Your search keyword '"Ethanol fermentation"' showing total 4 results

1. Genomic structural variations contribute to trait improvement during whole-genome shuffling of yeast.

Author

Zheng, Dao-Qiong, Chen, Jie, Zhang, Ke, Gao, Ke-Hui, Li, Ou, Wang, Pin-Mei, Zhang, Xiao-Yang, Du, Feng-Guang, Sun, Pei-Yong, Qu, Ai-Min, Wu, Shuang, and Wu, Xue-Chang

Subjects

*YEAST fungi genetics, *FUNGAL genomes, *PHENOTYPES, *SACCHAROMYCES cerevisiae, *ETHANOL as fuel, *GENETIC transcription

Abstract

Whole-genome shuffling (WGS) is a powerful technology of improving the complex traits of many microorganisms. However, the molecular mechanisms underlying the altered phenotypes in isolates were less clarified. Isolates with significantly enhanced stress tolerance and ethanol titer under very-high-gravity conditions were obtained after WGS of the bioethanol Saccharomyces cerevisiae strain ZTW1. Karyotype analysis and RT-qPCR showed that chromosomal rearrangement occurred frequently in genome shuffling. Thus, the phenotypic effects of genomic structural variations were determined in this study. RNA-Seq and physiological analyses revealed the diverse transcription pattern and physiological status of the isolate S3-110 and ZTW1. Our observations suggest that the improved stress tolerance of S3-110 can be largely attributed to the copy number variations in large DNA regions, which would adjust the ploidy of yeast cells and expression levels of certain genes involved in stress response. Overall, this work not only constructed shuffled S. cerevisiae strains that have potential industrial applications but also provided novel insights into the molecular mechanisms of WGS and enhanced our knowledge on this useful breeding strategy. [ABSTRACT FROM AUTHOR]

Published

2014

2. Scientific challenges of bioethanol production in Brazil.

Author

Amorim, Henrique V., Lopes, Mário Lucio, De Castro Oliveira, Juliana Velasco, Buckeridge, Marcos S., and Goldman, Gustavo Henrique

Subjects

*ETHANOL as fuel, *SUGARCANE, *RECOMBINANT DNA, *PHOTOSYNTHESIS

Abstract

Bioethanol (fuel alcohol) has been produced by industrial alcoholic fermentation processes in Brazil since the beginning of the twentieth century. Currently, 432 mills and distilleries crush about 625 million tons of sugarcane per crop, producing about 27 billion liters of ethanol and 38.7 million tons of sugar. The production of bioethanol from sugarcane represents a major large-scale technology capable of producing biofuel efficiently and economically, providing viable substitutes to gasoline. The combination of immobilization of CO by sugarcane crops by photosynthesis into biomass together with alcoholic fermentation of this biomass has allowed production of a clean and high-quality liquid fuel that contains 93% of the original energy found in sugar. Over the last 30 years, several innovations have been introduced to Brazilian alcohol distilleries resulting in the improvement of plant efficiency and economic competitiveness. Currently, the main scientific challenges are to develop new technologies for bioethanol production from first and second generation feedstocks that exhibit positive energy balances and appropriately meet environmental sustainability criteria. This review focuses on these aspects and provides special emphasis on the selection of new yeast strains, genetic breeding, and recombinant DNA technology, as applied to bioethanol production processes. [ABSTRACT FROM AUTHOR]

Published

2011

3. Improving ethanol fermentation performance of Saccharomyces cerevisiae in very high-gravity fermentation through chemical mutagenesis and meiotic recombination.

Author

Jing-Jing Liu, Wen-Tao Ding, Guo-Chang Zhang, and Jing-Yu Wang

Subjects

*SACCHAROMYCES cerevisiae, *ETHANOL, *FERMENTATION, *CHEMICAL mutagenesis, *ETHYL methanesulfonate, *PHENOTYPES, *OSMOLAR concentration

Abstract

Genome shuffling is an efficient way to improve complex phenotypes under the control of multiple genes. For the improvement of strain's performance in very high-gravity (VHG) fermentation, we developed a new method of genome shuffling. A diploid ste2/ ste2 strain was subjected to EMS (ethyl methanesulfonate) mutagenesis followed by meiotic recombination-mediated genome shuffling. The resulting haploid progenies were intrapopulation sterile and therefore haploid recombinant cells with improved phenotypes were directly selected under selection condition. In VHG fermentation, strain WS1D and WS5D obtained by this approach exhibited remarkably enhanced tolerance to ethanol and osmolarity, increased metabolic rate, and 15.12% and 15.59% increased ethanol yield compared to the starting strain W303D, respectively. These results verified the feasibility of the strain improvement strategy and suggested that it is a powerful and high throughput method for development of Saccharomyces cerevisiae strains with desired phenotypes that is complex and cannot be addressed with rational approaches. [ABSTRACT FROM AUTHOR]

Published

2011

4. Marker-disruptive gene integration and URA3 recycling for multiple gene manipulation in Saccharomyces cerevisiae.

Author

Kaneko, Shohei, Tanaka, Tsutomu, Noda, Hideo, Fukuda, Hideki, Akada, Rinji, and Kondo, Akihiko

Subjects

*SACCHAROMYCES cerevisiae, *GENETIC regulation, *YEAST fungi genetics, *GENETIC markers, *FERMENTATION, *INDUSTRIAL applications

Abstract

The introduction of several kinds of genes into the yeast chromosome is a powerful tool in many fields from fundamental study to industrial application. Here, we describe a general strategy for one-step gene integration and a marker recycling method. Forty base pairs of a short sequence derived from a region adjacent to the HIS3 locus were placed between cell surface displaying β-glucosidase (BGL) and URA3 marker genes. HIS3 deletion and BGL–URA3 fragment integration were achieved via a PCR fragment consisting of the BGL–URA3 fragment attached to homology sequences flanked by the HIS3 targeting locus. The obtained his3:: URA3 disruptants were plated on a 5-FOA plate to select for the URA3 deletion due to repeated sequences at both sides of URA3 gene. In all selected colonies, BGL genes were integrated at the targeted HIS3 locus and URA3 was completely deleted. In addition, introduced BGL was efficiently expressed, and the transformants fermented cellobiose to ethanol effectively. As our strategy creates next transformation markers continuously together with gene integration, this method can serve as a simple and powerful tool for multiple genetic manipulations in yeast engineering. [ABSTRACT FROM AUTHOR]

Published

2009