Sex‐specific activation of SK current by isoproterenol facilitates action potential triangulation and arrhythmogenesis in rabbit ventricles

Ethical approval

All experimental procedures were approved by the Institutional Animal Care and Use Committee of Indiana University School of Medicine (IACUC no. 10961), and conformed to the Guide for the Care and Use of Laboratory Animals (National Institutes of Health).

Optical mapping

A total of 50 adult (5–6 months old) New Zealand White rabbits (26 females and 24 males) were used for optical mapping studies. We placed the rabbits in a restrainer and euthanized them by intravenous sodium pentobarbitone overdose (160 mg kg⁻¹, i.v.) before heart removal. Hearts were harvested and Langendorff perfused with Tyrode solution (in mmol  L⁻¹: 128.3 NaCl, 4.7 KCl, 20.2 NaHCO₃, 0.4 NaH₂PO₄, 1.8 CaCl₂,1.2 MgSO₄, 11.1 glucose and bovine serum albumin 40 mg L⁻¹) that was bubbled with 95% O₂–5% CO₂ to maintain a pH of 7.40. All chemicals were purchased from Sigma‐Aldrich (St Louis, MO, USA).

Simultaneous optical mapping of the membrane potential (V_m) and Ca_i was performed using techniques similar to that reported elsewhere (Chang et al. 2013a). The hearts were stained with RH237 (10 μmol L⁻¹, from Thermo Fisher Scientific, Waltham, MA, USA) for V_m mapping and Rhod‐2 AM (1.4 μmol L⁻¹, from Thermo Fisher Scientific) for Ca_i mapping. Blebbistatin (15∼20 μmol L⁻¹, from Tocris Bioscience, Minneapolis, MN, USA) was used to inhibit contraction. The epicardial surfaces of right and left ventricles were excited with a laser (Verdi G5, Coherent Inc., Santa Clara, CA, USA) at a wavelength 532 nm, and the emitted fluorescence was filtered at 715 nm long pass. The fluorescence was recorded with 100 × 100 pixels for a spatial resolution of 0.35 × 0.35 mm² per pixel at 2 ms frame⁻¹ sampling rate. Optical signals were processed both spatially (3 × 3 pixels Gaussian filter) and temporally (3 frames moving average).

Seven different protocols were performed as listed below. Optical mapping data were collected at baseline and after each treatment. Protocol I was performed to test ventricular I_KAS at basal condition. Protocols II–IV aimed to examine if I_KAS is differentially activated by isoproterenol (100 nmol L⁻¹) in females and males and to determine the effects of I_KAS blockade on AP duration (APD) and Ca_i transient duration (Ca_iTD). Apamin (100 nmol L⁻¹) blocked I_KAS conducted by all SK channel isoforms while Lei‐Dab7 (20 nmol L⁻¹), a highly specific SK channel subtype 2 (SK2) blocker, differentiated I_KAS conducted by SK2 from that conducted by other isoforms. Chromanol 293B (I_Ks blocker, 10 μmol L⁻¹) was used to exclude the effects of I_Ks activation during β‐adrenergic stimulation. Protocols V and VI aimed to investigate the mechanisms underlying sex differences of I_KAS. Previous studies found that casein kinase‐2 (CK2) interacted with SK2 channels and diminished I_KAS in neurons (Pachuau et al. 2014). Therefore, we used a CK2 specific inhibitor, 4,5,6,7‐tetrabromobenzotriazole (TBB, 10 μmol L⁻¹), to determine if CK2 inhibition can increase I_KAS in males. BayK8644 (I_Ca,L agonist, 1 μmol L⁻¹) was applied to examine the effects of I_Ca,L on I_KAS activation. Protocol VII was performed to determine the effects of I_KAS activation and blockade on ventricular arrhythmogenicity and ventricular fibrillation (VF) dynamics.

Since ventricular pacing and atrioventricular node ablation could activate I_KAS and induce short‐term cardiac memory in normal rabbit ventricles (Chan et al. 2015), we avoided ventricular pacing in Protocols I–IV and VI for APD measurement. In Protocol I, we optically mapped the ventricles with right atrial (RA) pacing at cycle length (PCL) 200, 250 and 300 ms. Since isoproterenol markedly accelerated the sinus rhythm to about 240–290 beats min⁻¹, in Protocols II–IV, we optically mapped the ventricles at a fixed atrial PCL 200 ms in order to reach 1:1 capture. Optical mapping data in Protocols V and VII were collected under ventricular pacing. However, to minimize the ventricular pacing‐induced I_KAS activation, we left the ventricles unpaced except during induction of cardiac alternans and VF. In all protocols, the agents were sequentially added to the perfusate and recirculated until washout.

Transmembrane potential recording

To verify the optical mapping findings at the cellular level, we performed transmembrane potential (TMP) recording of cardiomyocytes from the epicardium of LV base using the protocol of baseline–isoproterenol–apamin–washout in four hearts (2 females and 2 males). After immobilization of the Langendorff‐perfused hearts by blebbistatin, standard glass capillary microelectrodes filled with 3 mol L⁻¹ KCl with a tip resistance of ∼20 MΩ at the digitization rate of 10 kHz was used to record TMP. The data were stored with Axoscope 10.2 (Molecular Devices, Sunnyvale, CA, USA). Experiments were performed at 38.3°C.

