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In an effort to explain how life started on Earth billions of years ago, some scientists have suggested that microbes \u2014 or perhaps the organic building blocks of life<\/a> \u2014 may have hitched a ride<\/a> while clinging to space dust, asteroids, comets, or planetoids.<\/p>\n The hypothesis, dubbed panspermia, raises the possibility that the earliest forms of life may have originated on other planets, including perhaps Mars, which scientists believe may have once been covered in oceans, lakes, and rivers<\/a>. A sub-theory, dubbed lithopanspermia, holds that asteroid strikes on other planets may have dislodged surface material back into orbit, allowing microorganisms embedded within the debris to eventually make it to Earth.<\/p>\n It\u2019s an intriguing idea, but proving it is exceedingly difficult. In an effort to push things along \u2014 and satisfy their curiosity \u2014 Johns Hopkins University asteroid impact expert KT Ramesh and his colleagues gathered experimental data exploring whether bacteria could survive a journey between planets via an asteroid strike.<\/p>\n As detailed in a new paper<\/a> published in the journal The Proceedings of the National Academy of Sciences NEXUS, the team found that an \u201cextremophile\u201d microorganism dubbed Deinococcus radiodurans, a bacterium that has previously been shown to be resistant to the extreme conditions of space, could indeed survive \u201ccontrolled extreme pressures\u201d simulating asteroid impacts.<\/p>\n Even after being blasted with 24,000 times the atmospheric pressure exerted by a steel plate while sandwiched between two more steel plates, an astonishing 60 percent of tiny organisms survived. At even more extreme pressures of 30,000 times atmospheric pressure, just under ten percent of the bacteria still managed to survive.<\/p>\n \u201cThe work has significant consequences for considerations of planetary protection, spacecraft mission design, our understanding of where we might find extraterrestrial life, and lithopanspermia,\u201d the authors concluded.<\/p>\n Despite Deinococcus radiodurans being known to be able to self-repair<\/a>, survive extreme dehydration<\/a>, and cope with copious amounts of radiation<\/a>, the results surprised the researchers.<\/p>\n \u201cWe didn\u2019t know what to expect,\u201d coauthor and Johns Hopkins University doctoral student Lily Zhao told the New York Times<\/a>. \u201cWe would have been excited to see one percent survival, honestly.\u201d<\/p>\n The team was unable to determine at which pressures all of the microorganisms would\u2019ve died after running into the limits of their experimental apparatus.<\/p>\n \u201cThe metals were failing and fracturing before the cells,\u201d Zhao said.<\/p>\n Of course, the jury is still out whether there even are, let alone were, microorganisms on Mars. Despite our best efforts, evidence of life on the planet remains elusive. But if they are there, it\u2019s looking like an asteroid strike could have dislodged some of these microbes and seeded the Earth billions of years ago.<\/p>\n The team is now hoping to expose other microorganisms, including fungi, to similar scenarios. They\u2019re hopeful others will also survive the ordeal.<\/p>\n \u201cLife is always hardier than we expect it to be,\u201d Zhao told the NYT.<\/p>\n