利钠肽寡聚物在心房心肌细胞中引起致心律失常的代谢和电生理效应。
Natriuretic Peptide Oligomers Cause Proarrhythmic Metabolic and Electrophysiological Effects in Atrial Myocytes.
机构信息
Departments of Medicine and Pharmacology, Vanderbilt University School of Medicine, Nashville, TN.
出版信息
Circ Arrhythm Electrophysiol. 2022 Mar;15(3):e010636. doi: 10.1161/CIRCEP.121.010636. Epub 2022 Feb 25.
BACKGROUND
With aging, the human atrium invariably develops amyloid composed of ANP (atrial natriuretic peptide) and BNP (B-type natriuretic peptide). Preamyloid oligomers are the primary cytotoxic species in amyloidosis, and they accumulate in the atrium during human hypertension and a murine hypertensive model of atrial fibrillation susceptibility. We tested the hypothesis that preamyloid oligomers derived from natriuretic peptides cause cytotoxic and electrophysiological effects in atrial cells that promote arrhythmia susceptibility and that oligomer formation is enhanced for a mutant form of ANP linked to familial atrial fibrillation.
METHODS
Oligomerization was assessed by Western blot analysis. Bioenergic profiling was performed using the Seahorse platform. Mitochondrial dynamics were investigated with immunostaining and gene expression quantitated using quantitative reverse transcription polymerase chain reaction. Action potentials and ionic currents were recorded using patch-clamp methods and intracellular calcium measured using Fura-2.
RESULTS
Oligomer formation was markedly accelerated for mutant ANP (mutANP) compared with WT (wild type) ANP. Oligomers derived from ANP, BNP, and mutANP suppressed mitochondrial function in atrial HL-1 cardiomyocytes, associated with increased superoxide generation and reduced biogenesis, while monomers had no effects. In hypertensive mice, atrial cardiomyocytes displayed reduced action potential duration and maximal dV/dT of phase 0, with an elevated resting membrane potential, compared with normotensive mice. Similar changes were observed when atrial cells were exposed to oligomers. mutANP monomers produced similar electrophysiological effects as mutANP oligomers, likely due to accelerated oligomer formation, while ANP and BNP monomers did not. Oligomers decreased Na current, inward rectifier K current, and L-type Ca current, while increasing sustained and transient outward K currents, to account for these effects.
CONCLUSIONS
These findings provide compelling evidence that natriuretic peptide oligomers are novel mediators of atrial arrhythmia susceptibility. Moreover, the accelerated oligomerization by mutANP supports a role for these mediators in the pathophysiology of this mutation in atrial fibrillation.
背景
随着年龄的增长,人类心房无一例外地会发展出由 ANP(心房利钠肽)和 BNP(B 型利钠肽)组成的淀粉样蛋白。前淀粉样寡聚体是淀粉样变性中的主要细胞毒性物质,它们在人类高血压和心房颤动易感性的小鼠高血压模型中在心房中积累。我们检验了这样一个假设,即源自利钠肽的前淀粉样寡聚体在心房细胞中引起细胞毒性和电生理效应,从而促进心律失常易感性,并且寡聚体形成对于与家族性心房颤动相关的 ANP 突变体形式增强。
方法
通过 Western blot 分析评估寡聚体的形成。使用 Seahorse 平台进行生物能量分析。使用免疫染色研究线粒体动力学,并使用定量逆转录聚合酶链反应定量基因表达。使用膜片钳方法记录动作电位和离子电流,并使用 Fura-2 测量细胞内钙。
结果
与 WT(野生型)ANP 相比,突变 ANP(mutANP)的寡聚体形成明显加快。来自 ANP、BNP 和 mutANP 的寡聚体抑制心房 HL-1 心肌细胞中的线粒体功能,与增加的超氧化物生成和减少的生物发生有关,而单体没有影响。与正常血压小鼠相比,高血压小鼠的心房心肌细胞显示动作电位持续时间缩短,0 相最大 dV/dT 降低,静息膜电位升高。当心房细胞暴露于寡聚体时,也观察到类似的变化。mutANP 单体产生与 mutANP 寡聚体相似的电生理效应,可能是由于寡聚体形成加速所致,而 ANP 和 BNP 单体则没有。寡聚体降低了钠电流、内向整流钾电流和 L 型钙电流,同时增加了持续和瞬态外向钾电流,以解释这些效应。
结论
这些发现为利钠肽寡聚体是心房性心律失常易感性的新型介质提供了令人信服的证据。此外,mutANP 的加速寡聚化支持这些介质在这种心房颤动突变的病理生理学中的作用。
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