Ventricular cardiomyocytes isolation

Ventricular cardiomyocytes were isolated from an additional eight rabbits (4 females and 4 males) for use in patch clamp, western blot and immunostaining studies. After intravenous sodium pentobarbitone overdose, hearts were quickly excised by thoracotomy and Langendorff perfused for 5 min with Tyrode solution followed by perfusion with an oxygenated buffer containing (in mmol  L⁻¹): 138 NaCl, 5.4 KCl, 0.3 NaH₂PO₄, 1.2 MgCl₂, 10 HEPES, 10 taurine and 10 glucose (pH 7.4 with NaOH at 37°C). This was followed by a 15 min perfusion with the same buffer containing 1 mg mL⁻¹ collagenase (Type II, 270 U mg⁻¹; Worthington Biochemical Corp., Lakewood, NJ, USA) and 0.1 mg mL⁻¹ protease (Type XIV, ≥3.5 U mg⁻¹; Sigma‐Aldrich). The heart was removed from the Langendorff apparatus. Cardiomyocytes from the base of the left ventricles were dissociated from digested ventricles by gentle mechanical dissociation.

I_KAS densities determined by voltage‐clamp techniques

Voltage‐clamp experiments were conducted at room temperature. An Axopatch 200B amplifier and pCLAMP 10 software (Molecular Devices) were used to generate and record all patch experiments. Pipette electrodes were fabricated using Corning 7056 glass capillaries (Warner Instruments, Hamden, CT, USA).

For whole‐cell I_KAS measurements, the pipette solution contained (in mmol  L⁻¹): 144 potassium gluconate; 1.15 MgCl₂, 5 EGTA, 10 HEPES and CaCl₂ yielding a free (unchelated) [Ca²⁺] of 1 μm (pH 7.25 using KOH). The extracellular solution contained (in mm): 140 N‐methylglucamine, 4 KCl, 1 MgCl₂, 5 glucose and 10 HEPES (pH 7.4 using HCl). The voltage‐clamp protocol consisted of a ramp‐pulse protocol (test pulse: between +40 and −120 mV, holding potential: −70 mV; pulse frequency: every 3 s). Pipette resistance ranged from 1 to 2 MΩ. Series resistance was electronically compensated by 70–80%. Currents were recorded at baseline and after the exposure to 100 nmol L⁻¹ apamin. We also recorded the current in the presence of 100 nmol L⁻¹ isoproterenol and after apamin. To obtain whole‐cell I_KAS, currents recorded in the presence of 100 nmol L⁻¹ apamin were digitally subtracted from those recorded in its absence.

To verify the selectivity of Lei‐Dab7 for I_KAS conducted by SK2 but not SK3, we tested the effects of Lei‐Dab7 on human embryonic kidney (HEK) 293 cells transfected with KCNN2 and KCNN3, respectively. HEK 293 cell were cultured in Iscove's modified Dulbecco's medium (Thermo Fisher Scientific) with 10% fetal bovine serum and 1% penicillin/streptomycin in 5% CO₂ at 37°C; 35 mm dishes of HEK 293 cells were transiently transfected using Effectene Transfection Reagent (Qiagen, Germantown, MD, USA) according to the manufacturer's protocol and were harvested for patch clamp experiment 48∼72 h later. The SK2 and SK3 clones were developed in our laboratory. HEK 293 cells were transfected with 2.0 μg of KCNN2/pIRES‐EGFP2 or 2.0 μg of KCNN3/pIRES‐EGFP2 plasmids, respectively. Single cells were picked and propagated in selection medium containing hygromycin 200 μg mL⁻¹. Currents were recorded at baseline and after exposure to 20 nmol L⁻¹ Lei‐Dab 7, followed by addition of 100 nmol L⁻¹ apamin. The LeiDab7‐sensitive current and apamin‐sensitive current (in the presence of LeiDab7) were calculated, respectively.

Western blot

Western blot was performed in isolated rabbit left ventricular cardiomyocytes. A Lowry protein assay was performed before western blot to guarantee that the protein loadings were identical among lanes. Samples were loaded on SDS‐PAGE and transferred to a nitrocellulose membrane. The blot was probed with the following antibodies: anti‐K_Ca2.2 (SK2) antibody (1:500, APC‐028, Alomone, Jerusalem, Israel), anti‐CK2α antibody (1:500, ab181734, Abcam, Cambridge, UK), anti‐CK2β antibody (1:500, ab201990, Abcam) and anti‐SERCA antibody 2A7‐A1 (1:1000). Antibody‐binding protein bands were quantified with a Bio‐Rad (Hercules, CA, USA) Personal Fx phosphorimager. The control sample for SK2 was the heterologously expressed human isoform of SK2 in cultured HEK 293 cells.

Immunofluorescence confocal microscopy

Both isolated myocytes and ventricular tissues were used for immunofluorescence staining and confocal microscopy. Isolated rabbit ventricular myocytes were fixed with 1% paraformaldehyde for 30 min and seeded on the laminin‐coated glass slides for at least 1 h to allow cell attachment. In addition, ventricular tissue samples were fixed with 4% paraformaldehyde for 45 min, followed by storage in 70% alcohol for at least 48 h. The tissue samples were then processed routinely and embedded in paraffin. Tissue sections (5 μm in thickness) were deparaffinized and hydrated by multiple xylene and ethanol washes.

