Flow Cytometric Analysis of Rhodamine 123 Fluorescence during Modulation of the Membrane Potential in Plant Mitochondria

The fluorescent dye rhodamine 123, which selectively accumulates in mitochondria based on the membrane potential, was used with flow cytometry to evaluate variations in activity of mitochondria isolated from plant tissues. In the presence of succinate and ATP, potato (Solanum tuberosum L.) tuber mitochondrial activity was affected by metabolic inhibitors and compounds that modify the membrane potential. The more uniform the mitochondrial population, the higher the observed membrane potential. The reactive population corresponds to the proportion of intact mitochondria (94-97%) defined by classic methods. Changes in the light-scattering properties are more related to internal modifications affecting the inner membrane-matrix system of the mitochondria during metabolic modulation than to specific volume change or outer membrane surface modifications. We tested our approach using an Arum maculatum preparation that contains three different types of mitochondria and demonstrated the validity of the light-scatter measurements to distinguish the α, β, and [ill] mitochondria and to measure their ability to built up a membrane potential in the presence of succinate. These results demonstrate clearly that flow cytometric techniques using rhodamine 123 can be employed to study the activity in isolated plant mitochondria.     

Regulation of the reaction rate of ATP synthesis in intact mitochondria

High concentrations of respiration inhibitors are known to sharply decrease the membrane potential in mitochondria. The effect of relatively low concentrations of oxidative phosphorylation inhibitors on the value of membrane potential of intact mitochondria and on the rate of respiration and phosphorylation as well was studied. It has been found that within a certain concentration range the inhibitors of oxidative phsophorylation--malonic acid, sodium cyanide m-chlorophenyl hydrozonecarbonylcyanide, sharply decrease the phosphorylation rate (by 70 divided by 90%) but do not practically a affect the membrane potential value of intact mitochondria in the state 3 according to Chance.     

Requirement of a membrane potential for the posttranslational transfer of proteins into mitochondria

Posttranslational transfer of most precursor proteins into mitochondria is dependent on energization of the mitochondria. Experiments were carried out to determine whether the membrane potential or the intramitochondrial ATP is the immediate energy source. Transfer in vitro of precursors to the ADP/ATP carrier and to ATPase subunit 9 into isolated Neurospora mitochondria was investigated. Under conditions where the level of intramitochondrial ATP was high and the membrane potential was dissipated, import and processing of these precursor proteins did not take place. On the other hand, precursors were taken up and processed when the intramitochondrial ATP level was low, but the membrane potential was not dissipated. We conclude that a membrane potential is involved in the import of those mitochondrial precursor proteins which require energy for intracellular translocation.     

Effects of amphipathic peptides,including presequences,on the functional integrity of rat liver mitochondrial membranes

A number of amphipathic peptides were tested for their effects on structural and functional properties of isolated rat liver mitochondria. The peptides included the matrix targeting sequence of subunit IV of (yeast) cytochromec oxidase. Titration experiments in which the mitochondria were incubated with increasing concentrations of the peptides revealed two major stages in the interaction. First, at low peptide/mitochondria ratios, peptide binding to the outer membrane occurred which was accompanied by gradual lysis of the outer membrane at higher ratios. The latter was deduced from the release of adenylate kinase, the classical marker enzyme of the intermembrane space. Secondly, at still higher peptide/mitochondria ratios, the permeability of the inner membrane progressively increased, as evidenced by measurements of respiratory control and of the membrane potential. Complete uncoupling of respiration seemed to precede dissipation of the membrane potential.     

