Endogenous muscarinic acetylcholine receptor signaling blunts α₁-adrenergic vasoconstriction during higher-intensity handgrip exercise in humans.

IF 2.2 3区医学 Q3 PHYSIOLOGY

American journal of physiology. Regulatory, integrative and comparative physiology Pub Date : 2025-06-01 Epub Date: 2025-04-16 DOI:10.1152/ajpregu.00305.2024

Janée D Terwoord, Frank A Dinenno, Jennifer C Richards, Christopher M Hearon

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引用次数: 0

Abstract

Muscarinic acetylcholine receptors (mAChRs) are expressed ubiquitously in the human skeletal muscle vasculature. Prior studies have been unable to identify a contribution of mAChR signaling to exercise-mediated vasodilation; however, no studies have determined whether endogenous mAChR signaling regulates the ability of contracting skeletal muscle to attenuate sympathetic vasoconstriction, a phenomenon called "functional sympatholysis." We tested the hypothesis that endogenous mAChR signaling contributes to functional sympatholysis in humans. In healthy volunteers (8 F, 8 M; 26 ± 5 yr), changes in forearm vascular conductance (ΔFVC) were calculated in response to intra-arterial infusions of phenylephrine (PE; α₁-agonist) during 1) infusion of a "nonmetabolic" vasodilator at rest (rest; adenosine or sodium nitroprusside), 2) dynamic handgrip exercise at 15% maximal voluntary contraction (MVC), and 3) higher-intensity exercise (25% MVC). Conditions were completed before and after intra-arterial infusion of atropine (mAChR antagonist). Under control conditions, vasoconstriction to PE was limited in parallel with exercise intensity (PE-induced %ΔFVC, rest: -40 ± 13%, 15% MVC: -20 ± 7%, 25% MVC: -12 ± 8%; P < 0.0001). There was no effect of atropine on PE vasoconstriction during rest (-38 ± 12%; P = 0.60 vs. control) or 15% MVC exercise (-23 ± 7%, P = 0.34 vs. control). However, PE-mediated vasoconstriction was approximately twofold greater during 25% MVC exercise after blockade of mAChRs (-22 ± 9%, P < 0.001 vs. control). These results provide evidence of a novel physiological role of endogenous mAChR signaling as a modulator of α₁-adrenergic vasoconstriction during higher-intensity handgrip exercise in humans.NEW & NOTEWORTHY The present study demonstrates that muscarinic acetylcholine receptor (mAChR) signaling attenuates postjunctional α₁-adrenergic signaling during higher-intensity exercise specifically within contracting skeletal muscle, thereby revealing endogenous mAChR signaling as a potential mechanism of functional sympatholysis. This is the first study to identify an endogenous signaling pathway that selectively modulates α₁-adrenergic vasoconstriction specifically in contracting muscle in humans. These findings establish a novel physiological role for endogenous mAChR signaling in the regulation of muscle blood flow during exercise.

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内源性毒蕈碱乙酰胆碱受体信号在人类高强度握力运动中减弱α1-肾上腺素能血管收缩。

毒蕈碱乙酰胆碱受体（mAChRs）在人体骨骼肌血管系统中普遍表达。先前的研究无法确定mAChR信号对运动介导的血管舒张的贡献；然而，没有研究确定内源性mAChR信号是否调节骨骼肌收缩的能力，以减轻交感血管收缩，这种现象被称为“功能性交感神经溶解”。我们测试了内源性mAChR信号有助于人类功能性交感神经溶解的假设。健康志愿者(8名F， 8名M；26±5年)，计算动脉内输注苯肾上腺素(PE；1)静息时输注“非代谢性”血管扩张剂(静息；（腺苷或硝普钠），2)15%最大自愿收缩（MVC）的动态握力运动，以及3)更高强度的运动（25% MVC）。在动脉输注阿托品（mAChR拮抗剂）之前和之后完成条件。在对照条件下，PE血管收缩与运动强度平行受限(PE诱导%ΔFVC，休息：-40±13%，15% MVC: -20±7%,25% MVC: -12±8%；P < 0.0001)。休息时阿托品对PE血管收缩无影响(-38±12%；P = 0.60 vs对照组)或15% MVC练习（-23±7%,P = 0.34 vs对照组）。然而，在阻断mAChRs后，25% MVC运动中pe介导的血管收缩大约是对照组的两倍（-22±9%,P < 0.001）。这些结果为内源性mAChR信号在人类高强度握力运动中作为α1-肾上腺素能血管收缩调节剂的新生理作用提供了证据。本研究表明，在高强度运动中，特别是在收缩的骨骼肌中，毒瘤碱乙酰胆碱受体（mAChR）信号通路减弱了突触后α - 1-肾上腺素能信号通路，从而揭示了内源性mAChR信号通路作为功能性交感神经解的潜在机制。这是第一个确定内源性信号通路选择性调节α1-肾上腺素能血管收缩的研究，特别是在人类收缩肌肉中。这些发现确立了内源性mAChR信号在运动过程中调节肌肉血流中的新生理作用。

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来源期刊

American journal of physiology. Regulatory, integrative and comparative physiology 医学-生理学

CiteScore

5.30

自引率

3.60%

发文量

145

审稿时长

2 months

期刊介绍： The American Journal of Physiology-Regulatory, Integrative and Comparative Physiology publishes original investigations that illuminate normal or abnormal regulation and integration of physiological mechanisms at all levels of biological organization, ranging from molecules to humans, including clinical investigations. Major areas of emphasis include regulation in genetically modified animals; model organisms; development and tissue plasticity; neurohumoral control of circulation and hypertension; local control of circulation; cardiac and renal integration; thirst and volume, electrolyte homeostasis; glucose homeostasis and energy balance; appetite and obesity; inflammation and cytokines; integrative physiology of pregnancy-parturition-lactation; and thermoregulation and adaptations to exercise and environmental stress.