Evenäs J, Forsén S, Malmendal A, Akke M
Physical Chemistry 2, Lund University, Lund, S-221 00, Sweden.
J Mol Biol. 1999 Jun 11;289(3):603-17. doi: 10.1006/jmbi.1999.2770.
Previous studies have suggested that the Ca2+-saturated E140Q mutant of the C-terminal domain of calmodulin exhibits equilibrium exchange between "open" and "closed" conformations similar to those of the Ca2+-free and Ca2+-saturated states of wild-type calmodulin. The backbone dynamics of this mutant were studied using15N spin relaxation experiments at three different temperatures. Measurements at each temperature of the15N rate constants for longitudinal and transverse auto-relaxation, longitudinal and transverse cross-correlation relaxation, and the1H-15N cross-relaxation afforded unequivocal identification of conformational exchange processes on microsecond to millisecond time-scales, and characterization of fast fluctuations on picosecond to nanosecond time-scales using model-free approaches. The results show that essentially all residues of the protein are involved in conformational exchange. Generalized order parameters of the fast internal motions indicate that the conformational substates are well folded, and exclude the possibility that the exchange involves a significant population of unfolded or disordered species. The temperature dependence of the order parameters offers qualitative estimates of the contribution to the heat capacity from fast fluctuations of the protein backbone, revealing significant variation between the well-ordered secondary structure elements and the more flexible regions. The temperature dependence of the conformational exchange contributions to the transverse auto-relaxation rate constants directly demonstrates that the microscopic exchange rate constants are greater than 2.7x10(3)s-1at 291 K. The conformational exchange contributions correlate with the chemical shift differences between the Ca2+-free and Ca2+-saturated states of the wild-type protein, thereby substantiating that the conformational substates are similar to the open and closed states of wild-type calmodulin. Taking the wild-type chemical shifts to represent the conformational substates of the mutant and populations estimated previously, the microscopic exchange rate constants could be estimated as 2x10(4)to 3x10(4)s-1at 291 K for a subset of residues. The temperature depen dence of the exchange allows the characterization of apparent energy barriers of the conformational transition, with results suggesting a complex process that does not correspond to a single global transition between substates.
先前的研究表明,钙调蛋白C末端结构域的Ca2+饱和E140Q突变体表现出“开放”和“闭合”构象之间的平衡交换,类似于野生型钙调蛋白的无Ca2+和Ca2+饱和状态。使用15N自旋弛豫实验在三个不同温度下研究了该突变体的主链动力学。在每个温度下测量纵向和横向自弛豫、纵向和横向交叉相关弛豫的15N速率常数,以及1H-15N交叉弛豫,明确识别了微秒到毫秒时间尺度上的构象交换过程,并使用无模型方法表征了皮秒到纳秒时间尺度上的快速波动。结果表明,该蛋白质基本上所有的残基都参与了构象交换。快速内部运动的广义序参数表明,构象亚态折叠良好,排除了交换涉及大量未折叠或无序物种的可能性。序参数的温度依赖性提供了蛋白质主链快速波动对热容量贡献的定性估计,揭示了有序二级结构元件和更灵活区域之间的显著差异。构象交换对横向自弛豫速率常数的温度依赖性直接表明,微观交换速率常数在291 K时大于2.7×10(3)s-1。构象交换贡献与野生型蛋白质的无Ca2+和Ca2+饱和状态之间的化学位移差异相关,从而证实构象亚态类似于野生型钙调蛋白的开放和闭合状态。以野生型化学位移代表突变体的构象亚态和先前估计的群体,对于一部分残基,在291 K时微观交换速率常数可估计为2×10(4)至3×10(4)s-1。交换的温度依赖性允许表征构象转变的表观能垒,结果表明这是一个复杂的过程,并不对应于亚态之间的单一全局转变。
