Hysteresis and the length dependence of calcium sensitivity in chemically skinned rat cardiac muscle.

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Hysteresis and the length dependence of calcium sensitivity in chemically skinned rat cardiac muscle.

S M Harrison, C Lamont and D J Miller

Institute of Physiology, Glasgow University.

1. The relationship between pCa (-log10[Ca2+]) and steady-stateisometric tension has been investigated in saponin- or Triton-treated(chemically 'skinned') cardiac muscle of rat. 2. Hysteresisexists in the relationship such that the muscle is less sensitiveto Ca2+ during increasing activation (as [Ca2+] is stepped upward)than during reducing activation (as [Ca2+] is stepped downward).3. The extent of the hysteresis is insensitive to interventionsthat increase overall calcium sensitivity by chemical means,such as caffeine, carnosine or increased pH. 4. The extent ofthe hysteresis is sensitive to sarcomere length. The phenomenonis virtually absent above sarcomere lengths of about 2.2-2.3microns but becomes progressively greater at shorter sarcomerelengths. 5. The effect of sarcomere length on calcium sensitivityis restricted to the upward-going (increasing activation) partof the pCa-tension loop below 2.2 microns. The downward-going(decreasing activation) part of the hysteretic relationshipis virtually unaffected by sarcomere length up to 2.2 microns.6. Significant alterations in sarcomere length do not occurduring tension development in the experiments described here:the phenomenon is not attributable to experimental artifactsof this kind. 7. Hysteresis develops sufficiently rapidly tobe consistent with a physiological relevance during the normalheart beat. 8. The effects of sarcomere length show that thephenomenon is not due to force per se since, for example, greaterpeak force produces less hysteresis as sarcomere length is increasedtowards 2.2 microns. 9. Tonicity increase (by high-molecular-weightdextran), which shrinks the myofilament lattice, increases calciumsensitivity but reduces the effect of sarcomere length on calciumsensitivity. 10. The results suggest that lattice shrinkageis the mechanism which accounts for hysteresis in, and the sarcomerelength dependence of, calcium sensitivity in cardiac muscle.

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