线粒体动力学调控机制及其在肾脏病理生理学中的作用

线粒体是一种动态变化的细胞器,它通过不断的融合、分裂来维持线粒体的形态、数量和功能稳定,这一过程称为线粒体动力学,是线粒体质量控制的重要机制。线粒体的过度融合与分裂都会导致线粒体动力学的稳态失衡,引起线粒体功能障碍,导致细胞损伤甚至死亡。肾脏的生理活动主要由线粒体供能,线粒体动力学稳态失衡影响着线粒体功能,与急性肾损伤、糖尿病肾病等肾脏疾病密切相关。本文对线粒体动力学的调节、线粒体动力学稳态失衡如何导致线粒体损伤以及线粒体损伤对肾脏病理生理学的影响进行综述,以加深对肾脏疾病中线粒体作用的理解与认识。     

基因敲除技术及其在研究线粒体动力学与胰岛素抵抗关系中的应用进展

线粒体动力学即线粒体融合和分裂保持动态平衡的过程,该过程由融合/分裂相关蛋白精确调控完成,对于线粒体代谢、质量和功能有着重要的生理意义,而这些蛋白发生异常可引发线粒体动力学失衡,进而引起线粒体功能障碍并引发各种疾病状态。文中围绕基因敲除技术,详细阐述了编码融合/分裂相关蛋白的基因敲除鼠在胰岛素抵抗研究工作中的作用及应用进展,以期为今后研究线粒体动力学失衡致胰岛素抵抗的信号转导机制奠定基础。     

线粒体动力学及线粒体自噬调控机制的研究进展

线粒体形态和功能的异常与多种疾病的发生密切相关。线粒体通过不断的分裂和融合,维持线粒体网络的动态平衡,该过程称为线粒体动力学,是维持线粒体形态、分布和数量,保证细胞稳态的重要基础。此外,机体还通过线粒体自噬过程降解胞内功能异常的线粒体,维持线粒体稳态。线粒体动力学与线粒体自噬二者之间可相互调控,共同维持线粒体质量平衡。探讨线粒体动力学和线粒体自噬的调控机制对揭示多种疾病发生的分子机制、开发新的靶向线粒体动力学蛋白或线粒体自噬调控蛋白的药物具有重要意义。本文从线粒体动力学与线粒体自噬出发,对线粒体动力学调控机制、线粒体自噬及其发生机制以及二者的相互作用关系、线粒体动力学及线粒体自噬与人类相关疾病等方面作一综述。     

线粒体形态学改变与细胞凋亡

近年来,对于线粒体形态学以及其在凋亡过程中的改变和作用的研究打破了传统的观点。正常情况下,线粒体在细胞内相互连接成管网状结构,并发生着频繁的融合与分裂。融合和分裂由一系列蛋白质介导,二者之间的动态平衡维持着线粒体的形态和功能。在细胞凋亡的早期,线粒体融合和分裂失平衡,导致线粒体管网状结构碎裂和嵴的重构,这些改变对线粒体随后的变化以及凋亡的发生具有重要的意义。融合和分裂的蛋白质不仅调控线粒体形态和细胞凋亡过程,也和某些凋亡相关疾病有关。此外,促凋亡的Bcl-2蛋白可能通过改变线粒体的构形来调控凋亡过程。     

线粒体功能缺陷和神经系统疾病

线粒体呼吸链缺陷一直被认为是诱发线粒体疾病的重要因素,这有助于研究人员阐释其遗传和临床多样性。然而,线粒体的其他功能也具有重要意义,包括蛋白质运输、细胞器动力学和细胞凋亡。调控这些功能的基因缺陷不仅导致神经和精神疾病,而且还导致年龄相关的神经变性疾病。因此,引起越来越多的关注。在讨论呼吸链缺陷引起相关神经系统疾病的一些致病难题后,就线粒体动力学改变引起的相关神经系统疾病病因和常见神经变性疾病的病理生理机制作一综述。     

