Identification of a 20-kDa protein with calcium uptake transport activity. Reconstitution in a membrane model

This paper presents results of experiments designed to further purify the membrane system involved in mitochondrial calcium transport. A partially purified extract, which transported calcium with a specific activity of 1194 nmol⁴⁵Ca²⁺/mg protein/5 min, was used to obtain mouse hyperimmune serum. This serum inhibited calcium uptake both in mitoplasts and in vesicles reconstituted with mitochondrial proteins containing cytochrome oxidase. Western blot analysis of the semipurified fraction showed that the serum recognized specifically two antigens of 75 and 20 kDa. Both antibodies were purified by elution from the nitrocellulose sheets and their inhibition capacity was analyzed. The antibody that recognized the 20-kDa protein produced a higher degree of inhibition than the other one.     

The mechanical effects of CRT promoting autophagy via mitochondrial calcium uniporter down‐regulation and mitochondrial dynamics alteration

The mechanism of cardiac resynchronization therapy (CRT) remains unclear. In this study, mitochondria calcium uniporter (MCU), dynamin‐related protein‐1 (DNM1L/Drp1) and their relationship with autophagy in heart failure (HF) and CRT are investigated. Thirteen male beagle's dogs were divided into three groups (sham, HF, CRT). Animals received left bundle branch (LBB) ablation followed by either 8‐week rapid atrial pacing or 4‐week rapid atrial pacing and 4‐week biventricular pacing. Cardiac function was evaluated by echocardiography. Differentially expressed genes (DEGs) were detected by microarray analysis. General morphological changes, mitochondrial ultrastructure, autophagosomes and mitophagosomes were investigated. The cardiomyocyte stretching was adopted to imitate the mechanical effect of CRT. Cells were divided into three groups (control, angiotensin‐II and angiotensin‐II + stretching). MCU, DNM1L/Drp1 and autophagy markers were detected by western blots or immunofluorescence. In the present study, CRT could correct cardiac dysfunction, decrease cardiomyocyte's size, alleviate cardiac fibrosis, promote the formation of autophagosome and mitigate mitochondrial injury. CRT significantly influenced gene expression profile, especially down‐regulating MCU and up‐regulating DNM1L/Drp1. Cell stretching reversed the angiotensin‐II induced changes of MCU and DNM1L/Drp1 and partly restored autophagy. CRT's mechanical effects down‐regulated MCU, up‐regulated DNM1L/Drp1 and subsequently enhanced autophagy. Besides, the mechanical stretching prevented the angiotensin‐II‐induced cellular enlargement.     

The mitochondrial calcium uniporter is a multimer that can include a dominant‐negative pore‐forming subunit

Mitochondrial calcium uniporter (MCU) channel is responsible for Ruthenium Red‐sensitive mitochondrial calcium uptake. Here, we demonstrate MCU oligomerization by immunoprecipitation and Förster resonance energy transfer (FRET) and characterize a novel protein (MCUb) with two predicted transmembrane domains, 50% sequence similarity and a different expression profile from MCU. Based on computational modelling, MCUb includes critical amino‐acid substitutions in the pore region and indeed MCUb does not form a calcium‐permeable channel in planar lipid bilayers. In HeLa cells, MCUb is inserted into the oligomer and exerts a dominant‐negative effect, reducing the [Ca²⁺]_mt increases evoked by agonist stimulation. Accordingly, in vitro co‐expression of MCUb with MCU drastically reduces the probability of observing channel activity in planar lipid bilayer experiments. These data unveil the structural complexity of MCU and demonstrate a novel regulatory mechanism, based on the inclusion of dominant‐negative subunits in a multimeric channel, that underlies the fine control of the physiologically and pathologically relevant process of mitochondrial calcium homeostasis.     

