Veitshans T, Klimov D, Thirumalai D
Laboratoire de Spectrométrie Physique, Université J Fourier, Grenoble, France.
Fold Des. 1997;2(1):1-22. doi: 10.1016/S1359-0278(97)00002-3.
Recent experimental and theoretical studies have revealed that protein folding kinetics can be quite complex and diverse depending on various factors such as size of the protein sequence and external conditions. For example, some proteins fold apparently in a kinetically two-state manner, whereas others follow complex routes to the native state. We have set out to provide a theoretical basis for understanding the diverse behavior seen in the refolding kinetics of proteins in terms of properties that are intrinsic to the sequence.
The folding kinetics of a number of sequences for off-lattice continuum models of proteins is studied using Langevin simulations at two different values of the friction coefficient. We show for these models that there is a remarkable correlation between folding time, tau F, and sigma = (T theta - TF)/T theta, where T theta and TF are the equilibrium collapse and folding transition temperatures, respectively. The microscopic dynamics reveals that several scenarios for the kinetics of refolding arise depending on the range of values of sigma. For relatively small sigma, the chain reaches the native conformation by a direct native conformation nucleation collapse (NCNC) mechanism without being trapped in any detectable intermediates. For moderate and large values of sigma, the kinetics is described by the kinetic partitioning mechanism, according to which a fraction of molecules phi (kinetic partition factor) reach the native conformation via the NCNC mechanism. The remaining fraction attains the native state by off-pathway processes that involve trapping in several misfolded structures. The rate-determining step in the off-pathway processes is the transition from the misfolded structures to the native state. The partition factor phi is also determined by sigma: the smaller the value of sigma, the larger is phi. The qualitative aspects of our results are found to be independent of the friction coefficient. The simulation results and theoretical arguments are used to obtain estimates for timescales for folding via the NCNC mechanism in small proteins, those with less than about 70 amino acid residues.
We have shown that the various scenarios for folding of proteins, and possibly other biomolecules, can be classified solely in terms of sigma. Proteins with small values of sigma reach the native conformation via a nucleation collapse mechanism and their energy landscape is characterized by having one dominant native basin of attraction (NBA). On the other hand, proteins with large sigma get trapped in competing basins of attraction (CBAs) in which they adopt misfolded structures. Only a small fraction of molecules access the native state rapidly when sigma is large. For these sequences, the majority of the molecules approach the native state by a three-stage multipathway mechanism in which the rate-determining step involves a transition from one of the CBAs to the NBA.
最近的实验和理论研究表明,蛋白质折叠动力学可能相当复杂且多样,这取决于各种因素,如蛋白质序列的大小和外部条件。例如,一些蛋白质显然以动力学两态方式折叠,而另一些则遵循复杂的途径达到天然状态。我们已着手从序列固有的特性出发,为理解蛋白质重折叠动力学中观察到的多样行为提供理论基础。
使用朗之万模拟在两个不同的摩擦系数值下研究了蛋白质的非格点连续体模型的多个序列的折叠动力学。对于这些模型,我们表明折叠时间τF与σ = (Tθ - TF)/Tθ之间存在显著相关性,其中Tθ和TF分别是平衡塌缩温度和折叠转变温度。微观动力学表明,根据σ值的范围,会出现几种重折叠动力学的情况。对于相对较小的σ,链通过直接的天然构象成核塌缩(NCNC)机制达到天然构象,而不会被困在任何可检测的中间体中。对于中等和较大的σ值,动力学由动力学分配机制描述,根据该机制,一部分分子φ(动力学分配因子)通过NCNC机制达到天然构象。其余部分通过涉及被困在几种错误折叠结构中的非途径过程达到天然状态。非途径过程中的速率决定步骤是从错误折叠结构到天然状态的转变。分配因子φ也由σ决定:σ值越小,φ越大。我们结果的定性方面被发现与摩擦系数无关。模拟结果和理论论证用于获得小蛋白质(氨基酸残基少于约70个)通过NCNC机制折叠的时间尺度估计。
我们已经表明,蛋白质以及可能其他生物分子的各种折叠情况可以仅根据σ进行分类。σ值小的蛋白质通过成核塌缩机制达到天然构象,其能量景观的特征是具有一个主要的天然吸引盆地(NBA)。另一方面,σ值大的蛋白质被困在竞争吸引盆地(CBA)中,在其中它们采用错误折叠结构。当σ大时,只有一小部分分子迅速进入天然状态。对于这些序列,大多数分子通过三阶段多途径机制接近天然状态,其中速率决定步骤涉及从一个CBA到NBA的转变。
