毛细胞束中门控弹簧施加力的位移钳测量
Displacement-clamp measurement of the forces exerted by gating springs in the hair bundle.
作者信息
Jaramillo F, Hudspeth A J
机构信息
Center for Basic Neuroscience Research, University of Texas Southwestern Medical Center, Dallas 75235-9039.
出版信息
Proc Natl Acad Sci U S A. 1993 Feb 15;90(4):1330-4. doi: 10.1073/pnas.90.4.1330.
Abstract
Mechanical stimuli applied to the hair bundle of a hair cell are communicated to the transduction channels by gating springs, elastic elements that are stretched when the bundle is displaced toward its tall edge. To quantify the magnitude and time dependence of the forces exerted by gating springs, we have developed a displacement-clamp system that constrains a bundle's motion while measuring the forces that the bundle produces during adaptation to mechanical stimuli, in response to channel blockage, and upon destruction of the gating springs. Our results suggest that each gating spring exerts a tension of approximately 8 pN in the resting bundle and can sustain at least 4-13 pN of additional tension. The experiments provide further evidence that the gating springs account for at least one-third of the hair bundle's dynamic stiffness and that a force of approximately 100 fN is sufficient to open a single transduction channel.
摘要
施加于毛细胞毛束的机械刺激通过门控弹簧传递给转导通道,门控弹簧是一种弹性元件,当毛束向其高侧边缘位移时会被拉伸。为了量化门控弹簧施加力的大小和时间依赖性,我们开发了一种位移钳系统,该系统在测量毛束在适应机械刺激、响应通道阻断以及门控弹簧破坏过程中产生的力时,会限制毛束的运动。我们的结果表明,每个门控弹簧在静息毛束中施加约8皮牛的张力,并且能够承受至少4 - 13皮牛的额外张力。这些实验进一步证明,门控弹簧至少占毛束动态刚度的三分之一,并且约100飞牛的力足以打开单个转导通道。
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