Why bac­teria could be the answer to a future without oil

His­tor­ic­ally pet­ro­leum has been used to devel­op the chem­ic­als needed for products such as pesti­cides, food sup­ple­ments and make-up. Although many of the build­ing blocks required to make these chem­ic­als occur nat­ur­ally, try­ing to take those nat­ur­al mater­i­als and use them in large-scale indus­tri­al pro­cesses has proved dif­fi­cult and costly. So pet­ro­leum is used instead. Until recently, oil was seen as a cheap com­mod­ity which was avail­able in abund­ance, so pet­ro­leum was per­fect for use in the chem­ic­al industry. How­ever, the world has changed. We now recog­nise the need to reduce our reli­ance on oil in order to pro­tect the envir­on­ment and main­tain our nation­al secur­ity. There are also health con­cerns over the use of pet­ro­leum in products we eat and apply to our bod­ies. This is why new advanced meth­ods for indus­tri­al bio­tech­no­logy are so import­ant; they are enabling the use of engin­eered bac­teri­al cells, rather than pet­ro­leum, in devel­op­ing chem­ic­als to be used in these products. Import­antly, the bac­teria can be grown on a range of cheap and renew­able resources, even vari­ous kinds of farm­land waste. How­ever, in order to use bac­teria effect­ively – and in a man­ner which can be scaled up by industry – we need to know a lot more about bac­teri­al cell bio­logy. Only by invest­ig­at­ing the machinery and pro­cesses at the heart of cells can we learn how to use them to devel­op organ­ic chem­ic­als in a man­ner that was pre­vi­ously unfeas­ible for industry.

Friendly bac­teria

At New­castle University’s Centre for Bac­teri­al Cell Bio­logy we’ve spent years study­ing Bacil­lus sub­til­is, a bac­teri­um that lives peace­fully in soil or even in the human gut. This organ­ism and its rel­at­ives are very good at mak­ing and secret­ing enzymes which are cata­lysts for all sorts of use­ful pro­cesses. It means Bacilli are already used widely by industry, for example in pro­du­cing the enzymes that are used in bio­lo­gic­al wash­ing powders such as pro­teases (which break down blood, egg and oth­er pro­tein stains) or amyl­ases (which dis­solve starch). How­ever, the range of enzymes they can secrete effi­ciently is much more lim­ited than we would like. Stud­ies on fun­da­ment­al struc­tures and pro­cesses of the bac­teri­um are now begin­ning to give us the abil­ity to engin­eer the cells to secrete a wider range of pro­teins from a diverse range of sources. This means that before long Bacil­lus will be used to make all kinds of enzymes, includ­ing those needed in the chem­ic­al industry to replace pro­cesses presently depend­ent on pet­ro­leum. This is a huge oppor­tun­ity. The European indus­tri­al bio­tech­no­logy industry has an estim­ated annu­al turnover of more than €60 bil­lion, and the glob­al indus­tri­al enzyme mar­ket is pre­dicted to be worth US$7.1 bil­lion by 2018. Deter­gent enzymes alone make up a bil­lion dol­lar busi­ness. How­ever, con­tin­ued reli­ance on oil-based solu­tions will hamper growth and could have sig­ni­fic­ant soci­et­al and envir­on­ment­al con­sequences. Repla­cing pet­ro­leum with bac­teria will have a real impact on people’s lives.

Algae vs sunburn

Sun­cream is a good example. One of the pro­jects we are work­ing on at New­castle is to devel­op organ­ic UV-absorber com­pounds from renew­able mater­i­als to be used in sun­screens. Dam­age from expos­ure to UV radi­ation is a major worry, and there is increas­ing demand for cos­met­ics that block UV rays. The industry relies on oil-based tech­no­logy and inor­gan­ic met­al oxide particles to cre­ate mater­i­als that block UV rays for use in sun­screen. How­ever, we know that pho­to­syn­thet­ic bac­teria called cyanobac­teria that grow in the sea make their own organ­ic sun­screen molecules. By tak­ing the rel­ev­ant genes from cyanobac­teria and trans­plant­ing them into a bac­teri­um that is already widely used in chem­ic­al pro­duc­tion, we hope to be able to change this. If we are suc­cess­ful, the pro­cess could eas­ily be scaled up so the cos­met­ics industry will be able to devel­op cheap organ­ic sun­screen. This is just one example of the way in which bac­teria could sup­port a future without oil. Work is already in pro­gress to explore the poten­tial of using waste to grow bac­teria or oth­er micro-organ­isms that could make chem­ic­als such as eth­an­ol for use as ​“bio­fuel” for cars and aero­planes, fur­ther redu­cing the use of oil. There is a lot of work still to be done to make this vis­ion a real­ity, but by con­tinu­ing to invest­ig­ate how bac­teri­al cells work and how they could be used in chem­ic­al pro­duc­tion we can see a future in which waste becomes energy and we can live without oil. This art­icle was ori­gin­ally pub­lished on The Con­ver­sa­tion. Read the ori­gin­al art­icle. By Jeff Erring­ton, New­castle University