about
Electrophoresis of DNA and other polyelectrolytes: Physical mechanismsExact method for numerically analyzing a model of local denaturation in superhelically stressed DNAStructural diversity of supercoiled DNA.A computer aided thermodynamic approach for predicting the formation of Z-DNA in naturally occurring sequences.Linking numbers and nucleosomesOpposite orientations of DNA bending by c-Myc and MaxHelical repeat of DNA in solutionDNA stability at temperatures typical for hyperthermophilesFluctuations in superhelical DNAStructure of a B-DNA dodecamer at 16 KArchitecture of nonspecific protein-DNA interactions in the Sso7d-DNA complexRegulation of bacterial DNA supercoiling: plasmid linking numbers vary with growth temperatureA Biophysical Model of CRISPR/Cas9 Activity for Rational Design of Genome Editing and Gene RegulationSupercoiling of the DNA template during transcriptionA molecular mechanical model to predict the helix twist angles of B-DNATemperature, template topology, and factor requirements of archaeal transcriptionMinute negative superhelicity is sufficient to induce the B-Z transition in the presence of low tensionA structural transition in duplex DNA induced by ethylene glycol.DNA supercoiling and its role in DNA decatenation and unknotting.Theoretical analysis of the stress induced B-Z transition in superhelical DNA.Regulation of the function of eukaryotic DNA topoisomerase I: topological conditions for inactivitySuperhelical torsion in cellular DNA responds directly to environmental and genetic factors.On the origin of the temperature dependence of the supercoiling free energy.Torque measurement at the single-molecule levelThe effect of intrinsic curvature on conformational properties of circular DNA.Effect of transcription of yeast chromatin on DNA topology in vivo.Formation of Z-DNA in negatively supercoiled plasmids is sensitive to small changes in salt concentration within the physiological range.Remodeling of yeast CUP1 chromatin involves activator-dependent repositioning of nucleosomes over the entire gene and flanking sequencesTheoretical analysis of competing conformational transitions in superhelical DNA.Thermal unwinding of simian virus 40 transcription complex DNADNA and spermidine provide a switch mechanism to regulate the activity of restriction enzyme Nae I.What controls DNA looping?DNA gyrase: structure and function.DNA overwinds when stretched.Temperature dependence of DNA persistence length.Step-wise DNA relaxation and decatenation by NaeI-43K.New alkaloid antibiotics that target the DNA topoisomerase I of Streptococcus pneumoniaePersistence of an alternate chromatin structure at silenced loci in vitro.Crucial role for DNA supercoiling in Mu transposition: a kinetic study.DNA relaxation by human topoisomerase I occurs in the closed clamp conformation of the protein
P2860
Q21563889-0DE91AB2-B74F-4EF3-91BA-6FE9FB2CCC14Q21686233-F3AB088C-4149-4779-BB7B-159453283F49Q22122088-2643D40C-01CC-4B1A-8518-9C0341C52ED7Q24531850-BB40DFBE-FB17-460B-8110-011C0D305636Q24561785-3B6C65B6-16F9-4D5D-95FC-A8D66584E22FQ24564314-CDC27853-07AA-45CF-B3D2-2D1C74D9D6EFQ24599121-00EAEEA5-EF02-4297-B260-D3C9CFF35E3EQ24610862-5A380707-F1D2-4C08-BE03-8977E36AB82AQ24633322-65D28E4B-580B-459C-9953-167ED86F66FCQ27729185-D68240A2-4DBB-423A-A229-243747AEA2F4Q27764578-DD41D930-D163-4991-8EAE-B532A4A19BB5Q28267186-275F1031-37F1-4AFB-A420-A4EA0E9189EBQ28552981-3DC56463-ECE3-4DE9-B71E-1320A199838BQ29617503-989289BB-632B-4E3B-BDCF-6EB43112F45EQ30533271-9B644633-D09C-4BA8-93F2-574F58B737F8Q33574111-7DC4746E-33C1-4C2C-988C-6FB9FF3F7A5EQ33740155-BCA28E6A-A128-4F38-8025-22C7D42965B0Q33761850-E3C5D5CA-C610-47F7-A1E5-5036D53D3A51Q33783142-FB7AD549-1E46-45E8-9BAC-7EE100E6ACB5Q33809365-5E4342D6-E8EC-41B4-ABDB-02520C821872Q33852312-B57BFCFC-1304-4058-96CC-A40D85055630Q33866962-39243AC5-0B85-46A5-916E-1277251CB789Q33907831-4D00B4CC-CDA3-4EA2-9A28-24F69CC2D591Q33914834-9D3C4391-78C1-44E9-9A49-0B64D2363D7CQ33915682-E1A7424F-B3AF-4AF0-9F40-29A8F9A752D3Q33920270-AB940E3B-8ED4-4B75-BE82-B8B1804D7D62Q33933477-D60CE19D-BF07-46C7-989E-74FA5DBA410FQ33966940-8A799B3A-ED43-486B-9EE1-8A8ED699A5DEQ34262981-8EA59318-4D92-48C5-92D7-8F5D8203BD7DQ34318479-6BEAAD72-E6E4-459E-AE8C-F7448C3F9250Q34324777-2E37440C-A00A-4308-9D5A-E311DDE7781EQ34358615-095CC7BC-9829-4C33-94BA-2696F61FB130Q34507230-C4B8E216-3B75-41C3-8078-BC3539185E21Q34550388-CA58EFFC-74FE-405C-A864-BC2017FE0F2DQ34609298-A8C1587A-90A3-4305-A689-3B63D67218E1Q34666242-50D55119-DD19-4CA7-BF71-A2603861AB30Q34675643-A7BFB7B0-3D10-4E47-8893-6BFE5A5E8CD8Q34807214-E9DF5228-EC84-401B-863A-0697A2657BDEQ34994105-36362889-F37B-484F-AF57-AB1E25D74A58Q35021762-D835CC40-0958-4E7E-856E-541AE005F1EC
P2860
description
1975 nî lūn-bûn
@nan
1975年の論文
@ja
1975年学术文章
@wuu
1975年学术文章
@zh-cn
1975年学术文章
@zh-hans
1975年学术文章
@zh-my
1975年学术文章
@zh-sg
1975年學術文章
@yue
1975年學術文章
@zh
1975年學術文章
@zh-hant
name
Conformational fluctuations of DNA helix
@en
Conformational fluctuations of DNA helix.
@nl
type
label
Conformational fluctuations of DNA helix
@en
Conformational fluctuations of DNA helix.
@nl
prefLabel
Conformational fluctuations of DNA helix
@en
Conformational fluctuations of DNA helix.
@nl
P2860
P356
P1476
Conformational fluctuations of DNA helix
@en
P2093
P2860
P304
P356
10.1073/PNAS.72.11.4275
P407
P577
1975-11-01T00:00:00Z