KiNext: a portable and scalable workflow for the identification and classification of protein kinases.

IF 2.9 3区 生物学 Q2 BIOCHEMICAL RESEARCH METHODS BMC Bioinformatics Pub Date : 2024-10-25 DOI:10.1186/s12859-024-05953-w
Elisabeth Hellec, Flavia Nunes, Charlotte Corporeau, Alexandre Cormier
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Abstract

Background: Protein kinases are a diverse superfamily of proteins common to organisms across the tree of life that are typically involved in signal transduction, allowing organisms to sense and respond to biotic or abiotic environmental factors. They have important roles in organismal physiology, including development, reproduction, acclimation to environmental stress, while their dysregulation can lead to disease, including several forms of cancer. Identifying the complement of protein kinases (the kinome) of any organism is useful for understanding its physiological capabilities, limitations and adaptations to environmental stress. The increasing availability of genomes makes it now possible to examine and compare the kinomes across a broad diversity of organisms. Here we present a pipeline respecting the FAIR principles (findable, accessible, interoperable and reusable) that facilitates the search and identification of protein kinases from a predicted proteome, and classifies them according to group of serine/threonine/tyrosine protein kinases present in eukaryotes.

Results: KiNext is a Nextflow pipeline that regroups a number of existing bioinformatic tools to search for and classify the protein kinases of an organism in a reproducible manner, starting from a set of amino acid sequences. Conventional eukaryotic protein kinases (ePKs) and atypical protein kinases (aPKs) are identified by using Hidden Markov Models (HMMs) generated from the catalytic domains of kinases. Furthermore, KiNext categorizes ePKs into the eight kinase groups by employing dedicated Hidden Markov Models (HMMs) tailored for each group. The performance of the KiNext pipeline was validated against previously identified kinomes obtained with other tools that were already published for two marine species, the Pacific oyster Crassostrea gigas and the unicellular green alga Ostreoccocus tauri. KiNext outperformed previous results by finding previously unidentified kinases and by attributing a large proportion of previously unclassified kinases to a group in both species. These results demonstrate improvements in kinase identification and classification, all while providing traceability and reproducibility of results in a FAIR pipeline. The default HMM models provided with KiNext are most suitable for eukaryotes, but the pipeline can be easily modified to include HMM models for other taxa of interest.

Conclusion: The KiNext pipeline enables efficient and reproducible identification of kinomes based on predicted amino acid sequences (i.e. proteomes). KiNext was designed to be easy to use, automated, portable and scalable.

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KiNext:用于蛋白激酶鉴定和分类的便携式可扩展工作流程。
背景:蛋白激酶是生命树上生物体中常见的多种超家族蛋白,通常参与信号转导,使生物体能够感知并响应生物或非生物环境因素。它们在生物体的生理过程中发挥着重要作用,包括发育、繁殖、适应环境压力,而它们的失调则可能导致疾病,包括几种形式的癌症。鉴定任何生物体的蛋白激酶补体(激酶组)都有助于了解其生理能力、局限性和对环境压力的适应性。随着基因组可用性的不断提高,现在有可能对多种生物的激酶组进行研究和比较。在此,我们介绍一种遵循 FAIR 原则(可发现、可访问、可互操作和可重复使用)的管道,它有助于从预测的蛋白质组中搜索和鉴定蛋白激酶,并根据真核生物中存在的丝氨酸/苏氨酸/酪氨酸蛋白激酶群对它们进行分类:KiNext是一个Nextflow管道,它重新组合了一些现有的生物信息学工具,从一组氨基酸序列开始,以可重复的方式搜索生物体内的蛋白激酶并对其进行分类。传统的真核生物蛋白激酶(ePKs)和非典型蛋白激酶(aPKs)是通过使用从激酶催化结构域生成的隐马尔可夫模型(HMMs)来识别的。此外,KiNext 还利用为每个激酶组定制的专用隐马尔可夫模型(HMM),将 ePKs 分成八个激酶组。KiNext 管道的性能与之前用其他工具获得的激酶组进行了验证,这些激酶组是针对两个海洋物种(太平洋牡蛎 Crassostrea gigas 和单细胞绿藻 Ostreoccocus tauri)已发表的激酶组进行鉴定的。KiNext 发现了以前未识别的激酶,并在这两个物种中将很大一部分以前未分类的激酶归入了一个群组,其结果优于以前的结果。这些结果证明了激酶鉴定和分类的改进,同时在 FAIR 管道中提供了结果的可追溯性和可重复性。KiNext 提供的默认 HMM 模型最适用于真核生物,但也可以很容易地修改管道,以包括适用于其他感兴趣类群的 HMM 模型:KiNext 管道可根据预测的氨基酸序列(即蛋白质组)高效、可重复地识别激酶组。KiNext 设计为易于使用、自动化、可移植和可扩展。
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来源期刊
BMC Bioinformatics
BMC Bioinformatics 生物-生化研究方法
CiteScore
5.70
自引率
3.30%
发文量
506
审稿时长
4.3 months
期刊介绍: BMC Bioinformatics is an open access, peer-reviewed journal that considers articles on all aspects of the development, testing and novel application of computational and statistical methods for the modeling and analysis of all kinds of biological data, as well as other areas of computational biology. BMC Bioinformatics is part of the BMC series which publishes subject-specific journals focused on the needs of individual research communities across all areas of biology and medicine. We offer an efficient, fair and friendly peer review service, and are committed to publishing all sound science, provided that there is some advance in knowledge presented by the work.
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