线粒体融合、分裂与神经变性疾病

线粒体是一种处于高度运动状态的频繁地进行融合与分裂的细胞器.在生理状态下,线粒体的融合与分裂处于一种平衡的状态,这种平衡受线粒体融合蛋白1/2（Mfn1/2）、视神经萎缩蛋白1（OPA1）和动力相关蛋白1（Drp1）的调节. Mfn1/2介导线粒体外膜的融合,而OPA1则参与线粒体内膜的融合,这些蛋白受泛素化和蛋白水解的调控. Drp1参与线粒体的分裂过程,受多种翻译后修饰的调节,如磷酸化、泛素化、SUMO化和S 硝基化.对于神经元来说,线粒体融合分裂的动态平衡对保证神经元末梢长距离运输和能量平均分布是非常重要的.因此,线粒体融合分裂异常可能是许多神经变性疾病的致病因素之一.对线粒体融合而言,Mfn2错义突变将导致遗传性运动感觉神经病2型（CMT2A）;OPA1错义突变将引起显性遗传性视神经萎缩(ADOA),而就线粒体分裂而言,Drp1突变与多系统功能障碍的新生儿致死性相关.     

线粒体融合与分裂在中枢神经系统疾病中的研究进展

线粒体是一种高度动态的细胞器,通过不断的融合和分裂维持其动态平衡,参与生理病理功能调节。线粒体融合与分裂主要由融合分裂相关蛋白调控,如Drp1、Fis1、Mfn1、Mfn2、OPA1等,多种诱导因子通过调节线粒体融合分裂相关蛋白表达及活化进而调节线粒体形态和生理功能。现有研究表明线粒体融合分裂的异常可能是许多中枢神经系统疾病的发病机制之一。本文从线粒体融合分裂的分子调控机制及其在缺血性脑中风、帕金森综合征和阿尔兹海默症等中枢神经系统疾病中的研究进展方面进行综述,为相关疾病的防治提供一定参考和线索。     

综述: 与神经退行性疾病相关的RNA结合蛋白在线粒体损伤中的作用

线粒体是细胞内制造能量的细胞器,它还负责各种细胞信号的整合,参与协调多种复杂的细胞功能.线粒体是动态变化的,连续不断地进行分裂与融合,这是其功能维持和增殖遗传的关键.在过去20年中,参与线粒体分裂与融合的核心因子陆续被发现,它们在进化上高度保守,但是在形成分裂与融合复合物中的详细分子机制还有待于深入研究.线粒体分裂与融合的动态变化,是线粒体质量控制的重要组成部分,其动态平衡在细胞发育和稳态维持中起重要作用.线粒体动态变化失衡和功能失调,则会导致多种神经退行性疾病的发生.这些研究的发现为探索线粒体生物学及与疾病的关系开拓了令人振奋的新方向.     

线粒体动力学在糖尿病心肌病中的作用及调节机制

心血管并发症是糖尿病患者死亡的首要原因。其中,糖尿病心肌病是排除了高血压、冠心病所致的心肌损伤后的一类特异性心肌病,其特征在于心肌细胞的代谢异常和心脏功能的逐渐衰退,临床表现为早期心肌舒张功能受损,晚期心肌收缩功能受损,最终发展为心力衰竭。线粒体是心肌细胞内提供能量的主要细胞器,线粒体动力学是指线粒体进行融合和分裂的动态过程,是线粒体质量控制的重要途径,线粒体动力学在维持线粒体稳态与心脏功能中起着至关重要的作用。调节线粒体分裂的蛋白主要是Drp1及其受体Fis1、MFF、MiD49和MiD51,执行线粒体外膜融合的蛋白为Mfn1/2,内膜融合蛋白为Opa1。本文综述了近期在糖尿病心肌病线粒体动力学方面的系列研究成果：1型与2型糖尿病心肌病的线粒体动力学失衡均表现为分裂增加与融合受阻,前者的分子机制主要是Drp1上调与Opa1下调,后者的分子机制主要为Drp1上调与Mfn1/2下调,线粒体分裂增加和融合受阻可导致线粒体功能障碍,促进糖尿病心肌病的发生、发展。中药单体安石榴苷、丹皮酚和内源性物质褪黑素等活性成分可通过抑制线粒体分裂或促进线粒体融合,改善线粒体功能,减轻糖尿病心肌病症状。本文...     

