RyR2R420Q catecholaminergic polymorphic ventricular tachycardia mutation induces bradycardia by disturbing the coupled clock pacemaker mechanism
Yue Yi Wang, Pietro Mesirca, Elena Marqués-Sulé, Alexandra Zahradnikova Jr., Olivier Villejoubert, Pilar D’Ocon, Cristina Ruiz, Diana Domingo, Esther Zorio, Matteo E. Mangoni, Jean-Pierre Benitah, Ana María Gómez
Yue Yi Wang, Pietro Mesirca, Elena Marqués-Sulé, Alexandra Zahradnikova Jr., Olivier Villejoubert, Pilar D’Ocon, Cristina Ruiz, Diana Domingo, Esther Zorio, Matteo E. Mangoni, Jean-Pierre Benitah, Ana María Gómez
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Research Article Cardiology

RyR2R420Q catecholaminergic polymorphic ventricular tachycardia mutation induces bradycardia by disturbing the coupled clock pacemaker mechanism

Abstract

Catecholaminergic polymorphic ventricular tachycardia (CPVT) is a lethal genetic arrhythmia that manifests syncope or sudden death in children and young adults under stress conditions. CPVT patients often present bradycardia and sino-atrial node (SAN) dysfunction. However, the mechanism remains unclear. We analyzed SAN function in two CPVT families and in a novel knock-in (KI) mouse model carrying the RyR2R420Q mutation. Humans and KI mice presented slower resting heart rate. Accordingly, the rate of spontaneous intracellular Ca2+ ([Ca2+]i) transients was slower in KI mouse SAN preparations than in WT, without any significant alteration in the “funny” current (If ). The L-type Ca2+ current was reduced in KI SAN cells in a [Ca2+]i-dependent way, suggesting that bradycardia was due to disrupted crosstalk between the “voltage” and “Ca2+” clock, and the mechanisms of pacemaking was induced by aberrant spontaneous RyR2- dependent Ca2+ release. This finding was consistent with a higher Ca2+ leak during diastolic periods produced by long-lasting Ca2+ sparks in KI SAN cells. Our results uncover a mechanism for the CPVT-causing RyR2 N-terminal mutation R420Q, and they highlight the fact that enhancing the Ca2+ clock may slow the heart rhythm by disturbing the coupling between Ca2+ and voltage clocks.

Authors

Yue Yi Wang, Pietro Mesirca, Elena Marqués-Sulé, Alexandra Zahradnikova Jr., Olivier Villejoubert, Pilar D’Ocon, Cristina Ruiz, Diana Domingo, Esther Zorio, Matteo E. Mangoni, Jean-Pierre Benitah, Ana María Gómez

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Figure 5

[Ca2+]i transient characteristics in SAN cells.

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[Ca2+]i transient characteristics in SAN cells. (A) Examples of line-sca...
(A) Examples of line-scan confocal images showing [Ca2+]i transients (shown as peak, F/F0, where F is the fluorescence peak and F0 the fluorescence during the diastolic period) from WT (left) and KI (right) SAN cells. (B) [Ca2+]i transient amplitude is unchanged in KI SAN. (C) KI SAN cells have similar decay time constant (obtained by fitting the decay portion of the fluorescence trace to a single exponential). (D) Time to peak (duration between the beginning of the fluorescence [Ca2+]i transient and its peak) is longer in KI SAN. (E) The maximum value of the derivative of the fluorescence [Ca2+]i transient over time is smaller in KI cells, reflecting a slowing of the Ca2+ release. (F) Example of a ramp (late diastolic Ca2+ release, left), and the percentage of cells that present at least one ramp (right), which is higher in KI SAN cells (χ2). Ramp identification in the fluorescence trace is indicated by the black arrow. Bar graphs display mean value ± SEM of SAN cells with individual data shown on the columns, while each SAN value is averaged from at least 4 cells recorded in the same SAN. WT, white bars, n = 13 SAN cells; KI, red bars, n = 13 SAN cells. *P < 0.05, **P < 0.01.