青蛙肌肉纤维固定端强直收缩期间的肌节间动力学。
Intersarcomere dynamics during fixed-end tetanic contractions of frog muscle fibres.
作者信息
Julian F J, Morgan D L
出版信息
J Physiol. 1979 Aug;293:365-78. doi: 10.1113/jphysiol.1979.sp012894.
Abstract
- The stability of sarcomere lengths along single twitch fibres from frog muscles was examined during fixed-end tetani, using a spot follower apparatus to monitor the length of a central segment. 2. Internal movement, with most of the fibre lengthening and small regions at the ends shortening as the contraction proceeded, was always seen at fibre lengths beyond those corresponding to a sarcomere length of 2.3 micrometer. 3. The rate of lengthening of the central region was fastest during the slow phase of tension rise (creep) but continued at a slower rate throughout the tetanus. These observations are in accord with the idea that progressive development of sarcomere non-uniformity is responsible for the creep phase. 4. Observations at various muscle lengths of the rate of decay of tension and the duration of the slow phase of relaxation suggest that movement during relaxation is due to sarcomere length non-uniformities and variations of decay rate with sarcomere length. 5. The rate of tension fall after stimulation ceases in an isometric sarcomere, and the factors which determine that rate, are discussed in view of evidence from fixed-end and length-clamped tetani, and recently reported experiments using aequorin.
摘要
- 在固定端强直收缩期间,使用光点跟踪装置监测青蛙肌肉单根单收缩纤维肌节长度的稳定性,以观察中央节段的长度。2. 在肌节长度超过2.3微米的纤维长度处,总能观察到内部运动,随着收缩的进行,大部分纤维伸长,两端的小区域缩短。3. 在张力上升的缓慢阶段(蠕动),中央区域的伸长速率最快,但在整个强直收缩过程中以较慢的速率持续。这些观察结果与肌节不均匀性的逐渐发展是蠕动阶段的原因这一观点一致。4. 在不同肌肉长度下对张力衰减速率和缓慢松弛阶段持续时间的观察表明,松弛期间的运动是由于肌节长度不均匀以及衰减速率随肌节长度的变化所致。5. 根据固定端和长度钳制强直收缩的证据以及最近使用水母发光蛋白进行的实验,讨论了等长肌节刺激停止后张力下降的速率以及决定该速率的因素。
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