Two-dimensional confocal images of organization, density, and gating of focal Ca 2+ release sites in rat cardiac myocytes

Abstract

In cardiac myocytes Ca²⁺ cross-signaling between Ca²⁺ channels and ryanodine receptors takes place by exchange of Ca²⁺ signals in microdomains surrounding dyadic junctions, allowing first the activation and then the inactivation of the two Ca²⁺-transporting proteins. To explore the details of Ca²⁺ signaling between the two sets of receptors we measured the two-dimensional cellular distribution of Ca²⁺ at 240 Hz by using a novel confocal imaging technique. Ca²⁺ channel-triggered Ca²⁺ transients could be resolved into dynamic “Ca²⁺ stripes” composed of hundreds of discrete focal Ca²⁺ releases, appearing as bright fluorescence spots (radius ≅ 0.5 μm) at reproducible sites, which often coincided with t-tubules as visualized with fluorescent staining of the cell membrane. Focal Ca²⁺ releases triggered stochastically by Ca²⁺ current (I_Ca) changed little in duration (≅7 ms) and size (≅100,000 Ca ions) between −40 and +60 mV, but their frequency of activation and first latency mirrored the kinetics and voltage dependence of I_Ca. The resolution of 0.95 ± 0.13 reproducible focal Ca²⁺ release sites per μm³ in highly Ca²⁺-buffered cells, where diffusion of Ca²⁺ is limited to 50 nm, suggests the presence of about one independent, functional Ca²⁺ release site per half sarcomere. The density and distribution of Ca²⁺ release sites suggest they correspond to dyadic junctions. The abrupt onset and termination of focal Ca²⁺ releases indicate that the cluster of ryanodine receptors in individual dyadic junctions may operate in a coordinated fashion.