棕榈酸对模拟高原低氧大鼠离体脑线粒体解耦联蛋白活性及质子漏的影响

本文旨在通过观察棕榈酸对模拟高原低氧大鼠离体脑线粒体解耦联蛋白(uncoupling proteins,UCPs)活性的影响及脑线粒体质子漏与膜电位的改变,探讨UCPs在介导游离脂肪酸对低氧时线粒体氧化磷酸化功能改变中的作用.将SpragueDawley大鼠随机分为对照组、急性低氧组和慢性低氧组.低氧大鼠于低压舱内模拟海拔5 000 m高原23 h/d作低氧暴露,分别连续低氧3 d和30 d.用差速密度梯度离心法提取脑线粒体,[3H-GTP法测定UCPs含量与活性,TPMP 电极与Clark氧电极结合法测量线粒体质子漏,罗丹明123荧光法测定线粒体膜电位.结果显示,低氧使脑线粒体内UCPs含量与活性升高、质子漏增加、线粒体膜电位降低;同时,低氧暴露降低脑线粒体对棕榈酸的反应性,UCPs活性的改变率低于对照组,且线粒体UCPs含量、质子漏、膜电位变化率亦出现相同趋势.线粒体质子漏与反映UCPs活性的Kd值呈线性负相关(P<0.01 r=-0.906),与反映UCPs含量的Bmax呈线性正相关(P<0.01,r=0.856),与膜电位呈线性负相关(P<0.01,r=-0.880).以上结果提示,低氧导致的脑线粒体质子漏增加及膜电位降低与线粒体内UCPs活性升高有关,同时低氧暴露能降低脑线粒体对棕榈酸的反应性,提示在高原低氧环境下,游离脂肪酸升高在维持线粒体能量代谢中起着自身保护和调节机制.     

Analysis of the membrane potential of rat- and mouse-liver mitochondria by flow cytometry and possible applications

Washed and purified rat- or mouse-liver mitochondria exhibiting high membrane integrity and metabolic activity were studied by flow cytometry. The electrophoretic accumulation/redistribution of cationic lipophilic probes, rhodamine 123, safranine O and a cyanine derivative, 3,3'-dihexyloxadicarbocyanine iodide, during the energization process was studied and was consistent with the generation of a negative internal membrane potential. An exception to this was nonylacridine orange which spontaneously bound to the mitochondrial membrane by hydrophobic interactions via its hydrocarbon chain. Energized purified mitochondria stained with potentiometric dyes exhibited both higher fluorescence and population homogeneity than the non-energized or deenergized (nigericin plus valinomycin) mitochondria. By contrast, under non-energized or deenergized conditions, the mitochondrial population exhibited fluorescence intensity heterogeneity related to the residual membrane potential; two subpopulations were evident, one of low fluorescence which may be related to the autofluorescence of the mitochondria (plus non-specific dye binding) and a second population which exhibited high fluorescence. Flow cytometry of the unpurified, simply washed, rat-liver mitochondria stained with rhodamine 123, a classically used dye, provided evidence of their heterogeneity in terms of light-scattering properties and membrane-potential-related fluorescence. One third of the washed mitochondria were found to be non-functional by such assays. The fluorescence of purified rat-liver mitochondria due to the membrane potential built up by endogenous substrates indicates heterogeneity of the mitochondrial population with respect to levels of endogenous substrates. The low-angle light scattering increases upon energization and provides some original information about the shape and modification of the inner mitochondrial conformation accompanying the energization. The heterogeneity of the rat liver mitochondrial population, from a structural, metabolic (existence of endogenous substrates) and functional (active and non-active mitochondrial population dispersion) point of view could thus be demonstrated by flow-cytometry analysis. Two animal models were examined with regard to the alteration of the mitochondrial membrane potential under the effects of drugs (rat-liver mitochondria), and the effects of ammonium toxicity (mouse-liver mitochondria). These results are promising and open new perspectives in the study of mitochondriopathies.     

DNA-binding properties of Mblk-1, a putative transcription factor from the honeybee

The membrane potentials, rates of NAD(P)H formation, and rates of flavoprotein reduction have been measured for single mitochondria isolated from porcine hearts. These metabolic responses were elicited by the addition of malate and measured using fluorescence microscopy. For the measurements of mitochondrial membrane potential, mitochondria were stained with tetramethylrhodamine ethyl ester, and the membrane potentials of single mitochondria were determined. Individual mitochondria maintained the membrane potential at around -80 mV before addition of malate. Upon the addition of malate, each mitochondrion was rapidly polarized to around -100 approximately -140 mV and underwent repeated cycles of polarization and depolarization, which were probably caused by openings and closings of permeability transition pores. NAD(P)(+) and flavoprotein were reduced immediately after addition of malate and then slowly became reoxidized. Thus, single mitochondria can undergo rapid and repetitive changes in membrane potential, but not in the redox state of NAD(P)H and flavoprotein.     

