Revealing the competition between peeled ssDNA, melting bubbles, and S-DNA during DNA overstretching using fluorescence microscopy
about
Unravelling the structural plasticity of stretched DNA under torsional constraintThe transition mechanism of DNA overstretching: a microscopic view using molecular dynamics.A possible pathogenetic factor of sickle-cell disease based on fluorescent analysis via an optofluidic resonator.Equilibrium and kinetics of DNA overstretching modeled with a quartic energy landscapeSingle aromatic residue location alters nucleic acid binding and chaperone function of FIV nucleocapsid protein.Extending the range for force calibration in magnetic tweezersForce regulated dynamics of RPA on a DNA forkThe impact of DNA intercalators on DNA and DNA-processing enzymes elucidated through force-dependent binding kinetics.DNA Binding Peptide Directed Synthesis of Continuous DNA Nanowires for Analysis of Large DNA Molecules by Scanning Electron Microscope.L1 retrotransposition requires rapid ORF1p oligomerization, a novel coiled coil-dependent property conserved despite extensive remodelingDisturbance-free rapid solution exchange for magnetic tweezers single-molecule studies.Mechanisms of small molecule-DNA interactions probed by single-molecule force spectroscopy.DNA Sequence Alignment during Homologous Recombination.Differential contribution of basic residues to HIV-1 nucleocapsid protein's nucleic acid chaperone function and retroviral replication.Oligomerization transforms human APOBEC3G from an efficient enzyme to a slowly dissociating nucleic acid-binding protein.Single-molecule studies of high-mobility group B architectural DNA bending proteins.Human RAD52 Captures and Holds DNA Strands, Increases DNA Flexibility, and Prevents Melting of Duplex DNA: Implications for DNA RecombinationSingle-molecule portrait of DNA and RNA double helices.Transient kinetics measured with force steps discriminate between double-stranded DNA elongation and melting and define the reaction energeticsExtracting physical chemistry from mechanics: a new approach to investigate DNA interactions with drugs and proteins in single molecule experiments.Visualizing recombination intermediates with single-stranded DNA curtains.Force Spectroscopy in Studying Infection.Coexistence of twisted, plectonemic, and melted DNA in small topological domains.An AT-barrier mechanically controls DNA reannealing under tension.Single-molecule mechanochemical characterization of E. coli pol III core catalytic activity.Dimerization regulates both deaminase-dependent and deaminase-independent HIV-1 restriction by APOBEC3G.Cavity approach for modeling and fitting polymer stretching.Force-induced melting of DNA--evidence for peeling and internal melting from force spectra on short synthetic duplex sequences.An effective mesoscopic model of double-stranded DNA.Global force-torque phase diagram for the DNA double helix: structural transitions, triple points, and collapsed plectonemes.Parallel triplex structure formed between stretched single-stranded DNA and homologous duplex DNA.Probing the mechanical stability of bridged DNA-H-NS protein complexes by single-molecule AFM pulling.Coarse-graining DNA for simulations of DNA nanotechnology.DNA overstretching transition induced by melting in a dynamical mesoscopic model.Freezing shortens the lifetime of DNA molecules under tension.Hyperstretching DNA.DNA partitions into triplets under tension in the presence of organic cations, with sequence evolutionary age predicting the stability of the triplet phase.Force-activated DNA substrates for probing individual proteins interacting with single-stranded DNA.Introduction to Optical Tweezers: Background, System Designs, and Commercial Solutions.Optical Trapping Nanometry of Hypermethylated CPG-Island DNA.
