Rat brain cortex mitochondria release group II secretory phospholipase A(2) under reduced membrane potential

Activation of brain mitochondrial phospholipase(s) A(2) (PLA(2)) might contribute to cell damage and be involved in neurodegeneration. Despite the potential importance of the phenomenon, the number, identities, and properties of these enzymes are still unknown. Here, we demonstrate that isolated mitochondria from rat brain cortex, incubated in the absence of respiratory substrates, release a Ca(2+)-dependent PLA(2) having biochemical properties characteristic to secreted PLA(2) (sPLA(2)) and immunoreacting with the antibody raised against recombinant type IIA sPLA(2) (sPLA(2)-IIA). Under identical conditions, no release of fumarase in the extramitochondrial medium was observed. The release of sPLA(2) from mitochondria decreases when mitochondria are incubated in the presence of respiratory substrates such as ADP, malate, and pyruvate, which causes an increase of transmembrane potential determined by cytofluorimetric analysis using DiOC(6)(3) as a probe. The treatment of mitochondria with the uncoupler carbonyl cyanide 3-chlorophenylhydrazone slightly enhances sPLA(2) release. The increase of sPLA(2) specific activity after removal of mitochondrial outer membrane indicates that the enzyme is associated with mitoplasts. The mitochondrial localization of the enzyme has been confirmed by electron microscopy in U-251 astrocytoma cells and by confocal laser microscopy in the same cells and in PC-12 cells, where the structurally similar isoform type V-sPLA(2) has mainly nuclear localization. In addition to sPLA(2), mitochondria contain another phospholipase A(2) that is Ca(2+)-independent and sensitive to bromoenol lactone, associated with the outer mitochondrial membrane. We hypothesize that, under reduced respiratory rate, brain mitochondria release sPLA(2)-IIA that might contribute to cell damage.     

Differentiation of phospholipases A in mitochondria and lysosomes of rat liver

Highly purified mitochondria from rat liver contain a phospholipase A that catalyzes removal of 2-fatty acids, with a pH optimum above pH 8.0. Lysosomal preparations appeared to have two phospholipases A associated with them, one with a pH optimum at about pH 4.0, the second between pH 6.0 and 7.0. Mitochondrial phospholipase A hydrolyzed exogenous phospholipid as fast as or faster than endogenous phospholipid. The difference in specific radioactivity of (14)C-ethanolamine-labeled endogenous mitochondrial phospholipid before and after incubation indicates that a fraction of mitochondrial phosphatidyl ethanolamine is hydrolyzed more rapidly than the mitochondrial phospholipids as a whole. Acyl bond hydrolysis of exogenous and endogenous phospholipid by mitochondria was stimulated by free fatty acid, Ca(++), or in certain cases, monoacyl phospholipids or by treatments that disrupt the mitochondrial membrane. Of various fatty acids tested, lauric, myristic, oleic, and linoleic were most effective. ADP and ATP inhibited mitochondrial phospholipase, probably because they compete for Ca(++). Mg(++) also behaved as a competitive inhibitor; the effect was overcome by relatively little Ca(++).     

Pore formation and uncoupling initiate a Ca2+-independent degradation of mitochondrial phospholipids

Mitochondria contain a type IIA secretory phospholipase A(2) that has been thought to hydrolyze phospholipids following Ca(2+) accumulation and induction of the permeability transition. These enzymes normally require millimolar Ca(2+) for optimal activity; however, no dependence of the mitochondrial activity on Ca(2+) can be demonstrated upon equilibrating the matrix space with extramitochondrial Ca(2+) buffers. Ca(2+)-independent activity is seen following protonophore-mediated uncoupling, when uncoupling arises through alamethicin-mediated pore formation, or upon opening the permeability transition pore. Under the latter conditions, activity continues in the presence of excess EGTA but is somewhat enhanced by exogenous Ca(2+). The Ca(2+)-independent activity is best seen in media of high ionic strength and displays a broad pH optimum located between pH 8 and pH 8.5. It is strongly inhibited by bromoenol lactone but not by arachidonyl trifluoromethyl ketone, dithiothreitol, and other inhibitors of particular phospholipase A(2) classes. Immunoanalysis of mitochondria and mitochondrial subfractions shows that a membrane-bound protein is present that is recognized by antibody against an authentic iPLA(2) that was first found in P388D(1) cells. It is concluded that mitochondria contain a distinct Ca(2+)-independent phospholipase A(2) that is regulated by bioenergetic parameters. It is proposed that this enzyme, rather than the Ca(2+)-dependent type IIA phospholipase A(2), initiates the removal of poorly functioning mitochondria by processes involving autolysis.     

