Kistner Sina, Mack Carina I, Rist Manuela J, Krüger Ralf, Egert Björn, Biniaminov Nathalie, Engelbert Ann Katrin, Seifert Stephanie, Dörr Claudia, Ferrario Paola G, Neumann Rainer, Altmann Stefan, Bub Achim
Department of Physiology and Biochemistry of Nutrition, Max Rubner-Institut, Karlsruhe, Germany.
Department of Safety and Quality of Fruit and Vegetables, Max Rubner-Institut, Karlsruhe, Germany.
Front Physiol. 2023 Jan 30;14:1028643. doi: 10.3389/fphys.2023.1028643. eCollection 2023.
Endurance exercise alters whole-body as well as skeletal muscle metabolism and physiology, leading to improvements in performance and health. However, biological mechanisms underlying the body's adaptations to different endurance exercise protocols are not entirely understood. We applied a multi-platform metabolomics approach to identify urinary metabolites and associated metabolic pathways that distinguish the acute metabolic response to two endurance exercise interventions at distinct intensities. In our randomized crossover study, 16 healthy, young, and physically active men performed 30 min of continuous moderate exercise (CME) and continuous vigorous exercise (CVE). Urine was collected during three post-exercise sampling phases (U01/U02/U03: until 45/105/195 min post-exercise), providing detailed temporal information on the response of the urinary metabolome to CME and CVE. Also, fasting spot urine samples were collected pre-exercise (U00) and on the following day (U04). While untargeted two-dimensional gas chromatography-mass spectrometry (GC×GC-MS) led to the detection of 608 spectral features, 44 metabolites were identified and quantified by targeted nuclear magnetic resonance (NMR) spectroscopy or liquid chromatography-mass spectrometry (LC-MS). 104 urinary metabolites showed at least one significant difference for selected comparisons of sampling time points within or between exercise trials as well as a relevant median fold change >1.5 or <0. (NMR, LC-MS) or >2.0 or <0.5 (GC×GC-MS), being classified as either or . Our findings indicate that CVE induced more profound alterations in the urinary metabolome than CME, especially at U01, returning to baseline within 24 h after U00. Most differences between exercise trials are likely to reflect higher energy requirements during CVE, as demonstrated by greater shifts in metabolites related to glycolysis (e.g., lactate, pyruvate), tricarboxylic acid cycle (e.g., -aconitate, malate), purine nucleotide breakdown (e.g., hypoxanthine), and amino acid mobilization (e.g., alanine) or degradation (e.g., 4-hydroxyphenylacetate). To conclude, this study provided first evidence of specific urinary metabolites as potential metabolic markers of endurance exercise intensity. Future studies are needed to validate our results and to examine whether acute metabolite changes in urine might also be partly reflective of mechanisms underlying the health- or performance-enhancing effects of endurance exercise, particularly if performed at high intensities.
耐力运动可改变全身以及骨骼肌的代谢和生理机能,从而提高运动表现和健康水平。然而,人体对不同耐力运动方案适应的生物学机制尚未完全明确。我们采用多平台代谢组学方法,以识别区分对两种不同强度耐力运动干预的急性代谢反应的尿液代谢物及相关代谢途径。在我们的随机交叉研究中,16名健康、年轻且有体育锻炼习惯的男性进行了30分钟的持续中等强度运动(CME)和持续高强度运动(CVE)。在运动后的三个采样阶段(U01/U02/U03:运动后45/105/195分钟内)收集尿液,提供了尿液代谢组对CME和CVE反应的详细时间信息。此外,在运动前(U00)和第二天(U04)收集空腹晨尿样本。非靶向二维气相色谱 - 质谱联用(GC×GC-MS)检测到608个光谱特征,通过靶向核磁共振(NMR)光谱或液相色谱 - 质谱联用(LC-MS)鉴定并定量了44种代谢物。在运动试验内或试验间的采样时间点的选定比较中,104种尿液代谢物显示出至少一个显著差异,且相关中位数变化倍数>1.5或<0. (NMR、LC-MS)或>2.0或<0.5(GC×GC-MS),被归类为上调或下调。我们的研究结果表明,与CME相比,CVE对尿液代谢组的影响更为深刻,尤其是在U01时,在U00后24小时内恢复到基线水平。运动试验之间的大多数差异可能反映了CVE期间更高的能量需求,这表现为与糖酵解(如乳酸、丙酮酸)、三羧酸循环(如乌头酸、苹果酸)、嘌呤核苷酸分解(如次黄嘌呤)以及氨基酸动员(如丙氨酸)或降解(如4-羟基苯乙酸)相关的代谢物有更大的变化。总之,本研究首次证明了特定尿液代谢物作为耐力运动强度潜在代谢标志物的证据。未来需要开展研究来验证我们的结果,并检验尿液中急性代谢物变化是否也可能部分反映了耐力运动对健康或运动表现增强作用的潜在机制,特别是在高强度运动时。
