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Background: Oxidative stress-induced mitochondrial damage is the major cause of cardiomyocyte dysfunction. Therefore, the maintenance of mitochondrial function, which is regulated by mitochondrial quality control (MQC), is necessary for cardiomyocyte homeostasis. This study aimed to explore the underlying mechanisms of N-acetylcysteine (NAC) function and its relationship with MQC. Methods: A hydrogen peroxide-induced oxidative stress model was established using H9c2 cardiomyocytes treated with or without NAC prior to oxidative stress stimulation. Autophagy with light chain 3 (LC3)-green fluorescent protein (GFP) assay, reactive oxygen species (ROS) with the 2',7'-dichlorodi hydrofluorescein diacetate (DCFH-DA) fluorescent, lactate dehydrogenase (LDH) release assay, adenosine triphosphate (ATP) content assay, and a mitochondrial membrane potential detection were used to evaluate mitochondrial dynamics in H2O2-treated H9c2 cardiomyocytes, with a focus on the involvement of MQC regulated by NAC. Cell apoptosis was analyzed using caspase-3 activity assay and Annexin V-fluorescein isothiocyanate (V-FITC)/propidium iodide (PI) double staining. Results: We observed that NAC improved cell viability, reduced ROS levels, and partially restored optic atrophy 1 (OPA1) protein expression under oxidative stress. Following transfection with a specific OPA1-small interfering RNA, the mitophagy, mitochondrial dynamics, mitochondrial functions, and cardiomyocyte apoptosis were evaluated to further explore the mechanisms of NAC. Our results demonstrated that NAC attenuated cardiomyocyte apoptosis via the ROS/OPA1 axis and protected against oxidative stress-induced mitochondrial damage via the regulation of OPA1-mediated MQC. Conclusions: NAC ameliorated the injury to H9c2 cardiomyocytes caused by H2O2 by promoting the expression of OPA1, consequently improving mitochondrial function and decreasing apoptosis.
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OPA1 is a dynamin-related GTPase that modulates various mitochondrial functions and is involved in mitochondrial morphology. There are eight different isoforms of OPA1 in humans and five different isoforms in mice that are expressed as short or long-form isoforms. These isoforms contribute to OPA1's ability to control mitochondrial functions. However, isolating OPA1 all long and short isoforms through western blot has been a difficult task. To address this issue, we outline an optimized western blot protocol to isolate 5 different isoforms of OPA1 on the basis of different antibodies. This protocol can be used to study changes in mitochondrial structure and function.
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Bicalutamide (Bic) is an androgen deprivation therapy (ADT) for treating prostate cancer, while ADT is potentially associated with acute kidney injury. Previously, we recognized Bic induced renal mitochondria dysfunction in vitro and in vivo via the ROS -HIF1α pathway. Whether OXPHOS complex, as well as mitochondrial dynamics, can be influenced by Bic via modulation of peroxisome proliferator-activated receptor coactivator 1α (PGC1α), NADPH oxidase 4 (Nox4), mitofusins 1/2 (MFN 1/2), optic atrophy 1 (OPA1), and sirtuins (SIRTs) has not been documented. Renal mesangial cell line was treated with Bic (30~60 µM) for the indicated time. SIRTs, complex I, mitochondrial dynamics- and oxidative stress-related proteins were analyzed. Bic dose-dependently reduced mitochondrial potential, but dose- and time-dependently suppressed translocase of the outer mitochondrial membrane member 20 (Tomm 20), complex I activity. Nox4 and glutathione lead to decreased NAD+/NADH ratio, with upregulated superoxide dismutase 2. SIRT1 was initially stimulated and then suppressed, while SIRT3 was time- and dose-dependently downregulated. PGC1α, MFN2, and OPA1 were all upregulated, with MFN1 and pro-fission dynamin-related protein I downregulated. Bic exhibits potential to damage mitochondria via destroying complex I, complex I activity, and mitochondrial dynamics. Long-term treatment with Bic should be carefully followed up.
