Abstract
To protect Mars from microbial contamination, research on growth of microorganisms found in spacecraft assembly clean rooms under simulated Martian conditions is required. This study investigated the effects of low atmospheric pressure on the growth of chemoorganotrophic spacecraft bacteria and whether the addition of Mars relevant anaerobic electron acceptors might enhance growth. The 125 bacteria screened here were recovered from actual Mars spacecraft. Growth at 7 hPa, 0 °C, and a CO2-enriched anoxic atmosphere (called low-PTA conditions) was tested on five TSA-based media supplemented with anaerobic electron acceptors. None of the 125 spacecraft bacteria showed active growth under the tested low-PTA conditions and amended media. In contrast, a decrease in viability was observed in most cases. Growth curves of two hypopiezotolerant strains, Serratia liquefaciens and Trichococcus pasteurii, were performed to quantify the effects of the added anaerobic electron acceptors. Slight variations in growth rates were determined for both bacteria. However, the final cell densities were similar for all media tested, indicating no general preference for any specific anaerobic electron acceptor. By demonstrating that a broad diversity of chemoorganotrophic and culturable spacecraft bacteria do not grow under the tested conditions, we conclude that there may be low risk of growth of chemoorganotrophic bacteria typically recovered from Mars spacecraft during planetary protection bioburden screenings.
Highlights
Protecting solar system bodies from contamination by Earth life allows the preservation of extraterrestrial habitats in their natural state and is a precaution to avoid contamination in places where life might exist
We surveyed 125 bacteria recovered from six authentic Mars spacecraft including the Viking, Pathfinder, Spirit, Opportunity, Phoenix, InSight and Curiosity platforms (Fig. 1;9)
All bacteria were able to grow on trypticase soy agar (TSA) incubated under lab-normal conditions of 1013 hPa, 30 °C and pO2 (21%) and on the media supplemented with the different anaerobic electron acceptors, with the exception of the iron supplemented medium at pH 5.0
Summary
Protecting solar system bodies from contamination by Earth life allows the preservation of extraterrestrial habitats in their natural state and is a precaution to avoid contamination in places where life might exist. These hypopiezotolerant microorganisms (def., able to grow at ≤ 10 hPa16) inhabit diverse ecological niches including arctic and alpine soils, Siberian permafrost, environmental surface waters, plant surfaces, and seawater; and represent only a minor fraction of the overall microbiota while the vast majority of microorganisms were not able to proliferate even though adequate water and nutrients were provided (e.g.,15) In these studies, the possibility that microbial species required specific geochemical redox couples or terminal anaerobic electron acceptors under low-PTA conditions for growth was not examined. The second objective was to evaluate a range of Mars-relevant geochemical terminal anaerobic electron acceptors to determine if they would enhance microbial activity and growth under simulated low-PTA conditions
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