Search results for "DNA polymerase II"

showing 10 items of 11 documents

DNA-replication complex from cells infected with herpes virus.

2005

Herpes simplex virus (HSV) DNA synthesis is initiated in an intact cell system by a 36-residue ribonucleotide stretch [W.E.G. Müller, R.K. Zahn, J. Arendes, and D. Falke (1979) Virology, 98, 200-210]. In the present study a nucleoplasmic fraction was isolated from rabbit kidney cells infected with HSV (type 1), which catalyzes DNA synthesis. By means of specific assays, containing single-stranded deoxyribopolymers, it was elucidated that the replication complex contains both an RNA-synthesizing and a DNA-synthesizing enzyme. These enzymes were characterized as host cell RNA polymerase II and HSV-induced DNA polymerase. The RNA polymerase II synthesizes an RNA initiator with an average chain…

Cell NucleusDNA ReplicationCytoplasmDNA clampbiologyDNA polymeraseDNA polymerase IIDNA replicationDNA-Directed DNA PolymeraseKidneyBiochemistryMolecular biologyDNA polymerase deltaKineticsSolubilityDNA Viralbiology.proteinAnimalsSimplexvirusPrimaseRNA Polymerase IIRabbitsDNA polymerase IPolymeraseEuropean journal of biochemistry
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A neutralizing antibody against human DNA polymerase epsilon inhibits cellular but not SV40 DNA replication.

1999

The contribution of human DNA polymerase epsilon to nuclear DNA replication was studied. Antibody K18 that specifically inhibits DNA polymerase activity of human DNA polymerase epsilon in vitro significantly inhibits DNA synthesis both when microinjected into nuclei of exponentially growing human fibroblasts and in isolated HeLa cell nuclei. The capability of this neutralizing antibody to inhibit DNA synthesis in cells is comparable to that of monoclonal antibody SJK-132-20 against DNA polymerase alpha. Contrary to the antibody against DNA polymerase alpha, antibody K18 against DNA polymerase epsilon did not inhibit SV40 DNA replication in vitro. These results indicate that DNA polymerase e…

DNA ReplicationDNA polymeraseDNA polymerase IIDNA polymerase epsilonSimian virus 40Virus ReplicationDNA polymerase deltaAntibodiesCell LineNeutralization TestsCatalytic DomainGeneticsAnimalsHumansPolymeraseDNA clampbiologyDNA replicationDNA Polymerase IIFibroblastsMolecular biologyProliferating cell nuclear antigenBromodeoxyuridineDNA Viralbiology.proteinCattleRabbitsHeLa CellsResearch ArticleNucleic acids research
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Age-dependent alterations of DNA synthesis. Terminal deoxynucleotidyl transferase and DNA polymerase activities in bone marrow subpopulations from mi…

1980

Abstract The decrease of functional capacity of cellular immunity during ageing seems to be due to cellular changes of stem cells, particularly in the growth properties and the cell density in T-cell subsets. We approached this problem at the molecular biological level by quantifying the key enzymes necessary for DNA synthesis in bone marrow cells from mice: deoxynucleotidyl transferase (TdT) and DNA polymerase α. The bone marrow cells were fractionated on a discontinuous bovine serum albumin density gradient and the extractable enzyme activities (expressed per 10 8 nucleated cells in the respective fraction) were determined. TdT activity was found to decrease markedly during ageing. Mature…

MaleAgingCellular immunitybiologyDNA synthesisDNA polymeraseBone Marrow CellsDNA Polymerase IIDNA-Directed DNA PolymeraseMolecular biologyMicemedicine.anatomical_structureTerminal deoxynucleotidyl transferaseBone MarrowDNA NucleotidylexotransferaseAgeingDNA Nucleotidyltransferasesbiology.proteinmedicineAnimalsBone marrowBovine serum albuminStem cellDevelopmental BiologyMechanisms of Ageing and Development
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POLE, POLD1, and NTHL1: the last but not the least hereditary cancer-predisposing genes

2021

POLE, POLD1, and NTHL1 are involved in DNA replication and have recently been recognized as hereditary cancer-predisposing genes, because their alterations are associated with colorectal cancer and other tumors. POLE/POLD1-associated syndrome shows an autosomal dominant inheritance, whereas NTHL1-associated syndrome follows an autosomal recessive pattern. Although the prevalence of germline monoallelic POLE/POLD1 and biallelic NTHL1 pathogenic variants is low, they determine different phenotypes with a broad tumor spectrum overlapping that of other hereditary conditions like Lynch Syndrome or Familial Adenomatous Polyposis. Endometrial and breast cancers, and probably ovarian and brain tumo…

