Immediate and Delayed Response of Simulated Human Atrial Myocytes to Clinically-Relevant Hypokalemia

Although plasma electrolyte levels are quickly and precisely regulated in the mammalian cardiovascular system, even small transient changes in K+, Na+, Ca2+, and/or Mg2+ can significantly alter physiological responses in the heart, blood vessels, and intrinsic (intracardiac) autonomic nervous system. We have used mathematical models of the human atrial action potential (AP) to explore the electrophysiological mechanisms that underlie changes in resting potential (Vr) and the AP following decreases in plasma K+, [K+]o, that were selected to mimic clinical hypokalemia. Such changes may be associated with arrhythmias and are commonly encountered in patients (i) in therapy for hypertension and heart failure; (ii) undergoing renal dialysis; (iii) with any disease with acid-base imbalance; or (iv) post-operatively. Our study emphasizes clinically-relevant hypokalemic conditions, corresponding to [K+]o reductions of approximately 1.5 mM from the normal value of 4 to 4.5 mM. We show how the resulting electrophysiological responses in human atrial myocytes progress within two distinct time frames:(i) Immediately after [K+]o is reduced, the K+-sensing mechanism of the background inward rectifier current (IK1) responds. Specifically, its highly non-linear current-voltage relationship changes significantly as judged by the voltage dependence of its region of outward current. This rapidly alters, and sometimes even depolarizes, Vr and can also markedly prolong the final repolarization phase of the AP, thus modulating excitability and refractoriness.(ii) A second much slower electrophysiological response (developing 5–10 minutes after [K+]o is reduced) results from alterations in the intracellular electrolyte balance. A progressive shift in intracellular [Na+]i causes a change in the outward electrogenic current generated by the Na+/K+ pump, thereby modifying Vr and AP repolarization and changing the human atrial electrophysiological substrate.In this study, these two effects were investigated quantitatively, using seven published models of the human atrial AP. This highlighted the important role of IK1 rectification when analyzing both the mechanisms by which [K+]o regulates Vr and how the AP waveform may contribute to “trigger” mechanisms within the proarrhythmic substrate. Our simulations complement and extend previous studies aimed at understanding key factors by which decreases in [K+]o can produce effects that are known to promote atrial arrhythmias in human hearts.

Patch-Clamp Recordings of Action Potentials From Human Atrial Myocytes: Optimization Through Dynamic Clamp

Introduction: Atrial fibrillation (AF) is the most common cardiac arrhythmia. Consequently, novel therapies are being developed. Ultimately, the impact of compounds on the action potential (AP) needs to be tested in freshly isolated human atrial myocytes. However, the frequent depolarized state of these cells upon isolation seriously hampers reliable AP recordings.Purpose: We assessed whether AP recordings from single human atrial myocytes could be improved by providing these cells with a proper inward rectifier K+ current (IK1), and consequently with a regular, non-depolarized resting membrane potential (RMP), through “dynamic clamp”.Methods: Single myocytes were enzymatically isolated from left atrial appendage tissue obtained from patients with paroxysmal AF undergoing minimally invasive surgical ablation. APs were elicited at 1 Hz and measured using perforated patch-clamp methodology, injecting a synthetic IK1 to generate a regular RMP. The injected IK1 had strong or moderate rectification. For comparison, a regular RMP was forced through injection of a constant outward current. A wide variety of ion channel blockers was tested to assess their modulatory effects on AP characteristics.Results: Without any current injection, RMPs ranged from −9.6 to −86.2 mV in 58 cells. In depolarized cells (RMP positive to −60 mV), RMP could be set at −80 mV using IK1 or constant current injection and APs could be evoked upon stimulation. AP duration differed significantly between current injection methods (p < 0.05) and was shortest with constant current injection and longest with injection of IK1 with strong rectification. With moderate rectification, AP duration at 90% repolarization (APD90) was similar to myocytes with regular non-depolarized RMP, suggesting that a synthetic IK1 with moderate rectification is the most appropriate for human atrial myocytes. Importantly, APs evoked using each injection method were still sensitive to all drugs tested (lidocaine, nifedipine, E-4031, low dose 4-aminopyridine, barium, and apamin), suggesting that the major ionic currents of the atrial cells remained functional. However, certain drug effects were quantitatively dependent on the current injection approach used.Conclusion: Injection of a synthetic IK1 with moderate rectification facilitates detailed AP measurements in human atrial myocytes. Therefore, dynamic clamp represents a promising tool for testing novel antiarrhythmic drugs.

