Your search keyword '"based metabolic flux"' showing total 659 results

1. Thermodynamics-Based Metabolic Flux Analysis

Author

Henry, Christopher S., Broadbelt, Linda J., and Hatzimanikatis, Vassily

Published

2007

2. The Metabolic Flux Probe (MFP)-Secreted Protein as a Non-Disruptive Information Carrier for 13 C-Based Metabolic Flux Analysis.

Author

Dusny C and Schmid A

Subjects

Carbon Isotopes metabolism, Saccharomycetales growth & development, 6-Phytase metabolism, Carbon Isotopes analysis, Fungal Proteins metabolism, Glucose metabolism, Isotope Labeling methods, Metabolic Flux Analysis methods, Saccharomycetales metabolism

Abstract

Novel cultivation technologies demand the adaptation of existing analytical concepts. Metabolic flux analysis (MFA) requires stable-isotope labeling of biomass-bound protein as the primary information source. Obtaining the required protein in cultivation set-ups where biomass is inaccessible due to low cell densities and cell immobilization is difficult to date. We developed a non-disruptive analytical concept for 13 C-based metabolic flux analysis based on secreted protein as an information carrier for isotope mapping in the protein-bound amino acids. This "metabolic flux probe" (MFP) concept was investigated in different cultivation set-ups with a recombinant, protein-secreting yeast strain. The obtained results grant insight into intracellular protein turnover dynamics. Experiments under metabolic but isotopically nonstationary conditions in continuous glucose-limited chemostats at high dilution rates demonstrated faster incorporation of isotope information from labeled glucose into the recombinant reporter protein than in biomass-bound protein. Our results suggest that the reporter protein was polymerized from intracellular amino acid pools with higher turnover rates than biomass-bound protein. The latter aspect might be vital for 13 C-flux analyses under isotopically nonstationary conditions for analyzing fast metabolic dynamics.

Published

2021

3. mfapy: An open-source Python package for 13 C-based metabolic flux analysis.

Author

Matsuda F, Maeda K, Taniguchi T, Kondo Y, Yatabe F, Okahashi N, and Shimizu H

Abstract

13 C-based metabolic flux analysis ( 13 C-MFA) is an essential tool for estimating intracellular metabolic flux levels in metabolic engineering and biology. In 13 C-MFA, a metabolic flux distribution that explains the observed isotope labeling data was computationally estimated using a non-linear optimization method. Herein, we report the development of mfapy, an open-source Python package developed for more flexibility and extensibility for 13 C-MFA. mfapy compels users to write a customized Python code by describing each step in the data analysis procedures of the isotope labeling experiments. The flexibility and extensibility provided by mfapy can support trial-and-error performance in the routine estimation of metabolic flux distributions, experimental design by computer simulations of 13 C-MFA experiments, and development of new data analysis techniques for stable isotope labeling experiments. mfapy is available to the public from the Github repository (https://github.com/fumiomatsuda/mfapy)., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2021 The Author(s).)

Published

2021

4. Gene Expression and Tracer-Based Metabolic Flux Analysis Reveals Tissue-Specific Metabolic Scaling in vitro, ex vivo, and in vivo

Author

Ngozi D. Akingbesote, Brooks P. Leitner, Daniel G. Jovin, Reina Desrouleaux, Wanling Zhu, Zongyu Li, Michael N. Pollak, and Rachel J. Perry

Abstract

Metabolic scaling, the inverse correlation of metabolic rates to body mass, has been appreciated for more than 80 years. Studies of metabolic scaling have almost exclusively been restricted to mathematical modeling of oxygen consumption. The possibility that other metabolic processes scale with body size has not been studied. To address this gap in knowledge, we employed a systems approach spanning from transcriptomics to in vitro and in vivo tracer-based flux. Gene expression in livers of five species spanning a 30,000-fold range in mass revealed differential expression of genes related to cytosolic and mitochondrial metabolic processes, in addition to detoxication of oxidative damage. This suggests that transcriptional scaling of damage control mechanisms accommodates increased oxidative metabolism in smaller species. To determine whether flux through key implicated metabolic pathways scaled, we applied stable isotope tracer methodology to study multiple cellular compartments, tissues, and species. Comparing mice and rats, we demonstrate that while scaling of metabolic fluxes is not observed in the cell-autonomous setting, it is present in liver slices and in vivo. Together, these data reveal that metabolic scaling extends beyond oxygen consumption to numerous other metabolic pathways, and is likely regulated at the level of gene expression and substrate supply.

Published

2022

5. The benefits of being transient: isotope-based metabolic flux analysis at the short time scale

Author

Nöh, Katharina and Wiechert, Wolfgang

Published

2011

6. Implementation of data-dependent isotopologue fragmentation in C-based metabolic flux analysis.

Author

Mairinger, Teresa and Hann, Stephan

Subjects

*CHROMATOGRAPHIC analysis, *FEASIBILITY studies, *REFERENCE sources, *METABOLISM, *NUCLEAR spectroscopy

Abstract

A novel analytical approach based on liquid chromatography coupled to quadrupole time of flight mass spectrometry, employing data-dependent triggering for analysis of isotopologue and tandem mass isotopomer fractions of metabolites of the primary carbon metabolism was developed. The implemented QTOFMS method employs automated MS/MS triggering of higher abundant, biologically relevant isotopologues for generating positional information of the respective metabolite. Using this advanced isotopologue selective fragmentation approach enables the generation of significant tandem mass isotopomer data within a short cycle time without compromising sensitivity. Due to a lack of suitable reference material certified for isotopologue ratios, a Pichia pastoris cell extract with a defined C distribution as well as a cell extract from a C-based metabolic flux experiment were employed for proof of concept. Moreover, a method inter-comparison with an already established GC-CI-(Q)TOFMS approach was conducted. Both methods showed good agreement on isotopologue and tandem mass isotopomer distributions for the two different cell extracts. [ABSTRACT FROM AUTHOR]

Published

2017

7. GC-QTOFMS with a low-energy electron ionization source for advancing isotopologue analysis in 13 C-based metabolic flux analysis.

Author

Mairinger T, Sanderson J, and Hann S

Abstract

For the study of different levels of (intra)cellular regulation and condition-dependent insight into metabolic activities, fluxomics experiments based on stable isotope tracer experiments using 13 C have become a well-established approach. The experimentally obtained non-naturally distributed 13 C labeling patterns of metabolite pools can be measured by mass spectrometric detection with front-end separation and can be consequently incorporated into biochemical network models. Here, despite a tedious derivatization step, gas chromatographic separation of polar metabolites is favorable because of the wide coverage range and high isomer separation efficiency. However, the typically employed electron ionization energy of 70 eV leads to significant fragmentation and consequently only low-abundant ions with an intact carbon backbone. Since these ions are considered a prerequisite for the analysis of the non-naturally distributed labeling patterns and further integration into modeling strategies, a softer ionization technique is needed. In the present work, a novel low energy electron ionization source is optimized for the analysis of primary metabolites and compared with a chemical ionization approach in terms of trueness, precision, and sensitivity.

Published

2019

8. Comprehensive assessment of measurement uncertainty in 13 C-based metabolic flux experiments.

Author

Mairinger T, Wegscheider W, Peña DA, Steiger MG, Koellensperger G, Zanghellini J, and Hann S

Subjects

Carbon Isotopes analysis, Carbon Isotopes metabolism, Computer Simulation, Metabolic Engineering, Metabolic Networks and Pathways, Metabolome, Metabolomics methods, Models, Biological, Monte Carlo Method, Pichia chemistry, Pichia cytology, Uncertainty, Metabolic Flux Analysis methods, Pichia metabolism

Abstract

In the field of metabolic engineering 13 C-based metabolic flux analysis experiments have proven successful in indicating points of action. As every step of this approach is affected by an inherent error, the aim of the present work is the comprehensive evaluation of factors contributing to the uncertainty of nonnaturally distributed C-isotopologue abundances as well as to the absolute flux value calculation. For this purpose, a previously published data set, analyzed in the course of a 13 C labeling experiment studying glycolysis and the pentose phosphate pathway in a yeast cell factory, was used. Here, for isotopologue pattern analysis of these highly polar metabolites that occur in multiple isomeric forms, a gas chromatographic separation approach with preceding derivatization was used. This rendered a natural isotope interference correction step essential. Uncertainty estimation of the resulting C-isotopologue distribution was performed according to the EURACHEM guidelines with Monte Carlo simulation. It revealed a significant increase for low-abundance isotopologue fractions after application of the necessary correction step. For absolute flux value estimation, isotopologue fractions of various sugar phosphates, together with the assessed uncertainties, were used in a metabolic model describing the upper part of the central carbon metabolism. The findings pinpointed the influence of small isotopologue fractions as sources of error and highlight the need for improved model curation. Graphical abstract ᅟ.

Published

2018

9. Markov Chain Monte Carlo Algorithm based metabolic flux distribution analysis on Corynebacterium glutamicum

Author

Kadirkamanathan, Visakan, Yang, Jing, Billings, Stephen A., and Wright, Phillip C.

Published

2006

10. Metabolic fluxes in recombinant Streptomyces lividans analyzed with 13 C-based metabolic flux analysis

Author

Jozef Anné, Kristel Bernaerts, Bart Nicolai, Wouter Daniels, and Jeroen Bouvin

Subjects

0301 basic medicine, chemistry.chemical_classification, Strain (chemistry), Heterologous, Cellulase, Biology, Pentose phosphate pathway, Redox, Amino acid, Citric acid cycle, 03 medical and health sciences, 030104 developmental biology, chemistry, Biochemistry, Control and Systems Engineering, Metabolic flux analysis, biology.protein

Abstract

Streptomyces lividans is an interesting host for the production of heterologous proteins. Expression of these foreign proteins often results in a metabolic burden leading to unsatisfactory yields. In this work, metabolic fluxes in Streptomyces lividans producing thermostable cellulase A are quantified. More insight in metabolic changes is acquired by estimating the fluxes in the central carbon metabolism by means of stationary 13C-based metabolic flux analysis. Labelling was measured in proteinogenic amino acids, which were obtained from batch experiments with an optimally chosen mixture of uniformly labelled glucose and position one labelled glucose. The cellulase A producing strain shows an increased secretion of organic acids, while growth is less efficient. Intracellularly, an increase through the pentose phosphate pathway and the citric acid cycle is observed, which alters the redox potential. Production of NADH and NADPH is higher in the CelA-producing strain, although the need is expected to be lower.