MICU1 and MICU2 play nonredundant roles in the regulation of the mitochondrial calcium uniporter

The mitochondrial uniporter is a selective Ca²⁺ channel regulated by MICU1, an EF hand‐containing protein in the organelle's intermembrane space. MICU1 physically associates with and is co‐expressed with a paralog, MICU2. To clarify the function of MICU1 and its relationship to MICU2, we used gene knockout (KO) technology. We report that HEK‐293T cells lacking MICU1 or MICU2 lose a normal threshold for Ca²⁺ intake, extending the known gating function of MICU1 to MICU2. Expression of MICU1 or MICU2 mutants lacking functional Ca²⁺‐binding sites leads to a striking loss of Ca²⁺ uptake, suggesting that MICU1/2 disinhibit the channel in response to a threshold rise in [Ca²⁺]. MICU2's activity and physical association with the pore require the presence of MICU1, though the converse is not true. We conclude that MICU1 and MICU2 are nonredundant and together set the [Ca²⁺] threshold for uniporter activity.     

Involvement of the mitochondrial calcium uniporter in cardioprotection by ischemic preconditioning

The objective of the present study was to determine whether the mitochondrial calcium uniporter plays a role in the cardioprotection induced by ischemic preconditioning (IPC). Isolated rat hearts were subjected to 30 min of regional ischemia by ligation of the left anterior descending artery followed by 120 min of reperfusion. IPC was achieved by two 5-min periods of global ischemia separated by 5 min of reperfusion. IPC reduced the infarct size and lactate dehydrogenase release in coronary effluent, which was associated with improved recovery of left ventricular contractility. Treatment with ruthenium red (RR, 5 μM), an inhibitor of the uniporter, or with Ru360 (10 μM), a highly specific uniporter inhibitor, provided cardioprotective effects like those of IPC. The cardioprotection induced by IPC was abolished by spermine (20 μM), an activator of the uniporter. Cyclosporin A (CsA, 0.2 μM), an inhibitor of the mitochondrial permeability transition pore, reversed the effects caused by spermine. In mitochondria isolated from untreated hearts, both Ru360 (10 μM) and RR (1 μM) decreased pore opening, while spermine (20 μM) increased pore opening which was blocked by CsA (0.2 μM). In mitochondria from preconditioned hearts, the opening of the pore was inhibited, but this inhibition did not occur in the mitochondria from hearts treated with IPC plus spermine. These results indicate that the mitochondrial calcium uniporter is involved in the cardioprotection conferred by ischemic preconditioning.     

线粒体钙单向转运体在心肌低氧/复氧损伤中的作用

目的:观察线粒体钙单向转运体在心肌低氧/复氧损伤中的作用并探讨其机制。方法:应用Langendorff大鼠心脏灌流模型,低氧/复氧(H/R)采用冠脉前降支结扎30 min、复灌120 min的方法。用生物信号采集系统记录左室发展压(LVDP)、左室压最大上升/下降速率(±dP/dtmax)、左室舒张末压(LVEDP);分光光度法分别检测冠脉流出液中乳酸脱氢酶(LDH)的含量和线粒体活性氧(ROS);TTC染色法检测心肌梗死面积。结果:与单纯低氧/复氧组相比,复氧起始给予线粒体钙单向转运体抑制剂钌红(5μmol/L)明显改善左心室各项功能指标,减小心肌梗死面积,降低线粒体ROS和冠脉流出液中LDH含量;而在复氧期起始给予线粒体钙单向转运体激动剂精胺(20μmol/L),显著升高了线粒体ROS活性,冠脉流出液中LDH含量在复氧5 min、20 min、30 min时显著增多,左心室各项功能指标与心肌梗死面积与单纯低氧/复氧组相比无显著差异。ROS清除剂MPG(1 mmol/L)与精胺联合应用则取消了精胺的作用。结论:抑制线粒体钙单向转运体可能通过减少线粒体ROS的生成减轻心脏低氧/复氧损伤。     

Mitochondrial glycosidic residues contribute to the interaction between ruthenium amine complexes and the calcium uniporter

The role of glycosidic residues in the inhibitory properties of ruthenium complexes on mitochondrial calcium uptake was determined in mitoplasts.Our results showed that the binding and inhibitory properties of ruthenium amine complexes were modified when mitoplasts were exposed to N-glycosidase F action, but calcium uptake was not altered. N-linked proteins of the mitochondrial inner membrane were identified. We detected an 18-kDa protein that binds labeled Ru₃₆₀ under control conditions, but failed to bind the inhibitor after deglycosilation. A relationship between this protein and the action of ruthenium amine inhibitors of the mitochondrial uniporter is proposed.     

