In EDS ansehen

Metabolic Engineering of Yeast

Gespeichert in:
Bibliographische Detailangaben
Titel: Metabolic Engineering of Yeast
Autoren: Shi, Shuobo, 1981, Chen, Yu, Nielsen, Jens B, 1962
Quelle: Annual review of biophysics. 54(1):101-120
Schlagwörter: yeast cell factory, synthetic biology, computational design, Saccharomyces cerevisiae, biorefinery, metabolic engineering
Beschreibung: Microbial cell factories have been developed to produce various compounds in a sustainable and economically viable manner. The yeast Saccharomyces cerevisiae has been used as a platform cell factory in industrial biotechnology with numerous advantages, including ease of operation, rapid growth, and tolerance for various industrial stressors. Advances in synthetic biology and metabolic models have accelerated the design-build-test-learn cycle in metabolic engineering, significantly facilitating the development of yeast strains with complex phenotypes, including the redirection of metabolic fluxes to desired products, the expansion of the spectrum of usable substrates, and the improvement of the physiological properties of strain. Strains with enhanced titer, rate, and yield are now competing with traditional petroleum-based industrial approaches. This review highlights recent advances and perspectives in the metabolic engineering of yeasts for the production of a variety of compounds, including fuels, chemicals, proteins, and peptides, as well as advancements in synthetic biology tools and mathematical modeling.
Dateibeschreibung: electronic
Zugangs-URL: https://research.chalmers.se/publication/546527
https://research.chalmers.se/publication/546527/file/546527_Fulltext.pdf
Datenbank: SwePub
Beschreibung
Abstract:Microbial cell factories have been developed to produce various compounds in a sustainable and economically viable manner. The yeast Saccharomyces cerevisiae has been used as a platform cell factory in industrial biotechnology with numerous advantages, including ease of operation, rapid growth, and tolerance for various industrial stressors. Advances in synthetic biology and metabolic models have accelerated the design-build-test-learn cycle in metabolic engineering, significantly facilitating the development of yeast strains with complex phenotypes, including the redirection of metabolic fluxes to desired products, the expansion of the spectrum of usable substrates, and the improvement of the physiological properties of strain. Strains with enhanced titer, rate, and yield are now competing with traditional petroleum-based industrial approaches. This review highlights recent advances and perspectives in the metabolic engineering of yeasts for the production of a variety of compounds, including fuels, chemicals, proteins, and peptides, as well as advancements in synthetic biology tools and mathematical modeling.
ISSN:1936122x
19361238
DOI:10.1146/annurev-biophys-070924-103134