Published

2016

11. Efficient computational methods for sampling-based metabolic flux analysis

Author

Liphardt, Thomas, Stelling, Jörg, Sauer, Uwe, and Noeh, Katharina

Subjects

MCMC methods, Sampling methods, ddc:570, Isotopomer labeling experiments, MathematicsofComputing_NUMERICALANALYSIS, Metabolic Flux Analysis, Life sciences

Abstract

The aim of metabolic flux analysis is to determine the rates at which the processes in metabolism take place. Stationary isotopomer labeling experiments are the state-of-the-art method to generate data for metabolic flux analysis. The analysis of such experiments requires an atom transition model which is able to simulate the carbon atom transitions that take place in metabolism. The operational state of metabolism is represented by the rates at which the considered processes take place. We call this operational state the flux distribution, and it is a parameter of the atom transition model. By comparing the results of the model simulation against experimental data, we gain information about the flux distribution. To increase the identifiability of this inverse problem, we use constraint-based modeling, i.e. we restrict the flux distribution by applying linear constraints that can be derived directly from the stoichiometry of the considered processes. We took a probabilistic view on this inverse problem. We developed computational methods for the complete computational pipeline which is required to carry out metabolic flux analysis based on stationary isotopomer labeling experiments. First, we developed methods for the parametrization of the solution space that arises from constraint-based modeling. We then implemented the software necessary to simulate and evaluate data from labeling experiments. We next formulated the probabilistic framework which describes labeling experiments. The key to carrying out this probabilistic analysis was the development of efficient sampling methods that are able to sample from polytope-supported probability distributions in high dimensions. We first improved the efficiency of existing MCMC methods for sampling uniformly from convex polytopes. We then developed an efficient sampling procedure for the sampling of general convex polytopes-supported probability distribution based on nested sampling. We analyzed datasets from labeling experiments and compared different methods for the computation of confidence intervals for the estimated fluxes. We further generated synthetic data representing simulated labeling experiments, outlining new ways of experimental design.

Published

2018

12. Physiological characterization of recombinant Saccharomyces cerevisiae expressing the Aspergillus nidulans phosphoketolase pathway: validation of activity through C-based metabolic flux analysis.

Author

Papini, Marta, Nookaew, Intawat, Siewers, Verena, and Nielsen, Jens

Subjects

*SACCHAROMYCES cerevisiae, *ASPERGILLUS nidulans, *METABOLIC flux analysis, *GLYCOLYSIS, *ACETATES

Abstract

Several bacterial species and filamentous fungi utilize the phosphoketolase pathway (PHK) for glucose dissimilation as an alternative to the Embden-Meyerhof-Parnas pathway. In Aspergillus nidulans, the utilization of this metabolic pathway leads to increased carbon flow towards acetate and acetyl CoA. In the first step of the PHK, the pentose phosphate pathway intermediate xylulose-5-phosphate is converted into acetylphosphate and glyceraldehyde-3-phosphate through the action of xylulose-5-phosphate phosphoketolase, and successively acetylphosphate is converted into acetate by the action of acetate kinase. In the present work, we describe a metabolic engineering strategy used to express the fungal genes of the phosphoketolase pathway in Saccharomyces cerevisiae and the effects of the expression of this recombinant route in yeast. The phenotype of the engineered yeast strain MP003 was studied during batch and chemostat cultivations, showing a reduced biomass yield and an increased acetate yield during batch cultures. To establish whether the observed effects in the recombinant strain MP003 were due directly or indirectly to the expression of the phosphoketolase pathway, we resolved the intracellular flux distribution based on C labeling during chemostat cultivations. From flux analysis it is possible to conclude that yeast is able to use the recombinant pathway. Our work indicates that the utilization of the phosphoketolase pathway does not interfere with glucose assimilation through the Embden-Meyerhof-Parnas pathway and that the expression of this route can contribute to increase the acetyl CoA supply, therefore holding potential for future metabolic engineering strategies having acetyl CoA as precursor for the biosynthesis of industrially relevant compounds. [ABSTRACT FROM AUTHOR]

Published

2012

13. Metabolic fluxes in recombinant Streptomyces lividans analyzed with 13 C-based metabolic flux analysis

Author

Bouvin, Jeroen, primary, Daniels, Wouter, additional, Anné, Jozef, additional, Nicolaï, Bart, additional, and Bernaerts, Kristel, additional

Published

2016

14. Genome based metabolic flux analysis of ethanoligenens harbinense for enhanced hydrogen production

Author

Jean Franco Castro, Valeria Razmilic, and Ziomara P. Gerdtzen

Subjects

Metabolic state, Media optimization, Ethanoligenens harbinense, biology, Renewable Energy, Sustainability and the Environment, Chemistry, Energy Engineering and Power Technology, Condensed Matter Physics, biology.organism_classification, Genome, Metabolic engineering, Fuel Technology, Metabolic Model, Biochemistry, Metabolic flux analysis, Hydrogen production

Abstract

Ethanoligenens harbinense is a promising hydrogen producing microorganism due to its high inherent hydrogen production rate. Even though the effect of media optimization and inhibitory metabolites has been studied in order to improve the hydrogen productivity of these cultures, the identification of the underlying causes of the observed changes in productivity has not been targeted to date. In this work we present a genome based metabolic flux analysis (MFA) framework, for the comprehensive study of E. harbinense in culture, and the effect of inhibitory metabolites and media composition on its metabolic state. A metabolic model was constructed for E. harbinense based on its annotated genome sequence and proteomic evidence. This model was employed to perform MFA and obtain the intracellular flux distribution under different culture conditions. These results allow us to identify key elements in the metabolism that can be associated to the observed production phenotypes, and that can be potential targets for metabolic engineering in order to enhanced hydrogen production in E. harbinense.

Published

2013

15. Abstract 3372: Constraints-based metabolic flux analysis approach links tumor stage to metabolic adaptations and survival in cancer cells

Author

Achreja, Abhinav, primary, Yang, Lifeng, additional, Zhao, Hongyun, additional, Marini, Juan, additional, and Nagrath, Deepak, additional

Published

2014

16. On the Robustness of Elementary-Flux-Modes-based Metabolic Flux Analysis

Author

Oddsdóttir, Hildur Æsa, Hagrot, Erika, Chotteau, Veronique, Forsgren, Anders, Oddsdóttir, Hildur Æsa, Hagrot, Erika, Chotteau, Veronique, and Forsgren, Anders

Abstract

Elementary flux modes (EFMs) are vectors defined from a metabolic reaction network, giving the connections between substrates and products. EFMs-based metabolic flux analysis (MFA) estimates the flux over each EFM from external flux measurements through least-squares data fitting. The measurements used in the data fitting are subject to errors. A robust optimization problem includes information on errors and gives a way to examine the sensitivity of the solution of the EFMs-based MFA to these errors. In general, formulating a robust optimization problem may make the problem significantly harder. We show that in the case of the EFMs-based MFA the robust problem can be stated as a convex quadratic programming problem. We have previously shown how the data fitting problem may be solved in a column-generation framework. In this paper, we show how column generation may be applied also to the robust problem. Furthermore, the option to indicate intervals on metabolites that are not measured is introduced in this column generation framework. The robustness of the data is evaluated in a case-study, which indicated that the solutions of our non-robust problems are in fact near-optimal also when robustness is considered, implying that the errors in measurement do not have a large impact on the optimal solution. Furthermore, we showed that the addition of intervals on unmeasured metabolites resulted in a change in the optimal solution., QS 2015

17. A possibilistic framework for constraint-based metabolic flux analysis.

Author

Llaneras F, Sala A, and Picó J

Subjects

Corynebacterium glutamicum metabolism, Monte Carlo Method, Metabolomics methods

Abstract

Background: Constraint-based models allow the calculation of the metabolic flux states that can be exhibited by cells, standing out as a powerful analytical tool, but they do not determine which of these are likely to be existing under given circumstances. Typical methods to perform these predictions are (a) flux balance analysis, which is based on the assumption that cell behaviour is optimal, and (b) metabolic flux analysis, which combines the model with experimental measurements., Results: Herein we discuss a possibilistic framework to perform metabolic flux estimations using a constraint-based model and a set of measurements. The methodology is able to handle inconsistencies, by considering sensors errors and model imprecision, to provide rich and reliable flux estimations. The methodology can be cast as linear programming problems, able to handle thousands of variables with efficiency, so it is suitable to deal with large-scale networks. Moreover, the possibilistic estimation does not attempt necessarily to predict the actual fluxes with precision, but rather to exploit the available data--even if those are scarce--to distinguish possible from impossible flux states in a gradual way., Conclusion: We introduce a possibilistic framework for the estimation of metabolic fluxes, which is shown to be flexible, reliable, usable in scenarios lacking data and computationally efficient.

Published

2009

18. The benefits of being transient: isotope-based metabolic flux analysis at the short time scale

Author

Wolfgang Wiechert and Katharina Nöh

Subjects

Time Factors, Labeling time constants, Systems biology, Cells, Metabolic networks, metabolism [Bacteria], Biology, 01 natural sciences, Applied Microbiology and Biotechnology, Metabolic engineering, 03 medical and health sciences, ddc:570, chemistry [Bacteria], Metabolic flux analysis, Metabolome, methods [Isotope Labeling], Animals, Humans, chemistry [Fungi], Fluxomics, 030304 developmental biology, analysis [Carbon Isotopes], 0303 health sciences, Carbon Isotopes, Non-stationary C-13-metabolic flux analysis, Mathematical model, Bacteria, Scale (chemistry), 010401 analytical chemistry, Fungi, metabolism [Fungi], General Medicine, chemistry [Cells], 0104 chemical sciences, Biochemistry, Isotope Labeling, metabolism [Cells], Transient isotope-labeling experiments, Transient (oscillation), Biological system, metabolism [Carbon Isotopes], Biotechnology

Abstract

Metabolic fluxes are the manifestations of the co-operating actions in a complex network of genes, transcripts, proteins, and metabolites. As a final quantitative endpoint of all cellular interactions, the intracellular fluxes are of immense interest in fundamental as well as applied research. Unlike the quantities of interest in most omics levels, in vivo fluxes are, however, not directly measureable. In the last decade, ¹³C-based metabolic flux analysis emerged as the state-of-the-art technique to infer steady-state fluxes by data from labeling experiments and the use of mathematical models. A very promising new area in systems metabolic engineering research is non-stationary ¹³C-metabolic flux analysis at metabolic steady-state conditions. Several studies have demonstrated an information surplus contained in transient labeling data compared to those taken at the isotopic equilibrium, as it is classically done. Enabled by recent, fairly multi-disciplinary progress, the new method opens several attractive options to (1) generate new insights, e.g., in cellular storage metabolism or the dilution of tracer by endogenous pools and (2) shift limits, inherent in the classical approach, towards enhanced applicability with respect to cultivation conditions and biological systems. We review the new developments in metabolome-based non-stationary ¹³C flux analysis and outline future prospects for accurate in vivo flux measurement.

