Viral genome segmentation can result from a trade-off between genetic content and particle stability

The evolutionary benefit of viral genome segmentation is a classical, yet unsolved question in evolutionary biology and RNA genetics. Theoretical studies anticipated that replication of shorter RNA segments could provide a replicative advantage over standard size genomes. However, this question has...

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Bibliographic Details
Published in:PLoS genetics 2011-03, Vol.7 (3), p.e1001344-e1001344
Main Authors: Ojosnegros, Samuel, García-Arriaza, Juan, Escarmís, Cristina, Manrubia, Susanna C, Perales, Celia, Arias, Armando, Mateu, Mauricio García, Domingo, Esteban
Format: Article
Language:English
Subjects:
Animals
Atoms & subatomic particles
Cell culture
Cell Line
Computational Biology/Evolutionary Modeling
Computer Simulation
Cricetinae
Evolutionary biology
Experiments
Foot-and-mouth disease virus
Foot-and-Mouth Disease Virus - genetics
Foot-and-Mouth Disease Virus - metabolism
Foot-and-Mouth Disease Virus - pathogenicity
Genetic aspects
Genetic Fitness - genetics
Genetics
Genetics and Genomics/Microbial Evolution and Genomics
Genome, Viral - genetics
Genomes
Genomics
Kinetics
Microbial Viability - genetics
Models, Biological
Physiological aspects
Plasmids
Population
Proteins
RNA
RNA - biosynthesis
RNA, Viral - genetics
Viral Proteins - biosynthesis
Virion - metabolism
Virology/Virus Evolution and Symbiosis
Virus Replication - genetics
Viruses
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Summary:The evolutionary benefit of viral genome segmentation is a classical, yet unsolved question in evolutionary biology and RNA genetics. Theoretical studies anticipated that replication of shorter RNA segments could provide a replicative advantage over standard size genomes. However, this question has remained elusive to experimentalists because of the lack of a proper viral model system. Here we present a study with a stable segmented bipartite RNA virus and its ancestor non-segmented counterpart, in an identical genomic nucleotide sequence context. Results of RNA replication, protein expression, competition experiments, and inactivation of infectious particles point to a non-replicative trait, the particle stability, as the main driver of fitness gain of segmented genomes. Accordingly, measurements of the volume occupation of the genome inside viral capsids indicate that packaging shorter genomes involves a relaxation of the packaging density that is energetically favourable. The empirical observations are used to design a computational model that predicts the existence of a critical multiplicity of infection for domination of segmented over standard types. Our experiments suggest that viral segmented genomes may have arisen as a molecular solution for the trade-off between genome length and particle stability. Genome segmentation allows maximizing the genetic content without the detrimental effect in stability derived from incresing genome length.
ISSN:1553-7404
1553-7390
1553-7404
DOI:10.1371/journal.pgen.1001344