Your search keyword '"Metabolic modeling"' showing total 155 results

1. Integrating transcriptional activity in genome-scale models of metabolism.

Author

Banos DT, Trébulle P, and Elati M

Subjects

Phenotype, Genomics, Metabolism, Models, Biological, Transcription, Genetic

Abstract

Background: Genome-scale metabolic models provide an opportunity for rational approaches to studies of the different reactions taking place inside the cell. The integration of these models with gene regulatory networks is a hot topic in systems biology. The methods developed to date focus mostly on resolving the metabolic elements and use fairly straightforward approaches to assess the impact of genome expression on the metabolic phenotype., Results: We present here a method for integrating the reverse engineering of gene regulatory networks into these metabolic models. We applied our method to a high-dimensional gene expression data set to infer a background gene regulatory network. We then compared the resulting phenotype simulations with those obtained by other relevant methods., Conclusions: Our method outperformed the other approaches tested and was more robust to noise. We also illustrate the utility of this method for studies of a complex biological phenomenon, the diauxic shift in yeast.

Published

2017

2. Pan-Cancer, Genome-Scale Metabolic Network Analysis of over 10,000 Patients Elucidates Relationship between Metabolism and Survival.

Author

Bucksot, Jesse, Ritchie, Katherine, Biancalana, Matthew, Cole, John A., and Cook, Daniel

Subjects

*STEROID metabolism, *FOLIC acid metabolism, *GLUTATHIONE, *GENOMICS, *GLYCOLYSIS, *PHOSPHORYLATION, *CANCER patients, *TUMOR markers, *MULTIVARIATE analysis, *KAPLAN-Meier estimator, *METABOLISM, *STATISTICS, *METABOLOMICS, *TUMORS, *SURVIVAL analysis (Biometry), *FATTY acids, *FACTOR analysis, *DATA analysis software, *OVERALL survival, *PROPORTIONAL hazards models, *ALGORITHMS

Abstract

Simple Summary: This study describes a large-scale analysis of cancer metabolism across The Cancer Genome Atlas and Multiple Myeloma Research Foundation MMRF-COMMPASS study encompassing 10,915 patients from 34 different cancer types. To the best of our knowledge, this is the first such large-scale metabolic analysis performed using these data. Our approach identified biologically interpretable metabolic biomarkers of overall survival in 31 out of 34 cancer types evaluated. Additionally, in a subset of 7 cancer types, we predict chemosensitivity to antifolate-based therapies and a biomarker of response based on our patient-specific metabolic models. Finally, this work introduces the concept of "interpretation-driven biomarker identification". In this framework, biological interpretability of biomarker signatures is ensured first by using network-based simulations to characterize tumor biology, then using survival analysis to identify any biological features associated with overall survival—essentially decoupling biomarker discovery and biological interpretation of biomarker scores. Despite the high variability in cancer biology, cancers nevertheless exhibit cohesive hallmarks across multiple cancer types, notably dysregulated metabolism. Metabolism plays a central role in cancer biology, and shifts in metabolic pathways have been linked to tumor aggressiveness and likelihood of response to therapy. We therefore sought to interrogate metabolism across cancer types and understand how intrinsic modes of metabolism vary within and across indications and how they relate to patient prognosis. We used context specific genome-scale metabolic modeling to simulate metabolism across 10,915 patients from 34 cancer types from The Cancer Genome Atlas and the MMRF-COMMPASS study. We found that cancer metabolism clustered into modes characterized by differential glycolysis, oxidative phosphorylation, and growth rate. We also found that the simulated activities of metabolic pathways are intrinsically prognostic across cancer types, especially tumor growth rate, fatty acid biosynthesis, folate metabolism, oxidative phosphorylation, steroid metabolism, and glutathione metabolism. This work shows the prognostic power of individual patient metabolic modeling across multiple cancer types. Additionally, it shows that analyzing large-scale models of cancer metabolism with survival information provides unique insights into underlying relationships across cancer types and suggests how therapies designed for one cancer type may be repurposed for use in others. [ABSTRACT FROM AUTHOR]

Published

2024

3. Temperature Dependence of Platelet Metabolism.

Author

Jóhannsson, Freyr, Yurkovich, James T., Guðmundsson, Steinn, Sigurjónsson, Ólafur E., and Rolfsson, Óttar

Subjects

CHEMICAL kinetics, GLYCOLYSIS, BLOOD platelets, METABOLISM, TEMPERATURE effect, ENERGY metabolism, SYSTEMS biology

Abstract

Temperature plays a fundamental role in biology, influencing cellular function, chemical reaction rates, molecular structures, and interactions. While the temperature dependence of many biochemical reactions is well defined in vitro, the effect of temperature on metabolic function at the network level is poorly understood, and it remains an important challenge in optimizing the storage of cells and tissues at lower temperatures. Here, we used time-course metabolomic data and systems biology approaches to characterize the effects of storage temperature on human platelets (PLTs) in a platelet additive solution. We observed that changes to the metabolome with storage time do not simply scale with temperature but instead display complex temperature dependence, with only a small subset of metabolites following an Arrhenius-type relationship. Investigation of PLT energy metabolism through integration with computational modeling revealed that oxidative metabolism is more sensitive to temperature changes than glycolysis. The increased contribution of glycolysis to ATP turnover at lower temperatures indicates a stronger glycolytic phenotype with decreasing storage temperature. More broadly, these results demonstrate that the temperature dependence of the PLT metabolic network is not uniform, suggesting that efforts to improve the health of stored PLTs could be targeted at specific pathways. [ABSTRACT FROM AUTHOR]

Published

2024

4. A dynamic kinetic model captures cell-free metabolism for improved butanol production.

Author

Martin, Jacob P., Rasor, Blake J., DeBonis, Jonathon, Karim, Ashty S., Jewett, Michael C., Tyo, Keith E.J., and Broadbelt, Linda J.

Subjects

*DYNAMIC models, *ALCOHOL dehydrogenase, *METABOLIC models, *METABOLISM, *SENSITIVITY analysis

Abstract

Cell-free systems are useful tools for prototyping metabolic pathways and optimizing the production of various bioproducts. Mechanistically-based kinetic models are uniquely suited to analyze dynamic experimental data collected from cell-free systems and provide vital qualitative insight. However, to date, dynamic kinetic models have not been applied with rigorous biological constraints or trained on adequate experimental data to the degree that they would give high confidence in predictions and broadly demonstrate the potential for widespread use of such kinetic models. In this work, we construct a large-scale dynamic model of cell-free metabolism with the goal of understanding and optimizing butanol production in a cell-free system. Using a combination of parameterization methods, the resultant model captures experimental metabolite measurements across two experimental conditions for nine metabolites at timepoints between 0 and 24 h. We present analysis of the model predictions, provide recommendations for butanol optimization, and identify the aldehyde/alcohol dehydrogenase as the primary bottleneck in butanol production. Sensitivity analysis further reveals the extent to which various parameters are constrained, and our approach for probing valid parameter ranges can be applied to other modeling efforts. • A kinetic model captures timecourse data, including butanol production, in two experimental conditions in cell-free extracts. • Model hypothesizes metabolic mechanisms to explain experimentally observed behaviors between conditions. • Strategies to increase butanol production are predicted, the most promising of which is experimentally validated. • Analyses reveal how model parameters are constrained between many possible parameter sets within an ensemble. [ABSTRACT FROM AUTHOR]

Published

2023

5. Temperature Dependence of Platelet Metabolism

Author

Freyr Jóhannsson, James T. Yurkovich, Steinn Guðmundsson, Ólafur E. Sigurjónsson, and Óttar Rolfsson

Subjects

metabolism, platelet concentrates, temperature dependence, metabolic modeling, systems biology, Microbiology, QR1-502

Abstract

Temperature plays a fundamental role in biology, influencing cellular function, chemical reaction rates, molecular structures, and interactions. While the temperature dependence of many biochemical reactions is well defined in vitro, the effect of temperature on metabolic function at the network level is poorly understood, and it remains an important challenge in optimizing the storage of cells and tissues at lower temperatures. Here, we used time-course metabolomic data and systems biology approaches to characterize the effects of storage temperature on human platelets (PLTs) in a platelet additive solution. We observed that changes to the metabolome with storage time do not simply scale with temperature but instead display complex temperature dependence, with only a small subset of metabolites following an Arrhenius-type relationship. Investigation of PLT energy metabolism through integration with computational modeling revealed that oxidative metabolism is more sensitive to temperature changes than glycolysis. The increased contribution of glycolysis to ATP turnover at lower temperatures indicates a stronger glycolytic phenotype with decreasing storage temperature. More broadly, these results demonstrate that the temperature dependence of the PLT metabolic network is not uniform, suggesting that efforts to improve the health of stored PLTs could be targeted at specific pathways.

Published

2024

6. More is Different: Metabolic Modeling of Diverse Microbial Communities

Author

Christian Diener and Sean M. Gibbons

Subjects

flux balance analysis, metabolic modeling, metabolism, microbial communities, microbial ecology, systems biology, Microbiology, QR1-502

Abstract

ABSTRACT Microbial consortia drive essential processes, ranging from nitrogen fixation in soils to providing metabolic breakdown products to animal hosts. However, it is challenging to translate the composition of microbial consortia into their emergent functional capacities. Community-scale metabolic models hold the potential to simulate the outputs of complex microbial communities in a given environmental context, but there is currently no consensus for what the fitness function of an entire community should look like in the presence of ecological interactions and whether community-wide growth operates close to a maximum. Transitioning from single-taxon genome-scale metabolic models to multitaxon models implies a growth cone without a well-specified growth rate solution for individual taxa. Here, we argue that dynamic approaches naturally overcome these limitations, but they come at the cost of being computationally expensive. Furthermore, we show how two nondynamic, steady-state approaches approximate dynamic trajectories and pick ecologically relevant solutions from the community growth cone with improved computational scalability.

Published

2023

7. Influence of oxygen concentration on the metabolism of Penicillium chrysogenum.

Author

Janoska, Agnes, Verheijen, Jelle J., Tang, Wenjung, Lee, Queenie, Sikkema, Baukje, and van Gulik, Walter M.

Subjects

*PENICILLIUM chrysogenum, *METABOLISM, *OXYGEN, *CHEMOSTAT, *PENICILLIN, *SECONDARY metabolism

Abstract

In large‐scale bioreactors, there is often insufficient mixing and as a consequence, cells experience uneven substrate and oxygen levels that influence product formation. In this study, the influence of dissolved oxygen (DO) gradients on the primary and secondary metabolism of a high producing industrial strain of Penicillium chrysogenum was investigated. Within a wide range of DO concentrations, obtained under chemostat conditions, we observed different responses from P. chrysogenum: (i) no influence on growth or penicillin production (>0.025 mmol L−1); (ii) reduced penicillin production, but no growth limitation (0.013–0.025 mmol L−1); and (iii) growth and penicillin production limitations (<0.013 mmol L−1). In addition, scale down experiments were performed by oscillating the DO concentration in the bioreactor. We found that during DO oscillation, the penicillin production rate decreased below the value observed when a constant DO equal to the average oscillating DO value was used. To understand and predict the influence of oxygen levels on primary metabolism and penicillin production, we developed a black box model that was linked to a detailed kinetic model of the penicillin pathway. The model simulations represented the experimental data during the step experiments; however, during the oscillation experiments the predictions deviated, indicating the involvement of the central metabolism in penicillin production. [ABSTRACT FROM AUTHOR]

Published

2023

8. MetaboTools: A comprehensive toolbox for analysis of genome-scale metabolic models

Author

Thiele, Ines [Univ. of Luxembourg, Esch-sur-Alzette (Luxembourg)]

Published

2016

9. FastMM: an efficient toolbox for personalized constraint-based metabolic modeling

Author

Gong-Hua Li, Shaoxing Dai, Feifei Han, Wenxin Li, Jingfei Huang, and Wenzhong Xiao

Subjects

FastMM, Constraint-based model, Metabolic modeling, Metabolism, Computer applications to medicine. Medical informatics, R858-859.7, Biology (General), QH301-705.5

