PGC-1α与线粒体O生成调控在心血管疾病中的作用

线粒体是一类高度活跃的细胞器,在细胞能量代谢等生命活动中具有重要的作用。线粒体生成,即线粒体的增殖以及线粒体系统合成和个体合成的过程。近年来研究提示,线粒体生成与线粒体的功能调节密切相关,而过氧化物酶体增殖物激活受体γ辅激活因子-1α(peroxisome proliferator-ac-tivated receptor gamma co-activator,PGC-1α)可能是线粒体生成的关键调控因子。特别是在心血管系统中,PGC-1α信号途径调控的线粒体生成可能是维持和修复心肌细胞和血管内皮细胞等心血管系统细胞线粒体功能的主要机制之一,在心力衰竭、心肌肥大、糖尿病心血管并发症等心血管疾病的发生与发展过程中具有重要作用。PGC-1α作为心血管疾病疾病预防和治疗的潜在靶标,将有可能为心血管疾病的防治提供新的策略。     

Activating mitochondrial regulator PGC-1α expression by astrocytic NGF is a therapeutic strategy for Huntington's disease

Mitochondrial dysfunction plays an important role in Huntington's disease (HD). NGF gene delivery in AD patients showed an increase in brain energy metabolism and NGF has been shown neuroprotective effects against mitochondrial toxins. However, the role of NGF in regulating mitochondrial function is unclear. Here, we found that NGF-stimulated mitochondrial biogenesis in PC12 and primary neuron cells. Our results demonstrated that peroxisome proliferator-activated receptor gamma coactivator 1-α (PGC-1α) is a downstream key target of the NGF signalling pathway. In a 3-nitropropionic acid (3-NP) cell model, NGF treatment rescued the defects in mitochondrial activity and mitochondrial membrane potential. Since NGF cannot freely cross blood-brain barrier, we found an astrocytic NGF inducer, Ganoderma lucidum (GaLu) extract. Its active constituents had potent effects on the induction of NGF in primary astrocytes. Among the identified ingredients, ganoderic acid C(2) was most effective. We further found that GaLu-conditioned media can enhance mitochondrial biogenesis in PC12 cells and preventing NGF signalling using NGF antibody or PGC-1α siRNA blocked these effects. Moreover, GaLu and ganoderic acid C(2)-conditioned media treatment attenuated mitochondrial defects in 3-NP cell model. After 3-NP-induced behavioural impairment and striatal degeneration in mice, GaLu treatment therapeutically restored the behaviour score, sensorimotor ability and neuronal loss. We found that striatal NGF, PGC-1α expression level and succinate dehydrogenase activity were recovered in GaLu-fed mice. These results suggest that the NGF-signalling pathway connected to the mitochondrial regulator, PGC-1α, expression. This signalling triggered by astrocytic NGF with small molecule inducers may offer a therapeutic strategy for HD.     

AMPK activator acadesine fails to alleviate isoniazid‐caused mitochondrial instability in HepG2 cells

Isoniazid (INH) is a first‐line antituberculosis drug that is adversely associated with hepatotoxicity. Recently, impairment of mitochondrial homeostasis involved in this side effect has been noticed. Mitochondrial homeostasis is achieved by the balance between the generation of functional mitochondria by biogenesis and elimination of dysfunctional mitochondria by autophagy. AMP‐activated protein kinase (AMPK) can maintain mitochondrial stability through positive control of these two processes. In this study, we showed that AMPK activator acadesine (AICAR) alleviated INH‐caused impairment of mitochondrial biogenesis by activation of silent information regulator two ortholog 1 (SIRT1)–peroxisome proliferator‐activated receptor γ coactivator 1α (PGC1 α) pathway in HepG2 cells. However, mitochondrial instability and apoptosis were caused by AICAR along with an unexpected decrease in INH‐induced cytoprotective autophagy. Therefore, AICAR failed to alleviate INH‐caused mitochondrial instability in HepG2 cells due to its inhibitory effect on autophagy induced by INH. Copyright © 2017 John Wiley & Sons, Ltd.     

