State Key Laboratory of Southwestern Chinese Medicine Resources, School of Pharmacy/School of Modern Chinese Medicine Industry, Chengdu University of Traditional Chinese Medicine, Chengdu, 611137, China; Innovative Institute of Chinese Medicine and Pharmacy/Academy for Interdiscipline, Chengdu University of Traditional Chinese Medicine, Chengdu, 611137, China.
Research Service Office, Meishan Hospital of Chengdu University of Traditional Chinese Medicine, Meishan, 620000, China.
Eur J Pharmacol. 2024 Aug 15;977:176741. doi: 10.1016/j.ejphar.2024.176741. Epub 2024 Jun 15.
Voltage-gated potassium (Kv) channel growth is strongly associated with the development of arrhythmia. Salidroside (Sal), an active component from Rhodiola crenulata, has been shown to exert protective effects against heart disease. The present study was conducted to investigate the effects of Sal on Kv2.1 channel, and to explore the ionic mechanism of anti-arrhythmic.
In this study, we utilized cisapride (Cis., A stimulant that prolongs the QT interval and causes cardiac arrhythmias) by intravenous injection to establish an arrhythmia model, and detected the effects of Sal on electrocardiography (ECG) and pressure volume loop (P-V loop) in SD rats. The effect of Sal on ECG of citalopram (Cit., a Kv2 channel inhibition)-evoked arrhythmia rat models was further evaluated by monitoring the dynamic changes of multiple indicators of ECG. Then, we detected the effect of Sal on the viability of hypoxic H9c2 cells using CCK-8 assay. After that, the effect of Sal on Kv channel currents (I) and Kv2.1 channel currents (I) in H9c2 cells under normal and hypoxic conditions was examined using whole-cell patch clamp technique. In addition, the effect of Sal on I and I in H9c2 cells was determined under the inhibition of Kv and Kv2.1 channels. HEK293 cells stably transfected with Kv2.1 plasmids were also used to investigate the I changes under Sal pre-treated and co-incubated conditions. In addition, potential interactions of Sal with Kv2.1 protein were predicted and tested by molecular docking, molecular dynamics simulation (MDS), localized surface plasmon resonance (LSPR), and cellular thermal shift assay (CETSA) techniques, respectively. Furthermore, gene and protein levels of Kv2.1 in Sal-treated H9c2 cell were estimated by qRT-PCR, Western blot (WB) and immunofluorescence (IF) analysis.
Sal shortened the prolongated QT interval and ameliorated the cardiac impairment associated with arrhythmia in SD rats caused by Cis., as reflected in the ECG and P-V loop data. And Sal was also protective against arrhythmia in rats caused by Kv2 channel inhibition. At the cellular level, Sal increased cell viability after CoCl-induced hypoxic injury in H9c2 cells. Whole-cell patch clamp assay confirmed that Sal inhibited both I and I in normal H9c2 cells, while enhanced I and I in cardiomyocytes after hypoxic injury. And Sal enhanced I inhibited by 1.5 mM 4-AP and upregulated all inhibition of Kv2 channels induced by 20 mM 4-AP administration, antagonized the I inhibitory effect of Cit. Moreover, Sal pre-administration for 24 h and immediate administration increased I in HEK293 cells stably transfected with Kv2.1 plasmids. Molecular docking demonstrated the potential binding of Sal to the Kv2.1 protein, with calculated binding energy of -5.4 kcal/mol. MDS test illustrated that the average hydrogen bonding of the Sal-Kv2.1 complexes was 30.89%. LSPR results verified the potential binding of Sal to Kv2.1 protein with an affinity value of 9.95 × 10 M. CETSA assay confirmed Sal can enhance the expression of Kv2.1 protein in H9c2 cells treated with heat, which suggests that Sal may bind to Kv2.1 protein. The results of WB, qRT-PCR, and IF further argued that Sal pre-administration for 24 h enhanced the levels of the Kv2.1 gene and protein (with no effects on the Kv2.1 gene and protein for H9c2 cells co-incubated with Sal for 6 h and 12 h).