Published

2011

19. A possibilistic framework for constraint-based metabolic flux analysis

Author

Jesús Picó, Francisco Llaneras, and Antonio Sala

Subjects

Mathematical optimization, Computer science, Systems biology, Methodology Article, Applied Mathematics, MathematicsofComputing_NUMERICALANALYSIS, Metabolic network, Cell behaviour, Computer Science Applications, Slack variable, Flux balance analysis, Constraint (information theory), Corynebacterium glutamicum, lcsh:Biology (General), Structural Biology, Modeling and Simulation, Metabolic flux analysis, Modelling and Simulation, Applied mathematics, Metabolomics, Flux (metabolism), Monte Carlo Method, Molecular Biology, lcsh:QH301-705.5

Abstract

Background Constraint-based models allow the calculation of the metabolic flux states that can be exhibited by cells, standing out as a powerful analytical tool, but they do not determine which of these are likely to be existing under given circumstances. Typical methods to perform these predictions are (a) flux balance analysis, which is based on the assumption that cell behaviour is optimal, and (b) metabolic flux analysis, which combines the model with experimental measurements. Results Herein we discuss a possibilistic framework to perform metabolic flux estimations using a constraint-based model and a set of measurements. The methodology is able to handle inconsistencies, by considering sensors errors and model imprecision, to provide rich and reliable flux estimations. The methodology can be cast as linear programming problems, able to handle thousands of variables with efficiency, so it is suitable to deal with large-scale networks. Moreover, the possibilistic estimation does not attempt necessarily to predict the actual fluxes with precision, but rather to exploit the available data – even if those are scarce – to distinguish possible from impossible flux states in a gradual way. Conclusion We introduce a possibilistic framework for the estimation of metabolic fluxes, which is shown to be flexible, reliable, usable in scenarios lacking data and computationally efficient.

Published

2009

20. Markov Chain Monte Carlo Algorithm based metabolic flux distribution analysis on Corynebacterium glutamicum

Author

Jing Yang, Phillip C. Wright, Visakan Kadirkamanathan, and Stephen A. Billings

Subjects

Statistics and Probability, Mathematical optimization, Computer science, Metabolic Clearance Rate, Gaussian, Monte Carlo method, Biochemistry, Models, Biological, Hybrid Monte Carlo, symbols.namesake, Bacterial Proteins, Computer Simulation, Statistical physics, Kinetic Monte Carlo, Molecular Biology, Models, Statistical, Gene Expression Profiling, Markov chain Monte Carlo, Markov Chains, Computer Science Applications, Corynebacterium glutamicum, Computational Mathematics, Computational Theory and Mathematics, Gaussian noise, Dynamic Monte Carlo method, symbols, Monte Carlo method in statistical physics, Energy Metabolism, Algorithms, Monte Carlo molecular modeling, Signal Transduction

Abstract

Motivation: Metabolic flux analysis via a 13C tracer experiment has been achieved using a Monte Carlo method with the assumption of system noise as Gaussian noise. However, an unbiased flux analysis requires the estimation of fluxes and metabolites jointly without the restriction on the assumption of Gaussian noise. The flux distributions under such a framework can be freely obtained with various system noise and uncertainty models. Results: In this paper, a stochastic generative model of the metabolic system is developed. Following this, the Markov Chain Monte Carlo (MCMC) approach is applied to flux distribution analysis. The disturbances and uncertainties in the system are simplified as truncated Gaussian multiplicative models. The performance in a real metabolic system is illustrated by the application to the central metabolism of Corynebacterium glutamicum. The flux distributions are illustrated and analyzed in order to understand the underlying flux activities in the system. Availability: Algorithms are available upon request. Contact: visakan@sheffield.ac.uk

Published

2006

21. A possibilistic framework for constraint-based metabolic flux analysis.

Published

2009

22. Abstract 3372: Constraints-based metabolic flux analysis approach links tumor stage to metabolic adaptations and survival in cancer cells

Author

Abhinav Achreja, Hongyun Zhao, Deepak Nagrath, Juan C. Marini, and Lifeng Yang

Subjects

Cancer Research, Anabolism, Catabolism, Cancer, Computational biology, Biology, medicine.disease, Bioinformatics, Warburg effect, Glutamine, Metabolic pathway, Oncology, Metabolic flux analysis, Cancer cell, medicine

Abstract

The Warburg effect has been observed in many cancers and their high glycolytic capacity has signified their dependence on glucose. More recently, glutamine has emerged not only as an important nutrient for many cancers, but also necessary for their elevated energetic requirements. Due to these high energetic demands, certain cancer cells become addicted to glutamine to maintain viability. We postulate that distinct metabolic reconfigurations of certain cancers define their dependence or independence on glutamine for survival while maintaining their proliferative propensity and redox status. An intricate picture of the metabolic profiles is to be drawn from estimating intracellular fluxes, by combining stable isotope tracer measurements and experimental metabolomics data from different cancer cell lines, which have been observed to be glutamine dependent and independent. To this extent, we describe an approach that utilizes a redox-balanced model incorporating the electron transport chain and comprehensive amino-acid metabolic reactions to elucidate the importance of oxidative phosphorylation, often overlooked in classical approaches. Diving deeper into the foray of metabolic reprogramming, we perform in silico experiments using a constraint-based multi-objective modeling approach. This methodology elucidates the switching of metabolic pathways in glutamine-dependent and -independent cancers under nutrient-available and nutrient-deprived conditions. Our approach assumes that cancer cells operate at optimal levels, maintaining multiple objectives under certain environmental conditions. Constraining the proliferative phenotype from a maximal to minimal levels of the cells under different nutrient conditions emulates the observed behavior of glutamine-dependent cells under deprivation conditions and contrasts their metabolic reprogramming against that of glutamine-independent cells. We corroborated our simulations with experimentally derived metabolic fluxes and found that glutamine anabolism over catabolism dictates adaptations and survival in invasive cancers. Our results will lead to identification of potential targets for inducing nutrient-sensitivity and enhance current therapeutic approaches. Citation Format: Abhinav Achreja, Lifeng Yang, Hongyun Zhao, Juan Marini, Deepak Nagrath. Constraints-based metabolic flux analysis approach links tumor stage to metabolic adaptations and survival in cancer cells. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr 3372. doi:10.1158/1538-7445.AM2014-3372

Published

2014

23. Transcriptomic and fluxomic changes in Streptomyces lividans producing heterologous protein

Author

Wouter Daniels, Jeroen Bouvin, Tobias Busche, Christian Rückert, Kenneth Simoens, Spyridoula Karamanou, Lieve Van Mellaert, Ólafur H. Friðjónsson, Bart Nicolai, Anastassios Economou, Jörn Kalinowski, Jozef Anné, and Kristel Bernaerts

Subjects

Streptomyces lividans, Heterologous protein production and secretion, $$^{13}\hbox {C}$$ 13 C -based metabolic flux, RNA-seq analysis, Gene clustering analysis, Microbiology, QR1-502

Abstract

Abstract Background The Gram-positive Streptomyces lividans TK24 is an attractive host for heterologous protein production because of its high capability to secrete proteins—which favors correct folding and facilitates downstream processing—as well as its acceptance of methylated DNA and its low endogeneous protease activity. However, current inconsistencies in protein yields urge for a deeper understanding of the burden of heterologous protein production on the cell. In the current study, transcriptomics and $$^{13}\hbox {C}$$ 13C -based fluxomics were exploited to uncover gene expression and metabolic flux changes associated with heterologous protein production. The Rhodothermus marinus thermostable cellulase A (CelA)—previously shown to be successfully overexpressed in S. lividans—was taken as an example protein. Results RNA-seq and $$^{13}\hbox {C}$$ 13C -based metabolic flux analysis were performed on a CelA-producing and an empty-plasmid strain under the same conditions. Differential gene expression, followed by cluster analysis based on co-expression and co-localization, identified transcriptomic responses related to secretion-induced stress and DNA damage. Furthermore, the OsdR regulon (previously associated with hypoxia, oxidative stress, intercellular signaling, and morphological development) was consistently upregulated in the CelA-producing strain and exhibited co-expression with isoenzymes from the pentose phosphate pathway linked to secondary metabolism. Increased expression of these isoenzymes matches to increased fluxes in the pentose phosphate pathway. Additionally, flux maps of the central carbon metabolism show increased flux through the tricarboxylic acid cycle in the CelA-producing strain. Redirection of fluxes in the CelA-producing strain leads to higher production of NADPH, which can only partly be attributed to increased secretion. Conclusions Transcriptomic and fluxomic changes uncover potential new leads for targeted strain improvement strategies which may ease the secretion stress and metabolic burden associated with heterologous protein synthesis and secretion, and may help create a more consistently performing S. lividans strain. Yet, links to secondary metabolism and redox balancing should be further investigated to fully understand the S. lividans metabolome under heterologous protein production.

