Toroidal DNA condensates: unraveling the fine structure and the role of nucleation in determining size.

Nicholas V Hud, Igor D Vilfan
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引用次数: 189

Abstract

Toroidal DNA condensates have attracted the attention of biophysicists, biochemists, and polymer physicists for more than thirty years. In the biological community, the quest to understand DNA toroid formation has been motivated by its relevance to gene packing in certain viruses and by the potential use of DNA toroids in artificial gene delivery (e.g., gene therapy). In the physical sciences, DNA toroids are appreciated as a superb model system for studying particle formation by the collapse of a semiflexible, polyelectrolyte polymer. This review focuses on experimental studies from the past few years that have significantly increased our understanding of DNA toroid structure and the mechanism of their formation. Highlights include structural studies that show the DNA strands within toroids to be packed in an ideal hexagonal lattice, and also in regions with a nonhexagonal lattice that are required by the topological constraints associated with winding DNA into a toroid. Recent studies of DNA toroid formation have also revealed that toroid size limits result from a complex interplay between kinetic and thermodynamic factors that govern both toroid nucleation and growth. The work discussed in this review indicates that it will ultimately be possible to obtain substantial control over DNA toroid dimensions.

环状DNA凝聚体:揭示精细结构和成核在确定大小中的作用。
环状DNA凝聚体已经引起了生物物理学家、生物化学家和聚合物物理学家的关注三十多年。在生物界,了解DNA环状体形成的动机是它与某些病毒中的基因包装的相关性,以及DNA环状体在人工基因传递(例如基因治疗)中的潜在用途。在物理科学中,DNA环体被认为是一种极好的模型系统,用于研究由半柔性聚电解质聚合物坍塌形成的颗粒。本文综述了近年来对DNA环面结构及其形成机制的研究进展。重点包括结构研究,表明环面内的DNA链以理想的六边形晶格排列,以及与将DNA缠绕成环面相关的拓扑约束所要求的非六边形晶格区域。最近对DNA环状体形成的研究也表明,环状体的大小限制是由控制环状体成核和生长的动力学和热力学因素之间复杂的相互作用造成的。本综述中讨论的工作表明,最终有可能获得对DNA环面尺寸的实质性控制。
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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