The two-pathway model for the catch-slip transition in biological adhesion. - Wikidata - awgldk - TriplyDB

The two-pathway model for the catch-slip transition in biological adhesion.

The two-pathway model for the catch-slip transition in biological adhesion.

http://www.wikidata.org/entity/Q34350947

about

Mechanics of actomyosin bonds in different nucleotide states are tuned to muscle contraction E-selectin ligand complexes adopt an extended high-affinity conformation.Catch-bond mechanism of the bacterial adhesin FimH.Modeling cytoadhesion of Plasmodium falciparum-infected erythrocytes and leukocytes-common principles and distinctive features Loop 2 of myosin is a force-dependent inhibitor of the rigor bond A High-Throughput Technique Reveals the Load- and Site Density-Dependent Kinetics of E-Selectin Force spectroscopy reveals multiple "closed states" of the muscle thin filament.The Effects of Load on E-Selectin Bond Rupture and Bond Formation.Nano-motion dynamics are determined by surface-tethered selectin mechanokinetics and bond formation.Enhancement of L-selectin, but not P-selectin, bond formation frequency by convective flow.Catch-bond model derived from allostery explains force-activated bacterial adhesion.A structure-based sliding-rebinding mechanism for catch bonds.Selectin catch-slip kinetics encode shear threshold adhesive behavior of rolling leukocytes Plasticity of hydrogen bond networks regulates mechanochemistry of cell adhesion complexes.Single molecule and multiple bond characterization of catch bond associated cytoadhesion in malaria.Regulation of catch binding by allosteric transitions.Ideal, catch, and slip bonds in cadherin adhesion Dissociation of biological catch-bond by periodic perturbation.Multivalent binding of nanocarrier to endothelial cells under shear flow Resolving the molecular mechanism of cadherin catch bond formation.Asymmetric effect of mechanical stress on the forward and reverse reaction catalyzed by an enzyme.The two-pathway model of the biological catch-bond as a limit of the allosteric model Surface Plasmon Resonance (SPR) for the Evaluation of Shear-Force-Dependent Bacterial Adhesion.Effect of loading conditions on the dissociation behaviour of catch bond clusters.Reconstructing folding energy landscapes by single-molecule force spectroscopy.Temperature effect on the chemomechanical regulation of substeps within the power stroke of a single Myosin II.Determinants of maximal force transmission in a motor-clutch model of cell traction in a compliant microenvironment Catch-bond mechanism of force-enhanced adhesion: counterintuitive, elusive, but ... widespread?Molecular mechanisms of cellular mechanosensing.A model for cyclic mechanical reinforcement.Mechanochemitry: a molecular biomechanics view of mechanosensing.Adhesive organelles of Gram-negative pathogens assembled with the classical chaperone/usher machinery: structure and function from a clinical standpoint.Dynamic factors controlling carrier anchoring on vascular cells Biomechanics of cell adhesion: how force regulates the lifetime of adhesive bonds at the single molecule level.Catch Bonds at T Cell Interfaces: Impact of Surface Reorganization and Membrane Fluctuations.Mechanics of Vascular Smooth Muscle.Molecular mechanisms of mechanotransduction in integrin-mediated cell-matrix adhesion.Catch bond interaction between cell-surface sulfatase Sulf1 and glycosaminoglycans.Phenomenological and microscopic theories for catch bonds.Analytical catch-slip bond model for arbitrary forces and loading rates.