Effects of phospholipase A2 inhibitors on ruthenium red-induced Ca2+ release from mitochondria

The pharmacologic agents verapamil, nifedipine, diltiazem, prenylamine, N-oleoylethanolamine, R 24571, trifluoperazine, dibucaine, and quinacrine are examined as potential inhibitors of rat liver mitochondrial phospholipase A2 acting on endogenous phospholipid. Their potency as inhibitors of the enzyme is compared to their activities as inhibitors of phospholipase A2-dependent swelling and ruthenium red-induced Ca2+ release in intact mitochondria. For verapamil, diltiazem, trifluoperazine, dibucaine, and quinacrine, there is complete agreement between the relative potencies as inhibitors of phospholipase A2 and the two other processes. Nifedipine and prenylamine, which are weak inhibitors of phospholipase A2, produce a permeable inner membrane, provided that the mitochondrial have accumulated Ca2+. R 24571, which strongly inhibits the enzyme, disrupts mitochondria by a Ca2+-independent mechanism. N-Oleoylethanolamine, which is an effective inhibitor of swelling, does not inhibit phospholipase A2 or ruthenium red-induced Ca2+ release. The results support a proposed scheme wherein ruthenium red-induced Ca2+ release is viewed as reverse activity of the Ca2+-uptake uniporter occurring subsequent to decline in the proton motive force. The latter effect is proposed to arise from a specific phospholipase A2-dependent increase in inner-membrane H+ conductance of mitochondrial subpopulations. It is further shown that mitochondrial membranes display cyclic oscillations in free fatty acid content which are not dependent on the presence of Ca2+ or on the capacity to generate acylcoenzyme A.     

1-14C]oleate-labeled autoclaved yeast: a membranous substrate for measuring phospholipase A2 activity in vitro

Radiolabeled, autoclaved yeast were tested as a substrate for mammalian phospholipase A2 activity because the only other membranous substrate used for this purpose, autoclaved Escherichia coli, totally lacks a major mammalian phospholipid, phosphatidylcholine. Candida albicans were grown in the presence of [1-14C]oleate and then autoclaved. Sixty three percent of the incorporated label was in yeast phospholipid, and more than 95% of that was in the 2-acyl position. The distribution of label in the yeast phospholipids (phosphatidylcholine and -ethanolamine, -serine + -inositol, and phosphatidic acid corresponded closely to the chemical distribution of phosphorus in those phospholipids. Snake venom (Naja naja) and human synovial fluid phospholipase A2 hydrolyzed yeast phospholipid exclusively to release 14C-labeled fatty acid. When 50-60% of the yeast phospholipid was hydrolyzed, the radioactive fatty acids as determined by gas-liquid chromatographic analysis were predominantly oleate (45%) and linoleate (greater than 54%). Hydrolysis of yeast phospholipid by both enzymes was near-linear with protein and time under conditions of optimal pH (neutral-alkaline) and Ca2- (1-5 mM) previously reported for optimal hydrolysis of autoclaved E. coli phospholipid. N. naja phospholipase A2 showed less preference for phosphatidylethanolamine than -choline as liposomes or yeast phospholipid as compared to human synovial fluid phospholipase A2 which clearly preferred phosphatidylethanolamine to -choline as a liposome or yeast phospholipid. These results illustrate that radiolabeled phospholipids of autoclaved yeast, enriched in phosphatidylcholine, are readily hydrolyzed by snake venom and human nonpancreatic phospholipases A2 and may, therefore, be useful in the measurement of in vitro enzymatic activity.     

An amphitropic cAMP-binding protein in yeast mitochondria. 2. Phospholipid nature of the membrane anchor

We describe the first example of a mitochondrial protein with a covalently attached phosphatidylinositol moiety acting as a membrane anchor. The protein can be metabolically labeled with both stearic acid and inositol. The stearic acid label is removed by phospholipase D whereupon the protein with the retained inositol label is released from the membrane. This protein is a cAMP receptor of the yeast Saccharomyces cerevisiae and tightly associated with the inner mitochondrial membrane. However, it is converted into a soluble form during incubation of isolated mitochondria with Ca2+ and phospholipid (or lipid derivatives). This transition requires the action of a proteinaceous, N-ethylmaleimide-sensitive component of the intermembrane space and is accompanied by a decrease in the lipophilicity of the cAMP receptor. We propose that the component of the intermembrane space triggers the amphitropic behavior of the mitochondrial lipid-modified cAMP-binding protein through a phospholipase activity.     

