Search results for "phylodynamic"

showing 6 items of 6 documents

SARS-CoV-2 and COVID-19: A genetic, epidemiological, and evolutionary perspective

2020

In less than five months, COVID-19 has spread from a small focus in Wuhan, China, to more than 5 million people in almost every country in the world, dominating the concern of most governments and public health systems. The social and political distresses caused by this epidemic will certainly impact our world for a long time to come. Here, we synthesize lessons from a range of scientific perspectives rooted in epidemiology, virology, genetics, ecology and evolutionary biology so as to provide perspective on how this pandemic started, how it is developing, and how best we can stop it.

0301 basic medicineEconomic growth[SDV]Life Sciences [q-bio]Gene ExpressionSeverity of Illness IndexDisease OutbreaksBiological CoevolutionChiropteraPandemicEpidemiologyPhylogenyComputingMilieux_MISCELLANEOUSEutheriaPhylodynamics3. Good healthEuropeInfectious DiseasesHost susceptibilityHost-Pathogen InteractionsSpike Glycoprotein CoronavirusAngiotensin-Converting Enzyme 2Coronavirus InfectionsMicrobiology (medical)medicine.medical_specialtyAsiaCoronavirus disease 2019 (COVID-19)Pneumonia Viral030106 microbiologyFILOGENIAPeptidyl-Dipeptidase ABiologyMicrobiologyArticleBetacoronavirus03 medical and health sciencesPoliticsGeneticsmedicineAnimalsHumansChinaPandemicsMolecular BiologyEcology Evolution Behavior and SystematicsSARS-CoV-2Public healthPerspective (graphical)COVID-19Immunity InnateCoronavirusImmune system030104 developmental biologyViral phylodynamicsNorth AmericaCoevolution
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Quantifying transmission fitness costs of multi-drug resistant tuberculosis.

2021

As multi-drug resistant tuberculosis (MDR-TB) continues to spread, investigating the transmission potential of different drug-resistant strains becomes an ever more pressing topic in public health. While phylogenetic and transmission tree inferences provide valuable insight into possible transmission chains, phylodynamic inference combines evolutionary and epidemiological analyses to estimate the parameters of the underlying epidemiological processes, allowing us to describe the overall dynamics of disease spread in the population. In this study, we introduce an approach to Mycobacterium tuberculosis (M. tuberculosis) phylodynamic analysis employing an existing computationally efficient mod…

EpidemiologyComputer scienceAntibiotic resistance030231 tropical medicinePopulationAntitubercular AgentsInferenceInfectious and parasitic diseasesRC109-216Drug resistanceComputational biologyMicrobial Sensitivity TestsMicrobiologylaw.inventionMycobacterium tuberculosis03 medical and health sciencesMulti-type birth–death model0302 clinical medicinelawVirologyMulti-type birth-death modelTuberculosis Multidrug-ResistantmedicineHumans030212 general & internal medicineWhole genome M. tuberculosiseducationEpidemicsPhylogenyeducation.field_of_studybiologyPhylogenetic treeMulti-drug-resistant tuberculosisPublic Health Environmental and Occupational HealthAntibiotic resistance; Multi-type birth–death model; Phylodynamics; Whole genome M. tuberculosisMycobacterium tuberculosismedicine.diseasebiology.organism_classificationPhylodynamics614: Public Health und GesundheitsförderungInfectious DiseasesViral phylodynamicsTransmission (mechanics)ParasitologyEpidemics
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From molecular genetics to phylodynamics: evolutionary relevance of mutation rates across viruses.

2012

Although evolution is a multifactorial process, theory posits that the speed of molecular evolution should be directly determined by the rate at which spontaneous mutations appear. To what extent these two biochemical and population-scale processes are related in nature, however, is largely unknown. Viruses are an ideal system for addressing this question because their evolution is fast enough to be observed in real time, and experimentally-determined mutation rates are abundant. This article provides statistically supported evidence that the mutation rate determines molecular evolution across all types of viruses. Properties of the viral genome such as its size and chemical composition are…

Evolutionary Geneticslcsh:Immunologic diseases. AllergyMutation rateGenome evolutionImmunologyGenome ViralBiologyGenomeMicrobiologyEvolution Molecular03 medical and health sciencesMutation RateMolecular evolutionPhylogeneticsVirologyGeneticsMolecular BiologyBiologylcsh:QH301-705.5Phylogeny030304 developmental biologyGenetics0303 health sciencesEvolutionary BiologyModels Genetic030306 microbiologyMutagenesisMicrobial MutationBiological EvolutionViral phylodynamicslcsh:Biology (General)Viral evolutionVirusesParasitologylcsh:RC581-607Population GeneticsResearch ArticlePLoS Pathogens
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Evolutionary analysis of Citrus tristeza virus outbreaks in Calabria, Italy: two rapidly spreading and independent introductions of mild and severe i…

