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Modeling of conditions for origin of first organic forms of life in hot mineral water

Keywords:

Ignat Ignatov – Sc.D, Professor, Scientific Research Center of Medical Biophysics (SRCMB). E-mail: mbioph@dir.bg Oleg V. Mosin - Ph.D. (Chem.), Research Scientist, Moscow State University of Applied Biotechnology. E-mail: mosin-oleg@yandex.ru


The composition of water, its temperature and pH value was analyzed in experiments with modelling of primary hydrosphere and possible conditions for origin of first organic forms in hot mineral water. For this aim the authors performed experiments with hot mineral and seawater from Bulgaria by IR-spectrometry (DNES-method). As model systems were used cactus juice of Echinopsis pachanoi and Mediterranean jellyfish Cotylorhiza tuberculata. It was considered the reactions of condensation and dehydration in alkaline aqueous solutions with рН = 9–10, resulting in synthesis from separate molecules larger organic molecules as polymers and short polipeptides. It was shown that hot alkaline mineral water with temperature from +65 0C to +95 0C and pH value from 9 to 11 is more suitable for the origination of life and living matter than other analyzed water samples. The pH value of seawater on contrary is limited to the range of 7,5 to 8,4 units. Two common local maximums were observed in the IR-spectra of jellyfish and seawater, which were more pronouncedly expressed in IR-spectra of jellyfish.
References:

 

  1. Ignatov I., Mosin O.V. Color coronal (Kirlian) spectral analysis in modeling of nonequilibrioum conditions with the gas electric discharges simulating primary atmosphere. S. Miller\'s experiments // Naukovedenie. 2013. № 3(16). P. 1–15 [in Russian] [Online] Available: URL: http://naukovedenie.ru /PDF/05tvn313.pdf (May 10, 2013).
  2. Ignatov I., Mosin O.V. Isotopic composition of water and its temperature in the evolutionary origin of life and living matter // Naukovedenie. 2013. № 1(14). P. 1–16 [in Russian] [Online] Available: URL: http://naukovedenie.ru/PDF/42tvn113.pdf (February 13, 2013).
  3. Ignatov I., Mosin O.V. Possible processes for origin of life and living matter with modeling of physiological processes of bacterium Basillus subtilis as model system in heavy water // Journal of Natural Sciences Research. 2013.  V. 3. № 9. P. 6576.
  4. Ignatov I., Mosin O.V. Isotopic composition of water and its temperature in modeling of primordial hydrosphere experiments // Euro-Eco. Hanover. 2012. P. 62.
  5. Linsky J.L. D/H and nearby interstellar cloud structures / Ed. J.I. Linsky. Space Science Reviews. NY: Springer Science, Business Media. 2007. V. 130. 367 p.
  6. Ignatov I. Which water is optimal for the origin (generation) of life? // Euromedica. Hanover. 2010. P. 34–37.
  7. Ignatov I., Mosin O.V. Modeling of possible processes for origin of life and living matter in hot mineral and seawater with deuterium // Journal of Environment and Earth Science. 2013. V. 3. № 14. P. 103–118.
  8. Szostak J.W. An optimal degree of physical and chemical heterogeneity for the origin of life? // Philos. Trans. Royal Soc. Lond. Biol. Sci. 2011. V. 366. № 1580. P. 2894–901.
  9. Mulkidjanian A.Y., Galperin M.Y. On the origin of life in the Zinc world. Validation of the hypothesis on the photosynthesizing zinc sulfide edifices as cradles of life on Earth // Biology Direct. 2009. V. 4. P. 26.
  10. Trevors J.I., Pollack G.H. Hypothesis: origin of live in hydrogel environment // Progress in biophysics and molecular biology. 205. V. 89. № 1. P. 1–8.
  11. Ignatov I. Origin of life and living matter in hot mineral water. Conference on the Physics, Chemistry and Biology of Water. Vermont Photonics. USA. 2012. P. 67.
  12. Ignatov I., Mosin O.V. Method for colour coronal (Kirlian) spectral analysis // Biomedical Radio electronics. 2013. V. 1. P. 38–47 [in Russian].
  13. Schirber M. First fossil-makers in hot water // Astrobiology magazine. 2010 [Online] Available: URL: http://www.astrobio.net/exclusive/3418/first-fossil-makers-in-hot-water (January 3, 2010).
  14. Ponsa M.L., Quitte G., Fujii T., Rosing M.T., Reynarda B., Moynierd F., Doucheta Ch., Albaredea F. Early archean serpentine mud volcanoes at Isua, Greenland, as a niche for early life // Proc. Natl. Acad. Sci. U.S. 2011. V. 108. P.17639–17643.
  15. Kurihara K., Tamura M., Shohda K., Toyota T., Suzuki K., Sugawara T. Self-Reproduction of supramolecular giant vesicles combined with the amplification of encapsulated DNA // Nature Chemistry. 2011. V. 4.№ 10. P. 775–781.
  16. Calvin M. Chemical evolution / Ed. M. Calvin. Oxford: Clarendon. 1969. 278 p.
  17. Mathews C.N., Moser R. Peptide synthesis from hydrogen-cyanide and water // Nature. 1968. V. 215. P. 1230–1234.
  18. Miller S.L. A production of amino acids under possible primitive Earth conditions // Science. 1953. V. 117.№3046. P. 528–529.
  19. Abelson P. Chemical events on the “primitive” earth // Proc. Natl. Acad. Sci. U.S. 1966. V. 55. P. 1365–1372.
  20. Harada I., Fox S.W. Thermal synthesis of natural ammo-acids from a postulated primitive terrestrial atmosphere // Nature. 1964. V. 201.  P. 335–336.
  21. Fox S.W., Krampitz G. Catalytic decomposition  of glucose in aqueous solution by thermal proteinoids // Nature. 1964. V. 203.  P. 1362–1364.
  22. Fox S.W., Wang C.T. Melanocytestimulating hormone: Activity in thermal polymers of alpha-ammo acids // Science. 1968. V. 160.  P. 547–548.
  23. Nakashima T. Metabolism of proteinoid microspheres / Ed. T. Nakashima // In: Origins of life and evolution of biospheres. 1987. V. 20.  № (3–4). P. 269–277.
  24. Ignatov I., Tsvetkova. Water for the origin of life and informationability of water. Kirlian (electric images) of different types of water // Euromedica. Hanover. 2011. P. 32–35.
  25. Nikolis P., Prigozhin I. Self-organization in non-equilibrium systems. Moscow: Mir. 1979. P. 1–512 [in Russian].
  26. Sugawara T. Self-reproduction of supramolecular giant vesicles combined with the amplification of encapsulated DNA // Nature Chemistry. 2011. V. 1127. P. 775–780.

     

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