Вопрос жизни. Энергия, эволюция и происхождение сложности

(2011).

Химия катархейских океанов

Arndt, N., and E. Nisbet Processes on the young Earth and the habitats of early life // Annual Reviews Earth Planetary Sciences 40: 521–549 (2012).

Pinti, D. The origin and evolution of the oceans // Lectures Astrobiology 1: 83–112 (2005).

Russell, M. J., and N. T. Arndt Geodynamic and metabolic cycles in the Hadean // Biogeosciences 2: 97–111 (2005).

Zahnle, K., Arndt, N., Cockell, C., Halliday, A., Nisbet, E., Selsis, F., and N. H. Sleep Emergence of a habitable planet // Space Science Reviews 129: 35–78 (2007).

Термофорез

Baaske, P., Weinert, F. M., Duhr, S., et al. Extreme accumulation of nucleotides in simulated hydrothermal pore systems // Proceedings National Academy Sciences USA 104: 9346–9351 (2007).

Mast, C. B., Schink, S., Gerland, U., and D. Braun Escalation of polymerization in a thermal gradient // Proceedings National Academy Sciences USA 110: 8030–8035 (2013).

^{Термодинамика синтеза органических веществ в щелочных источниках}

Amend, J. P., and T. M. McCollom Energetics of biomolecule synthesis on early Earth / In: Zaikowski, L., et al., eds. Chemical Evolution II: From the Origins of Life to Modern Society. American Chemical Society (2009).

Ducluzeau, A.-L., Schoepp-Cothenet, B., Baymann, F., Russell, M. J., and W. Nitschke Free energy conversion in the LUCA: Quo vadis? // Biochimica et Biophysica Acta Bioenergetics 1837: 982–988 (2014).

Martin, W., and M. J. Russell On the origin of biochemistry at an alkaline hydrothermal vent // Phil. Trans. R. Soc. B 367: 1887–1925 (2007).

Shock, E., and P. Canovas The potential for abiotic organic synthesis and biosynthesis at seafloor hydrothermal systems // Geofluids 10: 161–192 (2010).

Sousa, F. L., Thiergart, T., Landan, G., Nelson-Sathi, S., Pereira, I. A. C., Allen, J. F., Lane, N., and W. F. Martin Early bioenergetic evolution // Phil. Trans. R. Soc. B 368: 20130088 (2013).

Восстановительный потенциал и кинетический барьер восстановления CO₂

Lane, N., and W. Martin The origin of membrane bioenergetics // Cell 151: 1406–1416 (2012).

Maden, B. E. H. Tetrahydrofolate and tetrahydromethanopterin compared: functionally distinct carriers in C₁ metabolism // Biochemical Journal 350: 609–629 (2000).

Wactershauser, G. Pyrite formation, the ?rst energy source for life: a hypothesis // Systematic and Applied Microbiology 10: 207–210 (1988).

Могут ли природные протонные градиенты инициировать восстановление CO₂?

Herschy, B., Whicher, A., Camprubi, E., Watson, C., Dartnell, L., Ward, J., Evans, J. R. G., and N. Lane An origin-of-life reactor to simulate alkaline hydrothermal vents // Journal of Molecular Evolution 79: 213–227 (2014).

Herschy, B. Nature’s electrochemical flow reactors: Alkaline hydrothermal vents and the origins of life // Biochemist 36: 4–8 (2014).

Lane, N. Bioenergetic constraints on the evolution of complex life // Cold Spring Harbor Perspectives in Biology, doi: 10.1101/cshperspect.a015982 (2014).

Nitschke, W., and M. J. Russell Hydrothermal focusing of chemical and chemiosmotic energy, supported by delivery of catalytic Fe, Ni, Mo, Co, S and Se forced life to emerge // Journal of Molecular Evolution 69: 481–496 (2009).

Yamaguchi, A., Yamamoto, M., Takai, K., Ishii, T., Hashimoto, K., and R. Nakamura Electrochemical CO₂ reduction by Nicontaining iron sulfides: how is CO₂ electrochemically reduced at bisulfide-bearing deep sea hydrothermal precipitates? // Electrochimica Acta 141: 311–318 (2014).

Вероятность серпентинизации на других планетах Млечного Пути

Leeuw, N. H. de, Catlow, C. R., King, H. E., Putnis, A., Muralidharan, K., Deymier, P., Stimpfl, M., and M. J. Drake Where on Earth has our water come from? // Chemical Communications 46: 8923–8925 (2010).

Petigura, E. A., Howard, A. W., and G. W. Marcy Prevalence of Earth-sized planets orbiting Sunlike stars //