预测相对代谢组转换(PRMT):从沿海海洋宏基因组数据集确定代谢转换。

Peter E Larsen, Frank R Collart, Dawn Field, Folker Meyer, Kevin P Keegan, Christopher S Henry, John McGrath, John Quinn, Jack A Gilbert
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引用次数: 91

摘要

背景:世界海洋是各种微生物生命的家园,它们的代谢活动有助于推动地球的生物地球化学循环。宏基因组分析已经彻底改变了我们对这些群落的访问,提供了微生物群落相互作用的系统尺度视角。然而,虽然宏基因组测序可以提供特定基因和分类群在不同环境之间或随时间变化的相对变化的有用估计,但这并不能调查不同代谢物产生或消耗的相对变化。结果:我们提出了一种方法,预测相对代谢周转(PRMT),该方法定义并实现了从宏基因组推断的代谢物空间的探索。我们对来自西英吉利海峡时间序列研究的宏基因组数据的分析表明,预测的相对代谢周转率与测量的环境参数丰度的季节性变化以及观察到的细菌种群结构的季节性变化之间存在相当大的相关性。结论:PRMT方法已成功应用于宏基因组数据,以探索西英吉利海峡微生物代谢组,以产生特异性的,生物学上可测试的假设。提出了有机磷酸盐利用与γ变形杆菌、植物菌和β变形菌有关的假设,几丁质降解为放线菌,以及慢孢菌、衣原菌和绿原菌的潜在小分子生物合成途径。PRMT方法可以作为分析其他宏基因组或转录组数据集的通用工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Predicted Relative Metabolomic Turnover (PRMT): determining metabolic turnover from a coastal marine metagenomic dataset.

Predicted Relative Metabolomic Turnover (PRMT): determining metabolic turnover from a coastal marine metagenomic dataset.

Predicted Relative Metabolomic Turnover (PRMT): determining metabolic turnover from a coastal marine metagenomic dataset.

Predicted Relative Metabolomic Turnover (PRMT): determining metabolic turnover from a coastal marine metagenomic dataset.

Background: The world's oceans are home to a diverse array of microbial life whose metabolic activity helps to drive the earth's biogeochemical cycles. Metagenomic analysis has revolutionized our access to these communities, providing a system-scale perspective of microbial community interactions. However, while metagenome sequencing can provide useful estimates of the relative change in abundance of specific genes and taxa between environments or over time, this does not investigate the relative changes in the production or consumption of different metabolites.

Results: We propose a methodology, Predicted Relative Metabolic Turnover (PRMT) that defines and enables exploration of metabolite-space inferred from the metagenome. Our analysis of metagenomic data from a time-series study in the Western English Channel demonstrated considerable correlations between predicted relative metabolic turnover and seasonal changes in abundance of measured environmental parameters as well as with observed seasonal changes in bacterial population structure.

Conclusions: The PRMT method was successfully applied to metagenomic data to explore the Western English Channel microbial metabalome to generate specific, biologically testable hypotheses. Generated hypotheses linked organic phosphate utilization to Gammaproteobactaria, Plantcomycetes, and Betaproteobacteria, chitin degradation to Actinomycetes, and potential small molecule biosynthesis pathways for Lentisphaerae, Chlamydiae, and Crenarchaeota. The PRMT method can be applied as a general tool for the analysis of additional metagenomic or transcriptomic datasets.

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