The yeast mitochondrial carrier proteins Mrs3p/Mrs4p mediate iron transport across the inner mitochondrial membrane

The yeast proteins Mrs3p and Mrs4p are two closely related members of the mitochondrial carrier family (MCF), which had previously been implicated in mitochondrial Fe²⁺ homeostasis. A vertebrate Mrs3/4 homologue named mitoferrin was shown to be essential for erythroid iron utilization and proposed to function as an essential mitochondrial iron importer. Indirect reporter assays in isolated yeast mitochondria indicated that the Mrs3/4 proteins are involved in mitochondrial Fe²⁺ utilization or transport under iron-limiting conditions. To have a more direct test for Mrs3/4p mediated iron uptake into mitochondria we studied iron (II) transport across yeast inner mitochondrial membrane vesicles (SMPs) using the iron-sensitive fluorophore PhenGreen SK (PGSK). Wild-type SMPs showed rapid uptake of Fe²⁺ which was driven by the external Fe²⁺ concentration and stimulated by acidic pH. SMPs from the double deletion strain mrs3/4Δ failed to show this rapid Fe²⁺ uptake, while SMPs from cells overproducing Mrs3/4p exhibited increased Fe²⁺ uptake rates. Cu²⁺ was transported at similar rates as Fe²⁺, while other divalent cations, such as Zn²⁺ and Cd²⁺ apparently did not serve as substrates for the Mrs3/4p transporters. We conclude that the carrier proteins Mrs3p and Mrs4p transport Fe²⁺ across the inner mitochondrial membrane. Their activity is dependent on the pH gradient and it is stimulated by iron shortage.     

The phospholipase A2-induced increase in the permeability of phospholipid membranes to Ca2+ and H+ ions

The permeability of liposomes prepared from beef heart mitochondrial phospholipids was studied after treatment with phospholipase A2. The permeability to H+ ions was measured by recording the rate of change of pH in the external medium following an addition of an aliquot of alkali to liposomes with a highly buffered inner medium, while the penetration of Ca2+ ions into liposomes was measured in liposomes loaded with arsenazo III. There was a doubling of H+ permeability when the lysophospholipid content was increased to 2% by treatment with phospholipase A2, and a tripling at 4%. Entrapped sucrose leakage from liposomes became apparent at above 6% lysophospholipid. Treatment with phospholipase A2 stimulated Ca2+ penetration into liposomes driven by a valinomycin-induced diffusion potential or a nigericin-induced H+ gradient. The data are discussed in relation to the mechanism of damage to mitochondria occurring in Ca2+ overload as well as in phospholipase A2-induced cellular damage.     

Lysosomal phospholipase A activities of rat ovarian tissue.

1.1. Lysosome-enriched fractions were prepared by differential centrifugation of homogenates of luteinized rats ovaries. Acid phospholipase A activities were characterized with [U-14C]diacyl-sn-glycero-3-phosphocholine and 1-palmitoyl-2-[9,10-3H]- or [1-14C]oleoyl-sn-glycero-3-phosphocholine as substrates. Acid phospholipase A1 activity had properties similar to other hydrolases of lysosomal origin; subcellular distribution, latency and acidic pH optimum. Acid phospholipase A2 activity with similar characteristics was also tentatively identified. We were unable to exclude the possibility that the combined action of phospholipase A1 and lysophospholipase contributed to the release of acyl moieties from the 2-position of the synthetic substrates. 2. Lysophospholipase activity was present in the lysosome-enriched fractions. This activity had an alkaline pH optimum. 3. Phospholipase A1 and A2 activities solubilized from lysosome fractions by freeze-thawing were inhibited by Ca2+ and slightly activated by EDTA. A Ca2+- stimulated phospholipase A2 activity, with an alkaline pH optimum, remained in the particulate residue of freeze-thawed lysosome preparations. This activity is believed to represent mitochondrial contamination. 4. Activities of acid phospholipase A, as well as other acid hydrolases, increased approx. 1.5-fold between 1 and 4 days following induction of luteinizatin, suggesting a hormonal influence on lysosomal enzyme activities.     

