Relationships between sucretolerance and salinotolerance in bacteria from hypersaline environments and their implications for the exploration of Mars and the icy worlds

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Authors
Fredsgaard, Casper
Moore, Donald B.
Alsoudi, Amer F.
Crisler, James D.
Chen, Fei
Clark, Benton C.
Schneegurt, Mark A.
Advisors
Issue Date
2017-04
Type
Article
Keywords
Extreme environments , Salinity tolerance , Sucrose , Sugar tolerance
Research Projects
Organizational Units
Journal Issue
Citation
Fredsgaard, C., Moore, D., Al Soudi, A., Crisler, J., Chen, F., Clark, B., & Schneegurt, M. (2017). Relationships between sucretolerance and salinotolerance in bacteria from hypersaline environments and their implications for the exploration of Mars and the icy worlds. International Journal of Astrobiology, 16(2), 156-162
Abstract

The most extremely osmotolerant microbial isolates are fungi from high-sugar environments that tolerate the lowest water activity (0.61) for growth yet reported. Studies of osmotolerant bacteria have focused on halotolerance rather than sucretolerance (ability to grow in high sugar concentrations). A collection of salinotolerant (>= 10% NaCl or >= 50% MgSO4) bacterial isolates from the Great Salt Plains of Oklahoma and Hot Lake in Washington were screened for sucretolerance in medium supplemented with >= 50% fructose, glucose or sucrose. Tolerances significantly differed between solutes, even though water activities for saline media (0.92 and 0.85 for 10 and 20% NaCl Salt Plains media, respectively) were comparable or lower than water activities for high-sugar media (0.93 and 0.90 for 50 and 70% sucrose artificial nectar media, respectively). These specific solute effects were differentially expressed among individual isolates. Extrapolating the results of earlier food science studies with yeasts at high sugar concentrations to bacteria in salty environments with low water activity should be done with caution. Furthermore, the discussion of habitable Special Regions on Mars and the icy worlds should reflect an understanding of specific solute effects.

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Publisher
Cambridge University Press
Journal
Book Title
Series
International Journal of Astrobiology;v.16:no.2
PubMed ID
DOI
ISSN
1473-5504
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