Overall, our findings indicate that Sal can resist drug-induced arrhythmias in SD rats, partially by modulating repolarization through stimulating Kv2.1.
电压门控钾 (Kv) 通道的生长与心律失常的发展密切相关。红景天苷 (Sal) 是红景天的一种活性成分,已被证明对心脏病有保护作用。本研究旨在探讨 Sal 对 Kv2.1 通道的影响,并探索其抗心律失常的离子机制。
本研究采用 cisapride (Cis.,一种延长 QT 间期并导致心律失常的兴奋剂) 静脉注射建立心律失常模型,检测 Sal 对 SD 大鼠心电图 (ECG) 和压力-容积环 (P-V 环) 的影响。通过监测 ECG 多个指标的动态变化,进一步评价 Sal 对 Cit.(一种 Kv2 通道抑制剂)诱发心律失常大鼠模型 ECG 的影响。然后,我们使用 CCK-8 测定法检测 Sal 对缺氧 H9c2 细胞活力的影响。之后,使用全细胞膜片钳技术检测 Sal 对正常和缺氧条件下 H9c2 细胞 Kv 通道电流 (I) 和 Kv2.1 通道电流 (I) 的影响。此外,还测定了 Sal 在抑制 Kv 和 Kv2.1 通道时对 I 和 I 的影响。还使用稳定转染 Kv2.1 质粒的 HEK293 细胞研究 Sal 预处理和共孵育条件下 I 的变化。此外,通过分子对接、分子动力学模拟 (MDS)、局部表面等离子体共振 (LSPR) 和细胞热转移测定 (CETSA) 技术分别预测和测试 Sal 与 Kv2.1 蛋白的潜在相互作用。此外,通过 qRT-PCR、Western blot (WB) 和免疫荧光 (IF) 分析估计 Sal 处理的 H9c2 细胞中 Kv2.1 的基因和蛋白水平。
Sal 缩短了 Cis.引起的 SD 大鼠 QT 间期延长,并改善了与心律失常相关的心脏损伤,表现在 ECG 和 P-V 环数据上。Sal 还能预防 Kv2 通道抑制引起的大鼠心律失常。在细胞水平上,Sal 可增加 CoCl 诱导的缺氧损伤后 H9c2 细胞的细胞活力。全细胞膜片钳检测证实 Sal 抑制正常 H9c2 细胞的 I 和 I,同时增强缺氧损伤后心肌细胞的 I 和 I。Sal 增强了由 1.5 mM 4-AP 抑制的 I,并拮抗 Cit 引起的所有 Kv2 通道抑制作用。此外,Sal 预处理 24 小时并立即给药可增加稳定转染 Kv2.1 质粒的 HEK293 细胞的 I。分子对接表明 Sal 与 Kv2.1 蛋白具有潜在的结合能力,计算得到的结合能为-5.4 kcal/mol。MDS 测试表明,Sal-Kv2.1 复合物的平均氢键为 30.89%。LSPR 结果验证了 Sal 与 Kv2.1 蛋白的潜在结合,亲和力值为 9.95×10-5 M。CETSA 实验证实 Sal 可以增强热处理的 H9c2 细胞中 Kv2.1 蛋白的表达,这表明 Sal 可能与 Kv2.1 蛋白结合。WB、qRT-PCR 和 IF 的结果进一步表明,Sal 预处理 24 小时可增强 Kv2.1 基因和蛋白水平(Sal 与 H9c2 细胞共孵育 6 小时和 12 小时对 Kv2.1 基因和蛋白没有影响)。
总的来说,我们的研究结果表明 Sal 可以抵抗 SD 大鼠的药物诱导性心律失常,部分通过刺激 Kv2.1 来调节复极化。
