Cairns Simeon P, Renaud Jean-Marc
SPRINZ, School of Sport and Recreation, Faculty of Health and Environmental Sciences, Auckland University of Technology, New Zealand.
Health and Rehabilitation Research Institute, Faculty of Health and Environmental Sciences, Auckland University of Technology, New Zealand.
J Physiol. 2023 Dec;601(24):5669-5687. doi: 10.1113/JP285129. Epub 2023 Nov 7.
A reduced muscle glycogen content and potassium (K ) disturbances across muscle membranes occur concomitantly during repeated intense exercise and together may contribute to skeletal muscle fatigue. Therefore, we examined whether raised extracellular K concentration ([K ] ) (4 to 11 mM) interacts with lowered glycogen to reduce force production. Isometric contractions were evoked in isolated mouse soleus muscles (37°C) using direct supramaximal field stimulation. (1) Glycogen declined markedly in non-fatigued muscle with >2 h exposure in glucose-free physiological saline compared with control solutions (11 mM glucose), i.e. to <45% control. (2) Severe glycogen depletion was associated with increased 5'-AMP-activated protein kinase activity, indicative of metabolic stress. (3) The decline of peak tetanic force at 11 mM [K ] was exacerbated from 67% initial at normal glycogen to 22% initial at lowered glycogen. This was due to a higher percentage of inexcitable fibres (71% vs. 43%), yet without greater sarcolemmal depolarisation or smaller amplitude action potentials. (4) Returning glucose while at 11 mM [K ] increased both glycogen and force. (5) Exposure to 4 mM [K ] glucose-free solutions (15 min) did not increase fatiguability during repeated tetani; however, after recovery there was a greater force decline at 11 mM [K ] at lower than normal glycogen. (6) An important exponential relationship was established between relative peak tetanic force at 11 mM [K ] and muscle glycogen content. These findings provide direct evidence of a synergistic interaction between raised [K ] and lowered muscle glycogen as the latter shifts the peak tetanic force-resting E relationship towards more negative resting E due to lowered sarcolemmal excitability, which hence may contribute to muscle fatigue. KEY POINTS: Diminished muscle glycogen levels and raised extracellular potassium concentrations ([K ] ) occur simultaneously during intense exercise and together may contribute to muscle fatigue. Prolonged exposure of isolated non-fatigued soleus muscles of mice to glucose-free physiological saline solutions markedly lowered muscle glycogen levels, as does fatigue then recovery in glucose-free solutions. For both approaches, the subsequent decline of maximal force at 11 mM [K ] , which mimics interstitial [K ] levels during intense exercise, was exacerbated at lowered compared with normal glycogen. This was mainly due to many more muscle fibres becoming inexcitable. We established an important relationship that provides evidence of a synergistic interaction between raised [K ] and lowered glycogen content to reduce force production. This paper indicates that partially lowered muscle glycogen (and/or metabolic stress) together with elevated interstitial [K ] interactively lowers muscle force, and hence may diminish performance especially during repeated high-intensity exercise.
在反复进行的高强度运动过程中,肌肉糖原含量降低和跨肌膜的钾(K⁺)紊乱同时出现,二者共同作用可能导致骨骼肌疲劳。因此,我们研究了细胞外钾浓度([K⁺])升高(4至11 mM)与糖原水平降低之间是否相互作用,从而降低力量产生。在37°C条件下,使用直接超强电场刺激,诱发分离的小鼠比目鱼肌进行等长收缩。(1)与对照溶液(11 mM葡萄糖)相比,在无葡萄糖的生理盐水中暴露超过2小时,非疲劳肌肉中的糖原显著下降,即降至对照水平的<45%。(2)严重的糖原耗竭与5'-AMP激活的蛋白激酶活性增加有关,这表明存在代谢应激。(3)在[K⁺]为11 mM时,强直收缩峰值力的下降在糖原正常时从初始的67%加剧至糖原降低时的初始的22%。这是由于不可兴奋纤维的比例更高(71%对43%),但肌膜去极化程度并未增加,动作电位幅度也未减小。(4)在[K⁺]为11 mM时恢复葡萄糖供应,糖原和力量均增加。(5)暴露于4 mM [K⁺]的无葡萄糖溶液中15分钟,在反复强直收缩期间并未增加疲劳性;然而,恢复后,在[K⁺]为11 mM且糖原低于正常水平时,力量下降幅度更大。(6)在[K⁺]为11 mM时的相对强直收缩峰值力与肌肉糖原含量之间建立了重要的指数关系。这些发现提供了直接证据,表明[K⁺]升高与肌肉糖原降低之间存在协同相互作用,因为后者由于肌膜兴奋性降低,使强直收缩峰值力-静息电位关系向更负的静息电位偏移,从而可能导致肌肉疲劳。关键点:在剧烈运动期间,肌肉糖原水平降低和细胞外钾浓度([K⁺])升高同时发生,二者共同作用可能导致肌肉疲劳。将分离的小鼠非疲劳比目鱼肌长时间暴露于无葡萄糖的生理盐溶液中,可显著降低肌肉糖原水平,在无葡萄糖溶液中疲劳然后恢复也会如此。对于这两种方法,在[K⁺]为11 mM(模拟剧烈运动期间的间质[K⁺]水平)时,随后最大力量的下降在糖原降低时比正常糖原时更严重。这主要是由于更多的肌纤维变得不可兴奋。我们建立了一种重要关系,为[K⁺]升高与糖原含量降低之间的协同相互作用提供了证据,这种相互作用会降低力量产生。本文表明,部分降低的肌肉糖原(和/或代谢应激)与升高的间质[K⁺]相互作用,会降低肌肉力量,因此可能会降低运动表现,尤其是在反复进行的高强度运动期间。
