Deepdefense:利用深度学习注释原核生物的免疫系统。

IF 11.8 2区 生物学 Q1 MULTIDISCIPLINARY SCIENCES
Sven Hauns, Omer S Alkhnbashi, Rolf Backofen
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引用次数: 0

摘要

背景:由于不断的进化军备竞赛,古菌和细菌进化出了丰富多样的免疫反应,以保护自身免受噬菌体的侵害。自从发现和应用 CRISPR-Cas 适应性免疫系统以来,已经发现了许多新的候选免疫系统。以前识别这些新型免疫系统的方法依赖于基于隐马尔可夫模型(HMM)的同源物搜索,或使用劳动密集型和昂贵的湿实验室实验。为了帮助寻找免疫系统基因组并对其进行分类,我们利用机器学习对已知的免疫系统蛋白质进行分类,并在基因组中发现潜在的候选者。近年来,神经网络在分类和预测蛋白质功能方面取得了可喜的成果。然而,这些方法通常是在封闭世界假设下运行的,即假定所有潜在结果或类别都是已知的,并包含在训练数据集中。这一假设在现实世界中并不总是成立的,例如在基因组学中,可能会出现新的样本,而这些样本之前在训练阶段并没有考虑到:在这项工作中,我们探索了用于免疫蛋白质分类的神经网络,处理了在全基因组搜索中剔除无关蛋白质的不同方法,并建立了一个基准。然后,我们对方法的准确性进行了优化。在此基础上,我们开发了一种名为 Deepdefense 的算法,用于根据基因组预测免疫盒类别。这种设计通过分析模型预测置信度值的变化,有助于区分与免疫系统相关和不相关的蛋白质,从而帮助识别已知和潜在的新型免疫系统蛋白质。最后,我们对照基于 HMM 的方法测试了我们检测基因组中免疫系统的方法:Deepdefense 可以自动检测基因,并使用 2 种模型分类来定义盒注释和分类。这是通过创建一个优化的深度学习模型来注释免疫系统,并结合校准方法和第二个模型来扫描整个基因组实现的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Deepdefense: annotation of immune systems in prokaryotes using deep learning.

Background: Due to a constant evolutionary arms race, archaea and bacteria have evolved an abundance and diversity of immune responses to protect themselves against phages. Since the discovery and application of CRISPR-Cas adaptive immune systems, numerous novel candidates for immune systems have been identified. Previous approaches to identifying these new immune systems rely on hidden Markov model (HMM)-based homolog searches or use labor-intensive and costly wet-lab experiments. To aid in finding and classifying immune systems genomes, we use machine learning to classify already known immune system proteins and discover potential candidates in the genome. Neural networks have shown promising results in classifying and predicting protein functionality in recent years. However, these methods often operate under the closed-world assumption, where it is presumed that all potential outcomes or classes are already known and included in the training dataset. This assumption does not always hold true in real-world scenarios, such as in genomics, where new samples can emerge that were not previously accounted for in the training phase.

Results: In this work, we explore neural networks for immune protein classification, deal with different methods for rejecting unrelated proteins in a genome-wide search, and establish a benchmark. Then, we optimize our approach for accuracy. Based on this, we develop an algorithm called Deepdefense to predict immune cassette classes based on a genome. This design facilitates the differentiation between immune system-related and unrelated proteins by analyzing variations in model-predicted confidence values, aiding in the identification of both known and potentially novel immune system proteins. Finally, we test our approach for detecting immune systems in the genome against an HMM-based method.

Conclusions: Deepdefense can automatically detect genes and define cassette annotations and classifications using 2 model classifications. This is achieved by creating an optimized deep learning model to annotate immune systems, in combination with calibration methods, and a second model to enable the scanning of an entire genome.

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来源期刊
GigaScience
GigaScience MULTIDISCIPLINARY SCIENCES-
CiteScore
15.50
自引率
1.10%
发文量
119
审稿时长
1 weeks
期刊介绍: GigaScience seeks to transform data dissemination and utilization in the life and biomedical sciences. As an online open-access open-data journal, it specializes in publishing "big-data" studies encompassing various fields. Its scope includes not only "omic" type data and the fields of high-throughput biology currently serviced by large public repositories, but also the growing range of more difficult-to-access data, such as imaging, neuroscience, ecology, cohort data, systems biology and other new types of large-scale shareable data.
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