单分子解折叠力分布揭示了漏斗状的能量景观。
Single-molecule unfolding force distributions reveal a funnel-shaped energy landscape.
作者信息
Schlierf Michael, Rief Matthias
出版信息
Biophys J. 2006 Feb 15;90(4):L33-5. doi: 10.1529/biophysj.105.077982. Epub 2005 Dec 16.
Abstract
The protein folding process is described as diffusion on a high-dimensional energy landscape. Experimental data showing details of the underlying energy surface are essential to understanding folding. So far in single-molecule mechanical unfolding experiments a simplified model assuming a force-independent transition state has been used to extract such information. Here we show that this so-called Bell model, although fitting well to force velocity data, fails to reproduce full unfolding force distributions. We show that by applying Kramers' diffusion model, we were able to reconstruct a detailed funnel-like curvature of the underlying energy landscape and establish full agreement with the data. We demonstrate that obtaining spatially resolved details of the unfolding energy landscape from mechanical single-molecule protein unfolding experiments requires models that go beyond the Bell model.
摘要
蛋白质折叠过程被描述为在高维能量景观上的扩散。展示潜在能量表面细节的实验数据对于理解折叠至关重要。到目前为止,在单分子机械解折叠实验中,一直使用一个假设过渡态与力无关的简化模型来提取此类信息。在此我们表明,这个所谓的贝尔模型虽然能很好地拟合力 - 速度数据,但无法重现完整的解折叠力分布。我们表明,通过应用克莱默斯扩散模型,我们能够重建潜在能量景观的详细漏斗状曲率,并与数据完全吻合。我们证明,从机械单分子蛋白质解折叠实验中获取解折叠能量景观的空间分辨细节需要超越贝尔模型的模型。
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