Screening and Construction of Saccharomyces Cerevisiae Strains with Improved Multi-tolerance and Bioethanol Fermentation Performance

Overview

Journal Bioresour Technol

Specialty Biophysics

Date 2010 Oct 29

PMID 20980141

Citations 24

Authors

Dao-Qiong Zheng

Xue-Chang Wu

Xiang-Lin Tao

Pin-Mei Wang

Ping Li

Xiao-Qin Chi

Yu-Dong Li

Qing-Feng Yan

Yu-Hua Zhao

Affiliations

Soon will be listed here.

Abstract

In this study, a systemic analysis was initially performed to investigate the relationship between fermentation-related stress tolerances and ethanol yield. Based on the results obtained, two elite Saccharomyces cerevisiae strains, Z8 and Z15, with variant phenotypes were chosen to construct strains with improved multi-stress tolerance by genome shuffling in combination with optimized initial selection. After three rounds of genome shuffling, a shuffled strain, YZ1, which surpasses its parent strains in osmotic, heat, and acid tolerances, was obtained. Ethanol yields of YZ1 were 3.11%, 10.31%, and 10.55% higher than those of its parent strains under regular, increased heat, and high gravity fermentation conditions, respectively. YZ1 was applied to bioethanol production at an industrial scale. Results demonstrated that the variant phenotypes from available yeast strains could be used as parent stock for yeast breeding and that the genome shuffling approach is sufficiently powerful in combining suitable phenotypes in a single strain.

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