Cracking phase diagram for the dynamics of an enzyme

2013

Phys. Rev. X

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We present nanorheology measurements on the folded state of an enzyme that show directly that the (ensemble-averaged) stress-strain relations are nonlinear and frequency dependent beyond 1-Å deformation. We argue that this frequency dependence allows for opening a nonequilibrium cycle in the forcedeformation plane if the forward and backward conformational changes of the enzyme during catalysis happen at different speeds. Using a heuristic model for the experimentally established viscoelastic properties of the enzyme, we examine a number of general features of enzymatic action. We find that the proposed viscoelastic cycle is consistent with the linear decrease of the speed of motor proteins with load. We find a relation between the stall force and the maximum rate for enzymes (in general) and motors (in particular). We estimate the stall force of the motor protein kinesin from thermodynamic quantities and estimate the maximum rate of enzymes from purely mechanical quantities. We propose that the viscoelastic cycle provides a framework for considering mechanochemical coupling in enzymes on the basis of possibly universal materials properties of the folded state of proteins.

Section: Hypothesismentioning

confidence: 66%

How Enzymes Work: A Look through the Perspective of Molecular Viscoelastic Properties

2013

Phys. Rev. X

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“…Previous measurements with this setup were performed in this evanescent wave scattering (EWS) regime. [4][5][6][7] In Fig. 3, we show the low frequency viscoelastic response of the enzyme GK measured using SPR (squares) and EWS (i.e., off resonance: circles).…”

mentioning

confidence: 99%

“…4,6,7 Briefly, the molecule under study (here, the enzyme Guanylate Kinase: GK) tethers 20 nm gold nanoparticles (GNPs) to a 30 nm thick gold layer deposited on a glass slide (Fig. 1).…”

mentioning

confidence: 99%

Plasmon resonance enhanced mechanical detection of ligand binding

Ariyaratne

Applied Physics Letters

2015

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Small molecule binding to the active site of enzymes typically modifies the mechanical stiffness of the enzyme. We exploit this effect, in a setup which combines nano-mechanics and surface plasmon resonance (SPR) enhanced optics, for the label free detection of ligand binding to an enzyme. The large dynamic range of the signal allows to easily obtain binding curves for small ligands, in contrast to traditional SPR methods which rely on small changes in index of refraction. Enzyme mechanics, assessed by nano-rheology, thus emerges as an alternative to electronic and spin resonances, assessed by traditional spectroscopies, for detecting ligand binding.

“…In the following we will often use, in discussing the data, the simplest model of visco-elasticity, which is the Maxwell model. While it is a linear model, it describes the frequency dependence of the deformation amplitude measured in the experiments remarkably well [11]. We therefore summarize it here.…”

Section: Resultsmentioning

confidence: 90%

“…High and low refers to a characteristic corner frequency ω c ∼ 100 rad/s well defined in the experiments. The system is nonlinear in that, for example, the characteristic frequency ω c depends on the amplitude F 0 of the applied force [11]. Indeed, at fixed forcing frequency ω and for increasing F 0 , the system undergoes an abrupt dynamic softening transition at a critical deformation amplitude x c ∼ 1Å (rms) [12].…”

Section: Introductionmentioning

confidence: 99%

Dissipation at the angstrom scale: Probing the surface and interior of an enzyme

Alavi

2018

Phys. Rev. E

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Pursuing a materials science approach to understanding the deformability of enzymes, we introduce measurements of the phase of the mechanical response function within the nanorheology paradigm. Driven conformational motion of the enzyme is dissipative as characterized by the phase measurements. The dissipation originates both from the surface hydration layer and the interior of the molecule, probed by examining the effect of point mutations on the mechanics. We also document changes in the mechanics of the enzyme examined, guanylate kinase, upon binding its four substrates. GMP binding stiffens the molecule, ATP and ADP binding softens it, while there is no clear mechanical signature of GDP binding. A hyperactive two-Gly mutant is found to possibly trade specificity for speed. Global deformations of enzymes are shown to be dependent on both hydration layer and polypeptide chain dynamics.