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Publicly Available Published by De Gruyter January 1, 2009

Chemical evolution toward the origin of life

  • Daniel Fitz , Hannes Reiner and Bernd Michael Rode

Abstract

Numerous hypotheses about how life on earth could have started can be found in the literature. In this article, we give an overview about the most widespread ones and try to point out which of them might have occurred on the primordial earth with highest probability from a chemical point of view. The idea that a very early stage of life was the "RNA world" encounters crucial problems concerning the formation of its building blocks and their stability in a prebiotic environment. Instead, it seems much more likely that a "peptide world" originated first and that RNA and DNA took up their part at a much later stage. It is shown that amino acids and peptides can be easily formed in a realistic primordial scenario and that these biomolecules can start chemical evolution without the help of RNA. The origin of biohomochirality seems strongly related to the most probable formation of the first peptides via the salt-induced peptide formation (SIPF) reaction.


Conference

Eurasia Conference on Chemical Sciences, 9th, Antalya, Turkey, 2006-09-09–2006-09-13


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