Published

2018

24. Anaplerotic Pathways in Halomonas elongata: The Role of the Sodium Gradient

Author

Karina Hobmeier, Marie C. Goëss, Christiana Sehr, Sebastian Schwaminger, Sonja Berensmeier, Andreas Kremling, Hans Jörg Kunte, Katharina Pflüger-Grau, and Alberto Marin-Sanguino

Subjects

thermodynamics-based metabolic flux analysis, halophilic bacteria, metabolic modeling, design principles, biochemistry and metabolism, Halomonas elongata, Microbiology, QR1-502

Abstract

Salt tolerance in the γ-proteobacterium Halomonas elongata is linked to its ability to produce the compatible solute ectoine. The metabolism of ectoine production is of great interest since it can shed light on the biochemical basis of halotolerance as well as pave the way for the improvement of the biotechnological production of such compatible solute. Ectoine belongs to the biosynthetic family of aspartate-derived amino-acids. Aspartate is formed from oxaloacetate, thereby connecting ectoine production to the anaplerotic reactions that refill carbon into the tricarboxylic acid cycle (TCA cycle). This places a high demand on these reactions and creates the need to regulate them not only in response to growth but also in response to extracellular salt concentration. In this work, we combine modeling and experiments to analyze how these different needs shape the anaplerotic reactions in H. elongata. First, the stoichiometric and thermodynamic factors that condition the flux distributions are analyzed, then the optimal patterns of operation for oxaloacetate production are calculated. Finally, the phenotype of two deletion mutants lacking potentially relevant anaplerotic enzymes: phosphoenolpyruvate carboxylase (Ppc) and oxaloacetate decarboxylase (Oad) are experimentally characterized. The results show that the anaplerotic reactions in H. elongata are indeed subject to evolutionary pressures that differ from those faced by other gram-negative bacteria. Ectoine producing halophiles must meet a higher metabolic demand for oxaloacetate and the reliance of many marine bacteria on the Entner-Doudoroff pathway compromises the anaplerotic efficiency of Ppc, which is usually one of the main enzymes fulfilling this role. The anaplerotic flux in H. elongata is contributed not only by Ppc but also by Oad, an enzyme that has not yet been shown to play this role in vivo. Ppc is necessary for H. elongata to grow normally at low salt concentrations but it is not required to achieve near maximal growth rates as long as there is a steep sodium gradient. On the other hand, the lack of Oad presents serious difficulties to grow at high salt concentrations. This points to a shared role of these two enzymes in guaranteeing the supply of oxaloacetate for biosynthetic reactions.

Published

2020

25. Thermodynamics-Based Metabolic Flux Analysis

Author

Vassily Hatzimanikatis, Linda J. Broadbelt, and Christopher S. Henry

Subjects

Ion Transport, Metabolite, Osmolar Concentration, Biophysics, Thermodynamics, Metabolism, Bioenergetics, Biology, Models, Biological, Gibbs free energy, chemistry.chemical_compound, symbols.namesake, Glucose, Metabolic Model, chemistry, Metabolic flux analysis, Escherichia coli, symbols, NAD+ kinase, Optimal growth, Genome, Bacterial, Metabolic Networks and Pathways, Ion transporter

Abstract

A new form of metabolic flux analysis (MFA) called thermodynamics-based metabolic flux analysis (TMFA) is introduced with the capability of generating thermodynamically feasible flux and metabolite activity profiles on a genome scale. TMFA involves the use of a set of linear thermodynamic constraints in addition to the mass balance constraints typically used in MFA. TMFA produces flux distributions that do not contain any thermodynamically infeasible reactions or pathways, and it provides information about the free energy change of reactions and the range of metabolite activities in addition to reaction fluxes. TMFA is applied to study the thermodynamically feasible ranges for the fluxes and the Gibbs free energy change, ΔrG′, of the reactions and the activities of the metabolites in the genome-scale metabolic model of Escherichia coli developed by Palsson and co-workers. In the TMFA of the genome scale model, the metabolite activities and reaction ΔrG′ are able to achieve a wide range of values at optimal growth. The reaction dihydroorotase is identified as a possible thermodynamic bottleneck in E. coli metabolism with a ΔrG′ constrained close to zero while numerous reactions are identified throughout metabolism for which ΔrG′ is always highly negative regardless of metabolite concentrations. As it has been proposed previously, these reactions with exclusively negative ΔrG′ might be candidates for cell regulation, and we find that a significant number of these reactions appear to be the first steps in the linear portion of numerous biosynthesis pathways. The thermodynamically feasible ranges for the concentration ratios ATP/ADP, NAD(P)/NAD(P)H, and \documentclass[10pt]{article} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{pmc} \pagestyle{empty} \oddsidemargin -1.0in \begin{document} \begin{equation*}{\mathrm{H}}_{{\mathrm{extracellular}}}^{+}/{\mathrm{H}}_{{\mathrm{intracellular}}}^{+}\end{equation*}\end{document} are also determined and found to encompass the values observed experimentally in every case. Further, we find that the NAD/NADH and NADP/NADPH ratios maintained in the cell are close to the minimum feasible ratio and maximum feasible ratio, respectively.

26. Markov Chain Monte Carlo Algorithm based metabolic flux distribution analysis on Corynebacterium glutamicum.

Author

Visakan Kadirkamanathan, Jing Yang, Stephen A. Billings, and Phillip C. Wright

Published

2006

27. Anaplerotic Pathways in

Author

Karina, Hobmeier, Marie C, Goëss, Christiana, Sehr, Sebastian, Schwaminger, Sonja, Berensmeier, Andreas, Kremling, Hans Jörg, Kunte, Katharina, Pflüger-Grau, and Alberto, Marin-Sanguino

Subjects

design principles, biochemistry and metabolism, metabolic modeling, Halomonas elongata, halophilic bacteria, Microbiology, thermodynamics-based metabolic flux analysis, Original Research

Abstract

Salt tolerance in the γ-proteobacterium Halomonas elongata is linked to its ability to produce the compatible solute ectoine. The metabolism of ectoine production is of great interest since it can shed light on the biochemical basis of halotolerance as well as pave the way for the improvement of the biotechnological production of such compatible solute. Ectoine belongs to the biosynthetic family of aspartate-derived amino-acids. Aspartate is formed from oxaloacetate, thereby connecting ectoine production to the anaplerotic reactions that refill carbon into the tricarboxylic acid cycle (TCA cycle). This places a high demand on these reactions and creates the need to regulate them not only in response to growth but also in response to extracellular salt concentration. In this work, we combine modeling and experiments to analyze how these different needs shape the anaplerotic reactions in H. elongata. First, the stoichiometric and thermodynamic factors that condition the flux distributions are analyzed, then the optimal patterns of operation for oxaloacetate production are calculated. Finally, the phenotype of two deletion mutants lacking potentially relevant anaplerotic enzymes: phosphoenolpyruvate carboxylase (Ppc) and oxaloacetate decarboxylase (Oad) are experimentally characterized. The results show that the anaplerotic reactions in H. elongata are indeed subject to evolutionary pressures that differ from those faced by other gram-negative bacteria. Ectoine producing halophiles must meet a higher metabolic demand for oxaloacetate and the reliance of many marine bacteria on the Entner-Doudoroff pathway compromises the anaplerotic efficiency of Ppc, which is usually one of the main enzymes fulfilling this role. The anaplerotic flux in H. elongata is contributed not only by Ppc but also by Oad, an enzyme that has not yet been shown to play this role in vivo. Ppc is necessary for H. elongata to grow normally at low salt concentrations but it is not required to achieve near maximal growth rates as long as there is a steep sodium gradient. On the other hand, the lack of Oad presents serious difficulties to grow at high salt concentrations. This points to a shared role of these two enzymes in guaranteeing the supply of oxaloacetate for biosynthetic reactions.

Published

2020

28. Transcriptomic and fluxomic changes in Streptomyces lividans producing heterologous protein

Author

Spyridoula Karamanou, Wouter Daniels, Jozef Anné, Jörn Kalinowski, Jeroen Bouvin, Ólafur H. Friðjónsson, Kenneth Simoens, Tobias Busche, Bart Nicolai, Lieve Van Mellaert, Christian Rückert, Kristel Bernaerts, and Anastassios Economou

Subjects

0301 basic medicine, 030106 microbiology, based metabolic flux, lcsh:QR1-502, Heterologous, Bioengineering, Heterologous protein production and secretion, Pentose phosphate pathway, Applied Microbiology and Biotechnology, lcsh:Microbiology, 03 medical and health sciences, \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$^{13}\hbox {C}$$\end{document}13C-based metabolic flux, Metabolic flux analysis, Protein biosynthesis, Secondary metabolism, Fluxomics, 2. Zero hunger, Chemistry, Research, Gene clustering analysis, Cell biology, Citric acid cycle, 030104 developmental biology, Regulon, Multigene Family, Protein Biosynthesis, Streptomyces lividans, $$^{13}\hbox {C}$$ 13 C -based metabolic flux, Transcriptome, RNA-seq analysis, Biotechnology

Abstract

Background The Gram-positive Streptomyces lividans TK24 is an attractive host for heterologous protein production because of its high capability to secrete proteins—which favors correct folding and facilitates downstream processing—as well as its acceptance of methylated DNA and its low endogeneous protease activity. However, current inconsistencies in protein yields urge for a deeper understanding of the burden of heterologous protein production on the cell. In the current study, transcriptomics and \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$^{13}\hbox {C}$$\end{document}13C-based fluxomics were exploited to uncover gene expression and metabolic flux changes associated with heterologous protein production. The Rhodothermus marinus thermostable cellulase A (CelA)—previously shown to be successfully overexpressed in S. lividans—was taken as an example protein. Results RNA-seq and \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$^{13}\hbox {C}$$\end{document}13C-based metabolic flux analysis were performed on a CelA-producing and an empty-plasmid strain under the same conditions. Differential gene expression, followed by cluster analysis based on co-expression and co-localization, identified transcriptomic responses related to secretion-induced stress and DNA damage. Furthermore, the OsdR regulon (previously associated with hypoxia, oxidative stress, intercellular signaling, and morphological development) was consistently upregulated in the CelA-producing strain and exhibited co-expression with isoenzymes from the pentose phosphate pathway linked to secondary metabolism. Increased expression of these isoenzymes matches to increased fluxes in the pentose phosphate pathway. Additionally, flux maps of the central carbon metabolism show increased flux through the tricarboxylic acid cycle in the CelA-producing strain. Redirection of fluxes in the CelA-producing strain leads to higher production of NADPH, which can only partly be attributed to increased secretion. Conclusions Transcriptomic and fluxomic changes uncover potential new leads for targeted strain improvement strategies which may ease the secretion stress and metabolic burden associated with heterologous protein synthesis and secretion, and may help create a more consistently performing S. lividans strain. Yet, links to secondary metabolism and redox balancing should be further investigated to fully understand the S. lividans metabolome under heterologous protein production. Electronic supplementary material The online version of this article (10.1186/s12934-018-1040-6) contains supplementary material, which is available to authorized users.

Published

2018

29. Constructing efficient bacterial cell factories to enable one-carbon utilization based on quantitative biology: A review.

