Hirose Sayako, Makiyama Takeru, Melgari Dario, Yamamoto Yuta, Wuriyanghai Yimin, Yokoi Fumika, Nishiuchi Suguru, Harita Takeshi, Hayano Mamoru, Kohjitani Hirohiko, Gao Jingshan, Kashiwa Asami, Nishikawa Misato, Wu Jie, Yoshimoto Jun, Chonabayashi Kazuhisa, Ohno Seiko, Yoshida Yoshinori, Horie Minoru, Kimura Takeshi
Department of Cardiovascular Medicine, Kyoto University Graduate School of Medicine, Kyoto, Japan.
Department of Cardiovascular and Respiratory Medicine, Shiga University of Medical Science, Otsu, Japan.
Front Cell Dev Biol. 2020 Aug 13;8:761. doi: 10.3389/fcell.2020.00761. eCollection 2020.
Long QT syndrome type 3 (LQT3) is caused by gain-of-function mutations in the gene, which encodes the α subunit of the cardiac voltage-gated sodium channel. LQT3 patients present bradycardia and lethal arrhythmias during rest or sleep. Further, the efficacy of β-blockers, the drug used for their treatment, is uncertain. Recently, a large multicenter LQT3 cohort study demonstrated that β-blocker therapy reduced the risk of life-threatening cardiac events in female patients; however, the detailed mechanism of action remains unclear.
This study aimed to establish LQT3-human induced pluripotent stem cells (hiPSCs) and to investigate the effect of propranolol in this model.
An hiPSCs cell line was established from peripheral blood mononuclear cells of a boy with LQT3 carrying the -N1774D mutation. He had suffered from repetitive torsades de pointes (TdPs) with QT prolongation since birth (QTc 680 ms), which were effectively treated with propranolol, as it suppressed lethal arrhythmias. Furthermore, hiPSCs were differentiated into cardiomyocytes (CMs), on which electrophysiological functional assays were performed using the patch-clamp method.
N1774D-hiPSC-CMs exhibited significantly prolonged action potential durations (APDs) in comparison to those of the control cells (N1774D: 440 ± 37 ms vs. control: 272 ± 22 ms; at 1 Hz pacing; < 0.01). Furthermore, N1774D-hiPSC-CMs presented gain-of-function features: a hyperpolarized shift of steady-state activation and increased late sodium current compared to those of the control cells. 5 μM propranolol shortened APDs and inhibited late sodium current in N1774D-hiPSC-CMs, but did not significantly affect in the control cells. In addition, even in the presence of intrapipette guanosine diphosphate βs (GDPβs), an inhibitor of G proteins, propranolol reduced late sodium current in N1774D cells. Therefore, these results suggested a unique inhibitory effect of propranolol on late sodium current unrelated to β-adrenergic receptor block in N1774D-hiPSC-CMs.
We successfully recapitulated the clinical phenotype of LQT3 using patient-derived hiPSC-CMs and determined that the mechanism, by which propranolol inhibited the late sodium current, was independent of β-adrenergic receptor signaling pathway.
3型长QT综合征(LQT3)由编码心脏电压门控钠通道α亚基的基因功能获得性突变引起。LQT3患者在休息或睡眠期间会出现心动过缓和致命性心律失常。此外,用于治疗该疾病的β受体阻滞剂的疗效尚不确定。最近,一项大型多中心LQT3队列研究表明,β受体阻滞剂治疗可降低女性患者发生危及生命的心脏事件的风险;然而,其详细作用机制仍不清楚。
本研究旨在建立LQT3人诱导多能干细胞(hiPSC)并研究普萘洛尔在该模型中的作用。
从一名携带-N1774D突变的LQT3男孩的外周血单个核细胞中建立hiPSC细胞系。他自出生以来就患有伴有QT延长的反复尖端扭转型室速(TdP)(QTc 680 ms),普萘洛尔可有效治疗该疾病,因为它能抑制致命性心律失常。此外,将hiPSC分化为心肌细胞(CM),并使用膜片钳方法对其进行电生理功能测定。
与对照细胞相比,N1774D-hiPSC-CM的动作电位时程(APD)显著延长(N1774D:440±37 ms,对照:272±22 ms;在1 Hz起搏频率下;P<0.01)。此外,N1774D-hiPSC-CM表现出功能获得性特征:与对照细胞相比,稳态激活发生超极化偏移且晚期钠电流增加。5μM普萘洛尔可缩短N1774D-hiPSC-CM的APD并抑制晚期钠电流,但对对照细胞无显著影响。此外,即使存在膜内鸟苷二磷酸β(GDPβ)(一种G蛋白抑制剂),普萘洛尔仍可降低N177D细胞中的晚期钠电流。因此,这些结果表明普萘洛尔对N1774D-hiPSC-CM中的晚期钠电流具有独特的抑制作用,且与β肾上腺素能受体阻滞无关。
我们利用患者来源的hiPSC-CM成功重现了LQT3的临床表型,并确定普萘洛尔抑制晚期钠电流的机制独立于β肾上腺素能受体信号通路。
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