Cardiovascular Research

Cardiovascular Research 2004 64(1):3-5; doi:10.1016/j.cardiores.2004.07.018
© 2004 by European Society of Cardiology

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Copyright © 2004, European Society of Cardiology

Mutant cardiac ryanodine receptors and ventricular arrhythmias: is ‘gain-of-function’ obligatory?

Ana Maria Gomez and Sylvain Richard^*

Physiopathologie Cardiovasculaire, INSERM U637, Université Montpellier 1, CHU Arnaud de Villeneuve, 371 Ave. du doyen Gaston Giraud 34295 Montpellier Cedex 5, France

^* Corresponding author. Tel.: +33 467 41 52 41; fax: +33 467 41 52 42. E-mail address: srichard{at}montp.inserm.fr

Received 22 July 2004; accepted 26 July 2004

See article by Thomas et al. [1] (pages 52–60) in this issue.

In this issue of Cardiovascular Research, Thomas et al. [1] evidence functional differences among sudden cardiac death (SCD)-linked ryanodine receptors (RyR₂) mutants. They challenge the conventional view that arrhythmogenic disorders associated with RyR₂ mutations result exclusively from ‘gain-of-function’ channelopathies generating aberrant spontaneous Ca²⁺ release [2–4]. Thomas et al. [1] now report a ‘loss-of-function’ phenotype of one RyR₂ mutant associated with SCD.

	1. RyR2 regulates cardiac contraction and rhythm

Top 1. RyR2 regulates cardiac... 2. RyR2 and ventricular... 3. Sudden cardiac death... 4. 'Gain' vs. 'loss-of-function'... References

 
The RyR₂ is primarily involved in cardiac contractile function. At each heartbeat, membrane depolarization during an action potential (AP) activates voltage-dependent L-type Ca²⁺ channels (L-VDCC), generating transmembrane Ca²⁺ influx (I_CaL). I_CaL triggers Ca²⁺ release via sarcoplasmic reticulum (SR) Ca²⁺ release channels (RyR₂). This Ca²⁺-induced Ca²⁺ release (CICR) amplification step provides the amount of Ca²⁺ required for contraction. Hence, RyR₂ are a key element in the control of cardiac output. However, RyR₂-released Ca²⁺ can, in turn, modify membrane potential by modulating Ca²⁺-sensitive sarcolemmal ion channels or transporters. Potential targets include, among others, L-VDCC, Ca²⁺-activated Cl^– channels, I_K1 channels, and the Na⁺/Ca²⁺ exchanger. The RyR₂ contributes to the setting of normal sinusal automaticity [5], but disordered RyR₂ activity generates ventricular arrhythmia [2–4,6].

Normal heart beating rate is fixed by the sinus node. Slow diastolic depolarization brings cellular membrane potential to a threshold, allowing the firing of an AP. RyR₂ activity contributes to accelerate diastolic depolarization [7,8]. Indeed, the Ca²⁺ released during diastole by the RyR₂ activates the Na⁺/Ca²⁺ exchanger in the forward mode. The resulting inward current accelerates diastolic depolarization and, thereby, promotes automaticity. The RyR₂ has been reported to be essential in determining cardiac rhythm under normal conditions [9,10] and during catecholamine stimulation [11]. Although the extent of its contribution, relative to other ionic currents, has evoked some controversy [12], RyR₂ clearly plays a significant role [5].

	2. RyR2 and ventricular arrhythmia

Top 1. RyR2 regulates cardiac... 2. RyR2 and ventricular... 3. Sudden cardiac death... 4. 'Gain' vs. 'loss-of-function'... References

 
RyR₂-released Ca²⁺ is also involved in triggered arrhythmia. Diastolic RyR₂ ‘gain-of-function’ is involved in the genesis of ventricular arrhythmia, mainly by activating an inward Na⁺/Ca²⁺ exchanger current. Systolic RyR₂ ‘gain-of-function’ might result in AP prolongation, which favors arrhythmogenicity. Modulation of both automatic activity and AP duration by RyR₂-released Ca²⁺ may also involve channels or transporters other than the Na⁺/Ca²⁺ exchanger. For example, the role of L-VDCC has been established in both cases [13,14]. The Ca²⁺ released by RyR₂ terminates Ca²⁺ entry through L-VDCC, because these channels are inactivated by Ca²⁺ [15], which shortens the AP plateau. When the amount of Ca²⁺ released by RyR₂ is reduced, as in heart failure (HF) or at high stimulation rate [16], I_CaL inactivates slowly (known as frequency-dependent facilitation of I_CaL[17]), resulting in AP prolongation in rat ventricular cells [14]. This regulation occurs on a beat-to-beat basis and potentially provides a substrate for early afterdepolarizations (EADs) in pathological conditions or in the presence of drugs lengthening AP duration [18]. Therefore, a depression of Ca²⁺ release from the SR can certainly increase the incidence of EADs, commonly associated with long AP duration [15]. Therefore, systolic RyR₂ ‘loss-of-function’ might also be arrhythmogenic.