Slides with either isolated myocytes or ventricular tissue were washed with water and PBS in Tween 20 at least 3 times. Samples were then permeabilized and blocked in PBS with 3% BSA and 0.2% Triton X‐100 for 1 h. After blocking, slides were incubated with anti‐K_Ca2.2 (SK2) antibody (APC‐028, Alomone) 1:200 diluted in PBS (BSA 1%) at 4°C overnight. Subsequently, slides were washed 3 times for 5 min with PBS and incubated with protein A conjugated with fluorescent dyes (Alexa 488, Thermo Fisher Scientific, 1:2000) and 4′,6‐diamidino‐2‐phenylindole for 1 h. After this step, the slides were again washed 3 times for 5 min with PBS followed by mounting with coverslips. The slides were allowed to dry at room temperature and then sealed with nail polish overnight. For comparison, samples from females and males were stained simultaneously.

Confocal images were obtained through a DMI6000 adaptive focus automated inverted microscope, Leica TCS SP8 FSU (argon ion laser) spectral confocal system with HyD supersensitivity detection. For comparison of the fluorescence intensities, slides from females and males were microscopically detected on the same day using identical microscopy settings.

Statistics and data analysis

APD at the level of 25% (APD₂₅) and 80% (APD₈₀) repolarization of the AP was optically measured. We used APD₂₅ to characterize the early phases (phases 1 and 2) of repolarization and APD₈₀ to represent the entire repolarization (phase 1, 2 and 3). Thus, the differences between APD₂₅ and APD₈₀ (APD₈₀ − APD₂₅) were used to characterize the repolarization at phase 3. The APD₂₅/APD₈₀ ratio was used as a quantitative measurement of the AP morphology, with a smaller APD₂₅/APD₈₀ ratio reflecting greater AP triangulation and a larger APD₂₅/APD₈₀ ratio representing AP squaring. Intracellular calcium transient duration at 25% and 80% recovery (Ca_iTD₂₅ and Ca_iTD₈₀) were used as measures of early and total Ca_i duration, respectively. We also calculated the differences between Ca_iTD and APD (Ca_iTD₂₅ − APD₂₅ and Ca_iTD₈₀ − APD₈₀) to characterize the Ca_i–V_m coupling. We averaged the APD in the regions of interest and presented them in the summary data.

Continuous variables were expressed as mean ± SEM. Student's paired t test was used to compare two variables from the same rabbit (such as APD₂₅ before and after apamin). Unpaired t tests were used to compare variables between two groups (such as ΔAPD₂₅ between females and males). Multiple t tests were used to compare I_KAS current densities between sexes at different membrane potentials. One‐way or two‐way ANOVA with the appropriate post hoc test, as indicated in each experiment, was used to compare the means among three or more different variables. A two‐sided P value of <0.05 was considered statistically significant.

Isoproterenol activates I_KAS in female rabbit ventricles

Consistent with previous studies (Chua et al. 2011), I_KAS blockade by apamin only minimally prolonged APD (by <5%) in ventricles from females and males at baseline (Protocol I, Fig. 1). The magnitudes of APD prolongation was not significantly different between males and females. We then tested the effects of I_KAS blockade in the presence of isoproterenol in female rabbit ventricles (Fig. 2A, Protocol II). The AP exhibited a prominent phase 2 plateau at baseline. Isoproterenol shortened and triangulated the AP. Subsequent apamin administration (with isoproterenol in the recirculation) significantly prolonged APD₂₅ (from 29 ± 2 to 40 ± 2 ms, P < 0.001) and APD₈₀ (from 92 ± 4 to 101 ± 3 ms, P < 0.001, Fig. 2B and C), indicating I_KAS activation during isoproterenol perfusion. In addition to APD prolongation, apamin also affected the AP morphology, i.e. reversing isoproterenol‐induced AP triangulation and restoring the phase 2 plateau of repolarization, by lengthening APD₂₅ (11 ± 1 ms and 41 ± 6%) more prominently than APD₈₀ (9 ± 1 ms and 10 ± 1%, P = 0.018 for absolute value and P < 0.001 for percentage, Fig. 2D). As a result, the ratio APD₂₅/APD₈₀ was significantly increased (from 32 ± 2% to 40 ± 2%, P < 0.001, Fig. 2E). Apamin significantly abbreviated differences between APD₈₀ and APD₂₅ from 63 ± 2 to 60 ± 3 ms (P = 0.043, Fig. 2F), indicating a slight acceleration of phase 3 repolarization. Furthermore, as shown in Fig. 2G, the prolongation of the entire repolarization (positive ΔAPD₈₀) was associated with the abbreviation of phase 3 repolarization (negative Δ(APD₈₀ − APD₂₅)) in 7/8 females (circles in quadrant IV), indicating the APD prolongation was completely attributable to the prolongation of phase 2 repolarization. After isoproterenol washout, APD was further prolonged towards the baseline level. As shown in Fig. 2H, TMP recording in cardiomyocytes of female rabbits also verified the optical mapping findings. These results indicate that I_KAS is activated during β‐adrenergic stimulation in female rabbit ventricles.

