Metabolic Modelling as a Framework for Metabolomics Data Integration and Analysis

Volkova, Svetlana; Matos, Marta R. A.; Mattanovich, Matthias; Mas, Igor Marín de

doi:10.3390/metabo10080303

Cited by 53 publications

(44 citation statements)

References 162 publications

(261 reference statements)

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“…However, retrosynthesis, performed on a multitude of precursor–product metabolite pairs, might boost the metabolic network complexity. In this case, a similar strategy could be applied as currently performed in the curation of GSMM, i.e., applying CBM to remove non-essential edges on the one hand and to point pathway gaps on the other hand [25] . Further support for particular biotransformation paths can also be provided via another GSMM-applied strategy: pathway mapping using multi-omics data, especially when derived from time-course or comparative studies.…”

Section: Discussionmentioning

confidence: 99%

“…When attempting to complete the metabolic network of a particular species, gaps representing unknown reactions have to be filled in, which demands an exhaustive search for all gene–protein–reaction associations by concatenating gene–protein and protein–reaction information from different databases. Subsequently, a final curation via constraint-based modeling (CBM, see Glossary) [23] , [24] , [25] yields a so-called genome-scale metabolic model (GSMM) [26] , [27] , [28] . Metabolic networks are mainly displayed either as a homogenous network (nodes and edges reflecting metabolites and reactions) or as a bipartite graph characterized by two types of nodes (representing metabolites and enzymes), in which the edges represent links between substrates/products and their respective enzymes.…”

Section: Introductionmentioning

confidence: 99%

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Seeing the forest for the trees: Retrieving plant secondary biochemical pathways from metabolome networks

Desmet

Brouckaert

Boerjan

et al. 2021

Computational and Structural Biotechnology Journal

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Seeing the forest for the trees: Retrieving plant secondary biochemical pathways from metabolome networks

Desmet

Brouckaert

Boerjan

et al. 2021

Computational and Structural Biotechnology Journal

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“…For example, increased metabolite abundances may result either from an elevated metabolism or an accumulation due to the inhibition of individual steps. This issue can be overcome by the use of metabolic flux analyses [ 167 ] or the investigation of additional omics layers [ 168 ].…”

Section: Discussionmentioning

confidence: 99%

Systematic Review of Multi-Omics Approaches to Investigate Toxicological Effects in Macrophages

Karkossa

Raps

Bergen

et al. 2020

IJMS

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Insights into the modes of action (MoAs) of xenobiotics are of utmost importance for the definition of adverse outcome pathways (AOPs), which are essential for a mechanism-based risk assessment. A well-established strategy to reveal MoAs of xenobiotics is the use of omics. However, often an even more comprehensive approach is needed, which can be achieved using multi-omics. Since the immune system plays a central role in the defense against foreign substances and pathogens, with the innate immune system building a first barrier, we systematically reviewed multi-omics studies investigating the effects of xenobiotics on macrophages. Surprisingly, only nine publications were identified, combining proteomics with transcriptomics or metabolomics. We summarized pathways and single proteins, transcripts, or metabolites, which were described to be affected upon treatment with xenobiotics in the reviewed studies, thus revealing a broad range of effects. In summary, we show that macrophages are a relevant model system to investigate the toxicological effects induced by xenobiotics. Furthermore, the multi-omics approaches led to a more comprehensive overview compared to only one omics layer with slight advantages for combinations that complement each other directly, e.g., proteome and metabolome.

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“…Constraint-based modeling (CBM) can overcome the limitations of the kinetic models by reducing the need for complex kinetic parameters. Therefore, this approach has been extensively used for understanding the behavior of genome-wide systems [31]. The main goal of CBM is to build models with high prediction accuracy to analyze the genome-scale networks and shed light on relationships between genotype, phenotype, and environmental conditions [32,33].…”

Section: Constraint-based Modeling: a Mechanistic-driven Approachmentioning

confidence: 99%

Constraint-based modeling and machine learning applications for analysis and optimization of fermentation parameters

Isp

Lewis

et al. 2021

Preprint

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Recent noteworthy advances in the development of high-performing microbial and mammalian strains have enabled the sustainable production of bio-economically valuable substances such as bio-compounds, biofuels, and biopharmaceuticals. However, to obtain an industrially viable mass-production scheme, much time and effort are required. The robust and rational design of fermentation processes requires analysis and optimization of different extracellular conditions and medium components, which have a massive effect on growth and productivity. In this regard, knowledge- and data-driven modeling methods have received much attention. Constraint-based modeling (CBM) is a knowledge-driven mathematical approach that has been widely used in fermentation analysis and optimization due to its capabilities of predicting the cellular phenotype from genotype through high-throughput means. On the other hand, machine learning (ML) is a data-driven statistical method that identifies the data patterns within sophisticated biological systems and processes, where there is inadequate knowledge to represent underlying mechanisms. Furthermore, ML models are becoming a viable complement to constraint-based models in a reciprocal manner when one is used as a pre-step of another. As a result, more predictable models are produced. This review highlights the applications of CBM and ML independently and the combination of these two approaches for analyzing and optimizing fermentation parameters.

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Metabolic Modelling as a Framework for Metabolomics Data Integration and Analysis

Cited by 53 publications

References 162 publications

Seeing the forest for the trees: Retrieving plant secondary biochemical pathways from metabolome networks

Seeing the forest for the trees: Retrieving plant secondary biochemical pathways from metabolome networks

Systematic Review of Multi-Omics Approaches to Investigate Toxicological Effects in Macrophages

Constraint-based modeling and machine learning applications for analysis and optimization of fermentation parameters

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