Evolutionary Engineering of Microorganisms to Overcome Toxicity During Lignocellulose Hydrolysates Utilization

“…These mutations enable the adapted cell to move back towards the pre-inhibited physiological state. Specific tolerance responses have been shown to be more energy efficient than global stress responses ( Lastiri-Pancardo and Utrilla, 2017 ). In contrast, ALE control experiments of the BS168 xyl and KO7s xyl backgrounds displayed a more constant increase in growth rate ( Fig.…”

“…The development of microbial strains with increased tolerance has the potential to minimize the degree of detoxification required. Unfortunately, tolerance is a complex trait, involving the coordinated action of hundreds of genes ( Lastiri-Pancardo and Utrilla, 2017 ). As biomass hydrolysates contain a plethora of different toxic compounds, rational design is challenging due to the lack of prerequisite knowledge.…”

Adaptive laboratory evolution of Bacillus subtilis to overcome toxicity of lignocellulosic hydrolysate derived from Distiller's dried grains with solubles (DDGS)

“…These mutations enable the adapted cell to move back towards the pre-inhibited physiological state. Specific tolerance responses have been shown to be more energy efficient than global stress responses ( Lastiri-Pancardo and Utrilla, 2017 ). In contrast, ALE control experiments of the BS168 xyl and KO7s xyl backgrounds displayed a more constant increase in growth rate ( Fig.…”

“…The development of microbial strains with increased tolerance has the potential to minimize the degree of detoxification required. Unfortunately, tolerance is a complex trait, involving the coordinated action of hundreds of genes ( Lastiri-Pancardo and Utrilla, 2017 ). As biomass hydrolysates contain a plethora of different toxic compounds, rational design is challenging due to the lack of prerequisite knowledge.…”

Adaptive laboratory evolution of Bacillus subtilis to overcome toxicity of lignocellulosic hydrolysate derived from Distiller's dried grains with solubles (DDGS)

Bioremediation through microbes: systems biology and metabolic engineering approach