病毒壳的离散断裂模式揭示了力学构建块。

Discrete fracture patterns of virus shells reveal mechanical building blocks.

机构信息

Faculty of Exact Sciences, Department of Physics and Astronomy, Vrije Universiteit, De Boeleaan 1081, 1081 HV Amsterdam, The Netherlands.

出版信息

Proc Natl Acad Sci U S A. 2011 Aug 2;108(31):12611-6. doi: 10.1073/pnas.1105586108. Epub 2011 Jul 18.

DOI:10.1073/pnas.1105586108

PMID:21768340

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3150942/

Abstract

Viral shells are self-assembled protein nanocontainers with remarkable material properties. They combine simplicity of construction with toughness and complex functionality. These properties make them interesting for bionanotechnology. To date we know little about how virus structure determines assembly pathways and shell mechanics. We have here used atomic force microscopy to study structural failure of the shells of the bacteriophage Φ29. We observed rigidity patterns following the symmetry of the capsid proteins. Under prolonged force exertion, we observed fracture along well-defined lines of the 2D crystal lattice. The mechanically most stable building block of the shells was a trimer. Our approach of "reverse engineering" the virus shells thus made it possible to identify stable structural intermediates. Such stable intermediates point to a hierarchy of interactions among equal building blocks correlated with distinct next-neighbor interactions. The results also demonstrate that concepts from macroscopic materials science, such as fracture, can be usefully employed in molecular engineering.

摘要

病毒壳是具有显著材料特性的自组装蛋白纳米容器。它们将构造的简单性与韧性和复杂功能结合在一起。这些特性使它们在生物纳米技术中很有趣。迄今为止，我们对病毒结构如何决定组装途径和壳力学知之甚少。我们在这里使用原子力显微镜研究了噬菌体 Φ29 壳的结构失效。我们观察到了与衣壳蛋白对称性一致的刚性模式。在长时间的力作用下，我们观察到沿着 2D 晶格的明确定义线断裂。壳的机械最稳定的构建块是三聚体。我们对病毒壳的“反向工程”方法使我们能够识别稳定的结构中间体。这种稳定的中间体能指向与不同近邻相互作用相关的等距构建块之间相互作用的层次结构。结果还表明，来自宏观材料科学的概念，如断裂，可以在分子工程中得到有效利用。

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