肌质磷酸盐在骨骼肌收缩功能中的作用:对肌酸激酶缺陷小鼠的研究
Role of myoplasmic phosphate in contractile function of skeletal muscle: studies on creatine kinase-deficient mice.
作者信息
Dahlstedt A J, Katz A, Westerblad H
机构信息
Department of Physiology and Pharmacology, Karolinska Institutet, S-171 77 Stockholm, Sweden.
出版信息
J Physiol. 2001 Jun 1;533(Pt 2):379-88. doi: 10.1111/j.1469-7793.2001.0379a.x.
Abstract
- Increased myoplasmic inorganic phosphate (P(i)) has been suggested to have an important role in skeletal muscle fatigue, especially in the early phase. In the present study we used intact fast-twitch muscle cells from mice completely deficient in creatine kinase (CK(-/-)) to test this suggestion. These CK(-/-) muscle cells provide a good model since they display a higher P(i) concentration in the unfatigued state and fatigue without significant increase of P(i). 2. Tetanic contractions (350 ms duration) were produced in intact single muscle fibres. The free myoplasmic [Ca(2+)] (Ca(2+)) was measured with the fluorescent indicator indo-1. The force-Ca(2+) relationship was constructed from tetani at different frequencies. 3. Compared with wild-type fibres, CK(-/-) fibres displayed lower force in 100 Hz tetani and at saturating Ca(2+) (i.e. 100 Hz stimulation during caffeine exposure), higher tetanic Ca(2+) during the first 100 ms of tetanic stimulation, reduced myofibrillar Ca(2+) sensitivity when measurements were performed 100-200 ms into tetani, and slowed force relaxation that was due to altered cross-bridge kinetics rather than delayed Ca(2+) removal from the myoplasm. 4. In wild-type fibres, a series of 10 tetani resulted in reduced tetanic force, slowed force relaxation, and increased amplitude of Ca(2+) tails after tetani. None of these changes were observed in CK(-/-) fibres. 5. Complementary experiments on isolated fast-twitch extensor digitorum longus muscles showed a reduction of tetanic force and relaxation speed in CK(-/-) muscles similar to those observed in single fibres. 6. In conclusion, increased P(i) concentration can explain changes observed in the early phase of skeletal muscle fatigue. Increased P(i) appears to be involved in both fatigue-induced changes of cross-bridge function and SR Ca(2+) handling.
摘要
- 肌质无机磷酸盐(P(i))增加被认为在骨骼肌疲劳中起重要作用,尤其是在早期阶段。在本研究中,我们使用完全缺乏肌酸激酶(CK(-/-))的小鼠完整快肌细胞来验证这一观点。这些CK(-/-)肌细胞提供了一个良好的模型,因为它们在未疲劳状态下显示出较高的P(i)浓度,并且在不显著增加P(i)的情况下发生疲劳。2. 在完整的单根肌纤维中产生强直收缩(持续时间350毫秒)。用荧光指示剂indo-1测量游离肌质[Ca(2+)](Ca(2+))。通过不同频率的强直刺激构建力-Ca(2+)关系。3. 与野生型纤维相比,CK(-/-)纤维在100Hz强直刺激下以及在饱和Ca(2+)时(即咖啡因暴露期间100Hz刺激)显示出较低的力,在强直刺激的前100毫秒内强直Ca(2+)较高,在强直刺激100 - 200毫秒时进行测量时肌原纤维Ca(2+)敏感性降低,并且力松弛减慢,这是由于横桥动力学改变而非肌质中Ca(2+)移除延迟所致。4. 在野生型纤维中,一系列10次强直刺激导致强直力降低、力松弛减慢以及强直后Ca(2+)尾波幅度增加。在CK(-/-)纤维中未观察到这些变化。5. 对分离的快肌趾长伸肌进行的补充实验表明,CK(-/-)肌肉中的强直力和松弛速度降低,与在单根纤维中观察到的情况相似。6. 总之,P(i)浓度增加可以解释骨骼肌疲劳早期观察到的变化。P(i)增加似乎参与了疲劳诱导的横桥功能变化和肌浆网Ca(2+)处理过程。
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