2014
Complementation for an essential ancillary non-structural protein function across parvovirus genera
Mihaylov IS, Cotmore SF, Tattersall P. Complementation for an essential ancillary non-structural protein function across parvovirus genera. Virology 2014, 468: 226-237. PMID: 25194919, PMCID: PMC4254310, DOI: 10.1016/j.virol.2014.07.043.Peer-Reviewed Original ResearchConceptsCell cycle progressionAncillary proteinsProtein functionDNA replicationReplication centersNP1 proteinPrimary sequenceFunctional overlapProtein NS2Cycle progressionGenus BocaparvovirusGenus ProtoparvovirusLate defectsNP1 inductionParvovirus genusVirion productionMinute virusSpecific defectsCell populationsUninfected cellsGenusCell viabilityProteinHuman bocavirus 1NP1 expression
2011
Mutations at the Base of the Icosahedral Five-Fold Cylinders of Minute Virus of Mice Induce 3′-to-5′ Genome Uncoating and Critically Impair Entry Functions
Cotmore SF, Tattersall P. Mutations at the Base of the Icosahedral Five-Fold Cylinders of Minute Virus of Mice Induce 3′-to-5′ Genome Uncoating and Critically Impair Entry Functions. Journal Of Virology 2011, 86: 69-80. PMID: 22013064, PMCID: PMC3255873, DOI: 10.1128/jvi.06119-11.Peer-Reviewed Original ResearchConceptsSubgenomic DNAWild typeAnalysis of progenyMinute virusVP2 N-terminusDNA genomeAccumulation of virionsUncoating reactionGenome releaseImpaired mutantsEndosomal compartmentsEntry defectN-terminusVirion assemblyMutantsProtein capsidGenome uncoatingCation depletionBilayer penetrationCell entryDNAGenomeVP1 domainTerminusProteolysis
2010
Recruitment of DNA replication and damage response proteins to viral replication centers during infection with NS2 mutants of Minute Virus of Mice (MVM)
Ruiz Z, Mihaylov IS, Cotmore SF, Tattersall P. Recruitment of DNA replication and damage response proteins to viral replication centers during infection with NS2 mutants of Minute Virus of Mice (MVM). Virology 2010, 410: 375-384. PMID: 21193212, PMCID: PMC3072075, DOI: 10.1016/j.virol.2010.12.009.Peer-Reviewed Original ResearchConceptsViral replication centersDamage responseReplication centersDamage response proteinsMutant infectionDNA damage responsePhosphorylation of ATRNS2 mutantsProtein recruitmentViral DNA amplificationATM activationCellular proteinsDNA replicationReplication factorsResponse proteinsBody maturationA9 cellsMVM infectionMinute virusWidespread associationWestern transferDNA amplificationMechanism of actionProteinRecruitment
2001
The Left-End and Right-End Origins of Minute Virus of Mice DNA Differ in Their Capacity to Direct Episomal Amplification and Integration In Vivo
Corsini J, Cotmore S, Tattersall P, Winocour E. The Left-End and Right-End Origins of Minute Virus of Mice DNA Differ in Their Capacity to Direct Episomal Amplification and Integration In Vivo. Virology 2001, 288: 154-163. PMID: 11543668, DOI: 10.1006/viro.2001.1076.Peer-Reviewed Original Research
1997
A novel cellular site-specific DNA-binding protein cooperates with the viral NS1 polypeptide to initiate parvovirus DNA replication
Christensen J, Cotmore S, Tattersall P. A novel cellular site-specific DNA-binding protein cooperates with the viral NS1 polypeptide to initiate parvovirus DNA replication. Journal Of Virology 1997, 71: 1405-1416. PMID: 8995666, PMCID: PMC191197, DOI: 10.1128/jvi.71.2.1405-1416.1997.Peer-Reviewed Original ResearchConceptsReplication protein AProliferating-cell nuclear antigenOrigin replicationDNA replicationSite-specific DNA-binding proteinRecombinant replication protein AUV cross-linking analysisParvovirus DNA replicationDNA-binding proteinsSequence-specific DNACross-linking analysisSimian virus 40 replicationParvovirus initiation factorCellular proteinsInitiation factorsTranscription factorsEndonuclease functionMinimal originGel shiftMVM replicationNS1 polypeptideSpecific nickingS100 extractsSite regionDNA proceeds