In vitro inhibition of lysosomal phospholipase A1 of rat lung by amiodarone and desethylamiodarone

Amiodarone causes phospholipid storage in the lysosomes of various types of lung cell in animals and man. It has been proposed that this is due to its ability to inhibit lysosomal phospholipase A. To investigate this further, a crude lysosomal fraction from rat lung was prepared and phospholipase A was isolated and its positional specificity was determined. Analysis of the products formed after incubation with 2-[1-14C]oleoylphosphatidylcholine showed that only phospholipase A1 activity is present. This soluble preparation of lung lysosomal phospholipase A1 was used to study inhibition by amiodarone and desethylamiodarone, in vitro. Both were extremely potent inhibitors of the lung acid phospholipase A1. To evaluate the levels of amiodarone in lung lysosomes, rats were treated with the agent for 3 days and the combined mitochondrial/lysosomal fraction of lung tissue was prepared by differential centrifugation. This fraction had been shown previously to be highly enriched in amiodarone. Purified mitochondria and lysosomes were isolated from the combined mitochondrial/lysosomal fraction with Percoll gradients and analyzed for their drug content by HPLC. Amiodarone and desethylamiodarone were present in roughly equal amounts, relative to protein, in mitochondria and lysosomes, respectively. Amiodarone appears to differ from other cationic amphiphilic drugs which cause lipidosis because the latter are more highly lysosomotropic. Although amiodarone does not appear to be highly lysosomotropic in lung, it causes lysosomal phospholipid storage because of its ability to concentrate in lung and because it inhibits lysosomal phospholipase A to a much greater extent than other cationic amphiphiles such as diethylaminoethoxyhexestrol, chloroquine and chlorphentermine.     

The role of lipid-protein interactions in NADH-cytochrome c reductase (rotenone-insensitive) of rat liver mitochondria

The phospholipid depletion of rat liver mitochondria, induced by acetone-extraction or by digestion with phospholipase A₂ or phospholipase C, greatly inhibited the activity of NADH-cytochrome c reductase (rotenone-insensitive). A great decrease of the reductase activity also occurred in isolated outer mitochondrial membranes after incubation with phospholipase A₂. The enzyme activity was almost completely restored by the addition of a mixture of mitochondrial phospholipids to either lipid-deficient mitochondria, or lipid-deficient outer membranes. The individual phospholipids present in the outer mitochondrial membrane induced little or no stimulation of the reductase activity. Egg phosphatidylcholine was the most active phospholipid, but dipalmitoyl phosphatidylcholine was almost ineffective. The lipid depletion of mitochondria resulted in the disappearance of the non-linear Arrhenius plot which characterized the native reductase activity. A non-linear plot almost identical to that of the native enzyme was shown by the enzyme reconstituted with mitochondrial phospholipids. Triton X-100, Tween 80 or sodium deoxycholate induced only a small activation of NADH-cytochrome c reductase (rotenone-insensitive) in lipiddeficient mitochondria. The addition of cholesterol to extracted mitochondrial phospholipids at a 1 : 1 molar ratio inhibited the reactivation of NADH-cytochrome c reductase (rotenone-insensitive) but not the binding of phospholipids to lipid-deficient mitochondria or lipid-deficient outer membranes.These results show that NADH-cytochrome c reductase (rotenone-insensitive) of the outer mitochondrial membrane requires phospholipids for its activity. A mixture of phospholipids accomplishes this requirement better than individual phospholipids or detergents. It also seems that the membrane fluidity may influence the reductase activity.     

Adriamycin, a drug interacting with acidic phospholipids, blocks import of precursor proteins by isolated yeast mitochondria

Acidic phospholipids such as cardiolipin partially unfold an artificial precursor protein which consists of a mitochondrial presequence fused to mouse dihydrofolate reductase (Endo, T., and Schatz, G. (1988) EMBO J. 7, 1153-1158). We now show that import of this precursor protein into isolated yeast mitochondria is blocked by adriamycin, a drug binding to cardiolipin and other acidic phospholipids. This inhibition is lessened if the precursor's dihydrofolate reductase moiety is labilized by point mutations; inhibition is abolished altogether if the "wild-type" precursor is presented to mitochondria in a urea-denatured state. These and other observations suggest that adriamycin interferes with the generation of a translocation-competent, loose structure of the precursor protein. They imply that acidic phospholipids such as cardiolipin participate, directly or indirectly, in the translocation of this fusion protein into isolated mitochondria.     