Phosphate is required to maintain the outer membrane integrity and membrane potential of respiring yeast mitochondria.

The buffer requirements to maintain mitochondrial intactness and membrane potential in in vitro studies were investigated, using gradient purified yeast mitochondria. It was found that the presence of phosphate is crucial for generation of a stable membrane potential and for preserving the intactness of the outer membrane, as assessed by probing the accessibility of Tom40p to trypsin and the leakage of cytochrome b2 from the intermembrane space. Upon addition of respiratory substrate in the absence of phosphate, mitochondria generate a membrane potential that collapses within 1 min. Under the same conditions, the mitochondrial outer membrane is disrupted. The presence of phosphate prevents both phenomena. The DeltapH component of the proton motive force appears to be responsible for the compromised outer membrane integrity. The collapse of the membrane potential is reversible to a limited extent. Only when phosphate is added soon enough after the addition of exogenous respiratory substrate can a stable membrane potential be obtained again. Within a few minutes, this capacity is lost. The presence of Mg(2+) prevents rupture of the outer membrane, but does not prevent rapid dissipation of the membrane potential. Similar results were obtained for mitochondria isolated and stored in the presence of dextran or bovine serum albumin.     

Acute knockdown of uncoupling protein-2 increases uncoupling via the adenine nucleotide transporter and decreases oxidative stress in diabetic kidneys

Increased O(2) metabolism resulting in chronic hypoxia is common in models of endstage renal disease. Mitochondrial uncoupling increases O(2) consumption but the ensuing reduction in mitochondrial membrane potential may limit excessive oxidative stress. The present study addressed the hypothesis that mitochondrial uncoupling regulates mitochondria function and oxidative stress in the diabetic kidney. Isolated mitochondria from kidney cortex of control and streptozotocin-induced diabetic rats were studied before and after siRNA knockdown of uncoupling protein-2 (UCP-2). Diabetes resulted in increased UCP-2 protein expression and UCP-2-mediated uncoupling, but normal mitochondria membrane potential. This uncoupling was inhibited by GDP, which also increased the membrane potential. siRNA reduced UCP-2 protein expression in controls and diabetics (-30-50%), but paradoxically further increased uncoupling and markedly reduced the membrane potential. This siRNA mediated uncoupling was unaffected by GDP but was blocked by ADP and carboxyatractylate (CAT). Mitochondria membrane potential after UCP-2 siRNA was unaffected by GDP but increased by CAT. This demonstrated that further increased mitochondria uncoupling after siRNA towards UCP-2 is mediated through the adenine nucleotide transporter (ANT). The increased oxidative stress in the diabetic kidney, manifested as increased thiobarbituric acids, was reduced by knocking down UCP-2 whereas whole-body oxidative stress, manifested as increased circulating malondialdehyde, remained unaffected. All parameters investigated were unaffected by scrambled siRNA. In conclusion, mitochondrial uncoupling via UCP-2 regulates mitochondria membrane potential in diabetes. However, blockade of the diabetes-induced upregulation of UCP- 2 results in excessive uncoupling and reduced oxidative stress in the kidney via activation of ANT.     

Electrophoresis of chloride ions and changes in the membrane potential of energized mitochondria]

In energized rat liver mitochondria the simultaneous H+, K+ and C1- transport was studied by corresponding ion selective electrodes. It was shown that the C1- transport induced by valinomycin, by valinomycin plus carbonyclyanide m-chlorophenylhydrazone was governed by the membrane potential. It is suggested that observed in energized mitochondria the C1- electrophoresis may servt as an indicator of membrane potential changes.     

Resting state respiration of mitochondria: reappraisal of the role of passive ion fluxes

Rat liver mitochondria respiring under resting state conditions in the presence of oligomycin were rapidly blocked with cyanide and the dissipation of the membrane potential, measured with a tetraphenylphosphonium-sensitive electrode, was followed over time. The plot of the rate of membrane potential dissipation versus the actual value of the membrane potential was nonlinear and identical to the plot of resting state respiration (titrated with small amounts of a respiratory inhibitor) versus the membrane potential. The relationship between the respiratory chain activity and the proton-motive force in mitochondria oxidizing succinate with either oxygen or ferricyanide as electron acceptors was also found to be identical. These results are interpreted as an indication that the passive permeability of the inner mitochondrial membrane toward ions is far more significant in maintaining resting state respiration than is the molecular slippage of the pumps in the respiratory chain. These results also confirm the non-ohmic characteristics of the inner mitochondrial membrane.     

