Improving ethanol yields in sugarcane molasses fermentation by engineering the high osmolarity glycerol pathway while maintaining osmotolerance in Saccharomyces cerevisiae

The ever-increasing demand of energy has made it imperative to increase the production of renewable fuels like ethanol. Many studies have reported increase in ethanol production by reducing fermentation by-products like glycerol. Deletion of structural genes like gpd1 and gpd2 leads to an increase i...

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Bibliographic Details
Published in:Applied microbiology and biotechnology 2019-01, Vol.103 (2), p.1031-1042
Main Authors: Jagtap, Rutuja Shivaji, Mahajan, Dheeraj Madhukar, Mistry, Sanjay Ratilal, Bilaiya, Megha, Singh, Rajesh Kumar, Jain, Rishi
Format: Article
Language:English
Subjects:
Acetic acid
Additives
Alternative fuels
Backup software
Baking yeast
Bioenergy and Biofuels
Bioengineering
Biomedical and Life Sciences
Biotechnology
Ethanol
Ethanol fuels
Fermentation
Genes
Genetic research
Glycerol
Industrial strains
Life Sciences
Methods
Microbial Genetics and Genomics
Microbiology
Molasses
Organic acids
Osmolarity
Physiological aspects
Production processes
Renewable fuels
Saccharomyces cerevisiae
Sugarcane
Synergistic effect
Syrups & sweeteners
Yeast
Yeasts
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Summary:The ever-increasing demand of energy has made it imperative to increase the production of renewable fuels like ethanol. Many studies have reported increase in ethanol production by reducing fermentation by-products like glycerol. Deletion of structural genes like gpd1 and gpd2 leads to an increase in ethanol by reducing glycerol; however, it makes the yeast osmosensitive that is not desirable for industrial strains. In this study, genes in the HOG pathway which regulates glycerol synthesis in Saccharomyces cerevisiae were targeted for improving ethanol yields in fermentation of sugarcane molasses. Deletion strains of ssk1 , hot1 , and smp1 were tested and they did not show osmosensitivity. Δssk1 and Δsmp1 recombinant strains showed consistent improved ethanol yields. As a result, a double-deletion strain, Δssk 1 Δsmp1 , was also constructed, which showed a synergistic effect leading to 6% increase in ethanol yield and 35% decrease in glycerol yield. It was also observed that there was a significant decrease in acetic acid yields of all the recombinant strains. Overall, the study demonstrates an industrially viable technique of engineering the HOG pathway resulting in decrease of glycerol and no loss of osmotolerance. These S. cerevisiae strains showed a significant increase in ethanol yields.
ISSN:0175-7598
1432-0614
DOI:10.1007/s00253-018-9532-1