Steif C, Weber P, Hinz H J, Flossdorf J, Cesareni G, Kokkinidis M
Institut für Physikalische Chemie, Westfälischen Wilhelms-Universität, Münster, Germany.
Biochemistry. 1993 Apr 20;32(15):3867-76. doi: 10.1021/bi00066a005.
Detailed thermodynamic and spectroscopic studies were carried out on the ColE1-ROP protein in order to establish a quantitative basis for the contribution of noncovalent interactions to the stability of four-helix-bundle proteins. The energetics of both heat- and GdnHCl-induced denaturation were measured by differential scanning microcalorimetry (DSC) and/or by following the change in circular dichroism in the far-UV range. Sedimentation equilibrium analyses were performed to characterize the state of aggregation of the protein. No intermediate species could be detected during thermal unfolding of the dimer in the absence of GdnHCl. Under these conditions ROP unfolding exhibits a strict two-state behavior. The thermodynamic parameters for the reaction N2<->2D are delta HD = 580 +/- 20 kJ.(mol of dimer)-1, delta Cp = 10.3 +/- 1.3 kJ.(mol of dimer)-1.K-1, and Tm = 71.0 +/- 0.5 degrees C. The corresponding Gibbs energy change of unfolding is delta GD degree = 71.7 kJ.(mol of dimer)-1 at 25 degrees C and pH 6. In the presence of 2.5 M GdnHCl, however, ROP dissociates into monomers at elevated temperatures, as the loss of the concentration dependence of Tm and the decreased molecular weight demonstrate. The corresponding transition parameters are delta HD (2.5 M GdnHCl) = 130 +/- 10 kJ.(mol of monomer)-1 and Tm = 51.6 +/- 0.3 degrees C. Isothermal unfolding studies at 19 degrees C using GdnHCl as denaturant yielded a Gibbs energy change of unfolding of 22.4 kJ.(mol of monomer)-1. This extrapolated value is 38% lower than the corresponding delta GD degree value of 35.85 kJ.(mol of monomer)-1 calculated from thermal unfolding for the monomer in the absence of GdnHCl, where the protein is known to be a dimer. These results suggest that subunit interactions are an important source of stabilization of the native four-helix-bundle structure of ROP.
为了建立非共价相互作用对四螺旋束蛋白稳定性贡献的定量基础,对ColE1-ROP蛋白进行了详细的热力学和光谱学研究。通过差示扫描量热法(DSC)和/或跟踪远紫外范围内圆二色性的变化,测量了热诱导和盐酸胍(GdnHCl)诱导变性的能量学。进行沉降平衡分析以表征蛋白质的聚集状态。在没有GdnHCl的情况下,二聚体热解折叠过程中未检测到中间物种。在这些条件下,ROP解折叠表现出严格的两态行为。反应N2<->2D的热力学参数为:ΔHD = 580±20 kJ·(二聚体摩尔)-1,ΔCp = 10.3±1.3 kJ·(二聚体摩尔)-1·K-1,以及Tm = 71.0±0.5℃。在25℃和pH 6条件下,相应的解折叠吉布斯自由能变化为ΔGD° = 71.7 kJ·(二聚体摩尔)-1。然而,在2.5 M GdnHCl存在下,随着Tm对浓度依赖性的丧失和分子量的降低表明,ROP在升高的温度下解离成单体。相应的转变参数为:ΔHD(2.5 M GdnHCl) = 130±10 kJ·(单体摩尔)-1,以及Tm = 51.6±0.3℃。以GdnHCl为变性剂在19℃进行的等温解折叠研究得出解折叠吉布斯自由能变化为22.4 kJ·(单体摩尔)-1。该外推值比在没有GdnHCl时从单体热解折叠计算得到的相应ΔGD°值35.85 kJ·(单体摩尔)-1低38%,已知此时蛋白质为二聚体。这些结果表明,亚基相互作用是ROP天然四螺旋束结构稳定的重要来源。
