Origin of Life and the Phosphate Transfer Catalyst

In this paper, we revisit several issues relevant to origin-of-life research and propose a Phosphate Transfer Catalyst hypothesis that furthers our understanding of some of the key events in prebiotic chemical evolution. In the Phosphate Transfer Catalyst hypothesis, we assume the existence of hypot...

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Veröffentlicht in:	Astrobiology 2017-03, Vol.17 (3), p.277-285
Hauptverfasser:	Piast, Radosław W, Wieczorek, Rafał M
Format:	Artikel
Sprache:	eng
Schlagworte:	Amino acids Astrobiology Catalysis Catalysts Chemical evolution Energy Energy consumption Energy resources Energy sources Genetic code Hypotheses Models, Theoretical Nucleic acids Nucleic Acids - chemistry Nucleosides Nucleotides Origin of Life Peptides - chemistry Phosphate Phosphates Phosphates - chemistry Polymerization Polyphosphates Prebiotics Ribosomes Substrates
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creator	Piast, Radosław W Wieczorek, Rafał M
description	In this paper, we revisit several issues relevant to origin-of-life research and propose a Phosphate Transfer Catalyst hypothesis that furthers our understanding of some of the key events in prebiotic chemical evolution. In the Phosphate Transfer Catalyst hypothesis, we assume the existence of hypothetical metallopeptides with phosphate transfer activity that use abundant polyphosphates as both substrates and energy sources. Nonspecific catalysis by this phosphate transfer catalyst would provide a variety of different products such as phosphoryl amino acids, nucleosides, polyphosphate nucleotides, nucleic acids, and aminoacylated nucleic acids. Moreover, being an autocatalytic set and metabolic driver at the same time, it could possibly replicate itself and produce a collective system of two polymerases; a nucleic acid able to catalyze peptide bond formation and a peptide able to polymerize nucleic acids. The genetic code starts at first as a system that reduces the energy barrier by bringing substrates (2'/3' aminoacyl-nucleotides) together, an ancestral form of the catalysis performed by modern ribosomes. Key Words: Origin of life-Prebiotic chemistry-Catalysis-Nucleic acids. Astrobiology 17, 277-285.
doi_str_mv	10.1089/ast.2015.1463
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subjects	Amino acids Astrobiology Catalysis Catalysts Chemical evolution Energy Energy consumption Energy resources Energy sources Genetic code Hypotheses Models, Theoretical Nucleic acids Nucleic Acids - chemistry Nucleosides Nucleotides Origin of Life Peptides - chemistry Phosphate Phosphates Phosphates - chemistry Polymerization Polyphosphates Prebiotics Ribosomes Substrates
title	Origin of Life and the Phosphate Transfer Catalyst
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