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Full-Text Articles in Biomedical Engineering and Bioengineering
Manipulation Of The Precursor Supply For High-Level Production Of Longifolene By Metabolically Engineered Escherichia Coli, Yujin Cao, Rubing Zhang, Wei Liu, Guang Zhao, Wei Niu, Jiantao Guo, Mo Xian, Huizhou Liu
Manipulation Of The Precursor Supply For High-Level Production Of Longifolene By Metabolically Engineered Escherichia Coli, Yujin Cao, Rubing Zhang, Wei Liu, Guang Zhao, Wei Niu, Jiantao Guo, Mo Xian, Huizhou Liu
Department of Chemical and Biomolecular Engineering: Faculty Publications
Longifolene is a naturally occurring tricyclic sesquiterpene widely used in many different fields. Up to now, this valuable terpene was mainly manufactured from the high-boiling fraction of certain pine resins. Microbial production can be a promising alternative to the extraction from natural plant sources. Here, we present the metabolic engineering strategy to assemble biosynthetic pathway for longifolene production in Escherichia coli. E. coli was rendered to produce longifolene by heterologously expressing a codon optimized longifolene synthase from Picea abies. Augmentation of the metabolic flux to farnesyl pyrophosphate (FPP) by different FPP synthases conferred a 1.8-fold increase in longifolene …
Comparative Kinetic Modeling Of Growth And Molecular Hydrogen Overproduction By Engineered Strains Of Thermotoga Maritima, Raghuveer Singh, Rahul Tevatia, Derrick White, Yaşar Demirel, Paul H. Blum
Comparative Kinetic Modeling Of Growth And Molecular Hydrogen Overproduction By Engineered Strains Of Thermotoga Maritima, Raghuveer Singh, Rahul Tevatia, Derrick White, Yaşar Demirel, Paul H. Blum
Department of Chemical and Biomolecular Engineering: Faculty Publications
Thermotoga maritima is an anaerobic hyperthermophilic bacterium known for its high amounts of hydrogen (H2) production. In the current study, the kinetic modeling was applied on the engineered strains of T. maritima that surpassed the natural H2 production limit. The study generated a kinetic model explaining H2 overproduction and predicted a continuous fermentation system. A Leudking-Piret equation-based model predicted that H2 production by Tma200 (0.217 mol-H2 g–1-biomass) and Tma100 (0.147 mol-H2 g–1-biomass) were higher than wild type (0.096 mol-H2 g–1 -biomass) with reduced rates of maltose utilization. …