离子强度和pH值对神经丝刷平衡结构的影响。
Effect of the ionic strength and pH on the equilibrium structure of a neurofilament brush.
作者信息
Zhulina E B, Leermakers F A M
机构信息
Institute of Macromolecular Compounds of the Russian Academy of Sciences, St Petersburg, Russia.
出版信息
Biophys J. 2007 Sep 1;93(5):1452-63. doi: 10.1529/biophysj.107.104695. Epub 2007 May 18.
Abstract
Using the numerical model of Scheutjens and Fleer, we investigated, on a self-consistent field level, the equilibrium structure of the neurofilament brush formed by projection domains of the constituent NF-H, NF-M, and NF-L proteins. The phosphorylation of such a brush is a major regulatory process that triggers the relocation of the H tails from the NF core to the brush periphery. We explore how the pH and the ionic strength affect the rearrangements in the NF brush structure upon phosphorylation. We demonstrate that the translocation of H tails in an individual NF occurs as a sharp cooperative transition below and up to the physiological salt concentration. Regularities of this process are reminiscent of the collapse-to-stretching transition in a cylindrical polyelectrolyte brush in a poor solvent. The effect of pH at physiological ionic strength is noticeable only in the acidic range and is more pronounced for a dephosphorylated NF.
摘要
利用朔伊滕斯和弗莱尔的数值模型,我们在自洽场水平上研究了由组成蛋白NF-H、NF-M和NF-L的投影结构域形成的神经丝刷的平衡结构。这种神经丝刷的磷酸化是一个主要的调节过程,它会触发H尾从神经丝核心重新定位到刷状结构的外围。我们探究了pH值和离子强度如何影响磷酸化后神经丝刷结构的重排。我们证明,在单个神经丝中,H尾的易位在低于和直至生理盐浓度时表现为急剧的协同转变。这一过程的规律让人联想到在不良溶剂中圆柱形聚电解质刷从塌陷到伸展的转变。在生理离子强度下,pH值的影响仅在酸性范围内明显,并且对于去磷酸化的神经丝更为显著。
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