Search results for "Virus assembly"

showing 10 items of 29 documents

Purified Membrane-Containing Procapsids of Bacteriophage PRD1 Package the Viral Genome

2009

Icosahedral-tailed double-stranded DNA (dsDNA) bacteriophages and herpesviruses translocate viral DNA into a preformed procapsid in an ATP-driven reaction by a packaging complex that operates at a portal vertex. A similar packaging system operates in the tailless dsDNA phage PRD1 (Tectiviridae family), except that there is an internal membrane vesicle in the procapsid. The unit-length linear dsDNA genome with covalently linked 5'-terminal proteins enters the procapsid through a unique vertex. Two small integral membrane proteins, P20 and P22, provide a conduit for DNA translocation. The packaging machinery also contains the packaging ATPase P9 and the packaging efficiency factor P6. Here we…

Viral Plaque AssayvirusesATPaseViral Plaque AssayGenomeViral Proteins03 medical and health scienceschemistry.chemical_compoundCapsidBacteriophage PRD1Structural BiologyBacteriophage PRD1Molecular BiologyIntegral membrane protein030304 developmental biology0303 health sciencesMicrobial Viabilitybiology030306 microbiologyVirus AssemblyCell MembraneMembrane ProteinsMolecular biologyMembranechemistryDNA Viralbiology.proteinBiophysicsTectiviridaeDNAJournal of Molecular Biology
researchProduct

Molecular and structural characterization of fluorescent human parvovirus B19 virus-like particles

2005

Although sharing a T = 1 icosahedral symmetry with other members of the Parvoviridae family, it has been suggested that the fivefold channel of the human parvovirus B19 VP2 capsids is closed at its outside end. To investigate the possibility of placing a relatively large protein moiety at this site of B19, fluorescent virus-like particles (fVLPs) of B19 were developed. The enhanced green fluorescent protein (EGFP) was inserted at the N-terminus of the structural protein VP2 and assembly of fVLPs from this fusion protein was obtained. Electron microscopy revealed that these fluorescent protein complexes were very similar in size when compared to wild-type B19 virus. Further, fluorescence cor…

Models MolecularImmunoprecipitationRecombinant Fusion ProteinsvirusesGreen Fluorescent ProteinsBiophysicsFluorescence correlation spectroscopyEndosomesSpodopteraBiologyMicroscopy Atomic ForceBiochemistryFluorescenceCell LineGreen fluorescent proteinParvoviridae InfectionsBimolecular fluorescence complementationCell Line Tumorhemic and lymphatic diseasesParvovirus B19 HumanAnimalsHumansImmunoprecipitationMolecular BiologyParvoviridaeImmune SeraVirus AssemblyVirionvirus diseasesCell Biologybiology.organism_classificationFusion proteinMolecular biologyNanostructuresCell biologyTransport proteinProtein TransportCapsidCapsid Proteins
researchProduct

Something old, something new : exploring membrane-containing bacteriophages

2016

Cystoviridaesaperonitrakenneviruksetvirus assemblymembrane-containing virusbakteriofagitfluoresenssimikroskopiassDNA phagevirologiaperimäkalvotchaperonin complexproteiinitbacteriophage PRD1fluorescent fusion proteinkapsidi
researchProduct

Assembly of fluorescent chimeric virus-like particles of canine parvovirus in insect cells

2004

Canine parvovirus (CPV) is a small non-enveloped ssDNA virus composed of the viral proteins VP1, VP2, and VP3 with a T=1 icosahedral symmetry. VP2 is nested in VP1 and the two proteins are produced by differential splicing of a primary transcript of the right ORF of the viral genome. The VP2 protein can be further proteolytically cleaved to form VP3. Previous studies have shown that VP1 and VP3 are unnecessary for capsid formation and consequently, that VP2 alone is sufficient for assembly. We have hypothesized that insertion of the enhanced green fluorescent protein (EGFP) at the N-terminus of VP2 could be carried out without altering assembly. To investigate the possibility to develop flu…