P2860

Q24550964-9DD21CAD-6077-4AC9-AC9D-D6D07BAB1714 Q27300610-3D719D06-9EB3-4739-A74B-FB148487B4DA Q27331629-B7650C30-EEA2-43AE-8E40-435723ABE591 Q28071399-7F9210EB-AE84-4E2E-ACDA-D6F6BBD7B0C9 Q30406110-1DD7E4E2-23E1-4595-A026-B77AE7C84114 Q30414863-C5A85E36-3BAF-4C6C-BFA5-517B4C72CAC3 Q30426070-C5FD5763-7FD2-4962-9552-9A7A848BDD4C Q30432073-43D02D97-0885-4772-A33B-C85C8FC6986E Q30437627-7D8817E9-DC17-4282-A167-6004CBA55268 Q30440291-F6590101-DF3C-4B86-AD8C-5AAC34AF0F27 Q30445371-B6D80422-3516-4289-BE0A-CA7828658D90 Q30478974-21CC41E5-2D13-4E23-BD79-B67B471CD348 Q30485786-68B57712-7F0B-4B65-AFC9-EB2E4EC66A9E Q30582334-030467C3-7638-4B6E-9696-E60DC06D77BF Q33829952-ADF09F00-5CC5-42A1-825E-90436C80B5E0 Q34125138-7F4CA097-EA5D-4B75-8A97-AC5DF17CBD55 Q34461981-161E631F-3798-4CB2-B458-FA4BB00A3A7B Q34698716-DF2CF772-2AA1-45AF-9FE8-F2B3ED1AC341 Q35106692-EEB7C5E6-7D78-4771-A6E3-DA283D381CBA Q35179920-FF0891CF-BE3B-4202-9417-A3F77C6DAF1B Q35202296-0C696E94-9574-4B9B-BE60-EDD1795F0A2D Q35342323-A4A1D53B-2380-43C5-93FD-59F90FE0F418 Q35824573-3B8D0AED-8B98-495A-B38C-98B84EF9656E Q35836990-779E3936-0625-4B5E-92D0-69FD4D411C97 Q36173545-C6FA980B-9212-4E3B-95A8-602DA9FBF5C2 Q36501051-F4667B52-A1C2-4943-B7D3-B7A5D54C0168 Q37078518-2BA0DFD0-983A-49C6-A8EB-ECA634E00000 Q37293577-7908E9BA-44FE-4239-8CF6-95DEE764FF4E Q37338476-F1422B82-7898-41F1-B172-E01EA587E039 Q37369037-6CC28C2B-6542-4E24-A3ED-19F4613F3909 Q37620157-8A294870-9CB6-43E5-8224-F6906323A105 Q37673260-89255DAB-1685-420A-A06F-82BF2118CC5C Q37896551-42B170A1-9E36-457E-AF35-C896F430189C Q38178101-7E15804E-37A9-4B37-8345-B81D54DA5020 Q38682295-C6C36860-C86D-4FDF-91E4-913461F5693D Q38693274-6A284354-D5B8-4707-B8B9-EC994DFFCB43 Q38976602-3176C13C-5BE1-4501-824E-C2D847CFCBF8 Q39427216-CFC44F96-642F-4B41-8F96-0419D80936D0 Q39862600-C811ECC3-0752-45CE-B9EA-315B90DFC7FF Q40002026-CE24686F-D790-4482-BC96-A9B583186034

P2860

The two-pathway model for the catch-slip transition in biological adhesion.

http://www.wikidata.org/entity/Q34350947

description

2005 nî lūn-bûn

@nan

2005 թուականի Յունիսին հրատարակուած գիտական յօդուած

@hyw

2005 թվականի հունիսին հրատարակված գիտական հոդված

@hy

2005年の論文

@ja

2005年論文

@yue

2005年論文

@zh-hant

2005年論文

@zh-hk

2005年論文

@zh-mo

2005年論文

@zh-tw

2005年论文

@wuu

name

The two-pathway model for the catch-slip transition in biological adhesion.

@ast

The two-pathway model for the catch-slip transition in biological adhesion.

@en

The two-pathway model for the catch-slip transition in biological adhesion.

@nl

type

label

The two-pathway model for the catch-slip transition in biological adhesion.

@ast

The two-pathway model for the catch-slip transition in biological adhesion.

@en

The two-pathway model for the catch-slip transition in biological adhesion.

@nl

prefLabel

The two-pathway model for the catch-slip transition in biological adhesion.