P2860
Q30381156-7C7C1997-641A-4F4A-9842-90194CD46815Q30596224-99366EEA-0A14-4993-AB89-5D97E431D384Q33784413-B5CC755C-3DC2-445B-AC79-E3DD262E5834Q34467116-089BE05C-DB7B-4515-9B8B-A73A81D6A5ECQ34614790-C9E6FDFF-D1DC-4E40-8E28-EFE9FED65EE5Q35687172-2823E353-EA6E-4BE9-AB74-960DF7FFE41EQ35970890-81083ABE-E83E-498B-A230-3BD695C13AA6Q36018830-319C51E0-125B-468E-BDA5-561C9103833CQ36182644-899BBBCF-D7F4-48E3-8811-2279786002FAQ36443314-C98576A4-41A1-42E8-A958-E8EB7A10E031Q36676714-8630C1FF-23D2-42F0-8A40-3647E514A775Q36914636-1B324918-FBE9-478A-A14E-403E335D4314Q36941063-9A28F405-8AF5-4AB9-B9DC-1A61CBFDD9C6Q37606985-D0AFB089-FFD1-4FC4-9962-2C56FCC7D55BQ37631430-EBA3C200-2C0B-4547-8356-CDAAEDF9E90FQ37672521-880A1B98-79B2-42CE-9D32-0E391A037850Q37736341-1A010DC7-14FC-4E45-BD40-C0B1D34A00B2Q38244946-AAAC29FA-2EAF-47C6-8E5A-624DD7D72289Q38256914-95B763CF-4345-479E-96FF-5C3BF96B1261Q38569444-B6214B31-E165-40B9-AB27-B5F398318014Q38796466-89EE7BF3-F4B4-4FC3-B482-D65EFF69D2CEQ38837743-6756EC6B-FDF5-40BC-BF7C-0905C2B2C80AQ39760272-998DD104-6F51-4EE9-8B13-47AD2E66F87CQ40667051-05921849-8BE9-4CC1-9595-3BB383635E08Q41089391-073B9C2F-109D-443B-9AD3-D0BA26C58A69Q41701165-B40F6E8C-7AFB-4B40-8B84-F355FD6D1145Q41706578-23F8CE22-DB23-41B1-9244-E19FD2B0C062Q41834042-79063DD1-0B82-42BC-8CF3-6DE96A06134AQ41954084-966F4F83-F75F-42EF-A343-E15E3CC0E3DAQ41982231-289F6571-E053-441F-B1D8-0807CE52AB68Q42367970-A3E4989A-CB3C-4C88-B301-B123E6607045Q43536268-DEB3DA8E-0A1E-4BA7-8E6B-968DAB56D940Q43817739-2102B774-9A83-407A-88F0-A726599AE8A7Q44846505-CA375B0D-78EE-4748-AABE-2B457D89DFC6Q45329623-962BA196-51C0-48E2-9F09-C76EC4257E7AQ47104471-BFA91718-207D-463E-BD2F-EA6DAD0C2808Q47301759-D2F12FEE-6270-4177-97FC-AC3F406A4A9EQ47601791-FE169945-F0A2-4350-B4C1-C92E3BC6E46EQ47757772-2D8C9C67-4D6D-4302-82B0-895CB80B124CQ49635345-65E436C7-BBF9-4124-8C8F-2F1D37A44E98
P2860
Revealing the competition between peeled ssDNA, melting bubbles, and S-DNA during DNA overstretching using fluorescence microscopy
description
2013 nî lūn-bûn
@nan
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
2013年论文
@zh
2013年论文
@zh-cn
name
Revealing the competition betw ...... using fluorescence microscopy
@ast
Revealing the competition betw ...... using fluorescence microscopy
@en
type
label
Revealing the competition betw ...... using fluorescence microscopy
@ast
Revealing the competition betw ...... using fluorescence microscopy
@en
prefLabel
Revealing the competition betw ...... using fluorescence microscopy
@ast
Revealing the competition betw ...... using fluorescence microscopy
@en
P2093
P2860
P356
P1476
Revealing the competition betw ...... using fluorescence microscopy
@en
P2093
Gijs J L Wuite
Graeme A King
Peter Gross
Ulrich Bockelmann
P2860
P304
P356
10.1073/PNAS.1213676110
P407
P577
2013-02-19T00:00:00Z