Volume-Exclusion Effects in Tethered-Particle Experiments: Bead Size Matters - Test2 - elhamkhani - TriplyDB

Volume-Exclusion Effects in Tethered-Particle Experiments: Bead Size Matters

Volume-Exclusion Effects in Tethered-Particle Experiments: Bead Size Matters

http://www.wikidata.org/entity/Q27346205

about

Conformational equilibria in monomeric alpha-synuclein at the single-molecule level Magnetic forces and DNA mechanics in multiplexed magnetic tweezers Direct Characterization of Transcription Elongation by RNA Polymerase I Concentration and length dependence of DNA looping in transcriptional regulation The MHF complex senses branched DNA by binding a pair of crossover DNA duplexes Interconvertible lac repressor-DNA loops revealed by single-molecule experiments Chemotaxis in Escherichia coli: a molecular model for robust precise adaptation Stepwise bending of DNA by a single TATA-box binding protein.Lac repressor hinge flexibility and DNA looping: single molecule kinetics by tethered particle motion DNA looping kinetics analyzed using diffusive hidden Markov model.Rational optimization and imaging in vivo of a genetically encoded optical voltage reporter.Dissecting protein-induced DNA looping dynamics in real time.Single-molecule approaches to probe the structure, kinetics, and thermodynamics of nucleoprotein complexes that regulate transcription.First-principles calculation of DNA looping in tethered particle experiments.High-throughput single-molecule analysis of DNA-protein interactions by tethered particle motion.Stretching submicron biomolecules with constant-force axial optical tweezers.The persistence length of double stranded DNA determined using dark field tethered particle motion.Multiple LacI-mediated loops revealed by Bayesian statistics and tethered particle motion.DNA synapsis through transient tetramerization triggers cleavage by Ecl18kI restriction enzyme.HU protein induces incoherent DNA persistence length.Balls and chains--a mesoscopic approach to tethered protein domains.Lac repressor mediated DNA looping: Monte Carlo simulation of constrained DNA molecules complemented with current experimental results.Tethered fluorophore motion: studying large DNA conformational changes by single-fluorophore imaging Molecular mechanochemistry: low force switch slows enzymatic cleavage of human type I collagen monomer.Optical Pushing: A Tool for Parallelized Biomolecule Manipulation.Elasticity of short DNA molecules: theory and experiment for contour lengths of 0.6-7 microm Sequence dependence of transcription factor-mediated DNA looping Remote control of DNA-acting enzymes by varying the Brownian dynamics of a distant DNA end Biological consequences of tightly bent DNA: the other life of a macromolecular celebrity.Subpiconewton dynamic force spectroscopy using magnetic tweezers.Single-molecule microscopy of Cre recombination Capturing reaction paths and intermediates in Cre-loxP recombination using single-molecule fluorescence Nonequilibrium distributions and hydrodynamic coupling distort the measurement of nanoscale forces near interfaces.Optical Methods to Study Protein-DNA Interactions in Vitro and in Living Cells at the Single-Molecule Level.Probing DNA topology using tethered particle motion.Silica encapsulation of fluorescent nanodiamonds for colloidal stability and facile surface functionalization.Type III restriction enzymes communicate in 1D without looping between their target sites.Hidden Markov analysis of nucleosome unwrapping under force.Biochemistry on a leash: the roles of tether length and geometry in signal integration proteins.Probing the conformational distributions of subpersistence length DNA.

