Bacteria,algae and also metazoans may live at temperature sbelow 0°C and survive ice formation in al lbody compartments, 1 ,2.In the Antarctic Dry Valleys, 3, microorganisms live at 35°C. Bacteria in culture metabolizeandreproduce, 4 ,at 10°C. In order to identify and characterize new species we suggest, after having isolated anaerobic microorganisms in culture from frozen samples, performing a selective cloning of 16S rRNA genes by PCR, electrophoresis to isolate genes, sequence analysis after subcloning and propagation in E. coli cells, building a phylogenetic tree of the bacterium. These devices are very common, being used for biomedical purposes in every country in the world. Ecology, evolutionary biology and astrobiology studies, as models of possible life on Mars or Jovian moons, or as microorganisms able to play important roles in terraforming perspectives, will benefit from a greater knowledge of these life forms and, last but not least, their enzymes, because of their low energy requirements, high specific activity at low temperature and thermolability, may provide a real spin-off for biotechnology. 1 Kohshima,S. (1984). Nature310, 225–227. 2 Wharton, D.A. & Ferns, D.J. (1995) J. Exp. Biol.198, 1381–1387. 3 Mahaney,W.C. et al. (2001). Icarus154, 113–130. 4 Bakermans, C. et al. (2003). Environ. Microbiol.5, 321–326.
Bianciardi, G. (2005). Molecular Analysis of Anaerobic Psychrophilic Bacteria. In National Workshop on AstrobiologySearch for Life in the Solar System Abstract Book (pp.18-18).
Molecular Analysis of Anaerobic Psychrophilic Bacteria
BIANCIARDI, GIORGIO
2005-01-01
Abstract
Bacteria,algae and also metazoans may live at temperature sbelow 0°C and survive ice formation in al lbody compartments, 1 ,2.In the Antarctic Dry Valleys, 3, microorganisms live at 35°C. Bacteria in culture metabolizeandreproduce, 4 ,at 10°C. In order to identify and characterize new species we suggest, after having isolated anaerobic microorganisms in culture from frozen samples, performing a selective cloning of 16S rRNA genes by PCR, electrophoresis to isolate genes, sequence analysis after subcloning and propagation in E. coli cells, building a phylogenetic tree of the bacterium. These devices are very common, being used for biomedical purposes in every country in the world. Ecology, evolutionary biology and astrobiology studies, as models of possible life on Mars or Jovian moons, or as microorganisms able to play important roles in terraforming perspectives, will benefit from a greater knowledge of these life forms and, last but not least, their enzymes, because of their low energy requirements, high specific activity at low temperature and thermolability, may provide a real spin-off for biotechnology. 1 Kohshima,S. (1984). Nature310, 225–227. 2 Wharton, D.A. & Ferns, D.J. (1995) J. Exp. Biol.198, 1381–1387. 3 Mahaney,W.C. et al. (2001). Icarus154, 113–130. 4 Bakermans, C. et al. (2003). Environ. Microbiol.5, 321–326.
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