Abstract

Abstract Background Constraint-based metabolic modeling has been applied to understand metabolism related disease mechanisms, to predict potential new drug targets and anti-metabolites, and to identify biomarkers of complex diseases. Although the state-of-art modeling toolbox, COBRA 3.0, is powerful, it requires substantial computing time conducting flux balance analysis, knockout analysis, and Markov Chain Monte Carlo (MCMC) sampling, which may limit its application in large scale genome-wide analysis. Results Here, we rewrote the underlying code of COBRA 3.0 using C/C++, and developed a toolbox, termed FastMM, to effectively conduct constraint-based metabolic modeling. The results showed that FastMM is 2~400 times faster than COBRA 3.0 in performing flux balance analysis and knockout analysis and returns consistent outputs. When applied to MCMC sampling, FastMM is 8 times faster than COBRA 3.0. FastMM is also faster than some efficient metabolic modeling applications, such as Cobrapy and Fast-SL. In addition, we developed a Matlab/Octave interface for fast metabolic modeling. This interface was fully compatible with COBRA 3.0, enabling users to easily perform complex applications for metabolic modeling. For example, users who do not have deep constraint-based metabolic model knowledge can just type one command in Matlab/Octave to perform personalized metabolic modeling. Users can also use the advance and multiple threading parameters for complex metabolic modeling. Thus, we provided an efficient and user-friendly solution to perform large scale genome-wide metabolic modeling. For example, FastMM can be applied to the modeling of individual cancer metabolic profiles of hundreds to thousands of samples in the Cancer Genome Atlas (TCGA). Conclusion FastMM is an efficient and user-friendly toolbox for large-scale personalized constraint-based metabolic modeling. It can serve as a complementary and invaluable improvement to the existing functionalities in COBRA 3.0. FastMM is under GPL license and can be freely available at GitHub site: https://github.com/GonghuaLi/FastMM.

Published

2020

10. Enhancing Microbiome Research through Genome-Scale Metabolic Modeling

Author

Nana Y. D. Ankrah, David B. Bernstein, Matthew Biggs, Maureen Carey, Melinda Engevik, Beatriz García-Jiménez, Meiyappan Lakshmanan, Alan R. Pacheco, Snorre Sulheim, and Gregory L. Medlock

Subjects

microbiome, metabolic modeling, metabolism, Microbiology, QR1-502

Abstract

ABSTRACT Construction and analysis of genome-scale metabolic models (GEMs) is a well-established systems biology approach that can be used to predict metabolic and growth phenotypes. The ability of GEMs to produce mechanistic insight into microbial ecological processes makes them appealing tools that can open a range of exciting opportunities in microbiome research. Here, we briefly outline these opportunities, present current rate-limiting challenges for the trustworthy application of GEMs to microbiome research, and suggest approaches for moving the field forward.

Published

2021

11. Metabolic functions of Pseudomonas fluorescens strains from Populus deltoides depend on rhizosphere or endosphere isolation compartment

Author

Timm, Collin M, Campbell, Alisha G, Utturkar, Sagar M, Jun, Se-Ran, Parales, Rebecca E, Tan, Watumesa A, Robeson, Michael S, Lu, Tse-Yuan S, Jawdy, Sara, Brown, Steven D, Ussery, David W, Schadt, Christopher W, Tuskan, Gerald A, Doktycz, Mitchel J, Weston, David J, and Pelletier, Dale A

Subjects

Microbiology, Plant Biology, Biological Sciences, microbiome, Populus, metabolism, endosphere, rhizosphere, metabolic modeling, Environmental Science and Management, Soil Sciences, Medical microbiology

Abstract

The bacterial microbiota of plants is diverse, with 1000s of operational taxonomic units (OTUs) associated with any individual plant. In this work, we used phenotypic analysis, comparative genomics, and metabolic models to investigate the differences between 19 sequenced Pseudomonas fluorescens strains. These isolates represent a single OTU and were collected from the rhizosphere and endosphere of Populus deltoides. While no traits were exclusive to either endosphere or rhizosphere P. fluorescens isolates, multiple pathways relevant for plant-bacterial interactions are enriched in endosphere isolate genomes. Further, growth phenotypes such as phosphate solubilization, protease activity, denitrification and root growth promotion are biased toward endosphere isolates. Endosphere isolates have significantly more metabolic pathways for plant signaling compounds and an increased metabolic range that includes utilization of energy rich nucleotides and sugars, consistent with endosphere colonization. Rhizosphere P. fluorescens have fewer pathways representative of plant-bacterial interactions but show metabolic bias toward chemical substrates often found in root exudates. This work reveals the diverse functions that may contribute to colonization of the endosphere by bacteria and are enriched among closely related isolates.

Published

2015

12. Current Status and Future Prospects of Genome-Scale Metabolic Modeling to Optimize the Use of Mesenchymal Stem Cells in Regenerative Medicine

Author

Þóra Sigmarsdóttir, Sarah McGarrity, Óttar Rolfsson, James T. Yurkovich, and Ólafur E. Sigurjónsson

Subjects

MSCs, metabolism, personalized/precision medicine, metabolomics, metabolic modeling, tissue engineering, Biotechnology, TP248.13-248.65

Abstract

Mesenchymal stem cells are a promising source for externally grown tissue replacements and patient-specific immunomodulatory treatments. This promise has not yet been fulfilled in part due to production scaling issues and the need to maintain the correct phenotype after re-implantation. One aspect of extracorporeal growth that may be manipulated to optimize cell growth and differentiation is metabolism. The metabolism of MSCs changes during and in response to differentiation and immunomodulatory changes. MSC metabolism may be linked to functional differences but how this occurs and influences MSC function remains unclear. Understanding how MSC metabolism relates to cell function is however important as metabolite availability and environmental circumstances in the body may affect the success of implantation. Genome-scale constraint based metabolic modeling can be used as a tool to fill gaps in knowledge of MSC metabolism, acting as a framework to integrate and understand various data types (e.g., genomic, transcriptomic and metabolomic). These approaches have long been used to optimize the growth and productivity of bacterial production systems and are being increasingly used to provide insights into human health research. Production of tissue for implantation using MSCs requires both optimized production of cell mass and the understanding of the patient and phenotype specific metabolic situation. This review considers the current knowledge of MSC metabolism and how it may be optimized along with the current and future uses of genome scale constraint based metabolic modeling to further this aim.

Published

2020

13. FastMM: an efficient toolbox for personalized constraint-based metabolic modeling.

Author

Li, Gong-Hua, Dai, Shaoxing, Han, Feifei, Li, Wenxin, Huang, Jingfei, and Xiao, Wenzhong

Subjects

*METABOLIC models, *MARKOV chain Monte Carlo

Abstract

Background: Constraint-based metabolic modeling has been applied to understand metabolism related disease mechanisms, to predict potential new drug targets and anti-metabolites, and to identify biomarkers of complex diseases. Although the state-of-art modeling toolbox, COBRA 3.0, is powerful, it requires substantial computing time conducting flux balance analysis, knockout analysis, and Markov Chain Monte Carlo (MCMC) sampling, which may limit its application in large scale genome-wide analysis. Results: Here, we rewrote the underlying code of COBRA 3.0 using C/C++, and developed a toolbox, termed FastMM, to effectively conduct constraint-based metabolic modeling. The results showed that FastMM is 2~400 times faster than COBRA 3.0 in performing flux balance analysis and knockout analysis and returns consistent outputs. When applied to MCMC sampling, FastMM is 8 times faster than COBRA 3.0. FastMM is also faster than some efficient metabolic modeling applications, such as Cobrapy and Fast-SL. In addition, we developed a Matlab/Octave interface for fast metabolic modeling. This interface was fully compatible with COBRA 3.0, enabling users to easily perform complex applications for metabolic modeling. For example, users who do not have deep constraint-based metabolic model knowledge can just type one command in Matlab/Octave to perform personalized metabolic modeling. Users can also use the advance and multiple threading parameters for complex metabolic modeling. Thus, we provided an efficient and user-friendly solution to perform large scale genome-wide metabolic modeling. For example, FastMM can be applied to the modeling of individual cancer metabolic profiles of hundreds to thousands of samples in the Cancer Genome Atlas (TCGA). Conclusion: FastMM is an efficient and user-friendly toolbox for large-scale personalized constraint-based metabolic modeling. It can serve as a complementary and invaluable improvement to the existing functionalities in COBRA 3.0. FastMM is under GPL license and can be freely available at GitHub site: https://github.com/GonghuaLi/FastMM. [ABSTRACT FROM AUTHOR]

Published

2020

14. Cupriavidus necator as a platform for polyhydroxyalkanoate production: An overview of strains, metabolism, and modeling approaches.

Author

Morlino, Maria Silvia, Serna García, Rebecca, Savio, Filippo, Zampieri, Guido, Morosinotto, Tomas, Treu, Laura, and Campanaro, Stefano

Subjects

*POLYHYDROXYALKANOATES, *METABOLIC models, *WASTE products, *GENETIC engineering, *COMPARATIVE genomics, *GENETIC variation, *METABOLISM

Abstract

Cupriavidus necator is a bacterium with a high phenotypic diversity and versatile metabolic capabilities. It has been extensively studied as a model hydrogen oxidizer, as well as a producer of polyhydroxyalkanoates (PHA), plastic-like biopolymers with a high potential to substitute petroleum-based materials. Thanks to its adaptability to diverse metabolic lifestyles and to the ability to accumulate large amounts of PHA, C. necator is employed in many biotechnological processes, with particular focus on PHA production from waste carbon sources. The large availability of genomic information has enabled a characterization of C. necator 's metabolism, leading to the establishment of metabolic models which are used to devise and optimize culture conditions and genetic engineering approaches. In this work, the characteristics of available C. necator strains and genomes are reviewed, underlining how a thorough comprehension of the genetic variability of C. necator is lacking and it could be instrumental for wider application of this microorganism. The metabolic paradigms of C. necator and how they are connected to PHA production and accumulation are described, also recapitulating the variety of carbon substrates used for PHA accumulation, highlighting the most promising strategies to increase the yield. Finally, the review describes and critically analyzes currently available genome-scale metabolic models and reduced metabolic network applications commonly employed in the optimization of PHA production. Overall, it appears that the capacity of C. necator of performing CO 2 bioconversion to PHA is still underexplored, both in biotechnological applications and in metabolic modeling. However, the accurate characterization of this organism and the efforts in using it for gas fermentation can help tackle this challenging perspective in the future. • Taxonomy of Cupriavidus necator strains is examined by comparative genomics. • The metabolism of C. necator is suited to diverse aerobic and anaerobic lifestyles. • C. necator can convert many waste products to polyhydroxyalkanoates. • Metabolic modeling of C. necator is a powerful tool for bioprocess optimization. [ABSTRACT FROM AUTHOR]

Published

2023

15. Clostridioides difficile 630Δerm in silico and in vivo – quantitative growth and extensive polysaccharide secretion

Author

Henning Dannheim, Sabine E. Will, Dietmar Schomburg, and Meina Neumann‐Schaal

Subjects

Clostridioides difficile, Clostridium difficile, exopolysaccharide, genome‐scale, metabolic modeling, metabolism, Biology (General), QH301-705.5

Abstract

Antibiotic‐associated infections with Clostridioides difficile are a severe and often lethal risk for hospitalized patients, and can also affect populations without these classical risk factors. For a rational design of therapeutical concepts, a better knowledge of the metabolism of the pathogen is crucial. Metabolic modeling can provide a simulation of quantitative growth and usage of metabolic pathways, leading to a deeper understanding of the organism. Here, we present an elaborate genome‐scale metabolic model of C. difficile 630Δerm. The model iHD992 includes experimentally determined product and substrate uptake rates and is able to simulate the energy metabolism and quantitative growth of C. difficile. Dynamic flux balance analysis was used for time‐resolved simulations of the quantitative growth in two different media. The model predicts oxidative Stickland reactions and glucose degradation as main sources of energy, while the resulting reduction potential is mostly used for acetogenesis via the Wood–Ljungdahl pathway. Initial modeling experiments did not reproduce the observed growth behavior before the production of large quantities of a previously unknown polysaccharide was detected. Combined genome analysis and laboratory experiments indicated that the polysaccharide is an acetylated glucose polymer. Time‐resolved simulations showed that polysaccharide secretion was coupled to growth even during unstable glucose uptake in minimal medium. This is accomplished by metabolic shifts between active glycolysis and gluconeogenesis which were also observed in laboratory experiments.

