Search results for " Cell"

showing 10 items of 14074 documents

Internalization of novel non-viral vector TAT-streptavidin into human cells

2007

BMC Biotechnology, 7 (1)

virusesEndocytic cyclePROTEINS + POLYPEPTIDES (BIOCHEMISTRY)02 engineering and technologyei-virusperäinen vektoriProtein EngineeringgeeniterapiaPost Transductionchemistry.chemical_compoundTHERAPIES + THERAPEUTICS (MEDICINE)Drug Delivery SystemsLääketieteen bioteknologia - Medical biotechnologyInternalizationmedia_commoninfo:eu-repo/classification/ddc/5700303 health sciencesPinocytosisNocodazoleVEKTOREN (GENETISCHE TECHNIKEN)021001 nanoscience & nanotechnologyLife sciencesCell biologyEndosomal EscapeBiotinylationGene Products tatVirusesVECTORS (GENETIC TECHNIQUES)VEKTOREN (GENETISCHE TECHNIKEN); THERAPIEN + THERAPEUTIK (MEDIZIN); PROTEINE + POLYPEPTIDE (BIOCHEMIE); VECTORS (GENETIC TECHNIQUES); THERAPIES + THERAPEUTICS (MEDICINE); PROTEINS + POLYPEPTIDES (BIOCHEMISTRY)0210 nano-technologyTHERAPIEN + THERAPEUTIK (MEDIZIN)BiotechnologyResearch ArticleStreptavidinEndosomeImmunoelectron microscopymedia_common.quotation_subjectRecombinant Fusion Proteinslcsh:BiotechnologyGenetic VectorsBiologyEndocytosis03 medical and health sciencesstreptavidiiniddc:570lcsh:TP248.13-248.65HumansEndosomal Marker030304 developmental biologyMolecular biologyEndocytic VesiclechemistryStreptavidinTATPROTEINE + POLYPEPTIDE (BIOCHEMIE)HeLa CellsBMC Biotechnology
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The endogenous retroviral insertion in the human complement C4 gene modulates the expression of homologous genes by antisense inhibition

2001

Intron 9 contains the complete endogenous retrovirus HERV-K(C4) as a 6.4-kb insertion in 60% of human C4 genes. The retroviral insertion is in reverse orientation to the C4 coding sequence. Therefore, expression of C4 could lead to the transcription of an antisense RNA, which might protect against exogenous retroviral infections. To test this hypothesis, open reading frames from the HERV sequence were subcloned in sense orientiation into a vector allowing expression of a beta-galactosidase fusion protein. Mouse L cells which had been stably transfected with either the human C4A or C4B gene both carrying the HERV insertion (LC4 cells), and L(Tk-) cells without the C4 gene were transiently tr…

virusesEndogenous RetrovirusesImmunologyIntronEndogenous retrovirusComplement C4TransfectionBiologyMolecular biologyFusion proteinAntisense RNAInterferon-gammaMiceL CellsGene Expression RegulationTranscription (biology)Sense (molecular biology)GeneticsAnimalsHumansRNA AntisenseGeneRetroviridae InfectionsImmunogenetics
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Infection-induced chromatin modifications facilitate translocation of herpes simplex virus capsids to the inner nuclear membrane

2021

Herpes simplex virus capsids are assembled and packaged in the nucleus and move by diffusion through the nucleoplasm to the nuclear envelope for egress. Analyzing their motion provides conclusions not only on capsid transport but also on the properties of the nuclear environment during infection. We utilized live-cell imaging and single-particle tracking to characterize capsid motion relative to the host chromatin. The data indicate that as the chromatin was marginalized toward the nuclear envelope it presented a restrictive barrier to the capsids. However, later in infection this barrier became more permissive and the probability of capsids to enter the chromatin increased. Thus, although …

virusesGene ExpressionVirus ReplicationPathology and Laboratory Medicineherpes simplex -virusChlorocebus aethiopsCapsidsMedicine and Health SciencesSimplexvirusBiology (General)Mass DiffusivityStainingChromosome BiologyPhysicsChromatinChemistryMedical MicrobiologyViral PathogensPhysical SciencesVirusesHerpes Simplex Virus-1EpigeneticsCellular Structures and OrganellesPathogenskapsidiResearch ArticleHerpesvirusesNuclear EnvelopeQH301-705.5Biological Transport ActiveViral StructureResearch and Analysis MethodsinfektiotMicrobiologydiffuusio (fysikaaliset ilmiöt)CapsidNuclear MembraneVirologyGeneticsAnimalsherpesviruksetVero CellsMicrobial PathogensCell NucleusChemical PhysicsOrganismsBiology and Life SciencesHerpes SimplexCell Biologybiochemical phenomena metabolism and nutritionRC581-607Viral ReplicationHerpes Simplex VirusNuclear StainingSpecimen Preparation and TreatmentImmunologic diseases. AllergyDNA viruses
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The Nasal Epithelium as a Factory for Systemic Protein Delivery

