Enzymes from Evonik to become poten­tial com­pet­it­ors for petroleum

Research­ers at the spe­cialty chem­ic­als com­pany Evonik Indus­tries, in cooper­a­tion with sci­ent­ists at Graz Uni­ver­sity, have dis­covered a biocata­lyt­ic access to 1‑alkenes such as propene and 1‑butene. Such hydro­car­bon com­pounds are con­sidered as key sub­stances for the chem­ic­al industry’s soph­ist­ic­ated integ­rated pro­duc­tion of high-qual­ity products. For example, Evonik uses propene in the man­u­fac­ture of super­ab­sorb­ents or methion­ine, while 1‑butene serves as a com­pon­ent in many types of poly­ethyl­ene and can be used as a raw mater­i­al for pro­du­cing plas­ti­cizers. Such source mater­i­als have thus far not been typ­ic­ally man­u­fac­tured with the aid of biocata­lys­is. In the opin­ion of lead­ing sci­ent­ists, the expan­sion of bio­tech­no­lo­gic­al pro­cesses to base, bulk and numer­ous spe­cialty chem­ic­als remains a largely unre­solved chal­lenge to this day. Dr. Thomas Haas, head of the Sci­ence & Tech­no­logy unit at Creav­is, Evonik’s stra­tegic innov­a­tion unit, says: ​“If we can suc­ceed in devel­op­ing tech­nic­ally and eco­nom­ic­ally feas­ible solu­tions in this area, we would be able to effi­ciently com­bine bio­tech­no­lo­gic­al and pet­ro­chem­ic­al pro­cesses in the chem­ic­al industry in the form of integ­rated pro­duc­tion for great­er added value.” The industry research­ers and the sci­ent­ists work­ing at Graz Uni­ver­sity under Pro­fess­or Kurt Faber achieved a first break­through when they used nat­ur­ally occur­ring short-chain alkano­ic acids — sat­ur­ated fatty acids pro­duced by bac­teria — as the source mater­i­al for 1‑alkenes. Haas notes: ​“It took the team a year to find an enzyme sys­tem for the optim­al cata­lys­is of con­vert­ing the sat­ur­ated fatty acids to 1‑alkenes, ulti­mately with great suc­cess.” An estab­lished enzyme sys­tem, P450 monooxy­genase OleT, cata­lyzes this chem­ic­al reac­tion — oxid­at­ive decarboxyla­tion of alkano­ic acids to 1‑alkenes — very effi­ciently and sub­strate-spe­cific­ally. Thanks to a cas­cade of two addi­tion­al enzyme sys­tems, the required elec­trons for oxid­a­tion are absorbed from oxy­gen in the air. Haas describes the next steps: ​“We are now work­ing to trans­fer our enzyme com­bin­a­tion to liv­ing cells. How­ever, there is still a lot of work to do before we are ready for industry-scale pro­duc­tion.” Haas and his team are con­sist­ently pur­su­ing the goal of mak­ing renew­able resources usable for the chem­ic­al industry with the help of bio­tech­no­logy pro­cesses. ​“We will only be able to make equal use of fossil and bio­gen­ic raw mater­i­al streams if we can find a way to incor­por­ate bio­tech­no­lo­gic­al pro­cesses into integ­rated chem­ic­al pro­duc­tion. This will help main­tain and expand the industry’s estab­lished and effi­cient value chains,” he explains.

Com­pany information

Evonik, the cre­at­ive indus­tri­al group from Ger­many, is one of the world lead­ers in spe­cialty chem­ic­als. Prof­it­able growth and a sus­tained increase in the value of the com­pany form the heart of Evonik’s cor­por­ate strategy. Its activ­it­ies focus on the key mega­trends health, nutri­tion, resource effi­ciency and glob­al­iz­a­tion. Evonik bene­fits spe­cific­ally from its innov­at­ive prowess and integ­rated tech­no­logy plat­forms. Evonik is act­ive in over 100 coun­tries around the world. In fisc­al 2014 more than 33,000 employ­ees gen­er­ated sales of around €12.9 bil­lion and an oper­at­ing profit (adjus­ted EBITDA) of about €1.9 bil­lion. Source: idw/​Evonik Indus­tries AG