With NASAsCuriosity Rover safely on Mars and ready to search for signs of life, back on Earth attempts are underway to engineer bacteria that could thrive on the Red Planet. <\/p>\n
A team of undergraduates from Stanford and Brown Universities are busy applying synthetic biology to space exploration, outfitting microbes to survive extreme Martian conditions and produce resources needed to sustain a human colony. <\/p>\n
Though Mars is potentially a place where life may have survived at some point, it is not an especially friendly environment, and thriving there will not be easy for humans or microbes. The average surface temperature of Mars is minus 80 degrees Fahrenheit, and the almost-nonexistent atmosphere is 95 percent carbon dioxide. Although water exists in Mars ice caps and theres some evidence that giant oceans once coveredthe planet, today its essentially a deep-frozen desert. Colonizing Mars would be challenging and pricey. <\/p>\n
Obviously, bringing up heavy machinery or building materials is going to be really expensive,said Brown student and team captain Ben Geilich. The benefit of having bacteria that can do this for you is theyre really small and very light. Once there, they could grow food, produce medicine, extract minerals, and build building material. <\/p>\n
The project is part of the International Genetically Engineered Machines (iGEM) challenge, an annual synthetic biology competition that pits students around the world against each other in attempts to ingeniously hack living cells to perform new tasks. In a regional iGEM meet in October, Geilichs team will present what they call aHell Cell, asuite of genetically engineered parts that could enable a bacterium to withstand severe cold, dryness and radiation. Geilich calls it a genetic box of crayons for extremophile conditions. <\/p>\n
In the Stanford-Brown iGEM lab, students work on designing bacteria that could survive on Mars. (Lynn Rothschild) <\/p>\n
The Hell Cell includes genetic modules, or BioBricks, based on DNA from a variety of ultra-tough organisms, including a cold-resistant species of Siberian beetle that makes antifreeze proteins, aradiation-resistant bacterium that sequesters large amounts of the element manganese, andE. coli, which produces a nutrient that confers cold and drought resistance. The team is also investigating heat- and acid-tolerance mechanisms that could be useful in other planetary environments. <\/p>\n
While theyre currently experimenting with E. coli, BioBricks can be mixed and matched in other species, tailoring new strains to particular conditions. You go into nature and find genes, and then you can recombine them into circuits that you cannot find in nature, explained Andre Burnier, one of the teams mentorsand a lab technician at NASAs Ames Research Center. <\/p>\n
To be really successful, the bacteria must do more than just survive on Mars. They need to perform functions usefulfor establishing a human colony one day. In addition to the Hell Cell suite, the team is developing bacteria that could extract minerals from Martian sediment or recycle rare metals from spacecraft electronics. <\/p>\n
The teams main focus is on the latter,which requires engineering bacteria to separate metals from the silica that coats most electronics. <\/p>\n<\/p>\n
See the original post: With NASAsCuriosity Rover safely on Mars and ready to search for signs of life, back on Earth attempts are underway to engineer bacteria that could thrive on the Red Planet. A team of undergraduates from Stanford and Brown Universities are busy applying synthetic biology to space exploration, outfitting microbes to survive extreme Martian conditions and produce resources needed to sustain a human colony. Continue reading
\nEngineering Life to Survive on Mars and Aid Human Colonization<\/a><\/p>\n","protected":false},"excerpt":{"rendered":"