Advances in microbial metabolic engineering for the production of butanol isomers (isobutanol and 1-butanol) from a various biomass

“…Aldehyde dehydrogenase is used in the Ehrlich pathway, however, to transform 2ketoisovalerate, a by-product of valine biosynthesis, into isobutanol. In essence, the Ehrlich route in S. cerevisiae uses 2-ketoisovalerate as a precursor molecule to produce isobutanol [39,40]. Despite the possibility of producing 1butanol using S. cerevisiae, little has been done to completely understand its cellular metabolism.…”

“…Similar to E. coli and Clostridium species, S. cerevisiae may synthesize butanol. various metabolic approaches have been applied to S. cerevisiae for production of two main isomers of butanol such as Iso-butanol and 1-butanol [40].…”

“…Since many different biomolecules require acetoacetyl-CoA as a precursor, foreign genes must be expressed to create heterologous enzymes that can convert acetoacetyl-CoA into 1-butanol. [40]. In their first attempt, Steen and his team successfully produced 1-butanol in S. cerevisiae by expressing isoenzymes from multiple sources to construct the 1butanol pathway.…”

Metabolic engineering of Saccharomyces cerevisiae for ethanol and butanol biofuel production

“…Aldehyde dehydrogenase is used in the Ehrlich pathway, however, to transform 2ketoisovalerate, a by-product of valine biosynthesis, into isobutanol. In essence, the Ehrlich route in S. cerevisiae uses 2-ketoisovalerate as a precursor molecule to produce isobutanol [39,40]. Despite the possibility of producing 1butanol using S. cerevisiae, little has been done to completely understand its cellular metabolism.…”

“…Similar to E. coli and Clostridium species, S. cerevisiae may synthesize butanol. various metabolic approaches have been applied to S. cerevisiae for production of two main isomers of butanol such as Iso-butanol and 1-butanol [40].…”

“…Since many different biomolecules require acetoacetyl-CoA as a precursor, foreign genes must be expressed to create heterologous enzymes that can convert acetoacetyl-CoA into 1-butanol. [40]. In their first attempt, Steen and his team successfully produced 1-butanol in S. cerevisiae by expressing isoenzymes from multiple sources to construct the 1butanol pathway.…”

Metabolic engineering of Saccharomyces cerevisiae for ethanol and butanol biofuel production

“…26 Microbial engineering has been extensively applied to enhance isobutanol production and increase the yields and titers obtained by different microorganisms, such as S. cerevisiae , 27–30 Escherichia coli , 31–33 and many others. 34–43…”

“…26 Microbial engineering has been extensively applied to enhance isobutanol production and increase the yields and titers obtained by different microorganisms, such as S. cerevisiae, [27][28][29][30] Escherichia coli, [31][32][33] and many others. [34][35][36][37][38][39][40][41][42][43] Different feedstocks have been used to produce isobutanol using these microorganisms. Atsumi et al engineered E. coli bacteria to produce 22 g L −1 of isobutanol from glucose.…”

High yield co-production of isobutanol and ethanol from switchgrass: experiments, and process synthesis and analysis

Advances in Microbial Metabolic Engineering for Increased Biobutanol Production