通过热涨落监测表面之间的受体-配体相互作用。
Monitoring receptor-ligand interactions between surfaces by thermal fluctuations.
作者信息
Chen Wei, Evans Evan A, McEver Rodger P, Zhu Cheng
机构信息
Woodruff School of Mechanical Engineering, Georgia Institute of Technology, Atlanta, Georgia 30332-0363, USA.
出版信息
Biophys J. 2008 Jan 15;94(2):694-701. doi: 10.1529/biophysj.107.117895. Epub 2007 Sep 21.
Abstract
We describe a new method for determining receptor-ligand association/dissociation events across the interface of two surfaces (two-dimensional binding) by monitoring abrupt decrease/resumption in thermal fluctuations of a biomembrane force probe. Our method has been validated by rigorous control experiments and kinetic experiments. We show that cellular on-rate of association can be measured by analysis of intervals from a dissociation event to the next association event (waiting times). Similarly, off-rate of molecular dissociation can be measured by analysis of intervals from an association event to the next dissociation event (bond lifetimes). Different types of molecular bonds could be distinguished by different levels of reduction in thermal fluctuations. This novel method provides a powerful tool to study cell adhesion and signaling mediated by single or multiple receptor-ligand species.
摘要
我们描述了一种新方法,通过监测生物膜力探针热波动的突然下降/恢复来确定跨两个表面界面的受体-配体结合/解离事件(二维结合)。我们的方法已通过严格的对照实验和动力学实验得到验证。我们表明,细胞结合的结合速率可以通过分析从解离事件到下一个结合事件的间隔(等待时间)来测量。同样,分子解离的解离速率可以通过分析从结合事件到下一个解离事件的间隔(键寿命)来测量。不同类型的分子键可以通过热波动降低的不同水平来区分。这种新方法为研究由单一或多种受体-配体种类介导的细胞粘附和信号传导提供了一个强大的工具。
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