Engineering E. coli for simultaneous glucose–xylose utilization during methyl ketone production

Abstract Background We previously developed an E. coli strain that overproduces medium-chain methyl ketones for potential use as diesel fuel blending agents or as flavors and fragrances. To date, the strain’s performance has been optimized during growth with glucose. However, lignocellulosic biomass...

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Main Authors: Xi Wang, Ee-Been Goh, Harry R. Beller
Format: Article
Language:English
Published: BMC 2018-01-01
Series:Microbial Cell Factories
Subjects:
Online Access:http://link.springer.com/article/10.1186/s12934-018-0862-6
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spelling doaj-24ee70dc773a4f62a08982ea942aa0cd2020-11-24T21:50:11ZengBMCMicrobial Cell Factories1475-28592018-01-0117111110.1186/s12934-018-0862-6Engineering E. coli for simultaneous glucose–xylose utilization during methyl ketone productionXi Wang0Ee-Been Goh1Harry R. Beller2Joint BioEnergy Institute (JBEI)Joint BioEnergy Institute (JBEI)Joint BioEnergy Institute (JBEI)Abstract Background We previously developed an E. coli strain that overproduces medium-chain methyl ketones for potential use as diesel fuel blending agents or as flavors and fragrances. To date, the strain’s performance has been optimized during growth with glucose. However, lignocellulosic biomass hydrolysates also contain a substantial portion of hemicellulose-derived xylose, which is typically the second most abundant sugar after glucose. Commercialization of the methyl ketone-producing technology would benefit from the increased efficiency resulting from simultaneous, rather than the native sequential (diauxic), utilization of glucose and xylose. Results In this study, genetic manipulations were performed to alleviate carbon catabolite repression in our most efficient methyl ketone-producing strain. A strain engineered for constitutive expression of xylF and xylA (involved in xylose transport and metabolism) showed synchronized glucose and xylose consumption rates. However, this newly acquired capability came at the expense of methyl ketone titer, which decreased fivefold. Further efforts were made to improve methyl ketone production in this strain, and we found that two strategies were effective at enhancing methyl ketone titer: (1) chromosomal deletion of pgi (glucose-6-phosphate isomerase) to increase intracellular NADPH supply and (2) downregulation of CRP (cAMP receptor protein) expression by replacement of the native RBS with an RBS chosen based upon mutant library screening results. Combining these strategies resulted in the most favorable overall phenotypes for simultaneous glucose–xylose consumption without compromising methyl ketone titer at both 1 and 2% total sugar concentrations in shake flasks. Conclusions This work demonstrated a strategy for engineering simultaneous utilization of C6 and C5 sugars in E. coli without sacrificing production of fatty acid-derived compounds.http://link.springer.com/article/10.1186/s12934-018-0862-6Carbon catabolite repressionMethyl ketonesNADPHcAMP receptor proteinMetabolic engineering
collection DOAJ
language English
format Article
sources DOAJ
author Xi Wang
Ee-Been Goh
Harry R. Beller
spellingShingle Xi Wang
Ee-Been Goh
Harry R. Beller
Engineering E. coli for simultaneous glucose–xylose utilization during methyl ketone production
Microbial Cell Factories
Carbon catabolite repression
Methyl ketones
NADPH
cAMP receptor protein
Metabolic engineering
author_facet Xi Wang
Ee-Been Goh
Harry R. Beller
author_sort Xi Wang
title Engineering E. coli for simultaneous glucose–xylose utilization during methyl ketone production
title_short Engineering E. coli for simultaneous glucose–xylose utilization during methyl ketone production
title_full Engineering E. coli for simultaneous glucose–xylose utilization during methyl ketone production
title_fullStr Engineering E. coli for simultaneous glucose–xylose utilization during methyl ketone production
title_full_unstemmed Engineering E. coli for simultaneous glucose–xylose utilization during methyl ketone production
title_sort engineering e. coli for simultaneous glucose–xylose utilization during methyl ketone production
publisher BMC
series Microbial Cell Factories
issn 1475-2859
publishDate 2018-01-01
description Abstract Background We previously developed an E. coli strain that overproduces medium-chain methyl ketones for potential use as diesel fuel blending agents or as flavors and fragrances. To date, the strain’s performance has been optimized during growth with glucose. However, lignocellulosic biomass hydrolysates also contain a substantial portion of hemicellulose-derived xylose, which is typically the second most abundant sugar after glucose. Commercialization of the methyl ketone-producing technology would benefit from the increased efficiency resulting from simultaneous, rather than the native sequential (diauxic), utilization of glucose and xylose. Results In this study, genetic manipulations were performed to alleviate carbon catabolite repression in our most efficient methyl ketone-producing strain. A strain engineered for constitutive expression of xylF and xylA (involved in xylose transport and metabolism) showed synchronized glucose and xylose consumption rates. However, this newly acquired capability came at the expense of methyl ketone titer, which decreased fivefold. Further efforts were made to improve methyl ketone production in this strain, and we found that two strategies were effective at enhancing methyl ketone titer: (1) chromosomal deletion of pgi (glucose-6-phosphate isomerase) to increase intracellular NADPH supply and (2) downregulation of CRP (cAMP receptor protein) expression by replacement of the native RBS with an RBS chosen based upon mutant library screening results. Combining these strategies resulted in the most favorable overall phenotypes for simultaneous glucose–xylose consumption without compromising methyl ketone titer at both 1 and 2% total sugar concentrations in shake flasks. Conclusions This work demonstrated a strategy for engineering simultaneous utilization of C6 and C5 sugars in E. coli without sacrificing production of fatty acid-derived compounds.
topic Carbon catabolite repression
Methyl ketones
NADPH
cAMP receptor protein
Metabolic engineering
url http://link.springer.com/article/10.1186/s12934-018-0862-6
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