Nearing the Limits of Life on Earth
Failure to find active microbes in coldest Antarctic soils has implications for search for life on Mars
Released: 19-Jan-2016 9:05 AM EST
Source Newsroom: McGill University
Newswise — It took Jackie Goordial over 1000 Petri dishes before she was ready to accept what she was seeing. Or not seeing. Goordial, a post-doctoral fellow in the Department of Natural Resource Sciences at McGill University has spent the past four years looking for signs of active microbial life in permafrost soil taken from one of the coldest, oldest and driest places on Earth: in University Valley, located in the high elevation McMurdo Dry Valleys of Antarctica, where extremely cold and dry conditions have persisted for over 150,000 years. The reason that scientists are looking for life in this area is that it is thought to be the place on Earth that most closely resembles the permafrost found in the northern polar region of Mars at the Phoenix landing site.
In University Valley, high in the McMurdo Dry Valleys of Antarctica, there is a layer of dry permafrost soil overlaying ice-rich permanently frozen ground. The ice in the permafrost is formed not by liquid water, but by frozen water vapour; the absence of liquid water, makes the soil less likely to be able to sustain life.
“I’ve been trying to cheer her up by telling her that not finding life is important too,” says Lyle Whyte, Goordial’s supervisor. “Going into the study, we were sure that we would detect a functioning and viable microbial ecosystem in the permafrost soils of University Valley as we and others have done in Arctic and Antarctic permafrost, including in other sites at lower elevations in Antarctica. It is hard for both of us to believe that we may have reached a cold and arid threshold where even microbial life cannot actively exist.”
Drilling for microbes in Antarctica What brought the researchers to University Valley was a NASA ASTEP (astrobiology science and technology for exploring planets) project to test the IceBite auger, a permafrost drill designed to drill into Martian permafrost. The average daily air temperature in the Antarctic summer of 2013, when Goordial collected the permafrost samples which she tested both on the spot and later in the lab, was − 14 °C and it never rose above 0 °C, making the permafrost difficult to drill.
The McGill team analyzed samples from two permafrost boreholes which reached a depth of just 42 cm and 55 cms below the surface. This may not sound like a lot, but drilling into permafrost to get soil samples for testing is very difficult.
“Anytime you drill into frozen ground and it has some ice in it the drilling process creates friction which melts the ice. The hole will refreeze within seconds if the drilling is interrupted, freezing the drill bit into the hole” says Whyte.” I remember drilling in the Arctic and losing a drill bit in one of the holes we had made, just because it froze into the ice before we could get it out.”
"Previous studies in the lower dry valleys of Antarctica and in subglacial lakes were giving us the impression that microbial life was rich in the cold regions. But this is finally Mars!” says Chris McKay of NASA’s Ames Research Centre. “University Valley has the coldest driest soil we can find on Earth. And life is really having a hard time of it there. This is certainly the training ground for the search for evidence of life on Mars and an extremely important result for NASA's astrobiology effort."
All the tests came out negativeThe research team carried out a variety of tests, both in the field (where they failed to find evidence of carbon dioxide or methane – a gas used by all living things – in the soil) and then back in the lab at McGill in Montreal. They sent soil samples for DNA testing, looking for matches with particular genes known to be found in microbes and fungi; they tried to stimulate microbial growth on a wide variety of substances and then count the cells produced; and they used highly sensitive radiorespiration activity assays, which involve feeding the soil microorganisms a food source which has been labelled with radioactive carbon, which can then be used to detect if the microorganisms are active.
The tests failed to show any signs of active life.
“We couldn’t detect any microbial activity within these samples,” says Whyte. “Any, very limited traces we were able to find of microbial life in these samples are most likely the remnants of microbes that are dormant or are slowly dying off. Given the continuous dryness and subfreezing temperatures, and the lack of available water, even in summer, it is unlikely that any microbial communities can grow in these soils.”
Goordial adds, “We don’t know if there is activity beyond our limits of detection. All we can say for sure is that after using all the current methods of testing available to us, the samples are unlike any other permafrost we have encountered to date on Earth”
Implications for the search for life on Mars“If conditions are too cold and dry to support active microbial life on an analogous climate on Earth, then the colder dryer conditions in the near surface permafrost on Mars are unlikely to contain life.” Says Whyte. “Additionally, if we cannot detect activity on Earth, in an environment which is teeming with microorganisms, it will be extremely unlikely and difficult to detect such activity on Mars.”
On a positive note however, the researchers add that this suggests that any microorganisms that may be transported to Mars from Earth by mistake are unlikely to be able to survive on the Martian surface, something that is of current concern for planetary protection.
The research was funded by NASA ASTEP program, the Natural Sciences and Engineering Research Council (NSERC) Discovery Grant Program, and NSERC and CREATE Canadian Astrobiology Training Program (CATP).
To read “Nearing the cold-arid limits of microbial life in permafrost of an upper dry valley, Antarctica” by Jacqueline Goordial et al in The ISME Journal: 10.1038/ismej.2015.239
Experts who are willing to comment on the research:
Corien Bakermans, Dept. of Microbiology, Pennsylvania State Universitycub21@psu.edu
Alberto G. Fairen, Dept. of Planetology and Habitability, Centro de Astrobiologia (NASA Astrobiology Institute associate), Visiting Scientist at the Department of Astronomy, Cornell Universityagfairen@cab.inta-csic.es
Victor Parro, Dept. of Planetology and Habitability Centro de Astrobiologia(NASA Astrobiology Institute associate)firstname.lastname@example.org
Contacts:Jackie Goordial, Post-doctoral fellow, Dept. of Natural Resource Sciences, McGill UniversityJacqueline.Goordial@mail.mcgill.ca, 514-398-7823 (English interviews)
Prof. Lyle Whyte, Dept. of Natural Resource Science & McGill Space Institute, McGill UniversityLyle.email@example.com, 514-398-7889 (English and French interviews)
Chris McKay, Planetary Scientist, Space Science Division, NASA Ames Research Center, firstname.lastname@example.org
Katherine Gombay, Media Relations, McGill UniversityKatherine.email@example.com, 514-398-2189