<p> Scientists, including one of Indian-origin, have engineered a strain of bacteria that enables a "one-pot" method for producing advanced biofuels from a slurry of pre-treated plant material.<br /><br /></p>.<p>The Escherichia coli (E coli) is able to tolerate the liquid salt used to break apart plant biomass into sugary polymers, researchers said.<br /><br />Since the salt solvent, known as ionic liquids, interferes with later stages in biofuels production, it needs to be removed before proceeding, a process that takes time and money. Developing ionic-liquid-tolerant bacteria eliminates the need to wash away the residual ionic liquid.<br /><br />The achievement is a critical step in making biofuels a viable competitor to fossil fuels because it helps streamline the production process, researchers said.<br /><br />"Being able to put everything together at one point, walk away, come back, and then get your fuel, is a necessary step in moving forward with a biofuel economy," said Aindrila Mukhopadhyay from the US Department of Energy's Lawrence Berkeley National Laboratory.<br /><br />"The E coli we have developed gets us closer to that goal. It is like a chassis that we build other things onto, like the chassis of a car," said said Mukhopadhyay.<br /><br />"It can be used to integrate multiple recent technologies to convert a renewable carbon source like switchgrass to an advanced jet fuel," she said.<br /><br />The basic steps of biofuel production start with deconstructing the cellulose, hemicellulose and lignin that are bound together in the complex plant structure.<br />Enzymes are then added to release the sugars from that gooey mixture of cellulose and hemicellulose, a step called saccharification.<br /><br />Bacteria can then take that sugar and churn out the desired biofuel. The multiple steps are all done in separate pots.<br /><br />Researchers pioneered the use of ionic liquids, salts that are liquid at room temperature, to tackle the deconstruction of plant material because of the efficiency with which the solvent works.<br /><br />However, what makes ionic liquids great for deconstruction also makes it harmful for the downstream enzymes and bacteria used in biofuel production.<br /><br />They established that an amino acid mutation in the gene rcdA, which helps regulate various genes, leads to an E coli strain that is highly tolerant to ionic liquids.<br /><br />They used this strain as the foundation to build on earlier work - including the ionic-liquid-tolerant enzymes - and take the steps further to the one-pot biofuel finishing line.<br />The findings were published in the journal Green Chemistry.</p>
<p> Scientists, including one of Indian-origin, have engineered a strain of bacteria that enables a "one-pot" method for producing advanced biofuels from a slurry of pre-treated plant material.<br /><br /></p>.<p>The Escherichia coli (E coli) is able to tolerate the liquid salt used to break apart plant biomass into sugary polymers, researchers said.<br /><br />Since the salt solvent, known as ionic liquids, interferes with later stages in biofuels production, it needs to be removed before proceeding, a process that takes time and money. Developing ionic-liquid-tolerant bacteria eliminates the need to wash away the residual ionic liquid.<br /><br />The achievement is a critical step in making biofuels a viable competitor to fossil fuels because it helps streamline the production process, researchers said.<br /><br />"Being able to put everything together at one point, walk away, come back, and then get your fuel, is a necessary step in moving forward with a biofuel economy," said Aindrila Mukhopadhyay from the US Department of Energy's Lawrence Berkeley National Laboratory.<br /><br />"The E coli we have developed gets us closer to that goal. It is like a chassis that we build other things onto, like the chassis of a car," said said Mukhopadhyay.<br /><br />"It can be used to integrate multiple recent technologies to convert a renewable carbon source like switchgrass to an advanced jet fuel," she said.<br /><br />The basic steps of biofuel production start with deconstructing the cellulose, hemicellulose and lignin that are bound together in the complex plant structure.<br />Enzymes are then added to release the sugars from that gooey mixture of cellulose and hemicellulose, a step called saccharification.<br /><br />Bacteria can then take that sugar and churn out the desired biofuel. The multiple steps are all done in separate pots.<br /><br />Researchers pioneered the use of ionic liquids, salts that are liquid at room temperature, to tackle the deconstruction of plant material because of the efficiency with which the solvent works.<br /><br />However, what makes ionic liquids great for deconstruction also makes it harmful for the downstream enzymes and bacteria used in biofuel production.<br /><br />They established that an amino acid mutation in the gene rcdA, which helps regulate various genes, leads to an E coli strain that is highly tolerant to ionic liquids.<br /><br />They used this strain as the foundation to build on earlier work - including the ionic-liquid-tolerant enzymes - and take the steps further to the one-pot biofuel finishing line.<br />The findings were published in the journal Green Chemistry.</p>