Systems Metabolic Engineering Strategies: Integrating Systems and Synthetic Biology with Metabolic Engineering

Metabolic engineering allows development of microbial strains efficiently producing chemicals and materials, but it requires much time, effort, and cost to make the strains industrially competitive. Systems metabolic engineering, which integrates tools and strategies of systems biology, synthetic bi...

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Bibliographic Details
Published in:Trends in biotechnology (Regular ed.) 2019-08, Vol.37 (8), p.817-837
Main Authors: Choi, Kyeong Rok, Jang, Woo Dae, Yang, Dongsoo, Cho, Jae Sung, Park, Dahyeon, Lee, Sang Yup
Format: Article
Language:English
Subjects:
Automation
Biological evolution
Biology
biorefinery
Biosensors
Business competition
Business metrics
Capital costs
CRISPR
Deoxyribonucleic acid
DNA
DNA methylation
Engineering research
Enzymes
evolutionary engineering
Fermentation
Gene expression
Genetic engineering
industrial biotechnology
Metabolic engineering
Metabolic flux
Metabolic pathways
Metabolism
Metabolites
Microorganisms
Optimization
Organic chemistry
Plasmids
Productivity
Proteins
Raw materials
Synthetic biology
systems biology
systems metabolic engineering
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Summary:Metabolic engineering allows development of microbial strains efficiently producing chemicals and materials, but it requires much time, effort, and cost to make the strains industrially competitive. Systems metabolic engineering, which integrates tools and strategies of systems biology, synthetic biology, and evolutionary engineering with traditional metabolic engineering, has recently been used to facilitate development of high-performance strains. The past decade has witnessed this interdisciplinary strategy continuously being improved toward the development of industrially competitive overproducer strains. In this article, current trends in systems metabolic engineering including tools and strategies are reviewed, focusing on recent developments in selection of host strains, metabolic pathway reconstruction, tolerance enhancement, and metabolic flux optimization. Also, future challenges and prospects are discussed. Systems metabolic engineering, which integrated systems biology, synthetic biology, and evolutionary engineering with traditional metabolic engineering, is facilitating the development of high performance strains. More diverse microorganisms are being used as production host strains, supported by the new genetic tools and strategies. Recent advances in biosynthetic/semisynthetic design strategies are expanding the portfolio of products that can be produced biologically. Evolutionary engineering tools and strategies are facilitating the improvement of strain and enzyme performances. Advances in tools and strategies of omics, in silico metabolic simulation, genetic and genomic engineering, and high-throughput screening are accelerating optimization of metabolic fluxes for the enhanced production of target bioproducts.
ISSN:0167-7799
1879-3096
DOI:10.1016/j.tibtech.2019.01.003