Inhibitors of the mitochondrial calcium uniporter for the treatment of disease

The mitochondrial calcium uniporter (MCU) is a protein located in the inner mitochondrial membrane that is responsible for mitochondrial Ca²⁺ uptake. Under certain pathological conditions, dysregulation of Ca²⁺ uptake through the MCU results in cellular dysfunction and apoptotic cell death. Given the role of the MCU in human disease, researchers have developed compounds capable of inhibiting mitochondrial calcium uptake as tools for understanding the role of this protein in cell death. In this article, we describe recent findings on the role of the MCU in mediating pathological conditions and the search for small-molecule inhibitors of this protein for potential therapeutic applications.     

Inhibition of the mitochondrial Ca2+ uniporter by pure and impure ruthenium red

Commercial ruthenium red is often purified by a single recrystallization as described by Luft, J.H. (1971) Anat Rec 171, 347–368, which yields small amounts of material having an apparent molar extinction coefficient of 67,400 at 533 nm. A simple modification to the procedure dramatically improves the yield, allowing crystallization to be repeated. Three times recrystallized ruthenium red has an apparent extinction coefficient of 85,900, the highest value reported to date. Both crude and highly purified ruthenium red can be shown to inhibit reverse activity of the mitochondrial Ca²⁺ uniporter (uncoupled mitochondria), provided that care is taken to minimize and account for Ca²⁺ release through the permeability transition pore. Crude ruthenium red is 7–10 fold more potent than the highly purified material in this regard, on an actual ruthenium red concentration basis. The same relative potency is seen against forward uniport (coupled mitochondria), however, the I₅₀ values are 10 fold lower for both the crude and purified preparations. These data demonstrate unambiguously that the energy state of mitochondria affects the sensitivity of the Ca²⁺ uniporter to ruthenium red preparations, and that both the forward and reverse reactions are subject to complete inhibition. The data suggest, however, that the active inhibitor may not be ruthenium redper se, but one or more of the other ruthenium complexes which are present in ruthenium red preparations.Abbreviations CCP carbonyl cyanide p-chlorophenylhydrazone - CSA cyclosporin A - Hepes 4-(2-hydroxyethyl)-1-piperazine ethanesulfonic acid     

Different Subunit Location of the Inhibition and Transport Sites in the Mitochondrial Calcium Uniporter

The mitochondrial calcium uniporter behaves as a cooperative mechanism, where the velocity is dependent on [Ca2+]ex. Transport kinetics follows a sigmoidal behavior with a Hill coefficient near 2.0, indicating the binding of at least two calcium molecules. Calcium transport in mitochondria is dependent on a negative inner membrane potential and is inhibited by policationic ruthenium compounds. In this study, calcium uptake activity was reconstituted into cytochrome oxidase vesicles by incorporating solubilized mitochondrial proteins. Calcium accumulation plotted against increasing Ca2+ concentrations followed a sigmoidal behavior with a Hill coefficient of 1.53. The uptake was sensitive to ruthenium policationic inhibitors, e.g. ruthenium red and Ru360. After mitochondrial proteins were separated by preparative isoelectrofocusing and incorporated into cytochrome oxidase vesicles, two peaks of calcium uptake activity were recovered. One of the activities was inhibited by Ru360, while the second activity was insensitive to Ru360 and was associated with proteins focused at very acidic isoelectric points. By using a thiol-group crosslinker and radiolabeled Ru360, we proposed a scheme of partial dissociation of the uniporter inhibitor-binding subunit under acidic conditions.     

