Research Institute for Sport and Exercise Sciences, Liverpool John Moores University, Tom Reilly Building, Byrom St Campus, Liverpool, L3 3AF, UK.
Musculoskeletal Physiology Research Group, Sport, Health and Performance Enhancement Research Centre, School of Science and Technology, Nottingham Trent University, UK.
J Physiol. 2019 Sep;597(18):4779-4796. doi: 10.1113/JP278209. Epub 2019 Aug 21.
Reduced carbohydrate (CHO) availability before and after exercise may augment endurance training-induced adaptations of human skeletal muscle, as mediated via modulation of cell signalling pathways. However, it is not known whether such responses are mediated by CHO restriction, energy restriction or a combination of both. In recovery from a twice per day training protocol where muscle glycogen concentration is maintained within 200-350 mmol kg dry weight (dw), we demonstrate that acute post-exercise CHO and energy restriction (i.e. < 24 h) does not potentiate potent cell signalling pathways that regulate hallmark adaptations associated with endurance training. In contrast, consuming CHO before, during and after an acute training session attenuated markers of bone resorption, effects that are independent of energy availability. Whilst the enhanced muscle adaptations associated with CHO restriction may be regulated by absolute muscle glycogen concentration, the acute within-day fluctuations in CHO availability inherent to twice per day training may have chronic implications for bone turnover.
We examined the effects of post-exercise carbohydrate (CHO) and energy availability (EA) on potent skeletal muscle cell signalling pathways (regulating mitochondrial biogenesis and lipid metabolism) and indicators of bone metabolism. In a repeated measures design, nine males completed a morning (AM) and afternoon (PM) high-intensity interval (HIT) (8 × 5 min at 85% ) running protocol (interspersed by 3.5 h) under dietary conditions of (1) high CHO availability (HCHO: CHO ∼12 g kg , EA∼ 60 kcal kg fat free mass (FFM)), (2) reduced CHO but high fat availability (LCHF: CHO ∼3 ( , EA∼ 60 kcal kg FFM) or (3), reduced CHO and reduced energy availability (LCAL: CHO ∼3 g kg , EA∼ 20 kcal kg FFM). Muscle glycogen was reduced to ∼200 mmol kg dw in all trials immediately post PM HIT (P < 0.01) and remained lower at 17 h (171, 194 and 316 mmol kg dw) post PM HIT in LCHF and LCAL (P < 0.001) compared to HCHO. Exercise induced comparable p38MAPK phosphorylation (P < 0.05) immediately post PM HIT and similar mRNA expression (all P < 0.05) of PGC-1α, p53 and CPT1 mRNA in HCHO, LCHF and LCAL. Post-exercise circulating βCTX was lower in HCHO (P < 0.05) compared to LCHF and LCAL whereas exercise-induced increases in IL-6 were larger in LCAL (P < 0.05) compared to LCHF and HCHO. In conditions where glycogen concentration is maintained within 200-350 mmol kg dw, we conclude post-exercise CHO and energy restriction (i.e. < 24 h) does not potentiate cell signalling pathways that regulate hallmark adaptations associated with endurance training. In contrast, consuming CHO before, during and after HIT running attenuates bone resorption, effects that are independent of energy availability and circulating IL-6.
在运动前后减少碳水化合物(CHO)的供应可能会增强人体骨骼肌对耐力训练的适应,这是通过调节细胞信号通路来实现的。然而,目前尚不清楚这种反应是通过 CHO 限制、能量限制还是两者的结合来介导的。在每天进行两次训练的方案中,肌肉糖原浓度保持在 200-350mmolkg 干重(dw)范围内,我们证明急性运动后 CHO 和能量限制(即<24 小时)不会增强调节与耐力训练相关的标志性适应的强效细胞信号通路。相比之下,在急性训练期间和之后摄入 CHO 会减弱骨吸收的标志物,而这些效果与能量供应无关。虽然与 CHO 限制相关的增强的肌肉适应可能受到绝对肌肉糖原浓度的调节,但每天两次训练中固有的急性 CHO 供应波动可能对骨转换有慢性影响。
我们研究了运动后碳水化合物(CHO)和能量可用性(EA)对强效骨骼肌细胞信号通路(调节线粒体生物发生和脂质代谢)和骨代谢标志物的影响。在一项重复测量设计中,九名男性在高碳水化合物可用性(HCHO:CHO∼12gkg,EA∼60kcalkg 去脂体重(FFM))、低 CHO 但高脂肪可用性(LCHF:CHO∼3gkg,EA∼60kcalkg FFM)或低 CHO 和低能量可用性(LCAL:CHO∼3gkg,EA∼20kcalkg FFM)的条件下完成了上午(AM)和下午(PM)高强度间歇(HIT)(8×5min,85%)跑步方案(每隔 3.5 小时进行一次)。在 PM HIT 后,所有试验中肌肉糖原立即降至约 200mmolkg dw(P<0.01),在 PM HIT 后 17 小时(171、194 和 316mmolkg dw),LCHF 和 LCAL 中的糖原仍较低(P<0.001)与 HCHO 相比。运动后即刻 PM HIT 时 p38MAPK 磷酸化(P<0.05)和 PGC-1α、p53 和 CPT1mRNA 的相似 mRNA 表达(均 P<0.05)诱导出可比的 p38MAPK 磷酸化。在 HCHO 中,运动后循环βCTX 较低(P<0.05)与 LCHF 和 LCAL 相比,而 LCAL 中运动诱导的 IL-6 增加更大(P<0.05)与 LCHF 和 HCHO 相比。在糖原浓度保持在 200-350mmolkg dw 范围内的情况下,我们得出结论,运动后 CHO 和能量限制(即<24 小时)不会增强调节与耐力训练相关的标志性适应的细胞信号通路。相比之下,在 HIT 跑步前后摄入 CHO 会减弱骨吸收,这些效果与能量可用性和循环 IL-6 无关。
