An improved mathematical approach for determination of molecular kinetics in living cells with FRAP.

Tanmay Lele, Philmo Oh, Jeffrey A Nickerson, Donald E Ingber
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Abstract

The estimation of binding constants and diffusion coefficients of molecules that associate with insoluble molecular scaffolds inside living cells and nuclei has been facilitated by the use of Fluorescence Recovery after Photobleaching (FRAP) in conjunction with mathematical modeling. A critical feature unique to FRAP experiments that has been overlooked by past mathematical treatments is the existence of an 'equilibrium constraint': local dynamic equilibrium is not disturbed because photobleaching does not functionally destroy molecules, and hence binding-unbinding proceeds at equilibrium rates. Here we describe an improved mathematical formulation under the equilibrium constraint which provides a more accurate estimate of molecular reaction kinetics within FRAP studies carried out in living cells. Due to incorporation of the equilibrium constraint, the original nonlinear kinetic terms become linear allowing for analytical solution of the transport equations and greatly simplifying the estimation process. Based on mathematical modeling and scaling analysis, two experimental measures are identified that can be used to delineate the rate-limiting step. A comprehensive analysis of the interplay between binding-unbinding and diffusion, and its effect on the recovery curve, are presented. This work may help to bring clarity to the study of molecular dynamics within the structural complexity of living cells.

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用FRAP测定活细胞分子动力学的改进数学方法。
利用光漂白后荧光恢复(FRAP)与数学建模相结合,可以估计活细胞和细胞核内与不溶性分子支架相关的分子的结合常数和扩散系数。过去的数学处理忽略了FRAP实验独有的一个关键特征,即“平衡约束”的存在:局部动态平衡不会受到干扰,因为光漂白不会在功能上破坏分子,因此结合-解结合以平衡速率进行。在这里,我们描述了一个在平衡约束下改进的数学公式,它提供了在活细胞中进行的FRAP研究中分子反应动力学的更准确估计。由于加入了平衡约束,原来的非线性动力学项变成了线性的,从而可以解析求解输运方程,大大简化了估计过程。在数学建模和尺度分析的基础上,确定了两种可用于描述限速步骤的实验方法。综合分析了结合-解结合与扩散之间的相互作用及其对回收率曲线的影响。这项工作可能有助于使活细胞结构复杂性中的分子动力学研究更加清晰。
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