Chemical Basis of Carbon Fixation Autotrophic Paleometabolism

On the basis of biomimetic, phylometabolic, and thermodynamic analysis of modern CO 2 assimilation pathways, a paleophenotypic reconstruction of ancient autotrophic metabolism systems was carried out. As a chemical basis for CO 2 fixation paleometabolism, metabolic networks capable of self-reproduct...

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Veröffentlicht in:Biology bulletin of the Russian Academy of Sciences 2021-09, Vol.48 (5), p.519-529
Hauptverfasser: Marakushev, S. A., Belonogova, O. V.
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description On the basis of biomimetic, phylometabolic, and thermodynamic analysis of modern CO 2 assimilation pathways, a paleophenotypic reconstruction of ancient autotrophic metabolism systems was carried out. As a chemical basis for CO 2 fixation paleometabolism, metabolic networks capable of self-reproduction and evolution are considered, and the reversibility of the transformation reactions of its intermediates is the most important factor in self-development of this network. The substances of the C–H–O system, paragenetically associated with hydrocarbons, create a phase space, which is a set of universal intermediates of the autotrophic paleometabolism chemical network. The concept of two strategies for the origin and development of autotrophic carbon fixation paleometabolism in the oxidized (CO 2 ) and reduced (CH 4 ) redox regimes of degassing of the ancient Earth is proposed. It was shown that P, T, and the redox conditions of hydrothermal systems of the early Archean were favorable for the development of primary methanotrophic metabolism.
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subjects Biochemistry
Biomedical and Life Sciences
Carbon dioxide
Carbon dioxide fixation
Carbon fixation
Cell Biology
Ecology
Intermediates
Life Sciences
Metabolic networks
Metabolism
Theoretical and Evolutionary Biology
Zoology
title Chemical Basis of Carbon Fixation Autotrophic Paleometabolism
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