P2863Regional specific remodeling of cGMP pathway in human atrial fibrillation

Background Atrial fibrillation (AF) is accompanied by a profound remodeling of membrane receptors and alterations in cyclic nucleotides-dependent regulation of Ca2+-handling. Thus, while basal ryanodine receptors activity is upregulated, L-type calcium current (ICa,L) density is diminish in AF, due to local microdomain-specific cAMP dynamics. The same seems true for cGMP regulation in AF. In AF cGMP-mediated increase in ICa,L is blunted but NO-mediated attenuation of β-adrenoceptors stimulation-mediated increase is preserved. However, although the role of cGMP in controling atrial function and pathophysiology is controversial, no study has been ever performed in human myocytes to measure cGMP directly. Methods We isolated myocytes from the right and/or left atrium of 27 patients in sinus rhythm (SR), and with AF. Cells were then transfected with adenovirus to express the cytosolic FRET-based cGMP sensor red-cGES-DE5 and cultured for 48 hours. Förster resonance energy transfer (FRET) was used to measure cGMP in 61 living human atrial myocytes. We stimulated cells with the C-type natriuretic peptide CNP (100 nM and 1 μM), and the non-selective phosphodiesterases (PDEs) inhibitor IBMX (100 μM). Additionally, PDE specific inhibitors for PDE2 (Bay 60–7550, 100 nM) and PDE3 (Cilostamide, 10 μM) as well as inhibitor of the soluble guanylyl cyclase (ODQ, 50 μM) were used. We also measured PDE2 and PDE3 mRNA levels in atrial tissue samples from both groups of patients using RT-qPCR. Results We could show that stimulation with CNP increased cGMP levels in human atrial myocytes. However, in myocytes from patients with AF global cGMP responses to CNP and to IBMX was reduced compared to SR. Additionally, there was a difference in response to CNP and IBMX in patients with AF between the right and the left atria. Whereas in the right atria IBMX could further increase cGMP levels in the cell, in the left atria leaded to a reduction in cGMP levels. RT-qPCR showed a tendency of PDE3 to be reduced in AF. On the other hand, PDE2A gene expression was upregulated in the left atria. Conclusions We have shown that PDEs contributes cGMP signaling in the human atria and that they are involved in atrial pathophysiology. Now our data clearly show differences in cGMP regulation in cardiomyocytes isolated from left and right atrium from patients in atrial fibrillation and sinus rhythm. We observe a major role of PDEs, regulating cGMP pathway promoted by the reduced responses in AF, especially PDE2 in the left atria.

P2869Role of PDE8 in cAMP dynamics in human atrial fibrillation

Background Cardiac arrhythmias, such as atrial fibrillation (AF), are often related to remodeling of membrane receptors and alterations in cAMP-dependent regulation of Ca2+ handling mechanisms. For instance, decreased L-type calcium current (ICa,L) density but upregulated RyR2 are major hallmarks of AF. These inhomogeneous AF-associated changes of protein phosphorylation point to a local regulation of PKA activity within these intracellular compartments. Local cAMP compartmentation and the role of phosphodiesterase (PDEs) have ben extensively studied in ventricular myocytes from animals. However, only a few studies have evaluated the contribution of PDEs to the pathophysiology of AF and the reason for the persistent AF-associated hypophosphorylation of the L-type calcium channel (LTCC) is currently unknown. The aim of this study was to investigate whether a change in the expression level of PDE8 in human atrium may affects cAMP nearby LTCC promoting the reduction of the ICa,L observed in persistent AF. Methods Atrial myocytes were isolated from tissue of 47 patients in sinus rhythm (SR) and with AF. Cells were then transfect with an adenovirus (Epac1-camps or pm-Epac1-camps) in order to express the (cytosolic or membrane, respectively) FRET-based cAMP sensor and cultured during 48 hours. Föster-resonance energy transfer (FRET) was used to measure cAMP in 232 isolated human atrial myocytes. Ro-20-1724 (10 μM), Cilostamide (1 μM) and PF-04957325 (30 nM) and IBMX (100 μM) were used as PDE4, PDE3, PDE8 and non-selective phosphodiesterases (PDEs) inhibitor respectively. Results Effects of PDE4 and especially PDE3 inhibition on cytosolic [cAMP] are reduced in AF. Pharmacological PDE8 inhibition induces only a small increase in basal intracellular [cAMP] in AF but it showed a big synergic effect when PDE4 was inhibit at the same time. By contrast, PDE8 inhibition dramatically increased basal [cAMP] in the subsarcolemmal compartment in AF while PDE3 or PDE4 inhibition had a smaller effect that didn't change between SR and AF. Conclusions PDE8 controls basal cytosolic cAMP levels in human atrial myocytes from patients with persistent AF while PDE3 effects tends to be reduced in these patients. Furthermore, PDE8 is the main PDE in controlling cAMP levels at the membrane in persistent AF. Thus, our study may provide a clue for the reported reduction of the ICa,L in persistent AF.

