Determination of the number of superhelical turns in simian virus 40 DNA by gel electrophoresis.
about
The radioresistance kinase TLK1B protects the cells by promoting repair of double strand breaks.Linking numbers and nucleosomesDNA stability at temperatures typical for hyperthermophilesFluctuations in superhelical DNAComparison of nuclease digestion of polyoma virus nucleoprotein complex and mouse chromatinGenomic transcriptional response to loss of chromosomal supercoiling in Escherichia coliThe DNA unwinding element: a novel, cis-acting component that facilitates opening of the Escherichia coli replication originThe dynamic response of upstream DNA to transcription-generated torsional stressTopoisomerase IV, alone, unknots DNA in E. coliActivation of gene expression by a novel DNA structural transmission mechanism that requires supercoiling-induced DNA duplex destabilization in an upstream activating sequence.Organization of DNA in chromatin.Effective and robust plasmid topology analysis and the subsequent characterization of the plasmid isoforms thereby observed.Effect of polyethylene glycol on the supercoiling free energy of DNA.DNA supercoiling-dependent transcriptional coupling between the divergently transcribed promoters of the ilvYC operon of Escherichia coli is proportional to promoter strengths and transcript lengths.The dynamic interplay between DNA topoisomerases and DNA topology.Intercalators promote the binding of RecA protein to double-stranded DNAStable DNA unwinding, not "breathing," accounts for single-strand-specific nuclease hypersensitivity of specific A+T-rich sequences.Small abundant DNA binding proteins from the thermoacidophilic archaeon Sulfolobus shibatae constrain negative DNA supercoils.DNA supercoiling helps to unlink sister duplexes after replication.An improved method for large-scale preparation of negatively and positively supercoiled plasmid DNA.Effect of transcription of yeast chromatin on DNA topology in vivo.Strand separation required for initiation of replication at the chromosomal origin of E.coli is facilitated by a distant RNA--DNA hybrid.Formation of Z-DNA in negatively supercoiled plasmids is sensitive to small changes in salt concentration within the physiological range.Inhibition of eukaryotic tRNA transcription by potential Z-DNA sequences.How many base-pairs per turn does DNA have in solution and in chromatin? Some theoretical calculationsDNA gyrase: an enzyme that introduces superhelical turns into DNA.Acidic polypeptides can assemble both histones and chromatin in vitro at physiological ionic strength.Effects of supercoiling in electrophoretic trapping of circular DNA in polyacrylamide gels.Chromatin fibers are left-handed double helices with diameter and mass per unit length that depend on linker length.X-ray scattering from randomly oriented superhelices. Circular superhelical DNA.Structure of chromatin and the linking number of DNA.Expression of yeast DNA topoisomerase I can complement a conditional-lethal DNA topoisomerase I mutation in Escherichia coli.Step-wise DNA relaxation and decatenation by NaeI-43K.Topological complexity of different populations of pBR322 as visualized by two-dimensional agarose gel electrophoresis.DNA unwinding and inhibition of mouse leukemia L1210 DNA topoisomerase I by intercalators.Methylene blue photosensitised strand cleavage of DNA: effects of dye binding and oxygen.The main early and late promoters of Bacillus subtilis phage phi 29 form unstable open complexes with sigma A-RNA polymerase that are stabilized by DNA supercoilingNovobiocin and coumermycin inhibit DNA supercoiling catalyzed by DNA gyrase.Renaturation of complementary single-stranded DNA circles: complete rewinding facilitated by the DNA untwisting enzyme.The non-B-DNA structure of d(CA/TG)n differs from that of Z-DNA.
P2860
Q21263017-41D67FB0-1555-4F53-8088-6714328F56C3Q24561785-CD268214-BE13-4695-AD25-C87841243115Q24610862-4527E821-360F-45B5-A25D-72CBC757FD62Q24633322-34B67307-E500-4121-97B4-49EDD30D5029Q24633668-C70418AA-68E3-446A-8DDD-411D01081DF5Q24809586-BE7C53B2-DDAD-4160-9A0A-F39D0E352146Q28254988-F30A87AF-6BBD-4F60-A87D-4CBCD14D08A4Q28289461-17027990-AB2A-4FF1-9601-47B5C6057749Q28361527-7EE7E728-964F-4862-BFC8-CB1130D774BFQ28533041-0A903F2C-7576-4522-BF98-6D8CDDB2B93AQ30449120-F68B6782-59C3-489F-AC98-A8E3CF808134Q30840643-FA4380E2-3A81-4AB2-8E4A-675585860B10Q31623204-D9752DD7-0BFB-420E-88C9-6BD8255E4BD9Q31727630-AFEDC162-4F7D-41A9-BAEA-2F3B77D2F9FBQ33639806-90349C37-2EA5-4EAD-B1A3-AD3E9A0773F4Q33660249-86C6316A-8335-4734-B28E-DF0C7C26CE2EQ33684785-0BB4C3E6-5113-478A-A7D0-9893B2D39DEEQ33730508-EC5157EF-1948-480F-923A-01B80D6F382CQ33753277-1262E22D-7E1A-4AF4-ABAE-27AFBCA3AB4BQ33803757-434674B1-193E-4316-8E9B-9A08E1F56431Q33920270-E31FA57B-14CB-402A-9581-AFF2E3D01B77Q33920987-0DE713E9-7637-41D0-AC20-12104016ED3DQ33933477-64D3442D-061F-433B-A289-F522DF760C93Q33939674-37242A06-F769-463C-AE09-8318014664FEQ33959935-96C3622B-08D3-4389-92E7-44420F1F978AQ34013173-7CF79B38-3ACF-4EFC-AFE6-8022A26427EBQ34035715-56339431-79D4-4601-8F59-534B70BCB64BQ34168166-5DC4924A-6422-4CF6-8B7D-9A9ADA79963DQ34196678-770B1297-08DF-4984-BB33-D572DFEBE7DCQ34254801-C8DA067D-0BED-48F3-9CC6-2B6D60E0657BQ34273632-AD8D838E-CEB8-476A-B124-8CFFAED5B092Q34377860-1DF4A147-A8D6-4E3A-921E-26296B60887AQ34666242-0FF52532-96D8-4429-8345-D1317C0F4C59Q34670868-F6E9EEFC-43FC-4E6A-B6EA-16EF9FD1A926Q34700902-43750A13-AD00-4622-AD97-562E764D32D8Q34708353-6E26FDE4-5BAE-43C8-A4C9-19C8A1DDA70EQ34972682-4E1316D4-B72A-4B27-8971-990948747699Q35042255-17D84532-BC7D-43AF-8AFB-45CC7F89D266Q35048971-827BFF99-89E4-44BD-9037-D14A9B134FB6Q35081051-280A331C-F6A5-405C-B686-A84877D023ED
P2860
Determination of the number of superhelical turns in simian virus 40 DNA by gel electrophoresis.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on December 1975
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Determination of the number of ...... 40 DNA by gel electrophoresis.
@en
Determination of the number of ...... 40 DNA by gel electrophoresis.
@nl
type
label
Determination of the number of ...... 40 DNA by gel electrophoresis.
@en
Determination of the number of ...... 40 DNA by gel electrophoresis.
@nl
prefLabel
Determination of the number of ...... 40 DNA by gel electrophoresis.
@en
Determination of the number of ...... 40 DNA by gel electrophoresis.
@nl
P2860
P356
P1476
Determination of the number of ...... 40 DNA by gel electrophoresis.
@en
P2093
P2860
P304
P356
10.1073/PNAS.72.12.4876
P407
P577
1975-12-01T00:00:00Z