Search results for "Viral Evolution"

showing 10 items of 72 documents

Mechanisms of viral mutation

2016

The remarkable capacity of some viruses to adapt to new hosts and environments is highly dependent on their ability to generate de novo diversity in a short period of time. Rates of spontaneous mutation vary amply among viruses. RNA viruses mutate faster than DNA viruses, single-stranded viruses mutate faster than double-strand virus, and genome size appears to correlate negatively with mutation rate. Viral mutation rates are modulated at different levels, including polymerase fidelity, sequence context, template secondary structure, cellular microenvironment, replication mechanisms, proofreading, and access to post-replicative repair. Additionally, massive numbers of mutations can be intro…

0301 basic medicineMutation rateEvolutionMutation ratevirusesGenome ViralReviewBiologyVirus ReplicationGenetic diversityVirus03 medical and health sciencesCellular and Molecular NeuroscienceMolecular BiologySuppressor mutationRecombination GeneticPharmacologyGeneticsCell BiologyResistance mutationVirologyReplication fidelityVirusPost-replicative repair030104 developmental biologyViral replicationViral evolutionMutationVirusesMutation (genetic algorithm)Dynamic mutationMolecular MedicineHyper-mutationCellular and Molecular Life Sciences
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The role of spatial structure in the evolution of viral innate immunity evasion: A diffusion-reaction cellular automaton model

2020

Most viruses have evolved strategies for preventing interferon (IFN) secretion and evading innate immunity. Recent work has shown that viral shutdown of IFN secretion can be viewed as a social trait, since the ability of a given virus to evade IFN-mediated immunity depends on the phenotype of neighbor viruses. Following this idea, we investigate the role of spatial structure in the evolution of innate immunity evasion. For this, we model IFN signaling and viral spread using a spatially explicit approximation that combines a diffusion-reaction model and cellular automaton. Our results indicate that the benefits of preventing IFN secretion for a virus are strongly determined by spatial struct…

0301 basic medicinePhysiologyApoptosisVirus ReplicationBiochemistryVirionsEpitopes0302 clinical medicineInterferonMedicine and Health SciencesBiology (General)Innate Immune Systemeducation.field_of_studyCell DeathEcology3. Good healthCell biologyPhenotypeComputational Theory and MathematicsCell ProcessesModeling and SimulationViral evolutionHost-Pathogen InteractionsVirusesSignal TransductionResearch Articlemedicine.drugEvolutionary ImmunologyQH301-705.5ImmunologyPopulationViral StructureBiologyAntiviral AgentsMicrobiologyViral EvolutionVirusViral Proteins03 medical and health sciencesCellular and Molecular NeuroscienceImmunityVirologyGeneticsmedicineAnimalsHumansComputer SimulationSocial BehavioreducationMolecular BiologySecretionEcology Evolution Behavior and SystematicsImmune EvasionEvolutionary BiologyInnate immune systemVirionBiology and Life SciencesProteinsCell BiologyEvasion (ethics)Immunity InnateOrganismal Evolution030104 developmental biologyViral replicationImmune SystemMicrobial EvolutionInterferonsPhysiological Processes030217 neurology & neurosurgery
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Viral fitness correlates with the magnitude and direction of the perturbation induced in the host’s transcriptome: the tobacco etch Potyvirus—tobacco…

2018

Determining the fitness of viral genotypes has become a standard practice in virology as it is essential to evaluate their evolutionary potential. Darwinian fitness, defined as the advantage of a given genotype with respect to a reference one, is a complex property that captures, in a single figure, differences in performance at every stage of viral infection. To what extent does viral fitness result from specific molecular interactions with host factors and regulatory networks during infection? Can we identify host genes in functional classes whose expression depends on viral fitness? Here, we compared the transcriptomes of tobacco plants infected with seven genotypes of tobacco etch potyv…

0301 basic medicinePotyvirusViral fitnessGene ExpressionBiologyReal-Time Polymerase Chain ReactionHost-virus interactionModels BiologicalTranscriptome03 medical and health sciencesDarwinian FitnessTobaccoGene expressionGeneticsTranscriptomicsGeneMolecular BiologyDiscoveriesEcology Evolution Behavior and SystematicsPlant DiseasesNicotiana tabacum PotyvirusGeneticsNicotiana tabacumPotyvirusresponse to infection Systems biologyPotyvirusRNAMicroarray Analysisbiology.organism_classificationResponse to infectionVirus evolutionRNA silencing030104 developmental biologyViral evolutionHost-Pathogen InteractionsTEVGenetic FitnessTranscriptomeSystems biologyHost–virus interaction
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Different Within-Host Viral Evolution Dynamics in Severely Immunosuppressed Cases with Persistent SARS-CoV-2

2021

12 páginas, 2 figuras, 1 tabla.

