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Author
dc.contributor.author
B, Könnyű 
Author
dc.contributor.author
T, Czárán 
Availability Date
dc.date.accessioned
2023-07-21T07:03:06Z
Availability Date
dc.date.available
2023-07-21T07:03:06Z
Release
dc.date.issued
2011
uri
dc.identifier.uri
http://hdl.handle.net/10831/91098
Abstract
dc.description.abstract
The chemical machinery of life must have been catalytic from the outset. Models of the chemical origins have attempted to explain the ecological mechanisms maintaining a minimum necessary diversity of prebiotic replicator enzymes, but little attention has been paid so far to the evolutionary initiation of that diversity. We propose a possible first step in this direction: based on our previous model of a surface-bound metabolic replicator system we try to explain how the adaptive specialization of enzymatic replicator populations might have led to more diverse and more efficient communities of cooperating replicators with two different enzyme activities. The key assumptions of the model are that mutations in the replicator population can lead towards a) both of the two different enzyme specificities in separate replicators: efficient ‘‘specialists’’ or b) a ‘‘generalist’’ replicator type with both enzyme specificities working at less efficiency, or c) a fast-replicating, non-enzymatic ‘‘parasite’’. We show that under realistic trade-off constraints on the phenotypic effects of these mutations the evolved replicator community will be usually composed of both types of specialists and of a limited abundance of parasites, provided that the replicators can slowly migrate on the mineral surface. It is only at very weak trade-offs that generalists take over in a phase-transition-like manner. The parasites do not seriously harm the system but can freely mutate, therefore they can be considered as pre-adaptations to later, useful functions that the metabolic system can adopt to increase its own fitness.
Language
dc.language
Angol

dc.rights
Nevezd meg! CC BY

dc.rights.uri
https://creativecommons.org/licenses/by/4.0/
Title
dc.title
The evolution of enzyme specificity in the Metabolic Replikcator Model of prebiotic evolution
Type
dc.type
folyóiratcikk
Date Change
dc.date.updated
2023-07-21T07:00:00Z
Note
dc.description.note
Cited By :20 Export Date: 21 September 2022 Correspondence Address: Czárán, T.; Theoretical Biology and Ecology Research Group, , Budapest, Hungary; email: czaran@ludens.elte.hu
Scope
dc.format.page
e20931-e20931
Doi ID
dc.identifier.doi
https://doi.org/10.1371/journal.pone.0020931
Wos ID
dc.identifier.wos
000291734100033
ID Scopus
dc.identifier.scopus
79959294119
MTMT ID
dc.identifier.mtmt
1869363
Issue Number
dc.identifier.issue
6
abbreviated journal
dc.identifier.jabbrev
PLOS ONE
Journal
dc.identifier.jtitle
PLOS ONE
Volume Number
dc.identifier.volume
6
Release Date
dc.description.issuedate
2011
Pubmed ID
dc.identifier.pubmed
21698204
department of Author
dc.contributor.institution
Növényrendszertani, Ökológiai és Elméleti Biológiai Tanszék
department of Author
dc.contributor.institution
MTA-ELTE Elméleti Biológiai és Evolúciós Ökológiai Kutatócsoport
department of Author
dc.contributor.institution
MTA-ELTE Elméleti Biológiai és Ökológiai Kutatócsoport
department of Author
dc.contributor.institution
Növényrendszertani és Ökológiai Tanszék
department of Author
dc.contributor.institution
Evolúciós GINOP Csoport
Author institution
dc.contributor.department
Növényrendszertani és Ökológiai Tanszék
Author institution
dc.contributor.department
MTA-ELTE Elméleti Biológiai és Ökológiai Kutatócsoport


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The evolution of enzyme specificity in the Metabolic Replikcator Model of prebiotic evolution
 

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Nevezd meg! CC BY
Except where otherwise noted, this item's license is described as Nevezd meg! CC BY