Author

Song, Yazhen, Feng, Chenxi, Zhou, Difei, Ma, Zengxin, He, Lian, Zhang, Cong, Yu, Guihong, Zhao, Yan, Yang, Song, and Xing, Xinhui

Subjects

BACTERIAL cells, METHYLOTROPHIC bacteria, CARBON dioxide mitigation, ELECTROCATALYSIS, METABOLISM

Abstract

Developing methylotrophic cell factories that can efficiently catalyze organic one-carbon (C1) feedstocks derived from electrocatalytic reduction of carbon dioxide into bio-based chemicals and biofuels is of strategic significance for building a carbon-neutral, sustainable economic and industrial system. With the rapid advancement of RNA sequencing technology and mass spectrometer analysis, researchers have used these quantitative microbiology methods extensively, especially isotope-based metabolic flux analysis, to study the metabolic processes initiating from C1 feedstocks in natural C1-utilizing bacteria and synthetic C1 bacteria. This paper reviews the use of advanced quantitative analysis in recent years to understand the metabolic network and basic principles in the metabolism of natural C1-utilizing bacteria grown on methane, methanol, or formate. The acquired knowledge serves as a guide to rewire the central methylotrophic metabolism of natural C1-utilizing bacteria to improve the carbon conversion efficiency, and to engineer non-C1-utilizing bacteria into synthetic strains that can use C1 feedstocks as the sole carbon and energy source. These progresses ultimately enhance the design and construction of highly efficient C1-based cell factories to synthesize diverse high value-added products. The integration of quantitative biology and synthetic biology will advance the iterative cycle of understand--design--build--testing--learning to enhance C1-based biomanufacturing in the future. [ABSTRACT FROM AUTHOR]

Published

2024

30. Isotope tracing reveals distinct substrate preference in murine melanoma subtypes with differing anti-tumor immunity.

Author

Zhang, Xinyi, Halberstam, Alexandra A., Zhu, Wanling, Leitner, Brooks P., Thakral, Durga, Bosenberg, Marcus W., and Perry, Rachel J.

Abstract

Background: Research about tumor “metabolic flexibility”—the ability of cells to toggle between preferred nutrients depending on the metabolic context—has largely focused on obesity-associated cancers. However, increasing evidence for a key role for nutrient competition in the tumor microenvironment, as well as for substrate regulation of immune function, suggests that substrate metabolism deserves reconsideration in immunogenic tumors that are not strongly associated with obesity. Methods: We compare two murine models: immunologically cold YUMM1.7 and immunologically-hot YUMMER1.7. We utilize stable isotope and radioisotope tracer-based metabolic flux studies as well as gas and liquid chromatography-based metabolomics analyses to comprehensively probe substrate preference in YUMM1.7 and YUMMER1.7 cells, with a subset of studies on the impact of available metabolites across a panel of five additional melanoma cell lines. We analyze bulk RNA-seq data and identify increased expression of amino acid and glucose metabolism genes in YUMMER1.7. Finally, we analyze melanoma patient RNA-seq data to identify potential prognostic predictors rooted in metabolism. Results: We demonstrate using stable isotope tracer-based metabolic flux studies as well as gas and liquid chromatography-based metabolomics that immunologically-hot melanoma utilizes more glutamine than immunologically-cold melanoma in vivo and in vitro. Analyses of human melanoma RNA-seq data demonstrate that glutamine transporter and other anaplerotic gene expression positively correlates with lymphocyte infiltration and function. Conclusions: Here, we highlight the importance of understanding metabolism in non-obesity-associated cancers, such as melanoma. This work advances the understanding of the correlation between metabolism and immunogenicity in the tumor microenvironment and provides evidence supporting metabolic gene expression as potential prognostic factors of melanoma progression and may inform investigations of adjunctive metabolic therapy in melanoma. Trial registration: Deidentified data from The Cancer Genome Atlas were analyzed. [ABSTRACT FROM AUTHOR]

Published

2022

31. 13C-based metabolic flux analysis of Saccharomyces cerevisiae with a reduced Crabtree effect.

Author

Kajihata, Shuichi, Matsuda, Fumio, Yoshimi, Mika, Hayakawa, Kenshi, Furusawa, Chikara, Kanda, Akihisa, and Shimizu, Hiroshi

Subjects

*METABOLIC flux analysis, *SACCHAROMYCES cerevisiae, *CRABAPPLES, *BIOMASS, *NICOTINAMIDE adenine dinucleotide phosphate

Abstract

Saccharomyces cerevisiae shows a Crabtree effect that produces ethanol in a high glucose concentration even under fully aerobic condition. For efficient production of cake yeast or compressed yeast for baking, ethanol by-production is not desired since glucose limited chemostat or fed-batch cultivations are performed to suppress the Crabtree effect. In this study, the 13 C-based metabolic flux analysis ( 13 C-MFA) was performed for the S288C derived S. cerevisiae strain to characterize a metabolic state under the reduced Crabtree effect. S. cerevisiae cells were cultured at a low dilution rate (0.1 h −1 ) under the glucose-limited chemostat condition. The estimated metabolic flux distribution showed that the acetyl-CoA in mitochondria was mainly produced from pyruvate by pyruvate dehydrogenase (PDH) reaction and that the level of the metabolic flux through the pentose phosphate pathway was much higher than that of the Embden–Meyerhof–Parnas pathway, which contributes to high biomass yield at low dilution rate by supplying NADPH required for cell growth. [ABSTRACT FROM AUTHOR]

Published

2015

32. Global 13C tracing and metabolic flux analysis of intact human liver tissue ex vivo

Author

Grankvist, Nina, Jönsson, Cecilia, Hedin, Karin, Sundqvist, Nicolas, Sandström, Per, Björnsson, Bergthor, Begzati, Arjana, Mickols, Evgeniya, Artursson, Per, Jain, Mohit, Cedersund, Gunnar, Nilsson, Roland, Grankvist, Nina, Jönsson, Cecilia, Hedin, Karin, Sundqvist, Nicolas, Sandström, Per, Björnsson, Bergthor, Begzati, Arjana, Mickols, Evgeniya, Artursson, Per, Jain, Mohit, Cedersund, Gunnar, and Nilsson, Roland

Abstract

Liver metabolism is central to human physiology and influences the pathogenesis of common metabolic diseases. Yet, our understanding of human liver metabolism remains incomplete, with much of current knowledge based on animal or cell culture models that do not fully recapitulate human physiology. Here, we perform in-depth measurement of metabolism in intact human liver tissue ex vivo using global 13C tracing, non-targeted mass spectrometry and model-based metabolic flux analysis. Isotope tracing allowed qualitative assessment of a wide range of metabolic pathways within a single experiment, confirming well-known features of liver metabolism but also revealing unexpected metabolic activities such as de novo creatine synthesis and branched-chain amino acid transamination, where human liver appears to differ from rodent models. Glucose production ex vivo correlated with donor plasma glucose, suggesting that cultured liver tissue retains individual metabolic phenotypes, and could be suppressed by postprandial levels of nutrients and insulin, and also by pharmacological inhibition of glycogen utilization. Isotope tracing ex vivo allows measuring human liver metabolism with great depth and resolution in an experimentally tractable system.

Published

2024

33. Selecting a preculture strategy for improving biomass and astaxanthin productivity of Chromochloris zofingiensis.

Author

Wang, Yuxin, Wang, Jia, Yang, Shufang, Liang, Qingping, Gu, Ziqiang, Wang, Ying, Mou, Haijin, and Sun, Han

Subjects

*ASTAXANTHIN, *METABOLIC flux analysis, *BIOMASS, *UNSATURATED fatty acids, *LIPID synthesis, *GLUCOSE metabolism

Abstract

Chromochloris zofingiensis is a potential source of natural astaxanthin; however, its rapid growth and astaxanthin enrichment cannot be achieved simultaneously. This study established autotrophic, mixotrophic, and heterotrophic preculture patterns to assess their ameliorative effect on the C. zofingiensis heterotrophic growth state. In comparison, mixotrophic preculture (MP) exhibited the best improving effect on heterotrophic biomass concentration of C. zofingiensis (up to 121.5 g L−1) in a 20 L fermenter, reaching the global leading level. The astaxanthin productivity achieved 111 mg L−1 day−1, 7.4-fold higher than the best record. The transcriptome and 13C tracer-based metabolic flux analysis were used for mechanism inquiry. The results revealed that MP promoted carotenoid and lipid synthesis, and supported synthesis preference of low unsaturated fatty acids represented by C18:1 and C16:0. The MP group maintained the best astaxanthin productivity via mastering the balance between increasing glucose metabolism and inhibition of carotenoid synthesis. The MP strategy optimized the physiological state of C. zofingiensis and realized its heterotrophic high-density growth for an excellent astaxanthin yield on a pilot scale. This strategy exhibits great application potential in the microalgae-related industry. Key points: • Preculture strategies changed carbon flux and gene expression in C. zofingiensis • C. zofingiensis realized a high-density culture with MP and fed-batch culture (FBC) • Astaxanthin productivity achieved 0.111 g L−1day−1with MP and FBC [ABSTRACT FROM AUTHOR]

Published

2024

34. Linear programming based gene expression model (LPM-GEM) predicts the carbon source for Bacillus subtilis.

Author

Thanamit, Kulwadee, Hoerhold, Franziska, Oswald, Marcus, and Koenig, Rainer

Subjects

LINEAR programming, BACILLUS subtilis, GENE expression, CARBON, GENETIC code

Abstract

Background: Elucidating cellular metabolism led to many breakthroughs in biotechnology, synthetic biology, and health sciences. To date, deriving metabolic fluxes by 13C tracer experiments is the most prominent approach for studying metabolic fluxes quantitatively, often with high accuracy and precision. However, the technique has a high demand for experimental resources. Alternatively, flux balance analysis (FBA) has been employed to estimate metabolic fluxes without labeling experiments. It is less informative but can benefit from the low costs and low experimental efforts and gain flux estimates in experimentally difficult conditions. Methods to integrate relevant experimental data have been emerged to improve FBA flux estimations. Data from transcription profiling is often selected since it is easy to generate at the genome scale, typically embedded by a discretization of differential and non-differential expressed genes coding for the respective enzymes. Result: We established the novel method Linear Programming based Gene Expression Model (LPM-GEM). LPM-GEM linearly embeds gene expression into FBA constraints. We implemented three strategies to reduce thermodynamically infeasible loops, which is a necessary prerequisite for such an omics-based model building. As a case study, we built a model of B. subtilis grown in eight different carbon sources. We obtained good flux predictions based on the respective transcription profiles when validating with 13C tracer based metabolic flux data of the same conditions. We could well predict the specific carbon sources. When testing the model on another, unseen dataset that was not used during training, good prediction performance was also observed. Furthermore, LPM-GEM outperformed a well-established model building methods. Conclusion: Employing LPM-GEM integrates gene expression data efficiently. The method supports gene expression-based FBA models and can be applied as an alternative to estimate metabolic fluxes when tracer experiments are inappropriate. [ABSTRACT FROM AUTHOR]

