Abstract
The small conductance Ca(2+)-activated K(+) (SK) channels have recently been found to be expressed in the heart, and genome-wide association studies have shown that they are implicated in atrial fibrillation. Diabetes mellitus is an independent risk factor of atrial fibrillation, but the ionic mechanism underlying this relationship remains unclear. We hypothesized that SK channel function is abnormal in diabetes mellitus, leading to altered cardiac electrophysiology. We found that in streptozotocin-induced diabetic mice, the expression of SK2 and SK3 isoforms was down-regulated by 85 and 92%, respectively, whereas that of SK1 was not changed. SK currents from isolated diabetic mouse atrial myocytes were significantly reduced compared with controls. The resting potentials of isolated atrial preparations were similar between control and diabetic mice, but action potential durations were significantly prolonged in the diabetic atria. Exposure to apamin significantly prolonged action potential durations in control but not in diabetic atria. Production of reactive oxygen species was significantly increased in diabetic atria and in high glucose-cultured HL-1 cells, whereas exposure of HL-1 cells in normal glucose culture to H2O2 reduced the expression of SK2 and SK3. Tyrosine nitration in SK2 and SK3 was significantly increased by high glucose culture, leading to accelerated channel turnover. Treatment with Tiron prevented these changes. Our results suggest that increased oxidative stress in diabetes results in SK channel-associated electrical remodeling in diabetic atria and may promote arrhythmogenesis.
Highlights
small conductance Ca2؉-activated K؉ (SK) channels are implicated in atrial fibrillation (AF), and diabetes (DM) is a risk factor for AF
Production of reactive oxygen species was significantly increased in diabetic atria and in high glucose-cultured HL-1 cells, whereas exposure of HL-1 cells in normal glucose culture to H2O2 reduced the expression of SK2 and SK3
We determined whether the down-regulation of SK2 and SK3 channel protein expression was due to down-regulation of their mRNA expression using real time PCR techniques
Summary
SK channels are implicated in atrial fibrillation (AF), and diabetes (DM) is a risk factor for AF. Results: Atrial SK2 and SK3 are significantly down-regulated from accelerated turnover in diabetic mice, resulting in action potential prolongation and arrhythmias. The small conductance Ca2؉-activated K؉ (SK) channels have recently been found to be expressed in the heart, and genomewide association studies have shown that they are implicated in atrial fibrillation. The resting potentials of isolated atrial preparations were similar between control and diabetic mice, but action potential durations were significantly prolonged in the diabetic atria. SK channels have similar topology to members of the voltage-gated Kϩ channel subfamily They have small conductances (10 –20 picosiemens) that are not activated by voltage but by intracellular free Ca2ϩ with sensitivity conferred by intimate interaction between calmodulin and each of the four channel subunits [9, 10]. We hypothesized that atrial SK channel function is abnormal in DM, resulting in altered cardiac electrophysiology, which in turn may lead to development of arrhythmias
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