Chase P B, Martyn D A, Hannon J D
Department of Radiology, University of Washington, Seattle 98195.
J Muscle Res Cell Motil. 1994 Apr;15(2):119-29. doi: 10.1007/BF00130423.
To examine the mechanism by which aluminiofluoride, a tightly binding analogue of inorganic phosphate, inhibits force in single, chemically skinned fibres from rabbit psoas muscle, we measured the Ca(2+)-dependence of the kinetics of inhibitor dissociation and the kinetics of actomyosin interactions when aluminiofluoride was bound to the crossbridges. The relation between stiffness and the speed of stretch during small amplitude ramp stretches (< 5 nm per h.s.) was used to characterize the kinetic properties of crossbridges attached to actin; sarcomere length was assessed with HeNe laser diffraction. During maximum Ca(2+)-activation at physiological ionic strength (pCa 4.0, 0.2 M gamma/2), stiffness exhibited a steep dependence on the rate of stretch; aluminiofluoride inhibition at pCa 4.0 (0.2 M gamma/2) resulted in an overall decrease in stiffness, with stiffness at high rates of stretch (10(3)-10(4) nm per h.s. per s) being disproportionately reduced. Thus the slope of the stiffness-speed relation was reduced during aluminiofluoride inhibition of activated fibres. Relaxation of inhibited fibres (pCa 9.2, 0.2 M gamma/2) resulted in aluminiofluoride being 'trapped' and was accompanied by a further decrease in stiffness at all rates of stretch which was comparable to that found in control relaxed fibres. In relaxed, low ionic strength conditions (pCa 9.2, 0.02 M gamma/2) which promote weak crossbridge binding, stiffness at all rates of stretch was significantly inhibited by aluminiofluoride 'trapped' in the fibre. To determine the Ca(2+)-dependence of inhibitor dissociation, force was regulated independent of Ca2+ using an activating troponin C (aTnC). Results obtained with a TnC-activated fibres confirmed that there is no absolute requirement for Ca2+ for recovery from force inhibition by inorganic phosphate analogues in skinned fibres; the only requirement is thin filament activation which enables active crossbridge cycling. These results indicate that aluminiofluoride preferentially inhibits rapid equilibrium or weak crossbridge attachment to actin, that aluminiofluoride-bound crossbridges attach tightly to the activated thin filament, and that, at maximal (or near-maximal) activation, crossbridge attachment to actin prior to inorganic phosphate analogue dissociation is the primary event regulated by Ca2+.
为了研究无机磷酸紧密结合类似物铝氟化物抑制兔腰大肌单根化学去皮纤维中力的机制,我们测量了铝氟化物与横桥结合时抑制剂解离动力学和肌动球蛋白相互作用动力学对Ca(2+)的依赖性。在小幅度斜坡拉伸(<5 nm/小时·秒)过程中,利用刚度与拉伸速度之间的关系来表征附着于肌动蛋白的横桥的动力学特性;通过氦氖激光衍射评估肌节长度。在生理离子强度(pCa 4.0,0.2 Mγ/2)下最大Ca(2+)激活时,刚度对拉伸速率表现出强烈依赖性;在pCa 4.0(0.2 Mγ/2)下铝氟化物抑制导致刚度总体下降,在高拉伸速率(10(3)-10(4) nm/小时·秒·秒)下刚度下降不成比例。因此,在铝氟化物抑制激活纤维时,刚度-速度关系的斜率降低。抑制纤维(pCa 9.2,0.2 Mγ/2)的松弛导致铝氟化物被“捕获”,并伴随着在所有拉伸速率下刚度进一步下降,这与对照松弛纤维中的情况相当。在促进弱横桥结合的松弛、低离子强度条件(pCa 9.2,0.02 Mγ/2)下,纤维中“捕获”的铝氟化物显著抑制了所有拉伸速率下的刚度。为了确定抑制剂解离对Ca(2+)的依赖性,使用激活肌钙蛋白C(aTnC)独立于Ca2+调节力。用TnC激活纤维获得的结果证实,在去皮纤维中,从无机磷酸类似物引起的力抑制中恢复并不绝对需要Ca2+;唯一的要求是细肌丝激活,这能使活跃的横桥循环。这些结果表明,铝氟化物优先抑制快速平衡或弱横桥与肌动蛋白的附着,铝氟化物结合的横桥紧密附着于激活的细肌丝,并且在最大(或接近最大)激活时,无机磷酸类似物解离之前横桥与肌动蛋白的附着是受Ca2+调节的主要事件。
