Bioethanol or biofuel as an alternative to fossil fuels has been expanded in the last few decades in the whole world. Use of bioethanol as a renewable transportation fuel will minimize the amounts of fossil-derived carbon dioxide (CO2) to the Earth’s atmosphere. Yeast is the most favorite organism for ethanol production because of its diverse substrate specificity and ease of production of ethanol under anaerobic condition. The main objective of this research work was to isolate & characterize stress tolerant, high potential ethanol producing yeast strains from agro industrial waste. In total 4 yeast isolates have been characterized on the basis of morphological and physico-chemical characters. Based on morphological appearance of vegetative cell under microscope, ascospore production, colony character and physico-chemical characters all the strains was identified to be Yeast. Phylogenetic identification by DNA sequencing confirmed that the strain P is Saccharomyces Unisporus, strain C is Saccharomyces cerevisiae, strain T is Saccharomyces cerevisiae & strain DB2 is Candida piceae. Most of the strains were thermotolerant, pH tolerant, ethanol tolerant as well as osmotolerant. They were resistant to cycloheximide at 0.0015g/100ml concentration, hydrogen peroxide (0.50%), Chloramphenicol (30µg/disc) but growth was inhibited in the presence of 1% acetic Acid. The strains P, C & T showed good Invertase activity & only the T strain was capable of producing killer toxin. They were capable of fermenting glucose, fructose, sucrose, amylose & trehalose. Ethanol producing capability of the strains was studied using sugarcane molasses as substrate. The bioethanol production capacity of the yeasts were found to be 15%, 14.5%, 12% & 8.15% for P, C, T & DB2 respectively at pH 6.0, 30oC temperature in media with 5.5% initial reducing sugar concentration in shaking condition. Pilot scale ethanol production by P strain was 13.10%, C strain 11.15%, T strain 9.80% & DB2 strains 7.85% at 60 hours. These strains could be potential for ethanol production from cane molasses.
Published in | American Journal of BioScience (Volume 1, Issue 2) |
DOI | 10.11648/j.ajbio.20130102.11 |
Page(s) | 24-34 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
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Copyright © The Author(s), 2013. Published by Science Publishing Group |
Ethanol, Molasses, DNA Sequencing, Stress Tolerant
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APA Style
Md. Fakruddin, Md. Ariful Islam, Md. Abdul Quayum, Monzur Morshed Ahmed, Nayuum Chowdhury. (2013). Characterization of Stress Tolerant High Potential Ethanol Producing Yeast from Agro-Industrial Waste. American Journal of BioScience, 1(2), 24-34. https://doi.org/10.11648/j.ajbio.20130102.11
ACS Style
Md. Fakruddin; Md. Ariful Islam; Md. Abdul Quayum; Monzur Morshed Ahmed; Nayuum Chowdhury. Characterization of Stress Tolerant High Potential Ethanol Producing Yeast from Agro-Industrial Waste. Am. J. BioScience 2013, 1(2), 24-34. doi: 10.11648/j.ajbio.20130102.11
AMA Style
Md. Fakruddin, Md. Ariful Islam, Md. Abdul Quayum, Monzur Morshed Ahmed, Nayuum Chowdhury. Characterization of Stress Tolerant High Potential Ethanol Producing Yeast from Agro-Industrial Waste. Am J BioScience. 2013;1(2):24-34. doi: 10.11648/j.ajbio.20130102.11
@article{10.11648/j.ajbio.20130102.11, author = {Md. Fakruddin and Md. Ariful Islam and Md. Abdul Quayum and Monzur Morshed Ahmed and Nayuum Chowdhury}, title = {Characterization of Stress Tolerant High Potential Ethanol Producing Yeast from Agro-Industrial Waste}, journal = {American Journal of BioScience}, volume = {1}, number = {2}, pages = {24-34}, doi = {10.11648/j.ajbio.20130102.11}, url = {https://doi.org/10.11648/j.ajbio.20130102.11}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ajbio.20130102.11}, abstract = {Bioethanol or biofuel as an alternative to fossil fuels has been expanded in the last few decades in the whole world. Use of bioethanol as a renewable transportation fuel will minimize the amounts of fossil-derived carbon dioxide (CO2) to the Earth’s atmosphere. Yeast is the most favorite organism for ethanol production because of its diverse substrate specificity and ease of production of ethanol under anaerobic condition. The main objective of