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小鼠β-神经生长因子的平衡变性研究

Equilibrium denaturation studies of mouse beta-nerve growth factor.

作者信息

Timm D E, Neet K E

机构信息

Department of Biochemistry, Case Western Reserve University, Cleveland, Ohio 44106.

出版信息

Protein Sci. 1992 Feb;1(2):236-44. doi: 10.1002/pro.5560010205.

DOI:10.1002/pro.5560010205
PMID:1304906
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2142196/
Abstract

Equilibrium denaturation of dimeric mouse beta-nerve growth factor (beta-NGF) has been studied by monitoring changes in the protein's spectroscopic characteristics. Denaturation of beta-NGF in guanidine hydrochloride and urea resulted in an altered intrinsic fluorescence emission spectrum, fluorescence depolarization, and diminished negative circular dichroism. Native-like spectroscopic properties and specific biological activity are restored when denaturant is diluted from unfolded samples, demonstrating that this process is fully reversible. However, refolding of denatured beta-NGF is dependent on the three disulfide bonds present in the native protein and does not readily occur when the disulfide bonds are reduced. Graphical analysis and nonlinear least-squares fitting of beta-NGF denaturation data demonstrate that denaturation is dependent on the concentration of beta-NGF and is consistent with a two-state model involving native dimer and denatured monomer (N2 = 2D). The conformational stability of mouse beta-NGF calculated according to this model is 19.3 +/- 1.1 kcal/mol in 100 mM sodium phosphate at pH 7. Increasing the hydrogen ion concentration resulted in a 25% decrease in beta-NGF stability at pH 4 relative to pH 7.

摘要

通过监测蛋白质光谱特征的变化,研究了二聚体小鼠β-神经生长因子(β-NGF)的平衡变性。β-NGF在盐酸胍和尿素中变性导致其固有荧光发射光谱、荧光去极化发生改变,负圆二色性减弱。当从展开的样品中稀释变性剂时,可恢复类似天然的光谱性质和特定的生物活性,表明该过程是完全可逆的。然而,变性β-NGF的重折叠依赖于天然蛋白质中存在的三个二硫键,当二硫键被还原时,重折叠不容易发生。β-NGF变性数据的图形分析和非线性最小二乘法拟合表明,变性依赖于β-NGF的浓度,并且与涉及天然二聚体和变性单体的两态模型(N2 = 2D)一致。根据该模型计算,在pH 7的100 mM磷酸钠中,小鼠β-NGF的构象稳定性为19.3 +/- 1.1 kcal/mol。相对于pH 7,将氢离子浓度增加导致pH 4时β-NGF稳定性降低25%。

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