UCLA engin­eers devel­op new meta­bol­ic path­way to more effi­ciently con­vert sug­ars into biofuels

The new path­way is inten­ded to replace the nat­ur­al meta­bol­ic path­way known as gly­co­lys­is, a series of chem­ic­al reac­tions that nearly all organ­isms use to con­vert sug­ars into the molecu­lar pre­curs­ors that cells need. Gly­co­lys­is con­verts four of the six car­bon atoms found in gluc­ose into two-car­bon molecules known acet­yl-CoA, a pre­curs­or to bio­fuels like eth­an­ol and butan­ol, as well as fatty acids, amino acids and phar­ma­ceut­ic­als. How­ever, the two remain­ing gluc­ose car­bons are lost as car­bon diox­ide. Gly­co­lys­is is cur­rently used in biore­finies to con­vert sug­ars derived from plant bio­mass into bio­fuels, but the loss of two car­bon atoms for every six that are input is seen as a major gap in the effi­ciency of the pro­cess. The UCLA research team’s syn­thet­ic gly­co­lyt­ic path­way con­verts all six gluc­ose car­bon atoms into three molecules of acet­yl-CoA without los­ing any as car­bon diox­ide. The research is pub­lished online Sept. 29 in the peer-reviewed journ­al Nature. The prin­cip­al invest­ig­at­or on the research is James Liao, UCLA’s Ral­ph M. Par­sons Found­a­tion Pro­fess­or of Chem­ic­al Engin­eer­ing and chair of the chem­ic­al and bio­molecu­lar engin­eer­ing depart­ment. Igor Bogorad, a gradu­ate stu­dent in Liao’s labor­at­ory, is the lead author. ​“This path­way solved one of the most sig­ni­fic­ant lim­it­a­tions in bio­fuel pro­duc­tion and biore­fin­ing: los­ing one-third of car­bon from car­bo­hydrate raw mater­i­als,” Liao said. ​“This lim­it­a­tion was pre­vi­ously thought to be insur­mount­able because of the way gly­co­lys­is evolved.”

The syn­thet­ic path­way uses enzymes found in sev­er­al dis­tinct path­ways in nature

The team first tested and con­firmed that the new path­way worked in vitro. Then, they genet­ic­ally engin­eered E. coli bac­teria to use the syn­thet­ic path­way and demon­strated com­plete car­bon con­ser­va­tion. The res­ult­ing acet­yl-CoA molecules can be used to pro­duce a desired chem­ic­al with high­er car­bon effi­ciency. The research­ers dubbed their new hybrid path­way non-oxid­at­ive gly­co­lys­is, or NOG. ​“This is a fun­da­ment­ally new cycle,” Bogorad said. ​“We rerouted the most cent­ral meta­bol­ic path­way and found a way to increase the pro­duc­tion of acet­yl-CoA. Instead of los­ing car­bon atoms to CO₂, you can now con­serve them and improve your yields and pro­duce even more product.” The research­ers also noted that this new syn­thet­ic path­way could be used with many kinds of sug­ars, which in each case have dif­fer­ent num­bers of car­bon atoms per molecule, and no car­bon would be wasted. ​“For biore­fin­ing, a 50 per­cent improve­ment in yield would be a huge increase,” Bogorad said. ​“NOG can be a nice plat­form with dif­fer­ent sug­ars for a 100 per­cent con­ver­sion to acet­yl-CoA. We envi­sion that NOG will have wide-reach­ing applic­a­tions and will open up many new pos­sib­il­it­ies because of the way we can con­serve car­bon.” The research­ers also sug­gest this new path­way could be used in bio­fuel pro­duc­tion using pho­to­syn­thet­ic microbes.

Ori­gin­al publication:

Igor W. Bogorad, Tzu-Shy­ang Lin, James C. Liao. Syn­thet­ic non-oxid­at­ive gly­co­lys­is enables com­plete car­bon con­ser­va­tion. Nature, 2013; DOI: 10.1038/nature12575 Source: Uni­ver­sity of California