线粒体分裂、融合与细胞凋亡

线粒体是高度动态变化的细胞器,其在细胞内不断分裂、融合并形成网状结构。线粒体的分裂和融合是由多种蛋白质精确调控完成的。Drp1／Dnm1p,Fis1／Fis1p,Caf4p和Mdv1p参与线粒体分裂的调控;Mfn1／2／Fzo1p控制线粒体外膜的融合,而Mgm1p／OPA1则参与线粒体内膜的融合。在细胞凋亡过程中线粒体片段化,网状结构被破坏,线粒体嵴发生重构,抑制这一过程可以部分抑制细胞色素c的释放和细胞凋亡。线粒体形态对于细胞维持正常生理代谢和机体发育起着重要的作用,一旦出现障碍会导致严重的疾病。     

The BH3‐only Bnip3 binds to the dynamin Opa1 to promote mitochondrial fragmentation and apoptosis by distinct mechanisms

Opa1 modulates mitochondrial fusion, cristae structure and apoptosis. The relationships between these functions and autosomal dominant optic atrophy, caused by mutations in Opa1, are poorly defined. We show that Bnip3 interacts with Opa1, leading to mitochondrial fragmentation and apoptosis. Fission is due to inhibition of Opa1‐mediated fusion and is counteracted by Opa1 in an Mfn1‐dependent manner. Bnip3–Opa1 interaction is necessary to trigger Opa1 complex disruption in a Bax‐ and/or Bak‐dependent manner, ultimately leading to apoptosis. Our results uncover a direct link between Opa1 on the inner mitochondrial membrane and the apoptotic machinery on the outer membrane that modulates fusion and cristae structure by separate mechanisms. These findings might help to unravel optic atrophy aetiology as retinal ganglion cells are particularly prone to hypoxia, an inductor of Bnip3 expression.     

有氧运动改善AD模型APP/PS1双转基因小鼠中枢神经元线粒体融合分裂动态平衡

线粒体融合分裂平衡是线粒体动力学的需要。本研究观察12周规律有氧运动对APP/PS1双转基因小鼠中枢神经元线粒体融合分裂动态平衡的影响。本研究采用3月龄雄性APP/PS1小鼠（AD模型）随机分为AD安静组（AS）、AD运动组（AE）,同月龄雄性C57BL/6J小鼠做正常对照组（CS）。AE组进行12周规律跑台运动,5 d/周,60 min/d。前10 min运动速度12 m/min,后50 min运动速度15 m/min,跑台坡度为0°。八臂迷宫实验检测小鼠工作记忆错误频率和参考记忆错误频率;Western印迹检测小鼠皮层、海马组织中线粒体分裂蛋白Drp1和Fis1的含量,以及Drp1的活性（p-Drp1-Ser616）、线粒体融合蛋白Mfn1、Mfn2、Opa1的表达水平;透射电镜观察皮层、海马线粒体形态结构、健康线粒体比率及线粒体平均直径。本研究证实AS组较CS组工作记忆错误频率显著提高（P<0.05）,12周有氧运动显著降低工作记忆错误频率（P<0.05）。AS组小鼠皮层Fis1蛋白和海马脑区Drp1、Fis1蛋白表达水平及皮层、海马脑区Drp1蛋白的活性增加（P<0.05）。而皮层Mfn1和海马Mfn1、Mfn2蛋白表达水平显著降低（P<0.05）。12周有氧运动显著减低Fis1、Drp1蛋白表达及Drp1蛋白的活性,提高Mfn1、Mfn2蛋白表达水平（P<0.05）。AS组小鼠皮层、海马线粒体多呈现球形,部分线粒体膜结构消失,线粒体嵴结构紊乱。且AS组较CS组小鼠健康线粒体比率降低、直径缩短。12周规律有氧运动可明显改善线粒体形态和结构,提高健康线粒体比率及直径。本研究提示,12周规律有氧运动可有效抑制皮层、海马脑区线粒体分裂蛋白Drp1和 Fis1的表达,降低Drp1的活性（p-Drp1-Ser616）,上调线粒体融合蛋白Mfn1、Mfn2的蛋白表达水平,改善线粒体形态和结构以促进线粒体质量控制,是有氧运动改善AD模型空间学习记忆能力的分子机制之一。     

