Analysis of glucose and xylose metabolism in new indigenous Meyerozyma caribbica strains isolated from corn residues

Aiming to broaden the base of knowledge about wild yeasts, four new indigenous strains were isolated from corn residues, and phylogenetic-tree assemblings on ITS and LSU regions indicated they belong to Meyerozyma caribbica . Yeasts were cultivated under full- and micro-aerobiosis, starting with low...

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Published in:World journal of microbiology & biotechnology 2022-02, Vol.38 (2), p.35-35, Article 35
Main Authors: Tadioto, Viviani, Milani, Letícia M., Barrilli, Évelyn T., Baptista, Cristina W., Bohn, Letícia, Dresch, Aline, Harakava, Ricardo, Fogolari, Odinei, Mibielli, Guilherme M., Bender, João P., Treichel, Helen, Stambuk, Boris U., Müller, Caroline, Alves, Sérgio L.
Format: Article
Language:English
Subjects:
Acetic Acid
Aerobiosis
Applied Microbiology
Biochemistry
Biomass
Biomedical and Life Sciences
Biotechnology
Carbohydrates
Cell density
Corn
Culture Media - chemistry
Density
Environmental Engineering/Biotechnology
Ethanol
Exhaustion
Fermentation
Glucose
Glucose - metabolism
Hexose
Hydrolysates
Inoculum
Life Sciences
Lignin
Metabolism
Meyerozyma caribbica
Microbiology
Monosaccharides
Original Paper
Phylogeny
Residues
Saccharomycetales - classification
Saccharomycetales - genetics
Saccharomycetales - isolation & purification
Saccharomycetales - metabolism
Xylitol
Xylitol - biosynthesis
Xylose
Xylose - metabolism
Yeast
Yeasts
Zea mays - microbiology
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Summary:Aiming to broaden the base of knowledge about wild yeasts, four new indigenous strains were isolated from corn residues, and phylogenetic-tree assemblings on ITS and LSU regions indicated they belong to Meyerozyma caribbica . Yeasts were cultivated under full- and micro-aerobiosis, starting with low or high cell-density inoculum, in synthetic medium or corn hydrolysate containing glucose and/or xylose. Cells were able to assimilate both monosaccharides, albeit by different metabolic routes (fermentative or respiratory). They grew faster in glucose, with lag phases ~ 10 h shorter than in xylose. The hexose exhaustion occurred between 24 and 34 h, while xylose was entirely consumed in the last few hours of cultivation (44–48 h). In batch fermentation in synthetic medium with high cell density, under full-aerobiosis, 18–20 g glucose l −1 were exhausted in 4–6 h, with a production of 6.5–7.0 g ethanol l −1 . In the xylose medium, cells needed > 12 h to consume the carbohydrate, and instead of ethanol, cells released 4.4–6.4 g l −1 xylitol. Under micro-aerobiosis, yeasts were unable to assimilate xylose, and glucose was more slowly consumed, although the ethanol yield was the theoretical maximum. When inoculated into the hydrolysate, cells needed 4–6 h to deplete glucose, and xylose had a maximum consumption of 57%. Considering that the hydrolysate contained ~ 3 g l −1 acetic acid, it probably has impaired sugar metabolism. Thus, this study increases the fund of knowledge regarding indigenous yeasts and reveals the biotechnological potential of these strains. Graphical abstract
ISSN:0959-3993
1573-0972
DOI:10.1007/s11274-021-03221-0