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Survival of lichens and bacteria exposed to outer space conditions - Results of the Lithopanspermia experiments

Research output: Contribution to journalArticle

  • Rosa de la Torre
  • Leopoldo G. Sancho
  • Gerda Horneck
  • Asuncion de los Rios
  • Jacek Wierzchos
  • Karen Olsson-Francis
  • Charles S. Cockell
  • Petra Rettberg
  • Thomas Berger
  • Jean-Pierre P. de Vera
  • Sieglinde Ott
  • Jesus Martinez Frias
  • Pablo Gonzalez Melendi
  • Maria Mercedes Lucas
  • Manuel Reina
  • Ana Pintado
  • Rene Demets

Related Edinburgh Organisations

Original languageEnglish
Pages (from-to)735-748
Number of pages14
JournalIcarus
Volume208
Issue number2
DOIs
Publication statusPublished - Aug 2010

Abstract

In the space experiments Lithopanspermia, experimental support was provided to the likelihood of the lithopanspermia concept that considers a viable transport of microorganisms between the terrestrial planets by means of meteorites. The rock colonising lichens Rhizocarpon geographicum and Xanthoria elegans, the vagrant lichen Aspicilia fruticulosa, and endolithic and endoevaporitic communities of cyanobacteria and bacteria with their natural rock substrate were exposed to space for 10 days onboard the Biopan facility of the European Space Agency (ESA). Biopan was closed during launch and re-entry. In addition, in the Stone facility, one sample of R. geographicum on its natural granitic substrate was attached at the outer surface of the re-entry capsule close to the stagnation point, only protected by a thin cover of glass textolite. Post-flight analysis, which included determination of the photosynthetic activity, LIVE/DEAD staining, and germination capacity of the ascospores, demonstrated that all three lichen were quite resistant to outer space conditions, which include the full spectrum of solar extraterrestrial electromagnetic radiation or selected wavelength ranges. This high resistance of the lichens to space appears to be due to their symbiotic nature and protection by their upper pigmented layer, the cortex. In contrast, the rock- or halite-inhabiting bacteria were severely damaged by the same exposure. After atmospheric re-entry, the granite of the Stone sample was transformed into a glassy, nearly homogenous material, with several friction striae. None of the lichen cells survived this re-entry process. The data suggest that lichens are suitable candidates for testing the concept of lithopanspermia, because they are extremely resistant to the harsh environment of outer space. The more critical event is the atmospheric re-entry after being captured by a planet. Experiments simulating the re-entry process of a microbe-carrying meteoroid did not show any survivors. (C) 2010 Elsevier Inc. All rights reserved.

    Research areas

  • Astrobiology, Exobiology, Meteorites, Solar radiation, MARTIAN METEORITE DELIVERY, BACILLUS-SUBTILIS SPORES, LOW-EARTH-ORBIT, UV-B, HYPERVELOCITY IMPACTS, XANTHORIA-PARIETINA, ATMOSPHERIC ENTRY, SIMULATED SPACE, MICROBIAL LIFE, MARS

ID: 1496365