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26 results on '"Raghavendran, Vijayendran"'

12. Ethanol yield calculations in biorefineries

Author

Bermejo, Pamela Magalí, primary, Badino, Alberto, additional, Zamberlan, Luciano, additional, Raghavendran, Vijayendran, additional, Basso, Thiago Olitta, additional, and Gombert, Andreas Karoly, additional

Published
2021
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20. Forever panting and forever growing: physiology of Saccharomyces cerevisiae at extremely low oxygen availability in the absence of ergosterol and unsaturated fatty acids

Author

da Costa, Bruno Labate Vale, primary, Raghavendran, Vijayendran, additional, Franco, Luís Fernando Mercier, additional, Chaves Filho, Adriano de Britto, additional, Yoshinaga, Marcos Yukio, additional, Miyamoto, Sayuri, additional, Basso, Thiago Olitta, additional, and Gombert, Andreas Karoly, additional

Published
2019
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23. Anaerobiosis revisited: growth of <italic>Saccharomyces cerevisiae</italic> under extremely low oxygen availability.

Author

da Costa, Bruno Labate Vale, Basso, Thiago Olitta, Raghavendran, Vijayendran, and Gombert, Andreas Karoly

Subjects
ANAEROBIOSIS, SACCHAROMYCES cerevisiae, ETHANOL as fuel, CELL physiology, GENETIC regulation, BUTYL rubber, CHEMOSTAT
Abstract

The budding yeast Saccharomyces cerevisiae plays an important role in biotechnological applications, ranging from fuel ethanol to recombinant protein production. It is also a model organism for studies on cell physiology and genetic regulation. Its ability to grow under anaerobic conditions is of interest in many industrial applications. Unlike industrial bioreactors with their low surface area relative to volume, ensuring a complete anaerobic atmosphere during microbial cultivations in the laboratory is rather difficult. Tiny amounts of O2 that enter the system can vastly influence product yields and microbial physiology. A common procedure in the laboratory is to sparge the culture vessel with ultrapure N2 gas; together with the use of butyl rubber stoppers and norprene tubing, O2 diffusion into the system can be strongly minimized. With insights from some studies conducted in our laboratory, we explore the question ‘how anaerobic is anaerobiosis?’. We briefly discuss the role of O2 in non-respiratory pathways in S. cerevisiae and provide a systematic survey of the attempts made thus far to cultivate yeast under anaerobic conditions. We conclude that very few data exist on the physiology of S. cerevisiae under anaerobiosis in the absence of the anaerobic growth factors ergosterol and unsaturated fatty acids. Anaerobicity should be treated as a relative condition since complete anaerobiosis is hardly achievable in the laboratory. Ideally, researchers should provide all the details of their anaerobic set-up, to ensure reproducibility of results among different laboratories. [ABSTRACT FROM AUTHOR]

Published
2018
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25. Forever panting and forever growing: physiology of Saccharomyces cerevisiae at extremely low oxygen availability in the absence of ergosterol and unsaturated fatty acids.

Author

Costa, Bruno Labate Vale da, Raghavendran, Vijayendran, Franco, Luís Fernando Mercier, Filho, Adriano de Britto Chaves, Yoshinaga, Marcos Yukio, Miyamoto, Sayuri, Basso, Thiago Olitta, and Gombert, Andreas Karoly

Subjects
*UNSATURATED fatty acids, *SACCHAROMYCES cerevisiae, *OLEIC acid, *SATURATED fatty acids, *GROWTH factors, *PHYSIOLOGY
Abstract

