Coffey Vernon G, Shield Anthony, Canny Benedict J, Carey Kate A, Cameron-Smith David, Hawley John A
School of Medical Sciences, RMIT University, Melbourne, Australia.
Am J Physiol Endocrinol Metab. 2006 May;290(5):E849-55. doi: 10.1152/ajpendo.00299.2005. Epub 2005 Dec 6.
Skeletal muscle displays enormous plasticity to respond to contractile activity with muscle from strength- (ST) and endurance-trained (ET) athletes representing diverse states of the adaptation continuum. Training adaptation can be viewed as the accumulation of specific proteins. Hence, the altered gene expression that allows for changes in protein concentration is of major importance for any training adaptation. Accordingly, the aim of the present study was to quantify acute subcellular responses in muscle to habitual and unfamiliar exercise. After 24-h diet/exercise control, 13 male subjects (7 ST and 6 ET) performed a random order of either resistance (8 x 5 maximal leg extensions) or endurance exercise (1 h of cycling at 70% peak O2 uptake). Muscle biopsies were taken from vastus lateralis at rest and 3 h after exercise. Gene expression was analyzed using real-time PCR with changes normalized relative to preexercise values. After cycling exercise, peroxisome proliferator-activated receptor-gamma coactivator-1alpha (ET approximately 8.5-fold, ST approximately 10-fold, P < 0.001), pyruvate dehydrogenase kinase-4 (PDK-4; ET approximately 26-fold, ST approximately 39-fold), vascular endothelial growth factor (VEGF; ET approximately 4.5-fold, ST approximately 4-fold), and muscle atrophy F-box protein (MAFbx) (ET approximately 2-fold, ST approximately 0.4-fold) mRNA increased in both groups, whereas MyoD (approximately 3-fold), myogenin (approximately 0.9-fold), and myostatin (approximately 2-fold) mRNA increased in ET but not in ST (P < 0.05). After resistance exercise PDK-4 (approximately 7-fold, P < 0.01) and MyoD (approximately 0.7-fold) increased, whereas MAFbx (approximately 0.7-fold) and myostatin (approximately 0.6-fold) decreased in ET but not in ST. We conclude that prior training history can modify the acute gene responses in skeletal muscle to subsequent exercise.
骨骼肌表现出巨大的可塑性,能够对收缩活动做出反应,来自力量训练(ST)和耐力训练(ET)运动员的肌肉代表了适应连续体的不同状态。训练适应可被视为特定蛋白质的积累。因此,允许蛋白质浓度发生变化的基因表达改变对于任何训练适应都至关重要。相应地,本研究的目的是量化肌肉对习惯性和不熟悉运动的急性亚细胞反应。在进行24小时饮食/运动控制后,13名男性受试者(7名ST和6名ET)以随机顺序进行阻力运动(8组,每组5次最大腿部伸展)或耐力运动(在70%峰值摄氧量下骑行1小时)。在休息时和运动后3小时从股外侧肌采集肌肉活检样本。使用实时PCR分析基因表达,并将变化相对于运动前值进行归一化。在进行骑行运动后,两组中过氧化物酶体增殖物激活受体γ共激活因子-1α(ET组约8.5倍,ST组约10倍,P<0.001)、丙酮酸脱氢酶激酶-4(PDK-4;ET组约26倍,ST组约39倍)、血管内皮生长因子(VEGF;ET组约4.5倍,ST组约4倍)和肌肉萎缩F盒蛋白(MAFbx)(ET组约2倍,ST组约0.4倍)的mRNA均增加,而MyoD(约3倍)、肌细胞生成素(约0.9倍)和肌肉生长抑制素(约2倍)的mRNA在ET组增加而在ST组未增加(P<0.05)。在进行阻力运动后,ET组中PDK-4(约7倍,P<0.01)和MyoD(约0.7倍)增加,而MAFbx(约0.7倍)和肌肉生长抑制素(约0.6倍)减少,ST组则无此变化。我们得出结论,先前的训练史可以改变骨骼肌对后续运动的急性基因反应。