P2860

Q21563559-85FB6E9D-5D05-41B9-9B83-1E075E9FB5B9 Q27331997-3E3F1110-BAD3-4F41-87C7-395E98C70B4E Q27334051-CF06B330-401A-4D9D-A8B8-3C2D97BD85A5 Q27349246-9397B3FF-DAA3-466B-84BF-874ACF1E5704 Q27681193-3E42951A-2A04-4E83-AB6B-6DDC0553E029 Q28295676-C7EDE254-BE55-4911-BEDF-9697A22EE4D3 Q28471934-8E6E020D-21D9-42D5-B187-E01128AE9813 Q30477147-43CBD602-AAD8-4510-B625-ED4B30B4D11C Q30477690-2FCD5EC9-3888-4814-8137-9E89D11A4BEA Q30479142-5C8F155D-1EED-4BCA-9766-1ED90DE76BCF Q30489003-45423486-49E0-488C-A0BD-6084C98F5E61 Q30490896-DBD19F24-A477-44C7-828E-E2CB62012C80 Q30494866-390D1C2F-7EC2-41FD-892F-9DE98348084B Q30508525-ABD8787B-B6BB-4908-A085-4D545F2C231E Q30518261-2F0A9497-F12D-4241-807F-A57022D0900C Q33457765-15EE4B14-D89A-45EF-BEB2-2D7149DD106E Q33464546-91284F1B-FFA3-428B-BBD0-17EC14AD1286 Q34249726-1BBD839B-01A1-4F4F-AA58-D046A0AB9F15 Q34298082-C3339BD1-BC3E-4989-BF79-98004E86D6DE Q34536393-23265EF0-BA9C-40C7-A41F-DAFF898966AC Q35021368-93D79D8E-00B1-464A-895A-A5E895E68EB3 Q35163591-FF464C04-A6B3-44EA-B93B-1E9A13C89835 Q35237698-6516195B-733A-4EE7-99BE-533E0348FF92 Q35822098-CD69AAC2-CF06-45F1-B4D7-B128C63A5BE3 Q35888717-A8AFE66D-E020-46CA-8BBB-B2325BE1B465 Q36175891-0B9CB9EE-779F-4D09-8517-735C09A9BE15 Q36228471-4BBA470B-42E5-421E-9651-1AA097F3B04D Q36339776-774DE6D6-8F55-4649-91FD-B3BCA1726656 Q36395025-D86D38D1-45D9-41E6-B395-E41B0D19B235 Q36481435-56682B73-010E-4F63-81AA-248015136E4E Q36485069-9E9526E6-A312-488D-A3EF-2905B9423DA8 Q36485115-29B3BA06-9F58-4264-8892-17DFC615625B Q36621992-5944CE7E-838E-40D9-89DB-2A9982EFF1B4 Q36656166-FA267587-EE63-457B-BFC6-7B3B644CABD9 Q36842347-6D7E3435-7882-47AB-95E0-69CE18440377 Q36946888-02A39C7E-6224-465B-91DD-7DD66C8128B1 Q37078204-C2E0D815-F4A1-4723-8CFE-5546CEAD04C3 Q37263583-39C1C5DE-CBD8-4B75-806F-1D7A799BC1BE Q37279169-BCB37081-CFB4-43F7-9BD8-887786E7C5D4 Q37359445-3CAB2008-0B37-4DF4-A9CC-D4E47C960771