2002

We have previously shown that recombinant Sendai virus (SeV) produces efficient in vivo airway epithelial gene transfer. The ability to produce therapeutic levels of circulating proteins following noninvasive gene transfer would have widespread clinical application. Here, we compared nose, lung, and skeletal muscle for the ability to produce circulating levels of the secreted mouse antiinflammatory cytokine interleukin-10 (IL10) following SeV-mediated gene transfer. High levels of serum IL10 were obtained from each site with a potency order of lung > nose > muscle for a given viral titer. Serum levels from each site were within the likely required range for anti-inflammatory effects. The co…

virusesGenetic enhancementmedicine.medical_treatmentMucous membrane of noseSendai virus03 medical and health sciences0302 clinical medicineIn vivoDrug DiscoverymedicineGeneticsAnimalsHumansMuscle SkeletalLungMolecular BiologyNose030304 developmental biologyPharmacology0303 health sciencesLungbiologyGene Transfer TechniquesSkeletal musclerespiratory systembiology.organism_classificationSendai virus3. Good healthInterleukin-10Nasal Mucosamedicine.anatomical_structureCytokine030220 oncology & carcinogenesisImmunologyCOS CellsMolecular MedicineHeLa CellsMolecular Therapy
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Replication of herpes simplex virus type 1 and 2 in the medulla of the adrenal gland after vaginal infection of mice.

1996

After vaginal infections of mice with neuroinvasive strains of herpes simplex virus type 1 and 2 (HSV-1, HSV-2) virus replicates in the epithelium of the vagina, in the paravaginal ganglia, in the spinal cord and finally in the brain and in the adrenal glands. However, viral antigens could be demonstrated only in the medulla of the adrenal glands but not in the cortex, as assessed by immunohistochemistry (IHC). HSV could not be isolated from liver, spleen, uterus, and ovaries. This contrasts to the intraperitoneal (i.p) route of infection with replication in different visceral organs including the adrenal gland's cortex.

virusesHerpesvirus 2 HumanUterusSpleenHerpesvirus 1 HumanBiologymedicine.disease_causeVirus ReplicationHerpesviridaeVirusMiceVirologyChlorocebus aethiopsmedicineAnimalsHumansAntigens ViralVero CellsMedullaCerebral CortexMice Inbred BALB CAdrenal glandGeneral MedicineVirologymedicine.anatomical_structureHerpes simplex virusSpinal CordAdrenal MedullaVaginaVaginaFemaleArchives of virology
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Assembly and Translocation of Papillomavirus Capsid Proteins

2002

ABSTRACT The major and minor capsid proteins of polyomavirus are preassembled in the cytoplasm and translocated to the nucleus only as a VP1-VP2/VP3 complex. In this study, we describe independent nuclear translocation of the L1 major protein and the L2 minor capsid protein of human papillomavirus type 33 by several approaches. First, we observed that expression and nuclear translocation of L2 in natural lesions precede expression of L1. Second, using a cell culture system for coexpression, we found that accumulation of L2 in nuclear domain 10 (ND10) subnuclear structures precedes L1 by several hours. In contrast, complexes of L2 and mutants of L1 forced to assemble in the cytoplasm are tra…

virusesImmunologyActive Transport Cell NucleusChromosomal translocationBiologyMicrobiologychemistry.chemical_compoundCapsidVirologyMG132medicineAnimalsHumansPapillomaviridaeCOS cellsStructure and AssemblyVirus AssemblyOncogene Proteins Viralbiochemical phenomena metabolism and nutritionMolecular biologymedicine.anatomical_structureCapsidchemistryCytoplasmCell cultureInsect ScienceCOS CellsProteasome inhibitorCapsid ProteinsFemaleNucleusmedicine.drug
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Nuclear localization but not PML protein is required for incorporation of the papillomavirus minor capsid protein L2 into virus-like particles.

