Isobutanol tolerance and production of Saccharomyces cerevisiae can be improved by engineering its TATA‐binding protein Spt15
W Zhang, W Shao, A Zhang - Letters in Applied Microbiology, 2021 - academic.oup.com
… We conducted metabolic engineering of the strains harbouring the YCplac22‐SPT15 and
YCplac22‐spt15‐3 plasmids and used them as platforms for isobutanol production. We …
YCplac22‐spt15‐3 plasmids and used them as platforms for isobutanol production. We …
Engineering Saccharomyces cerevisiae for isoprenol production
… cerevisiae and this work provides the key strategies to engineer yeast as an industrial
platform for isoprenol production. …
platform for isoprenol production. …
Microbial engineering for the production of isobutanol: current status and future directions
NM Lakshmi, P Binod, R Sindhu, MK Awasthi… - …, 2021 - Taylor & Francis
… genetic and metabolic engineering practices adopted to improve the isobutanol production
in … Isobutanol is preferred over bioethanol and n butanol due to its high octane number, less …
in … Isobutanol is preferred over bioethanol and n butanol due to its high octane number, less …
[HTML][HTML] Metabolic engineering of Saccharomyces cerevisiae for the biosynthesis of ethyl crotonate
G Zhang, X Kang, M Xie, M Wei, Y Zhang, Q Li, X Guo… - LWT, 2022 - Elsevier
… In this study, Saccharomyces cerevisiae AY14α was engineered to produce ethyl crotonate.
Firstly, … Recent advances in n-butanol and butyrate production using engineered Clostridium …
Firstly, … Recent advances in n-butanol and butyrate production using engineered Clostridium …
Metabolic engineering strategies toward production of biofuels
… continued effort to produce advanced biofuels with higher efficiencies. In this article,
metabolic engineering strategies recently exploited to enhance biofuel production and facilitate …
metabolic engineering strategies recently exploited to enhance biofuel production and facilitate …
[HTML][HTML] The role of metabolic engineering technologies for the production of fatty acids in yeast
… to obtain a high production of desired products. … produced using metabolic engineering.
However, classical methods used for engineering yeast metabolic pathways for the production of …
However, classical methods used for engineering yeast metabolic pathways for the production of …
[HTML][HTML] Enhancing biofuels production by engineering the actin cytoskeleton in Saccharomyces cerevisiae
H Liu, P Zhou, M Qi, L Guo, C Gao, G Hu… - Nature …, 2022 - nature.com
… induced by n-butanol and MCFAs. Accordingly, n-butanol stress tolerance and production
are enhanced by shortening actin cable tortuosity using an n-butanol responsive promoter-…
are enhanced by shortening actin cable tortuosity using an n-butanol responsive promoter-…
Enhanced isobutanol production by co-production of polyhydroxybutyrate and cofactor engineering
HS Song, JM Jeon, SK Bhatia, TR Choi, SM Lee… - Journal of …, 2020 - Elsevier
… , metabolic engineering was conducted to manipulate the cofactor distribution for the optimal
co-production of … However, in the presence of n-butanol, cell growth was seriously limited or …
co-production of … However, in the presence of n-butanol, cell growth was seriously limited or …
[HTML][HTML] Isobutanol production by combined in vivo and in vitro metabolic engineering
M Gupta, M Wong, K Jawed, K Gedeon… - Metabolic Engineering …, 2022 - Elsevier
… Moreover, several transcriptional analyses were performed previously to study the stress
caused by different alcohols including ethanol, n‐butanol, and isobutanol for E. coli (Gonzalez …
caused by different alcohols including ethanol, n‐butanol, and isobutanol for E. coli (Gonzalez …
[HTML][HTML] Improvement of ethanol and 2,3-butanediol production in Saccharomyces cerevisiae by ATP wasting
… Hence, the synthesis of higher alcohols (n-butanol [8] and 1,3-… the metabolic engineering
strategy of introducing opt_ecoFBPase and ATPase can increase the ethanol production rate in …
strategy of introducing opt_ecoFBPase and ATPase can increase the ethanol production rate in …