The mitochondrial calcium uniporter is involved in mitochondrial calcium cycle dysfunction: Underlying mechanism of hypertension associated with mitochondrial tRNAIle A4263G mutation

Recent studies have shown that the mitochondrial DNA mutations are involved in the pathogenesis of hypertension. Our previous study identified mitochondrial tRNA^Ile A4263G mutation in a large Chinese Han family with maternally-inherited hypertension. This mutation may contribute to mitochondrial Ca²⁺ cycling dysfuntion, but the mechanism is unclear. Lymphoblastoid cell lines were derived from hypertensive and normotensive individuals, either with or without tRNA^Ile A4263G mutation. The mitochondrial calcium ([Ca²⁺]_m) in cells from hypertensive subjects with the tRNA^Ile A4263G mutation, was lower than in cells from normotension or hypertension without mutation, or normotension with mutation (P < 0.05). Meanwhile, cytosolic calcium ([Ca²⁺]_c) in hypertensive with mutation cells was higher than another three groups. After exposure to caffeine, which could increase the [Ca²⁺]_c by activating ryanodine receptor on endoplasmic reticulum, [Ca²⁺]_c/[Ca²⁺]_m increased higher than in hypertensive with mutation cells from another three groups. Moreover, MCU expression was decreased in hypertensive with mutation cells compared with in another three groups (P < 0.05). [Ca²⁺]_c increased and [Ca²⁺]_m decreased after treatment with Ru360 (an inhibitor of MCU) or an siRNA against MCU. In this study we found decreased MCU expression in hypertensive with mutation cells contributed to dysregulated Ca²⁺ uptake into the mitochondria, and cytoplasmic Ca²⁺ overload. This abnormality might be involved in the underlying mechanisms of maternally inherited hypertension in subjects carrying the mitochondrial tRNA^Ile A4263G mutation.     

The mitochondrial calcium uniporter engages UCP1 to form a thermoporter that promotes thermogenesis

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The elusive importance of being a mitochondrial Ca uniporter

The molecular components of the mitochondrial Ca²⁺ uptake machinery have been only recently identified. In the last months, in addition to the pore forming subunit and of one regulatory protein (named MCU and MICU1, respectively) other four components of this complex have been described. In addition, a MCU KO mouse model has been generated and a genetic human disease due to missense mutation of MICU1 has been discovered. In this contribution, we will first summarize the recent findings, discussing the roles of the different subunits of the mitochondrial Ca²⁺ uptake complex, pointing to the current contradictions in the published data, as well as possible explanations. Finally we will speculate on the recent, totally unexpected, results obtained in the MCU knock-out (KO) mice.     

Tissue-specific modulation of the mitochondrial calcium uniporter by magnesium ions

This paper analyzes the kinetics of the Ca2+ uniporter of mitochondria from rat heart, kidney and liver operating in a range of Ca2+ concentrations near the steady-state value (1-4 microM). Heart mitochondria exhibit the lowest activity, and physiological Mg2+ concentrations inhibit the mitochondrial Ca2+ uniporter by approx. 50% in heart and kidney, and by 20% in liver. At physiological Ca2+ and Mg2+ concentrations the external free Ca2+ maintained by respiring mitochondria in vitro is higher in heart and kidney with respect to liver mitochondria. This behaviour could represent an adaptation of different mitochondria to their specific intracellular environment.     

