Physicochemical Parameters Limiting Growth of Debaryomyces hansenii in Solutions of Hygroscopic Compounds and Their Effects on the Habitability of Martian Brines

The availability of liquid water is a prerequisite for all lifeforms on Earth. In hyperarid subzero environments like the Dry Valleys in Antarctica or the near-subsurface of Mars liquid water might be provided temporarily by hygroscopic substances that absorb water from the atmosphere and lower the...

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Bibliographic Details
Published in:Life
Main Authors: Heinz, J., Rambags, V., Schulze-Makuch, D.
Format: Article in Journal/Newspaper
Language:English
Published: 2021
Subjects:
Mars
brines
salts
microorganisms
halotolerance
yeast
microbial growth
water activity
chaotropicity
WATER-ACTIVITY LIMIT
LIQUID WATER
PERCHLORATE
DELIQUESCENCE
TEMPERATURE
CHLORATE
POINTS
STRESS
ENVIRONMENTS
Antarc*
Antarctica
Online Access:https://cris.maastrichtuniversity.nl/en/publications/470781f4-46e4-4e9f-943d-957c1f620d64
https://doi.org/10.3390/life11111194
Description
Summary:The availability of liquid water is a prerequisite for all lifeforms on Earth. In hyperarid subzero environments like the Dry Valleys in Antarctica or the near-subsurface of Mars liquid water might be provided temporarily by hygroscopic substances that absorb water from the atmosphere and lower the freezing point of water. To evaluate the potential of hygroscopic compounds to serve as a habitat, it is necessary to explore the microbial tolerances towards these substances and their life-limiting properties. Here we present a study investigating the tolerances of the halotolerant yeast Debaryomyces hansenii to various solutes. Growth experiments were conducted via counting colony forming units (CFUs) after inoculation of a liquid growth medium containing a specific solute concentration. The lowest water activities (a(w)) enabling growth were determined to be ~0.83 in glycerol and fructose-rich media. For all other solutes the growth-enabling a(w) was higher, due to additional stress factors such as chaotropicity and ionic strength. Additionally, we found that the solute tolerances of D. hansenii correlate with both the eutectic freezing point depressions and the deliquescence relative humidities of the respective solutes. Our findings strongly impact our understanding of the habitability of solute-rich low a(w) environments on Earth and beyond.

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