Computer simulation on the cooperation of functional molecules during the early stages of evolution

Computer simulation on the cooperation of functional molecules during the early stages of evolution

It is very likely that life began with some RNA (or RNA-like) molecules, self-replicating by base-pairing and exhibiting enzyme-like functions that favored the self-replication. Different functional molecules may have emerged by favoring their own self-replication at different aspects. Then, a direc...

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Bibliographic Details
Published in:PloS one 2012-04, Vol.7 (4), p.e35454-e35454
Main Authors: Ma, Wentao, Hu, Jiming
Format: Article
Language:eng
Subjects:
Acids
Analysis
Animals
Biological Evolution
Biology
Catalysis
Chemistry
Coexistence
Computer Science
Computer Simulation
Computer-generated environments
Cooperation
Dispersal
Emergence
Enzymes
Evolution
Evolutionary genetics
Fatty acids
Genes
Hypotheses
Metabolism
Monte Carlo method
Monte Carlo methods
Nucleotides
Phospholipids
Physiological aspects
Polymers
Prebiotics
Raw materials
Replicating
Replication
Ribonucleic acid
RNA
Simulation
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Summary:It is very likely that life began with some RNA (or RNA-like) molecules, self-replicating by base-pairing and exhibiting enzyme-like functions that favored the self-replication. Different functional molecules may have emerged by favoring their own self-replication at different aspects. Then, a direct route towards complexity/efficiency may have been through the coexistence/cooperation of these molecules. However, the likelihood of this route remains quite unclear, especially because the molecules would be competing for limited common resources. By computer simulation using a Monte-Carlo model (with "micro-resolution" at the level of nucleotides and membrane components), we show that the coexistence/cooperation of these molecules can occur naturally, both in a naked form and in a protocell form. The results of the computer simulation also lead to quite a few deductions concerning the environment and history in the scenario. First, a naked stage (with functional molecules catalyzing template-replication and metabolism) may have occurred early in evolution but required high concentration and limited dispersal of the system (e.g., on some mineral surface); the emergence of protocells enabled a "habitat-shift" into bulk water. Second, the protocell stage started with a substage of "pseudo-protocells", with functional molecules catalyzing template-replication and metabolism, but still missing the function involved in the synthesis of membrane components, the emergence of which would lead to a subsequent "true-protocell" substage. Third, the initial unstable membrane, composed of prebiotically available fatty acids, should have been superseded quite early by a more stable membrane (e.g., composed of phospholipids, like modern cells). Additionally, the membrane-takeover probably occurred at the transition of the two substages of the protocells. The scenario described in the present study should correspond to an episode in early evolution, after the emergence of single "genes", but before the appearance of a "chromosome" with linked genes.
ISSN:1932-6203
1932-6203