Study shows sending microbes to Earth’s stratosphere, to test their endurance to Martian conditions, can reveal their potential use and threats to space travel.
Some microbes from Earth could temporarily survive on Mars, finds a new study by NASA and German Aerospace Center scientists. The researchers launched these small lifeforms into Earth’s stratosphere, which replicates key characteristics of the Martian environment, and found that some microorganisms, in particular spores of black mold, survived the trip. This new way of testing endurance to space travel will be invaluable for understanding the threats and opportunities of microbes in future missions to Mars.
Some microbes on Earth could temporarily survive on the surface of Mars, finds a new study by NASA and German Aerospace Center scientists. The researchers tested the endurance of microorganisms to Martian conditions by launching them into the Earth’s stratosphere, as it closely represents key conditions on the Red Planet. Published in Frontiers in Microbiology, this work paves the way for understanding not only the threat of microbes to space missions, but also the opportunities for resource independence from Earth.
“We successfully tested a new way of exposing bacteria and fungi to Mars-like conditions by using a scientific balloon to fly our experimental equipment up to Earth’s stratosphere,” reports Marta Filipa Cortesão, joint first author of this study. “Some microbes, in particular spores from the black mold fungus, were able to survive the trip, even when exposed to very high UV radiation.”
Understanding the endurance of microbes to space travel is vital for the success of future missions. When searching for extra-terrestrial life, we need to be sure that anything we discover has not just travelled with us from Earth.
“With crewed long-term missions to Mars, we need to know how human-associated microorganisms would survive on the Red Planet, as some may pose a health risk to astronauts,” says joint first author Katharina Siems, also based at the German Aerospace Center. “In addition, some microbes could be invaluable for space exploration. They could help us produce food and material supplies independently from Earth, which will be crucial when far away from home.”
Mars in a box
Many key characteristics of the environment at the Martian surface cannot be found or easily replicated at the surface of our planet. However, above the ozone layer in Earth’s middle stratosphere the conditions are remarkably similar.
“We launched the microbes into the stratosphere inside the MARSBOx (Microbes in Atmosphere for Radiation, Survival and Biological Outcomes experiment) payload, which was kept at Martian pressure and filled with artificial Martian atmosphere throughout the mission,” explains Cortesão. “The box carried two sample layers, with the bottom layer shielded from radiation. This allowed us to separate the effects of radiation from the other tested conditions: desiccation, atmosphere, and temperature fluctuation during the flight. The top layer samples were exposed to more than 1,000 times more UV radiation than levels that can cause sunburn on our skin.”
“While not all the microbes survived the trip, one previously detected on the International Space Station, the black mold Aspergillus niger, could be revived after it returned home,” explains Siems, who highlights the importance of this ongoing research.
“Microorganisms are closely-connected to us; our body, our food, our environment, so it is impossible to rule them out of space travel. Using good analogies for the Martian environment, such as the MARSBOx balloon mission to the stratosphere, is a really important way to help us explore all the implications of space travel on microbial life and how we can drive this knowledge towards amazing space discoveries.”
1. Quartz disc with dried Aspergillus niger spores, before being placed in the aluminum sample carriers that went on the Trex-box. Credit: German Aerospace Center (DLR); 2. Trex-Box being sealed during sample preparation at DLR. You can see the top layer harboring the quartz disc that carry the dried microbial samples. Credit: DLR; 3. Aspergillus niger spores seen by Scanning Electron Microscopy (SEM). Credit: DLR and Institute for Electrical Engineering and Plasma Technology (AEPT)
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