Yeast mitochondria lacking the phosphate carrier/p32 are blocked in phosphate transport but can import preproteins after regeneration of a membrane potential.

Two different functions have been proposed for the phosphate carrier protein/p32 of Saccharomyces cerevisiae mitochondria: transport of phosphate and requirement for import of precursor proteins into mitochondria. We characterized a yeast mutant lacking the gene for the phosphate carrier/p32 and found both a block in the import of phosphate and a strong reduction in the import of preproteins transported to the mitochondrial inner membrane and matrix. Binding of preproteins to the surface of mutant mitochondria and import of outer membrane proteins were not inhibited, indicating that the inhibition of protein import occurred after the recognition step at the outer membrane. The membrane potential across the inner membrane of the mutant mitochondria was strongly reduced. Restoration of the membrane potential restored preprotein import but did not affect the block of phosphate transport of the mutant mitochondria. We conclude that the inhibition of protein import into mitochondria lacking the phosphate carrier/p32 is indirectly caused by a reduction of the mitochondrial membrane potential (delta(gamma)), and we propose a model that the reduction of delta(psi) is due to the defective phosphate import, suggesting that phosphate transport is the primary function of the phosphate carrier/p32.     

Effect of bovine serum albumin on membrane potential in plant mitochondria

The membrane potential in highly coupled potato ( Solanum tuberosum L.) mitochondria, as measured by changes in safranine absorbance, was significantly increased by addition of bovine serum albumin. Purification of potato mitochondria on Percoll, in removing 50% of free unsaturated fatty acids, decreased the BSA-de-pendent membrane potential. The effect of added linoleic acid and of the natural accumulation of fatty acids during aging was studied. The response of membrane potential to addition of bovine serum albumin appeared to be directly correlated to the amount of free unsaturated fatty acids. Aging in vitro, in releasing free fatty acids, decreased respiratory control and ADP:O ratios and collapsed the membrane potential. During 2–3 h of incubation, addition of BSA completely restored membrane potential and oxidative phosphorylation.
It is concluded that both in fresh and in aged potato mitochondria the effect of bovine serum albumin on oxidative phosphorylation can be ascribed to an effect on membrane permeability to ions. BSA, in binding free unsaturated fatty acids, restored maximal membrane potential. The bovine serum albumin-dependent membrane potential appears to be a sensitive criterion of the functional integrity of the inner mitochondrial membrane.     

Digitonin permeabilization does not affect mitochondrial function and allows the determination of the mitochondrial membrane potential of Trypanosoma cruzi in situ.

Digitonin can be used to permeabilize selectively the plasma membrane of Trypanosoma cruzi epimastigotes without significantly affecting the functional integrity of mitochondria. Addition of digitonin at concentrations close to 64 microM caused decrease in the rate of basal respiration of epimastigotes similar to that caused by oligomycin. A further addition of carbonyl cyanide p-trifluorophenylhydrazone (FCCP) brought respiration to the same rate observed prior to the inclusion of digitonin or oligomycin. This suggests that like oligomycin, digitonin is shifting respiration to a nonphosphorylating state probably by depleting the cells from adenine nucleotides due to permeabilization of the plasma membrane. The use of low concentrations of digitonin allowed the quantitative determination of the mitochondrial membrane potential of these cells in situ using safranine O. The response of epimastigotes mitochondrial membrane potential to phosphate, FCCP, valinomycin, nigericin, ADP, and Ca2+ indicates that these mitochondria behave similarly to vertebrate mitochondria regarding the properties of their electrochemical proton gradient. In addition, T. cruzi mitochondria are able to build up and retain a membrane potential of a value comparable to that of mammalian mitochondria. The trypanocidal drug crystal violet, as well as other cationic drugs such as dequalinium, induced a rapid dose-related collapse of the inner mitochondrial membrane potential.     

