Magnesium ions acted as a negative modulator of coupling strength among ryanodine receptors in an in silico model, damping the positive feedback of the calcium-induced calcium-release mechanism.
In silico modeling demonstrates that magnesium ions act as negative modulators of coupling strength among ryanodine receptors, damping the positive feedback of calcium-induced calcium release.
Ryanodine receptor channels at calcium release sites of cardiac myocytes operate on the principle of calcium-induced calcium release. In vitro experiments revealed competition of Ca 2+ and Mg 2+ in the activation of ryanodine receptors (RyRs) as well as inhibition of RyRs by Mg 2+ . The impact of RyR modulation by Mg 2+ on calcium release is not well understood due to the technical limitations of in situ experiments. We turned instead to an in silico model of a calcium release site (CRS), based on a homotetrameric model of RyR gating with kinetic parameters determined from in vitro measurements. We inspected changes in the activity of the CRS model in response to a random opening of one of 20 realistically distributed RyRs, arising from Ca 2+ /Mg 2+ interactions at RyR channels. Calcium release events (CREs) were simulated at a range of Mg 2+ -binding parameters at near-physiological Mg 2+ and ATP concentrations. Facilitation of Mg 2+ binding to the RyR activation site inhibited the formation of sparks and slowed down their activation. Impeding Mg-binding to the RyR activation site enhanced spark formation and speeded up their activation. Varying Mg 2+ binding to the RyR inhibition site also dramatically affected calcium release events. Facilitation of Mg 2+ binding to the RyR inhibition site reduced the amplitude, relative occurrence, and the time-to-end of sparks, and vice versa. The characteristics of CREs correlated dose-dependently with the effective coupling strength between RyRs, defined as a function of RyR vicinity, single-channel calcium current, and Mg-binding parameters of the RyR channels. These findings postulate the role of Mg 2+ in calcium release as a negative modulator of the coupling strength among RyRs in a CRS, translating to damping of the positive feedback of the calcium-induced calcium-release mechanism.
Iaparov et al. (Tue,) conducted a other in Cardiac calcium release. Magnesium ions was evaluated on Calcium release events. Magnesium ions acted as a negative modulator of coupling strength among ryanodine receptors in an in silico model, damping the positive feedback of the calcium-induced calcium-release mechanism.