Characterization of radial force and radial stiffness in Ca(2+)-activated skinned fibres of the rabbit psoas muscle.

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Characterization of radial force and radial stiffness in Ca(2+)-activated skinned fibres of the rabbit psoas muscle.

B Brenner and L C Yu

University of Tübingen, Germany.

1. When chemically skinned muscle fibres are activated by Ca2+at an ionic strength of 170 mM, the spacing between the filamentshas been shown to decrease with increasing force, suggestingthat the cross-bridges can generate force not only in the axialbut also in the radial direction. In the present study, radialforce and radial stiffness of activated single skinned rabbitpsoas fibres were studied by X-ray diffraction. The responsesof the lattice spacing to changes in osmotic pressure by applicationof dextran T500, which is equivalent to force applied in theradial direction, was examined. The radial force generated bythe attached cross-bridges was calculated, with the approximationthat a negligible fraction of cross-bridges was attached inthe relaxed muscle at the same ionic strength of 170 mM. 2.The active radial force was found to be a slightly non-linearfunction of lattice spacing, reaching zero at 34 nm. The radialforce was compressive at lattice spacing greater than 34 nmand expansive at less than 34 nm. 3. The active axial force,on the other hand, was found to be much less affected by theapplication of dextran T500. Active axial force increased by4% to a plateau at 4% dextran T500 and then decreased by 10%at 8% dextran T500. 4. While not under osmotic pressure, theradial force of the activated fibre was determined to be 400pN (single thick filament)-1. This is of the same order of magnitudeas the axial force. The radial stiffness was also comparableto the axial stiffness at 7 pN (thick filament)-1 (0.1 nm)-1.5. The radial elasticity of the fully activated fibre differssignificantly from that of the fibre in rigor. The radial stiffnessexhibited by fibres in rigor was approximately five times higher,at 30 pN (thick filament)-1 (0.1 nm)-1 and the point where theradial force reached zero was 38 nm. 6. In the activated state,the point at which radial force reaches zero is independentof the level of Ca2+ activation, i.e. independent of the numberof cross-bridges attached to actin in the force-generating state.We suggest that the zero-force point is equivalent to the equilibriumpoint of a spring and is an intrinsic property of the radialelasticity of the cross-bridge. 7. It is concluded that activatedand rigor cross-bridges exhibit a spring-like property in theradial direction.(ABSTRACT TRUNCATED AT 400 WORDS)

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