0301 basic medicineQH301-705.5medicine.medical_treatment030106 microbiologyInmunologíaMedicine (miscellaneous)GenomicsSingle-nucleotide polymorphismDiseaseBiologyArticleGeneral Biochemistry Genetics and Molecular BiologyVirusdiversityPersistence03 medical and health sciencesmedicinegenomicsBiology (General)Evolutionary dynamicsimmunosuppressedDiversitySARS-CoV-2COVID-19ImmunosuppressionGenomicspersistencemedicine.diseaseVirologyviral viabilityLymphoma030104 developmental biologyImmunosuppressedViral evolutionViral viability
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Ortervirales: New Virus Order Unifying Five Families of Reverse-Transcribing Viruses

2018

International audience; Reverse-transcribing viruses, which synthesize a copy of genomic DNA from an RNA template, are widespread in animals, plants, algae, and fungi (1, 2). This broad distribution suggests the ancient origin(s) of these viruses, possibly [...]

0301 basic medicineS1retrovirusesviruses[SDV]Life Sciences [q-bio]ImmunologyretroviridaeMESH: Reverse TranscriptionL73 - Maladies des animauxVirus Replication[SDV.BID.SPT]Life Sciences [q-bio]/Biodiversity/Systematics Phylogenetics and taxonomyMicrobiologyVirusbelpaoviridaeMESH: Viruses03 medical and health sciencesVirologyinternational committee on taxonomy of viruses (ICTV)Metaviridaevirus classificationLetter to the EditorVirus classificationGeneticsTy3/Gypsy and Ty1/Copia LTR retrotransposonscaulimoviridaevirus evolutionbiologyfungiMESH: Virus ReplicationRNAPseudoviridaeReverse Transcriptionbiology.organism_classificationMESH: Caulimoviridaegenomic DNA030104 developmental biologyMESH: RetroviridaeMESH: HepadnaviridaeInsect ScienceViral evolutionhepadnaviridaeBelpaoviridae; Caulimoviridae; Hepadnaviridae; International Committee on Taxonomy of Viruses (ICTV); Metaviridae; Pseudoviridae; Retroviridae; Ty3/Gypsy and Ty1/Copia LTR retrotransposons; retroviruses; virus classification; virus evolutionViruses[SDV.MP.VIR]Life Sciences [q-bio]/Microbiology and Parasitology/VirologymetaviridaeCaulimoviridaepseudoviridae
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Constrained evolvability of interferon suppression in an RNA virus.

2016

AbstractInnate immunity responses controlled by interferon (IFN) are believed to constitute a major selective pressure shaping viral evolution. Viruses encode a variety of IFN suppressors, but these are often multifunctional proteins that also play essential roles in other steps of the viral infection cycle, possibly limiting their evolvability. Here, we experimentally evolved a vesicular stomatitis virus (VSV) mutant carrying a defect in the matrix protein (M∆51) that abolishes IFN suppression and that has been previously used in the context of oncolytic virotherapy. Serial transfers of this virus in normal, IFN-secreting cells led to a modest recovery of IFN blocking capacity and to weak …

0301 basic medicineviruses030106 microbiologyAdaptation BiologicalBiologyVirus ReplicationModels BiologicalVirusArticleCell Line03 medical and health sciencesViral ProteinsRNA Virus InfectionsInterferonmedicineHumansRNA VirusesPhosphorylationMultidisciplinaryViral matrix proteinInterferon SuppressionGenetic Variationbiology.organism_classificationVirologyBiological EvolutionImmunity InnateOncolytic virus030104 developmental biologyViral replicationVesicular stomatitis virusViral evolutionMutationInterferonsmedicine.drugScientific reports
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A putative antiviral role of plant cytidine deaminases