Effects of Low Concentrations of Rotenone upon Mitohormesis in SH-SY5Y Cells

The mitochondrial toxin rotenone exerts cytotoxicity via overproduction of reactive oxygen species (ROS) and depolarization of the mitochondrial membrane. We investigated the effects of rotenone (12.5, 25, 50, 100 nmol/L) on mitochondrial biogenesis and the potential roles of ROS production in SH-SY5Y cells. Mitochondrial biogenesis was assessed by counting the number of mitochondria, determining protein expression of peroxisome proliferator-activated receptor γ coactivator α (PGC1-α) and its regulator, SIRT1, and oxygen consumption. ROS production and levels of reduced glutathione (GSH) and oxidized glutathione (GSSG) were also determined. Compared with controls, rotenone (12.5 nmol/L) significantly increased the quantity of mitochondria and amount of oxygen consumption, whereas rotenone at >12.5 nmol/L decreased the quantity of mitochondria and amount of oxygen consumption. GSH contents and GSH/GSSG were also significantly enhanced by rotenone at 12.5 nmol/L and decreased by rotenone at >12.5 nmol/L. Except for ROS production and SIRT1 protein expression, all concentration–response relationships showed a typical inverted-U shape. ROS production was continually increased in cells treated with rotenone. These data indicate that low concentrations of rotenone can induce mitohormesis, which may be attributed to ROS production.     

Troglitazone induces cytotoxicity in part by promoting the degradation of peroxisome proliferator-activated receptor �� co-activator-1�� protein

BACKGROUND AND PURPOSE

Troglitazone (Tro), rosiglitazone (Rosi) and pioglitazone (Pio) are anti-diabetic thiazolidinediones that function as ligands for peroxisome proliferator-activated receptor γ (PPARγ); however, Tro has been withdrawn from the market due to liver toxicity issues. Mitochondrial dysfunction induced by Tro has been suggested to be an important mechanism behind its cytotoxicity. Constitutively active nuclear hormone receptors, oestrogen-related receptor α and γ are thought to regulate mitochondrial mass and oxidative phosphorylation together with their co-activators PPARγ co-activator-1α and -1β (PGC-1α and PGC-1β). Hence, in this study, we investigated whether Tro affects the expression and activity levels of these regulators.

EXPERIMENTAL APPROACH

Cellular viability was measured by an ATP-based assay. Mitochondrial mass and reactive oxygen species (ROS) were quantified by two different fluorogenic probes. Apoptosis was measured by an Annexin-V-based kit. Gene expression at the levels of mRNA and protein was measured by quantitative RT-PCR and Western analysis. Over-expression of PGC-1α was mediated by an adenovirus.

KEY RESULTS

Tro, but not Rosi or Pio, selectively stimulated PGC-1α protein degradation. As a result, Tro reduced mitochondrial mass, and superoxide dismutases 1 and 2 expressions, but induced ROS to initiate apoptosis. Using a ubiquitin–proteasome inhibitor MG132, it was established that blocking PGC-1α degradation partially suppressed the reduction of mitochondrial mass. Importantly, over-expressing PGC-1α partially restored the Tro-suppressed mitochondrial mass and attenuated the cytotoxic effects of Tro.

CONCLUSIONS AND IMPLICATIONS

Collectively, these results suggest that PGC-1α degradation is an important mechanism behind the cytotoxic effects of Tro in the liver.     

