青蛙松弛肌纤维中不存在附着弱结合横桥的力学证据。
Absence of mechanical evidence for attached weakly binding cross-bridges in frog relaxed muscle fibres.
作者信息
Bagni M A, Cecchi G, Colomo F, Garzella P
机构信息
Dipartimento di Scienze Fisiologiche, Università degli Studi di Firenze, Italy.
出版信息
J Physiol. 1995 Jan 15;482 ( Pt 2)(Pt 2):391-400. doi: 10.1113/jphysiol.1995.sp020526.
Abstract
- Passive force responses to ramp stretches at various velocities were measured in intact and skinned single muscle fibres isolated from the lumbricalis muscle of the frog. Force was measured using a fast capacitance transducer and sarcomere length was measured using a laser light diffraction technique at a point very close to the fixed end so as to avoid effects of fibre inertia. Experiments were performed at 15 degrees C with sarcomere length between 2.13 and 3.27 microns under high (170 mM) and low (20 mM) ionic strength. 2. The analysis shows that the force response is the sum of at least three components: (i) elastic (force proportional to the amount of stretch), (ii) viscous (force proportional to rate of stretch), and (iii) viscoelastic (resembling the response of a pure viscous element in series with an elastic element). 3. The amplitude of all these components increased progressively with sarcomere length in the whole range measured. 4. A further component, attributable to the short-range elasticity (SREC), was present in the force response of the intact fibres. 5. The amplitude of the force response decreased substantially upon skinning at high ionic strength but increased again at low ionic strength. The SREC was completely abolished by skinning. 6. None of the components of the force response was found to have the properties expected from the previously postulated 'weakly binding bridges'.
摘要
- 在从青蛙蚓状肌分离出的完整和去膜单根肌纤维中,测量了不同速度下斜坡拉伸的被动力响应。使用快速电容换能器测量力,并使用激光衍射技术在非常靠近固定端的一点测量肌节长度,以避免纤维惯性的影响。实验在15摄氏度下进行,肌节长度在2.13至3.27微米之间,分别处于高离子强度(170 mM)和低离子强度(20 mM)条件下。2. 分析表明,力响应至少由三个成分组成:(i)弹性成分(力与拉伸量成正比),(ii)粘性成分(力与拉伸速率成正比),以及(iii)粘弹性成分(类似于与弹性元件串联的纯粘性元件的响应)。3. 在整个测量范围内,所有这些成分的幅度都随着肌节长度的增加而逐渐增大。4. 在完整纤维的力响应中存在另一个可归因于短程弹性(SREC)的成分。5. 在高离子强度下去膜时,力响应的幅度大幅下降,但在低离子强度下又再次增加。去膜完全消除了SREC。6. 未发现力响应的任何成分具有先前假设的“弱结合桥”所预期的特性。
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