1995
Minute virus of mice transcriptional activator protein NS1 binds directly to the transactivation region of the viral P38 promoter in a strictly ATP-dependent manner
Christensen J, Cotmore S, Tattersall P. Minute virus of mice transcriptional activator protein NS1 binds directly to the transactivation region of the viral P38 promoter in a strictly ATP-dependent manner. Journal Of Virology 1995, 69: 5422-5430. PMID: 7636987, PMCID: PMC189388, DOI: 10.1128/jvi.69.9.5422-5430.1995.Peer-Reviewed Original ResearchMeSH KeywordsAdenosine TriphosphateAnimalsBase SequenceBinding SitesCell LineDeoxyribonuclease IDNA, ViralGenes, ViralGenetic VectorsGenome, ViralMinute virus of miceMolecular Sequence DataNucleopolyhedrovirusesPlasmidsPromoter Regions, GeneticRecombinant ProteinsSpodopteraTranscriptional ActivationTransfectionViral Nonstructural ProteinsViral ProteinsConceptsATP-dependent mannerGamma S-ATPTransactivation regionP38 promoterCognate sitesDNA fragmentsNS1 bindsCore DNA sequenceCarboxy-terminal peptidePotent transcriptional activatorMinute virusS-ATPTranscriptional activatorMVM genomeATP bindingTAR sequenceTATA boxDNA sequencesATP hydrolysisBiochemical stepsBp 5DNase INS1 polypeptideTAR bindingAntibodies
1992
Expression of functional parvoviral NS1 from recombinant vaccinia virus: Effects of mutations in the nucleotide-binding motif
Noesch J, Cotmore S, Tattersall P. Expression of functional parvoviral NS1 from recombinant vaccinia virus: Effects of mutations in the nucleotide-binding motif. Virology 1992, 191: 406-416. PMID: 1413512, DOI: 10.1016/0042-6822(92)90202-z.Peer-Reviewed Original ResearchMeSH KeywordsAmino Acid SequenceAnimalsBase SequenceBiological TransportBlotting, WesternCell LineCell NucleusCloning, MolecularDNA ReplicationDNA, ViralGenes, ViralHumansMiceMinute virus of miceMolecular Sequence DataPlasmidsPolymerase Chain ReactionRecombinant ProteinsTranscriptional ActivationVaccinia virusViral Nonstructural ProteinsConceptsWild-type NS1Mutant formsEfficient cap-independent translationVaccinia thymidine kinase geneNucleotide-binding motifCap-independent translationBacteriophage T7 promoterT7 RNA polymeraseEffects of mutationsThymidine kinase geneExpression of NS1Recombinant vaccinia virusP38 promoterRNA polymeraseReplicative proteinsChromosomal sitesLysine codonPurine triphosphatesKinase geneT7 promoterUntranslated regionMouse cellsNuclear extractsVaccinia virusVTF7-3Two amino acid substitutions within the capsid are coordinately required for acquisition of fibrotropism by the lymphotropic strain of minute virus of mice
Ball-Goodrich L, Tattersall P. Two amino acid substitutions within the capsid are coordinately required for acquisition of fibrotropism by the lymphotropic strain of minute virus of mice. Journal Of Virology 1992, 66: 3415-3423. PMID: 1316457, PMCID: PMC241122, DOI: 10.1128/jvi.66.6.3415-3423.1992.Peer-Reviewed Original ResearchConceptsRestrictive infectionDouble mutant virusLymphotropic strainViral life cycleMinute virusInfectionImmunosuppressive strainFibroblast infectionVirusParvovirus minute virusMutant virusA9 fibroblastsCodon 317MiceCodon 321Amino acid substitutionsFibroblastsSame cellsCapsid geneCellsGene expressionAcid substitutionsSynergistic interactionNucleotide changesA9 cells
1991
Parvoviral target cell specificity: Acquisition of fibrotropism by a mutant of the lymphotropic strain of minute virus of mice involves multiple amino acid substitutions within the capsid