Vimentin intermediate filaments increase mitochondrial membrane potential

Mitochondria are the main source of energy in eukaryotic cells. They also play an important role in the number of other processes, such as regulation of calcium concentration and sequestration of apoptotic factors. Almost all functions of mitochondria depend on their ability to generate and maintain membrane potential by means of aerobic respiration. The level of mitochondrial potential is under the control of different inner and outer factors. However, mechanisms of this regulation are still poorly understood. In the present study we answer the question of how membrane potential of mitochondria depends on their motility. Using the potential-dependent dye MitoTracker Red, fluorescent microscopy of live cells, and the analysis of mitochondrial motility, two sub-populations of mitochondria were determined: (1) moving mitochondria transported along microtubules and (2) stationary mitochondria. We have shown that stationary mitochondria have higher membrane potential than moving mitochondria. It was also found that the level of potential of mitochondria is regulated by their interaction with vimentin intermediate filaments.     

Energy flux modulation on the outer membrane of mitochondria by metabolically-derived potential

Voltage-dependent anion channels (VDACs) are the porins in the outer mitochondrial membrane allowing metabolite flux between mitochondria and the cytoplasm. The permeabilities of the VDACs to ATP(-4), ADP(3-), creatine phosphate2-, Pi2-, Pi-, and other charged metabolites depend on the membrane potential. But neither the existence of the electrical potential across the outer membrane of mitochondria, nor its generation mechanisms have been experimentally shown. In this work, the concept of metabolically-derived potential that could be generated on the outer membrane was developed further. The computational study of the quantitative models shows that a steady-state membrane potential above 40 mV may be generated across a membrane with VDACs, if the VDACs are considered to be non-permeable to K+ and Cl-. Free permeability of VDACs to these inorganic ions, mimicking VDACs biological behavior, decreases the potential to nearly 12 mV. This decrease does not result from the electrical shortening of the potential by K+ and Cl- fluxes, but is caused by the electrodynamic compartmentation of the charged metabolites influencing the Goldman fluxes and the enzyme activity determining the fluxes. The interaction of two cyclic steady-state fluxes of charged metabolites due to the synergetic superposition of the potentials generated by each of these fluxes was obtained, and the effect of amplification of one flux by the other was theoretically demonstrated. These calculations based on VDACs' known permeability-voltage characteristics indicate that there is a certain possibility that the cell energy metabolism is regulated on the outer membrane of mitochondria by the electrical potential generated by various metabolically-dependent mechanisms.     

Quantitation and origin of the mitochondrial membrane potential in human cells lacking mitochondrial DNA.

Mammalian mitochondrial DNA (mtDNA) encodes 13 polypeptide components of oxidative phosphorylation complexes. Consequently, cells that lack mtDNA (termed rho degrees cells) cannot maintain a membrane potential by proton pumping. However, most mitochondrial proteins are encoded by nuclear DNA and are still imported into mitochondria in rho degrees cells by a mechanism that requires a membrane potential. This membrane potential is thought to arise from the electrogenic exchange of ATP4- for ADP3- by the adenine nucleotide carrier. An intramitochondrial ATPase, probably an incomplete FoF1-ATP synthase lacking the two subunits encoded by mtDNA, is also essential to ensure sufficient charge flux to maintain the potential. However, there are considerable uncertainties about the magnitude of this membrane potential, the nature of the intramitochondrial ATPase and the ATP flux required to maintain the potential. Here we have investigated these factors in intact and digitonin-permeabilized mammalian rho degrees cells. The adenine nucleotide carrier and ATP were essential, but not sufficient to generate a membrane potential in rho degrees cells and an incomplete FoF1-ATP synthase was also required. The maximum value of this potential was approximately 110 mV in permeabilized cells and approximately 67 mV in intact cells. The membrane potential was eliminated by inhibitors of the adenine nucleotide carrier and by azide, an inhibitor of the incomplete FoF1-ATP synthase, but not by oligomycin. This potential is sufficient to import nuclear-encoded proteins but approximately 65 mV lower than that in 143B cells containing fully functional mitochondria. Subfractionation of rho degrees mitochondria showed that the azide-sensitive ATPase activity was membrane associated. Further analysis by blue native polyacrylamide gel electrophoresis (BN/PAGE) followed by activity staining or immunoblotting, showed that this ATPase activity was an incomplete FoF1-ATPase loosely associated with the membrane. Maintenance of this membrane potential consumed about 13% of the ATP produced by glycolysis. This work has clarified the role of the adenine nucleotide carrier and an incomplete FoF1-ATP synthase in maintaining the mitochondrial membrane potential in rho degrees cells.     