Published

2017

16. Metabolic Model of the Phytophthora infestans-Tomato Interaction Reveals Metabolic Switches during Host Colonization

Author

Sander Y. A. Rodenburg, Michael F. Seidl, Howard S. Judelson, Andrea L. Vu, Francine Govers, and Dick de Ridder

Subjects

Phytophthora infestans, metabolic modeling, metabolism, oomycetes, tomato, Microbiology, QR1-502

Abstract

ABSTRACT The oomycete pathogen Phytophthora infestans causes potato and tomato late blight, a disease that is a serious threat to agriculture. P. infestans is a hemibiotrophic pathogen, and during infection, it scavenges nutrients from living host cells for its own proliferation. To date, the nutrient flux from host to pathogen during infection has hardly been studied, and the interlinked metabolisms of the pathogen and host remain poorly understood. Here, we reconstructed an integrated metabolic model of P. infestans and tomato (Solanum lycopersicum) by integrating two previously published models for both species. We used this integrated model to simulate metabolic fluxes from host to pathogen and explored the topology of the model to study the dependencies of the metabolism of P. infestans on that of tomato. This showed, for example, that P. infestans, a thiamine auxotroph, depends on certain metabolic reactions of the tomato thiamine biosynthesis. We also exploited dual-transcriptome data of a time course of a full late blight infection cycle on tomato leaves and integrated the expression of metabolic enzymes in the model. This revealed profound changes in pathogen-host metabolism during infection. As infection progresses, P. infestans performs less de novo synthesis of metabolites and scavenges more metabolites from tomato. This integrated metabolic model for the P. infestans-tomato interaction provides a framework to integrate data and generate hypotheses about in planta nutrition of P. infestans throughout its infection cycle. IMPORTANCE Late blight disease caused by the oomycete pathogen Phytophthora infestans leads to extensive yield losses in tomato and potato cultivation worldwide. To effectively control this pathogen, a thorough understanding of the mechanisms shaping the interaction with its hosts is paramount. While considerable work has focused on exploring host defense mechanisms and identifying P. infestans proteins contributing to virulence and pathogenicity, the nutritional strategies of the pathogen are mostly unresolved. Genome-scale metabolic models (GEMs) can be used to simulate metabolic fluxes and help in unravelling the complex nature of metabolism. We integrated a GEM of tomato with a GEM of P. infestans to simulate the metabolic fluxes that occur during infection. This yields insights into the nutrients that P. infestans obtains during different phases of the infection cycle and helps in generating hypotheses about nutrition in planta.

Published

2019

17. Genomewide Assessment of Mycobacterium tuberculosis Conditionally Essential Metabolic Pathways

Author

Yusuke Minato, Daryl M. Gohl, Joshua M. Thiede, Jeremy M. Chacón, William R. Harcombe, Fumito Maruyama, and Anthony D. Baughn

Subjects

comparative genomics, metabolic modeling, metabolism, Tn-seq, tuberculosis, Microbiology, QR1-502

Abstract

ABSTRACT A better understanding of essential cellular functions in pathogenic bacteria is important for the development of more effective antimicrobial agents. We performed a comprehensive identification of essential genes in Mycobacterium tuberculosis, the major causative agent of tuberculosis, using a combination of transposon insertion sequencing (Tn-seq) and comparative genomic analysis. To identify conditionally essential genes by Tn-seq, we used media with different nutrient compositions. Although many conditional gene essentialities were affected by the presence of relevant nutrient sources, we also found that the essentiality of genes in a subset of metabolic pathways was unaffected by metabolite availability. Comparative genomic analysis revealed that not all essential genes identified by Tn-seq were fully conserved within the M. tuberculosis complex, including some existing antitubercular drug target genes. In addition, we utilized an available M. tuberculosis genome-scale metabolic model, iSM810, to predict M. tuberculosis gene essentiality in silico. Comparing the sets of essential genes experimentally identified by Tn-seq to those predicted in silico reveals the capabilities and limitations of gene essentiality predictions, highlighting the complexity of M. tuberculosis essential metabolic functions. This study provides a promising platform to study essential cellular functions in M. tuberculosis. IMPORTANCE Mycobacterium tuberculosis causes 10 million cases of tuberculosis (TB), resulting in over 1 million deaths each year. TB therapy is challenging because it requires a minimum of 6 months of treatment with multiple drugs. Protracted treatment times and the emergent spread of drug-resistant M. tuberculosis necessitate the identification of novel targets for drug discovery to curb this global health threat. Essential functions, defined as those indispensable for growth and/or survival, are potential targets for new antimicrobial drugs. In this study, we aimed to define gene essentialities of M. tuberculosis on a genomewide scale to comprehensively identify potential targets for drug discovery. We utilized a combination of experimental (functional genomics) and in silico approaches (comparative genomics and flux balance analysis). Our functional genomics approach identified sets of genes whose essentiality was affected by nutrient availability. Comparative genomics revealed that not all essential genes were fully conserved within the M. tuberculosis complex. Comparing sets of essential genes identified by functional genomics to those predicted by flux balance analysis highlighted gaps in current knowledge regarding M. tuberculosis metabolic capabilities. Thus, our study identifies numerous potential antitubercular drug targets and provides a comprehensive picture of the complexity of M. tuberculosis essential cellular functions.

Published

2019

18. INSIGHTS INTO MECHANISMS OF REDOX HOMEOSTASIS IN NITROGEN-FIXING AZOTOBACTER VINELANDII

Author

Alleman, Alexander

Subjects

Metabolism, metabolic modeling, FOS: Biological sciences, Nitrogen Fixation, Bioenergetics, Microbiology, soil microbiology

Abstract

Overuse of industrial nitrogen fertilizers causes environmental degradation through runoff, lowers soil pH, and generates greenhouse gas emissions. There is considerable interest in promoting biological nitrogen fixation (BNF) as a mechanism to reduce the inputs of nitrogen fertilizers in agriculture. However, considerable fundamental knowledge gaps need to be addressed to realize the potential impacts of BNF in agriculture. BNF is catalyzed by the enzyme nitrogenase, which requires a large amount of energy in the form of ATP and low potential electrons. Nitrogen-fixing organisms that respire aerobically have an advantage in meeting the energy demands of BNF but face challenges of protecting nitrogenase from inactivation by oxygen. The model aerobic nitrogen-fixing bacteria Azotobacter vinelandii has a unique electron transport system that accommodates excess oxygen while producing enough energy for nitrogenase. The mechanism, termed respiratory protection, consumes excess oxygen at the membrane and leads to lower oxygen accumulation in the cytosol. A. vinelandii also contains two enzymes, Rnf and Fix, that deliver reductant to nitrogenase in the form of low potential electrons. A physiological and systems-based approach was taken to understand how the dynamics of the electron transport systems are integrated to protect nitrogenase from oxygen while simultaneously creating enough energy for nitrogen fixation. A metabolic model of A. vinelandii was constructed that accurately determines growth rate under high oxygen and substrate concentrations, demonstrating the large flux directed to the respiratory protection mechanism. Interestingly, the respiratory protection mechanism is also required for accurate predictions even when ammonia is supplemented during growth, suggesting that respiratory protection might be an essential part of normal growth rather than strictly reserved for nitrogenase protection. The model has also shown how A. vinelandii can adapt under different oxygen concentrations, metal availability, and ammonia excreting phenotype by rearranging flux through the electron transport system. Through mutational studies of electron transport enzymes Rnf and Fix, Fix was shown to be required under low oxygen concentrations, and Rnf contributes to the regulation of redox homeostasis under high oxygen. Understanding the energy dynamics in aerobic nitrogen fixation will further allow the development of biotechnologies that can help supplement industrial nitrogenous fertilizer

Published

2023

19. Interrogation of the perturbed gut microbiota in gouty arthritis patients through in silico metabolic modeling

Author

Michael A. Henson

Subjects

0106 biological sciences, musculoskeletal diseases, Environmental Engineering, Bioengineering, Butyrate, Gut flora, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, gout, metabolic modeling, 010608 biotechnology, medicine, Research Articles, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, biology, gut microbiota, Catabolism, Metabolism, biology.organism_classification, medicine.disease, bacterial communities, Amino acid, Gout, machine learning, chemistry, Biochemistry, Uric acid, Bacteroides, TP248.13-248.65, Research Article, Biotechnology

Abstract

Recent studies have shown perturbed gut microbiota associated with gouty arthritis, a metabolic disease characterized by an imbalance between uric acid production and excretion. To mechanistically investigate altered microbiota metabolism associated with gout disease, 16S rRNA gene amplicon sequence data from stool samples of gout patients and healthy controls were computationally analyzed through bacterial community metabolic models. Patient‐specific community models constructed with the metagenomics modeling pipeline, mgPipe, were used to perform k‐means clustering of samples according to their metabolic capabilities. The clustering analysis generated statistically significant partitioning of samples into a Bacteroides‐dominated, high gout cluster and a Faecalibacterium‐elevated, low gout cluster. The high gout cluster was predicted to allow elevated synthesis of the amino acids D‐alanine and L‐alanine and byproducts of branched‐chain amino acid catabolism, while the low gout cluster allowed higher production of butyrate, the sulfur‐containing amino acids L‐cysteine and L‐methionine, and the L‐cysteine catabolic product H2S. By expanding the capabilities of mgPipe to provide taxa‐level resolution of metabolite exchange rates, acetate, D‐lactate and succinate exchanged from Bacteroides to Faecalibacterium were predicted to enhance butyrate production in the low gout cluster. Model predictions suggested that sulfur‐containing amino acid metabolism generally and H2S more specifically could be novel gout disease markers.

Published

2021

20. Combining Genome-Scale Experimental and Computational Methods To Identify Essential Genes in Rhodobacter sphaeroides

Author

Brian T. Burger, Saheed Imam, Matthew J. Scarborough, Daniel R. Noguera, and Timothy J. Donohue

Subjects

Rhodobacter sphaeroides, Tn-seq, gene disruption, genomics, metabolic modeling, metabolism, Microbiology, QR1-502

Abstract

ABSTRACT Rhodobacter sphaeroides is one of the best-studied alphaproteobacteria from biochemical, genetic, and genomic perspectives. To gain a better systems-level understanding of this organism, we generated a large transposon mutant library and used transposon sequencing (Tn-seq) to identify genes that are essential under several growth conditions. Using newly developed Tn-seq analysis software (TSAS), we identified 493 genes as essential for aerobic growth on a rich medium. We then used the mutant library to identify conditionally essential genes under two laboratory growth conditions, identifying 85 additional genes required for aerobic growth in a minimal medium and 31 additional genes required for photosynthetic growth. In all instances, our analyses confirmed essentiality for many known genes and identified genes not previously considered to be essential. We used the resulting Tn-seq data to refine and improve a genome-scale metabolic network model (GEM) for R. sphaeroides. Together, we demonstrate how genetic, genomic, and computational approaches can be combined to obtain a systems-level understanding of the genetic framework underlying metabolic diversity in bacterial species. IMPORTANCE Knowledge about the role of genes under a particular growth condition is required for a holistic understanding of a bacterial cell and has implications for health, agriculture, and biotechnology. We developed the Tn-seq analysis software (TSAS) package to provide a flexible and statistically rigorous workflow for the high-throughput analysis of insertion mutant libraries, advanced the knowledge of gene essentiality in R. sphaeroides, and illustrated how Tn-seq data can be used to more accurately identify genes that play important roles in metabolism and other processes that are essential for cellular survival. Author Video: An author video summary of this article is available.

