Soren Z. Coulson , Brynne M. Duffy , James F. Staples
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引用次数: 0
Abstract
Mitochondria serve several important roles in maintaining cellular homeostasis, including adenosine triphosphate (ATP) synthesis, apoptotic signalling, and regulation of both reactive oxygen species (ROS) and calcium. Therefore, mitochondrial studies may reveal insights into metabolism at higher levels of physiological organization. The apparent complexity of mitochondrial function may be daunting to researchers new to mitochondrial physiology. This review is aimed, therefore, at such researchers to provide a brief, yet approachable overview of common techniques used to assess mitochondrial function. Here we discuss the use of high-resolution respirometry in mitochondrial experiments and common analytical platforms used for this technique. Next, we compare the use of common mitochondrial preparation techniques, including adherent cells, tissue homogenate, permeabilized fibers and isolated mitochondria. Finally, we outline additional techniques that can be used in tandem with high-resolution respirometry to assess additional aspects of mitochondrial metabolism, including ATP synthesis, calcium uptake, membrane potential and reactive oxygen species emission. We also include limitations to each of these techniques and outline recommendations for experimental design and interpretation. With a general understanding of methodologies commonly used to study mitochondrial physiology, experimenters may begin contributing to our understanding of this organelle, and how it affects other physiological phenotypes.
线粒体在维持细胞稳态方面发挥着多种重要作用,包括三磷酸腺苷(ATP)合成、凋亡信号以及活性氧(ROS)和钙的调节。因此,线粒体研究可以揭示更高层次的生理组织代谢。线粒体功能的复杂性可能会让初涉线粒体生理学的研究人员望而生畏。因此,本综述旨在为这类研究人员提供评估线粒体功能的常用技术的简要而平易近人的概述。在此,我们将讨论线粒体实验中高分辨率呼吸测定法的使用以及该技术的常用分析平台。接下来,我们比较了常用线粒体制备技术的使用,包括粘附细胞、组织匀浆、渗透纤维和分离线粒体。最后,我们概述了可与高分辨率呼吸测定法同时使用的其他技术,以评估线粒体代谢的其他方面,包括 ATP 合成、钙吸收、膜电位和活性氧释放。我们还介绍了每种技术的局限性,并概述了有关实验设计和解释的建议。有了对线粒体生理学常用研究方法的一般了解,实验人员就可以开始帮助我们了解这一细胞器以及它如何影响其他生理表型。
期刊介绍:
Comparative Biochemistry & Physiology (CBP) publishes papers in comparative, environmental and evolutionary physiology.
Part B: Biochemical and Molecular Biology (CBPB), focuses on biochemical physiology, primarily bioenergetics/energy metabolism, cell biology, cellular stress responses, enzymology, intermediary metabolism, macromolecular structure and function, gene regulation, evolutionary genetics. Most studies focus on biochemical or molecular analyses that have clear ramifications for physiological processes.
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