We sought to investigate how far the growth of Saccharomyces cerevisiae under full anaerobiosis is dependent on the widely used anaerobic growth factors (AGF) ergosterol and oleic acid. A continuous cultivation setup was employed and, even forcing ultrapure N2 gas through an O2 trap upstream of the bioreactor, neither cells from S. cerevisiae CEN.PK113–7D (a lab strain) nor from PE-2 (an industrial strain) washed out after an aerobic-to-anaerobic switch in the absence of AGF. S. cerevisiae PE-2 seemed to cope better than the laboratory strain with this extremely low O2 availability, since it presented higher biomass yield, lower specific rates of glucose consumption and CO2 formation, and higher survival at low pH. Lipid (fatty acid and sterol) composition dramatically altered when cells were grown anaerobically without AGF: saturated fatty acid, squalene and lanosterol contents increased, when compared to either cells grown aerobically or anaerobically with AGF. We concluded that these lipid alterations negatively affect cell viability during exposure to low pH or high ethanol titers. [ABSTRACT FROM AUTHOR]

Published
2019
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26. Blocking Mitophagy Does Not Significantly Improve Fuel Ethanol Production in Bioethanol Yeast Saccharomyces cerevisiae.

Author

Pontes Eliodório, Kevy, de Gois Cunha, Gabriel Caetano, White, Brianna A., Patel, Demisha H. M., Fangyi Zhang, Hettema, Ewald H., Basso, Thiago Olitta, Gombert, Andreas Karoly, and Raghavendran, Vijayendran

Subjects
*ETHANOL as fuel, *SACCHAROMYCES cerevisiae, *ENERGY conservation, *ETHANOL, *FERMENTATION, *BREWING, *YEAST
Abstract

Ethanolic fermentation is frequently performed under conditions of low nitrogen. In Saccharomyces cerevisiae, nitrogen limitation induces macroautophagy, including the selective removal of mitochondria, also called mitophagy. Previous research showed that blocking mitophagy by deletion of the mitophagy-specific gene ATG32 increased the fermentation performance during the brewing of Ginjo sake. In this study, we tested if a similar strategy could enhance alcoholic fermentation in the context of fuel ethanol production from sugarcane in Brazilian biorefineries. Conditions that mimic the industrial fermentation process indeed induce Atg32-dependent mitophagy in cells of S. cerevisiae PE-2, a strain frequently used in the industry. However, after blocking mitophagy, no significant differences in CO2 production, final ethanol titers, or cell viability were observed after five rounds of ethanol fermentation, cell recycling, and acid treatment, which is commonly performed in sugarcane biorefineries. To test if S. cerevisiae’s strain background influenced this outcome, cultivations were carried out in a synthetic medium with strains PE-2, Ethanol Red (industrial), and BY (laboratory) with and without a functional ATG32 gene and under oxic and oxygen restricted conditions. Despite the clear differences in sugar consumption, cell viability, and ethanol titers, among the three strains, we did not observe any significant improvement in fermentation performance related to the blocking of mitophagy. We concluded, with caution, that the results obtained with Ginjo sake yeast were an exception and cannot be extrapolated to other yeast strains and that more research is needed to ascertain the role of autophagic processes during fermentation. IMPORTANCE Bioethanol is the largest (per volume) ever biobased bulk chemical produced globally. The fermentation process is well established, and industries regularly attain nearly 85% of maximum theoretical yields. However, because of the volume of fuel produced, even a small improvement will have huge economic benefits. To this end, besides already implemented process improvements, various free energy conservation strategies have been successfully exploited at least in laboratory strains to increase ethanol yields and decrease byproduct formation. Cellular housekeeping processes have been an almost unexplored territory in strain improvement. It was previously reported that blocking mitophagy by deletion of the mitophagy receptor gene ATG32 in Saccharomyces cerevisiae led to a 2.1% increase in final ethanol titers during Japanese sake fermentation. We found in two commercially used bioethanol strains (PE-2 and Ethanol Red) that ATG32 deficiency does not lead to a significant improvement in cell viability or ethanol levels during fermentation with molasses or in a synthetic complete medium. More research is required to ascertain the role of autophagic processes during fermentation conditions. [ABSTRACT FROM AUTHOR]

Published
2022
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