@ast

The two-pathway model for the catch-slip transition in biological adhesion.

@en

The two-pathway model for the catch-slip transition in biological adhesion.

@nl

P1433

Q34350947-B819DAD8-B9E6-42AA-B24F-80365AF5343F

P1476

Q34350947-02E5AC19-CFBD-49C4-B7E3-082514C9C949

P2093

Q34350947-3518096E-9210-4436-9DB6-BAAACE84F1A1

Q34350947-49F6381C-48BD-43D3-8F7E-72A24508B3C1

Q34350947-4AA6932C-965E-4C64-A264-FE378BA4EDCA

Q34350947-87585FE9-3BDC-4B9B-9DBB-885BB190204A

Q34350947-C0D71EB3-20C1-4A28-8D94-AD9E4D927C31

P2860

Q34350947-192CB3B5-AD84-42EB-8F85-C090BE5A3C34

Q34350947-1EB6FB24-97B8-45B6-A753-AF147EA13CF4

Q34350947-2A0CD743-ED89-4B85-8F52-3630474F0D27

Q34350947-2E9D4EA1-954F-4714-A9D5-5A157D22D993

Q34350947-315EE825-1D9F-4A86-91DA-FCFD268E53CC

Q34350947-39EE679A-B2AD-4F1C-8A2F-936186B82F25

Q34350947-43E83BE9-8F85-431C-BA48-8A900442D3EF

Q34350947-531EA026-7198-47FE-A267-355DD7333396

Q34350947-5813A549-313B-4ABF-BF79-6BD0A4AAE87A

Q34350947-5BF7D430-7B8C-4F74-AD4B-9AC261349CC7

P304

Q34350947-5D7360DA-2234-4672-BB8F-656EAAFCAA83

P31

Q34350947-562301AA-B1EE-4D9E-818B-664CB1CF4EC3

P356

Q34350947-BDDF1334-E9BF-42D8-A1E8-81CD085D5C03

P407

Q34350947-25097355-50A5-41C1-AC59-5B14FB584DB1

P433

Q34350947-CE08AE48-E895-4D4F-855C-50613D962901

P478

Q34350947-196095A3-B145-44D0-83E1-65438CF76AAD

P577

Q34350947-04A9C4DD-7304-4E01-95C5-A84D3F95D004

P5875

Q34350947-CD533613-5442-4B51-9DDD-0CC5ECF58428

P698

Q34350947-32B86B0E-7BB3-4DA2-8CEC-FA4E1984D908

P932

Q34350947-BF776B4D-1055-4964-AFC3-8565D7E199E7

P356

BIOPHYSJ.105.062158

P1433

Biophysical Journal

P1476

The two-pathway model for the catch-slip transition in biological adhesion.

@en

P2093

Evgeni V Sokurenko

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

Manu Forero

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

Oleg V Prezhdo

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

Wendy E Thomas

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

Yuriy V Pereverzev

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

P2860

Mechanical switching and coupling between two dissociation pathways in a P-selectin adhesion bond

Bacterial adhesion to target cells enhanced by shear force

Models for the specific adhesion of cells to cells

Energy landscape of streptavidin-biotin complexes measured by atomic force microscopy.

Dynamics of unbinding of cell adhesion molecules: transition from catch to slip bonds.

Molecular dynamics study of unbinding of the avidin-biotin complex.

Effects of intermediate bound states in dynamic force spectroscopy.

Direct observation of catch bonds involving cell-adhesion molecules.

Probing the relation between force--lifetime--and chemistry in single molecular bonds.

Low force decelerates L-selectin dissociation from P-selectin glycoprotein ligand-1 and endoglycan.

P304

1446-1454

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

P31

scholarly article

P356

10.1529/BIOPHYSJ.105.062158

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

P407

P433

3

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

P478

89

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

P577

2005-06-10T00:00:00Z

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

P5875

7792086

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

P698

15951391

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

P932

1366651

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