MaleCancer ResearchSettore MED/06 - Oncologia MedicaColorectal cancerBiologymedicine.disease_causeGermlineFamilial adenomatous polyposisDeoxyribonuclease (Pyrimidine Dimer)Breast cancerNeoplasmsGeneticsmedicineHumansGenetic Predisposition to DiseasePoly-ADP-Ribose Binding ProteinsMolecular BiologyDNA Polymerase IIIGenetic testingMutationPOLD1medicine.diagnostic_testDNA Polymerase IIDNAmedicine.diseaseLynch syndromePOLE POLD1 and NTHL1Lynch SyndromeCancer researchFemaleOncogene
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Influence of template inactivators on the binding of DNA polymerase to DNA.

1974

The agents daunomycin, ethidium bromide, distamycin A and cytochrome c inhibit DNA dependent DNA polymerase I (E. coli) reaction competitively to DNA. The influence of these template inactivators on the binding of DNA polymerase to native as well as denatured DNA has been determined by affinity chromatography. Cytochrome c blocks the binding of the enzyme to double-stranded and to single-stranded DNA Sepharose. In contrast to these results daunomycin, ethidium bromide or distamycin A reduce the binding affinity only with denatured DNA Sepharose as matrix. These data are discussed with respect to the modification by template inactivators of the affinity of DNA to the different binding sites …

MaleDNA polymeraseDNA polymerase IICytochrome c GroupIn Vitro Techniqueschemistry.chemical_compoundNucleic acid thermodynamicsEthidiumGeneticsAnimalsEnzyme InhibitorsPolymeraseDNA clampBinding SitesbiologyDaunorubicinDistamycinsDNADNA Polymerase IMolecular biologyKineticschemistryBiochemistrybiology.proteinPrimer (molecular biology)DNA polymerase IDNANucleic acids research
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The telomeric Cdc13-Stn1-Ten1 complex regulates RNA polymerase II transcription

2019

Advance article.

S phase transcribed genesTranscription GeneticChromosomal Proteins Non-HistoneCell Cycle ProteinsRNA polymerase IIBur1[SDV.BC.BC]Life Sciences [q-bio]/Cellular Biology/Subcellular Processes [q-bio.SC]Genome Integrity Repair and ReplicationS Phase0302 clinical medicineTranscription (biology)Gene Expression Regulation FungalTranscriptional regulation0303 health sciencesCdc13-Stn1-Ten1biology030302 biochemistry & molecular biologyTranscription regulationRNA pol IIChromatinCyclin-Dependent KinasesCell biologyTelomeres030220 oncology & carcinogenesisRNA Polymerase IITranscriptional Elongation FactorsSaccharomyces cerevisiae ProteinsDNA polymerase IITelomere-Binding ProteinsSaccharomyces cerevisiae[SDV.CAN]Life Sciences [q-bio]/CancerSaccharomyces cerevisiaeCST complex03 medical and health sciencesGeneticsBudding yeastGenomesGene030304 developmental biologyHmo1RNA[SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry Molecular Biology/Molecular biologyPromoterbiology.organism_classificationCromosomesTelomerebiology.proteinSpt5Cyclin-Dependent Kinase-Activating Kinase
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UV-induced cross-linking of proteins to plasmid pBR322 containing 8-azidoadenine 2′-deoxyribonucleotides

1988

Abstract An efficient method of cross-linking DNA to protein is described. The method is based on the incorporation of photoactive 8-azidoadenine 2′-deoxyribonucleotides into DNA. We have found that 8-N 3 dATP is a substrate for E. coli DNA polymerase I and that 8-N 3 dATP can be incorporated into plasmid pBR322 by nick-translation. Subsequently we were able to cross-link a set of different proteins to 8-azido-2′-deoxyadenosine-containing pBR322 by UV irradiation (366 nm). No DNA-protein photocross-linking was observed under the same conditions when the non-photoactive plasmid pBR322 was used.