Ca_i mapping was simultaneously performed in females under Protocol II (Fig. 3). Compared with baseline, isoproterenol markedly shortened Ca_iTD₂₅ and Ca_iTD₈₀ (Fig. 3A) but increased the peak Ca_i (Fig. 3B). These findings indicate higher Ca_i at phase 2 repolarization. In addition, isoproterenol markedly increased the differences between Ca_iTD and APD (Ca_iTD − APD) and more drastically for Ca_iTD₂₅ − APD₂₅ than for Ca_iTD₈₀ − APD₈₀ (30 ± 2 vs. 23 ± 3, P = 0.041, Fig. 3C and F), suggesting an early activated outward current in compensation for the amplified I_Ca,L during phase 2 repolarization. Apamin had minimal effect on Ca_iTD and peak Ca_i (Fig. 3B and D), but produced significant abbreviation of Ca_iTD₂₅ − APD₂₅ (from 30 ± 2 to 20 ± 2 ms, P < 0.001, Fig. 3E) and elimination of the isoproterenol‐induced differences Ca_iTD₂₅ − APD₂₅ and Ca_iTD₈₀ − APD₈₀ (P = 0.563, Fig. 3G). Taken together, isoproterenol increases Ca_i, which in turn activates I_KAS to shorten the APD. Therefore, isoproterenol increases the differences between Ca_iTD₂₅ and APD₂₅ during phase 2 (negative Ca_i–APD coupling).

SK2, but not SK3 or I_KS, is responsible for isoproterenol‐induced AP triangulation in females

Among subtypes of SK channels which generate I_KAS, SK2 and SK3 are important to ventricular repolarization and are completely blocked by 100 nmol L⁻¹ apamin (Yu et al. 2014). Here, we took advantage of the specific SK2 blocker Lei‐Dab7 (20 nmol L⁻¹) (Shakkottai et al. 2001) to distinguish the contributions of I_KAS conducted by different SK subtypes. Firstly, we verified the selectivity of Lei‐Dab7 on SK2 over SK3 (Fig. 4A and B). Lei‐Dab7 at 20 nmol L⁻¹ inhibited the majority of whole‐cell currents in KCNN2‐transfected HEK293 cells but had only minimal effect on KCNN3‐transfected cells. These results indicate Lei‐Dab7 at 20 nmol L⁻¹ only blocks SK2 channels.

We further tested the effects of Lei‐Dab7 (20 nmol L⁻¹) in females under Protocol III (Fig. 4). In the presence of isoproterenol, SK2 blockade by Lei‐Dab7 significantly prolonged APD₂₅ and to a smaller extent APD₈₀ (Fig. 4C and D). Subsequently administered apamin, which only blocked SK3 with Lei‐Dab7 pretreatment, failed to further lengthen APD (Fig. 4E and F). In other words, SK2 blockade (ΔAPD_{LeiDab7−isoproterenol}) had significantly larger effects than SK3 blockade (ΔAPD_{Apamin−LeiDab7}) on both APD₂₅ (11 ± 1 vs. 1 ± 1 ms, P = 0.007) and APD₈₀ (13 ± 2 vs. 1 ± 1 ms, P = 0.004, Fig. 4G). These results suggest that SK2, rather than SK3, is the predominant channel isoform underlying I_KAS activation during β‐adrenergic stimulation.

Similar to I_KAS, I_Ks is also calcium sensitive and is enhanced during sympathetic stimulation (Aflaki et al. 2014; Banyasz et al. 2014; Bartos et al. 2017). To exclude I_Ks as a cause of AP triangulation in females, we pretreated ventricles with the I_Ks blocker chromanol 293B (10 μmol L⁻¹) in Protocol IV (Fig. 5). With I_Ks blockade, isoproterenol still shortened and triangulated AP. Subsequent apamin administration significantly prolonged APD₂₅ and to a lesser extent APD₈₀, indicating that I_KAS contributes to APD shortening and AP triangulation independently of I_Ks.

I_KAS is minimally activated by isoproterenol in male rabbit ventricles

To test sex differences in I_KAS activation, we repeated Protocol II in male rabbit ventricles (Fig. 6A). In contrast to females, apamin prolonged APD very slightly after isoproterenol infusion, although the increment was statistically significant (for APD₂₅, from 30 ± 2 to 33 ± 2 ms and for APD₈₀, from 93 ± 3 to 98 ± 4 ms, P = 0.001 for both, Fig. 6B and C). The prolongations of APD₂₅ and APD₈₀ were similar (for absolute value: 3 ± 0 ms vs. 4 ± 0 ms, P = 0.154; for percentage: 11 ± 0% and 6 ± 1%, P = 0.060; Fig. 6D) and barely altered the APD₂₅/APD₈₀ ratio (32 ± 2 vs. 33 ± 2, P = 0.101, Fig. 6E), indicating no major AP morphology change by apamin. Apamin had little effect on phase 3 repolarization (represented by APD₈₀ − APD₂₅, 64 ± 3 ms vs. 65 ± 4 ms, P = 0.180, Fig. 6F). Figure 6G shows that apamin abbreviated phase 3 repolarization but prolonged the APD₈₀ in 4/8 male rabbit ventricles (positive ΔAPD₈₀ with negative Δ(APD₈₀ − APD₂₅), circles in quadrant IV). These data indicate that the APD prolongation, although only slight, was completely attributable to phase 2 prolongation in these four rabbits. For the other four males, however, the APD₈₀ prolongation relied on the phase 3 prolongation (positive ΔAPD₈₀ with positive Δ(APD₈₀ − APD₂₅), circles in quadrant I), which was a different apamin responses from females. As shown in Fig. 6H, we further verified the findings of optical mapping at the cellular level by TMP recording in cardiomyocytes from male rabbits. Taken together, in contrast to females, males only exhibit minimal I_KAS activation both at baseline and during isoproterenol infusion. I_KAS activation could shorten either phase 2 or phase 3 repolarization of the AP in males.

