MOLECULAR BIOLOGY AT THE QUANTUM LEVEL: CAN MODERN DENSITY FUNCTIONAL THEORY FORGE THE PATH?

arXiv: Biological Physics Pub Date : 2012-07-04 DOI:10.1142/S1793984412300063

B. Kolb, T. Thonhauser

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引用次数: 10

Abstract

Recent years have seen vast improvements in the ability of rigorous quantum-mechanical methods to treat systems of interest to molecular biology. In this review article, we survey common computational methods used to study such large, weakly bound systems, starting from classical simulations and reaching to quantum chemistry and density functional theory. We sketch their underlying frameworks and investigate their strengths and weaknesses when applied to potentially large biomolecules. In particular, density functional theory — a framework that can treat thousands of atoms on firm theoretical ground — can now accurately describe systems dominated by weak van der Waals interactions. This newfound ability has rekindled interest in using this tried-and-true approach to investigate biological systems of real importance. In this review, we focus on some new methods within the density functional theory that allow for accurate inclusion of the weak interactions that dominate binding in biological macromolecules. Recent work utilizing these methods to study biologically relevant systems will be highlighted, and a vision for the future of density functional theory within molecular biology will be discussed.

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量子水平的分子生物学:现代密度泛函理论能开辟道路吗?

近年来，严格的量子力学方法在处理分子生物学感兴趣的系统方面取得了巨大的进步。在这篇综述文章中，我们调查了用于研究这种大型弱束缚系统的常用计算方法，从经典模拟开始，达到量子化学和密度泛函理论。我们概述了它们的基本框架，并研究了它们在应用于潜在的大型生物分子时的优势和劣势。特别是，密度泛函理论——一个可以在坚实的理论基础上处理数千个原子的框架——现在可以准确地描述由弱范德华相互作用主导的系统。这种新发现的能力重新点燃了人们对使用这种可靠的方法来研究真正重要的生物系统的兴趣。在这篇综述中，我们重点介绍了密度泛函理论中的一些新方法，这些方法可以精确地包含生物大分子中主导结合的弱相互作用。本文将重点介绍利用这些方法研究生物相关系统的最新工作，并讨论分子生物学中密度泛函理论的未来前景。

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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arXiv: Biological Physics

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