Published

2017

21. Clostridioides difficile 630Δ erm in silico and in vivo - quantitative growth and extensive polysaccharide secretion.

Author

Dannheim, Henning, Will, Sabine E., Schomburg, Dietmar, and Neumann-Schaal, Meina

Subjects

CLOSTRIDIOIDES difficile, DRUG side effects, POLYSACCHARIDES, BACTERIAL growth, ENERGY metabolism, HOSPITAL care

Abstract

Antibiotic-associated infections with Clostridioides difficile are a severe and often lethal risk for hospitalized patients, and can also affect populations without these classical risk factors. For a rational design of therapeutical concepts, a better knowledge of the metabolism of the pathogen is crucial. Metabolic modeling can provide a simulation of quantitative growth and usage of metabolic pathways, leading to a deeper understanding of the organism. Here, we present an elaborate genome-scale metabolic model of C. difficile 630Δ erm. The model iHD992 includes experimentally determined product and substrate uptake rates and is able to simulate the energy metabolism and quantitative growth of C. difficile. Dynamic flux balance analysis was used for time-resolved simulations of the quantitative growth in two different media. The model predicts oxidative Stickland reactions and glucose degradation as main sources of energy, while the resulting reduction potential is mostly used for acetogenesis via the Wood-Ljungdahl pathway. Initial modeling experiments did not reproduce the observed growth behavior before the production of large quantities of a previously unknown polysaccharide was detected. Combined genome analysis and laboratory experiments indicated that the polysaccharide is an acetylated glucose polymer. Time-resolved simulations showed that polysaccharide secretion was coupled to growth even during unstable glucose uptake in minimal medium. This is accomplished by metabolic shifts between active glycolysis and gluconeogenesis which were also observed in laboratory experiments. [ABSTRACT FROM AUTHOR]

Published

2017

22. MetaboTools: A comprehensive toolbox for analysis of genome-scale metabolic models

Author

Maike Kathrin Aurich, Ronan Fleming, and Ines Thiele

Subjects

Metabolism, Metabolomics, metabolic modeling, model analysis, protocol, Metabolic phenotypes, Physiology, QP1-981

Abstract

Metabolomic data sets provide a direct read-out of cellular phenotypes and are increasingly generated to study biological questions. Previous work, by us and others, revealed the potential of analyzing extracellular metabolomic data in the context of the metabolic model using constraint-based modeling. With the MetaboTools , we make our methods available to the broader scientific community. The MetaboTools consist of a protocol, a toolbox, and tutorials of two use cases. The protocol describes, in a step-wise manner, the workflow of data integration and computational analysis. The MetaboTools comprise the Matlab code required to complete the workflow described in the protocol. Tutorials explain the computational steps for integration of two different data sets and demonstrate a comprehensive set of methods for the computational analysis of metabolic models and stratification thereof into different phenotypes. The presented workflow supports integrative analysis of multiple omics data sets. Importantly, all analysis tools can be applied to metabolic models without performing the entire workflow. Taken together, the MetaboTools constitute a comprehensive guide to the intra-model analysis of extracellular metabolomic data from microbial, plant, or human cells. This computational modeling resource offers a broad set of computational analysis tools for a wide biomedical and non-biomedical research community.

Published

2016

23. Understanding the causes and implications of endothelial metabolic variation in cardiovascular disease through genome scale metabolic modeling

Author

Sarah eMcGarrity, Haraldur eHalldórsson, Sirus ePalsson, Pӓr Ingemar Johansson, and Óttar eRolfsson

Subjects

Endothelium, Genetics, Metabolism, Metabolomics, metabolic modeling, personalized/precision medicine, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

High-throughput biochemical profiling has led to a requirement for advanced data interpretation techniques capable of integrating the analysis of gene, protein, and metabolic profiles to shed light on genotype-phenotype relationships. Herein, we consider the current state of knowledge of endothelial cell (EC) metabolism and its connections to cardiovascular disease, and explore the use of genome scale metabolic models (GEMs) for integrating metabolic and genomic data. GEMs combine gene expression and metabolic data acting as frameworks for their analysis and, ultimately, afford mechanistic understanding of how genetic variation impacts metabolism. We demonstrate how GEMs can be used to investigate cardiovascular disease-related genetic variation, drug resistance mechanisms, and novel metabolic pathways, in ECs. The application of GEMs in personalized medicine is also highlighted. Particularly, we focus on the potential of GEMs to identify metabolic biomarkers of endothelial dysfunction and to discover methods of stratifying treatments for cardiovascular diseases based on individual genetic markers. Recent advances in systems biology methodology, and how these methodologies can be applied to understand EC metabolism in both health and disease, are thus highlighted.

Published

2016

24. Protocol for hybrid flux balance, statistical, and machine learning analysis of multi-omic data from the cyanobacterium Synechococcus sp. PCC 7002

Author

Supreeta Vijayakumar and Claudio Angione

Subjects

Science (General), Computer science, Bioinformatics, Systems biology, Machine learning, computer.software_genre, Microbiology, General Biochemistry, Genetics and Molecular Biology, Machine Learning, Q1-390, Protocol, Metabolic modeling, Synechococcus sp, Protocol (object-oriented programming), Synechococcus, General Immunology and Microbiology, business.industry, General Neuroscience, Key features, Flux balance analysis, Metabolism, Artificial intelligence, business, Metabolic activity, Transcriptome, computer, Flux (metabolism), Computer sciences

Abstract

Summary Combining a computational framework for flux balance analysis with machine learning improves the accuracy of predicting metabolic activity across conditions, while enabling mechanistic interpretation. This protocol presents a guide to condition-specific metabolic modeling that integrates regularized flux balance analysis with machine learning approaches to extract key features from transcriptomic and fluxomic data. We demonstrate the protocol as applied to Synechococcus sp. PCC 7002; we also outline how it can be adapted to any species or community with available multi-omic data. For complete details on the use and execution of this protocol, please refer to Vijayakumar et al. (2020)., Graphical abstract, Highlights • Step-by-step instructions are provided for metabolic modeling and machine learning • Any organism with a working GSMM and available transcriptomic data can be analyzed • Analyzing multi-omic data provides a more complete picture of metabolism • Machine learning algorithms reduce dimensionality and detect cross-omic features, Combining a computational framework for flux balance analysis with machine learning improves the accuracy of predicting metabolic activity across conditions, while enabling mechanistic interpretation. This protocol presents a guide to condition-specific metabolic modeling that integrates regularized flux balance analysis with machine learning approaches to extract key features from transcriptomic and fluxomic data. We demonstrate the protocol as applied to Synechococcus sp. PCC 7002; we also outline how it can be adapted to any species or community with available multi-omic data.

Published

2021

25. Metabolic memory underlying minimal residual disease in breast cancer

Author

Ksenija Radic Shechter, Daniel C. Sévin, Britta Brügger, Sylwia Gawrzak, Kiran Raosaheb Patil, Daniel Machado, Christian Lüchtenborg, Martin Jechlinger, Ashna Alladin, Eleni Kafkia, Katharina Zirngibl, Radic Shechter, Ksenija [0000-0003-3139-9184], Zirngibl, Katharina [0000-0002-7518-0339], Gawrzak, Sylwia [0000-0002-7047-3319], Machado, Daniel [0000-0002-2063-5383], Patil, Kiran R [0000-0002-6166-8640], Jechlinger, Martin [0000-0002-3710-4466], Apollo - University of Cambridge Repository, and Patil, Kiran [0000-0002-6166-8640]

Subjects

Medicine (General), Neoplasm, Residual, QH301-705.5, Breast Neoplasms, Biology, Malignancy, EMBO21, General Biochemistry, Genetics and Molecular Biology, Article, Transcriptome, Mice, Breast cancer, R5-920, metabolic modeling, medicine, Animals, Humans, Glycolysis, Epigenetics, Biology (General), organoids, Cancer, General Immunology and Microbiology, Applied Mathematics, Articles, multi‐omics integration, glycolysis, medicine.disease, Phenotype, Minimal residual disease, oncogenic memory, EMBO03, multi���omics integration, Metabolism, Computational Theory and Mathematics, DNA methylation, Cancer research, Female, multi-omics integration, Neoplasm Recurrence, Local, General Agricultural and Biological Sciences, Information Systems

Abstract

Funder: European Molecular Biology Laboratory, Funder: European Molecular Biology Laboratory (EMBL), Tumor relapse from treatment-resistant cells (minimal residual disease, MRD) underlies most breast cancer-related deaths. Yet, the molecular characteristics defining their malignancy have largely remained elusive. Here, we integrated multi-omics data from a tractable organoid system with a metabolic modeling approach to uncover the metabolic and regulatory idiosyncrasies of the MRD. We find that the resistant cells, despite their non-proliferative phenotype and the absence of oncogenic signaling, feature increased glycolysis and activity of certain urea cycle enzyme reminiscent of the tumor. This metabolic distinctiveness was also evident in a mouse model and in transcriptomic data from patients following neo-adjuvant therapy. We further identified a marked similarity in DNA methylation profiles between tumor and residual cells. Taken together, our data reveal a metabolic and epigenetic memory of the treatment-resistant cells. We further demonstrate that the memorized elevated glycolysis in MRD is crucial for their survival and can be targeted using a small-molecule inhibitor without impacting normal cells. The metabolic aberrances of MRD thus offer new therapeutic opportunities for post-treatment care to prevent breast tumor recurrence.

Published

2021

26. Metabolic functions of Pseudomonas fluorescens strains from Populus deltoides depend on rhizosphere or endosphere isolation compartment

Author

Collin M Timm, Alisha G Campbell, Sagar M Utturkar, Se Ran eJun, Rebecca E Parales, Watumesa eTan, Michael Scott Robeson, Tse-Yuan eLu, Sara eJawdy, Steven D. Brown, David W Ussery, Christopher Warren Schadt, Gerald A Tuskan, Mitchel J Doktycz, David Joseph Weston, and Dale Adam Pelletier

Subjects

Metabolism, Populus, microbiome, metabolic modeling, rhizosphere, endosphere, Microbiology, QR1-502

Abstract

The bacterial microbiota of plants is diverse, with 1,000s of operational taxonomic units (OTUs) associated with any individual plant. In this work we investigate the differences between 19 sequenced Pseudomonas fluorescens strains, isolated from Populus deltoides rhizosphere and endosphere and which represent a single OTU, using phenotypic analysis, comparative genomics, and metabolic models. While no traits were exclusive to either endosphere or rhizosphere P. fluorescens isolates, multiple pathways relevant for plant-bacterial interactions are enriched in endosphere isolate genomes. Further, growth phenotypes such as phosphate solubilization, protease activity, denitrification and root growth promotion are biased towards endosphere isolates. Endosphere isolates have significantly more metabolic pathways for plant signaling compounds and an increased metabolic range that includes utilization of energy rich nucleotides and sugars, consistent with endosphere colonization. Rhizosphere P. fluorescens have fewer pathways representative of plant-bacterial interactions but show metabolic bias towards chemical substrates often found in root exudates. This work reveals the diverse functions that may contribute to colonization of the endosphere by bacteria and are enriched among closely related isolates.