2014

The evolution of citrus tristeza virus (CTV) from outbreaks occurred in Calabria, Italy, was compared with that of CTV outbreaks reported previously in another two proximal Italian regions, Sicily and Apulia. Examination of four genomic regions (genes p20, p25 and p23, and one fragment of open reading frame 1) showed two recombination events, and phylogenetic analysis disclosed two divergent CTV groups in Calabria: one formed by severe and the other by mild isolates. This analysis, together with others involving population genetic parameters, revealed a low migration rate of CTV between the three Italian regions, as well as significant differences in selective pressures, epidemiology and de…

Geneticseducation.field_of_studyClosterovirusbiologyPhylogenetic treeMigration phylogeographyPopulationCTV phylodynamic CalabriaOutbreakCitrus tristeza virusSettore AGR/12 - Patologia VegetalePlant ScienceHorticulturebiology.organism_classificationVirologyRecombinationPhylogeneticsGenetic structureCTVClosteroviruseducationSelectionAgronomy and Crop SciencePhylogeny
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Emergence and Phylodynamics of Citrus tristeza virus in Sicily, Italy

2013

Citrus tristeza virus (CTV) outbreaks were detected in Sicily island, Italy for the first time in 2002. To gain insight into the evolutionary forces driving the emergence and phylogeography of these CTV populations, we determined and analyzed the nucleotide sequences of the p20 gene from 108 CTV isolates collected from 2002 to 2009. Bayesian phylogenetic analysis revealed that mild and severe CTV isolates belonging to five different clades (lineages) were introduced in Sicily in 2002. Phylogeographic analysis showed that four lineages co-circulated in the main citrus growing area located in Eastern Sicily. However, only one lineage (composed of mild isolates) spread to distant areas of Sici…

Nonsynonymous substitutionCitrusGenetic-variationLineage (evolution)Population Dynamicslcsh:MedicinePopulation geneticsPlant Sciencelcsh:SciencePhylogenetic analysesPhylogenyGeneticsMultidisciplinarybiologyPhylogenetic treeGeographyCitrus tristeza virusAgriculturePhylogeneticsItalyRNA ViralEvolutionary dynamicsCross-protectionSequence AnalysisResearch ArticleClosterovirusDNA ComplementaryMolecular Sequence DataPlant PathogensCropsMicrobiologyViral EvolutionFruitsGenetic driftSpecies SpecificityVirologyMosaic-virusGenetic variationCTV Phylodynamics SicilyEvolutionary SystematicsPopulation-structureHost passageBiologyPlant DiseasesEvolutionary BiologyMaximum-likelihoodlcsh:RSettore AGR/12 - Patologia VegetaleComputational BiologyGenetic VariationBayes TheoremSequence Analysis DNAPlant Pathologybiology.organism_classificationAgronomyViral phylodynamicsDNA polymorphismEvolutionary biologyMolecular evolutionlcsh:Q
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Phylodynamic Analysis and Implication of HCV Genotype 4 Variability on Antiviral Drug Response and T-Cell Recognition.

2020

Therapies for HCV care could change the prevalence and the geographic distribution of genotypes due to differences in Sustained Virologic Response (SVR). In this scenario, uncommon genotypes/subtypes, such as genotype 4, could spread from high-risk groups, replacing genotypes eradicated by antiviral drugs. Genotype eradication is also strongly influenced by the CD8+ T cell response. In this study, the genetic variability in HCV genotype 4 strains obtained from a cohort of 67 patients na&iuml

Settore MED/07 - Microbiologia E Microbiologia ClinicaT-Lymphocyteslcsh:QR1-502Bayesian analysisHepacivirusViral Nonstructural Proteinslcsh:MicrobiologyCoalescent theoryphylodynamicGenotypegenetic variabilityPhylogenyBayesian analysimedia_commonSettore MED/12 - Gastroenterologiavirus diseasesMiddle Agedviral epitopeHepatitis CHost-Pathogen InteractionInfectious Diseasesmedicine.anatomical_structureHost-Pathogen InteractionsHCVtMRCADrugAdultGenotypemedicine.drug_classmedia_common.quotation_subjectT cellmacromolecular substancesHuman leukocyte antigenBiologyAntiviral AgentsArticleYoung AdultT cell recognitionVirologyDrug Resistance ViralmedicineHumansGenetic variabilitygenotype 4AgedDAAAntiviral AgentHepaciviruVirologydigestive system diseasesviral epitopesAntiviral drugCD8RASViruses
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