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Objective:To explore the mechanism of energy changes in the three stages of the formation of coronary heart disease due to blood stasis in rat model from the perspective of mitochondrial fusion-fission dynamic changes. Method:Thirty healthy male rats were divided into the blank control group (<italic>n</italic>=6) and model group (<italic>n</italic>=24) using SPSS 21.0 simple random sampling method. The rats in the blank control group were fed an ordinary diet, while those in the model group a high-fat diet. After seven days of adaptive feeding, the rats were treated with intragastric administration of vitamin D<sub>3</sub> (VitD<sub>3</sub>) at 300 000 U·kg<sup>-1</sup> and then at 200 000 U·kg<sup>-1</sup> 14 d later. The high-fat diet continued for 21 d, and six rats were randomly selected as samples for the pre-stage blood stasis syndrome group, followed by model verification and sampling. The remaining rats continued to receive the high-fat diet for 30 d, and six were randomly selected and categorized into the sub-stage blood stasis syndrome group, followed by model verification and sampling. The rest of rats were classified into the heart blood stasis syndrome group. While continuing the high-fat diet, they were also treated with multipoint subcutaneous injection of isoproterenol (ISO,5 mg·kg<sup>-1</sup>) for three consecutive days. One week later, the electrocardiogram (ECG) was recorded for determining whether the modeling was successful and the samples were taken at the same time. The changes in mitochondrial morphology and quantity were observed under a transmission electron microscope. The expression of mitochondrial dynamics-related proteins was measured by Western blot and the cellular localization of related proteins by immunofluorescence assay. Result:The levels of total cholesterol and low-density lipoprotein cholesterol in the pre-stage and sub-stage blood stasis syndrome groups were significantly increased as compared with those in the blank control group (<italic>P</italic><0.05). The blood rheology index in the pre-stage blood stasis syndrome group was significantly elevated in contrast to that in the blank control group (<italic>P</italic><0.05). The three-layered membrane of the aorta in the blank group was intact. However, the tunica media of the pre-stage blood stasis syndrome group began to show obvious calcification, with a small number of inflammatory cells adhering to the intima. The subintima and media smooth muscles in the sub-stage blood stasis syndrome group exhibited cavity structures. The three-layered structure of the arterial wall in the heart blood stasis syndrome group was severely damaged. The ECG of the blank control group revealed the regular appearance of P wave,regular QRS waveform (no broadening or deformity), and no obvious ST-segment depression or elevation. The ECG of the pre-stage blood stasis syndrome group showed no obvious abnormalities as compared with that of the blank control group. In the sub-stage blood stasis syndrome group, the ECG showed an upward trend of the J point and slight ST-segment elevation, with the elevation≤0.1 mV. The ECG in the heart blood stasis syndrome group displayed significant ST-segment depression (>0.1 mV) and J point depression >0.1 mV. The mitochondria in the blank control group were normal in size and morphology, with clear and dense cristae, whereas those in the pre-stage blood stasis syndrome group were fusiform with sparse cristae. Some mitochondria in the sub-stage blood stasis syndrome group were significantly elongated, and even vacuole-like changes were present. In the heart blood stasis syndrome group, the mitochondria were ruptured. As demonstrated by comparison with the blank control group, the expression levels of mitofusin 2 (Mfn2), dynamin-related protein 1 (Drp1), and fission protein 1 (Fis1) in the model group were significantly up-regulated (<italic>P</italic><0.05,<italic>P</italic><0.01). Compared with the pre-stage blood stasis syndrome group, the heart blood stasis syndrome group exhibited down-regulated Mfn2 (<italic>P<</italic>0.05). Compared with the blank control group and the pre-stage blood stasis syndrome group, the sub-stage blood stasis syndrome group and the heart blood stasis syndrome group displayed down-regulated optic atrophy 1(OPA1) (<italic>P</italic><0.05,<italic>P</italic><0.01). The Drp1 and Fis1 protein expression declined significantly in the sub-stage blood stasis syndrome group in comparison with that in the pre-stage blood stasis syndrome group (<italic>P</italic><0.05,<italic>P</italic><0.01). The expression levels of Mfn2 and Drp1 in the heart blood stasis syndrome group were lower than those in the sub-stage blood stasis syndrome group (<italic>P<</italic>0.01). The comparison with the blank control group showed that Mfn2 and OPA1 were extensively accumulated in mitochondria of both the pre-stage and sub-stage blood stasis syndrome groups, while the red-stained Mfn2 was significantly reduced in the heart blood stasis syndrome group. The Drp1/Fis1 fluorescence was weak in the blank group and the pre-stage blood stasis syndrome group but strong in the sub-stage blood stasis syndrome group and heart blood stasis syndrome group. Conclusion:The cardiomyocyte mitochondria dynamics changes with the change in energy demand of cardiomyocytes. Mfn2 is dominated by fusion effect in the early stage of the formation of coronary heart disease due to blood stasis. With the gradual development of this disease, Mfn2 begins to mediate mitochondrial autophagy. OPA1 plays a role in intimal fusion and cristae integrity. The decreased OPA1 expression is closely related to the accelerated progression of coronary heart disease differentiated into blood stasis syndrome. The process by which Drp1 and Fis1 separate damaged mitochondria to prepare for mitochondrial autophagy contributes to alleviating the imbalance between the energy demand and supply of human body.
