Xanthohumol Modulates Calcium Signaling in Rat Ventricular Myocytes: Possible Antiarrhythmic Properties
- J Pharmacol Exp Ther. 2017 Jan;360(1):239-248. doi: 10.1124/jpet.116.236588.
- 1. Cardiac Signaling Center of University of South Carolina, Medical University of South Carolina, and Clemson University, Charleston, South Carolina.
- 2. Cardiac Signaling Center of University of South Carolina, Medical University of South Carolina, and Clemson University, Charleston, South Carolina [email protected].
Cardiac arrhythmia is a major cause of mortality in cardiovascular pathologies. A host of drugs targeted to sarcolemmal Na+, CA2+, and K+ channels has had limited success clinically. Recently, CA2+ signaling has been target of pharmacotherapy based on finding that leaky ryanodine receptors elevate local CA2+ concentrations causing membrane depolarizations that trigger arrhythmias. In this study, we report that xanthohumol, an antioxidant extracted from hops showing therapeutic effects in Other pathologies, suppresses aberrant ryanodine receptor CA2+ release. The effects of xanthohumol (5-1000 nM) on CA2+ signaling pathways were probed in isolated rat ventricular myocytes incubated with Fluo-4 AM using the perforated patch-clamp technique. We found that 5-50 nM xanthohumol reduced the frequency of spontaneously occurring CA2+ sparks (>threefold) and CA2+ waves in control myocytes and in cells subjected to CA2+ overload caused by the following: 1) exposure to low K+ solutions, 2) periods of high frequency electrical stimulation, 3) exposures to isoproterenol, or 4) caffeine. At room temperatures, 50-100 nM xanthohumol reduced the rate of relaxation of electrically- or caffeine-triggered CA2+transients, without suppressing ICA, but this effect was small and reversed by isoproterenol at physiologic temperatures. Xanthohumol also suppressed the CA2+ content of the SR and its rate of recirculation. The stabilizing effects of xanthohumol on the frequency of spontaneously triggered CA2+ sparks and waves combined with its antioxidant properties, and lack of significant effects on Na+ and CA2+ channels, may provide this compound with clinically desirable antiarrhythmic properties.
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