P2860

Volume-Exclusion Effects in Tethered-Particle Experiments: Bead Size Matters

http://www.wikidata.org/entity/Q27346205

description

2006 nî lūn-bûn

@nan

2006 թուականի Մարտին հրատարակուած գիտական յօդուած

@hyw

2006 թվականի մարտին հրատարակված գիտական հոդված

@hy

2006年の論文

@ja

2006年論文

@yue

2006年論文

@zh-hant

2006年論文

@zh-hk

2006年論文

@zh-mo

2006年論文

@zh-tw

2006年论文

@wuu

name

Volume-Exclusion Effects in Tethered-Particle Experiments: Bead Size Matters

@ast

Volume-Exclusion Effects in Tethered-Particle Experiments: Bead Size Matters

@en

Volume-Exclusion Effects in Tethered-Particle Experiments: Bead Size Matters

@nl

type

label

Volume-Exclusion Effects in Tethered-Particle Experiments: Bead Size Matters

@ast

Volume-Exclusion Effects in Tethered-Particle Experiments: Bead Size Matters

@en

Volume-Exclusion Effects in Tethered-Particle Experiments: Bead Size Matters

@nl

prefLabel

Volume-Exclusion Effects in Tethered-Particle Experiments: Bead Size Matters

@ast

Volume-Exclusion Effects in Tethered-Particle Experiments: Bead Size Matters

@en

Volume-Exclusion Effects in Tethered-Particle Experiments: Bead Size Matters

@nl

P1433

Q27346205-2D9999BC-61BC-468E-AF1B-9E8AC879A520

P1476

Q27346205-5902F666-E2A8-4DB4-BA64-0E7D3D788712

P2093

Q27346205-371D4CF8-A5F0-46FF-A689-F3052456B66C

Q27346205-8F8EBA65-694A-4987-86D1-B16B750C3F50

Q27346205-CE635A37-8B5B-45BF-9DB3-2FBB9EE3AE86

P2860

Q27346205-2789C82A-AB19-4DAB-9A2E-DF4873CA6259

Q27346205-2B5CF669-BE7B-4939-B5FB-3B57EE4EB116

Q27346205-2DF7EDFB-7B24-40EF-9CC8-3AC7617BCA39

Q27346205-6F267519-C01E-42DF-BBAE-8FBC554E684D

Q27346205-CAA97CBD-E9D4-4EEF-A8F9-DF222DBE3A9F

Q27346205-E03B9F81-1362-45C4-BE81-B82268C3AA6A

Q27346205-EBE7FE92-6A60-4974-915A-C6DA52CAA698

Q27346205-EF68FC0B-E4F3-467E-9334-B099F71F5297

Q27346205-F76187A2-9AA0-4DB7-9AA1-6E87A21DEF46

Q27346205-FD7933D7-00FE-4EA7-8028-110A72F8065E

P31

Q27346205-FEFE2CF4-7C50-457B-901A-75865A3A513F

P3181

Q27346205-680EA6CA-C126-4E87-BA3C-0323FE73513B

P356

Q27346205-77D9AA22-3973-45FE-9134-1205987D7D00

P407

Q27346205-49594176-E294-4888-880E-9299D699327A

P433

Q27346205-3DEBE352-86F1-40B9-AA57-AB6C125C017B

P478

Q27346205-4771C8DA-ACDC-455B-8F41-C36E055CF0FE

P577

Q27346205-4BF2C554-5B3B-416B-A8D9-C56E531C9D20

P698

Q27346205-9BE57BBC-BC15-4E33-91B4-6E2AE4AD5007

P818

Q27346205-BD087CF1-5A5C-48E4-AEAF-1A61E7A4CA48

P932

Q27346205-CFC3B16B-9004-41CE-B5C1-D99884461524

P3181

P356

PHYSREVLETT.96.088306

P1433

Physical Review Letters

P1476

Volume-Exclusion Effects in Tethered-Particle Experiments: Bead Size Matters

@en

P2093

Darren E. Segall

http://www.w3.org/2001/XMLSchema#string

Philip C. Nelson

http://www.w3.org/2001/XMLSchema#string

Rob Phillips

http://www.w3.org/2001/XMLSchema#string

P2860

Tethered particle motion method for studying transcript elongation by a single RNA polymerase molecule

Transcription by single molecules of RNA polymerase observed by light microscopy.

Tracking kinesin-driven movements with nanometre-scale precision.

Quantitative study of polymer conformation and dynamics by single-particle tracking.

Single-particle tracking for DNA tether length monitoring

Protein synthesis by single ribosomes.

Single-molecule detection of DNA hybridization

Molecular motors and mechanisms of directional transport in neurons.

Single-molecule kinetics of lambda exonuclease reveal base dependence and dynamic disorder.

χ-Sequence recognition and DNA translocation by single RecBCD helicase/nuclease molecules

P31

scholarly article

P3181

4421088

http://www.w3.org/2001/XMLSchema#string

P356

10.1103/PHYSREVLETT.96.088306

http://www.w3.org/2001/XMLSchema#string

P407

P433

8

http://www.w3.org/2001/XMLSchema#string

P478

96

http://www.w3.org/2001/XMLSchema#string

P577

2006-03-03T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P698

16606235

http://www.w3.org/2001/XMLSchema#string

P818

q-bio/0508028

http://www.w3.org/2001/XMLSchema#string

P932

3261840

http://www.w3.org/2001/XMLSchema#string