Cloning, expression and biochemical characterization of a basic-acidic hybrid phospholipase A2-II from Agkistrodon halys pallas

A cDNA encoding a basic-acidic hybrid phospholipase A2-II from Agkistrodon halys Pallas with an N-terminus highly homologous to that of BPLA2 and a C-terminus sequence almost the same as that of APLA2 was inserted into a bacterial expression vector and effectively expressed in Escherichia coli RR1. The protein was produced as insoluble inclusion bodies. After partial purification by washing, the inclusion bodies with Triton X-100, denaturing and refolding, the renatured recombinant protein was purified by FPLC column superose 12. The purified recombinant enzyme with an isoelectric point of pH 6.8 could cross-react with antiserum prepared against acidic phospholipase A2. The enzymatic activity of the expressed basic-acidic hybrid phospholipase A2-II is close to that of denatured-refolded native basic phospholipase A2, and has the same inhibiting effect on platelet aggregation as denatured-refolded acidic phospholipase A2, but lacks the hemolytic activity of denatured-refolded basic phospholipase A2. To study the structural relationships among basic phospholipase A2, acidic phospholipase A2 and basic-acidic hybrid phospholipase A2-II, molecular modeling of basic-acidic hybrid phospholipase A2-II was done. The roles of various amino acid residues in the enzymatic activity and pharmacological activities of phospholipase A2 are discussed.     

A protein inhibitor of mitochondrial adenosine triphosphatase (F1) from Saccharomyces cerevisiae.

A heat-stable protein has been detected in Saccharomyces cerevisiae which inhibits mitochondrial ATPase activity. The protein inhibitor has been isolated from extracts prepared by brief heat treatment of unbroken cell suspensions. The isolated inhibitor is a small basic protein (molecular weight close to 7000, isoelectric proint 9.05) devoid of tryptophan, tyrosine, and cysteine as well as proline. The NHP2-terminal amino acid is serine. The ultraviolet absorption spectrum shows the vibrational fine structure of the phenyl-alanine band. Like the ATPase inhibitor from bovine heart mitochondria the yeast inhibitor is rapidly destroyed by trypsin. It is also inactivated by the yeast proteinases A and B. Radioimmunological analysis indicates that the inhibitor is synthesized on cytoplasmic ribosomes. Its accumulation seems to be connected to the formation of the mitochondrial ATPase complex, since its specific activity is greatly reduced both in extracts obtained from the F1-ATPase-deficient nuclear mutant pet 936 and from the cytoplasmic petite mutant D 273-10B-1.     

Purification of a Class B1 platelet aggregation inhibitor phospholipase A2 from Indian cobra (Naja Naja) venom

A platelet aggregation inhibitor phospholipase A(2) (NND-IV-PLA(2)) was isolated from Naja naja (Eastern India) venom by a combination of cation and anion exchange chromatography. NND-IV-PLA(2) is the most catalytically active enzyme isolated from the Indian cobra venom. The acidic PLA(2) profile of Eastern regional Indian cobra venom is distinctly different from that of the western regional venom. However the acidic PLA(2)s from both the regions follow the pattern of increasing catalytic activity with increase in acidic nature of the PLA(2) isoform. NND-IV-PLA(2) is a Class B1 platelet aggregation inhibitor and inhibits platelet aggregation induced by ADP, collagen and epinephrine. Modification of active site histidine abolishes both catalytic activity and platelet aggregation inhibition activities while aristolochic acid, a phospholipase A(2) inhibitor has only partial effect on the two activities.     