Mitochondrial dynamic alterations regulate melanoma cell progression

Research on mitochondrial fusion and fission (mitochondrial dynamics) has gained much attention in recent years, as it is important for understanding many biological processes, including the maintenance of mitochondrial functions, apoptosis, and cancer. The rate of mitochondrial biosynthesis and degradation can affect various aspects of tumor progression. However, the role of mitochondrial dynamics in melanoma progression remains controversial and requires a mechanistic understanding to target the altered metabolism of cancer cells. Therefore, in our study, we disrupted mitochondrial fission with mdivi-1, the reported inhibitor of dynamin related protein 1 (Drp1), and knocked down Drp1 and Mfn2 to evaluate the effects of mitochondrial dynamic alterations on melanoma cell progression. Our confocal study results showed that mitochondrial fission was inhibited both in mdivi-1 and in Drp1 knockdown cells and, in parallel, mitochondrial fusion was induced. We also found that mitochondrial fission inhibition by mdivi-1 induced cell death in melanoma cells. However, silencing Drp1 and Mfn2 did not affect cell viability, but enhanced melanoma cell migration. We further show that dysregulated mitochondrial fusion by Mfn2 knockdowns suppressed the oxygen consumption rate of melanoma cells. Together, our findings suggest that mitochondrial dynamic alterations regulate melanoma cell migration and progression.     

Mfn2 is critical for brown adipose tissue thermogenic function

Mitochondrial fusion and fission events, collectively known as mitochondrial dynamics, act as quality control mechanisms to ensure mitochondrial function and fine‐tune cellular bioenergetics. Defective mitofusin 2 (Mfn2) expression and enhanced mitochondrial fission in skeletal muscle are hallmarks of insulin‐resistant states. Interestingly, Mfn2 is highly expressed in brown adipose tissue (BAT), yet its role remains unexplored. Using adipose‐specific Mfn2 knockout (Mfn2‐adKO) mice, we demonstrate that Mfn2, but not Mfn1, deficiency in BAT leads to a profound BAT dysfunction, associated with impaired respiratory capacity and a blunted response to adrenergic stimuli. Importantly, Mfn2 directly interacts with perilipin 1, facilitating the interaction between the mitochondria and the lipid droplet in response to adrenergic stimulation. Surprisingly, Mfn2‐adKO mice were protected from high‐fat diet‐induced insulin resistance and hepatic steatosis. Altogether, these results demonstrate that Mfn2 is a mediator of mitochondria to lipid droplet interactions, influencing lipolytic processes and whole‐body energy homeostasis.     

Control of mitochondrial morphology through differential interactions of mitochondrial fusion and fission proteins

Mitochondria in mammals are organized into tubular networks that undergo frequent shape change. Mitochondrial fission and fusion are the main components mediating the mitochondrial shape change. Perturbation of the fission/fusion balance is associated with many disease conditions. However, underlying mechanisms of the fission/fusion balance are not well understood. Mitochondrial fission in mammals requires the dynamin-like protein DLP1/Drp1 that is recruited to the mitochondrial surface, possibly through the membrane-anchored protein Fis1 or Mff. Additional dynamin-related GTPases, mitofusin (Mfn) and OPA1, are associated with the outer and inner mitochondrial membranes, respectively, and mediate fusion of the respective membranes. In this study, we found that two heptad-repeat regions (HR1 and HR2) of Mfn2 interact with each other, and that Mfn2 also interacts with the fission protein DLP1. The association of the two heptad-repeats of Mfn2 is fusion inhibitory whereas a positive role of the Mfn2/DLP1 interaction in mitochondrial fusion is suggested. Our results imply that the differential binding of Mfn2-HR1 to HR2 and DLP1 regulates mitochondrial fusion and that DLP1 may act as a regulatory factor for efficient execution of both fusion and fission of mitochondria.     

