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01:15 - Source: CNN
CNN  — 

The surface of Mars is a harsh frozen desert, but some microbes from Earth could temporarily survive there, according to a new study. And the researchers didn’t even have to send microbes to Mars to find out.

The two planets may not seem very similar, but our stratosphere – a layer of the atmosphere 20 miles above the Earth’s surface – has some qualities in common with Mars. Our home planet’s stratosphere experiences low air pressure and high levels of radiation, and it’s dry and cold – much like the surface of the red planet.

Using the MARSBOx, or the Microbes in Atmosphere for Radiation, Survival and Biological Outcomes Experiment, scientists at NASA and the German Aerospace Center collaborated to send four types of microbes into the stratosphere on a balloon.

The study published Monday in the journal Frontiers in Microbiology.

“If a microbe can hack it up there, above much of the protective ozone layer, it just might be able to survive – however briefly – on a journey to the surface of Mars,” said study coauthor David J. Smith, MARSBOx co-principal investigator and researcher at NASA’s Ames Research Center, in a statement.

Microbes, or microorganisms, have an expansive reach on Earth. It’s estimated that there are 1 trillion species of them on our planet. They can also be found living in harsh environments under varying extreme conditions.

Scientists at NASA need to know if these microbes could survive on Mars as they continue to send robotic explorers to the red planet on behalf of humans. That’s why the mission teams behind these rovers, like the recently landed Perseverance rover, take the cleanliness of these machines very seriously before they’re launched to Mars.

Perseverance is the cleanest yet. It’s searching for signs of ancient life on Mars, and microbes from Earth could present a false positive during this search, or they could contaminate our planetary neighbor.

To test the likelihood of microbe survival on Mars, the research team placed millions of microbes, including dried and dormant fungal and bacteria spores representing four species of microorganisms, on quartz discs. These discs were placed inside aluminum boxes designed by the study collaborators at the German Aerospace Center.

The MARSBOx took flight in September 2019. Its door rotated open, exposing samples of four different types of microorganisms to the extreme environmental conditions of the Earth's stratosphere.

A mixture of gases similar to those in the Martian atmosphere, which is dominated by carbon dioxide, was pumped into the boxes. A large science balloon carrying the experiment was released from Fort Sumner, New Mexico, on September 23, 2019.

Shutters were used to help shield the microbes from the sun during ascent and descent. But once they reached the Earth’s stratosphere 24 miles up, the shutters opened and exposed them to the harsh radiation there. The microbes were exposed to this for more than five hours, along with temperatures averaging negative 20 degrees Fahrenheit.

In the stratosphere, there is a thousand times less pressure than we experience at sea level, as well as very dry air.

When the experiment returned to the ground, the scientists determined that two of the four species survived the journey, proving that these two could temporarily endure the harsh conditions of Earth’s stratosphere and, potentially, the Martian surface.

“This research gives us a better understanding of which microbes could linger in environments once assumed to be lethal, like the surface of Mars, and gives us clues about how to avoid unintentionally bringing tiny hitchhikers with us to off-world destinations,” said study coauthor Ralf Moeller, MARSBOx co-principal investigator and head of the Aerospace Microbiology Research Group at the German Aerospace Center, in a statement.

The surviving species included Staphylococcus capitis and Salinisphaera shabanensis. The first is a bacteria associated with human skin and the second is a bacteria that can be found in deep-sea brine pools.

Aspergillus niger, a fungus that is used in the production of antibiotics, was dried to send it on the experiment, and it was also able to be revived once it returned from Earth’s stratosphere.