Defective mitochondrial function and motility due to mitofusin 1 overexpression in insulin secreting cells

Mitochondrial dynamics and distribution is critical for their role in bioenergetics and cell survival. We investigated the consequence of altered fission/fusion on mitochondrial function and motility in INS-1E rat clonal β-cells. Adenoviruses were used to induce doxycycline-dependent expression of wild type (WT-Mfn1) or a dominant negative mitofusin 1 mutant (DN-Mfn1). Mitochondrial morphology and motility were analyzed by monitoring mitochondrially-targeted red fluorescent protein. Adenovirus-driven overexpression of WT-Mfn1 elicited severe aggregation of mitochondria, preventing them from reaching peripheral near plasma membrane areas of the cell. Overexpression of DN-Mfn1 resulted in fragmented mitochondria with widespread cytosolic distribution. WT-Mfn1 overexpression impaired mitochondrial function as glucose- and oligomycin-induced mitochondrial hyperpolarization were markedly reduced. Viability of the INS-1E cells, however, was not affected. Mitochondrial motility was significantly reduced in WT-Mfn1 overexpressing cells. Conversely, fragmented mitochondria in DN-Mfn1 overexpressing cells showed more vigorous movement than mitochondria in control cells. Movement of these mitochondria was also less microtubule-dependent. These results suggest that Mfn1-induced hyperfusion leads to mitochondrial dysfunction and hypomotility, which may explain impaired metabolism-secretion coupling in insulin-releasing cells overexpressing Mfn1.     

Targeting mitochondrial biogenesis for preventing and treating insulin resistance in diabetes and obesity: Hope from natural mitochondrial nutrients

Insulin resistance is an important feature of type 2 diabetes and obesity. The underlying mechanisms of insulin resistance are still unclear and may involve pathological changes in multiple tissues. Mitochondrial dysfunction, including mitochondrial loss and over-production of oxidants, has been suggested to be involved in the development of insulin resistance. Increasing evidence suggests that targeting mitochondria to protect mitochondrial function as a unique measure, i.e. mitochondrial medicine, could prevent and ameliorate various diseases associated with mitochondrial dysfunction. In this review, we have summarized recent progress in pharmaceutical and nutritional studies of drugs and nutrients to targeting mitochondria by stimulating mitochondrial metabolism (biogenesis and degradation) to improve mitochondrial function and decrease oxidative stress for preventing and ameliorating insulin resistance. We have focused on nutrients from natural sources to stimulating mitochondrial biogenesis in cellular systems and in animal models. The in vitro and in vivo studies, especially our own work on the effects and mechanisms of mitochondrial targeting nutrients or their combinations, may help us to understand the importance and mechanisms of mitochondrial biogenesis in insulin resistance, and provide hope for developing mitochondria-targeting agents for preventing and treating insulin resistance in type 2 diabetes and obesity.     

Melatonin prevents blood-retinal barrier breakdown and mitochondrial dysfunction in high glucose and hypoxia-induced in vitro diabetic macular edema model

Diabetic macular edema (DME) is a leading cause of blindness in diabetic retinopathy. Prolonged hyperglycemia plus hypoxia contributes to DME pathogenesis. Retinal pigmented epithelial cells comprise the outer blood-retinal barrier and are essential for maintaining physiological functioning of the retina. Melatonin acts as an antioxidant and regulator of mitochondrial bioenergetics and has a protective effect against ocular diseases. However, the role of mitochondrial dysfunction and the therapeutic potential of melatonin in DME remain largely unexplored. Here, we used an in vitro model of DME to investigate blood-retinal barrier integrity and permeability, angiogenesis, mitochondrial dynamics, and apoptosis signaling to evaluate the potential protective efficacy of melatonin in DME. We found that melatonin prevents cell hyper-permeability and outer barrier breakdown by reducing HIF-1α, HIF-1β and VEGF and VEGF receptor gene expression. In addition, melatonin reduced the expression of genes involved in mitochondrial fission (DRP1, hFis1, MIEF2, MFF), mitophagy (PINK, BNip3, NIX), and increased the expression of genes involved in mitochondrial biogenesis (PGC-1α, NRF2, PPAR-γ) to maintain mitochondrial homeostasis. Moreover, melatonin prevented apoptosis of retinal pigmented epithelial cells. Our results suggest that mitochondrial dysfunction may be involved in DME pathology, and melatonin may have therapeutic value in DME, by targeting signaling in mitochondria.     