Structure,function, and regulation of mitofusin‐2 in health and disease

Mitochondria are highly dynamic organelles that constantly migrate, fuse, and divide to regulate their shape, size, number, and bioenergetic function. Mitofusins (Mfn1/2), optic atrophy 1 (OPA1), and dynamin‐related protein 1 (Drp1), are key regulators of mitochondrial fusion and fission. Mutations in these molecules are associated with severe neurodegenerative and non‐neurological diseases pointing to the importance of functional mitochondrial dynamics in normal cell physiology. In recent years, significant progress has been made in our understanding of mitochondrial dynamics, which has raised interest in defining the physiological roles of key regulators of fusion and fission and led to the identification of additional functions of Mfn2 in mitochondrial metabolism, cell signalling, and apoptosis. In this review, we summarize the current knowledge of the structural and functional properties of Mfn2 as well as its regulation in different tissues, and also discuss the consequences of aberrant Mfn2 expression.     

Hormone‐induced mitochondrial fission is utilized by brown adipocytes as an amplification pathway for energy expenditure

Adrenergic stimulation of brown adipocytes (BA) induces mitochondrial uncoupling, thereby increasing energy expenditure by shifting nutrient oxidation towards thermogenesis. Here we describe that mitochondrial dynamics is a physiological regulator of adrenergically‐induced changes in energy expenditure. The sympathetic neurotransmitter Norepinephrine (NE) induced complete and rapid mitochondrial fragmentation in BA, characterized by Drp1 phosphorylation and Opa1 cleavage. Mechanistically, NE‐mediated Drp1 phosphorylation was dependent on Protein Kinase‐A (PKA) activity, whereas Opa1 cleavage required mitochondrial depolarization mediated by FFAs released as a result of lipolysis. This change in mitochondrial architecture was observed both in primary cultures and brown adipose tissue from cold‐exposed mice. Mitochondrial uncoupling induced by NE in brown adipocytes was reduced by inhibition of mitochondrial fission through transient Drp1 DN overexpression. Furthermore, forced mitochondrial fragmentation in BA through Mfn2 knock down increased the capacity of exogenous FFAs to increase energy expenditure. These results suggest that, in addition to its ability to stimulate lipolysis, NE induces energy expenditure in BA by promoting mitochondrial fragmentation. Together these data reveal that adrenergically‐induced changes to mitochondrial dynamics are required for BA thermogenic activation and for the control of energy expenditure.     

SIRT2抑制对MPP+诱导的帕金森病细胞模型凋亡和线粒体动态平衡的影响*

探究siRNA敲减沉默信息调节因子2(SIRT2)对1-甲基-4-苯基吡啶离子(MPP⁺)诱导的帕金森病细胞模型细胞损伤的影响和机制。CCK-8法检测不同浓度MPP⁺处理对体外培养小鼠海马神经元HT-22细胞生存率的影响。将细胞分为对照组、MPP⁺最佳浓度处理组(1 mmol/L MPP⁺处理组)、阴性转染组(对照组基础上转染SIRT2阴性序列)、SIRT2 siRNA处理组(损伤组基础上转染SIRT2 siRNA)。观察各组细胞凋亡情况,检测凋亡相关蛋白(Bcl-2、Bax、Caspase-9)、线粒体分裂及融合相关蛋白(Drp1、Fis1、OPA1、Mfn1、Mfn2)。与对照组相比,MPP⁺处理组细胞抑制率均升高,细胞抑制率随MPP⁺浓度增加而逐渐增加(P<0.05)。与SIRT2 siRNA转染组相比,损伤组Bax、Caspase-9、Drp1、Fis1蛋白表达和细胞凋亡率升高,Bcl-2、Mfn1、Mfn2蛋白表达降低(P<0.05)。SIRT2在MPP⁺诱导帕金森病细胞模型中表达升高,抑制SIRT2可减轻MPP⁺诱导帕金森病细胞模型中细胞凋亡并促进线粒体融合,从而对神经元具有一定的保护作用。