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Prohibitin 2 (PHB2), an inner mitochondrial membrane (IMM) protein, has recently been identified as a novel receptor involved in parkin-mediated mitophagy. In the field of veterinary medicine, the role of PHB2 in parkin-mediated mitophagy was described, for the first time, in urothelial cells of cattle, naturally infected with bovine papillomavirus (BPV). The BPV2 and BPV13 E5 oncoprotein, responsible for abortive infections in urothelial cells, was detected by RT-PCR. Severe ultrastructural abnormalities of the inner mitochondrial membrane were detected using transmission electron microscopy. PHB2 formed a functional complex with PHB1. PHB2 was significantly overexpressed in mitochondrial fractions from urothelial mucosa samples taken from cattle harbouring BPV infection. PHB2 overexpression could be attributed to mitochondrial dysfunction, as its expression levels in the cytosolic, microsomal, and nuclear fractions were seen to be unmodified. Immunoprecipitation studies revealed the interaction between PHB2 and phosphorylated forms of both PINK1 and parkin. Furthermore, PHB2 interacted with LC3-II, a marker of autophagosomal membranes and autophagy receptors, such as p62 and optineurin. PHB2 was shown to interact with transcription factor EB (TFEB), which is activated following parkin-mediated mitophagy, and embryonic stem cell-expressed Ras (ERAS), a constitutive protein coded by ERas. Western blot analysis revealed a significant overexpression of unphosphorylated TFEB in mitochondrial and nuclear fractions from urothelial mucosa samples from cattle suffering from BPV infection. Finally, PHB2 interacted with ERAS, believed to be involved in mitophagosome maturation. Taken together, the molecular and ultrastructural findings of this study suggested that BPV infection is responsible for parkin-dependent mitophagy, in the pathway of which PHB2 plays a crucial role.
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Mitochondria are highly dynamic organelles, which move and fuse to regulate their shape, size, and fundamental function. The dynamin-related GTPases play a critical role in mitochondrial membrane fusion. In vitro reconstitution of membrane fusion using recombinant proteins and model membranes is quite useful in elucidating the molecular mechanisms underlying membrane fusion and to identify the essential elements involved in fusion. However, only a few reconstituting approaches have been reported for mitochondrial fusion machinery due to the difficulty of preparing active recombinant mitochondrial fusion GTPases. Recently, we succeeded in preparing a sufficient amount of recombinant OPA1 involved in mitochondrial inner membrane fusion using a BmNPV bacmid-silkworm expression system. In this chapter, we describe the method for the expression and purification of a membrane-anchored form of OPA1 and liposome-based in vitro reconstitution of membrane fusion.
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GTP Fosfohidrolasas/química , GTP Fosfohidrolasas/genética , Expresión Génica , Fusión de Membrana , Membranas Mitocondriales/química , Proteínas Recombinantes/química , Proteínas Recombinantes/genética , Animales , Bombyx/genética , Transferencia Resonante de Energía de Fluorescencia , GTP Fosfohidrolasas/aislamiento & purificación , Humanos , Membranas Mitocondriales/metabolismo , Proteolípidos , Proteínas Recombinantes/aislamiento & purificaciónRESUMEN
Optic Atrophy 1 (OPA1) has well-established roles in both mitochondrial fusion and apoptotic crista remodeling and is required for the maintenance and distribution of mitochondrial DNA (mtDNA), which are essential for energy metabolism. However, the relationship between OPA1 and mitochondrial metabolism and the underlying mechanisms remain unclear. Here, we show that OPA1-Exon4b modulates mitochondrial respiration and rescues inner mitochondrial membrane potential (Δψm), independent of mitochondrial fusion. OPA1-Exon4b is required for the maintenance of normal TFAM distribution and enhances mtDNA transcription by binding the D-loop of mtDNA. Finally, we show that mRNA levels of OPA1 isoforms containing Exon4b are specifically downregulated in hepatocellular carcinoma (HCC), leading to a reduction in Δψm. Thus, our study demonstrates a novel mitochondrial functional self-recovery pathway involving enhanced mtDNA transcription-mediated recovery of mitochondrial respiratory chain proteins. This mitochondrial fusion-independent pathway may contribute to mitochondrial multi-functional switches in tumorigenesis.