this research work was to isolate & characterize stress tolerant, high potential ethanol producing yeast strains from agro industrial waste. In total 4 yeast isolates have been characterized on the basis of morphological and physico-chemical characters. Based on morphological appearance of vegetative cell under microscope, ascospore production, colony character and physico-chemical characters all the strains was identified to be Yeast. Phylogenetic identification by DNA sequencing confirmed that the strain P is Saccharomyces Unisporus, strain C is Saccharomyces cerevisiae, strain T is Saccharomyces cerevisiae & strain DB2 is Candida piceae. Most of the strains were thermotolerant, pH tolerant, ethanol tolerant as well as osmotolerant. They were resistant to cycloheximide at 0.0015g/100ml concentration, hydrogen peroxide (0.50%), Chloramphenicol (30µg/disc) but growth was inhibited in the presence of 1% acetic Acid. The strains P, C & T showed good Invertase activity & only the T strain was capable of producing killer toxin. They were capable of fermenting glucose, fructose, sucrose, amylose & trehalose. Ethanol producing capability of the strains was studied using sugarcane molasses as substrate. The bioethanol production capacity of the yeasts were found to be 15%, 14.5%, 12% & 8.15% for P, C, T & DB2 respectively at pH 6.0, 30oC temperature in media with 5.5% initial reducing sugar concentration in shaking condition. Pilot scale ethanol production by P strain was 13.10%, C strain 11.15%, T strain 9.80% & DB2 strains 7.85% at 60 hours. These strains could be potential for ethanol production from cane molasses.}, year = {2013} }
TY - JOUR T1 - Characterization of Stress Tolerant High Potential Ethanol Producing Yeast from Agro-Industrial Waste AU - Md. Fakruddin AU - Md. Ariful Islam AU - Md. Abdul Quayum AU - Monzur Morshed Ahmed AU - Nayuum Chowdhury Y1 - 2013/07/10 PY - 2013 N1 - https://doi.org/10.11648/j.ajbio.20130102.11 DO - 10.11648/j.ajbio.20130102.11 T2 - American Journal of BioScience JF - American Journal of BioScience JO - American Journal of BioScience SP - 24 EP - 34 PB - Science Publishing Group SN - 2330-0167 UR - https://doi.org/10.11648/j.ajbio.20130102.11 AB - Bioethanol or biofuel as an alternative to fossil fuels has been expanded in the last few decades in the whole world. Use of bioethanol as a renewable transportation fuel will minimize the amounts of fossil-derived carbon dioxide (CO2) to the Earth’s atmosphere. Yeast is the most favorite organism for ethanol production because of its diverse substrate specificity and ease of production of ethanol under anaerobic condition. The main objective of this research work was to isolate & characterize stress tolerant, high potential ethanol producing yeast strains from agro industrial waste. In total 4 yeast isolates have been characterized on the basis of morphological and physico-chemical characters. Based on morphological appearance of vegetative cell under microscope, ascospore production, colony character and physico-chemical characters all the strains was identified to be Yeast. Phylogenetic identification by DNA sequencing confirmed that the strain P is Saccharomyces Unisporus, strain C is Saccharomyces cerevisiae, strain T is Saccharomyces cerevisiae & strain DB2 is Candida piceae. Most of the strains were thermotolerant, pH tolerant, ethanol tolerant as well as osmotolerant. They were resistant to cycloheximide at 0.0015g/100ml concentration, hydrogen peroxide (0.50%), Chloramphenicol (30µg/disc) but growth was inhibited in the presence of 1% acetic Acid. The strains P, C & T showed good Invertase activity & only the T strain was capable of producing killer toxin. They were capable of fermenting glucose, fructose, sucrose, amylose & trehalose. Ethanol producing capability of the strains was studied using sugarcane molasses as substrate. The bioethanol production capacity of the yeasts were found to be 15%, 14.5%, 12% & 8.15% for P, C, T & DB2 respectively at pH 6.0, 30oC temperature in media with 5.5% initial reducing sugar concentration in shaking condition. Pilot scale ethanol production by P strain was 13.10%, C strain 11.15%, T strain 9.80% & DB2 strains 7.85% at 60 hours. These strains could be potential for ethanol production from cane molasses. VL - 1 IS - 2 ER -