Department of Biotechnology, University of Verona, Verona, Italy.
Quadram Institute Bioscience, Norwich, UK.
mSystems. 2022 Oct 26;7(5):e0074122. doi: 10.1128/msystems.00741-22. Epub 2022 Sep 7.
Phages are the most abundant biological entities on the planet, and they play an important role in controlling density, diversity, and network interactions among bacterial communities through predation and gene transfer. To date, a variety of bacteriophage identification tools have been developed that differ in the phage mining strategies used, input files requested, and results produced. However, new users attempting bacteriophage analysis can struggle to select the best methods and interpret the variety of results produced. Here, we present MetaPhage, a comprehensive reads-to-report pipeline that streamlines the use of multiple phage miners and generates an exhaustive report. The report both summarizes and visualizes the key findings and enables further exploration of key results via interactive filterable tables. The pipeline is implemented in Nextflow, a widely adopted workflow manager that enables an optimized parallelization of tasks in different locations, from local server to the cloud; this ensures reproducible results from containerized packages. MetaPhage is designed to enable scalability and reproducibility; also, it can be easily expanded to include new miners and methods as they are developed in this continuously growing field. MetaPhage is freely available under a GPL-3.0 license at https://github.com/MattiaPandolfoVR/MetaPhage. Bacteriophages (viruses that infect bacteria) are the most abundant biological entities on earth and are increasingly studied as members of the resident microbiota community in many environments, from oceans to soils and the human gut. Their identification is of great importance to better understand complex bacterial dynamics and microbial ecosystem function. A variety of metagenome bacteriophage identification tools have been developed that differ in the phage mining strategies used, input files requested, and results produced. To facilitate the management and the execution of such a complex workflow, we developed MetaPhage (MP), a comprehensive reads-to-report pipeline that streamlines the use of multiple phage miners and generates an exhaustive report. The pipeline is implemented in Nextflow, a widely adopted workflow manager that enables an optimized parallelization of tasks. MetaPhage is designed to enable scalability and reproducibility and offers an installation-free, dependency-free, and conflict-free workflow execution.
噬菌体是地球上最丰富的生物实体,它们通过捕食和基因转移,在控制细菌群落的密度、多样性和网络相互作用方面发挥着重要作用。迄今为止,已经开发出了多种噬菌体鉴定工具,它们在使用的噬菌体挖掘策略、所需的输入文件和产生的结果上有所不同。然而,新的用户在尝试进行噬菌体分析时,可能难以选择最佳方法并解释产生的各种结果。在这里,我们提出了 MetaPhage,这是一个综合的从读取到报告的管道,它简化了多种噬菌体挖掘器的使用,并生成了详尽的报告。该报告既总结又可视化了关键发现,并通过交互式可过滤表进一步探索关键结果。该管道是在 Nextflow 中实现的,Nextflow 是一种广泛采用的工作流管理器,它可以在不同的位置(从本地服务器到云端)优化任务的并行化;这确保了来自容器化软件包的可重复结果。MetaPhage 的设计目的是实现可扩展性和可重复性;此外,它还可以轻松扩展,以包括随着这个不断发展的领域中开发的新的挖掘器和方法。MetaPhage 是免费提供的,可在 https://github.com/MattiaPandolfoVR/MetaPhage 上获得,许可证为 GPL-3.0。 噬菌体(感染细菌的病毒)是地球上最丰富的生物实体,并且作为许多环境(从海洋到土壤和人类肠道)中常驻微生物群落的成员,它们的鉴定对于更好地理解复杂的细菌动态和微生物生态系统功能非常重要。已经开发出了多种宏基因组噬菌体鉴定工具,它们在使用的噬菌体挖掘策略、所需的输入文件和产生的结果上有所不同。为了便于管理和执行如此复杂的工作流程,我们开发了 MetaPhage (MP),这是一个综合的从读取到报告的管道,它简化了多种噬菌体挖掘器的使用,并生成了详尽的报告。该管道是在 Nextflow 中实现的,Nextflow 是一种广泛采用的工作流管理器,它可以优化任务的并行化。MetaPhage 的设计目的是实现可扩展性和可重复性,并提供无安装、无依赖项和无冲突的工作流执行。
