Your search keyword '"Stambuk, Boris Ugarte"' showing total 3 results

1. Prospecting and engineering yeasts for ethanol production under inhibitory conditions: an experimental design analysis.

Author

Tadioto, Viviani, Deoti, Junior Romeo, Müller, Caroline, de Souza, Bruna Raquel, Fogolari, Odinei, Purificação, Marcela, Giehl, Anderson, Deoti, Letícia, Lucaroni, Ana Carolina, Matsushika, Akinori, Treichel, Helen, Stambuk, Boris Ugarte, and Alves Junior, Sergio Luiz

Abstract

The recently discovered wild yeast Wickerhamomyces sp. UFFS-CE-3.1.2 was analyzed through a high-throughput experimental design to improve ethanol yields in synthetic media with glucose, xylose, and cellobiose as carbon sources and acetic acid, furfural, formic acid, and NaCl as fermentation inhibitors. After Plackett–Burman (PB) and central composite design (CCD), the optimized condition was used in a fermentation kinetic analysis to compare this yeast's performance with an industrial Saccharomyces cerevisiae strain (JDY-01) genetically engineered to achieve a higher xylose fermentation capacity and fermentation inhibitors tolerance by overexpressing the genes XYL1, XYL2, XKS1, and TAL1. Our results show that furfural and NaCl had no significant effect on sugar consumption by UFFS-CE-3.1.2. Surprisingly, acetic acid negatively affected glucose but not xylose and cellobiose consumption. In contrast, the pH positively affected all the analyzed responses, indicating a cell's preference for alkaline environments. In the CCD, sugar concentration negatively affected the yields of ethanol, xylitol, and cellular biomass. Therefore, fermentation kinetics were carried out with the average concentrations of sugars and fermentation inhibitors and the highest tested pH value (8.0). Although UFFS-CE-3.1.2 fermented glucose efficiently, xylose and cellobiose were mainly used for cellular growth. Interestingly, the genetically engineered strain JDY-01 consumed ~ 30% more xylose and produced ~ 20% more ethanol. Also, while UFFS-CE-3.1.2 only consumed 32% of the acetic acid of the medium, JDY-01 consumed > 60% of it, reducing its toxic effects. Thus, the overexpressed genes played an essential role in the inhibitors' tolerance, and the applied engineering strategy may help improve 2G ethanol production. [ABSTRACT FROM AUTHOR]

Published

2023

2. Insufficient uracil supply in fully aerobic chemostat cultures of Saccharomyces cerevisiae leads to respiro-fermentative metabolism and double nutrient-limitation.

Author

Basso, Thiago Olitta, Dario, Marcelo Goulart, Tonso, Aldo, Stambuk, Boris Ugarte, and Gombert, Andreas Karoly

Subjects

SACCHAROMYCES cerevisiae, URACIL, METABOLISM, NITROGEN, GROWTH factors

Abstract

A combination of chemostat cultivation and a defined medium was used to demonstrate that uracil limitation leads to a drastic alteration in the physiology of auxotrophic cells of Saccharomyces cerevisiae. Under this condition, the carbon source is dissimilated mainly to ethanol and acetate, even in fully aerobic cultures grown at 0.1 h−1, which is far below the critical dilution rate. Differently from nitrogen-, sulphur-, or phosphate-limited cultures, uracil limitation leads to residual sugar (either glucose or sucrose) concentrations below 2 mM, which characterizes a situation of double-limitation: by the carbon source and by uracil. Furthermore, the specific rates of CO2 production and O2 consumption are increased when compared to the corresponding prototrophic strain. We conclude that when auxotrophic strains are to be used for quantitative physiological studies, special attention must be paid to the cultivation conditions, mainly regarding medium formulation, in order to avoid limitation of growth by the auxotrophic nutrient. [ABSTRACT FROM AUTHOR]

Published

2010

3. Production of ethanol fuel from enzyme-treated sugarcane bagasse hydrolysate using D-xylose-fermenting wild yeast isolated from Brazilian biomes.

Author

de Fátima Rodrigues de Souza, Raquel, Dutra, Emmanuel Daminiano, Leite, Fernanda Cristina Bezerra, Cadete, Raquel Miranda, Rosa, Carlos Augusto, Stambuk, Boris Ugarte, Stamford, Tânia Lúcia Montenegro, and de Morais, Marcos Antônio

Subjects

ETHANOL as fuel, BAGASSE industry, BIOMES, HYDROGEN peroxide, FERMENTATION

Abstract

In this study, we evaluated the potential of yeasts isolated from Amazon to produce second-generation ethanol from sugarcane bagasse delignified with alkaline hydrogen peroxide and hydrolysed with commercial enzyme preparation. The best efficiency savings in glucose and release of xylose were determined by considering the solids and enzyme loads. Furthermore, we selected Spathaspora passalidarum UFMG-CM-Y473 strain with the best fermentative parameters. Fermentations used bagasse hydrolysate without any nutritional supplementation, a significant difference from previous studies, which is closer to industrial conditions. Ethanol yield of 0.32 g/g and ethanol productivity of 0.34 g/L h were achieved after the consumption of 78% of the sugar. This hydrolysis/fermentation technology package could represent the input of an additional 3180 L of ethanol per hectare in areas of average sugarcane productivity such as 60 ton/ha. Thus, we concluded that Sp. passalidarum UFMG-CM-Y473 has a clear potential for the production of second-generation ethanol from delignified and enzyme-hydrolysed bagasse. [ABSTRACT FROM AUTHOR]

Published

2018