Evaluation of meteorites as habitats for terrestrial microorganisms: Results from the Nullarbor Plain, Australia, a Mars analogue site
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Tait, Alastair W.
Wilson, Siobhan A.
Tomkins, Andrew G.
Gagen, Emma J.
Fallon, Stewart J.
Southam, Gordon
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Elsevier
Abstract
Unambiguous identification of biosignatures on Mars requires access to well-characterized, long-lasting geochemical standards
at the planet’s surface that can be modified by theoretical martian life. Ordinary chondrites, which are ancient meteorites
that commonly fall to the surface of Mars and Earth, have well-characterized, narrow ranges in trace element and
isotope geochemistry compared to martian rocks. Given that their mineralogy is more attractive to known chemolithotrophic
life than the basaltic rocks that dominate the martian surface, exogenic rocks (e.g., chondritic meteorites) may be good places
to look for signs of prior life endemic to Mars. In this study, we show that ordinary chondrites, collected from the arid Australian
Nullarbor Plain, are commonly colonized and inhabited by terrestrial microorganisms that are endemic to this Mars
analogue site. These terrestrial endolithic and chasmolithic microbial contaminants are commonly found in close association
with hygroscopic veins of gypsum and Mg-calcite, which have formed within cracks penetrating deep into the meteorites. Terrestrial
bacteria are observed within corrosion cavities, where troilite (FeS) oxidation has produced jarosite [KFe3(SO4)2
(OH)6]. Where terrestrial microorganisms have colonized primary silicate minerals and secondary calcite, these mineral surfaces
are heavily etched. Our results show that inhabitation of meteorites by terrestrial microorganisms in arid environments
relies upon humidity and pH regulation by minerals. Furthermore, microbial colonization affects the weathering of meteorites
and production of sulfate, carbonate, Fe-oxide and smectite minerals that can preserve chemical and isotopic biosignatures
for thousands to millions of years on Earth. Meteorites are thus habitable by terrestrial microorganisms, even under highly
desiccating environmental conditions of relevance to Mars. They may therefore be useful as chemical and isotopic ‘‘standards”
that preserve evidence of life, thereby providing the possibility of universal context for recognition of microbial biosignatures
on Earth, Mars and throughout the solar system.
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Geochimica et Cosmochimica Acta
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Open Access