Pretreatment with Tilianin improves mitochondrial energy metabolism and oxidative stress in rats with myocardial ischemia/reperfusion injury via AMPK/SIRT1/PGC-1 alpha signaling pathway

Mitochondrial energy metabolism and oxidative stress play a crucial role in ameliorating myocardial ischemia/reperfusion injury (MIRI). Tilianin has been reported to have a significant protection for mitochondrion in MIRI. However, the underlying mechanisms remain unknown. This study investigated whether Tilianin regulates mitochondrial energy metabolism and oxidative stress in MIRI via AMPK/SIRT1/PGC-1 alpha signaling pathway. The MIRI model was established by 30 min of coronary occlusion followed by 2 h of reperfusion in rats. The results revealed that Tilianin significantly reduced myocardial infarction, improved the pathological morphology of myocardium, markedly increased the contents of ATP and NAD⁺, decreased ADP and AMP contents and the ratio of AMP/ATP, reduced the level of ROS and MDA, enhanced SOD activity, evidently increased the levels of AMPK, SIRT1 and PGC-1 alpha mRNA, up-regulated the expressions of AMPK, pAMPK, SIRT1, PGC-1alpha, NRF1, TFAM and FOXO1 proteins. However, these effects were respectively abolished by Compound C (a specific AMPK inhibitor) and EX-527 (a specific SIRT1 inhibitor). Taken together, this study found that Tilianin could attenuate MIRI by improving mitochondrial energy metabolism and reducing oxidative stress via AMPK/SIRT1/PGC-1 alpha signaling pathway.     

白藜芦醇通过上调小鼠胚胎干细胞过氧化物酶体增殖激活受体γ共激活子1α表达促进其分化为心肌细胞

目的观察白藜芦醇对小鼠胚胎干细胞(ESC)分化为心肌细胞的调节作用,并探讨其机制。方法 采用悬滴悬浮培养法培养ESC。白藜芦醇0.44,4.4和44μmo.lL-1处理ESC 96 h。光学显微镜下记录每组自发心肌搏动数;透射电镜观察细胞内线粒体结构;实时PCR方法测定α-肌球蛋白重链(α-MHC)、过氧化物酶体增殖物激活受体γ(PPARγ)、PPARγ共激活子1α(PGC-1α),核呼吸因子-1(NRF-1)、线粒体转录因子A(mtTFA)和线粒体呼吸链复合体Ⅳ(COXⅣ)的基因表达;Western蛋白印迹法检测PPARγ,α辅肌动蛋白和PGC-1α蛋白表达。结果 与正常对照组相比,白藜芦醇0.44和4.4μmo.l L-1可增加ESC细胞分化为自发搏动的心肌细胞数,并明显上调分化的ESC心肌特异性基因α-MHC表达,约分别为正常对照组的5.6和3.7倍;上调心肌细胞特定标识蛋白α辅肌动蛋白的表达,约为正常对照组的1.7和2.1倍;提示白藜芦醇可以促进ESC分化为心肌细胞。白藜芦醇干预各组均可上调PPARγ基因和蛋白表达,同时白藜芦醇0.44和4.4μmo.lL-1可以明显上调线粒体生物合成相关因子基因表达;白藜芦醇4.4μmo.lL-1处理组线粒体数目增多,提示线粒体生物合成可能是ESC分化为心肌细胞的重要机制。结论 白藜芦醇可以通过激动PPARγ受体并上调由PGC-1α介导的线粒体生物合成,从而促进ESC分化为心肌细胞。     

Turn up the power –pharmacological activation of mitochondrial biogenesis in mouse models