	3. Sudden cardiac death related to RyR2 mutations

Top 1. RyR2 regulates cardiac... 2. RyR2 and ventricular... 3. Sudden cardiac death... 4. 'Gain' vs. 'loss-of-function'... References

 
In HF, at stage IV of the NYHA, 50% of deaths are sudden and related to tachycardia degenerating into ventricular fibrillation. At this stage, diastolic [Ca²⁺]_i is increased and systolic [Ca²⁺]_i is depressed, which involves disordered activity of the RyR₂. However, SCD can also occur in non-failing hearts. Although it has been proposed that alteration of RyR₂ function have only transient effects [19], several mutations in the RyR₂ with major functional consequences have been identified in at least two different kinds of ventricular arrhythmia causing juvenile SCD: (i) Catecholamine-induced polymorphic ventricular tachycardia (CPVT), induced by stress and exercise, and (ii) arrhythmogenic right ventricular dysplasia/cardiomyopathy type 2 (ARVD2), characterized by structural alteration of the myocardium [20–23]. At least 21 single amino acid mutations (15 CPVT and 6 for ARVD2) have been related to arrhythmia. These mutations are localized in 3 highly conserved regions of the RyR₂: the FKBP12.6-binding region and the cytosolic N- and C-terminals.

Mutations in the FKBP12.6-RyR₂ binding region are expected to disturb the binding of FKBP12.6 to RyR₂. Because FKBP12.6 deficiency promotes ‘leaky RyR₂’ [24,25], it has been proposed that ‘leaky RyR₂’ underlies arrhythmia and SCD [2], which seems to be confirmed by the finding that FKBP12.6-deficient mice exhibit exercise-induced ventricular arrhythmias—mostly DADs—similar to those observed in CPVT [2]. However, George et al. [4] have shown that RyR₂ mutants related to CPVT maintain normal binding to FKBP12.6. Furthermore, basal activity of mutant RyR₂ was similar to wild-type RyR₂, although Ca²⁺ release induced by caffeine or isoproterenol was increased [4]. These analyses suggested that not only diastolic ‘gain-of-function’ but also systolic ‘gain-of-function’ under stress is related to CPVT.

	4. ‘Gain’ vs. ‘loss-of-function’ of RyR2 mutants

Top 1. RyR2 regulates cardiac... 2. RyR2 and ventricular... 3. Sudden cardiac death... 4. 'Gain' vs. 'loss-of-function'... References

 
In CPVT [22,23] and ARVD2 [21], RyR₂ mutations have been found at sites similar to that of skeletal RyR₁ mutants involved in malignant hyperthermia and central core disease. Hence, it has been hypothesized that, as in these skeletal muscle diseases, RyR₂ mutations would involve RyR₂ ‘gain-of-function’ [6]. This hypothesis was supported by the findings of Jiang et al. [3], who analyzed the function of one CPVT mutation. These authors found that the corresponding RyR₂ mutant has higher activity at low [Ca²⁺]_i and enhanced sensitivity to caffeine. These properties are expected to promote SR Ca²⁺ leak during diastole and DADs, triggering arrhythmogenic disorders. The findings by Thomas et al. [1] further support this conclusion for 3 ARDV2 mutants, suggesting that ‘gain-of-function’ phenotype can be found both in CPVT and ARDV2. Thomas et al. analyzed the function of 4 RyR₂ mutants linked to SCD (ARVD2). They expressed the wild-type and mutant RyR₂ in human embryonic kidney cells lacking endogenous RyR₂ and accessory proteins. Since these cells do not exhibit EC coupling, they used caffeine to assess Ca²⁺ sensitivity of the various RyR₂ mutants. Caffeine greatly enhances Ca²⁺ sensitivity of the RyR₂ that are activated at resting [Ca²⁺]_i, allowing measurable Ca²⁺ release. After verification of RyR₂ expression levels, the amplitude and kinetics of caffeine-induced Ca²⁺ release were compared among mutants and wild-type RyR₂ to get an insight into their function. The caffeine concentration–Ca²⁺ release curves revealed different behaviors. Three mutants were more sensitive to caffeine than the wild-type (lower EC₅₀), exhibiting a ‘gain-of-function’ phenotype. In contrast, one mutant, L⁴³³P, showed a higher EC₅₀, suggesting that this mutant is less sensitive to Ca²⁺ than other mutants and than the wild-type. Assuming that the intrinsic caffeine sensitivity was similar among these RyR₂ subtypes, the shift in the EC₅₀ would account for a shift in the Ca²⁺ sensitivity of mutants RyR₂. Therefore, the finding of SCD-related RyR₂ mutant with likely less Ca²⁺ sensitivity challenges the current perception that RyR₂-related arrhythmias are dependent on enhanced diastolic activity or so-called ‘gain-of-function’, and extends the current therapeutic perspectives [26]. Not only an excess of Ca²⁺ release, but also a depression of Ca²⁺ release by the SR could induce arrhythmia—as mentioned above for I_CaL. Although these data were obtained from a RyR₂ heterologous expression system in cells lacking RyR₂ accessory proteins and normal EC coupling, they argue against the concept of unicity in RyR₂-related arrhythmia. It is interesting to note that a depression of RyR₂ expression associated with atrial fibrillation has been reported [27]. Now, analysis of the biophysical properties of single RyR₂ (incorporated in lipid bilayers) and of their functional properties (E–C coupling, Ca²⁺ sparks) in native cardiac cells is highly desirable. Moreover, the ionic currents linking RyR₂ ‘loss-of-function’ to electrical disorders need to be identified. Transgenic animals will probably provide a unique means to address these important issues.

In conclusion, the observations by Thomas et al. [1] open new perspectives, suggesting that mechanistic analysis is mandatory for each SCD-linked RyR₂ mutant. The stake would be to design adequate therapeutic strategies on ‘a case-by-case’ basis for each identified mutation.

	References

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