Published

2015

27. MetaboTools: A Comprehensive Toolbox for Analysis of Genome-Scale Metabolic Models.

Author

Aurich, Maike K., Fleming, Ronan M. T., Thiele, Ines, Marin-Sanguino, Alberto, and Mardinoglu, Adil

Subjects

GENETIC software, METABOLOMICS, EXTRACELLULAR matrix

Abstract

Metabolomic data sets provide a direct read-out of cellular phenotypes and are increasingly generated to study biological questions. Previous work, by us and others, revealed the potential of analyzing extracellular metabolomic data in the context of the metabolic model using constraint-based modeling. With the MetaboTools, we make our methods available to the broader scientific community. The MetaboTools consist of a protocol, a toolbox, and tutorials of two use cases. The protocol describes, in a step-wise manner, the workflow of data integration, and computational analysis. The MetaboTools comprise the Matlab code required to complete the workflow described in the protocol. Tutorials explain the computational steps for integration of two different data sets and demonstrate a comprehensive set of methods for the computational analysis of metabolic models and stratification thereof into different phenotypes. The presented workflow supports integrative analysis of multiple omics data sets. Importantly, all analysis tools can be applied to metabolic models without performing the entire workflow. Taken together, the MetaboTools constitute a comprehensive guide to the intra-model analysis of extracellular metabolomic data from microbial, plant, or human cells. This computational modeling resource offers a broad set of computational analysis tools for a wide biomedical and non-biomedical research community. [ABSTRACT FROM AUTHOR]

Published

2016

28. Systematic identification and analysis of frequent gene fusion events in metabolic pathways.

Author

Henry, Christopher S., Lerma-Ortiz, Claudia, Gerdes, Svetlana Y., Mullen, Jeffrey D., Colasanti, Ric, Zhukov, Aleksey, Frelin, Océane, Thiaville, Jennifer J., Zallot, Rémi, Niehaus, Thomas D., Hasnain, Ghulam, Conrad, Neal, Hanson, Andrew D., and de Crécy-Lagard, Valérie

Subjects

*GENE fusion, *ESCHERICHIA coli, *PROKARYOTES, *FUNCTIONAL analysis, *METABOLISM

Abstract

Background: Gene fusions are the most powerful type of in silico-derived functional associations. However, many fusion compilations were made when <100 genomes were available, and algorithms for identifying fusions need updating to handle the current avalanche of sequenced genomes. The availability of a large fusion dataset would help probe functional associations and enable systematic analysis of where and why fusion events occur. Results: Here we present a systematic analysis of fusions in prokaryotes. We manually generated two training sets: (i) 121 fusions in the model organism Escherichia coli; (ii) 131 fusions found in B vitamin metabolism. These sets were used to develop a fusion prediction algorithm that captured the training set fusions with only 7 % false negatives and 50 % false positives, a substantial improvement over existing approaches. This algorithm was then applied to identify 3.8 million potential fusions across 11,473 genomes. The results of the analysis are available in a searchable database at http://modelseed.org/projects/fusions/. A functional analysis identified 3,000 reactions associated with frequent fusion events and revealed areas of metabolism where fusions are particularly prevalent. Conclusions: Customary definitions of fusions were shown to be ambiguous, and a stricter one was proposed. Exploring the genes participating in fusion events showed that they most commonly encode transporters, regulators, and metabolic enzymes. The major rationales for fusions between metabolic genes appear to be overcoming pathway bottlenecks, avoiding toxicity, controlling competing pathways, and facilitating expression and assembly of protein complexes. Finally, our fusion dataset provides powerful clues to decipher the biological activities of domains of unknown function. [ABSTRACT FROM AUTHOR]

Published

2016

29. Evaluation of rate law approximations in bottom-up kinetic models of metabolism.

Author

Bin Du, Zielinski, Daniel C., Kavvas, Erol S., Dräger, Andreas, Tan, Justin, Zhen Zhang, Ruggiero, Kayla E., Arzumanyan, Garri A., and Palsson, Bernhard O.

Subjects

*METABOLIC models, *MICHAELIS-Menten equation, *METABOLISM, *ENZYME kinetics, *PARAMETERIZATION, *TRANSIENTS (Dynamics)

Abstract

Background: The mechanistic description of enzyme kinetics in a dynamic model of metabolism requires specifying the numerical values of a large number of kinetic parameters. The parameterization challenge is often addressed through the use of simplifying approximations to form reaction rate laws with reduced numbers of parameters. Whether such simplified models can reproduce dynamic characteristics of the full system is an important question. Results: In this work, we compared the local transient response properties of dynamic models constructed using rate laws with varying levels of approximation. These approximate rate laws were: 1) a Michaelis-Menten rate law with measured enzyme parameters, 2) a Michaelis-Menten rate law with approximated parameters, using the convenience kinetics convention, 3) a thermodynamic rate law resulting from a metabolite saturation assumption, and 4) a pure chemical reaction mass action rate law that removes the role of the enzyme from the reaction kinetics. We utilized in vivo data for the human red blood cell to compare the effect of rate law choices against the backdrop of physiological flux and concentration differences. We found that the Michaelis-Menten rate law with measured enzyme parameters yields an excellent approximation of the full system dynamics, while other assumptions cause greater discrepancies in system dynamic behavior. However, iteratively replacing mechanistic rate laws with approximations resulted in a model that retains a high correlation with the true model behavior. Investigating this consistency, we determined that the order of magnitude differences among fluxes and concentrations in the network were greatly influential on the network dynamics. We further identified reaction features such as thermodynamic reversibility, high substrate concentration, and lack of allosteric regulation, which make certain reactions more suitable for rate law approximations. Conclusions: Overall, our work generally supports the use of approximate rate laws when building large scale kinetic models, due to the key role that physiologically meaningful flux and concentration ranges play in determining network dynamics. However, we also showed that detailed mechanistic models show a clear benefit in prediction accuracy when data is available. The work here should help to provide guidance to future kinetic modeling efforts on the choice of rate law and parameterization approaches. [ABSTRACT FROM AUTHOR]

Published

2016

30. A gap-filling algorithm for prediction of metabolic interactions in microbial communities

Author

Radhakrishnan Mahadevan, Dafni Giannari, and Cleo Hanchen Ho

Subjects

Databases, Factual, Microbial metabolism, Faecalibacterium prausnitzii, Biochemistry, Glucose Metabolism, Metabolites, Metabolic modeling, Biology (General), Gap filling, Ecology, biology, Organic Compounds, Microbiota, Applied Mathematics, Simulation and Modeling, Monosaccharides, Chemical Reactions, Ketones, Chemistry, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, Carbohydrate Metabolism, Identification (biology), Synthetic Biology, Algorithm, Algorithms, Metabolic Networks and Pathways, Research Article, Pyruvate, QH301-705.5, Ecology (disciplines), Exchange Reactions, Carbohydrates, Bifidobacterium adolescentis, Research and Analysis Methods, Models, Biological, Cellular and Molecular Neuroscience, Genetics, Escherichia coli, Humans, Computer Simulation, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Community level, Bacteroidetes, Organic Chemistry, Chemical Compounds, Computational Biology, Biology and Life Sciences, Carbon Dioxide, biology.organism_classification, Bacteroidales, Gastrointestinal Microbiome, Species Interactions, Metabolism, Glucose, Peptococcaceae, Acids, Mathematics

Abstract

The study of microbial communities and their interactions has attracted the interest of the scientific community, because of their potential for applications in biotechnology, ecology and medicine. The complexity of interspecies interactions, which are key for the macroscopic behavior of microbial communities, cannot be studied easily experimentally. For this reason, the modeling of microbial communities has begun to leverage the knowledge of established constraint-based methods, which have long been used for studying and analyzing the microbial metabolism of individual species based on genome-scale metabolic reconstructions of microorganisms. A main problem of genome-scale metabolic reconstructions is that they usually contain metabolic gaps due to genome misannotations and unknown enzyme functions. This problem is traditionally solved by using gap-filling algorithms that add biochemical reactions from external databases to the metabolic reconstruction, in order to restore model growth. However, gap-filling algorithms could evolve by taking into account metabolic interactions among species that coexist in microbial communities. In this work, a gap-filling method that resolves metabolic gaps at the community level was developed. The efficacy of the algorithm was tested by analyzing its ability to resolve metabolic gaps on a synthetic community of auxotrophic Escherichia coli strains. Subsequently, the algorithm was applied to resolve metabolic gaps and predict metabolic interactions in a community of Bifidobacterium adolescentis and Faecalibacterium prausnitzii, two species present in the human gut microbiota, and in an experimentally studied community of Dehalobacter and Bacteroidales species of the ACT-3 community. The community gap-filling method can facilitate the improvement of metabolic models and the identification of metabolic interactions that are difficult to identify experimentally in microbial communities., Author summary Microbes are the most abundant form of life on earth and they are almost never found in isolation as they live in close association with one another and with other organisms. The metabolic capacity of individual microbial species dictates their ways of interacting with other species as well as with their environment. The metabolic interactions among microorganisms has been recognised as the driving force for the properties of microbial communities. For this reason, understanding the effect of microbial metabolism on interspecies metabolic interactions is essential for the study of microbial communities. This study can benefit from metabolic modeling and the insights offered by constraint-based methods which have been developed for interrogating metabolic models. In this paper, we present an algorithm that predicts cooperative and competitive metabolic interactions between species while it resolves metabolic gaps in their metabolic models in a computationally efficient way. We use our community gap-filling algorithm to study microbial communities with interesting environmental and health-related applications.

Published

2021

31. Transcriptome integrated metabolic modeling of carbon assimilation underlying storage root development in cassava

Author

Porntip Chiewchankaset, Ratchaprapa Kamsen, Treenut Saithong, and Saowalak Kalapanulak

Subjects

0106 biological sciences, 0301 basic medicine, Manihot, Carbon metabolism, Science, Citric Acid Cycle, Computational biology, Pentose phosphate pathway, Biology, Models, Biological, Plant Roots, 01 natural sciences, Article, Pentose Phosphate Pathway, Transcriptome, 03 medical and health sciences, Carbon assimilation, Biochemical reaction networks, Alanine biosynthesis, Computational models, Metabolic modeling, Multidisciplinary, Biochemical networks, Metabolism, Carbon, Computational biology and bioinformatics, Citric acid cycle, 030104 developmental biology, Computer modelling, Medicine, Data integration, Systems biology, Glycolysis, Metabolic engineering, 010606 plant biology & botany

Abstract

The existing genome-scale metabolic model of carbon metabolism in cassava storage roots, rMeCBM, has proven particularly resourceful in exploring the metabolic basis for the phenotypic differences between high and low-yield cassava cultivars. However, experimental validation of predicted metabolic fluxes by carbon labeling is quite challenging. Here, we incorporated gene expression data of developing storage roots into the basic flux-balance model to minimize infeasible metabolic fluxes, denoted as rMeCBMx, thereby improving the plausibility of the simulation and predictive power. Three different conceptual algorithms, GIMME, E-Flux, and HPCOF were evaluated. The rMeCBMx-HPCOF model outperformed others in predicting carbon fluxes in the metabolism of storage roots and, in particular, was highly consistent with transcriptome of high-yield cultivars. The flux prediction was improved through the oxidative pentose phosphate pathway in cytosol, as has been reported in various studies on root metabolism, but hardly captured by simple FBA models. Moreover, the presence of fluxes through cytosolic glycolysis and alanine biosynthesis pathways were predicted with high consistency with gene expression levels. This study sheds light on the importance of prediction power in the modeling of complex plant metabolism. Integration of multi-omics data would further help mitigate the ill-posed problem of constraint-based modeling, allowing more realistic simulation.

Published

2021

32. Proteome constraints reveal targets for improving microbial fitness in nutrient‐rich environments

Author

Eunice van Pelt-KleinJan, Yu Chen, Sieze Douwenga, Berdien van Olst, Bas Teusink, Herwig Bachmann, Douwe Molenaar, Sjef Boeren, Jens Nielsen, Systems Bioinformatics, and AIMMS

Subjects

Medicine (General), Arginine, Proteome, Microorganism, Mutant, Proteomics, Biochemistry, 0302 clinical medicine, Adenosine Triphosphate, metabolic modeling, Gene expression, Biology (General), laboratory evolution, 0303 health sciences, biology, Applied Mathematics, Laboratory evolution, Articles, Biological Evolution, Microbiology, Virology & Host Pathogen Interaction, Lactococcus lactis, proteome constraint, Computational Theory and Mathematics, ccpA, General Agricultural and Biological Sciences, Information Systems, QH301-705.5, Proteome constraint, Biochemie, Chemostat, Computational biology, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Article, Metabolic modeling, 03 medical and health sciences, R5-920, Bacterial Proteins, Host-Microbe Interactomics, VLAG, 030304 developmental biology, General Immunology and Microbiology, Reproducibility of Results, Metabolism, biology.organism_classification, Glucose, Mutation, Genetic Fitness, Flux (metabolism), Bacteria, Function (biology), 030217 neurology & neurosurgery

Abstract

Cells adapt to different conditions via gene expression that tunes metabolism for maximal fitness. Constraints on cellular proteome may limit such expression strategies and introduce trade‐offs. Resource allocation under proteome constraints has explained regulatory strategies in bacteria. It is unclear, however, to what extent these constraints can predict evolutionary changes, especially for microorganisms that evolved under nutrient‐rich conditions, i.e., multiple available nitrogen sources, such as Lactococcus lactis. Here, we present a proteome‐constrained genome‐scale metabolic model of L. lactis (pcLactis) to interpret growth on multiple nutrients. Through integration of proteomics and flux data, in glucose‐limited chemostats, the model predicted glucose and arginine uptake as dominant constraints at low growth rates. Indeed, glucose and arginine catabolism were found upregulated in evolved mutants. At high growth rates, pcLactis correctly predicted the observed shutdown of arginine catabolism because limited proteome availability favored lactate for ATP production. Thus, our model‐based analysis is able to identify and explain the proteome constraints that limit growth rate in nutrient‐rich environments and thus form targets of fitness improvement., A proteome‐constrained genome‐scale metabolic model of Lactococcus lactis (pcLactis) is presented. The model is used to interpret microbial behaviour in nutrient‐rich conditions and predicts testable targets for fitness improvement.