Berberine derivatives as cationic fluorescent probes for the investigation of the energized state of mitochondria

The interaction of rat liver and bovine heart mitochondria with a series of fluorescent, cationic berberine derivatives varying in the length of alkyl chain has been investigated. An increase in the hydrophobicity of the derivative was accompanied by a larger value of the partition coefficient and by binding to a more hydrophobic region of the inner mitochondrial membrane. It was found that berberines could be used as sensitive indicators of processes which take place on the outer surface of the mitochondrial membrane; the greatest (15-fold) increase in fluorescence was obtained with 13-methylberberine in the energized state of mitochondria. The fluorescence increase was due to the increase in fluorescence quantum yield although a small increase in the amount of bound derivative could also be detected upon energization. The fluorescence was linearly dependent on the magnitude of the membrane potential. In parallel with an observed fluorescence enhancement a considerable decrease in rotational mobility was found. We suggest that berberines move in the inner membrane according to the polarity of the membrane potential; consequently, deeper immersion in the less polar region in the energized state brings about a larger fluorescence increase. More hydrophobic derivatives inhibited NAD-linked respiration in rat liver mitochondria but exerted no effect on succinate oxidation up to 10 μM concentration.     

Energetics of Ehrlich ascites mitochondria: membrane potential of isolated mitochondria and mitochondria within digitonin-permeabilized cells

Ehrlich ascites tumour cells were treated with digitonin so that they became permeable for low-molecular-weight compounds but, at certain concentrations of digitonin, retained most of their cytoplasmic proteins. Respiration of mitochondria with exogenous substrates and their membrane potential could thus be measured in situ by means of oxygen electrode and tetraphenylphosphonium-sensitive electrode, respectively. The results were compared with data from similar measurements on mitochondria isolated from such digitonin-permeabilized cells. Isolated mitochondria and mitochondria in situ oxidized succinate at similar rates and developed membrane potential of comparable magnitude. Both preparations also exhibited an identical nonlinear relationship between resting state respiration (titrated with a respiratory inhibitor) and the membrane potential. In the cells permeabilized with low concentrations of digitonin (i.e., retaining most of cytoplasmic proteins) and suspended in medium containing NaCl and other major anions and cations at concentrations close to those in mammalian plasma, anaerobiosis did not produce a decrease in the mitochondrial membrane potential, which was collapsed only after a subsequent addition of oligomycin. In this medium, glucose had little effect on either respiration or the membrane potential.     

Nicotine effects on mitochondria membrane potential: participation of nicotinic acetylcholine receptors

The effect of nicotine on the mouse liver mitochondria was studied by fluorescent flow cytometry. Mice consumed nicotine during 65 days; alternatively, nicotine was added to isolated mitochondria. Mitochondria of nicotine-treated mice had significantly lower basic levels of membrane potential and granularity as compared to those of the control group. Pre-incubation of the isolated mitochondria with nicotine prevented from dissipation of their membrane potential stimulated with 0.8 microM CaCl2 depending on the dose, and this effect was strengthened by the antagonist of alpha7 nicotinic receptors (alpha7 nAChR) methyllicaconitine. Mitochondria of mice intravenously injected with the antibodies against alpha7 nAChR demonstrated lower levels of membrane potential. Introduction of nicotine, choline, acetylcholine or synthetic alpha7 nAChR agonist PNU 282987 into the incubation medium inhibited Ca2+ accumulation in mitochondria, although the doses of agonists were too low to activate the alpha7 nAChR ion channel. It is concluded that nicotine consumption worsens the functional state of mitochondria by affecting their membrane potential and granularity, and this effect, at least in part, is mediated by alpha7 nAChR desensitization.