Phosphoproteomics Uncovers Exercise Intensity-Specific Skeletal Muscle Signaling Networks Underlying High-Intensity Interval Training in Healthy Male Participants

IF 9.4 1区医学 Q1 SPORT SCIENCES Sports Medicine Pub Date : 2025-04-21 DOI:10.1007/s40279-025-02217-2

Nolan J. Hoffman, Jamie Whitfield, Di Xiao, Bridget E. Radford, Veronika Suni, Ronnie Blazev, Pengyi Yang, Benjamin L. Parker, John A. Hawley

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Abstract

Background

In response to exercise, protein kinases and signaling networks are engaged to blunt homeostatic threats generated by acute contraction-induced increases in skeletal muscle energy and oxygen demand, as well as serving roles in the adaptive response to chronic exercise training to blunt future disruptions to homeostasis. High-intensity interval training (HIIT) is a time-efficient exercise modality that induces superior or similar health-promoting skeletal muscle and whole-body adaptations compared with prolonged, moderate-intensity continuous training (MICT). However, the skeletal muscle signaling pathways underlying HIIT’s exercise intensity-specific adaptive responses are unknown.

Objective

We mapped human muscle kinases, substrates, and signaling pathways activated/deactivated by an acute bout of HIIT versus work-matched MICT.

Methods

In a randomized crossover trial design (Australian New Zealand Clinical Trials Registry number ACTRN12619000819123; prospectively registered 6 June 2019), ten healthy male participants (age 25.4 ± 3.2 years; BMI 23.5 ± 1.6 kg/m²; \(\dot{V}{\text{O}}_{2} \max\) 37.9 ± 5.2 ml/kg/min, mean values ± SD) completed a single bout of HIIT and MICT cycling separated by ≥ 10 days and matched for total work (67.9 ± 10.2 kJ) and duration (10 min). Mass spectrometry-based phosphoproteomic analysis of muscle biopsy samples collected before, during (5 min), and immediately following (10 min) each exercise bout, to map acute temporal signaling responses to HIIT and MICT, identified and quantified 14,931 total phosphopeptides, corresponding to 8509 phosphorylation sites.

Results

Bioinformatic analyses uncovered exercise intensity-specific signaling networks, including > 1000 differentially phosphorylated sites (± 1.5-fold change; adjusted P < 0.05; ≥ 3 participants) after 5 min and 10 min HIIT and/or MICT relative to rest. After 5 and 10 min, 92 and 348 sites were differentially phosphorylated by HIIT, respectively, versus MICT. Plasma lactate concentrations throughout HIIT were higher than MICT (P < 0.05), and correlation analyses identified > 3000 phosphosites significantly correlated with lactate (q < 0.05) including top functional phosphosites underlying metabolic regulation.

Conclusions

Collectively, this first global map of the work-matched HIIT versus MICT signaling networks has revealed rapid exercise intensity-specific regulation of kinases, substrates, and pathways in human skeletal muscle that may contribute to HIIT’s skeletal muscle adaptations and health-promoting effects.

Preprint: The preprint version of this work is available on medRxiv, https://doi.org/10:1101/2024.07.11.24310302.

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磷蛋白质组学揭示了健康男性参与者高强度间歇训练背后的运动强度特异性骨骼肌信号网络

在对运动的反应中，蛋白激酶和信号网络参与减弱由急性收缩引起的骨骼肌能量和氧气需求增加所产生的体内平衡威胁，以及在对慢性运动训练的适应性反应中发挥作用，以减弱未来对体内平衡的破坏。高强度间歇训练（HIIT）是一种时间效率高的运动方式，与长时间、中等强度的连续训练（MICT）相比，它能诱导更好或相似的促进健康的骨骼肌和全身适应。然而，HIIT运动强度特异性适应性反应背后的骨骼肌信号通路尚不清楚。我们绘制了急性HIIT与工作匹配MICT激活/失活的人类肌肉激酶、底物和信号通路。方法采用随机交叉试验设计(澳大利亚-新西兰临床试验注册号：ACTRN12619000819123；前瞻性注册于2019年6月6日)，10名健康男性受试者(年龄25.4±3.2岁；BMI 23.5±1.6 kg/m2；\(\dot{V}{\text{O}}_{2} \max\) 37.9±5.2 ml/kg/min，平均值±SD)完成单次HIIT和MICT循环，间隔≥10天，总工作量（67.9±10.2 kJ）和持续时间（10分钟）相匹配。对每次运动前、运动中（5分钟）和运动后（10分钟）收集的肌肉活检样本进行基于质谱的磷酸化蛋白质组学分析，绘制HIIT和MICT的急性时间信号反应，鉴定并量化了14931个总磷酸化肽，对应8509个磷酸化位点。结果生物信息学分析揭示了运动强度特异性信号网络，包括1000个差异磷酸化位点(±1.5倍变化；调整P ＆lt； 0.05；≥3名参与者)相对于休息后5分钟和10分钟HIIT和/或MICT。5分钟和10分钟后，HIIT与MICT分别对92和348个位点进行了差异磷酸化。在整个HIIT过程中血浆乳酸浓度高于MICT (P ＆lt; 0.05)，相关分析发现＆gt； 3000个磷酸位点与乳酸显著相关（q ＆lt; 0.05），包括代谢调节的顶级功能磷酸位点。总的来说，这首个与工作匹配的HIIT与MICT信号网络的全球图谱揭示了人类骨骼肌中激酶、底物和途径的快速运动强度特异性调节，这可能有助于HIIT的骨骼肌适应和健康促进作用。预印本：本作品的预印本可在medRxiv， https://doi.org/10:1101/2024.07.11.24310302上获得。

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来源期刊

Sports Medicine 医学-运动科学

CiteScore

18.40

自引率

5.10%

发文量

165

审稿时长

6-12 weeks

期刊介绍： Sports Medicine focuses on providing definitive and comprehensive review articles that interpret and evaluate current literature, aiming to offer insights into research findings in the sports medicine and exercise field. The journal covers major topics such as sports medicine and sports science, medical syndromes associated with sport and exercise, clinical medicine's role in injury prevention and treatment, exercise for rehabilitation and health, and the application of physiological and biomechanical principles to specific sports. Types of Articles: Review Articles: Definitive and comprehensive reviews that interpret and evaluate current literature to provide rationale for and application of research findings. Leading/Current Opinion Articles: Overviews of contentious or emerging issues in the field. Original Research Articles: High-quality research articles. Enhanced Features: Additional features like slide sets, videos, and animations aimed at increasing the visibility, readership, and educational value of the journal's content. Plain Language Summaries: Summaries accompanying articles to assist readers in understanding important medical advances. Peer Review Process: All manuscripts undergo peer review by international experts to ensure quality and rigor. The journal also welcomes Letters to the Editor, which will be considered for publication.