Published

2021

33. From Next-Generation Sequencing to Systematic Modeling of the Gut Microbiome.

Author

Boyang Ji and Nielsen, Jens

Subjects

GUT microbiome, HUMAN microbiota, INDIVIDUALIZED medicine, MICROBIAL ecology, METABOLISM, PERIODICALS

Abstract

Changes in the human gut microbiome is associated with altered human metabolism and health, yet the mechanisms of interactions between microbial species and human metabolism have not been clearly elucidated. Next-generation sequencing has revolutionized the human gut microbiome research, but most current applications concentrate on studying the microbial diversity of communities and have at best provided associations between specific gut bacteria and human health. However, little is known about the inner metabolic mechanisms in the gut ecosystem. Here we review recent progress in modeling the metabolic interactions of gut microbiome, with special focus on the utilization of metabolic modeling to infer host-microbe interactions and microbial species interactions. The systematic modeling of metabolic interactions could provide a predictive understanding of gut microbiome, and pave the way to synthetic microbiota design and personalized-microbiome medicine and healthcare. Finally, we discuss the integration of metabolic modeling and gut microbiome engineering, which offer a new way to explore metabolic interactions across members of the gut microbiota. [ABSTRACT FROM AUTHOR]

Published

2015

34. Genome-scale metabolic modeling reveals SARS-CoV-2-induced metabolic changes and antiviral targets

Author

Yuan Pu, Xin Yin, Sumit K. Chanda, Nishanth Ulhas Nair, Eytan Ruppin, Laura Riva, Sanju Sinha, Lipika R. Pal, Laura Martin-Sancho, and Kuoyuan Cheng

Subjects

Medicine (General), viruses, Genome scale, Datasets as Topic, remdesivir, SARS‐CoV‐2, Chlorocebus aethiops, Metabolic modeling, Biology (General), RNA, Small Interfering, RNAi screen, media_common, Alanine, antiviral target, Applied Mathematics, Articles, Microbiology, Virology & Host Pathogen Interaction, Drug repositioning, Computational Theory and Mathematics, Drug development, Host-Pathogen Interactions, General Agricultural and Biological Sciences, Reprogramming, Metabolic Networks and Pathways, Information Systems, Drug, QH301-705.5, media_common.quotation_subject, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Computational biology, Biology, Antiviral Agents, General Biochemistry, Genetics and Molecular Biology, Article, Virus, R5-920, Drug Development, Animals, Humans, Pharmacology & Drug Discovery, Pandemics, Vero Cells, genome‐scale metabolic modeling, General Immunology and Microbiology, SARS-CoV-2, Sequence Analysis, RNA, Drug Repositioning, COVID-19, Adenosine Monophosphate, COVID-19 Drug Treatment, Metabolism, Vero cell, Caco-2 Cells, Genetic screen

Abstract

Tremendous progress has been made to control the COVID‐19 pandemic caused by the SARS‐CoV‐2 virus. However, effective therapeutic options are still rare. Drug repurposing and combination represent practical strategies to address this urgent unmet medical need. Viruses, including coronaviruses, are known to hijack host metabolism to facilitate viral proliferation, making targeting host metabolism a promising antiviral approach. Here, we describe an integrated analysis of 12 published in vitro and human patient gene expression datasets on SARS‐CoV‐2 infection using genome‐scale metabolic modeling (GEM), revealing complicated host metabolism reprogramming during SARS‐CoV‐2 infection. We next applied the GEM‐based metabolic transformation algorithm to predict anti‐SARS‐CoV‐2 targets that counteract the virus‐induced metabolic changes. We successfully validated these targets using published drug and genetic screen data and by performing an siRNA assay in Caco‐2 cells. Further generating and analyzing RNA‐sequencing data of remdesivir‐treated Vero E6 cell samples, we predicted metabolic targets acting in combination with remdesivir, an approved anti‐SARS‐CoV‐2 drug. Our study provides clinical data‐supported candidate anti‐SARS‐CoV‐2 targets for future evaluation, demonstrating host metabolism targeting as a promising antiviral strategy., Metabolic modeling of 12 SARS‐CoV‐2 datasets identifies novel single or combinatory antiviral targets by reverting the virus‐induced host metabolic reprogramming.

Published

2021

35. Metabolic Modeling of the C3-CAM Continuum Revealed the Establishment of a Starch/Sugar-Malate Cycle in CAM Evolution

Author

C. Y. Maurice Cheung, Ignacius Y. Y. Tay, and Kristoforus Bryant Odang

Subjects

0106 biological sciences, 0301 basic medicine, Stomatal conductance, Starch, flux balance analysis, Plant Science, lcsh:Plant culture, Photosynthesis, 01 natural sciences, Tricarboxylate, CAM evolution, chemistry.chemical_compound, 03 medical and health sciences, CAM cycling, metabolic modeling, lcsh:SB1-1110, Sugar, CAM idling, Original Research, Chemistry, Carbon fixation, Metabolism, Electron transport chain, Flux balance analysis, 030104 developmental biology, crassulacean acid metabolism, Biophysics, Crassulacean acid metabolism, 010606 plant biology & botany

Abstract

The evolution of Crassulacean acid metabolism (CAM) is thought to be along a C3-CAM continuum including multiple variations of CAM such as CAM cycling and CAM idling. Here, we applied large-scale constraint-based modelling to investigate the metabolism and energetics of plants operating in C3, CAM, CAM cycling and CAM idling. Our modelling results suggested that CAM cycling and CAM idling could be potential evolutionary intermediates in CAM evolution by establishing a starch/sugar-malate cycle. Our model analysis showed that by varying CO2 exchange during the light period, as a proxy of stomatal conductance, there exists a C3-CAM continuum with gradual metabolic changes, supporting the notion that evolution of CAM from C3 could occur solely through incremental changes in metabolic fluxes. Along the C3-CAM continuum, our model predicted changes in metabolic fluxes not only through the starch/sugar-malate cycle that is involved in CAM photosynthetic CO2 fixation but also other metabolic processes including the mitochondrial electron transport chain and the tricarboxylate acid cycle at night. These predictions could guide engineering efforts in introducing CAM into C3 crops for improved water use efficiency.

Published

2021

36. Genome-scale modeling of light-driven reductant partitioning and carbon fluxes in diazotrophic unicellular cyanobacterium Cyanothece sp. ATCC 51142

Author

Reed, Jennifer

Published

2012

37. A genome-scale metabolic flux model of Escherichia coli K¿12 derived from the EcoCyc database.

Author

Weaver, Daniel S., Keseler, Ingrid M., Mackie, Amanda, Paulsen, Ian T., and Karp, Peter D.

Subjects

*BACTERIAL genetics, *ESCHERICHIA coli, *METABOLISM, *METABOLIC flux analysis, *PREDICTION models, *GLUCOSE

Abstract

Background Constraint-based models of Escherichia coli metabolic flux have played a key role in computational studies of cellular metabolism at the genome scale. We sought to develop a next-generation constraintbased E. coli model that achieved improved phenotypic prediction accuracy while being frequently updated and easy to use. We also sought to compare model predictions with experimental data to highlight open questions in E. coli biology. Results We present EcoCyc–18.0–GEM, a genome-scale model of the E. coli K–12 MG1655 metabolic network. The model is automatically generated from the current state of EcoCyc using the MetaFlux software, enabling the release of multiple model updates per year. EcoCyc–18.0–GEM encompasses 1445 genes, 2286 unique metabolic reactions, and 1453 unique metabolites. We demonstrate a threepart validation of the model that breaks new ground in breadth and accuracy: (i) Comparison of simulated growth in aerobic and anaerobic glucose culture with experimental results from chemostat culture and simulation results from the E. coli modeling literature. (ii) Essentiality prediction for the 1445 genes represented in the model, in which EcoCyc–18.0–GEM achieves an improved accuracy of 95.2% in predicting the growth phenotype of experimental gene knockouts. (iii) Nutrient utilization predictions under 431 different media conditions, for which the model achieves an overall accuracy of 80.7%. The model's derivation from EcoCyc enables query and visualization via the EcoCyc website, facilitating model reuse and validation by inspection. We present an extensive investigation of disagreements between EcoCyc–18.0–GEM predictions and experimental data to highlight areas of interest to E. coli modelers and experimentalists, including 70 incorrect predictions of gene essentiality on glucose, 80 incorrect predictions of gene essentiality on glycerol, and 83 incorrect predictions of nutrient utilization. Conclusion Significant advantages can be derived from the combination of model organism databases and flux balance modeling represented by MetaFlux. Interpretation of the EcoCyc database as a flux balance model results in a highly accurate metabolic model and provides a rigorous consistency check for information stored in the database. [ABSTRACT FROM AUTHOR]

Published

2014

38. Knowledge-based generalization of metabolic networks: A practical study.

Author

Zhukova, Anna and Sherman, David J.

Subjects

*DECISION making, *METABOLIC models, *GENERALIZATION, *FATTY acids, *ORGANISMS, *METABOLISM

Abstract

The complex process of genome-scale metabolic network reconstruction involves semi-automatic reaction inference, analysis, and refinement through curation by human experts. Unfortunately, decisions by experts are hampered by the complexity of the network, which can mask errors in the inferred network. In order to aid an expert in making sense out of the thousands of reactions in the organism's metabolism, we developed a method for knowledge-based generalization that provides a higher-level view of the network, highlighting the particularities and essential structure, while hiding the details. In this study, we show the application of this generalization method to 1,286 metabolic networks of organisms in Path2Models that describe fatty acid metabolism. We compare the generalised networks and show that we successfully highlight the aspects that are important for their curation and comparison. [ABSTRACT FROM AUTHOR]

Published

2014

39. Computational tools for modeling xenometabolism of the human gut microbiota.

Author

Klünemann, Martina, Schmid, Melanie, and Patil, Kiran Raosaheb

Subjects

*COMPUTATIONAL biology, *MICROBIOLOGY, *HOLISTIC medicine, *METABOLISM, *BIOTECHNOLOGY

Abstract

Highlights: [•] We provide a conceptual overview of the hierarchy of xenometabolic processes in the gut microbiota. [•] We review computational tools relevant for modeling complex xenometabolic processes. [•] We present a unified perspective towards building holistic models of xenometabolism. [Copyright &y& Elsevier]

Published

2014

40. A Distance-Based Framework for the Characterization of Metabolic Heterogeneity in Large Sets of Genome-Scale Metabolic Models

Author

Peter A. J. Hilbers, Natal A. W. van Riel, Andrea Cabbia, Experimental Vascular Medicine, ACS - Microcirculation, Amsterdam Gastroenterology Endocrinology Metabolism, Computational Biology, and EAISI Health