Ball-Goodrich L, Moir R, Tattersall P. Parvoviral target cell specificity: Acquisition of fibrotropism by a mutant of the lymphotropic strain of minute virus of mice involves multiple amino acid substitutions within the capsid. Virology 1991, 184: 175-186. PMID: 1871965, DOI: 10.1016/0042-6822(91)90834-x.Peer-Reviewed Original ResearchConceptsCoat protein geneProtein geneA9 fibroblastsInfectious cloneAmino acidsSite-directed mutagenesisMinute virusMultiple amino acid substitutionsSingle base changeAmino acid substitutionsGlutamic acid residuesSame amino acidsMouse A9 fibroblastsDouble mutantSame small regionA9 cellsHost rangeAcid residuesMutantsAcid substitutionsT lymphocyte cell lineDNA sequencingRecombinants
1990
Susceptibility of human cells to killing by the parvoviruses H-1 and minute virus of mice correlates with viral transcription
Cornelis J, Chen Y, Spruyt N, Duponchel N, Cotmore S, Tattersall P, Rommelaere J. Susceptibility of human cells to killing by the parvoviruses H-1 and minute virus of mice correlates with viral transcription. Journal Of Virology 1990, 64: 2537-2544. PMID: 2139892, PMCID: PMC249429, DOI: 10.1128/jvi.64.6.2537-2544.1990.Peer-Reviewed Original ResearchConceptsViral mRNAsHuman cellsLevel of transcriptionMinute virusMajor viral transcriptViral DNA amplificationNonstructural polypeptidesGene productsOncogenic transformationGene expressionIntracellular localizationNonstructural proteinsViral transcriptionViral transcriptsTranscriptionViral genomeParvovirus HCell susceptibilityHuman fibroblastsVirus uptakeEpithelial cellsDNA amplificationResistant derivativesKeratinocyte lineDifferential susceptibility
1988
The terminal protein of minute virus of mice is an 83 kilodalton polypeptide linked to specific forms of double‐stranded and single‐stranded viral DNA
Gunther M, Tattersall P. The terminal protein of minute virus of mice is an 83 kilodalton polypeptide linked to specific forms of double‐stranded and single‐stranded viral DNA. FEBS Letters 1988, 242: 22-26. PMID: 3203742, DOI: 10.1016/0014-5793(88)80977-3.Peer-Reviewed Original ResearchEvidence that developmentally regulated control of gene expression by a parvoviral allotropic determinant is particle mediated
Gardiner E, Tattersall P. Evidence that developmentally regulated control of gene expression by a parvoviral allotropic determinant is particle mediated. Journal Of Virology 1988, 62: 1713-1722. PMID: 3357208, PMCID: PMC253210, DOI: 10.1128/jvi.62.5.1713-1722.1988.Peer-Reviewed Original ResearchConceptsProgeny virusIncoming viral capsidInfectious molecular cloneViral transcriptionInfectious centersAllotropic determinantHost cell susceptibilityImmunosuppressive strainAutonomous parvovirus minute virusMolecular cloneCell susceptibilityViral RNASame low levelVirusParvovirus minute virusCell linesRescue of virusPhenotype characteristicViral DNAIntracellular factorsDifferent infectivitySimilar numberFibroblastsMinute virusMouse cell lines
1986
The NS-1 polypeptide of the autonomous parvovirus MVM is a nuclear phosphoprotein
Cotmore S, Tattersall P. The NS-1 polypeptide of the autonomous parvovirus MVM is a nuclear phosphoprotein. Virus Research 1986, 4: 243-250. PMID: 3739422, DOI: 10.1016/0168-1702(86)90003-1.Peer-Reviewed Original ResearchConceptsParvovirus MVMNS-1 proteinVitro translation productsMessenger RNA speciesNS-1 polypeptideSame primary sequencePeptide map analysisNon-structural proteinsRNA speciesNuclear phosphoproteinReplication complexTranslation productsKb transcriptPrimary sequenceVivo productNS-1SpeciesProteinPredominant formPhosphoproteinMVMTranscriptsPolypeptideNucleusMap analysis
1984