The oxidative phosphorylation (OXPHOS) system in mitochondria is responsible for the generation of the majority of cellular energy in the form of ATP. Patients with genetic OXPHOS disorders form the largest group of inborn errors of metabolism. Unfortunately, there is still a lack of efficient therapies for these disorders other than management of symptoms. Developing therapies has been complicated because, although the total group of OXPHOS patients is relatively large, there is enormous clinical and genetic heterogeneity within this patient population. Thus there has been a lot of interest in generating relevant mouse models for the different kinds of OXPHOS disorders. The most common treatment strategies tested in these mouse models have aimed to up-regulate mitochondrial biogenesis, in order to increase the residual OXPHOS activity present in affected animals and thereby to ameliorate the energy deficiency. Drugs such as bezafibrate, resveratrol and AICAR target the master regulator of mitochondrial biogenesis PGC-1α either directly or indirectly to manipulate mitochondrial metabolism. This review will summarize the outcome of preclinical treatment trials with these drugs in mouse models of OXPHOS disorders and discuss similar treatments in a number of mouse models of common diseases in which pathology is closely linked to mitochondrial dysfunction. In the majority of these studies the pharmacological activation of the PGC-1α axis shows true potential as therapy; however, other effects besides mitochondrial biogenesis may be contributing to this as well.

Linked Articles

This article is part of a themed issue on Mitochondrial Pharmacology: Energy, Injury & Beyond. To view the other articles in this issue visit http://dx.doi.org/10.1111/bph.2014.171.issue-8     

Mitochondrial biogenesis in cardiac pathophysiology

Cardiac performance depends on a fine balance between the work the heart has to perform to satisfy the needs of the body and the energy that it is able to produce. Thus, energy production by oxidative metabolism, the main energy source of the cardiac muscle, has to be strictly regulated to adapt to cardiac work. Mitochondrial biogenesis is the mechanism responsible for mitochondrial component synthesis and assembly. This process controls mitochondrial content and thus correlates with energy production that, in turn, sustains cardiac contractility. Mitochondrial biogenesis should be finely controlled to match cardiac growth and cardiac work. When the heart is subjected to an increase in work in response to physiological and pathological challenges, it adapts by increasing its mass and expressing a new genetic program. In response to physiological stimuli such as endurance training, mitochondrial biogenesis seems to follow a program involving increased cardiac mass. But in the context of pathological hypertrophy, the modifications of this mechanism remain unclear. What appears clear is that mitochondrial biogenesis is altered in heart failure, and the imbalance between cardiac work demand and energy production represents a major factor in the development of heart failure.     

HIF-1α and HIF-2α are critically involved in hypoxia-induced lipid accumulation in hepatocytes through reducing PGC-1α-mediated fatty acid β-oxidation

During periods of cellular hypoxia, hepatocytes adapt to consume less oxygen by shifting energy production from mitochondrial fatty acid β-oxidation to glycolysis. One of the earliest responses to pathologic hypoxia is the activation of the hypoxia-inducible factor (HIF). In the present study, we examined whether HIF-1 and HIF-2 were involved in the regulation of fatty acid synthesis and β-oxidation. We showed that hypoxia induced fat accumulation in the livers of mice and in HepG2 cells. These hypoxia-induced changes in fatty acid metabolism were mediated by suppressing fatty acid β-oxidation, without significantly influencing fatty acid synthesis. Exposing hepatocytes to 1% O₂ reduced the mRNA expression of carnitine palmitoyltransferase 1 (CPT-1), which catalyzes the rate-limiting step in the mitochondrial import of fatty acids for β-oxidation. Moreover, hypoxia exposure reduced proliferator-activated receptor-γ coactivator-1α (PGC-1α) protein levels, which plays an important role in regulation of β-oxidation. Exposure of HIF-1α or HIF-2α deficient hepatocytes to hypoxia abrogated the reduction in PGC-1α and CPT-1 expression and cellular lipid accumulation observed in normal hepatocytes exposed to hypoxia. These results suggest that both HIF-1α and HIF-2α are involved in hypoxia-induced lipid accumulation in hepatocytes via reducing PGC-1α mediated fatty acid β-oxidation.