溶液中牛α-晶状体蛋白的光散射:流体动力学结构与粒子间相互作用
Light scattering by bovine alpha-crystallin proteins in solution: hydrodynamic structure and interparticle interaction.
作者信息
Xia J Z, Aerts T, Donceel K, Clauwaert J
机构信息
Department of Biochemistry, University of Antwerp, Belgium.
出版信息
Biophys J. 1994 Mar;66(3 Pt 1):861-72. doi: 10.1016/s0006-3495(94)80862-8.
Abstract
We have studied diluted bovine eye lens alpha-crystallin solutions by using light scattering. The protein particles were modeled as hard spheres, showing electrostatic repulsion, due to surplus electric charges, and weak attractive interaction. The repulsive potential VR is defined by the radius of the particles, the Debye length kappa-1, and the number of charges at the Gouy layer; the attractive potential has been described by the London-van der Waals potential and is defined by the Hamaker constant A. We have used the diluted gas approximation and the one component macrofluid model to relate the experimental static factor Ki to the theoretical expression of the interaction potential V(x). This resulted in a Hamaker constant A of 0.06 +/- 0.01 KBT and an effective charge q ranging from 18 +/- 1 at low ionic strength (omega = 0.0022 M) to 50 +/- 5 at high ionic strength (omega = 0.1472 M).
摘要
我们通过光散射研究了稀释的牛眼晶状体α-晶体蛋白溶液。蛋白质颗粒被建模为硬球,由于多余电荷而表现出静电排斥以及微弱的吸引相互作用。排斥势VR由颗粒半径、德拜长度κ-1和 Gouy 层的电荷量定义;吸引势由伦敦-范德瓦尔斯势描述,并由哈梅克常数A定义。我们使用稀释气体近似和单组分宏观流体模型将实验静态因子Ki与相互作用势V(x)的理论表达式相关联。这得出哈梅克常数A为0.06±0.01kBT,有效电荷q在低离子强度(ω = 0.0022 M)时为18±1,在高离子强度(ω = 0.1472 M)时为50±5。
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