P3830Carvedilol treatment diminishes spontaneous calcium release and electrical activity in human atrial myocytes

Background Atrial fibrillation (AF) has been associated with an increase in spontaneous calcium release induced electrical activity, which could potentially be reversed by carvedilol, a nonselective beta-blocker that also inhibits the cardiac ryanodine receptor (RyR2). Interestingly the enantiomer R-carvedilol inhibits the RyR2 but not beta-adrenergic receptors, allowing it to effectively prevent calcium release-induced spontaneous electrical activity without inducing bradycardia and hypotension. Purpose The purpose of this study was to determine how carvedilol treatment affects calcium release-induced transient inward currents (ITI) in human atrial myocytes from patients with AF; and to test the effects of R-carvedilol on spontaneous calcium release in order to assess its therapeutical utility. Methods Human atrial myocytes were isolated from patients undergoing cardiac surgery and subjected to patch-clamp technique (n=60) or confocal calcium imaging (n=6). Beta-2 adrenergic receptors were activated with the selective agonist fenoterol (3μM) and 1μM R-carvedilol was used to inhibit spontaneous calcium release events. Results Recordings of calcium release-induced transient inward currents (ITI) revealed that carvedilol treatment reduced the ITI frequency in patients with AF from 2.2±0.4 events/min in untreated patients to 0.59±0.35 events/min (p<0.01), which was even lower than the incidence in patients without AF (1.0±0.1 events/min; p<0.01). To assess the effects of R-carvedilol, myocytes were first simulated with fenoterol. This increased the calcium spark frequency from 23±15 to 960±336 events/s/1000μm2 in 16 cells from 6 patients (p<0.05). This was due to an increase in the spark site density (from 0.50±0.24 to 12.1±2.4 sites/1000μm2, p<0.001) rather than in the firing rate (0.068±0.14 vs. 0.035±0.012 sparks/s in control, p=0.14). Fenoterol also increased the spark duration from 50.9±5.4 to 77.3±4.1ms (p<0.001) without affecting the amplitude. Importantly, fenoterol also induced global calcium release events such as calcium waves and transients (2.8±1.1 vs. 0 events/min in control, p<0.05). When R-carvedilol was added, the effects of fenoterol were abolished, reducing the incidence of calcium sparks to 69±51 events/s/1000μm2 (p<0.05), the spark site density to 1.68±1.04 sites/1000μm2 (p<0.01), the spark duration to 63.4±4.3ms (p<0.05), and calcium waves and transients were reduced to 0.21±0.14 events/min (p<0.05). Conclusions Carvedilol treatment reduces the ITI frequency in patients with AF to levels below that observed at baseline in patients without AF. Furthermore, the non-beta-blocking R-carvedilol enantiomer abolishes spontaneous calcium release events induced by beta-2 adrenergic stimulation in human atrial myocytes, proposing a therapeutical utility for this compound in patients with AF linked to excessive spontaneous calcium release. Acknowledgement/Funding SAF2017-88019; Marato2015-20-30; SGR2017-1769; CIBERCV