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 virusVTF7-3
1990
Alternate splicing in a parvoviral nonstructural gene links a common amino-terminal sequence to downstream domains which confer radically different localization and turnover characteristics
Cotmore S, Tattersall P. Alternate splicing in a parvoviral nonstructural gene links a common amino-terminal sequence to downstream domains which confer radically different localization and turnover characteristics. Virology 1990, 177: 477-487. PMID: 2142555, DOI: 10.1016/0042-6822(90)90512-p.Peer-Reviewed Original ResearchMeSH KeywordsAmino Acid SequenceAnimalsAphidicolinBase SequenceCapsidCell DivisionChromosome MappingDiterpenesFluorescent Antibody TechniqueGenes, ViralL CellsMiceMinute virus of miceMolecular Sequence DataMolecular WeightParvoviridaeRNA SplicingRNA, ViralSequence Homology, Nucleic AcidViral Core ProteinsViral Nonstructural ProteinsViral Structural ProteinsConceptsCommon amino-terminal domainAmino-terminal domainNS-1 moleculesCommon amino-terminal sequenceNS-1 polypeptideAmino-terminal sequenceSodium dodecyl sulfate gel electrophoresisNS-1Dodecyl sulfate gel electrophoresisUnphosphorylated formInternal exonsAlternate splicingGene productsSulfate gel electrophoresisA9 cellsNonstructural genesSpliced formsPhosphorylated formDownstream domainContiguous sequencesNonstructural proteinsSpecies migratePeptide-specific antibodiesMinute virusTurnover characteristicsSusceptibility 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
1987
The Autonomously Replicating Parvoviruses of Vertebrates
Cotmore S, Tattersall P. The Autonomously Replicating Parvoviruses of Vertebrates. Advances In Virus Research 1987, 33: 91-174. PMID: 3296697, DOI: 10.1016/s0065-3527(08)60317-6.Peer-Reviewed Original ResearchConceptsHost cellsProductive replicationHost cell typesSpecific cell surface receptorsHost cell factorsCell surface receptorsDifferentiated stateAutonomous parvovirusesIntracellular interactionsCell typesCell cyclingSurface receptorsCellular levelHelper virusCell factorWhole animalParvovirus strainsReplicationViral particlesPathogenic processesVertebratesCellsVirusParvovirusParvovirus group
1986
Identification of the major structural and nonstructural proteins encoded by human parvovirus B19 and mapping of their genes by procaryotic expression of isolated genomic fragments
Cotmore S, McKie V, Anderson L, Astell C, Tattersall P. Identification of the major structural and nonstructural proteins encoded by human parvovirus B19 and mapping of their genes by procaryotic expression of isolated genomic fragments. Journal Of Virology 1986, 60: 548-557. PMID: 3021988, PMCID: PMC288924, DOI: 10.1128/jvi.60.2.548-557.1986.Peer-Reviewed Original ResearchConceptsProtein sequencesViral capsid polypeptidesCapsid polypeptidesSucrose velocity gradientsB19 genomeBacterial plasmid vectorRestriction endonuclease fragmentsGenomic fragmentProtein speciesApparent molecular weightNonstructural polypeptidesExpression constructsSimilar proteinsBAL-31GenomeExpression vectorNonstructural proteinsEndonuclease fragmentsPlasmid vectorViral genomeViral polypeptidesPolypeptide fragmentsProcaryotic expressionPolypeptideProteinOrganization of nonstructural genes of the autonomous parvovirus minute virus of mice
Cotmore S, Tattersall P. Organization of nonstructural genes of the autonomous parvovirus minute virus of mice. Journal Of Virology 1986, 58: 724-732. PMID: 2939261, PMCID: PMC252977, DOI: 10.1128/jvi.58.3.724-732.1986.Peer-Reviewed Original ResearchConceptsOpen reading frameAutonomous parvovirus minute virusParvovirus minute virusSimilar proteinsFusion proteinCommon amino-terminal sequenceSingle open reading frameNonstructural protein NS-1Rabbit reticulocyte lysate translation systemViral genomeReticulocyte lysate translation systemAlternative open reading framesNS-2 proteinsCarboxy-terminal halfNS-1 proteinNS-1Amino acid sequenceBacterial fusion proteinLysate translation systemMinute virusAmino-terminal sequenceProcaryotic expression vectorR2 transcriptsReading frameAcid sequenceNucleotide sequence and genome organization of human parvovirus B19 isolated from the serum of a child during aplastic crisis
