Multiscale characterization of macromolecular dynamics: application to photoacitve yellow protein

Proceedings of the Conference on Extreme Science and Engineering Discovery Environment: Gateway to Discovery Pub Date : 2013-07-22 DOI:10.1145/2484762.2484836

M. A. Rohrdanz, Wenwei Zheng, Bradley Lambeth, C. Clementi

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引用次数: 1

Abstract

Photoactive yellow protein was first discovered in Halorhodospira halophilia, causing the bacterium to flee potentially DNA-damaging light, and serves as a model system for signaling proteins. Upon absorption of a blue photon, PYP's chromophore undergoes a trans-to-cis isomerization that disrupts the hydrogen bond network in the core of the protein, resulting in a large conformational change and transformation into the signaling state. Because of the timescales involved, conventional molecular dynamics simulation of this system is practically impossible. In addition, due to the short signaling state lifetime, experimental determination of the signaling-state structure is also challenging. Here we use a combination of tools we have developed: a coarse-grain model [4], an all-atom reconstruction technique [5], locally scaled diffusion maps [9], and our most recent technique diffusion map-directed molecular dynamics [14], to explore the elusive structure of the signaling state of PYP.

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大分子动力学的多尺度表征:在光活性黄色蛋白中的应用

光活性黄色蛋白最早是在嗜盐盐螺旋体中发现的，它能使细菌逃离潜在的dna损伤光，并作为信号蛋白的模型系统。在吸收蓝色光子后，PYP的发色团发生反式到顺式异构化，破坏蛋白质核心的氢键网络，导致大的构象变化并转化为信号状态。由于所涉及的时间尺度，传统的分子动力学模拟实际上是不可能的。此外，由于信号状态寿命短，信号状态结构的实验确定也具有挑战性。在这里，我们使用了我们开发的工具组合:粗颗粒模型[4]，全原子重建技术[5]，局部缩放扩散图[9]，以及我们最新的扩散图定向分子动力学技术[14]，以探索PYP信号状态的难以捉摸的结构。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings of the Conference on Extreme Science and Engineering Discovery Environment: Gateway to Discovery

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