The Molecular Circadian Clock of Phox2b-expressing Cells Drives Daily Variation of the Hypoxic but Not Hypercapnic Ventilatory Response in Mice.

IF 5.1 Q2 CELL BIOLOGY Function (Oxford, England) Pub Date : 2023-01-01 DOI:10.1093/function/zqad023
Aaron A Jones, Gabriella M Marino, Allison R Spears, Deanna M Arble
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引用次数: 1

Abstract

While the suprachiasmatic nucleus (SCN) controls 24-h rhythms in breathing, including minute ventilation (VE), the mechanisms by which the SCN drives these daily changes are not well understood. Moreover, the extent to which the circadian clock regulates hypercapnic and hypoxic ventilatory chemoreflexes is unknown. We hypothesized that the SCN regulates daily breathing and chemoreflex rhythms by synchronizing the molecular circadian clock of cells. We used whole-body plethysmography to assess ventilatory function in transgenic BMAL1 knockout (KO) mice to determine the role of the molecular clock in regulating daily rhythms in ventilation and chemoreflex. Unlike their wild-type littermates, BMAL1 KO mice exhibited a blunted daily rhythm in VE and failed to demonstrate daily variation in the hypoxic ventilatory response (HVR) or hypercapnic ventilatory response (HCVR). To determine if the observed phenotype was mediated by the molecular clock of key respiratory cells, we then assessed ventilatory rhythms in BMAL1fl/fl; Phox2bCre/+ mice, which lack BMAL1 in all Phox2b-expressing chemoreceptor cells (hereafter called BKOP). BKOP mice lacked daily variation in HVR, similar to BMAL1 KO mice. However, unlike BMAL1 KO mice, BKOP mice exhibited circadian variations in VE and HCVR comparable to controls. These data indicate that the SCN regulates daily rhythms in VE, HVR, and HCVR, in part, through the synchronization of the molecular clock. Moreover, the molecular clock of Phox2b-expressing cells is specifically necessary for daily variation in the hypoxic chemoreflex. These findings suggest that disruption of circadian biology may undermine respiratory homeostasis, which, in turn, may have clinical implications for respiratory disease.

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表达phox2b细胞的分子昼夜节律钟驱动小鼠缺氧而非高碳酸通气反应的日常变化。
虽然视交叉上核(SCN)控制着24小时的呼吸节奏,包括分钟通气(VE),但SCN驱动这些日常变化的机制尚不清楚。此外,生物钟调节高碳酸血症和低氧通气化学反射的程度尚不清楚。我们假设SCN通过同步细胞的分子生物钟来调节日常呼吸和化学反射节律。我们使用全身容积描记术评估转基因BMAL1基因敲除(KO)小鼠的通气功能,以确定分子钟在调节通气和化学反射的日常节律中的作用。与野生型小鼠不同,BMAL1 KO小鼠在VE中表现出迟钝的日常节律,并且在低氧通气反应(HVR)或高碳酸通气反应(HCVR)中没有表现出日常变化。为了确定观察到的表型是否由关键呼吸细胞的分子钟介导,我们随后评估了BMAL1fl/fl的通气节律;Phox2bCre/+小鼠,在所有表达phox2b的化学受体细胞(以下称为BKOP)中缺乏BMAL1。与BMAL1 KO小鼠类似,BKOP小鼠的HVR缺乏日常变化。然而,与BMAL1 KO小鼠不同,BKOP小鼠在VE和HCVR方面表现出与对照组相当的昼夜变化。这些数据表明,SCN在一定程度上通过分子时钟的同步调节VE、HVR和HCVR的日常节律。此外,phox2b表达细胞的分子钟对于缺氧化学反射的日常变化是特别必要的。这些发现表明,昼夜节律生物学的破坏可能破坏呼吸稳态,这反过来可能对呼吸系统疾病具有临床意义。
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来源期刊
CiteScore
5.70
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0.00%
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审稿时长
3 weeks
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