unfettered daily V̇e rhythm with a peak time aligning closely with the daily V̇co₂ rhythm. Taken together, these results indicate that both daily V̇co₂ changes and intrinsic circadian time-keeping within Phox2b respiratory cells are predominant orchestrators of the daily rhythm in ventilation.NEW & NOTEWORTHY The master circadian clock organizes the daily rhythm in ventilation; however, the extent that this rhythm is driven by SCN regulation of metabolic rate versus other clock mechanisms remains unknown. We report that metabolic rate alone is insufficient to explain the daily oscillation in ventilation and that neural respiratory clocks within Phox2b-expressing cells additionally optimize breathing. Collectively, these findings advance our mechanistic understanding of the circadian rhythm in ventilatory control.

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限时喂食揭示了神经呼吸钟在优化小鼠每日通气-代谢耦合中的作用。

昼夜节律主时钟位于嗜铬细胞上核（SCN），负责组织每分钟通气量（VE）的日节律。然而，通气量的日节律在多大程度上继发于 SCN 施加的氧气和二氧化碳周期（即新陈代谢率），或由其他时钟机制驱动，仍是未知数。在此，我们通过实验，在不影响光诱导的 SCN 同步的情况下，使用限时喂食改变代谢率，以确定代谢率在协调 VE 日节律中的影响。主要在夜间进食的小鼠在氧气消耗量（VO2）、二氧化碳产生量（VCO2）和VE方面表现出与SCN组织相一致的、具有相似峰值时间（~ZT18）的强健日节律。然而，只在白天喂养小鼠会分离新陈代谢和通气节律的相对时间，导致 VCO2 提前约 8.5 小时，VE 节律被打乱，这表明昼夜节律和新陈代谢对 VE 的影响是相反的。为了确定参与呼吸神经控制的细胞的分子钟是否对每天的 VE 节律起作用，我们研究了在表达 Phox2b 的呼吸细胞中缺乏 BMAL1 的小鼠（即 BKOP 小鼠）的 VE。主要在夜间进食的 BKOP 小鼠的通气和代谢节律与野生型小鼠没有差异。然而，与野生型小鼠不同的是，BKOP 小鼠只在白天进食会导致不受约束的每日 VE 节律，其峰值时间与每日 VCO2 节律密切吻合。综上所述，这些结果表明，Phox2b 呼吸细胞内的每日 VCO2 变化和内在昼夜节律计时是通气每日节律的主要协调者。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

American journal of physiology. Endocrinology and metabolism 医学-内分泌学与代谢

CiteScore

9.80

自引率

0.00%

发文量

审稿时长

1 months

期刊介绍： The American Journal of Physiology-Endocrinology and Metabolism publishes original, mechanistic studies on the physiology of endocrine and metabolic systems. Physiological, cellular, and molecular studies in whole animals or humans will be considered. Specific themes include, but are not limited to, mechanisms of hormone and growth factor action; hormonal and nutritional regulation of metabolism, inflammation, microbiome and energy balance; integrative organ cross talk; paracrine and autocrine control of endocrine cells; function and activation of hormone receptors; endocrine or metabolic control of channels, transporters, and membrane function; temporal analysis of hormone secretion and metabolism; and mathematical/kinetic modeling of metabolism. Novel molecular, immunological, or biophysical studies of hormone action are also welcome.