Colón W, Elöve G A, Wakem L P, Sherman F, Roder H
Institute for Cancer Research, Fox Chase Cancer Center, Philadelphia, Pennsylvania 19111, USA.
Biochemistry. 1996 Apr 30;35(17):5538-49. doi: 10.1021/bi960052u.
The pairing of two alpha-helices at opposite ends of the chain is a highly conserved structural motif found throughout the cytochrome c family of proteins. It has previously been shown that association of the N- and C-terminal helices is a critical early event in the folding process of horse cytochrome c and is responsible for the formation of a partially folded intermediate (INC). In order to gain further insight into the structural and energetic basis of helix packing interactions and their role in folding, we prepared a series of horse cytochrome c variants in which Leu94, a critical residue at the helix contact site, was replaced by Ile, Val, or Ala. The Ile and Val substitutions resulted in minor changes in the stability of the native state, indicating that conservative mutations can be accommodated at the helix interface with only minor structural perturbations. In contrast, the L94A mutation resulted in a 3.5 kcal/mol decrease in unfolding free energy, suggesting that the smaller Ala side chain causes severe packing defects at the helix interface. The effect of these mutations on the kinetics of folding and unfolding as a function of denaturant concentration was studied by a systematic series of stopped-flow fluorescence measurements. The proteins with Leu, Ile, or Val at position 94 exhibit a major unresolved fluorescence change during the 1-ms dead time of the stopped-flow refolding measurements, while this effect is less pronounced in L94A, indicating that the rapid formation of a compact state (IC) with largely quenched Trp59 fluorescence is favored by a large hydrophobic side chain at the helix-helix interface. Despite their small effects on overall stability, the L94I and L94V mutations result in a substantial reduction in the relative amplitude of the fastest observable folding phase (formation of INC) consistent with a strong decrease in the population of INC compared to the wild-type protein. This effect is amplified in the case of the destabilizing L94A variant, which exhibits slower folding kinetics and negligible accumulation of INC. Whereas the presence of a large hydrophobic side chain at position 94 is sufficient for the stabilization of IC, the subsequent partially folded intermediate, INC, is stabilized by specific interactions that are responsible for the proper packing of the two alpha-helices.
在细胞色素c蛋白家族中,链两端的两个α-螺旋配对是一种高度保守的结构基序。此前已有研究表明,N端和C端螺旋的缔合是马细胞色素c折叠过程中的一个关键早期事件,并且负责形成部分折叠中间体(INC)。为了进一步深入了解螺旋堆积相互作用的结构和能量基础及其在折叠中的作用,我们制备了一系列马细胞色素c变体,其中螺旋接触位点的关键残基Leu94被Ile、Val或Ala取代。Ile和Val取代导致天然态稳定性发生微小变化,表明保守突变在螺旋界面处仅引起微小的结构扰动即可被容纳。相比之下,L94A突变导致解折叠自由能降低3.5千卡/摩尔,这表明较小的Ala侧链在螺旋界面处导致严重的堆积缺陷。通过一系列系统的停流荧光测量研究了这些突变对折叠和解折叠动力学随变性剂浓度变化的影响。在停流重折叠测量的1毫秒死时间内,94位为Leu、Ile或Val的蛋白质表现出主要的未解析荧光变化,而在L94A中这种效应不太明显,这表明螺旋-螺旋界面处的大疏水侧链有利于快速形成具有基本淬灭的Trp59荧光的紧密状态(IC)。尽管L94I和L94V突变对整体稳定性影响较小,但与野生型蛋白质相比,它们导致最快可观察到的折叠相(INC形成)的相对幅度大幅降低,这与INC群体的强烈减少一致。在不稳定的L94A变体中这种效应被放大,该变体表现出较慢的折叠动力学且INC的积累可忽略不计。虽然94位存在大疏水侧链足以稳定IC,但随后的部分折叠中间体INC通过负责两个α-螺旋正确堆积的特异性相互作用而稳定。
