Consolidated bioprocessing of cellulose to isobutanol using Clostridium thermocellum

Paul P. Lin; Lou Mi; Amy H. Morioka; Kouki M. Yoshino; Sawako Konishi; Sharon C. Xu; Beth A. Papanek; Lauren A. Riley; Adam M. Guss; James C. Liao

doi:10.1016/j.ymben.2015.07.001

Consolidated bioprocessing of cellulose to isobutanol using Clostridium thermocellum

Paul P. Lin, Lou Mi, Amy H. Morioka, Kouki M. Yoshino, Sawako Konishi, Sharon C. Xu, Beth A. Papanek, Lauren A. Riley, Adam M. Guss, James C. Liao

Synthetic Biology

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145 Scopus citations

Abstract

Consolidated bioprocessing (CBP) has the potential to reduce biofuel or biochemical production costs by processing cellulose hydrolysis and fermentation simultaneously without the addition of pre-manufactured cellulases. In particular, Clostridium thermocellum is a promising thermophilic CBP host because of its high cellulose decomposition rate. Here we report the engineering of C. thermocellum to produce isobutanol. Metabolic engineering for isobutanol production in C. thermocellum is hampered by enzyme toxicity during cloning, time-consuming pathway engineering procedures, and slow turnaround in production tests. In this work, we first cloned essential isobutanol pathway genes under different promoters to create various plasmid constructs in Escherichia coli. Then, these constructs were transformed and tested in C. thermocellum. Among these engineered strains, the best isobutanol producer was selected and the production conditions were optimized. We confirmed the expression of the overexpressed genes by their mRNA quantities. We also determined that both the native ketoisovalerate oxidoreductase (KOR) and the heterologous ketoisovalerate decarboxylase (KIVD) expressed were responsible for isobutanol production. We further found that the plasmid was integrated into the chromosome by single crossover. The resulting strain was stable without antibiotic selection pressure. This strain produced 5.4g/L of isobutanol from cellulose in minimal medium at 50^oC within 75h, corresponding to 41% of theoretical yield.

Original language	English
Pages (from-to)	44-52
Number of pages	9
Journal	Metabolic Engineering
Volume	31
DOIs	https://doi.org/10.1016/j.ymben.2015.07.001
State	Published - Sep 1 2015

Funding

This research was supported by the DOE BioEnergy Science Center (BESC) . This material is based upon research performed in a renovated collaborator by the National Science Foundation under Grant no. 0963183 , which is an award funded under the American Recovery and Reinvestment Act of 2009 (ARRA). We thank Katherine Chou and Pinching Maness for providing the C. thermocellum DSM1313 Δhpt strain. We thank Dan Olson and Evert Holwerda for the scientific discussion. We thank Jennifer L. Takasumi, Annabel Lee, Joseph G. Leong and Mickeala Tu for their technical assistance.

Keywords

Biofuel
Butanol
Clostridium thermocellum
Consolidated bioprocessing

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10.1016/j.ymben.2015.07.001

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title = "Consolidated bioprocessing of cellulose to isobutanol using Clostridium thermocellum",

abstract = "Consolidated bioprocessing (CBP) has the potential to reduce biofuel or biochemical production costs by processing cellulose hydrolysis and fermentation simultaneously without the addition of pre-manufactured cellulases. In particular, Clostridium thermocellum is a promising thermophilic CBP host because of its high cellulose decomposition rate. Here we report the engineering of C. thermocellum to produce isobutanol. Metabolic engineering for isobutanol production in C. thermocellum is hampered by enzyme toxicity during cloning, time-consuming pathway engineering procedures, and slow turnaround in production tests. In this work, we first cloned essential isobutanol pathway genes under different promoters to create various plasmid constructs in Escherichia coli. Then, these constructs were transformed and tested in C. thermocellum. Among these engineered strains, the best isobutanol producer was selected and the production conditions were optimized. We confirmed the expression of the overexpressed genes by their mRNA quantities. We also determined that both the native ketoisovalerate oxidoreductase (KOR) and the heterologous ketoisovalerate decarboxylase (KIVD) expressed were responsible for isobutanol production. We further found that the plasmid was integrated into the chromosome by single crossover. The resulting strain was stable without antibiotic selection pressure. This strain produced 5.4g/L of isobutanol from cellulose in minimal medium at 50oC within 75h, corresponding to 41% of theoretical yield.",

keywords = "Biofuel, Butanol, Clostridium thermocellum, Consolidated bioprocessing",

author = "Lin, {Paul P.} and Lou Mi and Morioka, {Amy H.} and Yoshino, {Kouki M.} and Sawako Konishi and Xu, {Sharon C.} and Papanek, {Beth A.} and Riley, {Lauren A.} and Guss, {Adam M.} and Liao, {James C.}",

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AU - Lin, Paul P.

AU - Mi, Lou

AU - Morioka, Amy H.

AU - Yoshino, Kouki M.

AU - Konishi, Sawako

AU - Xu, Sharon C.

AU - Papanek, Beth A.

AU - Riley, Lauren A.

AU - Guss, Adam M.

AU - Liao, James C.

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AB - Consolidated bioprocessing (CBP) has the potential to reduce biofuel or biochemical production costs by processing cellulose hydrolysis and fermentation simultaneously without the addition of pre-manufactured cellulases. In particular, Clostridium thermocellum is a promising thermophilic CBP host because of its high cellulose decomposition rate. Here we report the engineering of C. thermocellum to produce isobutanol. Metabolic engineering for isobutanol production in C. thermocellum is hampered by enzyme toxicity during cloning, time-consuming pathway engineering procedures, and slow turnaround in production tests. In this work, we first cloned essential isobutanol pathway genes under different promoters to create various plasmid constructs in Escherichia coli. Then, these constructs were transformed and tested in C. thermocellum. Among these engineered strains, the best isobutanol producer was selected and the production conditions were optimized. We confirmed the expression of the overexpressed genes by their mRNA quantities. We also determined that both the native ketoisovalerate oxidoreductase (KOR) and the heterologous ketoisovalerate decarboxylase (KIVD) expressed were responsible for isobutanol production. We further found that the plasmid was integrated into the chromosome by single crossover. The resulting strain was stable without antibiotic selection pressure. This strain produced 5.4g/L of isobutanol from cellulose in minimal medium at 50oC within 75h, corresponding to 41% of theoretical yield.

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Consolidated bioprocessing of cellulose to isobutanol using Clostridium thermocellum

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Keywords

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