Ultraviolet RaysDNA polymeraseDNA polymerase IIUltraviolet irradiationBiophysicsAzidoadeninePlasmid pBR322BiochemistryHistonesDeoxyadenine NucleotidesPlasmidStructural BiologyEscherichia coliGeneticsNick translationMolecular BiologyPlasmid preparationDNA clampNick-translationbiologyDNA-protein cross-linkCell BiologyDNA Polymerase IPBR322Cross-Linking ReagentsBiochemistrybiology.proteinDNA polymerase IPlasmidsFEBS Letters
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RNA dependent DNA polymerase in cells of xeroderma pigmentosum

1971

Abstract Cells from X.P. ∗ skin contain an RNA dependent DNA polymerase, while in cells from normal skin this enzyme is lacking. This finding stimulates the thought that carcinogenesis in X.P. cells is due to an infection with an oncogenic RNA virus.

Xeroderma pigmentosumHepatitis B virus DNA polymeraseDNA polymeraseDNA polymerase IIDeoxyribonucleotidesPolynucleotidesBiophysicsRNA-dependent RNA polymeraseTritiummedicine.disease_causeRauscher VirusBiochemistryMicemedicineAnimalsChemical PrecipitationHumansMolecular BiologySkinchemistry.chemical_classificationXeroderma Pigmentosumintegumentary systembiologyRNA virusDNATemplates GeneticCell BiologyRibonucleotidesmedicine.diseasebiology.organism_classificationVirologyMolecular biologyStimulation ChemicalEnzymechemistryAmmonium SulfateDNA Nucleotidyltransferasesbiology.proteinRNAFemaleGuanosine TriphosphateCarcinogenesisBiochemical and Biophysical Research Communications
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Bleomycin, a selective inhibitor of DNA-dependent DNA polymerase from oncogenic RNA viruses.

1972

Abstract Bleomycin, an antibiotic, inhibits the DNA-dependent DNA polymerase from Rauscher murine leukemia virus. Higher concentrations of BLM ∗ are required to inhibit it's RNA-dependent DNA polymerase. These inhibition effects of the non-competitive type are not altered by preincubation of the DNA with BLM. Under comparable conditions neither the DNA-dependent DNA polymerase activity from E. coli and mouse liver nor the DNA-dependent RNA polymerase activity from mouse lymphoma cells are affected by BLM.

congenital hereditary and neonatal diseases and abnormalitiesTime FactorsLymphomaDNA polymeraseHepatitis B virus DNA polymeraseUracil NucleotidesDNA polymerase IIBiophysicsRNA-dependent RNA polymeraseCytosine NucleotidesTritiumBiochemistryRauscher VirusCell LineBleomycinMiceEscherichia coliAnimalsMolecular BiologyPolymeraseDNA clampAntibiotics Antineoplasticbiologyurogenital systemnutritional and metabolic diseasesCell BiologyDNAMolecular biologyReverse transcriptaseKineticsReal-time polymerase chain reactionLiverDNA Nucleotidyltransferasesbiology.proteinRNABiochemical and biophysical research communications
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Activity and kinetics of DNA dependent DNA and RNA polymerases n xeroderma pigmentosum and in normal human skin.

1971

1. DNA dependent DNA polymerase (E.C.2.7.7.7) was prepared from human normal and from Xeroderma pigmentosum skin. 2. DNA polymerase from normal skin has the same Michaelis constant with native and denatured DNA as templateKm= 120 ± 11 µg DNA/ml, with differing maximum reaction velocities. 3. The enzyme from Xeroderma pigmentosum has the same Michaelis constant for denatured DNA as the enzyme from normal skin, but with native DNA as template, theKmvalue is lower (97.2 ± 9.8). The maximum reaction velocities of the Xeroderma pigmentosum enzyme with native resp. denatured DNA as template are the same. 4. DNA dependent RNA polymerases (E.C.2.7.7.6) from normal and Xeroderma pigmentosum skin wer…

congenital hereditary and neonatal diseases and abnormalitiesXeroderma pigmentosumDNA polymeraseDNA polymerase IIDermatologyTritiumEndonucleasechemistry.chemical_compoundmedicineHumansskin and connective tissue diseasesPolymeraseSkinCarbon IsotopesXeroderma PigmentosumDNA clampintegumentary systembiologynutritional and metabolic diseasesRNA NucleotidyltransferasesGeneral MedicineDNAClinical Enzyme Testsmedicine.diseaseMolecular biologyEnzyme ActivationchemistryDNA Nucleotidyltransferasesbiology.proteinPrimer (molecular biology)DNAArchiv fur dermatologische Forschung
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