Friday, September 2, 2011Good morning,
Scientists have long known how to turn trees into ethanol, but doing it profitably is another matter. The problem is cellulose. Found in plant cell walls, cellulose is the most abundant naturally occurring organic molecule on the planet, a potentially limitless source of energy. But it's a tough molecule to break down.
There are two complicated steps: first, introducing enzymes, called cellulases, to break the cellulose down into glucose and xylose; and second, using yeast and other microorganisms to ferment those sugars into ethanol.
Today's cellulases are the enzyme equivalent of vacuum tubes: clunky, slow, and expensive. But what if there were some miracle, enzyme-producing microorganism out there that could revolutionize the process, making it efficient and cheap?
Enter panda poop.
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Thanks for reading,
Your Living Green editor
Email the Editor***Bacteria found in Panda droppings could lead to a major new source of "biofuels" produced but from grass, wood chips and crop wastes, U.S. researchers say.
Scientists have long known that bacteria in the digestive systems of giant pandas are particularly effective at breaking down cellulose in plants into nutrients, as tough-to-digest bamboo constitutes about 99 percent of a giant panda's diet in the wild.
However, until the energy crunch raised interest in biofuels, there was little interest in determining exactly what microbes were involved in panda digestion.
"Who would have guessed that 'panda poop' might help solve one of the major hurdles to producing biofuels, which is optimizing the breakdown of the raw plant materials used to make the fuels?" study co-author Ashli Brown. said "We hope our research will help expand the use of biofuels in the future and help cut dependency on foreign oil. We also hope it will reinforce the importance of wildlife conservation."
Brown estimated the panda gut bacteria can, under certain conditions, convert about 95 percent of plant biomass into simple sugars, using bacteria enzymes so powerful they can eliminate the need for high heat, harsh acids and high pressures currently used in biofuel production processes.