Integrating highly quantitative proteomics and genome-scale metabolic modeling to study pH adaptation in the human pathogen Enterococcus faecalis

Großeholz, Ruth; Koh, Ching-Chiek; Veith, Nadine; Fiedler, Tomas; Strauss, Madlen; Olivier, Brett G.; Collins, Ben C.; Schubert, Olga T.; Bergmann, Frank; Kreikemeyer, Bernd; Aebersold, Ruedi; Kummer, Ursula

doi:10.1038/npjsba.2016.17

Cited by 34 publications

(54 citation statements)

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“…Constraints are imposed on a flux as upper- and lower-bounds to limit the maximum and minimum values that each flux can take. Constraints could reflect media conditions, where uptake and secretions rates are limited, or reaction velocities of internal enzymes obtained from experimental data [ 12 , 13 ]. Accordingly, each flux with constraints is formulated as: …”

Section: Application Of Bacterial Metabolic Network To Study Metabolmentioning

confidence: 99%

Understanding the host-microbe interactions using metabolic modeling

Jansma

Aidy

2021

Microbiome

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The human gut harbors an enormous number of symbiotic microbes, which is vital for human health. However, interactions within the complex microbiota community and between the microbiota and its host are challenging to elucidate, limiting development in the treatment for a variety of diseases associated with microbiota dysbiosis. Using in silico simulation methods based on flux balance analysis, those interactions can be better investigated. Flux balance analysis uses an annotated genome-scale reconstruction of a metabolic network to determine the distribution of metabolic fluxes that represent the complete metabolism of a bacterium in a certain metabolic environment such as the gut. Simulation of a set of bacterial species in a shared metabolic environment can enable the study of the effect of numerous perturbations, such as dietary changes or addition of a probiotic species in a personalized manner. This review aims to introduce to experimental biologists the possible applications of flux balance analysis in the host-microbiota interaction field and discusses its potential use to improve human health.

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Section: Application Of Bacterial Metabolic Network To Study Metabolmentioning

confidence: 99%

Understanding the host-microbe interactions using metabolic modeling

Jansma

Aidy

2021

Microbiome

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“…A newly developed resource, AGORA (assembly of gut organisms through reconstruction and analysis), provides draft reconstructions for over 700 members of the human gut microbiota, all compatible with Recon2, creating a platform for larger community models [74]. In parallel, others have developed highly curated models of gut pathogens including C. difficile [27] and Enterococcus faecalis [29,75] (Table 1). Simplified methods for multi-model amalgamation and further curation of commensal models are needed to bring existing work together to build a predictive genome-scale metabolic model of the gut microbiota that can be perturbed by intestinal pathogens.…”

Section: Future Directionsmentioning

confidence: 99%

Biomedical applications of genome-scale metabolic network reconstructions of human pathogens

Dunphy

Papin

2018

Current Opinion in Biotechnology

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The growing global threat of antibiotic resistant human pathogens has coincided with improved methods for developing and using genome-scale metabolic network reconstructions. Consequently, there has been an increase in the number of high-quality reconstructions of relevant human and zoonotic pathogens. Novel biomedical applications of pathogen reconstructions focus on three key aspects of pathogen behavior: the evolution of antibiotic resistance, virulence factor production, and host-pathogen interactions. New methods using these reconstructions aim to improve understanding of microbe pathogenicity and guide the development of new therapeutic strategies. This review summarizes the latest ways that genome-scale metabolic network reconstructions have been used to study human pathogens and suggests future applications with the potential to mitigate infectious disease.

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“…Transcriptomes are integrated for genome-scale model reconstruction by serving as a proxy for the activity levels of relevant enzymes [26]. However, it is well understood that transcript levels often represent the levels of their corresponding proteins poorly [46]. Therefore, it is expected that proteomic data integration can constrain genome-scale models more effectively.…”

Section: Discussionmentioning

confidence: 99%

Integration of Time-Series Transcriptomic Data with Genome-Scale CHO Metabolic Models for mAb Engineering

Huang

Yoon

2020

Processes

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Chinese hamster ovary (CHO) cells are the most commonly used cell lines in biopharmaceutical manufacturing. Genome-scale metabolic models have become a valuable tool to study cellular metabolism. Despite the presence of reference global genome-scale CHO model, context-specific metabolic models may still be required for specific cell lines (for example, CHO-K1, CHO-S, and CHO-DG44), and for specific process conditions. Many integration algorithms have been available to reconstruct specific genome-scale models. These methods are mainly based on integrating omics data (i.e., transcriptomics, proteomics, and metabolomics) into reference genome-scale models. In the present study, we aimed to investigate the impact of time points of transcriptomics integration on the genome-scale CHO model by assessing the prediction of growth rates with each reconstructed model. We also evaluated the feasibility of applying extracted models to different cell lines (generated from the same parental cell line). Our findings illustrate that gene expression at various stages of culture slightly impacts the reconstructed models. However, the prediction capability is robust enough on cell growth prediction not only across different growth phases but also in expansion to other cell lines.

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Integrating highly quantitative proteomics and genome-scale metabolic modeling to study pH adaptation in the human pathogen Enterococcus faecalis

Cited by 34 publications

References 50 publications

Understanding the host-microbe interactions using metabolic modeling

Understanding the host-microbe interactions using metabolic modeling

Biomedical applications of genome-scale metabolic network reconstructions of human pathogens

Integration of Time-Series Transcriptomic Data with Genome-Scale CHO Metabolic Models for mAb Engineering

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