Background
According to International Diabetes Federation, the global prevalence of diabetes was 415 million in 2015 and the number is estimated to be 642 million by 2040 [
1]. Type 2 diabetes mellitus (T2DM) accounts for 90-95% of all diagnosed cases of diabetes, and it also confers an approximately twofold-increased risk of cardiovascular diseases [
2,
3]. In addition to the well-documented coronary artery disease and related cardiac events, cardiac electrical disturbance are recognized as critical cardiovascular complications of T2DM and may lead to tachycardia, fibrillation, cardiomyopathy, and even death [
4‐
6]. However, the mechanisms underlying the relation between T2DM and arrhythmia is not fully understood.
Small conductance calcium-activated potassium channels (SK channels) are important players in cardiac action potential repolarization [
7]. The SK channels consists of three isoforms, namely, KCa2.1, KCa2.2 and KCa2.3, which are encoded by
KCNN1,
KCNN2 and
KCNN3, respectively. All the three SK isoforms are detected in rat atrial and ventricular myocytes with higher abundance of SK1 and SK2 in the atria than that in the ventricles [
8]. A genome-wide study has identified common genetic variants of
KCNN3 that were associated with lone atrial fibrillation [
9]. In addition, a selective SK blocker has been shown to significantly prolong atrial refractoriness and reduce atrial fibrillation duration in a canine model of atrial fibrillation [
10]. These findings imply an important role of the SK channels in the maintenance of atrial electrophysiology. However, whether the SK channels are involved in T2DM-associated arrhythmia remains to be elucidated.
Metformin is currently considered one of the first-line treatments for T2DM [
11]. Recently, the anti-arrhythmic effect of metformin has been gradually recognized. In a 13-year dynamic cohort study of 645,710 patients with T2DM, metformin treatment was associated with a significantly reduced incidence of new-onset atrial fibrillation [
12]. It remains unknown whether metformin exerts a direct corrective effect on the electrical activity in the diabetic atrial myocytes. Hence, the current study aims to explore the mechanism underlying the anti-arrhythmic effect of metformin in a T2DM rat model with a special focus on the SK channels.
Methods
Animals
Twelve male Goto-Kakizaki (GK) T2DM model rats (10 weeks old, 249.83 ± 4.68 g) were allowed to access to standard chow and water ad libitum and maintained in a controlled environment (22 ± 2 °C, relative humidity of 55 ± 5% and 12,12-h light-dark cycle). The rats’ body weights and blood glucose levels (determined by an Accu-Chek glucometer, Roche) were measured three times a week. Age-matched, male, non-diabetic Wistar rats (249.50 ± 4.48 g) were used as the control (Con). After two-week adaptation, fasting blood glucose and blood insulin levels were measured and an intraperitoneal glucose tolerance test was performed [
13] to conform the onset of diabetes in the GK rats. GK rats in the metformin-treated group (Met) (
n = 6) received intragastric administration of metformin (300 mg/kg/day) since 12 weeks of age for three months, while an equal volume of citric acid buffer was intragastrically administrated daily to the rats in the GK and Con groups (
n = 6 each group). This high dose of metformin was chosen because that long-term treatment with high-dose metformin could alleviate vascular dysfunction and rescue SK channel-mediated vasodilation in diabetic rats [
14,
15]. At the end of three-month metformin treatment, electrocardiogram (ECG) was performed on all rats to monitor the cardiac electrical activity.
Hematoxylin-eosin and Masson’s trichome staining
After the rats were euthanized by i.p. injection with 100 mg/kg pentobarbital sodium, the atrium were excised along with the outline of the atrial appendages, fixed in 4% paraformaldehyde and sectioned. Hematoxylin–eosin and Masson’s staining were performed as previously described [
16]. The images of stained atrial sections were captured under a light microscope, and the proportion of fibrotic areas was determined using the NIS-Elements F3.0 software (Nikon, Tokyo, Japan).
Western blot
To assess the expression levels of SK channels in the atrium, western blotting was conducted according to a previously described method [
17]. The primary antibodies used here included anti-KCa2.1 (1:400; Alomone, Israel), anti-KCa2.2 (1:200; Millipore, USA), anti-KCa2.3 (1:500; Abcam, UK), and anti-GAPDH (1,2000; Santa Cruz, USA). GAPDH served as the loading control. ImageJ software (NIH, Bethesda, MD) was used to analyze the intensity of the target bands.
Real-time PCR
Total RNAs in rat atrial tissues were extracted using an RNeasy kit (Qiagen, CA), and reversely transcribed into cDNA using a PrimeScript RT Reagent Kit with gDNA Eraser (Takara) according to the manufacturer’s instructions. The sequences of the sense (5’-3’) and antisense (5’-3’) primers are as follows: rKCNN1: CCTTCCTGTCCATCGGCTAC, GCGTTTTTAACCCGCTTGGT; rKCNN2: ACTAGCAACTTCCTTGGAGCA, GCAACCTGCACCCATTATTCC; rKCNN3: CACCTTCCCCAAAGCCAACA, CGATCACAAAGAGCTGTACTTCC; rGAPDH: GGCAAGTTCAACGGCACAGT, TGGTGAAGACGCCAGTAGACTC.
