基于折叠空间抽象的 RNA 动力学分析。

Analysing RNA-kinetics based on folding space abstraction.

机构信息

Genetics & Experimental Bioinformatics, Faculty of Biology, University of Freiburg, Schänzlestr, 1, 79104, Freiburg, Germany.

出版信息

BMC Bioinformatics. 2014 Feb 28;15:60. doi: 10.1186/1471-2105-15-60.

DOI:10.1186/1471-2105-15-60

PMID:24575751

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3974018/

Abstract

BACKGROUND

RNA molecules, especially non-coding RNAs, play vital roles in the cell and their biological functions are mostly determined by structural properties. Often, these properties are related to dynamic changes in the structure, as in the case of riboswitches, and thus the analysis of RNA folding kinetics is crucial for their study. Exact approaches to kinetic folding are computationally expensive and, thus, limited to short sequences. In a previous study, we introduced a position-specific abstraction based on helices which we termed helix index shapes (hishapes) and a hishape-based algorithm for near-optimal folding pathway computation, called HiPath. The combination of these approaches provides an abstract view of the folding space that offers information about the global features.

RESULTS

In this paper we present HiKinetics, an algorithm that can predict RNA folding kinetics for sequences up to several hundred nucleotides long. This algorithm is based on RNAHeliCes, which decomposes the folding space into abstract classes, namely hishapes, and an improved version of HiPath, namely HiPath2, which estimates plausible folding pathways that connect these classes. Furthermore, we analyse the relationship of hishapes to locally optimal structures, the results of which strengthen the use of the hishape abstraction for studying folding kinetics. Finally, we show the application of HiKinetics to the folding kinetics of two well-studied RNAs.

CONCLUSIONS

HiKinetics can calculate kinetic folding based on a novel hishape decomposition. HiKinetics, together with HiPath2 and RNAHeliCes, is available for download at http://www.cyanolab.de/software/RNAHeliCes.htm.

摘要

背景

RNA 分子，尤其是非编码 RNA，在细胞中发挥着至关重要的作用，其生物功能主要由结构特性决定。通常，这些特性与结构的动态变化有关，如在核酶中，因此分析 RNA 折叠动力学对于它们的研究至关重要。精确的动力学折叠方法在计算上是昂贵的，因此仅限于短序列。在之前的研究中，我们引入了一种基于螺旋的位置特异性抽象，称为螺旋指数形状（hishapes），以及一种基于 hishape 的近最优折叠途径计算算法，称为 HiPath。这些方法的结合提供了折叠空间的抽象视图，提供了有关全局特征的信息。

结果

在本文中，我们提出了 HiKinetics，这是一种可以预测长达数百个核苷酸的序列的 RNA 折叠动力学的算法。该算法基于 RNAHeliCes，它将折叠空间分解为抽象类，即 hishape，以及 HiPath 的改进版本 HiPath2，它估计连接这些类的合理折叠途径。此外，我们分析了 hishape 与局部最优结构的关系，结果加强了使用 hishape 抽象来研究折叠动力学。最后，我们展示了 HiKinetics 在两个研究充分的 RNA 折叠动力学中的应用。

结论

HiKinetics 可以基于新的 hishape 分解来计算动力学折叠。HiKinetics 与 HiPath2 和 RNAHeliCes 一起可在 http://www.cyanolab.de/software/RNAHeliCes.htm 下载。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a3cb/3974018/8b01cb91038f/1471-2105-15-60-1.jpg

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基于折叠空间抽象的 RNA 动力学分析。

Analysing RNA-kinetics based on folding space abstraction.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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