Search results for "Deletion Mutation"

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Different rates of spontaneous mutation of chloroplastic and nuclear viroids as determined by high-fidelity ultra-deep sequencing

2017

[EN] Mutation rates vary by orders of magnitude across biological systems, being higher for simpler genomes. The simplest known genomes correspond to viroids, subviral plant replicons constituted by circular non-coding RNAs of few hundred bases. Previous work has revealed an extremely high mutation rate for chrysanthemum chlorotic mottle viroid, a chloroplastreplicating viroid. However, whether this is a general feature of viroids remains unclear. Here, we have used high-fidelity ultra-deep sequencing to determine the mutation rate in a common host (eggplant) of two viroids, each representative of one family: the chloroplastic eggplant latent viroid (ELVd, Avsunviroidae) and the nuclear pot…

0301 basic medicineMutation rateChloroplastsViroidvirusesPospiviroidaeArtificial Gene Amplification and ExtensionPlant ScienceSelf-CleavageVirus ReplicationBiochemistryPolymerase Chain ReactionGenomeDatabase and Informatics MethodsSequencing techniquesRibozymeNucleic AcidsRibozymesBiology (General)GeneticsHigh-Throughput Nucleotide Sequencingfood and beveragesRNA sequencingViroidsEnzymesAvsunviroidaeDeletion MutationVirusesPhysical SciencesRNA ViralIn-VivoSequence AnalysisResearch ArticleSubstitution MutationHammerhead RibozymesQH301-705.5Materials by StructureBioinformaticsEvolutionMaterials ScienceImmunologyPlant PathogensGenerationReplicationBiologyMicrobiology03 medical and health sciencesSequence Motif AnalysisVirologyGeneticsSolanum melongenaRNA-PolymeraseMolecular BiologyPotato spindle tuber viroidPlant DiseasesMatter030102 biochemistry & molecular biologyPoint mutationOrganismsBiology and Life SciencesProteinsRNAReverse Transcriptase-Polymerase Chain ReactionRC581-607Plant Pathologybiology.organism_classificationVirologyResearch and analysis methodsMolecular biology techniques030104 developmental biologyMutagenesisOligomersMutationEnzymologyRNAMotifParasitologyImmunologic diseases. AllergyPLOS Pathogens
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Why are viral genomes so fragile? The bottleneck hypothesis

2021

If they undergo new mutations at each replication cycle, why are RNA viral genomes so fragile, with most mutations being either strongly deleterious or lethal? Here we provide theoretical and numerical evidence for the hypothesis that genetic fragility is partly an evolutionary response to the multiple population bottlenecks experienced by viral populations at various stages of their life cycles. Modelling within-host viral populations as multi-type branching processes, we show that mutational fragility lowers the rate at which Muller’s ratchet clicks and increases the survival probability through multiple bottlenecks. In the context of a susceptible-exposed-infectious-recovered epidemiolog…

Evolutionary GeneticsRNA virusesMutation rateEpidemiologyExtinct GenomesMedicine and Health SciencesBiology (General)Genetics0303 health sciencesEvolutionary epidemiologyEcologyMicrobial MutationGenomicsDeletion MutationComputational Theory and MathematicsViral genomesGenetic EpidemiologyModeling and SimulationViral evolutionPopulation bottlenecksVirusesRNA ViralResearch ArticleQH301-705.5Genomics[SDV.CAN]Life Sciences [q-bio]/CancerContext (language use)Genome ViralBiologyMicrobiologyGenomic InstabilityViral EvolutionBottleneckEvolution Molecular03 medical and health sciencesCellular and Molecular NeuroscienceSurvival probabilityVirologyGeneticsFragilityMolecular BiologyEcology Evolution Behavior and Systematics030304 developmental biologyEvolutionary BiologyModels Genetic030306 microbiologyOrganismsComputational BiologyBiology and Life SciencesRNAVirus evolutionOrganismal EvolutionGenetic architecture[MATH.MATH-PR]Mathematics [math]/Probability [math.PR]Population bottleneckViral replicationMutationMicrobial Evolution
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