Eom Kilho, Baek Seung-Chul, Ahn Jung-Hee, Na Sungsoo
Microsystem Research Center, Korea Institute of Science and Technology, Seoul 136-791, Korea.
J Comput Chem. 2007 Jun;28(8):1400-10. doi: 10.1002/jcc.20672.
The coarse-grained structural model such as Gaussian network has played a vital role in the normal mode studies for understanding protein dynamics related to biological functions. However, for the large proteins, the Gaussian network model is computationally unfavorable for diagonalization of Hessian (stiffness) matrix for the normal mode studies. In this article, we provide the coarse-graining method, referred to as "dynamic model condensation," which enables the further coarse-graining of protein structures consisting of small number of residues. It is shown that the coarser-grained structures reconstructed by dynamic model condensation exhibit the dynamic characteristics, such as low-frequency normal modes, qualitatively comparable to original structures. This sheds light on that dynamic model condensation and may enable one to study the large protein dynamics for gaining insight into biological functions of proteins.
诸如高斯网络这样的粗粒度结构模型在用于理解与生物功能相关的蛋白质动力学的正常模式研究中发挥了至关重要的作用。然而,对于大型蛋白质,高斯网络模型在用于正常模式研究的海森(刚度)矩阵对角化计算方面并不有利。在本文中,我们提供了一种粗粒化方法,称为“动态模型凝聚”,它能够对由少量残基组成的蛋白质结构进行进一步粗粒化。结果表明,通过动态模型凝聚重建的更粗粒度结构表现出诸如低频正常模式等动态特征,在定性上与原始结构相当。这为动态模型凝聚提供了启示,并可能使人们能够研究大型蛋白质动力学以深入了解蛋白质的生物学功能。