离子强度、温度和压力对密集蛋白质溶液相互作用势的影响:从非线性压力响应到蛋白质结晶。
The effect of ionic strength, temperature, and pressure on the interaction potential of dense protein solutions: from nonlinear pressure response to protein crystallization.
机构信息
Fakultät Physik/DELTA, TU Dortmund, Dortmund, Germany.
出版信息
Biophys J. 2012 Jun 6;102(11):2641-8. doi: 10.1016/j.bpj.2012.04.043. Epub 2012 Jun 5.
Abstract
Understanding the intermolecular interaction potential, V(r), of proteins under the influence of temperature, pressure, and salt concentration is essential for understanding protein aggregation, crystallization, and protein phase behavior in general. Here, we report small-angle x-ray scattering studies on dense lysozyme solutions of high ionic strength as a function of temperature and pressure. We show that the interaction potential changes in a nonlinear fashion over a wide range of temperatures, salt, and protein concentrations. Neither temperature nor protein and salt concentration lead to marked changes in the pressure dependence of V(r), indicating that changes of the water structure dominate the pressure dependence of the intermolecular forces. Furthermore, by analysis of the temperature, pressure, and ionic strength dependence of the normalized second virial coefficient, b2, we show that the interaction can be fine-tuned by pressure, which can be used to optimize b2 values for controlled protein crystallization.
摘要
了解蛋白质在温度、压力和盐浓度影响下的分子间相互作用势 V(r),对于理解蛋白质聚集、结晶以及蛋白质相行为具有重要意义。在这里,我们报告了在高离子强度下致密溶菌酶溶液的小角度 X 射线散射研究,该研究是关于温度、压力和蛋白质浓度的函数。我们表明,在很宽的温度、盐和蛋白质浓度范围内,相互作用势以非线性的方式发生变化。温度或蛋白质和盐浓度都不会导致 V(r)的压力依赖性发生明显变化,这表明水结构的变化主导了分子间力的压力依赖性。此外,通过对归一化第二维里系数 b2 的温度、压力和离子强度依赖性进行分析,我们表明可以通过压力来精细调节相互作用,这可用于优化 b2 值以实现对蛋白质结晶的控制。
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