病毒RNA的拓扑结构对其被病毒衣壳蛋白包裹的影响。
Impact of the topology of viral RNAs on their encapsulation by virus coat proteins.
作者信息
van der Schoot Paul, Zandi Roya
机构信息
Group Theory of Polymers and Soft Matter, Eindhoven University of Technology, PO Box 513, 5600 MB, Eindhoven, The Netherlands.
出版信息
J Biol Phys. 2013 Mar;39(2):289-99. doi: 10.1007/s10867-013-9307-y. Epub 2013 Mar 14.
Abstract
Single-stranded RNAs of simple viruses seem to be topologically more compact than other types of single-stranded RNA. It has been suggested that this has an evolutionary purpose: more compact structures are more easily encapsulated in the limited space that the cavity of the virus capsid offers. We employ a simple Flory theory to calculate the optimal amount of polymers confined in a viral shell. We find that the free energy gain or more specifically the efficiency of RNA encapsidation increases substantially with topological compactness. We also find that the optimal length of RNA encapsidated in a capsid increases with the degree of branching of the genome even though this effect is very weak. Further, we show that if the structure of the branching of the polymer is allowed to anneal, the optimal loading increases substantially.
摘要
简单病毒的单链RNA在拓扑结构上似乎比其他类型的单链RNA更为紧凑。有人提出,这具有进化意义:更紧凑的结构更容易被包裹在病毒衣壳腔内有限的空间中。我们运用一个简单的弗洛里理论来计算限制在病毒外壳内的聚合物的最佳数量。我们发现,自由能的增加,或者更具体地说,RNA包裹的效率会随着拓扑紧凑性而大幅提高。我们还发现,衣壳中包裹的RNA的最佳长度会随着基因组分支程度的增加而增加,尽管这种影响非常微弱。此外,我们表明,如果允许聚合物分支结构退火,最佳负载量会大幅增加。
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