The energetics of the reductive citric acid cycle in the pyrite-pulled surface metabolism in the early stage of evolution.

The chemoautotrophic theory concerning the origin of life postulates that a central role is played in the prebiotic chemical machinery by a reductive citric acid cycle operating without enzymes. The crucial point in this scenario is the formation of pyrite from hydrogen sulfide and ferrous sulfide, a reaction suggested to be linked to endergonic reactions, making them exergonic. This mechanism is believed to provide the driving force for the cycle to operate as a carbon dioxide fixation network. The present paper criticizes the thermodynamic calculations and their presentation in the original version of the archaic reductive citric acid cycle [Wächtershäuser, 1990. Evolution of the first metabolic cycles. Proc. Natl Acad. Sci. USA 87, 200-204.]. The most significant differences between the Wächtershäuser hypothesis and the present proposal: Wächtershäuser did not consider individual reactions in his calculations. A particularly questionable feature is the involvement of seven molecules of pyrite which does not emerge as a direct consequence of the chemical reactions presented in the archaic reductive citric acid cycle. The involvement of a considerable number of sulfur-containing organic intermediates as building blocks is also disputed. In the new scheme of the cycle proposed here, less free energy is liberated than hypothesized by Wächtershäuser, but it has the advantages that the free energy changes for the individual reactions can be calculated, the number of pyrite molecules involved in the cycle is reduced, and fewer sulfur-containing intermediates are required for the cycle to operate. In combination with a plausible route for the anaplerotic reactions [Kalapos, 1997a. Possible evolutionary role of methylglyoxalase pathway: anaplerotic route for reductive citric acid cycle of surface metabolists. J. Theor. Biol. 188, 201-206.], this new presentation of the cycle assigns a special meaning to hydrogen sulfide formation in the early stage of biochemical evolution.

[1]  S. Fox,et al.  Molecular evolution and the origin of life , 1972 .

[2]  B. Buchanan,et al.  A new ferredoxin-dependent carbon reduction cycle in a photosynthetic bacterium. , 1966, Proceedings of the National Academy of Sciences of the United States of America.

[3]  G. Wächtershäuser,et al.  Evolution of the first metabolic cycles. , 1990, Proceedings of the National Academy of Sciences of the United States of America.

[4]  G. Wächtershäuser,et al.  Before enzymes and templates: theory of surface metabolism. , 1988, Microbiological reviews.

[5]  G. Wächtershäuser,et al.  Groundworks for an evolutionary biochemistry: the iron-sulphur world. , 1992, Progress in biophysics and molecular biology.

[6]  L E Orgel,et al.  Self-organizing biochemical cycles. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[7]  Sidney W. Fox,et al.  The origins of prebiological systems and of their molecular matrices , 1965 .

[8]  S. Martin,et al.  Driving parts of Krebs cycle in reverse through mineral photochemistry. , 2006, Journal of the American Chemical Society.

[9]  G. Wächtershäuser,et al.  Pyrite Formation, the First Energy Source for Life: a Hypothesis , 1988 .

[10]  D. desmarais,et al.  Prebiotic organic syntheses and the origin of life , 1983 .

[11]  F. Anet The place of metabolism in the origin of life. , 2004, Current opinion in chemical biology.

[12]  M. Kalapos A theoretical approach to the link between oxidoreductions and pyrite formation in the early stage of evolution. , 2002, Biochimica et biophysica acta.

[13]  Two-dimensional life? , 1991, Proceedings of the National Academy of Sciences of the United States of America.

[14]  R. Thauer,et al.  Energy conservation in chemotrophic anaerobic bacteria , 1977, Bacteriological reviews.

[15]  G. Vidal Earth's Earliest Biosphere , 1985 .

[16]  J. William Schopf,et al.  Earth's earliest biosphere : its origin and evolution , 1983 .

[17]  F. Lipmann,et al.  Projecting Backward from the Present Stage of Evolution of Biosynthesis , 1965 .

[18]  G. Wächtershäuser Life in a ligand sphere. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[19]  R. Thauer Citric-acid cycle, 50 years on , 1988 .

[20]  H. Beinert,et al.  Iron-sulfur clusters: nature's modular, multipurpose structures. , 1997, Science.

[21]  WHEN DARWIN,et al.  The Origin of Life , 2019, Rethinking Evolution.

[22]  M. Saraste,et al.  Evolution of energetic metabolism: the respiration-early hypothesis. , 1995, Trends in biochemical sciences.

[23]  M. Kalapos,et al.  ON THE CHEMOTON THEORY , 1997 .

[24]  Efraim Racker,et al.  Mechanisms in bioenergetics , 1965 .

[25]  G. Cody TRANSITION METAL SULFIDES AND THE ORIGINS OF METABOLISM , 2004 .

[26]  Stanley L. Miller,et al.  The Origin and Early Evolution of Life: Prebiotic Chemistry, the Pre-RNA World, and Time , 1996, Cell.

[27]  P. Decker,et al.  Open Systems which Can Mutate between Several Steady States (“Bioids”) and a Possible Prebiological Role of the Autocatalytic Condensation of Formaldehyde / Offene Systeme die zwischen mehreren stationären Zuständen zu „mutieren” vermögen („Bioide”) und die präbiologische Rolle der autokatalytischen , 1972, Zeitschrift fur Naturforschung. Teil B. Anorganische Chemie, organische Chemie, Biochemie, Biophysik, Biologie.

[28]  B. Maden,et al.  No soup for starters? Autotrophy and the origins of metabolism. , 1995, Trends in biochemical sciences.

[29]  C. Duve Selection By Differential Molecular Survival - a Possible Mechanism of Early Chemical Evolution , 1987 .