Subjects

genome-scale metabolic models, Genome scale, General Decision Sciences, implemented, Computational biology, Biology, SDG 3 – Goede gezondheid en welzijn, and tested for one domain/problem, Article, Machine Learning, 03 medical and health sciences, 0302 clinical medicine, SDG 3 - Good Health and Well-being, DSML 2: Proof-of-Concept: Data science output has been formulated, implemented, and tested for one domain/problem, Consensus clustering, Genome-scale metabolic model, DSML 2: Proof-of-Concept: Data science output has been formulated, Metabolic modeling, 030304 developmental biology, lcsh:Computer software, 0303 health sciences, Distance, Metabolic heterogeneity, Correction, Model composition, Workflow, lcsh:QA76.75-76.765, Metabolism, Pattern recognition (psychology), heterogeneity, 030217 neurology & neurosurgery, Distance based

Abstract

Summary Gene expression and protein abundance data of cells or tissues belonging to healthy and diseased individuals can be integrated and mapped onto genome-scale metabolic networks to produce patient-derived models. As the number of available and newly developed genome-scale metabolic models increases, new methods are needed to objectively analyze large sets of models and to identify the determinants of metabolic heterogeneity. We developed a distance-based workflow that combines consensus machine learning and metabolic modeling techniques and used it to apply pattern recognition algorithms to collections of genome-scale metabolic models, both microbial and human. Model composition, network topology and flux distribution provide complementary aspects of metabolic heterogeneity in patient-specific genome-scale models of skeletal muscle. Using consensus clustering analysis we identified the metabolic processes involved in the individual responses to endurance training in older adults., Highlights • Distance metrics express heterogeneity between genome-scale metabolic models • Flux distribution and network topology are the main components of metabolic distance • Machine learning algorithms are applicable to sets of genome-scale metabolic models • We model individual responses to endurance training in older adults, The Bigger Picture High-throughput techniques enable the analysis of complex biological systems at multiple levels, including genome, transcriptome, proteome, and metabolome. Integration of multi-omics data is often focused on dimensionality reduction and feature selection for classification tasks. Genome-scale metabolic models are extensive maps of the network of biochemical reactions taking place in a particular cell, tissue or organism. Each reaction is associated with the respective enzyme and gene, enabling the mapping of transcriptomics and proteomics data and providing a structure for the system-level interpretation of multi-omics datasets. The result of this process is a personalized model that gives a snapshot of the metabolic status of an individual. Analyzing these complex models, for example, to detect differences between individuals, is cumbersome. We applied consensus clustering to a set of data-driven models to monitor the progression of a lifestyle intervention in a cohort of older adults., Genome-scale metabolic models are maps of the metabolic network that function as structures for the integration of molecular data, such as transcriptomics and proteomics. We developed a method for the analysis of large sets of data-driven models, using different distance metrics to quantify model similarity. Consensus analysis is then used to reach a single metabolic distance. The method was applied to model the individual variability in the responses to endurance training in a cohort of older adults.

Published

2020

41. Integration of machine learning and genome-scale metabolic modeling identifies multi-omics biomarkers for radiation resistance

Author

Joshua E. Lewis and Melissa L. Kemp

Subjects

0301 basic medicine, Computer science, Metabolite, Genome scale, General Physics and Astronomy, Datasets as Topic, computer.software_genre, Genome, Radiation Tolerance, Transcriptome, Machine Learning, chemistry.chemical_compound, 0302 clinical medicine, Radiation sensitivity, Neoplasms, Radiation, Ionizing, Databases, Genetic, Metabolic modeling, Metabolic biomarkers, Multidisciplinary, Flux balance analysis, Neoplasm Proteins, Gene Expression Regulation, Neoplastic, Treatment Outcome, 030220 oncology & carcinogenesis, Biomarker (medicine), Metabolic Networks and Pathways, Science, Machine learning, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Metabolomics, Atlases as Topic, Cell Line, Tumor, Humans, Radiosensitivity, business.industry, Genome, Human, Metabolism, General Chemistry, Survival Analysis, 030104 developmental biology, chemistry, Multi omics, Artificial intelligence, business, METABOLIC FEATURES, computer

Abstract

Resistance to ionizing radiation, a first-line therapy for many cancers, is a major clinical challenge. Personalized prediction of tumor radiosensitivity is not currently implemented clinically due to insufficient accuracy of existing machine learning classifiers. Despite the acknowledged role of tumor metabolism in radiation response, metabolomics data is rarely collected in large multi-omics initiatives such as The Cancer Genome Atlas (TCGA) and consequently omitted from algorithm development. In this study, we circumvent the paucity of personalized metabolomics information by characterizing 915 TCGA patient tumors with genome-scale metabolic Flux Balance Analysis models generated from transcriptomic and genomic datasets. Novel metabolic biomarkers differentiating radiation-sensitive and -resistant tumors were predicted and experimentally validated, enabling integration of metabolic features with other multi-omics datasets into ensemble-based machine learning classifiers for radiation response. These multi-omics classifiers showed improved classification accuracy, identified novel clinical patient subgroups, and demonstrated the utility of personalized blood-based metabolic biomarkers for radiation sensitivity. The integration of machine learning with genome-scale metabolic modeling represents a significant methodological advancement for identifying prognostic metabolite biomarkers and predicting radiosensitivity for individual patients.

Published

2020

42. Personalized whole‐body models integrate metabolism, physiology, and the gut microbiome

Author

Ronan M. T. Fleming, Maike K. Aurich, Almut Heinken, Ines Thiele, Laurent Heirendt, Johannes Hertel, and Swagatika Sahoo

Subjects

Male, Proteomics, Medicine (General), QH301-705.5, flux balance analysis, microbiome, Metabolic network, Human metabolism, Computational biology, Biology, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, R5-920, 0302 clinical medicine, Metabolomics, metabolic modeling, Humans, Computer Simulation, Microbiome, Biology (General), 030304 developmental biology, 0303 health sciences, Computational model, General Immunology and Microbiology, Systems Biology, Applied Mathematics, Computational Biology, Articles, Gut microbiome, Gastrointestinal Microbiome, Flux balance analysis, Metabolism, Gene Expression Regulation, Computational Theory and Mathematics, Organ Specificity, human metabolism, Metabolome, Female, Energy Metabolism, General Agricultural and Biological Sciences, Whole body, Algorithms, Biomarkers, Metabolic Networks and Pathways, 030217 neurology & neurosurgery, Information Systems

Abstract

Comprehensive molecular‐level models of human metabolism have been generated on a cellular level. However, models of whole‐body metabolism have not been established as they require new methodological approaches to integrate molecular and physiological data. We developed a new metabolic network reconstruction approach that used organ‐specific information from literature and omics data to generate two sex‐specific whole‐body metabolic (WBM) reconstructions. These reconstructions capture the metabolism of 26 organs and six blood cell types. Each WBM reconstruction represents whole‐body organ‐resolved metabolism with over 80,000 biochemical reactions in an anatomically and physiologically consistent manner. We parameterized the WBM reconstructions with physiological, dietary, and metabolomic data. The resulting WBM models could recapitulate known inter‐organ metabolic cycles and energy use. We also illustrate that the WBM models can predict known biomarkers of inherited metabolic diseases in different biofluids. Predictions of basal metabolic rates, by WBM models personalized with physiological data, outperformed current phenomenological models. Finally, integrating microbiome data allowed the exploration of host–microbiome co‐metabolism. Overall, the WBM reconstructions, and their derived computational models, represent an important step toward virtual physiological humans., Sex‐specific, whole‐body human metabolic models were developed and constrained with physiological, dietary, and metabolomic data. They recapitulate known whole‐body metabolic functions and enable mechanistic exploration of host‐microbiome co‐metabolism.

Published

2020

43. FastMM: an efficient toolbox for personalized constraint-based metabolic modeling

Author

Jing-Fei Huang, Gong-Hua Li, Wen-Xing Li, Fei-Fei Han, Shao-Xing Dai, and Wenzhong Xiao

Subjects

Interface (Java), Computer science, lcsh:Computer applications to medicine. Medical informatics, computer.software_genre, Models, Biological, Biochemistry, Genome, Metabolic modeling, 03 medical and health sciences, symbols.namesake, 0302 clinical medicine, Structural Biology, Neoplasms, Humans, MATLAB, lcsh:QH301-705.5, Molecular Biology, 030304 developmental biology, computer.programming_language, 0303 health sciences, Constraint-based model, Applied Mathematics, Markov chain Monte Carlo, Metabolism, Toolbox, Computer Science Applications, Flux balance analysis, Constraint (information theory), FastMM, lcsh:Biology (General), symbols, lcsh:R858-859.7, Data mining, DNA microarray, Threading (protein sequence), computer, Metabolic Networks and Pathways, Software, 030217 neurology & neurosurgery

Abstract

Background Constraint-based metabolic modeling has been applied to understand metabolism related disease mechanisms, to predict potential new drug targets and anti-metabolites, and to identify biomarkers of complex diseases. Although the state-of-art modeling toolbox, COBRA 3.0, is powerful, it requires substantial computing time conducting flux balance analysis, knockout analysis, and Markov Chain Monte Carlo (MCMC) sampling, which may limit its application in large scale genome-wide analysis. Results Here, we rewrote the underlying code of COBRA 3.0 using C/C++, and developed a toolbox, termed FastMM, to effectively conduct constraint-based metabolic modeling. The results showed that FastMM is 2~400 times faster than COBRA 3.0 in performing flux balance analysis and knockout analysis and returns consistent outputs. When applied to MCMC sampling, FastMM is 8 times faster than COBRA 3.0. FastMM is also faster than some efficient metabolic modeling applications, such as Cobrapy and Fast-SL. In addition, we developed a Matlab/Octave interface for fast metabolic modeling. This interface was fully compatible with COBRA 3.0, enabling users to easily perform complex applications for metabolic modeling. For example, users who do not have deep constraint-based metabolic model knowledge can just type one command in Matlab/Octave to perform personalized metabolic modeling. Users can also use the advance and multiple threading parameters for complex metabolic modeling. Thus, we provided an efficient and user-friendly solution to perform large scale genome-wide metabolic modeling. For example, FastMM can be applied to the modeling of individual cancer metabolic profiles of hundreds to thousands of samples in the Cancer Genome Atlas (TCGA). Conclusion FastMM is an efficient and user-friendly toolbox for large-scale personalized constraint-based metabolic modeling. It can serve as a complementary and invaluable improvement to the existing functionalities in COBRA 3.0. FastMM is under GPL license and can be freely available at GitHub site: https://github.com/GonghuaLi/FastMM.

Published

2020

44. AN INTEGRATIVE EXPERIMENTAL AND COMPUTATIONAL FRAMEWORK FOR THE GENOME-SCALE FLUX ANALYSIS OF ANTIBIOTIC RESISTANCE

Author

Mack, Sean

Subjects

FOS: Computer and information sciences, Metabolism, Bioinformatics, Molecular biology, Antibiotic Resistance, Flux Analysis, Metabolic Modeling, Computational Biology, Bioengineering, Network Reduction

Abstract

The prevalence of antibiotic-resistant bacterial pathogens demands the development of novel therapeutic approaches. An attractive target is metabolism, where the impact of antibiotics and resistance remains poorly understood. Numerous omics-driven studies have identified a metabolic response due to antibiotic stress and suggested that metabolism adjusts to accommodate the genetic burden of resistance. Arising from these data is the hypothesis that context-specific modification of metabolism is a key component of antibiotic resistance and stress. Further exploration of the relationship between metabolism, antibiotic stress, and resistance is clearly needed. To elucidate metabolic signatures of antibiotic resistance, we analyzed the metabolic behaviors of wild-type and resistant strains of Escherichia coli through a combined transcriptomic and fluxomic analysis. Specifically, we compared wild-type E. coli to isogenic strains expressing integrated copies of tetRA and dhfr resistance genes, respectively under normal and antibiotic stress conditions. From comprehensive genome-scale (GS) flux predictions, we observed a resistance-associated metabolic phenotype as well as mechanism- and target-specific metabolic shifts. Furthermore, we identified a distinct metabolic response to antibiotic stress in both resistant strains. To improve our computational framework, we developed NetRed, NetRed-MFA, and NetFlow, each designed to reduce complexity of GS flux analysis. Through lossless reduction of genome-scale models (GSMs), NetRed generated a comprehensive minimal model for aerobic and anaerobic growth in E. coli and rapidly elucidated the mechanism driving artemisinin production in yeast. NetRed-MFA extended the original algorithm by incorporating full carbon mapping to generate reduced models for 13C metabolic flux analysis. NetFlow leveraged GS carbon mapping to isolate the major carbon flows through a core network and GSM; from the GSM subnetwork, we identified a mechanistic relationship between a triple-knockout and increased lycopene production in E. coli. Our resistance work represents the first application of quantitative flux analysis to study the metabolism of resistant bacteria and should provide significant insight into the role of metabolic adaptation in antibiotic resistance. The developed tools each dramatically improve the interpretation of GS flux predictions and the mechanistic understanding of metabolic perturbations. Taken together, this dissertation describes a comprehensive framework for the prediction, comparison, and interpretation of altered metabolic states.

