Spriet L L
School of Human Biology, University of Guelph, Ontario, Canada.
Am J Physiol. 1989 Oct;257(4 Pt 1):E595-605. doi: 10.1152/ajpendo.1989.257.4.E595.
Rat fast-twitch muscles were tetanically stimulated in situ with an occluded circulation to examine ATP utilization and provision during isometric tension production. Plantaris (PL) and gastrocnemius (G) muscles were stimulated for 60 s in four conditions: A) 1.0-Hz train rate, 200-ms train duration at 80 Hz, B) 1.0 Hz (100 ms, 80 Hz), C) 0.5 Hz (100 ms, 80 Hz), and D) 1.0 Hz (200 ms, 40 Hz). Muscles were sampled pre- and post-stimulation for pH, high-energy phosphates, and glycolytic intermediates. Contributions to total ATP utilization (all muscles and conditions) were 64-67% glycolysis, 24-28% phosphocreatine, and 8-9% endogenous ATP. Glycogenolysis and glycolysis were greatest in white G (WG), 40% lower in red G (RG), and intermediate in PL muscles. Average energy costs in conditions A and D were approximately 0.60 mumol ATP/(N.s). Decreasing the train duration to 100 ms in B and the number of tetani to 30 in C increased energy costs to 0.93 +/- 0.05 and 1.26 +/- 0.07 mumol ATP/(N.s). Despite a lower pH, WG glycogenolytic (phosphorylase) activity was constant during condition A, whereas RG activity decreased in the final 30 contractions. Larger accumulations of Pi and inosine monophosphate may account for the maintained phosphorylase activity. Glycolytic (phosphofructokinase, PFK) activity was highest in WG and associated with higher fructose 6-phosphate concentration, greater depletion of ATP and, in later contractions, a higher NH4+ concentration. During tetanic in situ stimulation of fast-twitch muscle, the H+ profiles of phosphorylase and PFK are extended beyond in vitro predictions via the accumulation of positive modulators. This permits significant anaerobic ATP production via the glycolytic pathway despite increasing [H+]. The findings also suggest that lengthening the duration of tetani, generating lower peak tensions, and prolonging relaxation time all contribute to lower energy costs in fast-twitch muscle.
在原位对大鼠快肌进行强直刺激,同时阻断血液循环,以研究等长张力产生过程中的ATP利用和供应情况。在四种条件下对跖肌(PL)和腓肠肌(G)进行60秒的刺激:A)1.0赫兹的刺激频率,80赫兹下200毫秒的刺激持续时间;B)1.0赫兹(100毫秒,80赫兹);C)0.5赫兹(100毫秒,80赫兹);D)1.0赫兹(200毫秒,40赫兹)。在刺激前后对肌肉进行取样,检测pH值、高能磷酸盐和糖酵解中间产物。对总ATP利用(所有肌肉和条件)的贡献分别为:糖酵解64 - 67%、磷酸肌酸24 - 28%、内源性ATP 8 - 9%。糖原分解和糖酵解在白色腓肠肌(WG)中最为显著,在红色腓肠肌(RG)中低40%,在跖肌中处于中间水平。条件A和D下的平均能量消耗约为0.60微摩尔ATP/(牛顿·秒)。在B中将刺激持续时间缩短至100毫秒,在C中将强直刺激次数减少至30次,能量消耗分别增加至0.93±0.05和1.26±0.07微摩尔ATP/(牛顿·秒)。尽管pH值较低,但在条件A期间,WG的糖原分解(磷酸化酶)活性保持恒定,而RG的活性在最后30次收缩中下降。无机磷酸(Pi)和肌苷单磷酸的更大积累可能是磷酸化酶活性维持的原因。糖酵解(磷酸果糖激酶,PFK)活性在WG中最高,且与较高的6 - 磷酸果糖浓度、ATP的更大消耗以及后期收缩中较高的铵离子(NH4+)浓度相关。在快肌的原位强直刺激过程中,通过正性调节剂的积累,磷酸化酶和PFK的氢离子(H+)曲线超出了体外预测范围。这使得尽管[H+]增加,仍可通过糖酵解途径产生大量无氧ATP。研究结果还表明,延长强直刺激的持续时间、产生较低的峰值张力以及延长舒张时间均有助于降低快肌的能量消耗。
