Department of Biosystems Science and Engineering and SIB Swiss Institute of Bioinformatics, ETH Zurich, 4058, Basel, Switzerland.
Ph.D. Program Systems Biology, Life Science Zurich Graduate School, Zurich, Switzerland.
Nat Commun. 2023 Mar 27;14(1):1699. doi: 10.1038/s41467-023-37429-5.
Metabolic phenotypes are pivotal for many areas, but disentangling how evolutionary history and environmental adaptation shape these phenotypes is an open problem. Especially for microbes, which are metabolically diverse and often interact in complex communities, few phenotypes can be determined directly. Instead, potential phenotypes are commonly inferred from genomic information, and rarely were model-predicted phenotypes employed beyond the species level. Here, we propose sensitivity correlations to quantify similarity of predicted metabolic network responses to perturbations, and thereby link genotype and environment to phenotype. We show that these correlations provide a consistent functional complement to genomic information by capturing how network context shapes gene function. This enables, for example, phylogenetic inference across all domains of life at the organism level. For 245 bacterial species, we identify conserved and variable metabolic functions, elucidate the quantitative impact of evolutionary history and ecological niche on these functions, and generate hypotheses on associated metabolic phenotypes. We expect our framework for the joint interpretation of metabolic phenotypes, evolution, and environment to help guide future empirical studies.
代谢表型在许多领域都至关重要,但要弄清楚进化历史和环境适应如何塑造这些表型,这仍是一个悬而未决的问题。特别是对于微生物来说,它们的代谢方式多种多样,而且经常在复杂的群落中相互作用,很少有表型可以直接确定。相反,通常从基因组信息推断潜在的表型,而且很少有模型预测的表型超越物种水平。在这里,我们提出了敏感性相关性来量化预测代谢网络对干扰的反应的相似性,从而将基因型和环境与表型联系起来。我们表明,这些相关性通过捕捉网络上下文如何塑造基因功能,为基因组信息提供了一致的功能补充。例如,这使得我们能够在生物体层面上对所有生命领域进行系统发育推断。对于 245 种细菌物种,我们确定了保守和可变的代谢功能,阐明了进化历史和生态位对这些功能的定量影响,并对相关的代谢表型提出了假设。我们期望我们用于联合解释代谢表型、进化和环境的框架能够帮助指导未来的实证研究。
