Abstract
In recent years, the number of large-scale metabolomics studies on various cellular processes in different organisms has increased drastically. However, it remains a major challenge to perform a systematic identification of mechanistic regulatory events that mediate the observed changes in metabolite levels, due to complex interdependencies within metabolic networks. We present the metabolic network segmentation (MNS) algorithm, a probabilistic graphical modeling approach that enables genome-scale, automated prediction of regulated metabolic reactions from differential or serial metabolomics data. The algorithm sections the metabolic network into modules of metabolites with consistent changes. Metabolic reactions that connect different modules are the most likely sites of metabolic regulation. In contrast to most state-of-the-art methods, the MNS algorithm is independent of arbitrary pathway definitions, and its probabilistic nature facilitates assessments of noisy and incomplete measurements. With serial (i.e., time-resolved) data, the MNS algorithm also indicates the sequential order of metabolic regulation. We demonstrated the power and flexibility of the MNS algorithm with three, realistic case studies with bacterial and human cells. Thus, this approach enables the identification of mechanistic regulatory events from large-scale metabolomics data, and contributes to the understanding of metabolic processes and their interplay with cellular signaling and regulation processes.
Highlights
The consolidated notion that metabolites can provide feedback to cellular signaling and alter metabolism is a hallmark of several diseases
We first optimized the parameters used by the metabolic network segmentation (MNS) algorithm (S1 Table), based on a non-targeted metabolomics dataset of 62 Escherichia coli single enzyme knockout and overexpression mutants, which exhibited a wide variety of metabolome phenotypes (S2 Table, details in S1 Text)
The optimization results demonstrated that, for most parameter combinations, the MNS algorithm achieved inferences of regulatory sites that were comparable to those achieved by an expert scientist that manually identified the perturbed enzymes (S3 Table, S4 Fig)
Summary
The consolidated notion that metabolites can provide feedback to cellular signaling and alter metabolism is a hallmark of several diseases. This notion has boosted interest in gaining a mechanistic and quantitative understanding of metabolic phenotypes [1,2,3]. The quality of the data is reflected in the high number of detectable metabolites and the high experimental reproducibility. Due to these advances, it has become common that every study discovers multiple significant metabolite changes. This positive trend, has exacerbated the problem of interpreting metabolome changes
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