Survivability of Soil and Permafrost Microbial Communities after Irradiation with Accelerated Electrons under Simulated Martian and Open Space Conditions
One of the prior current astrobiological tasks is revealing the limits of microbial resistance to extraterrestrial conditions. Much attention is paid to ionizing radiation, since it can prevent the preservation and spread of life outside the Earth. The aim of this research was to study the impact of...
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| Language: | English |
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Multidisciplinary Digital Publishing Institute
2018
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| Online Access: | https://doi.org/10.3390/geosciences8080298 |
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ftmdpi:oai:mdpi.com:/2076-3263/8/8/298/ 2023-08-20T04:07:08+02:00 Survivability of Soil and Permafrost Microbial Communities after Irradiation with Accelerated Electrons under Simulated Martian and Open Space Conditions Vladimir Cheptsov Elena Vorobyova Andrey Belov Anatoly Pavlov Denis Tsurkov Vladimir Lomasov Sergey Bulat agris 2018-08-08 application/pdf https://doi.org/10.3390/geosciences8080298 EN eng Multidisciplinary Digital Publishing Institute Biogeosciences https://dx.doi.org/10.3390/geosciences8080298 https://creativecommons.org/licenses/by/4.0/ Geosciences; Volume 8; Issue 8; Pages: 298 astrobiology Mars accelerated electrons gamma radiation microbial communities radioresistance native environment soil permafrost Text 2018 ftmdpi https://doi.org/10.3390/geosciences8080298 2023-07-31T21:40:04Z One of the prior current astrobiological tasks is revealing the limits of microbial resistance to extraterrestrial conditions. Much attention is paid to ionizing radiation, since it can prevent the preservation and spread of life outside the Earth. The aim of this research was to study the impact of accelerated electrons (~1 MeV) as component of space radiation on microbial communities in their natural habitat—the arid soil and ancient permafrost, and also on the pure bacterial cultures that were isolated from these ecotopes. The irradiation was carried out at low pressure (~0.01 Torr) and low temperature (−130 °C) to simulate the conditions of Mars or outer space. High doses of 10 kGy and 100 kGy were used to assess the effect of dose accumulation in inactive and hypometabolic cells, depending on environmental conditions under long-term irradiation estimated on a geological time scale. It was shown that irradiation with accelerated electrons in the applied doses did not sterilize native samples from Earth extreme habitats. The data obtained suggests that viable Earth-like microorganisms can be preserved in the anabiotic state for at least 1.3 and 20 million years in the regolith of modern Mars in the shallow subsurface layer and at a 5 m depth, respectively. In addition, the results of the study indicate the possibility of maintaining terrestrial like life in the ice of Europa at a 10 cm depth for at least ~170 years or for at least 400 thousand years in open space within meteorites. It is established that bacteria in natural habitat has a much higher resistance to in situ irradiation with accelerated electrons when compared to their stability in pure isolated cultures. Thanks to the protective properties of the heterophase environment and the interaction between microbial populations even radiosensitive microorganisms as members of the native microbial communities are able to withstand very high doses of ionizing radiation. Text Ice permafrost MDPI Open Access Publishing Geosciences 8 8 298 |
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Open Polar |
| collection |
MDPI Open Access Publishing |
| op_collection_id |
ftmdpi |
| language |
English |
| topic |
astrobiology Mars accelerated electrons gamma radiation microbial communities radioresistance native environment soil permafrost |
| spellingShingle |
astrobiology Mars accelerated electrons gamma radiation microbial communities radioresistance native environment soil permafrost Vladimir Cheptsov Elena Vorobyova Andrey Belov Anatoly Pavlov Denis Tsurkov Vladimir Lomasov Sergey Bulat Survivability of Soil and Permafrost Microbial Communities after Irradiation with Accelerated Electrons under Simulated Martian and Open Space Conditions |
| topic_facet |
astrobiology Mars accelerated electrons gamma radiation microbial communities radioresistance native environment soil permafrost |
| description |
One of the prior current astrobiological tasks is revealing the limits of microbial resistance to extraterrestrial conditions. Much attention is paid to ionizing radiation, since it can prevent the preservation and spread of life outside the Earth. The aim of this research was to study the impact of accelerated electrons (~1 MeV) as component of space radiation on microbial communities in their natural habitat—the arid soil and ancient permafrost, and also on the pure bacterial cultures that were isolated from these ecotopes. The irradiation was carried out at low pressure (~0.01 Torr) and low temperature (−130 °C) to simulate the conditions of Mars or outer space. High doses of 10 kGy and 100 kGy were used to assess the effect of dose accumulation in inactive and hypometabolic cells, depending on environmental conditions under long-term irradiation estimated on a geological time scale. It was shown that irradiation with accelerated electrons in the applied doses did not sterilize native samples from Earth extreme habitats. The data obtained suggests that viable Earth-like microorganisms can be preserved in the anabiotic state for at least 1.3 and 20 million years in the regolith of modern Mars in the shallow subsurface layer and at a 5 m depth, respectively. In addition, the results of the study indicate the possibility of maintaining terrestrial like life in the ice of Europa at a 10 cm depth for at least ~170 years or for at least 400 thousand years in open space within meteorites. It is established that bacteria in natural habitat has a much higher resistance to in situ irradiation with accelerated electrons when compared to their stability in pure isolated cultures. Thanks to the protective properties of the heterophase environment and the interaction between microbial populations even radiosensitive microorganisms as members of the native microbial communities are able to withstand very high doses of ionizing radiation. |
| format |
Text |
| author |
Vladimir Cheptsov Elena Vorobyova Andrey Belov Anatoly Pavlov Denis Tsurkov Vladimir Lomasov Sergey Bulat |
| author_facet |
Vladimir Cheptsov Elena Vorobyova Andrey Belov Anatoly Pavlov Denis Tsurkov Vladimir Lomasov Sergey Bulat |
| author_sort |
Vladimir Cheptsov |
| title |
Survivability of Soil and Permafrost Microbial Communities after Irradiation with Accelerated Electrons under Simulated Martian and Open Space Conditions |
| title_short |
Survivability of Soil and Permafrost Microbial Communities after Irradiation with Accelerated Electrons under Simulated Martian and Open Space Conditions |
| title_full |
Survivability of Soil and Permafrost Microbial Communities after Irradiation with Accelerated Electrons under Simulated Martian and Open Space Conditions |
| title_fullStr |
Survivability of Soil and Permafrost Microbial Communities after Irradiation with Accelerated Electrons under Simulated Martian and Open Space Conditions |
| title_full_unstemmed |
Survivability of Soil and Permafrost Microbial Communities after Irradiation with Accelerated Electrons under Simulated Martian and Open Space Conditions |
| title_sort |
survivability of soil and permafrost microbial communities after irradiation with accelerated electrons under simulated martian and open space conditions |
| publisher |
Multidisciplinary Digital Publishing Institute |
| publishDate |
2018 |
| url |
https://doi.org/10.3390/geosciences8080298 |
| op_coverage |
agris |
| genre |
Ice permafrost |
| genre_facet |
Ice permafrost |
| op_source |
Geosciences; Volume 8; Issue 8; Pages: 298 |
| op_relation |
Biogeosciences https://dx.doi.org/10.3390/geosciences8080298 |
| op_rights |
https://creativecommons.org/licenses/by/4.0/ |
| op_doi |
https://doi.org/10.3390/geosciences8080298 |
| container_title |
Geosciences |
| container_volume |
8 |
| container_issue |
8 |
| container_start_page |
298 |
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1774718592271515648 |