Microbial Rock Inhabitants Survive Hypervelocity Impacts on Mars-Like Host Planets: First Phase of Lithopanspermia Experimentally Tested

Horneck, G.; Stöffler, D.; Ott, S.; Hornemann, U.; Cockell, Charles S.; Moeller, Ralf; Meyer, C.; Vera, Jean‐Pierre de; Fritz, J.; Schade, Sara; Artemieva, N. A.

doi:10.1089/ast.2007.0134

Cited by 156 publications

(159 citation statements)

References 63 publications

(122 reference statements)

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“…Despite this extremely challenging situation for life, there are organisms on Earth which are potentially able to survive space travel: it has been shown that different micro-organisms can survive launch by spallation from a hypervelocity impact (Horneck et al 2008a;Fajardo-Cavazos et al 2009) and hypervelocity atmospheric transit (Fajardo-Cavazos et al 2005). Thus, it has been suggested that, for example, bacterial spores situated on or within meteorites could survive interplanetary transport (Fajardo-Cavazos et al 2009) and hypervelocity entry from space through Earth's atmosphere (Fajardo-Cavazos et al 2005;reviewed in Olsson-Francis & Cockell 2010).…”

Section: Discussionmentioning

confidence: 99%

PCR-based analysis of microbial communities during the EuroGeoMars campaign at Mars Desert Research Station, Utah

Thiel

Ehrenfreund

Foing

et al. 2011

International Journal of Astrobiology

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Abstract:The search for evidence of past or present life on Mars will require the detection of markers that indicate the presence of life. Because deoxyribonucleic acid (DNA) is found in all known living organisms, it is considered to be a 'biosignature' of life. The main function of DNA is the long-term storage of genetic information, which is passed on from generation to generation as hereditary material. The Polymerase Chain Reaction (PCR) is a revolutionary technique which allows a single fragment or a small number of fragments of a DNA molecule to be amplified millions of times, making it possible to detect minimal traces of DNA. The compactness of the contemporary PCR instruments makes routine sample analysis possible with a minimum amount of laboratory space. Furthermore the technique is effective, robust and straightforward. Our goal was to establish a routine for the detection of DNA from micro-organisms using the PCR technique during the EuroGeoMars simulation campaign. This took place at the Mars Society's Mars Desert Research Station (MDRS) in Utah in February 2009 (organized with the support of the International Lunar Exploration Working Group (ILEWG), NASA Ames and the European Space Research and Technology Centre (ESTEC)). During the MDRS simulation, we showed that it is possible to establish a minimal molecular biology lab in the habitat for the immediate on-site analysis of samples by PCR after sample collection. Soil and water samples were taken at different locations and soil depths. The sample analysis was started immediately after the crew returned to the habitat laboratory. DNA was isolated from micro-organisms and used as a template for PCR analysis of the highly conserved ribosomal DNA to identify representatives of the different groups of micro-organisms (bacteria, archaea and eukarya). The PCR products were visualized by agarose gel electrophoresis and documented by transillumination and digital imaging. The microbial diversity in the collected samples was analysed with respect to sampling depth and the presence or absence of vegetation. For the first time, we have demonstrated that it is possible to perform direct on-site DNA analysis by PCR at MDRS, a simulated planetary habitat in an extreme environment that serves as a model for preparation and optimization of techniques to be used for future Mars exploration.

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Section: Discussionmentioning

confidence: 99%

PCR-based analysis of microbial communities during the EuroGeoMars campaign at Mars Desert Research Station, Utah

Thiel

Ehrenfreund

Foing

et al. 2011

International Journal of Astrobiology

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“…A more deleterious stressor of organisms during the process of impact ejection is shock. Spores of Bacillus subtilis can survive shock pressures greater than 50 GPa (Burchell et al 2001(Burchell et al , 2004Horneck 2001a;Stöffler et al 2007;Horneck et al 2007), which would allow for the survival of ejection to Earth's escape velocity. In contrast, vegetative cells are susceptible to disruption by low shock pressures.…”

Section: Launch Of Photosynthesis From a Planetmentioning

confidence: 99%

“…In flyer-plate experiments, we have shown that the asporogenous phototrophic cyanobacterium Chroococcidiopsis sp. was killed at shock pressures greater than 10 GPa Horneck et al 2007). This organism was chosen because it is naturally endolithic.…”

Section: Launch Of Photosynthesis From a Planetmentioning

confidence: 99%

Planetary targets in the search for extrasolar oxygenic photosynthesis

Cockell

Raven

Kaltenegger

et al. 2009

Plant Ecology & Diversity

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Background:In the coming decades space telescopes will be constructed that will attempt to find the gaseous products of oxygenic photosynthesis, the most promising biosignatures of life, in the atmospheres of temperate Earth-like planets orbiting distant stars. Aims: This paper aims to provide a synthesis of the range of feasible targets -either planets or their satellites -that could harbour photosynthesis. Methods: We calculated photosynthetically active radiation (PAR) fluxes on a diversity of planetary bodies including those receiving direct light from a single star, similarly to the Earth, and investigated the potential of these fluxes to support photosynthesis. Results: All main sequence stars emit radiation that is capable of supporting photosynthesis on Earth-like planets. We discuss tidally-locked M star planets as a special case. Less conventional targets for searches include large moons orbiting gas giant planets, which receive reflected light from their host planets and from the host star, planets in stable orbits in binary star systems, and the search for two planets within the same star system with photosynthetic signatures. Conclusions: A diversity of planetary bodies are targets in the search for extrasolar photosynthesis. The demonstration that many or none of these candidate planetary bodies harbour photosynthesis would be an important conclusion in understanding the evolution and prevalence of photosynthesis.

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“…40, 1665-1671. Horneck et al (2008). Microbial rock inhabitants survive hypervelocity impacts on Mars-like host planets: First phase of Lithopanspermia experimentally tested, Astrobiology, 8: 17-29.…”

Section: Dynamics Of Pattern Formation In Biomimetic Systemsmentioning

confidence: 99%

“…But did it occur on Earth? As Earth was sterilized during the LHB, about 700 My after the formation of the solar system, seeding by lithopanspermia is a definite possibility (Horneck et al, 2008). If so, the question is what the place of origin could be in the solar system.…”

Section: On the Transfer Of Meteorites (And Life?) From Earth To The mentioning

confidence: 99%

Special Issue: Abstracts From the 2008 Issol Meeting

Orange

Westall

Disnar

et al. 2009

Orig Life Evol Biosph

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Microbial Rock Inhabitants Survive Hypervelocity Impacts on Mars-Like Host Planets: First Phase of Lithopanspermia Experimentally Tested

Cited by 156 publications

References 63 publications

PCR-based analysis of microbial communities during the EuroGeoMars campaign at Mars Desert Research Station, Utah

PCR-based analysis of microbial communities during the EuroGeoMars campaign at Mars Desert Research Station, Utah

Planetary targets in the search for extrasolar oxygenic photosynthesis

Special Issue: Abstracts From the 2008 Issol Meeting

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