Urszula M Migas, Michelle K Quinn, Jennifer J McManus
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引用次数: 3
摘要
蛋白质的自组装已经在体外控制条件下进行了广泛的研究,最近在生物环境中进行了研究。在生物学中,蛋白质的自组装可以是蛋白质凝结病发病机制的一个特征,也可以在正常的生理功能中发生,例如在细胞内非膜结合细胞器的形成过程中。为了充分确定组装过程的机制,通常需要使用纯化蛋白溶液进行体外控制实验。然而,将从受控实验中获得的见解与复杂生物环境中的见解直接联系起来仍然是一个挑战。利用人γ - d -晶体蛋白(一种与先天性白内障相关的蛋白质)的P23T突变体,我们已经证明,用纯化蛋白溶液的相图测量的平衡溶解度边界和溶液行为与在人工细胞(没有荧光标记)和哺乳动物细胞中形成的凝聚物中无细胞表达培养基中表达的蛋白质的组装一致。从而直接将体外测量与生理条件下进行的测量联系起来。
Protein self-assembly following in situ expression in artificial and mammalian cells.
The self-assembly of proteins has been widely studied in controlled in vitro conditions, and more recently in biological environments. The self-assembly of proteins in biology can be a feature of the pathogenesis of protein condensation disease, or can occur during normal physiological function, for example during the formation of intracellular non-membrane bound organelles. To determine the mechanisms for the assembly process fully, controlled in vitro experiments using purified protein solutions are often required. However, making direct connections between insights gathered from controlled experiments and those in complex biological environments remains a challenge. Using the P23T mutant of human γD-crystallin, a protein associated with congenital cataract, we have demonstrated that the equilibrium solubility boundary and solution behavior measured using phase diagrams of purified protein solutions is consistent with the assembly of the protein expressed in cell-free expression medium in artificial cells (without fluorescent labelling) and condensates formed in mammalian cells, thereby directly connecting in vitro measurements with those performed under physiological conditions.
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