Parvovirus CanineRecombinant Fusion ProteinsvirusesGreen Fluorescent ProteinsBiophysicsHeterologousFluorescence correlation spectroscopySpodopteraBiochemistryVirusCell LineInclusion Bodies ViralGreen fluorescent proteinAnimalsAmino Acid SequenceMolecular BiologyMicroscopy ConfocalBase SequencebiologyChimeraVirus AssemblyCanine parvovirusvirus diseasesCell Biologybiochemical phenomena metabolism and nutritionbiology.organism_classificationMolecular biologyFusion proteinLuminescent ProteinsMicroscopy ElectronCapsidRNA splicingCapsid ProteinsPlasmidsBiochemical and Biophysical Research Communications
researchProduct

Subcellular localization of bacteriophage PRD1 proteins in Escherichia coli

2014

Bacteria possess an intricate internal organization resembling that of the eukaryotes. The complexity is especially prominent at the bacterial cell poles, which are also known to be the preferable sites for some bacteriophages to infect. Bacteriophage PRD1 is a well-known model serving as an ideal system to study structures and functions of icosahedral internal membrane-containing viruses. Our aim was to analyze the localization and interactions of individual PRD1 proteins in its native host Escherichia coli. This was accomplished by constructing a vector library for production of fluorescent fusion proteins. Analysis of solubility and multimericity of the fusion proteins, as well as their …

Cancer ResearchViral proteinvirusesIntracellular SpaceBiologymedicine.disease_causeBacterial cell structureProtein–protein interactionViral Proteins03 medical and health sciencesVirologyEscherichia colimedicineBacteriophage PRD1Escherichia coli030304 developmental biology0303 health sciencesBacteria030302 biochemistry & molecular biologyDNA replicationta1182Protein interactionsFusion proteinVirus assemblyCell biologyConfocal microscopyProtein TransportInfectious DiseasesMembrane proteinVirion assemblyMembrane virusVirus Research
researchProduct

Mosaic Qβ coats as a new presentation model

1998

The new protein carrier was developed on the basis of recombinant RNA phage Qbeta capsid. C-terminal UGA extension of the short form of Qbeta coat, so-called A1 extension, served as a target for presentation of foreign peptides on the outer surface of mosaic Qbeta particles. In conditions of enhanced UGA suppression, the proportion of A1-extended to short coats in mosaic particles dropped from 48% to 14%, with an increase of the length of A1 extension. A model insertion, short preS1 epitope 31-DPAFR-35 of hepatitis B surface antigen, demonstrated superficial location on the mosaic Qbeta particles and ensured specific antigenicity and immunogenicity.

AntigenicityRecombinant Fusion ProteinsGenetic VectorsBiophysicsBiologyHepatitis b surface antigenBiochemistryEpitopelaw.inventionCapsid assemblyMiceCapsidPhage QβPeptide LibraryStructural BiologylawGeneticsAnimalsHepatitis B virus preS1Cloning MolecularMolecular BiologyAllolevivirusMice Inbred BALB CCoat protein UGA suppressionVirus AssemblyImmunogenicityA1 extensionRNACell BiologyImmunogenicityVirologyMolecular biologyCapsidCarrier proteinCodon TerminatorRecombinant DNACapsid ProteinsFEBS Letters
researchProduct

Interaction of wild-type and naturally occurring deleted variants of hepatitis B virus core polypeptides leads to formation of mosaic particles

2000

AbstractThe simultaneous presence of hepatitis B virus (HBV) genomes carrying wild-type (wt) and in-frame deleted variants of the HBV core gene has been identified as a typical feature of HBV-infected renal transplant patients with severe liver disease. To investigate possible interactions of wt and deleted core polypeptides a two-vector Escherichia coli expression system ensuring their concomitant synthesis has been developed. Co-expression of wt and a mutant core lacking 17 amino acid residues (77–93) within the immunodominant region led to the formation of mosaic particles, whereas the mutant alone was incapable of self-assembly.

