Metabolic Burden: Cornerstones in Synthetic Biology and Metabolic Engineering Applications

Metabolic Burden: Cornerstones in Synthetic Biology and Metabolic Engineering Applications

Engineering cell metabolism for bioproduction not only consumes building blocks and energy molecules (e.g., ATP) but also triggers energetic inefficiency inside the cell. The metabolic burdens on microbial workhorses lead to undesirable physiological changes, placing hidden constraints on host produ...

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Veröffentlicht in:Trends in biotechnology (Regular ed.) 2016-08, Vol.34 (8), p.652-664
Hauptverfasser: Wu, Gang, Yan, Qiang, Jones, J. Andrew, Tang, Yinjie J, Fong, Stephen S, Koffas, Mattheos A.G
Format: Artikel
Sprache:eng
Schlagworte:
13C-MFA
Bacterial Physiological Phenomena
Bioreactors - microbiology
Biosynthesis
Carbon
Carbon - metabolism
chromosomal engineering
E coli
Energy Metabolism - physiology
Enzymes
Genetic engineering
Genetic Enhancement - methods
genome-scale model
Glucose
Internal Medicine
machine learning
Metabolic Engineering - methods
Metabolic Flux Analysis - methods
Metabolic Networks and Pathways - physiology
Metabolism
Metabolome - physiology
Models, Biological
Mutation
Nutrient utilization
Physiological responses
Physiology
Plasmids
Productivity
Respiration
Scale models
Synthetic biology
Synthetic Biology - methods
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Zusammenfassung:Engineering cell metabolism for bioproduction not only consumes building blocks and energy molecules (e.g., ATP) but also triggers energetic inefficiency inside the cell. The metabolic burdens on microbial workhorses lead to undesirable physiological changes, placing hidden constraints on host productivity. We discuss cell physiological responses to metabolic burdens, as well as strategies to identify and resolve the carbon and energy burden problems, including metabolic balancing, enhancing respiration, dynamic regulatory systems, chromosomal engineering, decoupling cell growth with production phases, and co-utilization of nutrient resources. To design robust strains with high chances of success in industrial settings, novel genome-scale models (GSMs),13 C-metabolic flux analysis (MFA), and machine-learning approaches are needed for weighting, standardizing, and predicting metabolic costs.
ISSN:0167-7799
1879-3096
DOI:10.1016/j.tibtech.2016.02.010