Edinburgh Research Explorer

Multiplication of microbes below 0.690 water activity: implications for terrestrial and extraterrestrial life

Research output: Contribution to journalLiterature review

  • Andrew Stevenson
  • Juergen Burkhardt
  • Charles S. Cockell
  • Jonathan A. Cray
  • Jan Dijksterhuis
  • Mark Fox-Powell
  • Terence P. Kee
  • Gerhard Kminek
  • Terry J. McGenity
  • Kenneth N. Timmis
  • David J. Timson
  • Mary A. Voytek
  • Frances Westall
  • Michail M. Yakimov
  • John E. Hallsworth

Related Edinburgh Organisations

Original languageEnglish
Pages (from-to)257-277
Number of pages21
JournalEnvironmental Microbiology
Volume17
Issue number2
DOIs
StatePublished - Feb 2015

Abstract

Since a key requirement of known life forms is available water (water activity; a(w)), recent searches for signatures of past life in terrestrial and extraterrestrial environments have targeted places known to have contained significant quantities of biologically available water. However, early life on Earth inhabited high-salt environments, suggesting an ability to withstand low water-activity. The lower limit of water activity that enables cell division appears to be approximate to 0.605 which, until now, was only known to be exhibited by a single eukaryote, the sugar-tolerant, fungal xerophile Xeromyces bisporus. The first forms of life on Earth were, though, prokaryotic. Recent evidence now indicates that some halophilic Archaea and Bacteria have water-activity limits more or less equal to those of X.bisporus. We discuss water activity in relation to the limits of Earth's present-day biosphere; the possibility of microbial multiplication by utilizing water from thin, aqueous films or non-liquid sources; whether prokaryotes were the first organisms able to multiply close to the 0.605-a(w) limit; and whether extraterrestrial aqueous milieux of 0.605a(w) can resemble fertile microbial habitats found on Earth.

    Research areas

  • DON-JUAN POND, BARBERTON GREENSTONE-BELT, SALTERN CRYSTALLIZER PONDS, BIOLOGICAL ICE NUCLEATORS, PHASE ESCHERICHIA-COLI, UPPER MARTIAN SURFACE, SOUTH-AFRICA, DEAD-SEA, EXTREME ENVIRONMENTS, METABOLIC-ACTIVITY

ID: 21168756