Robert K. Wright scite author profile

Differences in the mechanical properties of mammalian smooth, skeletal, and cardiac muscle have led to the proposal that the myosin isozymes expressed by these tissues may differ in their molecular mechanics. To test this hypothesis, mixtures of fast skeletal, V1 cardiac, V3 cardiac and smooth muscle (phosphorylated and unphosphorylated) myosin were studied in an in vitro motility assay in which fluorescently-labelled actin filaments are observed moving over a myosin coated surface. Pure populations of each myosin produced actin filament velocities proportional to their actin-activated ATPase rates. Mixtures of two myosin species produced actin filament velocities between those of the faster and slower myosin alone. However, the shapes of the myosin mixture curves depended upon the types of myosins present. Analysis of myosin mixtures data suggest that: (1) the two myosins in the mixture interact mechanically and (2) the same force-velocity relationship describes a myosin's ability to operate over both positive and negative forces. These data also allow us to rank order the myosins by their average force per cross-bridge and ability to resist motion (phosphorylated smooth > skeletal = V3 cardiac > V1 cardiac). The results of our study may reflect the mechanical consequence of multiple myosin isozyme expression in a single muscle cell.

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Local spline approximation of discontinuous functions and location of discontinuities, given low-order Fourier coefficient information

Wright

2004

Journal of Computational and Applied Mathematics

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A robust method for accurately representing nonperiodic functions given Fourier coefficient information

Wright

2002

Journal of Computational and Applied Mathematics

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Asymptotic behavior of solutions and adjunction fields for nonlinear first order differential equations

Strodt¹,

Wright²

1971

Memoirs of the AMS

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Role of cAMP in modulating relaxation kinetics and the force-frequency relation in mitral regurgitation heart failure

et al. 1997

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The report is a discussion of previously published and newly analyzed results concerning the association between heart diseases and alterations in the force-frequency relation (FFR). The optimum stimulation frequency of the FFR is measured and compared in isolated left ventricular myocardium from non-failing hearts with atrial septal defect, coronary artery disease (without and with insulin dependent diabetes mellitus) and from failing hearts with mitral regurgitation, or idiopathic dilated cardiomyopathy. Specifically, we examine the role of altered control of the excitation-contraction coupling system in blunting the force-frequency relation. We use the percent slope of the FFR as a measure of changes in the frequency sensitivity of this control. Our finding of a linear, direct relation between optimum stimulation frequency and % slope across all disease types suggests both parameters are coupled to the same underlying mechanism. To investigate the possible role of altered control of the calcium pump in this mechanism, we analyzed the detailed relation between isometric twitch relaxation kinetics and stimulation frequency in mitral regurgitation myocardium (MR). In the presence of 0.5 microM forskolin the depressed slope and optimum frequency of the FFR and the prolonged half-time of twitch relaxation were all restored to values found in non-failing myocardium. We use the kinetics of isometric twitch relaxation as an index of changes in pumping rate that occur in response to changes in stimulation frequency or in intracellular cyclic adenosine monophosphate concentration. A mathematical model based on the Hill relations for calcium pump uptake rate and for isometric tension as a function of intracellular pCa is developed to simulate isometric twitch relaxation in MR and non-failing myocardium. The success of this model in simulating non-failing and failing twitch relaxation supports a proposed mechanism for the prolonged relaxation time and depressed FFR in MR involving depressed protein kinase-A activity (due to lowered cAMP or to a defect in the Ser16 site of phospholamban) as a mechanism of altered control of the calcium pump in MR heart disease.

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Robert K. Wright

Smooth, cardiac and skeletal muscle myosin force and motion generation assessed by cross-bridge mechanical interactions in vitro

Local spline approximation of discontinuous functions and location of discontinuities, given low-order Fourier coefficient information

A robust method for accurately representing nonperiodic functions given Fourier coefficient information

Asymptotic behavior of solutions and adjunction fields for nonlinear first order differential equations

Role of cAMP in modulating relaxation kinetics and the force-frequency relation in mitral regurgitation heart failure

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