To evaluate the mechanism of isoproterenol‐induced AP shortening and triangulation that is independent of I_KAS activation in males, we pretreated male rabbits with chromanol 293B to inhibit I_Ks, which is activated by isoproterenol and exhibits stronger activation in males than females (Zhu et al. 2013). As shown in Fig. 7, chromanol 293B prolonged both APD₂₅ and APD₈₀ and more prominently APD₈₀. Compared with females, males had significantly larger APD prolongation, suggesting stronger I_Ks activation in males than females. However, isoproterenol still shortened and triangulated APD even with I_Ks and subsequent I_KAS blockade. These results indicate that isoproterenol‐induced APD shortening and triangulation in males cannot be explained only by I_Ks and I_KAS activation.

The differential I_KAS activation after isoproterenol infusion between sexes is summarized in Fig. 8. Females had significantly greater responses to I_KAS blockade than males in APD₂₅ (absolute value: 11 ± 1 vs. 3 ± 0 ms, P < 0.001; percentage: 39 ± 5% vs. 11 ± 2%, P < 0.001; Fig. 8A) and in APD₈₀ (absolute value: 9 ± 1 vs. 5 ± 1 ms, P = 0.003; percentage: 10 ± 1% vs. 5 ± 1%, P = 0.006; Fig. 8B). Apamin slightly accelerated phase 3 repolarization in females but not in males (Δ(APD₈₀ − APD₂₅): −2 ± 1 vs. 0 ± 1 ms, P = 0.035, Fig. 8C). The APD₂₅/APD₈₀ ratio was significantly larger in females than in males (40 ± 2% vs. 34 ± 2%, P = 0.037, Fig. 8D), indicating differential AP morphology changes by I_KAS blockade between sexes.

I_KAS current densities are higher in females than males

To better understand the mechanisms of the sex differential ventricular I_KAS activation, we examined I_KAS at cellular levels by performing patch clamp studies in isolated ventricular cardiomyocytes. As shown in Fig. 9A, with free Ca²⁺ concentration of 1 μm, mean I_KAS densities were significantly larger in cells from females than males measured at a potential >0 mV (at +10mV: 0.35 ± 0.03 vs. 0.19 ± 0.03 pA pF⁻¹; at +20 mV: 0.47 ± 0.04 vs. 0.21 ± 0.03 pA pF⁻¹; at +30 mV: 0.75 ± 0.05 vs. 0.28 ± 0.05 pA pF⁻¹; at +40 mV: 0.98 ± 0.09 vs. 0.34 ± 0.06 pA pF⁻¹; P < 0.05). We further tested I_KAS densities with pretreatment of 100 nmol L⁻¹ isoproterenol (Fig. 9B). In the presence of isoproterenol, I_KAS densities were significantly larger in myocytes from female than male rabbits at a potential >0 mV (at +10 mV: 0.42 ± 0.08 vs. 0.13 ± 0.03 pA pF⁻¹; at +20 mV: 0.70 ± 0.09 vs. 0.24 ± 0.02 pA pF⁻¹; at +30 mV: 0.99 ± 0.10 vs. 0.38 ± 0.03 pA pF⁻¹; at +40 mV: 1.30 ± 0.12 vs. 0.51 ± 0.03 pA pF⁻¹; P < 0.05). These patch clamp results supported our observations in optical mapping.

SK2 channel protein expression is higher in females than males

Since SK2 carried the enhanced I_KAS by isoproterenol in females, we examined the SK2 channel expression by western blot and confocal immunofluorescence microscopy in both sexes. Western blotting in Fig. 10A showed that SK2 protein expression was significantly higher in female rabbit cardiomyocytes than in males (SK2 normalized to SERCA: 0.075 ± 0.005 vs. 0.043 ± 0.004, P = 0.003). As further shown in Fig. 10B and C, confocal immunofluorescence microscopy detected the expression of SK2 along the Z‐line of plasma membrane at higher fluorescence intensities in females than that in males from both isolated cardiomyocytes and ventricular tissue sections. These results indicate that sex differences exist in SK2 protein expression, which contribute to sex differences in I_KAS.

CK2 activity correlates with I_KAS suppression in males

In its participation in a broad range of cellular signalling pathways, CK2 phosphorylates calmodulin, thus lowing the Ca²⁺ affinity of SK2 channels and reducing I_KAS in neurons (Pachuau et al. 2014). To evaluate if CK2 activity contributed to I_KAS suppression in male rabbit ventricles, we tested the effect of a CK2‐specific blocker, TBB, on APD (Protocol V). As shown in Fig. 11A, TBB drastically abbreviated and triangulated APD. Subsequently, apamin significantly prolonged both APD₂₅ (from 15 ± 2 to 22 ± 1 ms, P = 0.034) and APD₈₀ (from 39 ± 2 to 64 ± 4 ms, P = 0.045, Fig. 11B and C), indicating that CK2 inhibition in males can increase the I_KAS activation. Although western blotting showed CK2α and CK2β had similar expression levels between sexes (Fig. 11D), the significantly higher CK2/SK2 ratio in males than in females (CK2α/SK2: 12 ± 2 vs. 21 ± 2, P = 0.012; CK2β/SK2 ratio: 11 ± 1 vs. 18 ± 2, P = 0.031, Fig. 10E) may correlate with smaller I_KAS in males.