Published

2020

45. Metabolic modeling and response surface analysis of an Escherichia coli strain engineered for shikimic acid production

Author

Juan A. Martínez, Alvaro R. Lara, Francisco Bolívar, Guillermo Gosset, Fabian Moreno, Noemí Flores, Alberto Rodriguez, and Octavio T. Ramírez

Subjects

0106 biological sciences, 0301 basic medicine, Microbial metabolism, Glyoxylate cycle, Pentose phosphate pathway, medicine.disease_cause, 01 natural sciences, Models, Biological, Metabolic modeling, Metabolic engineering, 03 medical and health sciences, chemistry.chemical_compound, Central carbon metabolism, Structural Biology, 010608 biotechnology, medicine, Escherichia coli, Glycolysis, Shikimic acid, Molecular Biology, lcsh:QH301-705.5, Applied Mathematics, Biological Transport, Metabolism, Carbon, Metabolic Flux Analysis, Computer Science Applications, 030104 developmental biology, Glucose, chemistry, Biochemistry, Metabolic Engineering, lcsh:Biology (General), Response surface analysis, Modeling and Simulation, Research Article, Cybernetic modeling

Abstract

Background Classic metabolic engineering strategies often induce significant flux imbalances to microbial metabolism, causing undesirable outcomes such as suboptimal conversion of substrates to products. Several mathematical frameworks have been developed to understand the physiological and metabolic state of production strains and to identify genetic modification targets for improved bioproduct formation. In this work, a modeling approach was applied to describe the physiological behavior and the metabolic fluxes of a shikimic acid overproducing Escherichia coli strain lacking the major glucose transport system, grown on complex media. Results The obtained flux distributions indicate the presence of high fluxes through the pentose phosphate and Entner-Doudoroff pathways, which could limit the availability of erythrose-4-phosphate for shikimic acid production even with high flux redirection through the pentose phosphate pathway. In addition, highly active glyoxylate shunt fluxes and a pyruvate/acetate cycle are indicators of overflow glycolytic metabolism in the tested conditions. The analysis of the combined physiological and flux response surfaces, enabled zone allocation for different physiological outputs within variant substrate conditions. This information was then used for an improved fed-batch process designed to preserve the metabolic conditions that were found to enhance shikimic acid productivity. This resulted in a 40% increase in the shikimic acid titer (60 g/L) and 70% increase in volumetric productivity (2.45 gSA/L*h), while preserving yields, compared to the batch process. Conclusions The combination of dynamic metabolic modeling and experimental parameter response surfaces was a successful approach to understand and predict the behavior of a shikimic acid producing strain under variable substrate concentrations. Response surfaces were useful for allocating different physiological behavior zones with different preferential product outcomes. Both model sets provided information that could be applied to enhance shikimic acid production on an engineered shikimic acid overproducing Escherichia coli strain. Electronic supplementary material The online version of this article (10.1186/s12918-018-0632-4) contains supplementary material, which is available to authorized users.

Published

2018

46. Highlights from the Indo-US workshop “Cyanobacteria: molecular networks to biofuels” held at Lonavala, India during December 16–20, 2012.

Author

Sherman, Louis A., Wangikar, Pramod P., Swarup, Renu, and Kasture, Sangita

Abstract

An Indo-US workshop on “Cyanobacteria: molecular networks to biofuels” was held December 16–20, 2012 at Lagoona Resort, Lonavala, India. The workshop was jointly organized by two of the authors, PPW, a chemical engineer and LAS, a biologist, thereby ensuring a broad and cross-disciplinary participation. The main objective of the workshop was to bring researchers from academia and industry of the two countries together with common interests in cyanobacteria or microalgae and derived biofuels. An exchange of ideas resulted from a series of oral and poster presentations and, importantly, through one-on-one discussions during tea breaks and meals. Another key objective was to introduce young researchers of India to the exciting field of cyanobacterial physiology, modeling, and biofuels. PhD students and early stage researchers were especially encouraged to participate and about half of the 75 participants belonged to this category. The rest were comprised of senior researchers, including 13–15 invited speakers from each country. Overall, twenty-four institutes from 12 states of India were represented. The deliberations, which are being compiled in the present special issue, revolved mainly around molecular aspects of cyanobacterial biofuels including metabolic engineering, networks, genetic regulation, circadian rhythms, and stress responses. Representatives of some key funding agencies and industry provided a perspective and opportunities in the field and for bilateral collaboration. This article summarizes deliberations that took place at the meeting and provides a bird’s eye view of the ongoing research in the field in the two countries. [ABSTRACT FROM AUTHOR]

Published

2013

47. Rapid construction of metabolic models for a family of Cyanobacteria using a multiple source annotation workflow.

Author

Mueller, Thomas J., Berla, Bertram M., Pakrasi, Himadri B., and Maranas, Costas D.

Subjects

*CYANOBACTERIA, *METABOLISM, *NUTRITION, *SOLAR energy, *CARBON dioxide

Abstract

Background Cyanobacteria are photoautotrophic prokaryotes that exhibit robust growth under diverse environmental conditions with minimal nutritional requirements. They can use solar energy to convert CO2 and other reduced carbon sources into biofuels and chemical products. The genus Cyanothece includes unicellular nitrogen-fixing cyanobacteria that have been shown to offer high levels of hydrogen production and nitrogen fixation. The reconstruction of quality genome-scale metabolic models for organisms with limited annotation resources remains a challenging task. Results Here we reconstruct and subsequently analyze and compare the metabolism of five Cyanothece strains, namely Cyanothece sp. PCC 7424, 7425, 7822, 8801 and 8802, as the genome-scale metabolic reconstructions iCyc792, iCyn731, iCyj826, iCyp752, and iCyh755 respectively. We compare these phylogenetically related Cyanothece strains to assess their bio-production potential. A systematic workflow is introduced for integrating and prioritizing annotation information from the Universal Protein Resource (Uniprot), NCBI Protein Clusters, and the Rapid Annotations using Subsystems Technology (RAST) method. The genome-scale metabolic models include fully traced photosynthesis reactions and respiratory chains, as well as balanced reactions and GPR associations. Metabolic differences between the organisms are highlighted such as the non-fermentative pathway for alcohol production found in only Cyanothece 7424, 8801, and 8802. Conclusions Our development workflow provides a path for constructing models using information from curated models of related organisms and reviewed gene annotations. This effort lays the foundation for the expedient construction of curated metabolic models for organisms that, while not being the target of comprehensive research, have a sequenced genome and are related to an organism with a curated metabolic model. Organism specific models, such as the five presented in this paper, can be used to identify optimal genetic manipulations for targeted metabolite overproduction as well as to investigate the biology of diverse organisms. [ABSTRACT FROM AUTHOR]

Published

2013

48. A combined model of hepatic polyamine and sulfur amino acid metabolism to analyze S-adenosyl methionine availability.

Author

Reyes-Palomares, Armando, Montañez, Raúl, Sánchez-Jiménez, Francisca, and Medina, Miguel

Subjects

*POLYAMINES, *METHIONINE, *SYSTEMS biology, *METABOLISM, *ISOENZYMES, *GENETIC regulation, *HOMEOSTASIS, *GLUTATHIONE

Abstract

Many molecular details remain to be uncovered concerning the regulation of polyamine metabolism. A previous model of mammalian polyamine metabolism showed that S-adenosyl methionine availability could play a key role in polyamine homeostasis. To get a deeper insight in this prediction, we have built a combined model by integration of the previously published polyamine model and one-carbon and glutathione metabolism model, published by different research groups. The combined model is robust and it is able to achieve physiological steady-state values, as well as to reproduce the predictions of the individual models. Furthermore, a transition between two versions of our model with new regulatory factors added properly simulates the switch in methionine adenosyl transferase isozymes occurring when the liver enters in proliferative conditions. The combined model is useful to support the previous prediction on the role of S-adenosyl methionine availability in polyamine homeostasis. Furthermore, it could be easily adapted to get deeper insights on the connections of polyamines with energy metabolism. [ABSTRACT FROM AUTHOR]

Published

2012

49. Unpredictability of metabolism-the key role of metabolomics science in combination with next-generation genome sequencing.

Author

Weckwerth, Wolfram

Subjects

*METABOLISM, *GENOMES, *RNA, *NUCLEOTIDE sequence, *EUKARYOTIC cells

Abstract

Next-generation sequencing provides technologies which sequence whole prokaryotic and eukaryotic genomes in days, perform genome-wide association studies, chromatin immunoprecipitation followed by sequencing and RNA sequencing for transcriptome studies. An exponentially growing volume of sequence data can be anticipated, yet functional interpretation does not keep pace with the amount of data produced. In principle, these data contain all the secrets of living systems, the genotype-phenotype relationship. Firstly, it is possible to derive the structure and connectivity of the metabolic network from the genotype of an organism in the form of the stoichiometric matrix N. This is, however, static information. Strategies for genome-scale measurement, modelling and predicting of dynamic metabolic networks need to be applied. Consequently, metabolomics science-the quantitative measurement of metabolism in conjunction with metabolic modelling-is a key discipline for the functional interpretation of whole genomes and especially for testing the numerical predictions of metabolism based on genome-scale metabolic network models. In this context, a systematic equation is derived based on metabolomics covariance data and the genome-scale stoichiometric matrix which describes the genotype-phenotype relationship. [ABSTRACT FROM AUTHOR]

Published

2011

50. A flexible state-space approach for the modeling of metabolic networks II: Advanced interrogation of hybridoma metabolism

Author

Baughman, Adam C., Sharfstein, Susan T., and Martin, Lealon L.

Subjects

*HYBRIDOMAS, *METABOLISM, *STOICHIOMETRY, *METABOLITES, *TOPOLOGY, *MATHEMATICAL optimization

Abstract

Abstract: Having previously introduced the mathematical framework of topological metabolic analysis (TMA) – a novel optimization-based technique for modeling metabolic networks of arbitrary size and complexity – we demonstrate how TMA facilitates unique methods of metabolic interrogation. With the aid of several hybridoma metabolic investigations as case-studies (), we first establish that the TMA framework identifies biologically important aspects of the metabolic network under investigation. We also show that the use of a structured weighting approach within our objective provides a substantial modeling benefit over an unstructured, uniform, weighting approach. We then illustrate the strength of TAM as an advanced interrogation technique, first by using TMA to prove the existence of (and to quantitatively describe) multiple topologically distinct configurations of a metabolic network that each optimally model a given set of experimental observations. We further show that such alternate topologies are indistinguishable using existing stoichiometric modeling techniques, and we explain the biological significance of the topological variables appearing within our model. By leveraging the manner in which TMA implements metabolite inputs and outputs, we also show that metabolites whose possible metabolic fates are inadequately described by a given network reconstruction can be quickly identified. Lastly, we show how the use of the TMA aggregate objective function (AOF) permits the identification of modeling solutions that can simultaneously consider experimental observations, underlying biological motivations, or even purely engineering- or design-based goals. [Copyright &y& Elsevier]

Published

2011