AliNA - a deep learning program for RNA secondary structure prediction.

IF 2.8 4区医学 Q3 CHEMISTRY, MEDICINAL

Molecular Informatics Pub Date : 2023-12-01 Epub Date: 2023-11-02 DOI:10.1002/minf.202300113

Shamsudin S Nasaev, Artem R Mukanov, Ivan I Kuznetsov, Alexander V Veselovsky

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Abstract

Nowadays there are numerous discovered natural RNA variations participating in different cellular processes and artificial RNA, e. g., aptamers, riboswitches. One of the required tasks in the investigation of their functions and mechanism of influence on cells and interaction with targets is the prediction of RNA secondary structures. The classic thermodynamic-based prediction algorithms do not consider the specificity of biological folding and deep learning methods that were designed to resolve this issue suffer from homology-based methods problems. Herein, we present a method for RNA secondary structure prediction based on deep learning - AliNA (ALIgned Nucleic Acids). Our method successfully predicts secondary structures for non-homologous to train-data RNA families thanks to usage of the data augmentation techniques. Augmentation extends existing datasets with easily-accessible simulated data. The proposed method shows a high quality of prediction across different benchmarks including pseudoknots. The method is available on GitHub for free (https://github.com/Arty40m/AliNA).

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AliNA-一个用于RNA二级结构预测的深度学习程序。

目前已经发现了许多参与不同细胞过程的天然RNA变体和人工RNA。 g.适体、核糖开关。在研究它们的功能和对细胞的影响机制以及与靶标的相互作用时，所需的任务之一是预测RNA二级结构。经典的基于热力学的预测算法没有考虑生物折叠的特异性，为解决这一问题而设计的深度学习方法存在基于同源性的方法问题。在此，我们提出了一种基于深度学习的RNA二级结构预测方法——AliNA（ALIgned Nucleic Acids）。由于使用了数据扩增技术，我们的方法成功地预测了非同源的二级结构以训练数据RNA家族。增强功能利用易于访问的模拟数据扩展了现有数据集。所提出的方法在包括伪节点在内的不同基准上显示出高质量的预测。该方法在GitHub上免费提供(https://github.com/Arty40m/AliNA)。

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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来源期刊

Molecular Informatics CHEMISTRY, MEDICINAL-MATHEMATICAL & COMPUTATIONAL BIOLOGY

CiteScore

7.30

自引率

2.80%

发文量

审稿时长

3 months

期刊介绍： Molecular Informatics is a peer-reviewed, international forum for publication of high-quality, interdisciplinary research on all molecular aspects of bio/cheminformatics and computer-assisted molecular design. Molecular Informatics succeeded QSAR & Combinatorial Science in 2010. Molecular Informatics presents methodological innovations that will lead to a deeper understanding of ligand-receptor interactions, macromolecular complexes, molecular networks, design concepts and processes that demonstrate how ideas and design concepts lead to molecules with a desired structure or function, preferably including experimental validation. The journal''s scope includes but is not limited to the fields of drug discovery and chemical biology, protein and nucleic acid engineering and design, the design of nanomolecular structures, strategies for modeling of macromolecular assemblies, molecular networks and systems, pharmaco- and chemogenomics, computer-assisted screening strategies, as well as novel technologies for the de novo design of biologically active molecules. As a unique feature Molecular Informatics publishes so-called "Methods Corner" review-type articles which feature important technological concepts and advances within the scope of the journal.

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