Department of Physical Performance, Norwegian School of Sports Sciences, Oslo, Norway.
Research Institute for Sport and Exercise Sciences, Liverpool John Moores University, Liverpool, United Kingdom.
J Appl Physiol (1985). 2020 Aug 1;129(2):297-310. doi: 10.1152/japplphysiol.00817.2019. Epub 2020 Jun 25.
The present study compared the effects of postexercise carbohydrate plus protein (CHO+PROT) and carbohydrate (CHO)-only supplementation on muscle glycogen metabolism, anabolic cell signaling, and subsequent exercise performance. Nine endurance-trained males cycled twice to exhaustion (muscle glycogen decreased from ~495 to ~125 mmol/kg dry wt) and received either CHO only (1.2 g·kg·h) or CHO+PROT (0.8/0.4 g·kg·h) during the first 90 min of recovery. Glycogen content was similar before the performance test after 5 h of recovery. Glycogen synthase (GS) fractional activity increased after exhaustive exercise and remained activated 5 h after, despite substantial glycogen synthesis (176.1 ± 19.1 and 204.6 ± 27.0 mmol/kg dry wt in CHO and CHO+PROT, respectively; = 0.15). Phosphorylation of GS at and remained low during recovery. After the 5-h recovery, cycling time to exhaustion was improved by CHO+PROT supplementation compared with CHO supplementation (54.6 ± 11.0 vs. 46.1 ± 9.8 min; = 0.009). After the performance test, muscle glycogen was equally reduced in CHO+PROT and CHO. Akt Ser and p70s6k Thr phosphorylation was elevated after 5 h of recovery. There were no differences in Akt Ser, p70s6k Thr, or TSC2 Thr phosphorylation between treatments. Nitrogen balance was positive in CHO+PROT (19.6 ± 7.6 mg nitrogen/kg; = 0.04) and higher than CHO (-10.7 ± 6.3 mg nitrogen/kg; = 0.009). CHO+PROT supplementation during exercise recovery improved subsequent endurance performance relative to consuming CHO only. This improved performance after CHO+PROT supplementation could not be accounted for by differences in glycogen metabolism or anabolic cell signaling, but may have been related to differences in nitrogen balance. Endurance athletes competing consecutive days need optimal dietary intake during the recovery period. We report that coingestion of protein and carbohydrate soon after exhaustive exercise, compared with carbohydrate only, resulted in better performance the following day. The better performance after coingestion of protein and carbohydrate was not associated with a higher rate of glycogen synthesis or activation of anabolic signaling compared with carbohydrate only. Importantly, nitrogen balance was positive after coingestion of protein and carbohydrate, which was not the case after intake of carbohydrate only, suggesting that protein synthesis contributes to the better performance the following day.
本研究比较了运动后碳水化合物加蛋白质(CHO+PROT)和碳水化合物(CHO)补充对肌肉糖原代谢、合成代谢细胞信号和随后运动表现的影响。9 名耐力训练的男性进行了两次力竭性自行车运动(肌肉糖原从约 495 降至约 125mmol/kg 干重),在恢复的前 90 分钟内分别接受了仅 CHO(1.2g·kg·h)或 CHO+PROT(0.8/0.4g·kg·h)。在恢复 5 小时后进行运动表现测试前,糖原含量相似。运动后糖原合酶(GS)的分数活性增加,尽管有大量的糖原合成(CHO 和 CHO+PROT 分别为 176.1±19.1mmol/kg 和 204.6±27.0mmol/kg; = 0.15),但其活性仍保持激活状态。在恢复过程中,GS 的磷酸化在 和 保持低位。与 CHO 补充相比,CHO+PROT 补充在 5 小时恢复后可提高力竭性自行车运动的时间(54.6±11.0 与 46.1±9.8 分钟; = 0.009)。在运动表现测试后,CHO+PROT 和 CHO 组的肌肉糖原含量同样减少。恢复 5 小时后,Akt Ser 和 p70s6k Thr 磷酸化升高。两种处理之间,Akt Ser、p70s6k Thr 或 TSC2 Thr 磷酸化无差异。CHO+PROT 中的氮平衡为正(19.6±7.6mg 氮/kg; = 0.04),高于 CHO(-10.7±6.3mg 氮/kg; = 0.009)。与单独摄入 CHO 相比,运动后恢复期间摄入 CHO+PROT 可改善随后的耐力表现。与单独摄入 CHO 相比,摄入 CHO+PROT 后,肌肉糖原代谢或合成代谢细胞信号没有差异,但可能与氮平衡的差异有关。连续多天参加比赛的耐力运动员在恢复期需要最佳的饮食摄入。我们报告,与单独摄入碳水化合物相比,在力竭运动后立即摄入蛋白质和碳水化合物,可使次日的表现更好。与单独摄入碳水化合物相比,摄入蛋白质和碳水化合物后的表现更好,与糖原合成或合成代谢信号激活的速度更高无关。重要的是,摄入蛋白质和碳水化合物后氮平衡为正,而单独摄入碳水化合物则不然,这表明蛋白质合成有助于次日的更好表现。
