posted on 2022-09-14, 20:47authored byYe-Gi Lee, Chanwoo Kim, Nurzhan Kuanyshev, Nam Kyu Kang, Zia Fatma, Zong-Yen Wu, Ming-Hsun Cheng, Vijay Singh, Yasuo Yoshikuni, Huimin Zhao, Yong-Su Jin
Issatchenkia orientalis, exhibiting
high tolerance against harsh environmental conditions, is a promising
metabolic engineering host for producing fuels and chemicals from
cellulosic hydrolysates containing fermentation inhibitors under acidic
conditions. Although genetic tools for I. orientalis exist, they require auxotrophic mutants so that the selection of
a host strain is limited. We developed a drug resistance gene (cloNAT)-based
genome-editing method for engineering any I. orientalis strains and engineered I. orientalis strains isolated from various sources for xylose fermentation. Specifically,
xylose reductase, xylitol dehydrogenase, and xylulokinase from Scheffersomyces stipitis were integrated into an
intended chromosomal locus in four I. orientalis strains (SD108, IO21, IO45, and IO46) through Cas9-based genome
editing. The resulting strains (SD108X, IO21X, IO45X, and IO46X) efficiently
produced ethanol from cellulosic and hemicellulosic hydrolysates even
though the pH adjustment and nitrogen source were not provided. As
they presented different fermenting capacities, selection of a host I. orientalis strain was crucial for producing fuels
and chemicals using cellulosic hydrolysates.