Regulation of Catch Bonds by Rate of Force Application

Sarangapani, Krishna K.; Qian, Jin; Chen, Wei; Zarnitsyna, Veronika I.; Mehta, Padmaja; Yago, Tadayuki; McEver, Rodger P.; Zhu, Cheng

doi:10.1074/jbc.m111.240044

Cited by 47 publications

(48 citation statements)

References 50 publications

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“…Because the WT cadherins were loaded at a constant ramp rate to a constant hold force, we also tested the ramp-rate dependence of ideal bond formation; a recent study has shown that a mechanical bond that behaves as a catch-slip bond at low ramp rates may transform to slip-only bonds at high ramp rates (35). When we increased the ramp rate by an order of magnitude, the WT cadherins with 0.3 s interaction time continued to behave as ideal bonds, indicating the rate of force application did not affect ideal bond behavior (SI Appendix, Fig.…”

Section: Ideal Bonds Are Measured When Wt Cadherins Interact For a Shortmentioning

confidence: 99%

Ideal, catch, and slip bonds in cadherin adhesion

Rakshit

Zhang

Manibog

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

252

274

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Classical cadherin cell-cell adhesion proteins play key morphogenetic roles during development and are essential for maintaining tissue integrity in multicellular organisms. Classical cadherins bind in two distinct conformations, X-dimer and strand-swap dimer; during cellular rearrangements, these adhesive states are exposed to mechanical stress. However, the molecular mechanisms by which cadherins resist tensile force and the pathway by which they convert between different conformations are unclear. Here, we use single molecule force measurements with an atomic force microscope (AFM) to show that E-cadherin, a prototypical classical cadherin, forms three types of adhesive bonds: catch bonds, which become longer lived in the presence of tensile force; slip bonds, which become shorter lived when pulled; and ideal bonds that are insensitive to mechanical stress. We show that X-dimers form catch bonds, whereas strand-swap dimers form slip bonds. Our data suggests that ideal bonds are formed as X-dimers convert to strand-swap binding. Catch, slip, and ideal bonds allow cadherins to withstand tensile force and tune the mechanical properties of adhesive junctions.single molecule biomechanics | force clamp | trans dimers | protein conformation | structure-function relationship

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Section: Ideal Bonds Are Measured When Wt Cadherins Interact For a Shortmentioning

confidence: 99%

Ideal, catch, and slip bonds in cadherin adhesion

Rakshit

Zhang

Manibog

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

252

274

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“…It is also a challenge to develop a hierarchical organization of DE-based sensors and actuators that can respond to external stimuli in a programmable and intelligent way. Modeling such hierarchical compartmentalization generally requires theories of large deformation strongly coupled to other fields such as electronics, as well as microscopic processes such as bonding kinetics (Sarangapani et al, 2011;Ju et al, 2015) and mass transport (Jiang et al, 2015) that ubiquitously occur within materials and at interfaces. The analytical and numerical approach based on continuum mechanics and thermodynamics will continue to play an enormous role in understanding these materials, and in modeling these structures and designing these devices (Chen, 2014), and the bottom-up investigation of the microscopic processes in response to external stimuli has just begun.…”

Section: Concluding Remarks and Outlookmentioning

confidence: 99%

Mechanics of dielectric elastomers: materials, structures, and devices

Qian

2016

JZUS-A

Self Cite

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Dielectric elastomers (DEs) respond to applied electric voltage with a surprisingly large deformation, showing a promising capability to generate actuation in mimicking natural muscles. A theoretical foundation of the mechanics of DEs is of crucial importance in designing DE-based structures and devices. In this review, we survey some recent theoretical and numerical efforts in exploring several aspects of electroactive materials, with emphases on the governing equations of electromechanical coupling, constitutive laws, viscoelastic behaviors, electromechanical instability as well as actuation applications. An overview of analytical models is provided based on the representative approach of non-equilibrium thermodynamics, with computational analyses being required in more generalized situations such as irregular shape, complex configuration, and time-dependent deformation. Theoretical efforts have been devoted to enhancing the working limits of DE actuators by avoiding electromechanical instability as well as electric breakdown, and pre-strains are shown to effectively avoid the two failure modes. These studies lay a solid foundation to facilitate the use of DE materials, structures, and devices in a wide range of applications such as biomedical devices, adaptive systems, robotics, energy harvesting, etc.

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“…This counterintuitive behavior-a bond is strengthened by applying a force to it-is no longer a theoretical curiosity but has, in recent years, been experimentally demonstrated in a range of noncovalent biophysical bonds where it has become widely known as a catch bond [4,6]. For protein-protein bonds, such behavior is generally ascribed to specific conformational properties of the molecules involved [7][8][9][10][11]; we will show that catch bond behavior is generic for protein complexes in which multiple pathways for dissociation exists. In this paper, we will define a catch bond to mean a bound state whose average lifetime τ (f ) possesses an initial regime of increase with force:…”

Section: Introductionmentioning

confidence: 99%

Catch bonding in the forced dissociation of a polymer endpoint

Vrusch

Storm

2018

Phys. Rev. E

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Applying a force to certain supramolecular bonds may initially stabilize them, manifested by a lower dissociation rate. We show that this behavior, known as catch bonding and by now broadly reported in numerous biophysics bonds, is generically expected when either or both the trapping potential and the force applied to the bond possess some degree of nonlinearity. We enumerate possible scenarios, and for each identify the possibility and, if applicable, the criterion for catch bonding to occur. The effect is robustly predicted by Kramers theory, Mean First Passage Time theory, and finally confirmed in direct MD simulation. Among the catch scenarios, one plays out essentially any time the force on the bond originates in a polymeric object, implying that some degree of catch bond behavior is to be expected in any protein-protein bond, as well as in more general settings relevant to polymer network mechanics or optical tweezer experiments.

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Regulation of Catch Bonds by Rate of Force Application

Cited by 47 publications

References 50 publications

Ideal, catch, and slip bonds in cadherin adhesion

Ideal, catch, and slip bonds in cadherin adhesion

Mechanics of dielectric elastomers: materials, structures, and devices

Catch bonding in the forced dissociation of a polymer endpoint

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