Numerical analysis of ryanodine receptor activation by L-type channel activity in the cardiac muscle diad.

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Numerical analysis of ryanodine receptor activation by L-type channel activity in the cardiac muscle diad.

M B Cannell and C Soeller

Department of Pharmacology and Clinical Pharmacology, St. George's Hospital Medical School, London, England. mcannell@sghms.ac.uk

ABSTRACT

Computer simulations were used to examine the response of ryanodinereceptors (RyRs) to the sarcolemmal calcium influx via L-typecalcium channels (DHPRs). The effects of ryanodine receptororganization, diad geometry, DHPR single-channel current, andDHPR gating were examined. In agreement with experimental findings,the simulations showed that RyRs can respond rapidly (approximately0.4 ms) to calcium influx via DHPRs. The responsiveness of theRyR depends on the geometrical arrangement between the RyRsand the DHPR in the diad, with wider diads being generally lessresponsive. When the DHPR single-channel current is small (approximately25 fA), the organization of RyRs into small clusters resultsin an improved responsiveness. With experimentally observedDHPR mean open and closed times (0.17 ms and 4 ms, respectively)it is the first opening of the DHPR that is most likely to activatethe RyR. A measure of the efficiency (Q) by which DHPR gatingevokes sarcoplasmic reticulum release is defined. Q is at maximumfor tau approximately 0.3 ms, and we interpret this findingin terms of the "tuning" of DHPR gating to RyR response. Ifcertain cardiac myopathies are associated with a mismatch inthe "tuning," then modification of DHPR gating with drugs to"retune" calcium-induced calcium release should be possible.

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