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Optic atrophy 1 (OPA1) is a dynamin protein that mediates mitochondrial fusion at the inner membrane. OPA1 is also necessary for maintaining the cristae and thus essential for supporting cellular energetics. OPA1 exists as membrane-anchored long form (L-OPA1) and short form (S-OPA1) that lacks the transmembrane region and is generated by cleavage of L-OPA1. Mitochondrial dysfunction and cellular stresses activate the inner membrane-associated zinc metallopeptidase OMA1 that cleaves L-OPA1, causing S-OPA1 accumulation. The prevailing notion has been that L-OPA1 is the functional form, whereas S-OPA1 is an inactive cleavage product in mammals, and that stress-induced OPA1 cleavage causes mitochondrial fragmentation and sensitizes cells to death. However, S-OPA1 contains all functional domains of dynamin proteins, suggesting that it has a physiological role. Indeed, we recently demonstrated that S-OPA1 can maintain cristae and energetics through its GTPase activity, despite lacking fusion activity. Here, applying oxidant insult that induces OPA1 cleavage, we show that cells unable to generate S-OPA1 are more sensitive to this stress under obligatory respiratory conditions, leading to necrotic death. These findings indicate that L-OPA1 and S-OPA1 differ in maintaining mitochondrial function. Mechanistically, we found that cells that exclusively express L-OPA1 generate more superoxide and are more sensitive to Ca2+-induced mitochondrial permeability transition, suggesting that S-OPA1, and not L-OPA1, protects against cellular stress. Importantly, silencing of OMA1 expression increased oxidant-induced cell death, indicating that stress-induced OPA1 cleavage supports cell survival. Our findings suggest that S-OPA1 generation by OPA1 cleavage is a survival mechanism in stressed cells.
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GTP Fosfohidrolasas/metabolismo , Mitocondrias/metabolismo , Membranas Mitocondriales/enzimología , Estrés Oxidativo , Animales , Calcio/metabolismo , Línea Celular , Supervivencia Celular , GTP Fosfohidrolasas/genética , Isoenzimas/genética , Isoenzimas/metabolismo , Ratones , Ratones Noqueados , Mitocondrias/genética , Permeabilidad , Superóxidos/metabolismoRESUMEN
We report the results of molecular screening in 121 patients with suspected hereditary optic neuropathies. The 34 primary and 9 secondary LHON mutations were screened in all the patients. In the familial cases, OPA1 was also tested when negative finding for the mtDNA mutations screening. Molecular defects were identified in 35 patients (28.9% of screened patients). Among these, 33 patients (94.3%) had an mtDNA mutation, including m.11778Gâ¯>â¯A (69.7%), m.14484â¯Tâ¯>â¯C, m.3460Gâ¯>â¯A, m.3635Gâ¯>â¯A, m.14502â¯Tâ¯>â¯C and three secondary mutations m.3316Gâ¯>â¯A, m.3394â¯Tâ¯>â¯C, m.3497Câ¯>â¯T. Two novel OPA1 mutations, c.1301â¯Tâ¯>â¯G (p.Leu434Arg) and c.985-1Gâ¯>â¯A (IVS9-1Gâ¯>â¯A), were also detected in families with the evidence of father-to-son transmission. In conclusion, we reported the results of the molecular screening of 121 patients with hereditary optic neuropathies from southwest of China. Our results highlight the importance of investigating LHON-causing mtDNA mutations and OPA1 mutations in cases of suspected hereditary optic neuropathy.