Sex differences in I_KAS are not secondary to sex differences in I_Ca,L

SK2 is molecularly coupled with L‐type calcium channels (LTCCs) (Lu et al. 2007). The magnitude of I_Ca,L density is known to be smaller in males than in females (Vizgirda et al. 2002). It is therefore possible that the weaker I_Ca,L in males partially explains the lower of I_KAS. To test this hypothesis, BayK8644 was used to amplify I_Ca,L (Protocol VI, Fig. 12). In males, compared with baseline, BayK8644 led to markedly enlarged Ca_iTD, drastically increased peak Ca_i and prolonged APD. However, subsequently administered apamin failed to further prolong APD, indicating that BayK8644 failed to activate I_KAS in males. As a comparison, apamin prolonged APD in the presence of BayK8644 in females. These results are inconsistent with the hypothesis that the sex differences in I_KAS are simply secondary to the sex differences in I_Ca,L.

I_KAS blockade eliminates negative Ca_i–V_m coupling at phase 2 and attenuates APD alternans

Cardiac repolarization alternans often precedes life‐threatening ventricular arrhythmias. In alternans, Ca_i and V_m are coupled either positively (a large Ca_i transient prolongs APD of the same beat) or negatively (a large Ca_i transient shortens APD of the same beat) (Kennedy et al. 2017). To test the effects of I_KAS on alternans, rapid pacing was performed in females (Protocol VII, Fig. 13). At basal condition, Ca_i–V_m coupling was positive such that alternans was electromechanically concordant. During isoproterenol (Fig. 13A), the Ca_i–V_m coupling was still positive and the alternans remained electromechanically concordant at the level of APD₈₀. However, at early repolarization phases at the APD₂₅ level, Ca_i–V_m coupling became negative such that alternans became electromechanically discordant. In other words, during phase 2, a larger Ca_i transient (beat 1) led to a shorter and more triangular AP, while a smaller Ca_i transient (beat 2) corresponded to a longer and less triangular AP. As shown in Fig. 13B, I_KAS blockade by apamin eliminated the negative Ca_i–V_m coupling and APD₂₅ alternans (represented by ΔAPD_{25,beat1−beat2}) and also markedly attenuated APD₈₀ alternans (represented by ΔAPD_{80,beat1−beat2}). Figure 13C shows that apamin prolonged APD₂₅ of beat 1 more prominently than that of beat 2 (13 ± 1 vs. 6 ± 2 ms, P = 0.004) while APD₈₀ prolongations were similar between the two adjacent beats (5 ± 1 vs. 7 ± 1 ms, P = 0.250). Figure 13D shows that apamin eliminated alternans of APD₂₅ (from −7 ± 0 to 0 ± 1 ms, P = 0.002) and attenuated alternans of APD₈₀ (from 21 ± 1 to 17 ± 1, P = 0.010). These results indicate that β‐adrenergic stimulation elicits more abundant I_KAS activation at phase 2 than at phase 3 repolarization and during beats with a larger Ca_i transient than those with smaller Ca_i transient, leading to negative Ca_i–V_m coupling and electromechanically discordant alternans at early repolarization phases. I_KAS blockade mainly prolonged phase 2 repolarization in the beats with larger Ca_i transients and had less effect on the beats with smaller Ca_i transients, resulting in the elimination of negative Ca_i–V_m coupling and electromechanically discordant alternans. As a comparison (Fig. 13E and F), in male rabbits, isoproterenol induced Ca_i alternans at PCL 150 ms with less prominent APD alternans. Both Ca_i transient and V_m had little response to apamin. Therefore, the elimination of phase 2 repolarization alternans by I_KAS blockade in female rabbits suggests its potential antiarrhythmic effects during β‐adrenergic stimulation.

Antiarrhythmic effects of I_KAS blockade during isoproterenol infusion

To further assess the antiarrhythmic effects of I_KAS blockade during sympathetic stimulation, we compared VF vulnerabilities and characteristics between females and males (Protocol VII, Fig. 14). None of these ventricles developed spontaneous VF. Ventricular fast pacing was therefore performed to induce VF. As shown in Fig. 14A, VF inducibility (the number of induced VF episode) was similar between sexes at baseline, during isoproterenol and after washout. However, VF inducibility after apamin became significantly lower in females than in males. In addition, the first 100 ms at the onset of each episode of VF was optically captured. As shown in the phase map of VF (Fig. 14B), isoproterenol markedly increased the number of PSs in both groups compared with baseline. Apamin prominently decreased the number of PSs in females, but less prominently in males. As summarized in Fig. 14C, the numbers of PSs were similar between sexes at baseline, during isoproterenol and after washout. However, apamin elicited significant lower PS numbers in females than in males. The dominant frequencies were also similar between sexes at baseline. Isoproterenol infusion led to significantly higher dominant frequencies in females than in males. The differences were eliminated by apamin (Fig. 14D). These results indicate that I_KAS activation plays important roles in proarrhythmia and VF dynamics during sympathetic stimulation, especially in females.