Isolation of rat atrial myocytes and patch-clamp assay
Rat atrial myocytes was isolated as previously described using the Langendorff apparatus [
18]. The velocity of heart retrograde perfusion was 1 ml/min. SK currents were apamin sensitive. SK currents = baseline K
+ current before apamin - K
+ current after 100 pM apamin (a specific SK channel blocker). According to a standard method [
19], whole-cell K
+ currents in rat atrial myocytes were detected using an EPC10 amplifier, wherein all signals were acquired at 5 kHz and analyzed by Patchmaster software (version 2.72, HEKA Electronics, Lambrecht/Pfalz, Germany).
Quiescent, calcium-tolerant, spindle-shaped cells with clear cross striation were used for action potential recordings at 35 °C. Action potential was elicited as described previously [
19]. At the moment of 50 and 90% repolarization, the action potential duration (APD) was detected and recorded as APD
50 and APD
90, respectively. In addition, resting potential (RP), action potential amplitude (APA), APD
50 and APD
90 were recorded before and after exposure to 100 pM apamin for 15 min. The action potential recordings without apamin exposure showed the normal state, and the results after apamin exposure demonstrated the condition of SK channel blockade.
Statistical analysis
The data are expressed as mean ± SEM. Control and GK groups were compared using t test. For multiple comparisons, one-way analysis of variance (ANOVA) followed by Fisher’s least significant difference test was used when the data conformed Gaussian distribution and homogeneity of variance, and nonparametric Kruskal-Wallis test with Dunn’s multiple comparisons was used otherwise. Statistical analyses were performed using the SPSS software (version 19.0, Chicago, IL) and GraphPad Prism (version 6.0, La Jolla, CA).
Discussion
Our study demonstrates for the first time that the expression and current intensity of SK channels are altered in the atrial myocytes of diabetic GK rats, which leads to the prolongation of APD. Of course, the changes in APD may result from remodeling of multiple ion channels involving transient outward current and calcium current. By specifically blocking the SK channels with apamin, we found that the atrial myocytes from GK rats did not respond to apamin-induced APD prolongation, indicating that the function of the SK channels was impaired in the atrial myocytes of this T2DM model rat. Consistent with our findings, down-regulation of atrial SK channels in type 1 diabetic mice is associated with a decreased current intensity [
20]. In our study, KCa2.2 is the only down-regulated SK channel in diabetic atrium, and it is likely to be responsible for the reduced SK current and prolonged APD in atrial myocytes under diabetic conditions. On the other hand, by taking advantage of a
KCNN3 transgenic mouse model, Zhang et al. demonstrate that overexpression of KCa2.3 results in significant shortening of APD in atrial myocytes and increased susceptibility to atrial fibrillation [
21]. Thus, elevated expression of KCa2.3 is a risk factor of atrial fibrillation. Here, the expression of KCa2.3 was significantly increased in the atrium of GK rats, suggesting that it may play a role in diabetes-induced arrhythmia.
The relation between ion channel activity and cardiac electrical property is complicated. Clinical data indicate an increased risk of atrial fibrillation in patients with diabetes [
6]. In this study, KCa2.2 was down-regulated while KCa2.3 was up-regulated in the diabetic atrium, implying the potential involvement of the SK channel alteration in the development of arrhythmia or atrial fibrillation. It is reported that down-regulation of KCa2.1 and KCa2.2 is detected along the progression of atrial fibrillation in human [
22]. For these differential expression patterns of SK channels, we assume that the expression of SK channels changes with the development of arrhythmia, and the expression pattern depends on the stage of the disease. In addition, blockade of SK channels in various cardiac arrhythmia models has been shown to be both anti-arrhythmic [
23] and pro-arrhythmic [
7,
24], and both shortening and lengthening of action potential will lead to arrhythmia. Our results showed down-regulation of KCa2.2 and up-regulation of KCa2.3 were associated with prolonged APD in atrial myocytes and arrhythmia in diabetic rats, yet the relationship between each single SK channel and diabetic-associated arrhythmia need to be addressed in the future. Furthermore, our data suggests that diabetic conditions affected SK channel expression at the mRNA level. Therefore, it is important to identify the upstream transcription factors that regulate the expression of SK channels and microRNAs that interfere with the stability of SK channel transcripts [
25,
26], and these factors may become potential targets for the intervention of the pathologic changes (such as atrial arrhythmia) in T2DM.
Metabolic stress, inflammation and oxidative stress may affect cardiac functionality and contribute to arrhythmia, and alterations of ion channel activity are implicated in these pathological processes [
27]. In the patients affected by outflow tract premature ventricular contractions, a higher recurrence rate after catheter ablation was noticed in those with metabolic syndrome [
28]. It is mostly likely that alterations of ion channels in the cardiomyocytes affect the long-term post-ablation prognosis. Here we showed that myocardial expression of SK channels was altered under diabetic conditions. Therefore, in addition to the treatment of arrhythmia in T2DM patients, such as cardiac resynchronization [
29,
30], correction of ion channel expression and activity should be considered for the maintenance of cardiac functionality and prevention of recurrence.
In the present study, the anti-arrhythmic effect of metformin was analyzed. Metformin treatment alleviated diabetes-induced atrial remodeling, fibrosis and arrhythmia in GK rats. Moreover, metformin treatment reversed the changes in the expression of SK channels and preserved SK channel function in the atrial myocytes of diabetic rats. Our findings support the beneficial effect of metformin on cardiac electrophysiology under diabetic conditions. Therefore, this anti-diabetic agent not only stabilizes blood glucose in patients with T2DM, but may also provide protection to the heart and prevent diabetic arrhythmia.
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