Published

2022

35. Validation-based model selection for 13C metabolic flux analysis with uncertain measurement errors.

Author

Sundqvist, Nicolas, Grankvist, Nina, Watrous, Jeramie, Mohit, Jain, Nilsson, Roland, and Cedersund, Gunnar

Subjects

METABOLIC flux analysis, PYRUVATE carboxylase, MEASUREMENT errors, CELL metabolism, METABOLIC models, MASS spectrometry, MATHEMATICAL models

Abstract

Accurate measurements of metabolic fluxes in living cells are central to metabolism research and metabolic engineering. The gold standard method is model-based metabolic flux analysis (MFA), where fluxes are estimated indirectly from mass isotopomer data with the use of a mathematical model of the metabolic network. A critical step in MFA is model selection: choosing what compartments, metabolites, and reactions to include in the metabolic network model. Model selection is often done informally during the modelling process, based on the same data that is used for model fitting (estimation data). This can lead to either overly complex models (overfitting) or too simple ones (underfitting), in both cases resulting in poor flux estimates. Here, we propose a method for model selection based on independent validation data. We demonstrate in simulation studies that this method consistently chooses the correct model in a way that is independent on errors in measurement uncertainty. This independence is beneficial, since estimating the true magnitude of these errors can be difficult. In contrast, commonly used model selection methods based on the χ2-test choose different model structures depending on the believed measurement uncertainty; this can lead to errors in flux estimates, especially when the magnitude of the error is substantially off. We present a new approach for quantification of prediction uncertainty of mass isotopomer distributions in other labelling experiments, to check for problems with too much or too little novelty in the validation data. Finally, in an isotope tracing study on human mammary epithelial cells, the validation-based model selection method identified pyruvate carboxylase as a key model component. Our results argue that validation-based model selection should be an integral part of MFA model development. Author summary: Measuring metabolic reaction fluxes in living cells is difficult, yet important. The gold standard is to label extracellular metabolites with 13C, to use mass spectrometry to find out where the 13C-atoms ends up, and finally use mathematical modelling to calculate how quickly each reaction must have flowed, for the 13C-atoms to end up like that. This measurement thus relies on usage of the right mathematical model, which must be selected among various candidate models. In this manuscript, we present a new way to do this model selection step, utilizing validation data. Using an adopted approach to calculate the uncertainty of model predictions, we identify new validation experiments, which are neither too similar, nor too dissimilar, compared to the previous training data. The model candidate that is best at predicting this new validation data is the one chosen. Tests on simulated data where the true model is known, shows that the validation-based method is robust when the magnitude of the error in the measurement uncertainty is unknown, something that conventional methods are not. This improvement is important since true uncertainties can be difficult to estimate for these data. Finally, we demonstrate how the new method can be used on real data, to identify fluxes and important reactions. [ABSTRACT FROM AUTHOR]

Published

2022

36. Issue Information

Abstract

Methylotrophic cell factories are capable of effectively catalyzing organic single‐carbon (C1) feedstocks derived from the electrocatalytic reduction of carbon dioxide into bio‐based chemicals and biofuels. This process holds great promise for establishing a carbon‐neutral, sustainable economic and industrial system. The rapid advancement of quantitative multi‐omics methods, especially isotope‐based metabolic flux analysis, has facilitated a better understanding of the metabolic networks and fundamental principles involved in the metabolism of C1‐utilizing bacteria. Song et al. review recent advances in the quantitative understanding and remodelling of the assimilative metabolic network of natural C1‐utilizing bacteria and the use of quantitative data‐driven approaches for engineering new C1‐utilizing bacterial chassis. The analyses will provide new insights to better understand, design, and construct C1‐based cell factories for efficient carbon assimilation and high‐value product synthesis. They also offer their perspective on the future advances that could further improve C1‐based biomanufacturing. For details please refer to the article by Song et al. in pp. 1–128.

Published

2024

37. 13C-metabolic flux analysis in S-adenosyl-l-methionine production by Saccharomyces cerevisiae.

Author

Hayakawa, Kenshi, Kajihata, Shuichi, Matsuda, Fumio, and Shimizu, Hiroshi

Subjects

*METABOLIC flux analysis, *ADENOSYLMETHIONINE, *SACCHAROMYCES cerevisiae, *DIETARY supplements, *OXIDATIVE phosphorylation

Abstract

S -Adenosyl- l -methionine (SAM) is a major biological methyl group donor, and is used as a nutritional supplement and prescription drug. Yeast is used for the industrial production of SAM owing to its high intracellular SAM concentrations. To determine the regulation mechanisms responsible for such high SAM production, 13 C-metabolic flux analysis ( 13 C-MFA) was conducted to compare the flux distributions in the central metabolism between Kyokai no. 6 (high SAM-producing) and S288C (control) strains. 13 C-MFA showed that the levels of tricarboxylic acid (TCA) cycle flux in SAM-overproducing strain were considerably increased compared to those in the S228C strain. Analysis of ATP balance also showed that a larger amount of excess ATP was produced in the Kyokai 6 strain because of increased oxidative phosphorylation. These results suggest that high SAM production in Kyokai 6 strains could be attributed to enhanced ATP regeneration with high TCA cycle fluxes and respiration activity. Thus, maintaining high respiration efficiency during cultivation is important for improving SAM production. [ABSTRACT FROM AUTHOR]

Published

2015

38. Isotope tracing reveals distinct substrate preference in murine melanoma subtypes with differing anti-tumor immunity

Author

Xinyi Zhang, Alexandra A. Halberstam, Wanling Zhu, Brooks P. Leitner, Durga Thakral, Marcus W. Bosenberg, and Rachel J. Perry

Subjects

Melanoma, Tumor metabolism, Tumor microenvironment, Glucose, Amino acid, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Background Research about tumor “metabolic flexibility”—the ability of cells to toggle between preferred nutrients depending on the metabolic context—has largely focused on obesity-associated cancers. However, increasing evidence for a key role for nutrient competition in the tumor microenvironment, as well as for substrate regulation of immune function, suggests that substrate metabolism deserves reconsideration in immunogenic tumors that are not strongly associated with obesity. Methods We compare two murine models: immunologically cold YUMM1.7 and immunologically-hot YUMMER1.7. We utilize stable isotope and radioisotope tracer-based metabolic flux studies as well as gas and liquid chromatography-based metabolomics analyses to comprehensively probe substrate preference in YUMM1.7 and YUMMER1.7 cells, with a subset of studies on the impact of available metabolites across a panel of five additional melanoma cell lines. We analyze bulk RNA-seq data and identify increased expression of amino acid and glucose metabolism genes in YUMMER1.7. Finally, we analyze melanoma patient RNA-seq data to identify potential prognostic predictors rooted in metabolism. Results We demonstrate using stable isotope tracer-based metabolic flux studies as well as gas and liquid chromatography-based metabolomics that immunologically-hot melanoma utilizes more glutamine than immunologically-cold melanoma in vivo and in vitro. Analyses of human melanoma RNA-seq data demonstrate that glutamine transporter and other anaplerotic gene expression positively correlates with lymphocyte infiltration and function. Conclusions Here, we highlight the importance of understanding metabolism in non-obesity-associated cancers, such as melanoma. This work advances the understanding of the correlation between metabolism and immunogenicity in the tumor microenvironment and provides evidence supporting metabolic gene expression as potential prognostic factors of melanoma progression and may inform investigations of adjunctive metabolic therapy in melanoma. Trial registration Deidentified data from The Cancer Genome Atlas were analyzed.

Published

2022

39. Transcriptomic and fluxomic changes in Streptomyces lividans producing heterologous protein.

Author

Daniels, Wouter, Bouvin, Jeroen, Busche, Tobias, Rückert, Christian, Simoens, Kenneth, Karamanou, Spyridoula, Van Mellaert, Lieve, Friðjónsson, Ólafur H., Nicolai, Bart, Economou, Anastassios, Kalinowski, Jörn, Anné, Jozef, and Bernaerts, Kristel

Subjects

*STREPTOMYCES lividans, *XENOGRAFTS, *PROTEIN expression, *DNA, *PROTEOLYTIC enzymes

Abstract

Background: The Gram-positive Streptomyces lividans TK24 is an attractive host for heterologous protein production because of its high capability to secrete proteins—which favors correct folding and facilitates downstream processing—as well as its acceptance of methylated DNA and its low endogeneous protease activity. However, current inconsistencies in protein yields urge for a deeper understanding of the burden of heterologous protein production on the cell. In the current study, transcriptomics and 13 C \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$^{13}\hbox {C}$$\end{document} -based fluxomics were exploited to uncover gene expression and metabolic flux changes associated with heterologous protein production. The Rhodothermus marinus thermostable cellulase A (CelA)—previously shown to be successfully overexpressed in S. lividans—was taken as an example protein. Results: RNA-seq and 13 C \documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$^{13}\hbox {C}$$\end{document} -based metabolic flux analysis were performed on a CelA-producing and an empty-plasmid strain under the same conditions. Differential gene expression, followed by cluster analysis based on co-expression and co-localization, identified transcriptomic responses related to secretion-induced stress and DNA damage. Furthermore, the OsdR regulon (previously associated with hypoxia, oxidative stress, intercellular signaling, and morphological development) was consistently upregulated in the CelA-producing strain and exhibited co-expression with isoenzymes from the pentose phosphate pathway linked to secondary metabolism. Increased expression of these isoenzymes matches to increased fluxes in the pentose phosphate pathway. Additionally, flux maps of the central carbon metabolism show increased flux through the tricarboxylic acid cycle in the CelA-producing strain. Redirection of fluxes in the CelA-producing strain leads to higher production of NADPH, which can only partly be attributed to increased secretion. Conclusions: Transcriptomic and fluxomic changes uncover potential new leads for targeted strain improvement strategies which may ease the secretion stress and metabolic burden associated with heterologous protein synthesis and secretion, and may help create a more consistently performing S. lividans strain. Yet, links to secondary metabolism and redox balancing should be further investigated to fully understand the S. lividans metabolome under heterologous protein production. [ABSTRACT FROM AUTHOR]

Published

2018

40. Linking metabolism and histone acetylation dynamics by integrated metabolic flux analysis of Acetyl-CoA and histone acetylation sites.