Hepatitis B virusBlotting WesternMutantBiophysicsBiologymedicine.disease_causeBiochemistryGenomeHepatitis B virus PRE betaLiver diseaseStructural BiologyEscherichia coliGeneticsmedicineProtein Structure QuaternaryMolecular BiologyEscherichia coliSequence DeletionHepatitis B virusImmunodominant EpitopesHepatitis B virus coreViral Core ProteinsVirus AssemblyWild typeGenetic VariationCell Biologymedicine.diseaseDimer formationHepatitis B Core AntigensPrecipitin TestsVirologyMolecular biologyRecombinant ProteinsMosaic particleMicroscopy ElectronPeptidesDimerizationC gene deletionProtein BindingFEBS Letters
researchProduct

Replication of hepatitis C virus

2000

Viral pathogenesisHepatitis C virusVirus AssemblyViral transformationHepatitis CHepacivirusBiologymedicine.diseasemedicine.disease_causeTransfectionVirus ReplicationMicrobiologyVirologyPathogenesisViral ProteinsViral replicationReplication (statistics)medicineAnimalsRNA ViralOncovirusCells Cultured
researchProduct

Hepatitis B virus maturation is sensitive to functional inhibition of ESCRT-III, Vps4, and gamma 2-adaptin.

2007

ABSTRACT Hepatitis B virus (HBV) is an enveloped DNA virus that presumably buds at intracellular membranes of infected cells. HBV budding involves two endocytic host proteins, the ubiquitin-interacting adaptor γ2-adaptin and the Nedd4 ubiquitin ligase. Here, we demonstrate that HBV release also requires the cellular machinery that generates internal vesicles of multivesicular bodies (MVBs). In order to perturb the MVB machinery in HBV-replicating liver cells, we used ectopic expression of dominant-negative mutants of different MVB components, like the ESCRT-III complex-forming CHMP proteins and the Vps4 ATPases. Upon coexpression of mutated CHMP3, CHMP4B, or CHMP4C forms, as well as of ATPa…

Hepatitis B virusVacuolar Proton-Translocating ATPasesEndosomeImmunologyEndocytic cycleVesicular Transport Proteinsmacromolecular substancesEndosomesmedicine.disease_causeMicrobiologyESCRTVirusCell LineViral ProteinsVirologymedicineHumansAdaptor Protein Complex gamma SubunitsHepatitis B virusAdenosine TriphosphatasesMicroscopy ConfocalbiologyEndosomal Sorting Complexes Required for TransportVirus AssemblyDNA virusMolecular biologyUbiquitin ligaseCell biologyGenome Replication and Regulation of Viral Gene ExpressionMicroscopy FluorescenceInsect Sciencebiology.proteinHepatocytesATPases Associated with Diverse Cellular ActivitiesEctopic expressionJournal of virology
researchProduct

Non-structural proteins P17 and P33 are involved in the assembly of the internal membrane-containing virus PRD1.

2015

AbstractBacteriophage PRD1, which has been studied intensively at the structural and functional levels, still has some gene products with unknown functions and certain aspects of the PRD1 assembly process have remained unsolved. In this study, we demonstrate that the phage-encoded non-structural proteins P17 and P33, either individually or together, complement the defect in a temperature-sensitive GroES mutant of Escherichia coli for host growth and PRD1 propagation. Confocal microscopy of fluorescent fusion proteins revealed co-localisation between P33 and P17 as well as between P33 and the host chaperonin GroEL. A fluorescence recovery after photobleaching assay demonstrated that the diff…

assemblychaperoninvirusesMutantfluorescence recovery after photobleachingViral Nonstructural Proteinsmedicine.disease_causeVirus ReplicationChaperoninHost-Parasite InteractionsBacteriophagebacteriophageVirologymedicineEscherichia colifluorescent proteinBacteriophage PRD1Escherichia colimembrane virusMicroscopy Confocalbiologyprotein localisationVirus Assemblyta1182Fluorescence recovery after photobleachingGroESChaperonin 60biology.organism_classificationFusion proteinGroEL3. Good healthCell biologyVirology
researchProduct