Press Release
Professor engineers E. coli to produce biodiesel
Friday, September 3, 2010
E. coli (Credit: NIAID)
One mention of E. coli conjures images of sickness and food poisoning, but the malevolent bacteria may also be the key to the future of renewable energy.
Desmond Lun, an associate professor of computer science at Rutgers University–Camden, is researching how to alter the genetic makeup of E. coli to produce biodiesel fuel derived from fatty acids.
"If we can engineer biological organisms to produce biodiesel fuels, we'll have a new way of storing and using energy," Lun says.
Creating renewable energy by making fuels, like making ethanol out of corn, has been a common practice in trying to achieve sustainability.
However, Lun says, "It's widely acknowledged that making fuel out of food sources is not very sustainable. It's too expensive and it competes with our food sources."
One alternative is to modify the E. coli microorganism to make it overproduce fatty acids, which are used to make biodiesel.
"Fatty acid molecules aren't that different from a lot of fuel molecules," says Lun, a Philadelphia resident. "Biodiesel is something that we can generate quite easily. E. coli has been used as a lab organism for more than 60 years and it's well-studied. We know a lot about its genetics and how to manipulate it. We've got to make quite drastic changes to do it and it requires major intervention."
That's where Lun's computer science expertise comes in. Lun builds computational models of the E. coli organisms to determine what would happen if changes are made. Those changes could include removing enzymes to enhance fatty acid production.
"We call it synthetic biology," he says. "It's sort of the next stage of genetic engineering. Instead of making small changes to specific genes, we're really modifying large sections of genome. We're putting in entirely new traits rather than modifying existing traits."
Lun explains, "The unique aspect of my work is this emphasis on computational modeling as a way of guiding it. Even these simple bacteria are immensely complex. Computational modeling can offer a way to speed up the process and make it a faster, better process."
Fatty acid production in the altered bacteria would be enhanced, paving the way for biofuel development.
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Rutgers University: http://www.rutgers.edu
E. coli (Credit: NIAID)
Desmond Lun, an associate professor of computer science at Rutgers University–Camden, is researching how to alter the genetic makeup of E. coli to produce biodiesel fuel derived from fatty acids.
"If we can engineer biological organisms to produce biodiesel fuels, we'll have a new way of storing and using energy," Lun says.
Creating renewable energy by making fuels, like making ethanol out of corn, has been a common practice in trying to achieve sustainability.
However, Lun says, "It's widely acknowledged that making fuel out of food sources is not very sustainable. It's too expensive and it competes with our food sources."
One alternative is to modify the E. coli microorganism to make it overproduce fatty acids, which are used to make biodiesel.
"Fatty acid molecules aren't that different from a lot of fuel molecules," says Lun, a Philadelphia resident. "Biodiesel is something that we can generate quite easily. E. coli has been used as a lab organism for more than 60 years and it's well-studied. We know a lot about its genetics and how to manipulate it. We've got to make quite drastic changes to do it and it requires major intervention."
That's where Lun's computer science expertise comes in. Lun builds computational models of the E. coli organisms to determine what would happen if changes are made. Those changes could include removing enzymes to enhance fatty acid production.
"We call it synthetic biology," he says. "It's sort of the next stage of genetic engineering. Instead of making small changes to specific genes, we're really modifying large sections of genome. We're putting in entirely new traits rather than modifying existing traits."
Lun explains, "The unique aspect of my work is this emphasis on computational modeling as a way of guiding it. Even these simple bacteria are immensely complex. Computational modeling can offer a way to speed up the process and make it a faster, better process."
Fatty acid production in the altered bacteria would be enhanced, paving the way for biofuel development.
###
Rutgers University: http://www.rutgers.edu
Thanks to Rutgers University for this article.
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Comments
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Sun, Sep 05, 2010, 10:47 am CDT
One mention of E. coli conjures images of sickness and food poisoning, but the malevolent bacteria may also be the key to the future of renewable energy.
We should really keep in mind that E. coli is a completely benevolent bacteria, which lives in our body as a harmless commensal and serves as a useful cloning tool in science. There are some "pathogenic E. coli" strains, but these strains are as genetically distant from "E. coli" as the food-poisoning bugs Salmonella and Shigella. Not only is the usage of "E. coli" as a catch-all inaccurate, but it puts a bad face on a very useful and innocent little bug.
We should really keep in mind that E. coli is a completely benevolent bacteria, which lives in our body as a harmless commensal and serves as a useful cloning tool in science. There are some "pathogenic E. coli" strains, but these strains are as genetically distant from "E. coli" as the food-poisoning bugs Salmonella and Shigella. Not only is the usage of "E. coli" as a catch-all inaccurate, but it puts a bad face on a very useful and innocent little bug.
Sun, Sep 05, 2010, 5:42 pm CDT
The biggest thing to keep in mind is that there are very few pathogenic stains of e. Coli. E. Colin have probably saved more lives than killed AND our GI tract is full of the harmless variety!
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