Microbe pro­duces eth­an­ol from switch­grass without pretreatment

The con­ven­tion­al strategy for pro­du­cing eth­an­ol from plant bio­mass requires costly pre­treat­ment and enzyme-driv­en reac­tions. Refin­ing anoth­er strategy known as con­sol­id­ated biopro­cessing (CPB) could reduce costs. In second-gen­er­a­tion CPB, a microor­gan­ism splits of water and fer­ments the products to eth­an­ol, redu­cing the cost. Now, sci­ent­ists engin­eered a strain of a CBP bac­teri­um called Caldi­cel­lu­losiruptor bescii that effi­ciently breaks down bio­mass without pre­treat­ment. The microbe pro­duces eth­an­ol, demon­strat­ing the suc­cess­ful con­ver­sion of switch­grass cel­lu­losic bio­mass.

The Impact

Dir­ect con­ver­sion of bio­mass to eth­an­ol without pre­treat­ment rep­res­ents a new paradigm for CPB, offer­ing the poten­tial for car­bon-neut­ral, cost-effect­ive, and sus­tain­able bio­fuel pro­duc­tion.

Sum­mary

Pro­du­cing eth­an­ol from plant bio­mass typ­ic­ally requires three major steps: physi­co­chem­ic­al pre­treat­ment, enzymat­ic break­down of bio­mass into its con­stitu­ent sug­ars, and fer­ment­a­tion. Pre­treat­ment and enzymat­ic hydro­lys­is are costly steps in the pro­cess. CBP could reduce costs. In CBP, unpre­treated cel­lu­losic bio­mass is con­ver­ted to a bio­fuel in a single pro­cess by a microbe that breaks down the bio­mass and fer­ments the res­ult­ing sug­ars. Caldi­cel­lu­losiruptor bescii had been shown to fer­ment untreated switch­grass, but it lacked the genes to make eth­an­ol. Because C. bescii is a ther­mo­phile (heat lov­ing) and CBP is car­ried out at elev­ated tem­per­at­ures, a gene for a heat-stable enzyme enabling eth­an­ol syn­thes­is was needed. Research­ers iden­ti­fied a can­did­ate gene in Clostridi­um ther­mo­cel­lum and cloned it into C. bescii. The engin­eered strain of C. bescii was then able to pro­duce eth­an­ol from cel­lo­bi­ose, Avicel, and switch­grass. To optim­ize eth­an­ol fer­ment­a­tion, two genes were deleted that would oth­er­wise divert fer­ment­a­tion products. In this new C. bescii strain, roughly 30% of bio­mass was fer­men­ted, and 1.7 moles of eth­an­ol were pro­duced for each mole of gluc­ose, an amount close to the the­or­et­ic­al 2.0 moles of eth­an­ol per mole of gluc­ose. Although effi­cien­cies can be fur­ther improved, this study is an import­ant step in real­iz­ing the poten­tial of CBP and provides a plat­form for engin­eer­ing the pro­duc­tion of advanced bio­fuels and oth­er bioproducts dir­ectly from cel­lu­losic bio­mass without harsh and expens­ive pre­treat­ment. This research was con­duc­ted by the BioEn­ergy Sci­ence Cen­ter, a U.S. Depart­ment of Energy (DOE) Bioen­ergy Research Cen­ter sup­por­ted by the Office of Bio­lo­gic­al and Envir­on­ment­al Research with­in DOE’s Office of Sci­ence.

Pub­lic­a­tions

D. Chung, M. Cha, A. M. Guss, J. West­ph­el­ing. Dir­ect con­ver­sion of plant bio­mass to eth­an­ol by engin­eered Caldi­cel­lu­losiruptor bescii. Pro­ceed­ings of the Nation­al Academy of Sci­ences, 2014; 111 (24): 8931 DOI: 10.1073/pnas.1402210111 Source: US Depart­ment of Energy