Mak­ing fuels and house­hold chem­ic­als from sugar

Writ­ing in PNAS, the research­ers have shown that the emer­ging field of syn­thet­ic bio­logy can be used to manip­u­late hydro­car­bon chem­ic­als, found in soaps and sham­poos, in cells. This devel­op­ment, dis­covered with col­leagues at the Uni­ver­sity of Turku in Fin­land, could mean fuel for cars or house­hold power sup­plies could be cre­ated from nat­ur­ally-occur­ring fatty acids. The research­ers, led by Pro­fess­or Nick Turn­er from The Uni­ver­sity of Manchester, used syn­thet­ic bio­logy to hijack the nat­ur­ally-exist­ing fatty acids and dir­ect those fatty molecules towards the pro­duc­tion of ready-to-use fuel and house­hold chem­ic­als. Hydro­car­bon chem­ic­als are every­where in our daily lives; as fra­grance in soap, thicken­er in sham­poo and fuel in the car. Their num­ber of car­bons and wheth­er they are acid, alde­hyde, alco­hol or alkane are import­ant para­met­ers that influ­ence how tox­ic they are to bio­lo­gic­al organ­isms, the poten­tial for fuel and their olfact­ory per­cep­tion as aroma com­pounds. The break­through allows research­ers to fur­ther explore how to cre­ate renew­able energy from sus­tain­able sources, and the advance could lead to more innov­at­ive ways of sourcing fuel from nat­ur­al resources. Syn­thet­ic bio­logy is an area of bio­lo­gic­al research and tech­no­logy that com­bines sci­ence and engin­eer­ing for the bene­fit of soci­ety. Sig­ni­fic­ant advances have been made in this field in recent years. Pro­fess­or Turn­er said: ​“In our labor­at­or­ies in Manchester we cur­rently work with many dif­fer­ent biocata­lysts that cata­lyse a range of chem­ic­al reac­tions – the key is to match up the cor­rect biocata­lyst with the spe­cif­ic product you are try­ing to make. Biocata­lysts recog­nise molecules in the way that a lock recog­nises a key – they have to fit per­fectly togeth­er to work. Some­time we redesign the lock so that if can accept a slightly dif­fer­ent key allow­ing us to make even more inter­est­ing products.” ​“In this example we need to make sure that the fatty acid start­ing mater­i­als would be a per­fect match for the biocata­lysts that we dis­covered and developed in our labor­at­or­ies. As with many lead­ing areas of sci­ence today, in order to make major break­throughs it is neces­sary for two or more labor­at­or­ies around the world to come togeth­er to solve chal­len­ging prob­lems.”

Notes for editors

The paper, Carboxyl­ic acid reductase is a ver­sat­ile enzyme for the con­ver­sion of fatty acids into fuels and chem­ic­al com­mod­it­ies, by M. Kalim Akhtar, Nich­olas J. Turn­er, and Pat­rik R. Jones, is avail­able on request from the Press Office. Pro­fess­or Turn­er is avail­able for inter­view on request. Source: The Uni­ver­sity of Manchester