脲和盐酸胍诱导的卵清溶菌酶分子去折叠过程中各稳定构象态的分布和过渡

高等学校化学学报 ›› 2011, Vol. 32 ›› Issue (7): 1497.

脲和盐酸胍诱导的卵清溶菌酶分子去折叠过程中各稳定构象态的分布和过渡

张潭, 边六交

西北大学生命科学学院, 西安 710069

收稿日期:2010-09-13 修回日期:2010-10-28 出版日期:2011-07-10 发布日期:2011-06-02
通讯作者: 边六交 E-mail:bianliujiao@sohu.com
基金资助:
国家自然科学基金(批准号: 21075097) 资助.

Distribution and Transition of Stable Conformations of Hen Egg White Lysozymes in Their Unfolding Induced by Urea and Guanidine Hydrochloride Solutions

ZHANG Tan, BIAN Liu-Jiao^*

College of Life Science, Northwest University, Xi'an 710069, China

Received:2010-09-13 Revised:2010-10-28 Online:2011-07-10 Published:2011-06-02
Contact: BIAN Liu-Jiao E-mail:bianliujiao@sohu.com
Supported by:
国家自然科学基金(批准号: 21075097) 资助.

摘要/Abstract

摘要： 以内源荧光光谱和荧光相图法研究了脲和盐酸胍诱导的卵清溶菌酶分子去折叠过程，结果表明，当变性液中脲和盐酸胍浓度分别为约4.0和3.0mol/L时，它们的去折叠过程均存在一个折叠中间态溶菌酶分子，这两个去折叠过程均符合“三态模型”。在卵清溶菌酶分子“三态”去折叠过程的基础上，通过变性剂分子和卵清溶菌酶分子之间的缔合－解离作用，给出了一个定量描述在此去折叠过程中卵清溶菌酶分子残余活性率随溶液中脲和盐酸胍浓度变化的方程。这个方程包含两个特征展开参数，一个是蛋白质分子从一个稳定构象态过渡到另一个稳定构象态的热力学平衡常数k，另一个是在此过渡过程中平均每个蛋白质分子所结合的变性剂分子数目m。通过这两个特征展开参数，能够定量描述脲和盐酸胍诱导的卵清溶菌酶分子天然态、折叠中间态和完全展开态随变性液中脲和盐酸胍浓度的分布和过渡。

关键词: 卵清溶菌酶, 去折叠, 脲, 盐酸胍, 特征展开参数

Abstract: The unfolding of egg white lysozymes induced by urea and guanidine hydrochloride was studied by using intrinsic fluorescence emission spectra and phase diagram method of fluorescence. The result showed that in these two unfolding procedures, an egg white lysozyme intermediate separately existed at about 4.0 mol/L of urea or 3.0 mol/L of guanidine hydrochloride in denaturation solution, and both of these two unfolding procedures followed a three-state model. Based on the three-state unfolding, an equation which describes the residual activity ratios of egg white lysozymes under different urea and guanidine hydrochloride concentrations in denaturation solution was presented and through this equation two characteristic unfolding parameters, the thermodynamic equilibrium constant k for the conformational transition of protein molecules from their one conformational states to their another ones and the number m of denaturant molecules associated with one protein molecule during the unfolding of protein molecules, can be simultaneously derived. Through using these two characteristic unfolding parameters, we could further describe the distribution and transition of each conformational state of egg white lysozymes under different urea and guanidine hydrochloride concentrations in denaturation solution.

Key words: Egg white lysozyme, Unfolding, Urea, Guanidine hydrochloride, Characteristic unfolding parameter

TrendMD:

张潭边六交. 脲和盐酸胍诱导的卵清溶菌酶分子去折叠过程中各稳定构象态的分布和过渡. 高等学校化学学报, 2011, 32(7): 1497.

ZHANG Tan, BIAN Liu-Jiao*. Distribution and Transition of Stable Conformations of Hen Egg White Lysozymes in Their Unfolding Induced by Urea and Guanidine Hydrochloride Solutions. Chem. J. Chinese Universities, 2011, 32(7): 1497.

参考文献

[1] Chimon S., Ishii Y.. J. Am. Chem. Soc. [J], 2005, 127: 13472-13473 [2] Anand R., Marmorstein R.. J. Biol. Chem. [J], 2007, 282: 35425-35429 [3] Grimsrud P. A., Xie H., Griffin T. J., Bernlohr D. A.. J. Biol. Chem. [J], 2008, 283: 21837-21841 [4] Gorovits B. M., McGee W. A., Horowitz P. M.. Biochim. Biophys. Acta [J], 1998, 1382: 120-128 [5] ZOU Cheng-Lu (邹承鲁). The second genetic coding ? Studies on the nascent peptide and protein folding (第二遗传密码？新生肽链及蛋白质折叠的研究) [M], Changsha: Hu’nan Science and Technology Press, 1997: 59-61. [6] Kuznetsova I. M., Turoverov K. K., Uversky V. N.. J. Proteome Res. [J], 2004, 3: 485-494 [7] Latypov R. F., Cheng H., Roder N. A.. J. Mol. Biol. [J], 2006, 357: 1009-1025 [8] Uversky V. N., Narizhneva N. V., Kirschstein S. O., Winter S., Lober G.. Fold Des. [J], 1997, 2: 163-172 [9] Muralidhar D., Jobby M. K., Krishnan K.. J. Biol Chem. [J], 2005, 280: 15569-15578 [10] Uversky V. N., Ptitsyn O. B.. J. Mol. Biol. [J], 1996, 255: 215-228 [11] Kurganov B. I.. Biochemistry (Moscow) [J], 2002, 67: 409-422 [12] Uversky V. N., Ptitsyn O. B.. Biochemistry [J], 1994, 33: 2782-2791 [13] Kuznetsova I. M., Stepanenko O. V., Turoverov K. K.. Biochim. et Biophys. Acta [J], 2002, 1596: 138-155 [14] BIAN Liu-Jiao (边六交), YANG Xiao-Yang (杨晓燕), Liu Li (刘莉). Acta Chim. Sinica (化学学报) [J], 2005, 63: 1081-1086 [15] Bian L. J., Yang X. Y. , Liu L. Chin. J. Chem. [J], 2006, 24: 653-659 [16] LIANG Chang-Li (梁长利), BIAN Liu-Jiao (边六交). J. Anal. Sci. (分析科学学报) [J], 2006, 22: 641-645 [17] BIAN Liu-Jiao (边六交), LIANG Chang-Li (梁长利), YANG Xiao-Yang (杨晓燕), Liu Li (刘莉). Acta Chim. Sinica (化学学报) [J], 2007, 65: 2891-2897 [18] Bian L. J., Liang C. L., Yang X. Y., Liu L.. Chin. J. Chem. [J], 2007, 25: 364-369 [19] Bian L. J., Dong F. X., Liang C. L., Yang X. Y., Liu L.. Chin. J. Chem. [J], 2007, 25: 1896-1903 [20] Rozema D., Gellman S. H.. Biochemistry [J], 1996, 35: 15760-15771 [21] YANG Fang (杨芳), LIANG Yi (梁毅), YANG Fang (杨芳(小)). Acta Chim. Sinica (化学学报) [J], 2003, 61: 803-807