Shade R, Blundell M, Cotmore S, Tattersall P, Astell C. Nucleotide sequence and genome organization of human parvovirus B19 isolated from the serum of a child during aplastic crisis. Journal Of Virology 1986, 58: 921-936. PMID: 3701931, PMCID: PMC253001, DOI: 10.1128/jvi.58.3.921-936.1986.Peer-Reviewed Original ResearchConceptsNucleotide sequenceLarge open reading frameMajor nonstructural proteinOpen reading frameFull-length cloneMajor structural polypeptidesGenome organizationGenomic clonesPutative polypeptideTranscription unitEntire genomeReading frameDNA sequencesFourth promoterParvovirus genomeSequence informationNonstructural proteinsGenomeTerminal repeatDependovirus genusStructural polypeptidesViral DNAB19 genomePolypeptideSequenceDNA sequence of the lymphotropic variant of minute virus of mice, MVM(i), and comparison with the DNA sequence of the fibrotropic prototype strain
Astell C, Gardiner E, Tattersall P. DNA sequence of the lymphotropic variant of minute virus of mice, MVM(i), and comparison with the DNA sequence of the fibrotropic prototype strain. Journal Of Virology 1986, 57: 656-669. PMID: 3502703, PMCID: PMC252781, DOI: 10.1128/jvi.57.2.656-669.1986.Peer-Reviewed Original Research
1985
Characteristics and Taxonomy of Parvoviridae
Siegl G, Bates R, Berns K, Carter B, Kelly D, Kurstak E, Tattersall P. Characteristics and Taxonomy of Parvoviridae. Intervirology 1985, 23: 61-73. PMID: 3980186, DOI: 10.1159/000149587.Peer-Reviewed Original Research
1983
The autonomous parvovirus MVM encodes two nonstructural proteins in addition to its capsid polypeptides
Cotmore S, Sturzenbecker L, Tattersall P. The autonomous parvovirus MVM encodes two nonstructural proteins in addition to its capsid polypeptides. Virology 1983, 129: 333-343. PMID: 6623929, DOI: 10.1016/0042-6822(83)90172-1.Peer-Reviewed Original ResearchConceptsParvovirus MVMCapsid polypeptidesNS-1 proteinOpen reading frameNS-1 polypeptidePeptide map analysisMajor intronTranscription unitMVM genomeVitro translationApparent molecular weightReading frameNonstructural proteinsPolypeptideProteinVP-1NS-1VP-2GenomeIntronsComigratesMolecular weightTranscriptsMVMMap analysisConstruction of an infectious molecular clone of the autonomous parvovirus minute virus of mice
Merchlinsky M, Tattersall P, Leary J, Cotmore S, Gardiner E, Ward D. Construction of an infectious molecular clone of the autonomous parvovirus minute virus of mice. Journal Of Virology 1983, 47: 227-232. PMID: 6345805, PMCID: PMC255236, DOI: 10.1128/jvi.47.1.227-232.1983.Peer-Reviewed Original ResearchReciprocal 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
1979
About 30% of minute virus of mice RNA is spliced out following polyadenylation
TAL J, RON D, TATTERSALL P, BRATOSIN S, ALONI Y. About 30% of minute virus of mice RNA is spliced out following polyadenylation. Nature 1979, 279: 649-651. PMID: 450113, DOI: 10.1038/279649a0.Peer-Reviewed Original ResearchConceptsEukaryotic messenger RNAsStudy of transcriptionBlocks of sequenceStudy of RNAMinute virusComplementary strand synthesisDNA chromosomesMouse RNARNA splicingRNA speciesSplicing patternsVitro translationProtein speciesNon-contiguous regionsMRNA speciesAbundant speciesViral strandIcosahedral virionsAnimal virusesGenomic DNATranscription processStrand synthesisDNA moleculesRNASequence arrangement