2004

ABSTRACT Recent reports suggest that nuclear domain(s) 10 (ND10) is the site of papillomavirus morphogenesis. The viral genome replicates in or close to ND10. In addition, the minor capsid protein, L2, accumulates in these subnuclear structures and recruits the major capsid protein, L1. We have now used cell lines deficient for promyelocytic leukemia (PML) protein, the main structural component of ND10, to study the role of this nuclear protein for L2 incorporation into virus-like particles (VLPs). L2 expressed in PML protein knockout (PML −/− ) cells accumulated in nuclear dots, which resemble L2 aggregates forming at ND10 in PML protein-containing cells. These L2 assemblies also attracted…

virusesImmunologyActive Transport Cell NucleusNuclear dotsBiologyPromyelocytic Leukemia ProteinMicrobiologyCell LinePromyelocytic leukemia proteinMiceDeath-associated protein 6Virus-like particleVirologymedicineAnimalsHumansNuclear proteinPapillomaviridaeAdaptor Proteins Signal TransducingCell NucleusTumor Suppressor ProteinsStructure and AssemblyIntracellular Signaling Peptides and ProteinsVirionvirus diseasesNuclear ProteinsOncogene Proteins Viralbiochemical phenomena metabolism and nutritionMolecular biologyCell biologyNeoplasm ProteinsCell nucleusMicroscopy Electronmedicine.anatomical_structureInsect ScienceMutationbiology.proteinCapsid ProteinsNuclear transportCarrier ProteinsCo-Repressor ProteinsNuclear localization sequenceMolecular ChaperonesTranscription FactorsJournal of virology
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Generation and neutralization of pseudovirions of human papillomavirus type 33

1997

Since human papillomaviruses (HPV) cannot be propagated in cell culture, the generation of infectious virions in vitro is a highly desirable goal. Here we report that pseudovirions can be generated by the assembly of virus-like particles (VLPs) in COS-7 cells containing multiple copies of a marker plasmid. Using recombinant vaccinia viruses, we have obtained spherical VLPs of HPV type 33 (HPV-33) which fractionate into heavy and light VLPs in cesium chloride density gradients. VLPs in the heavy fraction (1.31 g/cm3) carry the plasmid in DNase-resistant form and are capable of transferring the genetic marker located on the plasmid to COS-7 cells in a DNase-resistant way (pseudoinfection). Th…

virusesImmunologyBiologyAntibodies Viralcomplex mixturesMicrobiologyNeutralizationlaw.inventionchemistry.chemical_compoundCapsidPlasmidNeutralization TestslawVirologyAnimalsDeoxyribonuclease IHumansAntigens ViralPapillomaviridaeAntiserumVirus AssemblyVirionvirus diseasesOncogene Proteins ViralVirologyMolecular biologyIn vitroTiterchemistryCapsidInsect ScienceCOS CellsDNA ViralRecombinant DNACapsid ProteinsDNAResearch ArticleJournal of Virology
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Enhancement of hepatitis C virus RNA replication by cell culture-adaptive mutations.

2001

ABSTRACT Studies of the Hepatitis C virus (HCV) replication cycle have been made possible with the development of subgenomic selectable RNAs that replicate autonomously in cultured cells. In these replicons the region encoding the HCV structural proteins was replaced by the neomycin phosphotransferase gene, allowing the selection of transfected cells that support high-level replication of these RNAs. Subsequent analyses revealed that, within selected cells, HCV RNAs had acquired adaptive mutations that increased the efficiency of colony formation by an unknown mechanism. Using a panel of replicons that differed in their degrees of cell culture adaptation, in this study we show that adaptive…

virusesImmunologyCell Culture TechniquesRNA-dependent RNA polymeraseReplicationHepacivirusBiologyViral Nonstructural ProteinsOrigin of replicationVirus ReplicationMicrobiologyReplication factor CControl of chromosome duplicationGenes ReporterVirologyTumor Cells CulturedHumansRepliconLuciferasesGeneRNAVirologyAdaptation PhysiologicalViral replicationInsect ScienceMutationRNA ViralRepliconJournal of virology
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Viral and cellular determinants of hepatitis C virus RNA replication in cell culture.

2003

Studies on the replication of hepatitis C virus (HCV) have been facilitated by the development of selectable subgenomic replicons replicating in the human hepatoma cell line Huh-7 at a surprisingly high level. Analysis of the replicon population in selected cells revealed the occurrence of cell culture-adaptive mutations that enhance RNA replication substantially. To gain a better understanding of HCV cell culture adaptation, we characterized conserved mutations identified by sequence analysis of 26 independent replicon cell clones for their effect on RNA replication. Mutations enhancing replication were found in nearly every nonstructural (NS) protein, and they could be subdivided into at …

virusesImmunologyCell Culture TechniquesReplicationRNA-dependent RNA polymeraseEukaryotic DNA replicationHepacivirusViral Nonstructural ProteinsBiologyVirus ReplicationOrigin of replicationMicrobiologyReplication factor CControl of chromosome duplicationVirologyTumor Cells Cultured[SDV.BBM] Life Sciences [q-bio]/Biochemistry Molecular BiologyHumansRepliconVirologyAmino Acid SubstitutionViral replicationInsect ScienceRNA ViralOrigin recognition complexRepliconRibosomes
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