I_KAS and sympathetic stimulation

Even in patients without apparent heart diseases, abnormal adrenergic regulation increases the susceptibility to ventricular arrhythmias (Jouven et al. 2005). β‐Adrenergic activation is known to regulate cardiac repolarization directly and indirectly via a number of currents including I_Ca,L (Reuter, 1983), I_KATP (Maruyama et al. 2014), I_Ks (Zhu et al. 2013; Aflaki et al. 2014; Bartos et al. 2017), and possibly I_Kr (Karle et al. 2002; Harmati et al. 2011) and I_K1 (Fauconnier et al. 2005; Banyasz et al. 2014). Although increased I_Ca,L tends to prolong APD, isoproterenol results in net shortening of APD by activating multiple compensatory outward currents at different phases of repolarization (Harmati et al. 2011; Zhu et al. 2013; Aflaki et al. 2014; Banyasz et al. 2014; Maruyama et al. 2014; Bartos et al. 2017). In addition, as observed in this study and by others (Banyasz et al. 2014), isoproterenol also gave rise to prominent AP morphology changes. While guinea pigs basally exhibited I_Kr > I_K1 > I_Ks, isoproterenol shaped the AP morphology by reversing the dominance pattern to I_Ks > I_K1 > I_Kr (Banyasz et al. 2014). However, the isoproterenol‐induced AP triangulation, i.e. preferentially shortening at phase 2 rather than phase 3 repolarization, is unlikely to rely on I_Kr, I_K1 or I_Ks because these voltage‐dependent currents exhibit limited activation at early repolarization phases under adrenergic stimulation. As an example, in the absence of adrenergic stimulation, I_Ks activates slowly during phase 1 and 2 repolarization and reaches its peak at the end of phase 2 (around 0 mV), followed by a rapid decline at phase 3 repolarization. However, in the presence of adrenergic stimulation, the peak of I_Ks is postponed from mid plateau to phase 3 repolarization (Banyasz et al. 2014). This was supported by the result that I_Ks blockade failed to reverse isoproterenol‐induced AP triangulation in this study (Figs 5 and 7).

Although weak under basal conditions, I_KAS in females was markedly amplified during β‐adrenergic stimulation. The I_KAS activation happens robustly at the early repolarization phases when I_Ca,L activity, sarcoplasmic Ca²⁺ release and Ca_i are all high, resulting in AP triangulation due to more prominent shortening of APD₂₅ than APD₈₀. I_KAS blockade preferentially prolonged phase 2 repolarization to restore the AP plateau and, surprisingly, even slightly shortened phase 3 repolarization, resulting in a squared AP morphology. The AP squaring after I_KAS blockade may be attributed to the further I_Ks activation facilitated by the longer or perhaps more positive plateau, which subsequently accelerated phase 3 repolarization. These findings indicate possible synergistic action between I_KAS and I_Ks in AP repolarization during adrenergic stimulation, especially in females. However, due to the results that isoproterenol still shortened and triangulated AP with both I_KAS and I_Ks blockade in male rabbits, other mechanisms might also contribute in the AP shortening and triangulation, such as the activation of sodium–calcium exchanger (I_NCX) and cAMP‐dependent Cl⁻ current (I_CFTR‐Cl) (Perchenet et al. 2000; Zhang et al. 2001; Lin et al. 2006).

Sex differences in SK2 channels

Sex differences are widely present in a variety of cardiac ion currents and exert large influences on cardiac electrophysiological properties and arrhythmogenesis (Liu et al. 1998; Vizgirda et al. 2002; Sims et al. 2008; Zhu et al. 2013). In this study, we found that I_KAS also exhibited sex differences but they were only unmasked during isoproterenol infusion. The activation of I_KAS could be attributed to the increased currents conducted by either SK2 or SK3, or both. Our experiments with the selective SK2 blocker Lei‐Dab7 suggest that SK2, rather than SK3, is the dominant isoform mediating the enhanced I_KAS during sympathetic stimulation. SK2 channel protein had significantly higher expression in females than in males, thus contributing to the majority of the sex differences in I_KAS activation. However, it is known that SK2 and SK3 proteins can form heteromeric channels in atria (Tuteja et al. 2010; Hancock et al. 2015). Therefore, we cannot exclude the possibility that the SK2‐specific blocker also inhibits I_KAS conducted by the heteromerically assembled SK2–SK3 channels in ventricles.

The sex differences in I_KAS were also verified by voltage clamp studies showing that outward I_KAS densities were larger in isolated ventricular myocytes from females than males with 1 μmol L⁻¹ intracellular Ca²⁺ at basal condition or in the presence of isoproterenol. Western blot and immunostaining suggested that SK2 protein expression was higher in females than males. However, similar I_KAS densities between sexes were detected at potentials ≤0 mV. Since SK2 channels are known for their versatile function and plasticity, the significant increase in outward I_KAS occurring only at potentials >0 mV suggests the mechanism is unlikely to simply result from differences in SK2 protein expression. The sex‐specific differences in outward I_KAS could be due to differential sensitivities of SK channels to voltage‐dependent block by internal Mg²⁺ or other ions. Another explanation is due to the fixed intracellular Ca²⁺ in the patch clamp study. In intact cardiomyocytes, Ca²⁺ influx and subsequent release through LTCC and ryanodine receptor (RyR) might increase the local subsarcolemmal Ca²⁺ concentration up to 100 μmol L⁻¹, while intracellular Ca²⁺ concentration might only reach 1 μmol L⁻¹. Since I_KAS is very sensitive to local Ca²⁺ between the SK channel and LTCC/RyR (Zhang et al. 2018), it is possible that I_KAS recorded at a fixed global Ca²⁺ concentration was not high enough to differentially activate I_KAS between sexes. Further studies with dynamical Ca²⁺ fluctuations are needed.

The Ca²⁺ sensitivity of SK2 channels is strongly modulated by CK2 in neurons (Adelman et al. 2012). Heart failure decreases the interaction between CK2 and SK2 and consequently enhances the sensitivity of I_KAS to Ca²⁺ (Yang et al. 2015). Consistent with those studies, our results further suggested the potential participation of CK2 inhibition in cardiac I_KAS activation. While male rabbit ventricles expressed lower SK2 channels than those of females, the equally expressed CK2 between sexes resulted in a higher CK2/SK2 ratio in males. While these results might in part contribute to the findings of the present study, more work will be needed to prove a causal relationship between the CK2/SK2 ratio and the sex differences of I_KAS densities.

