Journal Article10.1002/BIOT.201200316
Constraint-based strain design using continuous modifications (CosMos) of flux bounds finds new strategies for metabolic engineering
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TL;DR: This study proposes a new strain design method with continuous modifications (CosMos) that provides strategies for deletions, downregulations, and upregulations of fluxes that will lead to the production of the desired products.
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Abstract: In recent years, a growing number of metabolic engineering strain design techniques have employed constraint-based modeling to determine metabolic and regulatory network changes which are needed to improve chemical production. These methods use systems-level analysis of metabolism to help guide experimental efforts by identifying deletions, additions, downregulations, and upregulations of metabolic genes that will increase biological production of a desired metabolic product. In this work, we propose a new strain design method with continuous modifications (CosMos) that provides strategies for deletions, downregulations, and upregulations of fluxes that will lead to the production of the desired products. The method is conceptually simple and easy to implement, and can provide additional strategies over current approaches. We found that the method was able to find strain design strategies that required fewer modifications and had larger predicted yields than strategies from previous methods in example and genome-scale networks. Using CosMos, we identified modification strategies for producing a variety of metabolic products, compared strategies derived from Escherichia coli and Saccharomyces cerevisiae metabolic models, and examined how imperfect implementation may affect experimental outcomes. This study gives a powerful and flexible technique for strain engineering and examines some of the unexpected outcomes that may arise when strategies are implemented experimentally.
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Citations
Multivariate modular metabolic engineering for pathway and strain optimization.
Bradley W. Biggs,Brecht De Paepe,Christine Nicole S. Santos,Marjan De Mey,Parayil Kumaran Ajikumar +4 more
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Stoichiometric Representation of Gene-Protein-Reaction Associations Leverages Constraint-Based Analysis from Reaction to Gene-Level Phenotype Prediction.
TL;DR: The model transformation proposed in this work enables existing constraint-based methods to be used at the gene level without modification, and automatically leverages phenotype analysis from reaction to gene level, improving the biological insight that can be obtained from genome-scale models.
Co-evolution of strain design methods based on flux balance and elementary mode analysis
TL;DR: The last 10 years of in silico strain design with constraint-based models is looked back at and some features of the different approaches are highlighted and the utilization of these methods in successful in vivo metabolic engineering applications are discussed.
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