运动是药,还是运动加药?对 Na+、K+-ATPase 调节作用的比较。

IF 2.6 4区 医学 Q2 PHYSIOLOGY
J. Max Michel, Michael Kamal
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引用次数: 0

摘要

一个多世纪以来,科学家们已经知道骨骼肌高度依赖钠离子(Na+)和钾离子(K+),这两种离子的波动会改变肌纤维膜的极性并引发肌肉收缩(McKenna, Renaud, et al.)事实上,这些离子及其梯度非常重要,从高中到博士的生理学课程都会教授离子转运。Na+,K+-ATP酶(NKA)泵维持着这些离子梯度,与骨骼肌中的许多因素一样,它对运动和药物干预也有反应。在本期《实验生理学》杂志上,McKenna、Gong 等人(2024 年)试图利用这两种干预类型研究 NKA 泵的遗传调控。为此,他们在健康成年人休息和运动时为其提供地高辛,然后测量其骨骼肌中 NKA 异构体(α1-3 和 β1-3)mRNA 表达的相对变化。地高辛是一种口服药物,主要用于治疗心力衰竭和心房颤动,但也能抑制 NKA 活性并影响 NKA 相关基因的表达(Ren 等人,2021 年)。这项研究的结果表明,某些α和β亚基对运动普遍敏感(α1-3、β3),没有任何一个亚基对服用 DIG 有反应。有趣的是,当对同工酶表达进行总和和/或汇集时,可以观察到补充 DIG 会影响总 β 亚基 mRNA 的表达。但重要的是,在蛋白质水平上没有检测到 DIG 的影响,而α2 蛋白丰度在运动后 3 小时有所下降。在基线时,观察到 DIG 增加了总β亚基 mRNA,这与之前的一项调查(Sostaric 等人,2022 年)一致。α亚基没有发生变化可能是出乎意料的,因为这些亚基以前曾被证明会随着 DIG 的施用而上调或下调(Wang 等人,2000 年)。同样令人吃惊的是,虽然 DIG 对 β 亚基产生了一些影响,但运动对所有亚基的影响要明显得多。虽然人们对这方面的复合效应(如 DIG + 运动)的可能性感到兴奋,但 DIG 施用的其他意外效应(如自噬和细胞凋亡的增强)也具有机理上的合理性(Wang 等人,2000 年)。此外,虽然在适当的情况下激活这些分子途径不会造成危害,但外源性给药诱导的肌肉蛋白质分解途径(自噬)或细胞凋亡相关途径的激活可能会被证明是一种阻碍而非益处。因此,这需要在骨骼肌中进行进一步的研究,特别是在自噬和细胞凋亡相关途径受到额外监测的情况下,权衡同时服用 DIG 和运动对 NKA 基因和蛋白质调控的益处与单独运动的益处。不过,鉴于骨骼肌中 Na+ 和 K+ 离子调控相关知识的普及,麦肯纳等人的研究结果是新颖的,也是广大受众可以获得的。本文提供的信息表明,运动以及潜在的 DIG 给药会增强 NKA 转运体的基因表达,因此可能会增强 Na+ 和 K+ 离子的转运。这些发现扩展了目前与骨骼肌收缩有关的运动生理学知识库,因此对广大学生、生理学家和全科医生都有益处。两位作者均已阅读并批准了本手稿,并同意对工作的各个方面负责,确保与工作任何部分的准确性或完整性有关的问题得到适当的调查和解决。所有被指定为作者的人员均有资格成为作者,所有有资格成为作者的人员均已列名。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Exercise is medicine, or exercise with medicine? Comparative effects on Na+,K+-ATPase regulation

