• Title of article

    Entropy and Charge in Molecular Evolution—the Case of Phosphate

  • Author/Authors

    Arrhenius، نويسنده , , G. and Sales، نويسنده , , B. and Mojzsis، نويسنده , , S. and Lee، نويسنده , , T.، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 1997
  • Pages
    20
  • From page
    503
  • To page
    522
  • Abstract
    Biopoesis, the creation of life, implies molecular evolution from simple components, randomly distributed and in a dilute state, to form highly organized, concentrated systems capable of metabolism, replication and mutation. This chain of events must involve environmental processes that can locally lower entropy in several steps; by specific selection from an indiscriminate mixture, by concentration from dilute solution, and in the case of the mineral-induced processes, by particular effectiveness in ordering and selective reaction, directed toward formation of functional biomolecules. us circumstances provide support for the notion that negatively charged molecules were functionally required and geochemically available for biopoesis. Sulfate ion may have been important in bisulfite complex formation with simple aldehydes, facilitating the initial concentration by sorption of aldehydes in positively charged surface active minerals. Borate ion may have played a similar, albeit less investigated role in forming charged sugar complexes. anionic species, oligophosphate ions and charged phosphate esters are likely to have been of even more wide ranging importance, reflected in the continued need for phosphate in a proposed RNA world, and extending its central role to evolved biochemistry. Phosphorylation is shown to result in selective concentration by surface sorption of compounds otherwise too dilute to support condensation reaction. It provides protection against rapid hydrolysis of sugars and, by selective concentration, induces the oligomerization of aldehydes. As a manifestation of the life arisen, phosphate already appears in an organic context in the oldest preserved sedimentary record.
  • Journal title
    Journal of Theoretical Biology
  • Serial Year
    1997
  • Journal title
    Journal of Theoretical Biology
  • Record number

    1533281