完整单根肌纤维等张收缩期间的横桥附着与僵硬度

Cross-bridge attachment and stiffness during isotonic shortening of intact single muscle fibers.

作者信息

Griffiths P J, Ashley C C, Bagni M A, Maéda Y, Cecchi G

机构信息

University Laboratory of Physiology, Oxford, UK.

出版信息

Biophys J. 1993 Apr;64(4):1150-60. doi: 10.1016/S0006-3495(93)81481-4.

DOI:10.1016/S0006-3495(93)81481-4

PMID:8494976

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1262433/

Abstract

Equatorial x-ray diffraction pattern intensities (I10 and I11), fiber stiffness and sarcomere length were measured in single, intact muscle fibers under isometric conditions and during constant velocity (ramp) shortening. At the velocity of unloaded shortening (Vmax) the I10 change accompanying activation was reduced to 50.8% of its isometric value, I11 reduced to 60.7%. If the roughly linear relation between numbers of attached bridges and equatorial signals in the isometric state also applies during shortening, this would predict 51-61% attachment. Stiffness (measured using 4 kHz sinusoidal length oscillations), another putative measure of bridge attachment, was 30% of its isometric value at Vmax. When small step length changes were applied to the preparation (such as used for construction of T1 curves), no equatorial intensity changes could be detected with our present time resolution (5 ms). Therefore, unlike the isometric situation, stiffness and equatorial signals obtained during ramp shortening are not in agreement. This may be a result of a changed crossbridge spatial orientation during shortening, a different average stiffness per attached crossbridge, or a higher proportion of single headed crossbridges during shortening.

摘要

在等长条件下以及在恒速（斜坡）缩短过程中，对单根完整肌纤维测量赤道X射线衍射图案强度（I10和I11）、纤维刚度和肌节长度。在无负荷缩短速度（Vmax）时，伴随激活的I10变化降至其等长值的50.8%，I11降至60.7%。如果在缩短过程中等长状态下附着桥数量与赤道信号之间大致呈线性关系也适用，那么这将预测附着率为51 - 61%。刚度（使用4kHz正弦长度振荡测量）是另一种推测的桥附着测量指标，在Vmax时为其等长值的30%。当对标本施加小步长变化（如用于构建T1曲线）时，以我们目前的时间分辨率（5毫秒）未检测到赤道强度变化。因此，与等长情况不同，斜坡缩短过程中获得的刚度和赤道信号不一致。这可能是由于缩短过程中横桥空间取向改变、每个附着横桥的平均刚度不同，或者缩短过程中单头横桥比例更高所致。

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