Short-chain ketone production by engineered polyketide synthases in Streptomyces albus

被引:0
作者
Satoshi Yuzawa
Mona Mirsiaghi
Renee Jocic
Tatsuya Fujii
Fabrice Masson
Veronica T. Benites
Edward E. K. Baidoo
Eric Sundstrom
Deepti Tanjore
Todd R. Pray
Anthe George
Ryan W. Davis
John M. Gladden
Blake A. Simmons
Leonard Katz
Jay D. Keasling
机构
[1] Lawrence Berkeley National Laboratory,Biogical Systems and Engineering Division
[2] Joint BioEnegy Institute,Advanced Biofuels & Bioproducts Process Development Unit
[3] Lawrence Berkeley National Laboratory,Research Institute for Sustainable Chemistry, Institute for Synthetic Biology
[4] National Institute of Advanced Industrial Science and Technology,Department of Biomass Science and Conversion Technologies
[5] Sandia National Laboratory,QB3 Institute
[6] University of California,Department of Bioengineering
[7] University of California,Department of Chemical and Biomolecular Engineering
[8] University of California,Novo Nordisk Foundation Center for Biosustainability
[9] Technical University of Denmark,Center for Synthetic Biochemistry
[10] Shenzhen Institutes for Advanced Technologies,Biotechnology Research Center
[11] The University of Tokyo,undefined
来源
Nature Communications | / 9卷
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摘要
Microbial production of fuels and commodity chemicals has been performed primarily using natural or slightly modified enzymes, which inherently limits the types of molecules that can be produced. Type I modular polyketide synthases (PKSs) are multi-domain enzymes that can produce unique and diverse molecular structures by combining particular types of catalytic domains in a specific order. This catalytic mechanism offers a wealth of engineering opportunities. Here we report engineered microbes that produce various short-chain (C5–C7) ketones using hybrid PKSs. Introduction of the genes into the chromosome of Streptomyces albus enables it to produce >1 g · l−1 of C6 and C7 ethyl ketones and several hundred mg · l−1 of C5 and C6 methyl ketones from plant biomass hydrolysates. Engine tests indicate these short-chain ketones can be added to gasoline as oxygenates to increase the octane of gasoline. Together, it demonstrates the efficient and renewable microbial production of biogasolines by hybrid enzymes.
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