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pH诱导的深红红螺菌细胞色素c2的变化及随后的复性：一项15N核磁共振研究

pH-induced changes in Rhodospirillum rubrum cytochrome c2 and subsequent renaturation: an 15N NMR study.

作者信息

Yu L P, Smith G M

机构信息

Department of Food Science and Technology, University of California, Davis 95616.

出版信息

Proc Natl Acad Sci U S A. 1988 May;85(9):2894-8. doi: 10.1073/pnas.85.9.2894.

DOI:10.1073/pnas.85.9.2894

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC280109/

Abstract

The 15N-enriched ferrocytochrome c2 from Rhodospirillum rubrum was studied by 15N NMR at different solvent pH values. The mobility and chemical shift of the N-terminal glutamic acid (335.4 ppm at pH 5.1) were found to depend on pH. It was least mobile between pH 8 and 9.0, which is explained in terms of pH-dependent conformational changes and formation of salt linkages and/or hydrogen bonds. The resonances of the lysine side chains are centered around 341.7 ppm at low pH and move upfield with pH by about 8.4 ppm with pKa values of 10.8. The exchange rates of the epsilon NH protons are lowest near their pKa values. The protein is very stable in the pH range between 4.9 and 10.0 but unfolds abruptly at pH 10.5-11. Denaturation was verified by the measurement of several parameters by NMR. The renaturation of the protein demonstrates that the folding begins with reformation of heme coordination and establishment of a hydrophobic core, followed by positioning of side chains and peptide backbones linking the nucleation centers. The repositioning processes had time scales of minutes to hours in contrast to the reported values of seconds in some studies.

摘要

利用¹⁵N核磁共振对来自深红红螺菌的¹⁵N标记的细胞色素c₂在不同溶剂pH值下进行了研究。发现N端谷氨酸的迁移率和化学位移（在pH 5.1时为335.4 ppm）取决于pH值。在pH 8至9.0之间其迁移率最低，这可以通过pH依赖的构象变化以及盐键和/或氢键的形成来解释。赖氨酸侧链的共振在低pH值时集中在341.7 ppm左右，随着pH值升高向高场移动约8.4 ppm，pKa值为10.8。ε-NH质子的交换率在其pKa值附近最低。该蛋白质在4.9至10.0的pH范围内非常稳定，但在pH 10.5 - 11时会突然展开。通过核磁共振测量几个参数验证了变性。蛋白质的复性表明折叠开始于血红素配位的重新形成和疏水核心的建立，随后是连接成核中心的侧链和肽主链的定位。与一些研究中报道的秒级时间尺度相比，重新定位过程的时间尺度为几分钟到几小时。