For over a century, scientists have known that skeletal muscle is highly reliant on sodium (Na+) and potassium (K+) ions, which fluctuate to change the polarity of the muscle fibre membrane and trigger muscle contractions (McKenna, Renaud, et al., 2024). These ions and their gradients are so critical, in fact, that ion transport is taught in physiology classes from the high school to the doctoral level. The Na+,K+-ATPase (NKA) pump maintains these ion gradients and, like many factors in skeletal muscle, is responsive to exercise and pharmacological intervention. In this issue of Experimental Physiology, McKenna, Gong, et al. (2024) sought to investigate the genetic regulation of the NKA pump using these two intervention types. To do this, they provided healthy adults with digoxin both at rest and in response to exercise, and then measured the relative change in NKA isoform (α1–3 and β1–3) mRNA expression within their skeletal muscle. Digoxin is an oral pharmaceutical that was primarily used to treat heart failure and atrial fibrillation, but is also capable of inhibiting NKA activity and affecting the expression of NKA-associated genes (Ren et al., 2021). The results of this study demonstrated that certain α and β subunits were generally sensitive to exercise (α1–3, β3) and that no individual subunit was responsive to DIG administration. Interestingly, when isoform expression was summed and/or pooled, it was observed that total β subunit mRNA expression was impacted by DIG supplementation. Critically, however, no effects of DIG were detected at the protein level, while α2 protein abundance declined at 3 h post-exercise.

The observed increase in total β subunit mRNA with DIG at baseline is consistent with a prior investigation (Sostaric et al., 2022). The lack of change in α subunits was perhaps unexpected, as these have been previously shown to be up- or down-regulated in response to DIG administration (Wang et al., 2000). It is also striking that while DIG conferred some effect to β subunits, the effects of exercise were much more pronounced throughout all subunits. Although there is certainly excitement about the possibility of a compounding effect in this regard (e.g. DIG + exercise), there is also mechanistic validity to other unintended effects of DIG administration such as enhanced autophagy and apoptosis (Wang et al., 2000). Additionally, while the activation of such molecular pathways is not harmful in the right context, activation of muscle protein breakdown pathways (autophagy) or apoptosis-related pathways induced by exogenous drug administration could prove to be more of a hindrance than a benefit. Therefore, this warrants further interrogation in skeletal muscle, specifically in the context of weighing benefits of concomitant administration of DIG with exercise versus benefits of exercise alone in NKA gene and protein regulation where autophagy and apoptosis-related pathways are additionally monitored.

Nonetheless, the findings observed by McKenna et al. are novel and accessible to a wide audience given the widespread knowledge pertaining to Na+ and K+ ion regulation in skeletal muscle. The information provided herein indicates that exercise, and potentially DIG administration, augments gene expression of NKA transporters and therefore can putatively enhance Na+ and K+ ion transport. These findings expand the current knowledge base of exercise physiology relating to skeletal muscle contraction, and therefore benefit a wide range of students, physiologists and general practitioners alike.

Both authors have read and approved the manuscript and agree to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved. All persons designated as authors qualify for authorship, and all those who qualify for authorship are listed.

None declared.

None.

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来源期刊
Experimental Physiology
Experimental Physiology 医学-生理学
CiteScore
5.10
自引率
3.70%
发文量
262
审稿时长
1 months
期刊介绍: Experimental Physiology publishes research papers that report novel insights into homeostatic and adaptive responses in health, as well as those that further our understanding of pathophysiological mechanisms in disease. We encourage papers that embrace the journal’s orientation of translation and integration, including studies of the adaptive responses to exercise, acute and chronic environmental stressors, growth and aging, and diseases where integrative homeostatic mechanisms play a key role in the response to and evolution of the disease process. Examples of such diseases include hypertension, heart failure, hypoxic lung disease, endocrine and neurological disorders. We are also keen to publish research that has a translational aspect or clinical application. Comparative physiology work that can be applied to aid the understanding human physiology is also encouraged. Manuscripts that report the use of bioinformatic, genomic, molecular, proteomic and cellular techniques to provide novel insights into integrative physiological and pathophysiological mechanisms are welcomed.
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