Regulation of Ca2+ fluxes in rat liver mitochondria by Ca2+. Effects on Ca2+ distribution

Rat liver mitochondria are able to temporarily lower the steady-state concentration of external Ca²⁺ after having accumulated a pulse of added Ca²⁺. This has been attributed to inhibition of a putative -modulated efflux pathway [Bernardi, P. (1984)Biochim. Biophys. Acta 766, 277–282]. On the other hand, the rebounding could be due to stimulation of the uniporter by Ca²⁺ [Kröner, H. (1987)Biol. Chem. Hoppe-Seyler 369, 149–155]. By measuring unidirectional Ca²⁺ fluxes, it was found that the uniporter was stimulated during the rebounding peak both under Bernardi's and Kröner's conditions, while no effects on the efflux could be demonstrated. The rate of unidirectional efflux of Ca²⁺ was not affected by inhibition of the uniporter. It appears likely that the rebounding is due to stimulation of the uniporter rather than inhibition of efflux.     

Cation-induced efflux of calcium from the mitochondria of Hymenolepis diminuta

We have previously reported that Ca²⁺ influx into the mitochondria of Hymenolepis diminuta, a rat intestinal eestode, takes place through an electrophoretic uniport system. Sodium and lithium were found to induce efflux of ⁴⁵Ca²⁺ from the mitochondria of H. diminuta. The two cations induced the efflux in a hyperbolic and linear fashion, respectively. The efflux as well as an exchange of external Ca²⁺ with internal ⁴⁵Ca²⁺ was inhibited by lanthanum. The type of Ca²⁺ transport system in the cestode organelle has been discussed and compared with that of the host (mammalian) counterpart.     

Purification of the channel component of the mitochondrial calcium uniporter and its reconstitution into planar lipid bilayers

The purification of the channel-forming component of the mitochondrial calcium uniporter and its channel properties are described. After ethanol and 50% ethanol-water extraction of mitochondria from beef heart or perfused rat liver, the extract was passed through thiopropyl-Sepharose 6B column, and absorbed components were eluted with 2-mercaptoethanol, followed by gel-filtration on Sephadex G-15. The last fraction eluted (M _r about 2000) was then subjected to reverse-phase high-performance liquid chromatography. Of the more than 10 distinct peaks, only one showed specific Ca²⁺-channel activity in BLM with properties similar to earlier, less extensively purified preparations, i.e., conductance of 20 pS and multiples thereof, clustering of channels, participation of 2 or more subunits in channel formation, and sensitivity to 1 µM ruthenium red. Voltage sensitivity and cooperativity between channels are described. The Ca²⁺-binding glycoprotein with which the peptide was associated was found to have high homology with human acid ₁-glycoprotein (orosomucoid) and to show identity with beef plasma orosomucoid in the Ouchterlony immunodiffusion test.     

Modulation of the matrix redox signaling by mitochondrial Ca~(2+)

Mitochondria sense,shape and integrate signals,and thus function as central players in cellular signal transduction. Ca2+ waves and redox reactions are two such intracellular signals modulated by mitochondria. Mitochondrial Ca2+ transport is of utmost physio-pathological relevance with a strong impact on metabolism and cell fate. Despite its importance,the molecular nature of the proteins involvedin mitochondrial Ca2+ transport has been revealed only recently. Mitochondrial Ca2+ promotes energy metabolism through the activation of matrix dehydrogenases and downstream stimulation of the respiratory chain. These changes also alter the mitochondrial NAD(P)H/NAD(P)+ ratio,but at the same time will increase reactive oxygen species(ROS) production. Reducing equivalents and ROS are having opposite effects on the mitochondrial redox state,which are hard to dissect. With the recent development of genetically encoded mitochondrial-targeted redoxsensitive sensors,real-time monitoring of matrix thiol redox dynamics has become possible. The discoveries of the molecular nature of mitochondrial transporters of Ca2+ combined with the utilization of the novel redox sensors is shedding light on the complex relation between mitochondrial Ca2+ and redox signals and their impact on cell function. In this review,we describe mitochondrial Ca2+ handling,focusing on a number of newly identified proteins involved in mitochondrial Ca2+ uptake and release. We further discuss our recent findings,revealing how mitochondrial Ca2+ influences the matrix redox state. As a result,mitochondrial Ca2+ is able to modulate the many mitochondrial redox-regulated processes linked to normal physiology and disease.