Quantitative 3D electron microscopy characterization of mitochondrial structure, mitophagy, and organelle interactions in murine atrial fibrillation

IF 3 3区 生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY Journal of structural biology Pub Date : 2024-07-14 DOI:10.1016/j.jsb.2024.108110
Pavithran Guttipatti , Najla Saadallah , Ruiping Ji , Uma Mahesh R. Avula , Christopher N. Goulbourne , Elaine Y. Wan
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Abstract

Atrial fibrillation (AF) is the most common clinical arrhythmia, however there is limited understanding of its pathophysiology including the cellular and ultrastructural changes rendered by the irregular rhythm, which limits pharmacological therapy development. Prior work has demonstrated the importance of reactive oxygen species (ROS) and mitochondrial dysfunction in the development of AF. Mitochondrial structure, interactions with other organelles such as sarcoplasmic reticulum (SR) and T-tubules (TT), and degradation of dysfunctional mitochondria via mitophagy are important processes to understand ultrastructural changes due to AF. However, most analysis of mitochondrial structure and interactome in AF has been limited to two-dimensional (2D) modalities such as transmission electron microscopy (EM), which does not fully visualize the morphological evolution of the mitochondria during mitophagy. Herein, we utilize focused ion beam-scanning electron microscopy (FIB-SEM) and perform reconstruction of three-dimensional (3D) EM from murine left atrial samples and measure the interactions of mitochondria with SR and TT. We developed a novel 3D quantitative analysis of FIB-SEM in a murine model of AF to quantify mitophagy stage, mitophagosome size in cardiomyocytes, and mitochondrial structural remodeling when compared with control mice. We show that in our murine model of spontaneous and continuous AF due to persistent late sodium current, left atrial cardiomyocytes have heterogenous mitochondria, with a significant number which are enlarged with increased elongation and structural complexity. Mitophagosomes in AF cardiomyocytes are located at Z-lines where they neighbor large, elongated mitochondria. Mitochondria in AF cardiomyocytes show increased organelle interaction, with 5X greater contact area with SR and are 4X as likely to interact with TT when compared to control. We show that mitophagy in AF cardiomyocytes involves 2.5X larger mitophagosomes that carry increased organelle contents. In conclusion, when oxidative stress overcomes compensatory mechanisms, mitophagy in AF faces a challenge of degrading bulky complex mitochondria, which may result in increased SR and TT contacts, perhaps allowing for mitochondrial Ca2+ maintenance and antioxidant production.

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小鼠心房颤动中线粒体结构、有丝分裂和细胞器相互作用的定量三维电子显微镜表征。
心房颤动(房颤)是临床上最常见的心律失常,但人们对其病理生理学,包括不规则心律导致的细胞和超微结构变化的了解却很有限,这限制了药物疗法的开发。先前的研究表明,活性氧(ROS)和线粒体功能障碍在房颤的发病过程中起着重要作用。线粒体结构、与其他细胞器(如肌浆网(SR)和 T 管(TT))的相互作用,以及通过线粒体吞噬作用降解功能障碍的线粒体,是了解心房颤动引起的超微结构变化的重要过程。然而,对房颤中线粒体结构和相互作用组的分析大多局限于二维(2D)模式,如透射电子显微镜(EM),这种方法无法全面观察线粒体在有丝分裂过程中的形态演变。在此,我们利用聚焦离子束扫描电子显微镜(FIB-SEM)对小鼠左心房样本进行三维(3D)EM重建,并测量线粒体与SR和TT的相互作用。我们在小鼠房颤模型中开发了一种新颖的三维定量分析 FIB-SEM,与对照组小鼠相比,可量化有丝分裂阶段、心肌细胞中有丝分裂小体的大小以及线粒体结构的重塑。我们的研究表明,在由持续性晚期钠电流引起的自发性和持续性房颤小鼠模型中,左心房心肌细胞中的线粒体具有异质性,其中有相当数量的线粒体增大,伸长增加,结构更加复杂。心房颤动心肌细胞中的线粒体位于 Z 线处,与大型、伸长的线粒体相邻。心房颤动心肌细胞中的线粒体与细胞器的相互作用增加,与 SR 的接触面积是对照组的 5 倍,与 TT 相互作用的可能性是对照组的 4 倍。我们的研究表明,房颤心肌细胞的有丝分裂涉及的有丝分裂小体比对照组大 2.5 倍,携带的细胞器内容物也增加了。总之,当氧化应激克服了代偿机制时,房颤中的有丝分裂面临着降解体积庞大的复杂线粒体的挑战,这可能会导致SR和TT接触增加,从而使线粒体Ca2+得以维持并产生抗氧化剂。
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来源期刊
Journal of structural biology
Journal of structural biology 生物-生化与分子生物学
CiteScore
6.30
自引率
3.30%
发文量
88
审稿时长
65 days
期刊介绍: Journal of Structural Biology (JSB) has an open access mirror journal, the Journal of Structural Biology: X (JSBX), sharing the same aims and scope, editorial team, submission system and rigorous peer review. Since both journals share the same editorial system, you may submit your manuscript via either journal homepage. You will be prompted during submission (and revision) to choose in which to publish your article. The editors and reviewers are not aware of the choice you made until the article has been published online. JSB and JSBX publish papers dealing with the structural analysis of living material at every level of organization by all methods that lead to an understanding of biological function in terms of molecular and supermolecular structure. Techniques covered include: • Light microscopy including confocal microscopy • All types of electron microscopy • X-ray diffraction • Nuclear magnetic resonance • Scanning force microscopy, scanning probe microscopy, and tunneling microscopy • Digital image processing • Computational insights into structure
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