Author

Egger, Anna-Sophia, Rauch, Eva, Sharma, Suraj, Kipura, Tobias, Hotze, Madlen, Mair, Thomas, Hohenegg, Alina, Kobler, Philipp, Heiland, Ines, and Kwiatkowski, Marcel

Abstract

Histone acetylation is an important epigenetic modification that regulates various biological processes and cell homeostasis. Acetyl-CoA, a hub molecule of metabolism, is the substrate for histone acetylation, thus linking metabolism with epigenetic regulation. However, still relatively little is known about the dynamics of histone acetylation and its dependence on metabolic processes, due to the lack of integrated methods that can capture site-specific histone acetylation and deacetylation reactions together with the dynamics of acetyl-CoA synthesis. In this study, we present a novel proteo-metabo-flux approach that combines mass spectrometry-based metabolic flux analysis of acetyl-CoA and histone acetylation with computational modelling. We developed a mathematical model to describe metabolic label incorporation into acetyl-CoA and histone acetylation based on experimentally measured relative abundances. We demonstrate that our approach is able to determine acetyl-CoA synthesis dynamics and site-specific histone acetylation and deacetylation reaction rate constants, and that consideration of the metabolically labelled acetyl-CoA fraction is essential for accurate determination of histone acetylation dynamics. Furthermore, we show that without correction, changes in metabolic fluxes would be misinterpreted as changes in histone acetylation dynamics, whereas our proteo-metabo-flux approach allows to distinguish between the two processes. Our proteo-metabo-flux approach expands the repertoire of metabolic flux analysis and cross-omics and represents a valuable approach to study the regulatory interplay between metabolism and epigenetic regulation by histone acetylation. [Display omitted] • Dynamic metabolic flux analysis of acetyl-CoA and histone acetylation. • Simultaneous determination of acetyl-CoA synthesis rates and histone acetylation dynamics. • Integrated approach improves mechanistic understanding of metabolomics and epigenomics. [ABSTRACT FROM AUTHOR]

Published

2024

41. Metabolomics‐driven approaches for identifying therapeutic targets in drug discovery.

Author

Pan, Shanshan, Yin, Luan, Liu, Jie, Tong, Jie, Wang, Zichuan, Zhao, Jiahui, Liu, Xuesong, Chen, Yong, Miao, Jing, Zhou, Yuan, Zeng, Su, and Xu, Tengfei

Subjects

DRUG discovery, SYSTEMS biology, MULTIOMICS, DRUG development, PHENOTYPIC plasticity

Abstract

Identification of therapeutic targets can directly elucidate the mechanism and effect of drug therapy, which is a central step in drug development. The disconnect between protein targets and phenotypes under complex mechanisms hampers comprehensive target understanding. Metabolomics, as a systems biology tool that captures phenotypic changes induced by exogenous compounds, has emerged as a valuable approach for target identification. A comprehensive overview was provided in this review to illustrate the principles and advantages of metabolomics, delving into the application of metabolomics in target identification. This review outlines various metabolomics‐based methods, such as dose–response metabolomics, stable isotope‐resolved metabolomics, and multiomics, which identify key enzymes and metabolic pathways affected by exogenous substances through dose‐dependent metabolite–drug interactions. Emerging techniques, including single‐cell metabolomics, artificial intelligence, and mass spectrometry imaging, are also explored for their potential to enhance target discovery. The review emphasizes metabolomics' critical role in advancing our understanding of disease mechanisms and accelerating targeted drug development, while acknowledging current challenges in the field. [ABSTRACT FROM AUTHOR]

Published

2024

42. 13 C-MFA helps to identify metabolic bottlenecks for improving malic acid production in Myceliophthora thermophila.

Author

Jiang, Junfeng, Liu, Defei, Li, Jingen, Tian, Chaoguang, Zhuang, Yingping, and Xia, Jianye

Subjects

METABOLIC flux analysis, MALIC acid, GENE knockout, OXIDATIVE phosphorylation, CARBON dioxide

Abstract

Background: Myceliophthora thermophila has been engineered as a significant cell factory for malic acid production, yet strategies to further enhance production remain unclear and lack rational guidance. 13C-MFA (13C metabolic flux analysis) offers a means to analyze cellular metabolic mechanisms and pinpoint critical nodes for improving product synthesis. Here, we employed 13C-MFA to investigate the metabolic flux distribution of a high-malic acid-producing strain of M. thermophila and attempted to decipher the crucial bottlenecks in the metabolic pathways. Results: Compared with the wild-type strain, the high-Malic acid-producing strain M. thermophila JG207 exhibited greater glucose uptake and carbon dioxide evolution rates but lower oxygen uptake rates and biomass yields. Consistent with these phenotypes, the 13C-MFA results showed that JG207 displayed elevated flux through the EMP pathway and downstream TCA cycle, along with reduced oxidative phosphorylation flux, thereby providing more precursors and NADH for malic acid synthesis. Furthermore, based on the 13C-MFA results, we conducted oxygen-limited culture and nicotinamide nucleotide transhydrogenase (NNT) gene knockout experiments to increase the cytoplasmic NADH level, both of which were shown to be beneficial for malic acid accumulation. Conclusions: This work elucidates and validates the key node for achieving high malic acid production in M. thermophila. We propose effective fermentation strategies and genetic modifications for enhancing malic acid production. These findings offer valuable guidance for the rational design of future cell factories aimed at improving malic acid yields. [ABSTRACT FROM AUTHOR]

Published

2024

43. Targeting the Leloir Pathway with Galactose-Based Antimetabolites in Glioblastoma.

Author

Sharpe, Martyn A., Ijare, Omkar B., Raghavan, Sudhir, Baskin, Alexandra M., Baskin, Brianna N., and Baskin, David S.

Subjects

BIOLOGICAL models, TISSUE arrays, GLIOMAS, ANTIMETABOLITES, GLYCOSYLATION, RESEARCH funding, LECTINS, DATA analysis, T-test (Statistics), IN vivo studies, DESCRIPTIVE statistics, POLYSACCHARIDES, MICE, ANIMAL experimentation, WESTERN immunoblotting, MOLECULAR structure, STATISTICS, SURVIVAL analysis (Biometry), CELL survival, MICROSCOPY

Abstract

Simple Summary: Glioblastoma (GBM) uses the Leloir pathway to catabolize D-Galactose (Gal) for tumor growth. Selective targeting of the Leloir pathway with Gal-based antimetabolites has potential for the treatment of GBM. Here, we tested the effect of a Gal-based antimetabolite, 4-deoxy-4-fluorogalactose (4DFG) on the viability and metabolism of GBM cells in culture. 4DFG is a good Glut3/Glut14 substrate and acts as a potent glioma chemotherapeutic. GBM cell cultures were used to examine toxicity and alterations in glycan composition. 4DFG is moderately potent against GBM cells in vitro (IC50: 125–300 µM). Glycosylation in GBM was disrupted by 4DFG. The effect of 4DFG on D-glucose (Glc) metabolism in GBM cells was assessed by using 13C NMR-based tracer studies. 13C-NMR-based metabolic flux analysis revealed that both glycolytic and mitochondrial metabolic fluxes of [U-13C]Glc were significantly decreased in the presence of 4DFG in GBM cells. Survival analysis in an intracranial mouse model during treatment with 4DFG (6 × 25 mg/kg of 4DFG, intravenously) showed improved outcomes by three-fold (p < 0.01). 4DFG is metabolized by GBM in vitro and in vivo, and is lethal to GBM tumors, but well tolerated in mice. A functional Gal-scavenging pathway in GBM allows Gal-based antimetabolites to act as chemotherapeutics. Background: Glioblastoma (GBM) uses Glut3 and/or Glut14 and the Leloir pathway to catabolize D-Galactose (Gal). UDP-4-deoxy-4-fluorogalactose (UDP-4DFG) is a potent inhibitor of the two key enzymes, UDP-galactose-4-epimerase (GALE) and UDP-Glucose 6-dehydrogenase (UGDH), involved in Gal metabolism and in glycan synthesis. The Gal antimetabolite 4-deoxy-4-fluorogalactose (4DFG) is a good substrate for Glut3/Glut14 and acts as a potent glioma chemotherapeutic. Methods: Primary GBM cell cultures were used to examine toxicity and alterations in glycan composition via lectin binding in fixed cells and by Western blots. Toxicity/efficacy in vivo data was performed in mouse flank and intracranial models. The effect of 4DFG on D-glucose (Glc) metabolism in GBM cells was assessed by using 13C NMR-based tracer studies. Results: 4DFG is moderately potent against GBM cells (IC50: 125–300 µM). GBM glycosylation is disrupted by 4DFG. Survival analysis in an intracranial mouse model showed that treatment with 4DFG (6 × 25 mg/kg of 4DFG, intravenously) improved outcomes by three-fold (p < 0.01). Metabolic flux analysis revealed that both glycolytic and mitochondrial metabolic fluxes of [U-13C]Glc were significantly decreased in the presence of 4DFG in GBM cells. Conclusion: A functional Gal-scavenging pathway in GBM allows Gal-based antimetabolites to act as chemotherapeutics. 4DFG is metabolized by GBM in vitro and in vivo, is lethal to GBM tumors, and is well tolerated in mice. [ABSTRACT FROM AUTHOR]

Published

2024

44. Detection and Validation of Organic Metabolites in Urine for Clear Cell Renal Cell Carcinoma Diagnosis.

Author

Holbrook, Kiana L., Quaye, George E., Noriega Landa, Elizabeth, Su, Xiaogang, Gao, Qin, Williams, Heinric, Young, Ryan, Badmos, Sabur, Habib, Ahsan, Chacon, Angelica A., and Lee, Wen-Yee

Subjects

RENAL cell carcinoma, RENAL cancer, EARLY detection of cancer, THERMAL desorption, VOLATILE organic compounds