Notably, the function of SK channels not only relies on the total protein expression, but also depends critically on the subcellular distribution and the cell‐surface membrane expression. Interacting proteins, such as α‐actinin and filamin A, regulate SK channel anterograde trafficking to the surface membrane and recycling (Lu et al. 2009; Rafizadeh et al. 2014; Zhang et al. 2017). It is possible that differential channel trafficking properties exist between sexes and contribute to different I_KAS responses to sympathetic stimulation.

Antiarrhythmic effects of I_KAS blockade

AP triangulation, with either APD abbreviation or APD prolongation, predicts serious proarrhythmia (Hondeghem et al. 2001). Agents that prolong phase 3 repolarization (triangulation) are proarrhythmic, while agents that prolong phase 2 without slowing phase 3 (squaring) are generally antiarrhythmic (Hondeghem et al. 2001). Thus, it is important to develop repolarization‐delaying agents that lengthen APD in a safe fashion. In females, I_KAS blockade prolongs phase 2 repolarization without prolonging phase 3 repolarization, reversing AP triangulation and leading to AP squaring, thereby predicting a potential antiarrhythmic effect. Therefore, I_KAS could be a promising target for the development of antiarrhythmic agents, especially for females.

Cardiac alternans is a precursor to VF. APD and Ca_i transient alternans are caused by instabilities in both V_m and Ca_i cycling dynamics and their coupling (Weiss et al. 2006). V_m and Ca_i are coupled via calcium‐sensitive currents, such as I_Ca,L (Weiss et al. 2006), I_NCX (Weiss et al. 2006), I_Ks (Kennedy et al. 2017) and I_KAS (Kennedy et al. 2017). In silico models in the absence of I_KAS, Ca_i and V_m exhibit positive coupling and electromechanically concordant alternans (Kennedy et al. 2017). After introducing I_KAS with a relatively low calcium affinity, APD is shortened when the Ca_i transient is large, resulting in negative Ca_i–V_m coupling and electromechanically discordant alternans (Kennedy et al. 2017). In the present study, we have experimentally validated this prediction by demonstrating that I_KAS activation by isoproterenol caused Ca_i–V_m coupling to shift from positive to negative, resulting in electromechanically discordant alternans, especially at phase 2 repolarization. I_KAS blockade attenuated negative Ca_i–V_m coupling and phase 2 repolarization alternans. In addition, I_KAS blockade reduced the VF vulnerability and altered VF dynamics by reducing the number of PSs and dominant frequency, also suggesting its potential antiarrhythmic effects in females.

Study limitations

The optical mapping was performed only on the epicardium. These findings may not be applicable to mid and endocardium due to the transmurally heterogeneous distribution of I_KAS (Yu et al. 2015). Due to the unavailability of normal human cardiac tissue, the sex differences of I_KAS in human ventricles remain unknown. However, the rabbit is considered as a good animal model for studying sex differences in cardiac ion currents relevant to humans (Salama & Bett, 2014). Isoproterenol also induces AP triangulation in male rabbit ventricles, but apamin failed to normalize the AP morphology. The mechanism of AP triangulation in males remains unclear.

Conclusions and implications

A variety of cardiac electrical diseases exhibit sexual dimorphism (Salama & Bett, 2014; Antzelevitch et al. 2016). Understanding the arrhythmogenic mechanisms may therefore be important for generating sex‐specific therapies. Although ventricular I_KAS is relatively small, it still plays important roles in regulating APs under a variety of physiological and pathological conditions. In the present study, we show that adrenergic stimulation causes greater activation of I_KAS in females than males. The sex differences of I_KAS are attributable to the differences in the expression and biophysical properties of SK2 channels and the CK2/SK2 ratios. Activation of I_KAS is more abundant during phase 2 than during phase 3 repolarization, leading to AP triangulation, negative Ca_i–V_m coupling, electromechanically discordant phase 2 alternans and increased VF vulnerability. I_KAS blockade is potentially antiarrhythmic in females. Drugs specifically targeting cardiac I_KAS should be effective and safe. Amiodarone, a commonly used antiarrhythmic drug, is known to suppress I_KAS (Turker et al. 2013). More specific I_KAS blockers have also been tested in animal models (Diness et al. 2017; Ko et al. 2018). I_KAS blockers may prove to be a new class of antiarrhythmic drugs with sex‐specific clinical applications.

Competing interests

None

Author contributions

M.C.: design, data acquisition and analysis/interpretation; drafting and revision. D.Y., S.G., D.Z.X. and Z.W.: data acquisition and analysis. Z.C., M.R.L., S.F.L., T.H.E. and J.N.W.: design, interpretation and revision. P.S.C.: conception, design, interpretation, drafting and revision. All authors approved the final version of the manuscript. All authors agree to be accountable for the data integrity and ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved. All persons designated as authors qualify for authorship, and all those who qualify for authorship are listed.

Funding

This work was supported by NIH R01HL139829, P01HL78931, R56HL71140, R42DA043391 and TR0022080, a Charles Fisch Cardiovascular Research Award endowed by Dr Suzanne B. Knoebel of the Krannert Institute of Cardiology, a Medtronic‐Zipes Endowment and the Indiana University Health–Indiana University School of Medicine Strategic Research Initiative.