Correlation analysis of targeted proteins and metabolites to assess and engineer microbial isopentenol production

Kevin W George; Amy Chen; Aakriti Jain; Tanveer S Batth; Edward E K Baidoo; George Wang; Paul D Adams; Christopher J Petzold; Jay D Keasling; Taek Soon Lee

doi:10.1002/bit.25226

Correlation analysis of targeted proteins and metabolites to assess and engineer microbial isopentenol production

Kevin W George, Amy Chen, Aakriti Jain, Tanveer S Batth, Edward E K Baidoo, George Wang, Paul D Adams, Christopher J Petzold, Jay D Keasling, Taek Soon Lee

66 Citationer (Scopus)

Abstract

The ability to rapidly assess and optimize heterologous pathway function is critical for effective metabolic engineering. Here, we develop a systematic approach to pathway analysis based on correlations between targeted proteins and metabolites and apply it to the microbial production of isopentenol, a promising biofuel. Starting with a seven-gene pathway, we performed a correlation analysis to reduce pathway complexity and identified two pathway proteins as the primary determinants of efficient isopentenol production. Aided by the targeted quantification of relevant pathway intermediates, we constructed and subsequently validated a conceptual model of isopentenol pathway function. Informed by our analysis, we assembled a strain which produced isopentenol at a titer 1.5 g/L, or 46% of theoretical yield. Our engineering approach allowed us to accurately identify bottlenecks and determine appropriate pathway balance. Paired with high-throughput cloning techniques and analytics, this strategy should prove useful for the analysis and optimization of increasingly complex heterologous pathways.

Originalsprog	Engelsk
Tidsskrift	Biotechnology and Bioengineering
Vol/bind	111
Udgave nummer	8
Sider (fra-til)	1648-58
Antal sider	11
ISSN	0006-3592
DOI	https://doi.org/10.1002/bit.25226
Status	Udgivet - aug. 2014

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10.1002/bit.25226

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title = "Correlation analysis of targeted proteins and metabolites to assess and engineer microbial isopentenol production",

abstract = "The ability to rapidly assess and optimize heterologous pathway function is critical for effective metabolic engineering. Here, we develop a systematic approach to pathway analysis based on correlations between targeted proteins and metabolites and apply it to the microbial production of isopentenol, a promising biofuel. Starting with a seven-gene pathway, we performed a correlation analysis to reduce pathway complexity and identified two pathway proteins as the primary determinants of efficient isopentenol production. Aided by the targeted quantification of relevant pathway intermediates, we constructed and subsequently validated a conceptual model of isopentenol pathway function. Informed by our analysis, we assembled a strain which produced isopentenol at a titer 1.5 g/L, or 46% of theoretical yield. Our engineering approach allowed us to accurately identify bottlenecks and determine appropriate pathway balance. Paired with high-throughput cloning techniques and analytics, this strategy should prove useful for the analysis and optimization of increasingly complex heterologous pathways.",

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author = "George, {Kevin W} and Amy Chen and Aakriti Jain and Batth, {Tanveer S} and Baidoo, {Edward E K} and George Wang and Adams, {Paul D} and Petzold, {Christopher J} and Keasling, {Jay D} and Lee, {Taek Soon}",

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year = "2014",

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AU - George, Kevin W

AU - Chen, Amy

AU - Jain, Aakriti

AU - Batth, Tanveer S

AU - Baidoo, Edward E K

AU - Wang, George

AU - Adams, Paul D

AU - Petzold, Christopher J

AU - Keasling, Jay D

AU - Lee, Taek Soon

PY - 2014/8

Y1 - 2014/8

N2 - The ability to rapidly assess and optimize heterologous pathway function is critical for effective metabolic engineering. Here, we develop a systematic approach to pathway analysis based on correlations between targeted proteins and metabolites and apply it to the microbial production of isopentenol, a promising biofuel. Starting with a seven-gene pathway, we performed a correlation analysis to reduce pathway complexity and identified two pathway proteins as the primary determinants of efficient isopentenol production. Aided by the targeted quantification of relevant pathway intermediates, we constructed and subsequently validated a conceptual model of isopentenol pathway function. Informed by our analysis, we assembled a strain which produced isopentenol at a titer 1.5 g/L, or 46% of theoretical yield. Our engineering approach allowed us to accurately identify bottlenecks and determine appropriate pathway balance. Paired with high-throughput cloning techniques and analytics, this strategy should prove useful for the analysis and optimization of increasingly complex heterologous pathways.

AB - The ability to rapidly assess and optimize heterologous pathway function is critical for effective metabolic engineering. Here, we develop a systematic approach to pathway analysis based on correlations between targeted proteins and metabolites and apply it to the microbial production of isopentenol, a promising biofuel. Starting with a seven-gene pathway, we performed a correlation analysis to reduce pathway complexity and identified two pathway proteins as the primary determinants of efficient isopentenol production. Aided by the targeted quantification of relevant pathway intermediates, we constructed and subsequently validated a conceptual model of isopentenol pathway function. Informed by our analysis, we assembled a strain which produced isopentenol at a titer 1.5 g/L, or 46% of theoretical yield. Our engineering approach allowed us to accurately identify bottlenecks and determine appropriate pathway balance. Paired with high-throughput cloning techniques and analytics, this strategy should prove useful for the analysis and optimization of increasingly complex heterologous pathways.

KW - Acetates/metabolism

KW - Biofuels/microbiology

KW - Biosynthetic Pathways

KW - Escherichia coli/genetics

KW - Escherichia coli Proteins/genetics

KW - Glucose/metabolism

KW - Industrial Microbiology/methods

KW - Metabolic Engineering/methods

KW - Models, Biological

KW - Pentanols/metabolism

KW - Proteomics/methods

U2 - 10.1002/bit.25226

DO - 10.1002/bit.25226

M3 - Journal article

C2 - 24615242

SN - 0006-3592

VL - 111

SP - 1648

EP - 1658

JO - Biotechnology and Bioengineering

JF - Biotechnology and Bioengineering

IS - 8

ER -

Correlation analysis of targeted proteins and metabolites to assess and engineer microbial isopentenol production

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