Abstract

Background: Clear cell renal cell carcinoma (ccRCC) comprises the majority, approximately 70–80%, of renal cancer cases and often remains asymptomatic until incidentally detected during unrelated abdominal imaging or at advanced stages. Currently, standardized screening tests for renal cancer are lacking, which presents challenges in disease management and improving patient outcomes. This study aimed to identify ccRCC-specific volatile organic compounds (VOCs) in the urine of ccRCC-positive patients and develop a urinary VOC-based diagnostic model. Methods: This study involved 233 pretreatment ccRCC patients and 43 healthy individuals. VOC analysis utilized stir-bar sorptive extraction coupled with thermal desorption gas chromatography/mass spectrometry (SBSE-TD-GC/MS). A ccRCC diagnostic model was established via logistic regression, trained on 163 ccRCC cases versus 31 controls, and validated with 70 ccRCC cases versus 12 controls, resulting in a ccRCC diagnostic model involving 24 VOC markers. Results: The findings demonstrated promising diagnostic efficacy, with an Area Under the Curve (AUC) of 0.94, 86% sensitivity, and 92% specificity. Conclusions: This study highlights the feasibility of using urine as a reliable biospecimen for identifying VOC biomarkers in ccRCC. While further validation in larger cohorts is necessary, this study's capability to differentiate between ccRCC and control groups, despite sample size limitations, holds significant promise. [ABSTRACT FROM AUTHOR]

Published

2024

45. EMUlator: An Elementary Metabolite Unit (EMU) Based Isotope Simulator Enabled by Adjacency Matrix.

Author

Wu, Chao, Chen, Chia-hsin, Lo, Jonathan, Michener, William, Maness, PinChing, and Xiong, Wei

Subjects

METABOLIC flux analysis, ISOTOPES, CLOSTRIDIUM acetobutylicum, STABLE isotopes, CLOSTRIDIUM, RADIOLABELING

Abstract

Stable isotope based metabolic flux analysis is currently the unique methodology that allows the experimental study of the integrated responses of metabolic networks. This method primarily relies on isotope labeling and modeling, which could be a challenge in both experimental and computational biology. In particular, the algorithm implementation for isotope simulation is a critical step, limiting extensive usage of this powerful approach. Here, we introduce EMUlator a Python-based isotope simulator which is developed on Elementary Metabolite Unit (EMU) algorithm, an efficient and powerful algorithm for isotope modeling. We propose a novel adjacency matrix method to implement EMU modeling and exemplify it stepwise. This method is intuitively straightforward and can be conveniently mastered for various customized purposes. We apply this arithmetic pipeline to understand the phosphoketolase flux in the metabolic network of an industrial microbe Clostridium acetobutylicum. The resulting design enables a high-throughput and non-invasive approach for estimating phosphoketolase flux in vivo. Our computational insights allow the systematic design and prediction of isotope-based metabolic models and yield a comprehensive understanding of their limitations and potentials. [ABSTRACT FROM AUTHOR]

Published

2019

46. Validation-based model selection for C-13 metabolic flux analysis with uncertain measurement errors

Author

Sundqvist, Nicolas, Grankvist, Nina, Watrous, Jeramie, Mohit, Jain, Nilsson, Roland, Cedersund, Gunnar, Sundqvist, Nicolas, Grankvist, Nina, Watrous, Jeramie, Mohit, Jain, Nilsson, Roland, and Cedersund, Gunnar

Abstract

Accurate measurements of metabolic fluxes in living cells are central to metabolism research and metabolic engineering. The gold standard method is model-based metabolic flux analysis (MFA), where fluxes are estimated indirectly from mass isotopomer data with the use of a mathematical model of the metabolic network. A critical step in MFA is model selection: choosing what compartments, metabolites, and reactions to include in the metabolic network model. Model selection is often done informally during the modelling process, based on the same data that is used for model fitting (estimation data). This can lead to either overly complex models (overfitting) or too simple ones (underfitting), in both cases resulting in poor flux estimates. Here, we propose a method for model selection based on independent validation data. We demonstrate in simulation studies that this method consistently chooses the correct model in a way that is independent on errors in measurement uncertainty. This independence is beneficial, since estimating the true magnitude of these errors can be difficult. In contrast, commonly used model selection methods based on the chi(2)-test choose different model structures depending on the believed measurement uncertainty; this can lead to errors in flux estimates, especially when the magnitude of the error is substantially off. We present a new approach for quantification of prediction uncertainty of mass isotopomer distributions in other labelling experiments, to check for problems with too much or too little novelty in the validation data. Finally, in an isotope tracing study on human mammary epithelial cells, the validation-based model selection method identified pyruvate carboxylase as a key model component. Our results argue that validation-based model selection should be an integral part of MFA model development., Funding Agencies|Swedish Foundation for Strategic Research [FFL12-0220, IMT17-0245]; Swedish Research Council [2018-05418, 2018-03319]; Karolinska Institutet; CENIIT [15.09]; SciLifeLab National COVID-19 Research Program - Knut and Alice Wallenberg Foundation [2020.0182]; H2020 project PRECISE4Q grant [777107]; VINNOVA grants VisualSweden [2020-04711]; Swedish Fund for Research without Animal Experiments [F2019-0010]; ELLIIT [2020A12]

Published

2022

47. Propionate-induced changes in cardiac metabolism, notably CoA trapping, are not altered by L-carnitine.

Author

Yingxue Wang, Christopher, Bridgette A., Wilson, Kirkland A., Muoio, Deborah, McGarrah, Robert W., Brunengraber, Henri, and Guo-Fang Zhang

Abstract

High concentrations of propionate and its metabolites are found in several diseases that are often associated with the development of cardiac dysfunction, such as obesity, diabetes, propionic acidemia, and methylmalonic acidemia. In the present work, we employed a stable isotope-based metabolic flux approach to understand propionate-mediated perturbation of cardiac energy metabolism. Propionate led to accumulation of propionyl-CoA (increased by ~101-fold) and methylmalonyl-CoA (increased by 36-fold). This accumulation caused significant mitochondrial CoA trapping and inhibited fatty acid oxidation. The reduced energy contribution from fatty acid oxidation was associated with increased glucose oxidation. The enhanced anaplerosis of propionate and CoA trapping altered the pool sizes of tricarboxylic acid cycle (TCA) metabolites. In addition to being an anaplerotic substrate, the accumulation of proprionate-derived malate increased the recycling of malate to pyruvate and acetyl-CoA, which can enter the TCA for energy production. Supplementation of 3 mM l-carnitine did not relieve CoA trapping and did not reverse the propionate-mediated fuel switch. This is due to new findings that the heart appears to lack the specific enzyme catalyzing the conversion of short-chain (C3 and C4) dicarboxylyl-CoAs to dicarboxylylcarnitines. The discovery of this work warrants further investigation on the relevance of dicarboxylylcarnitines, especially C3 and C4 dicarboxylylcarnitines, in cardiac conditions such as heart failure. [ABSTRACT FROM AUTHOR]

Published

2018

48. Grid-based computational methods for the design of constraint-based parsimonious chemical reaction networks to simulate metabolite production: GridProd.

Author

Tamura, Takeyuki

Subjects

GENES, DNA synthesis, GENETIC code, LINEAR programming, METABOLITES

Abstract

Background: Constraint-based metabolic flux analysis of knockout strategies is an efficient method to simulate the production of useful metabolites in microbes. Owing to the recent development of technologies for artificial DNA synthesis, it may become important in the near future to mathematically design minimum metabolic networks to simulate metabolite production. Results: We have developed a computational method where parsimonious metabolic flux distribution is computed for designated constraints on growth and production rates which are represented by grids. When the growth rate of this obtained parsimonious metabolic network is maximized, higher production rates compared to those noted using existing methods are observed for many target metabolites. The set of reactions used in this parsimonious flux distribution consists of reactions included in the original genome scale model iAF1260. The computational experiments show that the grid size affects the obtained production rates. Under the conditions that the growth rate is maximized and the minimum cases of flux variability analysis are considered, the developed method produced more than 90% of metabolites, while the existing methods produced less than 50%. Mathematical explanations using examples are provided to demonstrate potential reasons for the ability of the proposed algorithm to identify design strategies that the existing methods could not identify. Conclusion: We developed an efficient method for computing the design of minimum metabolic networks by using constraint-based flux balance analysis to simulate the production of useful metabolites. The source code is freely available, and is implemented in MATLAB and COBRA toolbox. [ABSTRACT FROM AUTHOR]

Published

2018

49. Hansenula polymorpha methanol metabolism genes enhance recombinant protein production in Komagataella phaffi.

Author

Khalifeh Soltani, Maryam, Arjmand, Sareh, Ranaei Siadat, Seyed Omid, Bagheri, Abdolreza, and Marashi, Seyed Hassan

Subjects

RECOMBINANT proteins, GENE expression, CARBON metabolism, PROTEIN models, INDUSTRIAL capacity, NAD (Coenzyme)

Abstract

Recombinant protein production in Komagataella phaffi (K. phaffi), a widely utilized host organism, can be optimized by enhancing the metabolic flux in the central carbon metabolism pathways. The methanol utilization pathway (MUT) during methanol-based growth plays a crucial role in providing precursors and energy for cell growth and development. This study investigated the impact of boosting the methanol dissimilation pathway, a branch of MUT that plays a vital role in detoxifying formaldehyde and providing energy in the form of NADH, in K. phaffi. This was achieved by integrating two orthologous genes from Hansenula polymorpha into the K. phaffi genome: formaldehyde dehydrogenase (HpFLD) and formate dehydrogenase (HpFMDH). The HpFLD and HpFMDH genes were isolated from the Hansenula polymorpha genome and inserted under the regulation of the pAOX1 promoter in the genome of recombinant K. phaffi that already contained a single copy of model protein genes (eGFP or EGII). The expression levels of these model proteins were assessed through protein activity assays and gene expression analysis. The findings revealed that while both orthologous genes positively influenced model protein production, HpFMDH exhibited a more pronounced upregulation in expression compared to HpFLD. Co-expression of both orthologous genes demonstrated synergistic effects, resulting in approximately a twofold increase in the levels of the model proteins detected. This study provides valuable insights into enhancing the production capacity of recombinant proteins in K. phaffi. [ABSTRACT FROM AUTHOR]

Published

2024

50. Multi-omic analysis of bat versus human fibroblasts reveals altered central metabolism.

Author

Jagannathan, N. Suhas, Yu Peng Koh, Javier, Younghwan Lee, Sobota, Radoslaw Mikolaj, Irving, Aaron T., Lin-fa Wang, Yoko Itahana, Koji Itahana, and Tucker-Kellogg, Lisa

Published

2024