植物miRNA预测的机器学习方法:挑战、进展和未来方向

Zheng Kuang, Yongxin Zhao, Xiaozeng Yang
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引用次数: 0

摘要

MicroRNA (miRNA)是植物体内重要的基因表达调控因子,具有调控植物发育和生长的功能。在miRNA生物发生过程中,由于RNA加工而形成的特征序列和二级结构可用于鉴定独特的miRNA,并导致多种生物信息学工具用于miRNA预测的发展。人工智能(AI),特别是机器学习(ML),已经在图像识别、基因组中的调控元件识别和基因表达预测等各种任务中取得了重大进展。基于人工智能的工具也被用于预测植物mirna,并且与基于模式的工具一样准确。在这篇综述中,我们重点介绍了人工智能在植物mirna预测中的应用。我们演示了如何建立一个预测ML模型来预测mirna,并描述了每一步的潜在缺陷。然后,我们介绍了已经发表的基于ML的工具,并系统地评估了它们的性能。最后,我们讨论了如何为植物miRNA研究人员开发新的人工智能工具。
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Machine learning approaches for plant miRNA prediction: Challenges, advancements, and future directions

MicroRNA (miRNA) is an important regulator of gene expression in plants that functions to regulate plant development and growth. Signature sequences and secondary structures that are formed as a result of RNA processing during miRNA biogenesis can be used to identify unique miRNAs and has led to the development of multiple bioinformatic tools for miRNA prediction. Artificial intelligence (AI), particularly machine learning (ML), has enabled significant progress to be made in various tasks such as image recognition, regulatory element identification in genomes, and gene expression prediction. AI-based tools have also been used to predict plant miRNAs and are as accurate as pattern-based tools. In this review, we focus on the use of AI to predict plant miRNAs. We demonstrate how to establish a predictive ML model to predict miRNAs and describe the potential pitfalls at each step. We then introduce tools based on ML that have been published and systematically assess their performance. Finally, we discuss how new AI tools should be developed for plant miRNA researchers.

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