Abstract
We investigated effects of the ryanodine receptor (RyR) modulator caffeine on Na+ current (INa) activation and inactivation in intact loose-patch clamped murine skeletal muscle fibres subject to a double pulse procedure. INa activation was examined using 10-ms depolarising, V1, steps to varying voltages 0–80 mV positive to resting membrane potential. The dependence of the subsequent, INa inactivation on V1 was examined by superimposed, V2, steps to a fixed depolarising voltage. Current-voltage activation and inactivation curves indicated that adding 0.5 and 2 mM caffeine prior to establishing the patch seal respectively produced decreased (within 1 min) and increased (after ~2 min) peak INa followed by its recovery to pretreatment levels (after ~40 and ~30 min respectively). These changes accompanied negative shifts in the voltage dependence of INa inactivation (within 10 min) and subsequent superimposed positive activation and inactivation shifts, following 0.5 mM caffeine challenge. In contrast, 2 mM caffeine elicited delayed negative shifts in both activation and inactivation. These effects were abrogated if caffeine was added after establishing the patch seal or with RyR block by 10 μM dantrolene. These effects precisely paralleled previous reports of persistently (~10 min) increased cytosolic [Ca2+] with 0.5 mM, and an early peak rapidly succeeded by persistently reduced [Ca2+] likely reflecting gradual RyR inactivation with ≥1.0 mM caffeine. The latter findings suggested inhibitory effects of even resting cytosolic [Ca2+] on INa. They suggest potentially physiologically significant negative feedback regulation of RyR activity on Nav1.4 properties through increased or decreased local cytosolic [Ca2+], Ca2+-calmodulin and FKBP12.
Highlights
Skeletal muscle excitation-contraction coupling involves triggering of a Nav1.4 mediated action potential
Increases in free intracellular concentrations of FK506 binding protein, [FKBP12]i resulting from reductions in its affinity for ryanodine receptor (RyR) subunits associated with RyR opening[9,10], positively shifted activation and inactivation voltage dependences in cardiomyocyte Nav1.511, thought closely homologous to Nav1.44
These agents affected [Ca2+]i indirectly through modifying mitochondrial Ca2+ release or altering RyR activity through CAMKII-dependent pathways via Exchange protein directly activated by cAMP (Epac)
Summary
Skeletal muscle excitation-contraction coupling involves triggering of a Nav1.4 mediated action potential This is detected by voltage-dependent transverse tubular Cav1.1 that undergoes transitions resulting in an allosterically-activated ryanodine receptor (RyR) mediated release of sarcoplasmic reticular (SR) Ca2+ thereby increasing cytosolic free Ca2+ concentration, [Ca2+]i, Recent findings have been suggestive of feedback mechanisms through which downstream events in this feedforward sequence might affect Nav1.4 function. Many of these reports provided structural rather than functional evidence, or involved experiments in cell lines or isolated cultured cells. These agents affected [Ca2+]i indirectly through modifying mitochondrial Ca2+ release or altering RyR activity through CAMKII-dependent pathways via Exchange protein directly activated by cAMP (Epac)
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