about
Close encounters with DNANano-mechanical measurements of protein-DNA interactions with a silicon nitride pulleyPlectoneme tip bubbles: coupled denaturation and writhing in supercoiled DNA.Effect of temperature on the intrinsic flexibility of DNA and its interaction with architectural proteins.Mechanical properties of base-modified DNA are not strictly determined by base stacking or electrostatic interactions.Role of microscopic flexibility in tightly curved DNA.Probing the elastic limit of DNA bendingDouble-stranded RNA under force and torque: similarities to and striking differences from double-stranded DNA.E. coli Gyrase Fails to Negatively Supercoil Diaminopurine-Substituted DNA.Simulation Assisted Analysis of the Intrinsic Stiffness for Short DNA Molecules Imaged with Scanning Atomic Force MicroscopyThe role of structural parameters in DNA cyclizationRevisiting the Anomalous Bending Elasticity of Sharply Bent DNAExclusion of small terminase mediated DNA threading models for genome packaging in bacteriophage T4.Two conformational states in D-shaped DNA: Effects of local denaturation.Watching DNA breath one molecule at a timeMechanical properties of DNA-like polymers.Sequence Affects the Cyclization of DNA Minicircles.Elasticity of the transition state for oligonucleotide hybridization.Superstatistical model of bacterial DNA architecture.Dynamic Release of Bending Stress in Short dsDNA by Formation of a Kink and ForksExtracting physical chemistry from mechanics: a new approach to investigate DNA interactions with drugs and proteins in single molecule experiments.Single-molecule fluorescence studies on DNA loopingWhy Cortical Neurons Cannot Divide, and Why Do They Usually Die in the Attempt?Structure and dynamics of DNA loops on nucleosomes studied with atomistic, microsecond-scale molecular dynamics.Extreme bendability of DNA double helix due to bending asymmetry.Flexibility of short DNA helices with finite-length effect: From base pairs to tens of base pairs.Evaluating the role of coherent delocalized phonon-like modes in DNA cyclization.DNA, flexibly flexible.Atomic force microscopy study of DNA flexibility on short length scales: smooth bending versus kinkingVariola type IB DNA topoisomerase: DNA binding and supercoil unwinding using engineered DNA minicircles.Unusual isothermal multimerization and amplification by the strand-displacing DNA polymerases with reverse transcription activities.Euler buckling and nonlinear kinking of double-stranded DNA.Coarse-graining DNA for simulations of DNA nanotechnology.Kinetics of polymer looping with macromolecular crowding: effects of volume fraction and crowder size.Analytical expressions for the closure probability of a stiff wormlike chain for finite capture radius.Probing the role of intercalating protein sidechains for kink formation in DNA.Rigidity of melting DNA.Phase diagram of the ground states of DNA condensates.Spatially programmed assembling of oxidoreductases with single-stranded DNA for cofactor-required reactions.Bioluminescence-based measurement of viability of Pseudomonas aeruginosa ATCC 9027 harbouring plasmid-based lux genes under the control of constitutive promoters.
P2860
Q26999396-69793A30-2C0E-4018-83E6-6ABA2CFB64E0Q27324455-21E99B66-0BCC-4A9A-B847-186A5D38F045Q30834510-FBC0A4C5-705B-4F8B-9888-3938B861A0D8Q33746195-8B8E5EA4-4D9D-4616-A6C5-18AA85FD116DQ33922312-97FB08AC-1C60-4926-B234-BFB564F1ED20Q34243185-CDBA6F44-EE86-41E9-913A-662FBEEB1AE5Q34249692-25AE33B4-C408-4C60-8339-5D94D6562699Q34442088-2BB444A4-CC6F-4A09-9C8C-98D87CEBDB9BQ35688681-3F82689D-06BA-4C6C-BDCA-07F39305C3E0Q35831816-EE974643-FCA7-4FE1-8BE9-B09DE8871067Q35914822-3FC8F914-E45D-4805-B7AB-83AEE80ED094Q36363476-EE67340E-507E-4360-AE9A-7F46886773ADQ36914620-A0D86055-26F0-4C72-B2E8-1D5033E29E3AQ37034922-661956EB-9BE2-4E8F-9A42-A049A7859F5FQ37256134-9CA61E57-1C1D-40F5-BF69-D6DDF202CD9FQ37528844-9941DCA1-A823-4428-85AC-3BDBAC73DB98Q37631118-506E11E6-D4E0-4874-B803-41983520B885Q37649476-CA8D387F-E436-4129-A052-C8B1CDF4404CQ37657883-48AF7EE9-38D7-47C4-AF5A-12B7921FA0E4Q38277383-967FB6B5-62CE-45C6-8DDF-3C378C6A0FC4Q38569444-30422298-99E9-4DC1-9B04-532C635046D5Q38883227-EBA4116B-5EC1-4527-84DC-59D48A2BD0F0Q38893299-EBB27646-737C-422B-9032-A5CEC89D1D2AQ39836354-D19FF58B-F768-4037-AB6A-E0D963BDF932Q40535988-02C36D7C-CEAF-42C2-A637-AA2A4791A327Q41125874-A2B08132-DABD-49F9-9913-B0C625DFAD7BQ41548681-D9DF368E-35FB-42C6-86A3-ED45D088FF43Q41819502-B4F9D659-A64D-4136-9955-D6AE7D0A8657Q41820054-B92DD96D-EEFF-48F6-813B-574AA1DE3A5AQ42211325-F54CFA03-C790-4944-8B80-A2F9CE5DECCCQ42638723-5D6BEEAB-B2F8-4CA9-BF83-E0C8903F1C04Q42876248-27F5EC57-5EC5-473F-AEB6-84775E29A2CFQ43817739-416DBA2B-8424-4622-9179-68F8F68723BBQ47424724-912F20E6-F4DC-4C7C-B436-960ECDB71BC0Q49819137-DA3347CA-C35E-4C05-95E6-2A9B33D6A7B9Q50062363-F6342367-2B77-4FEF-B21B-B4B10A79FF3FQ50627727-4311F39B-4BA5-443A-83CC-BCDC1CC7F52BQ50735638-5AAD21F8-F8F8-48E1-B474-87434BFE7FB8Q51038284-9B1DEE9A-DEE8-4857-9212-D0B8C6505D2DQ51413236-8E93714D-2E64-4EF2-BA4C-11D454F293DA
P2860
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
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name
Strong bending of the DNA double helix.
@en
type
label
Strong bending of the DNA double helix.
@en
prefLabel
Strong bending of the DNA double helix.
@en
P2860
P356
P1476
Strong bending of the DNA double helix.
@en
P2093
Alexander Vologodskii
Maxim D Frank-Kamenetskii
P2860
P304
P356
10.1093/NAR/GKT396
P407
P577
2013-05-15T00:00:00Z
2013-08-01T00:00:00Z