Universal sequence replication, reversible polymerization and early functional biopolymers: a model for the initiation of prebiotic sequence evolution.

TitleUniversal sequence replication, reversible polymerization and early functional biopolymers: a model for the initiation of prebiotic sequence evolution.
Publication TypeJournal Article
Year of Publication2012
AuthorsWalker, SImari, Grover, MA, Hud, NV
JournalPLoS One
Volume7
Issue4
Paginatione34166
Date Published2012
ISSN1932-6203
KeywordsBiogenesis, Biological Evolution, Biopolymers, Desiccation, Diffusion, DNA Replication, Evolution, Chemical, Humidity, Kinetics, Models, Chemical, Monte Carlo Method, Polymerization, RNA Replicase
Abstract

Many models for the origin of life have focused on understanding how evolution can drive the refinement of a preexisting enzyme, such as the evolution of efficient replicase activity. Here we present a model for what was, arguably, an even earlier stage of chemical evolution, when polymer sequence diversity was generated and sustained before, and during, the onset of functional selection. The model includes regular environmental cycles (e.g. hydration-dehydration cycles) that drive polymers between times of replication and functional activity, which coincide with times of different monomer and polymer diffusivity. Template-directed replication of informational polymers, which takes place during the dehydration stage of each cycle, is considered to be sequence-independent. New sequences are generated by spontaneous polymer formation, and all sequences compete for a finite monomer resource that is recycled via reversible polymerization. Kinetic Monte Carlo simulations demonstrate that this proposed prebiotic scenario provides a robust mechanism for the exploration of sequence space. Introduction of a polymer sequence with monomer synthetase activity illustrates that functional sequences can become established in a preexisting pool of otherwise non-functional sequences. Functional selection does not dominate system dynamics and sequence diversity remains high, permitting the emergence and spread of more than one functional sequence. It is also observed that polymers spontaneously form clusters in simulations where polymers diffuse more slowly than monomers, a feature that is reminiscent of a previous proposal that the earliest stages of life could have been defined by the collective evolution of a system-wide cooperation of polymer aggregates. Overall, the results presented demonstrate the merits of considering plausible prebiotic polymer chemistries and environments that would have allowed for the rapid turnover of monomer resources and for regularly varying monomer/polymer diffusivities.

DOI10.1371/journal.pone.0034166
Alternate JournalPLoS ONE
PubMed ID22493682
PubMed Central IDPMC3320909