Formation of a host range mutant of the lymphotropic strain of minute virus of mice during persistent infection in mouse L cells
Ron D, Tattersall P, Tal J. Formation of a host range mutant of the lymphotropic strain of minute virus of mice during persistent infection in mouse L cells. Journal Of Virology 1984, 52: 63-69. PMID: 6090711, PMCID: PMC254489, DOI: 10.1128/jvi.52.1.63-69.1984.Peer-Reviewed Original ResearchConceptsLymphotropic strainPersistent infectionL cellsMinute virusT lymphocyte cell lineAltered host rangeCarrier stateHigh titersMiceCarrier culturesViral host rangeVirusCell linesSingle plaqueInfectionMassive cell lysisRestriction enzyme analysisMouse L cellsCellsViral genomeCell lysisHost range mutantsDaysEnzyme analysisEarly stages
1983
Interaction of minute virus of mice with differentiated cells: strain-dependent target cell specificity is mediated by intracellular factors
Spalholz B, Tattersall P. Interaction of minute virus of mice with differentiated cells: strain-dependent target cell specificity is mediated by intracellular factors. Journal Of Virology 1983, 46: 937-943. PMID: 6602221, PMCID: PMC256568, DOI: 10.1128/jvi.46.3.937-943.1983.Peer-Reviewed Original ResearchConceptsVirus-host cell interactionsTarget cell specificityCell typesIntracellular host factorsRestrictive cell typesRestrictive infectionCell interactionsMinute virusCell specificityHost cell typesViral determinantsViral replicationSpecific receptorsImmunosuppressive strainHost factorsSame receptorViral DNA synthesisPrototype strainVirusDetectable expressionIncoming viral genomesEarly eventsFinal outcomeInfectionMiceReciprocal productive and restrictive virus-cell interactions of immunosuppressive and prototype strains of minute virus of mice
Tattersall P, Bratton J. Reciprocal productive and restrictive virus-cell interactions of immunosuppressive and prototype strains of minute virus of mice. Journal Of Virology 1983, 46: 944-955. PMID: 6602222, PMCID: PMC256569, DOI: 10.1128/jvi.46.3.944-955.1983.Peer-Reviewed Original ResearchConceptsPrototype strainImmunosuppressive strainVirus variantsStrain-specific determinantsMurine host cellsVirus-host cell interactionsVirus-cell interactionsViral antigensT cellsHost cell populationsHelper functionMinute virusTarget cell specificityInfected cellsCell phenotypeCell populationsIndistinguishable strainsHost cell phenotypeCell interactionsGenomic criteriaDifferent cell typesSimian virus 40MiceHost cellsCell specificity
1976
Three structural polypeptides coded for by minite virus of mice, a parvovirus
Tattersall P, Cawte P, Shatkin A, Ward D. Three structural polypeptides coded for by minite virus of mice, a parvovirus. Journal Of Virology 1976, 20: 273-289. PMID: 988192, PMCID: PMC354988, DOI: 10.1128/jvi.20.1.273-289.1976.Peer-Reviewed Original ResearchConceptsLate maturation stepPulse-chase experimentsNuclei of cellsSodium dodecyl sulfate-polyacrylamide gel electrophoresisDodecyl sulfate-polyacrylamide gel electrophoresisDNA genomeSulfate-polyacrylamide gel electrophoresisThird polypeptideMaturation stepsVirion massProtein componentsHost cellsEmpty virionsStructural polypeptidesPolypeptideMinute virusGel electrophoresisCsCl gradientsProtein massUninfected cellsGrowth conditionsSequential harvestingEmpty particlesVirionsProtein
1972
Replication of the Parvovirus MVM I. Dependence of Virus Multiplication and Plaque Formation on Cell Growth
Tattersall P. Replication of the Parvovirus MVM I. Dependence of Virus Multiplication and Plaque Formation on Cell Growth. Journal Of Virology 1972, 10: 586-590. PMID: 4673484, PMCID: PMC356507, DOI: 10.1128/jvi.10.4.586-590.1972.Peer-Reviewed Original Research