Enhanced hexose fermentation by Saccharomyces cerevisiae through integration of stoichiometric modeling and genetic screening

•Stoichiometric modeling identified gene targets for improved ethanol production.•Subsequent genetic screening of the identified targets was performed.•Substantial phenotype variation was observed from the screening.•Three knockout mutants demonstrated significant advantages for ethanol production.•...

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Bibliographic Details
Published in:Journal of biotechnology 2015-01, Vol.194, p.48-57
Main Authors: Quarterman, Josh, Kim, Soo Rin, Kim, Pan-Jun, Jin, Yong-Su
Format: Article
Language:English
Subjects:
Constraint-based flux analysis
Cytochrome c oxidase
Deletion
Enzymes
Ethanol
Ethyl alcohol
Fermentation - physiology
Genes
Genetics
Genome-scale model
Hexoses
Hexoses - metabolism
Mathematical models
Saccharomyces cerevisiae
Saccharomyces cerevisiae - metabolism
Screening
Ubiquinol cytochrome c reductase
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Summary:•Stoichiometric modeling identified gene targets for improved ethanol production.•Subsequent genetic screening of the identified targets was performed.•Substantial phenotype variation was observed from the screening.•Three knockout mutants demonstrated significant advantages for ethanol production.•One of the knockout mutants maximized ethanol production with no growth defect. In order to determine beneficial gene deletions for ethanol production by the yeast Saccharomyces cerevisiae, we performed an in silico gene deletion experiment based on a genome-scale metabolic model. Genes coding for two oxidative phosphorylation reactions (cytochrome c oxidase and ubiquinol cytochrome c reductase) were identified by the model-based simulation as potential deletion targets for enhancing ethanol production and maintaining acceptable overall growth rate in oxygen-limited conditions. Since the two target enzymes are composed of multiple subunits, we conducted a genetic screening study to evaluate the in silico results and compare the effect of deleting various portions of the respiratory enzyme complexes. Over two-thirds of the knockout mutants identified by the in silico study did exhibit experimental behavior in qualitative agreement with model predictions, but the exceptions illustrate the limitation of using a purely stoichiometric model-based approach. Furthermore, there was a substantial quantitative variation in phenotype among the various respiration-deficient mutants that were screened in this study, and three genes encoding respiratory enzyme subunits were identified as the best knockout targets for improving hexose fermentation in microaerobic conditions. Specifically, deletion of either COX9 or QCR9 resulted in higher ethanol production rates than the parental strain by 37% and 27%, respectively, with slight growth disadvantages. Also, deletion of QCR6 led to improved ethanol production rate by 24% with no growth disadvantage. The beneficial effects of these gene deletions were consistently demonstrated in different strain backgrounds and with four common hexoses. The combination of stoichiometric modeling and genetic screening using a systematic knockout collection was useful for narrowing a large set of gene targets and identifying targets of interest.
ISSN:0168-1656
1873-4863
DOI:10.1016/j.jbiotec.2014.11.017