2014

[Background]: A mechanism of innate antiviral immunity operating against viruses infecting mammalian cells has been described during the last decade. Host cytidine deaminases (e.g., APOBEC3 proteins) edit viral genomes, giving rise to hypermutated nonfunctional viruses; consequently, viral fitness is reduced through lethal mutagenesis. By contrast, sub-lethal hypermutagenesis may contribute to virus evolvability by increasing population diversity. To prevent genome editing, some viruses have evolved proteins that mediate APOBEC3 degradation. The model plant Arabidopsis thaliana genome encodes nine cytidine deaminases ( AtCDAs), raising the question of whether deamination is an antiviral mec…

0301 basic medicinevirusesPopulation030106 microbiologyDeaminationAntiviral innate immunityGenomeGeneral Biochemistry Genetics and Molecular BiologyVirusError catastrophePararetrovirusGene product03 medical and health scienceschemistry.chemical_compoundPlant-virus interactionGenome editingPlant-Environment InteractionsVirologyHypermutagenesisArabidopsis thalianaGeneral Pharmacology Toxicology and PharmaceuticseducationGeneGeneticseducation.field_of_studyCauliflower mosaic virusGeneral Immunology and MicrobiologybiologyHost (biology)fungifood and beveragesCytidineGeneral MedicineArticlesbiology.organism_classificationVirologyVirus evolution030104 developmental biologychemistryMutational spectrumPlant Genetics & Gene ExpressionViral evolutionCauliflower mosaic virusResearch Article
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2019

Viruses frequently spread among cells or hosts in groups, with multiple viral genomes inside the same infectious unit. These collective infectious units can consist of multiple viral genomes inside the same virion, or multiple virions inside a larger structure such as a vesicle. Collective infectious units deliver multiple viral genomes to the same cell simultaneously, which can have important implications for viral pathogenesis, antiviral resistance, and social evolution. However, little is known about why some viruses transmit in collective infectious units, whereas others do not. We used a simple evolutionary approach to model the potential costs and benefits of transmitting in a collect…

0303 health sciencesCancer Research030306 microbiologyvirusesViral pathogenesisAntiviral resistanceBiologyVirologyGenome03 medical and health sciencesInfectious DiseasesMultiplicity of infectionViral replicationViral genomesVirologyViral evolution030304 developmental biologyVirus Research
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Experimental virus evolution in cancer cell monolayers, spheroids, and tissue explants

2021

Viral laboratory evolution has been used for different applications, such as modeling viral emergence, drug-resistance prediction, and therapeutic virus optimization. However, these studies have been mainly performed in cell monolayers, a highly simplified environment, raising concerns about their applicability and relevance. To address this, we compared the evolution of a model virus in monolayers, spheroids, and tissue explants. We performed this analysis in the context of cancer virotherapy by performing serial transfers of an oncolytic vesicular stomatitis virus (VSV-Δ51) in 4T1 mouse mammary tumor cells. We found that VSV-Δ51 gained fitness in each of these three culture systems, and t…

0303 health sciencesOncolytic virusAcademicSubjects/SCI01130AcademicSubjects/SCI02285SpheroidContext (language use)Biologybiology.organism_classificationMicrobiologyVirusCell biologyOncolytic virus03 medical and health sciences0302 clinical medicineExperimental evolutionVesicular stomatitis virus030220 oncology & carcinogenesisVirologyViral evolutionVesicular stomatitis virusCancer cellAcademicSubjects/MED00860VirotherapyResearch Article030304 developmental biology
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Five Challenges in the Field of Viral Diversity and Evolution

2021

Viral diversity and evolution play a central role in processes such as disease emergence, vaccine failure, drug resistance, and virulence. However, significant challenges remain to better understand and manage these processes. Here, we discuss five of these challenges. These include improving our ability to predict viral evolution, developing more relevant experimental evolutionary systems, integrating viral dynamics and evolution at different scales, more thoroughly characterizing the virosphere, and deepening our understanding of virus-virus interactions. Intensifying future research on these areas should improve our ability to combat viral diseases, as well as to more efficiently use vir…

0303 health sciencesViral metagenomicsExperimental evolutionField (physics)030306 microbiologymedia_common.quotation_subjectvirusesGeneral MedicineBiology3. Good health03 medical and health sciencesEvolutionary biologyViral evolutioninternationalPlan_S-Compliant_OA030304 developmental biologyDiversity (politics)media_commonFrontiers in Virology
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