Please use this identifier to cite or link to this item: http://dspace.unimap.edu.my:80/xmlui/handle/123456789/33471
Title: Time-based comparative transcriptomics in engineered xylose-utilizing Saccharomyces cerevisiae identifies temperature-responsive genes during ethanol production
Authors: Ku Syahidah, Ku Ismail
Sakamoto, Takatoshi
Hasunuma, Tomohisa
Kondo, Akihiko
kusyahidah@unimap.edu.my
hasunuma@port.kobe-u.ac.jp
akondo@kobe-u.ac.jp
Keywords: Bioethanol
Saccharomyces cerevisiae
Thermotolerant
Transcriptomics
Xylose
Issue Date: Sep-2013
Publisher: Society for Industrial Microbiology and Biotechnology
Citation: Journal of Industrial Microbiology and Biotechnology, vol. 40(9), 2013, pages 1039-1050
Abstract: Agricultural residues comprising lignocellulosic materials are excellent sources of pentose sugar, which can be converted to ethanol as fuel. Ethanol production via consolidated bioprocessing requires a suitable microorganism to withstand the harsh fermentation environment of high temperature, high ethanol concentration, and exposure to inhibitors. We genetically enhanced an industrial Saccharomyces cerevisiae strain, sun049, enabling it to uptake xylose as the sole carbon source at high fermentation temperature. This strain was able to produce 13.9 g/l ethanol from 50 g/l xylose at 38 C. To better understand the xylose consumption ability during long-term, high-temperature conditions, we compared by transcriptomics two fermentation conditions: high temperature (38 C) and control temperature (30 C) during the first 12 h of fermentation. This is the first long-term, time-based transcriptomics approach, and it allowed us to discover the role of heat-responsive genes when xylose is the sole carbon source. The results suggest that genes related to amino acid, cell wall, and ribosomal protein synthesis are down-regulated under heat stress. To allow cell stability and continuous xylose uptake in order to produce ethanol, hexose transporter HXT5, heat shock proteins, ubiquitin proteins, and proteolysis were all induced at high temperature. We also speculate that the strong relationship between high temperature and increased xylitol accumulation represents the cell's mechanism to protect itself from heat degradation.
Description: Link to publisher's homepage at http://www.simbhq.org/
URI: http://link.springer.com/article/10.1007%2Fs10295-013-1293-3
http://dspace.unimap.edu.my:80/dspace/handle/123456789/33471
ISSN: 1367-5435
Appears in Collections:School of Bioprocess Engineering (Articles)



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