Hydrolysis of membrane-associated phosphoglycerides by mitochondrial phospholipase A2

Conversion of membrane-bound substrates by membrane-associated enzymes can proceed in principle via intramembrane and intermembrane action. By using rat-liver mitochondria containing labeled phosphatidylethanolamine and inactivated phospholipase A2 as substrate source, and mitochondria containing unlabeled substrate and active enzyme, it is shown that hydrolysis of phosphatidylethanolamine by mitochondrial phospholipase A2 proceeds nearly entirely via intramembrane enzyme action. A study of the characteristics of this mode of enzyme action showed that all mitochondrial phosphoglycerides were hydrolyzed. Plots of approximate initial velocities of hydrolysis against the remaining amounts of each individual phospholipid, indicated that phosphatidylethanolamine was hydrolyzed fastest, with a rate about twice that for phosphatidylcholine and about 10-fold that for cardiolipin. The initial rates remained nearly constant in the initial phase of the hydrolysis, suggesting that the enzyme is surrounded by excess substrate.     

Ca2+ Induces a Cyclosporin A-Insensitive Permeability Transition Pore in Isolated Potato Tuber Mitochondria Mediated by Reactive Oxygen Species

Oxidative damage of mammalian mitochondria induced by Ca²⁺ and prooxidants is mediated by the attack of mitochondria-generated reactive oxygen species on membrane protein thiols promoting oxidation and cross-linkage that leads to the opening of the mitochondrial permeability transition pore (Castilho et al., 1995). In this study, we present evidence that deenergized potato tuber (Solanum tuberosum) mitochondria, which do not possess a Ca²⁺ uniport, undergo inner membrane permeabilization when treated with Ca²⁺ (>0.2 mM), as indicated by mitochondrial swelling. Similar to rat liver mitochondria, this permeabilization is enhanced by diamide, a thiol oxidant that creates a condition of oxidative stress by oxidizing pyridine nucleotides. This is inhibited by the antioxidants catalase and dithiothreitol. Potato mitochondrial membrane permeabilization is not inhibited by ADP, cyclosporin A, and ruthenium red, and is partially inhibited by Mg²⁺ and acidic pH, well known inhibitors of the mammalian mitochondrial permeability transition. The lack of inhibition of potato mitochondrial permeabilization by cyclosporin A is in contrast to the inhibition of the peptidylprolyl cis–trans isomerase activity, that is related to the cyclosporin A-binding protein cyclophilin. Interestingly, the monofunctional thiol reagent mersalyl induces an extensive cyclosporin A-insensitive potato mitochondrial swelling, even in the presence of lower Ca²⁺ concentrations (>0.01 mM). In conclusion, we have identified a cyclosporin A-insensitive permeability transition pore in isolated potato mitochondria that is induced by reactive oxygen species.     

A continuous spectrophotometric assay for phospholipase A(2) activity

This paper describes a simple continuous spectrophotometric method for assaying phospholipase A(2) (PLA(2)) activity. The procedure is based on a coupled enzymatic assay, using dilinoleoyl phosphatidylcholine as phospholipase substrate and lipoxygenase as coupling enzyme. The linoleic acid released by phospholipase was oxidized by lipoxygenase and then phospholipase activity was followed spectrophotometrically by measuring the increase in absorbance at 234 nm due to the formation of the corresponding hydroperoxide from the linoleic acid. The optimal assay concentrations of hog pancreatic phospholipase A(2) and lipoxygenase were established. PLA(2) activity varied with pH, reaching its optimal value at pH 8.5. Scans of the deoxycholate concentration pointed to an optimal detergent concentration of 3mM. Phospholipid hydrolysis followed classical Michaelis-Menten kinetics (V(m)=1.8 microM/min, K(m)=4.5 microM, V(m)/K(m)=0.4 min(-1)). This assay also allows PLA(2) inhibitors, such as p-bromophenacyl bromide or dehydroabietylamine acetate, to be studied. This method was proved to be specific since there was no activity in the absence of phospholipase A(2). It also has the advantages of a short analysis time and the use of commercially nonradiolabeled and inexpensive substrates, which are, furthermore, natural substrates of phospholipase A(2).     

Ca2+ transport in mitochondria from yeast expressing recombinant aequorin

We have expressed aequorin in mitochondria of the yeast Saccharomyces cerevisiae and characterized the resulting strain with respect to mitochondrial Ca(2+) transport in vivo and in vitro. When intact cells are suspended in water containing 1.4 mM ethanol and 14 mM CaCl(2), the matrix free Ca(2+) concentration is 200 nM, similar to the values expected in cytoplasm. Addition of ionophore ETH 129 allows an active accumulation of Ca(2+) and promptly increases the value to 1.2 microM. Elevated Ca(2+) concentrations are maintained for periods of 6 min or longer under these conditions. Isolated yeast mitochondria oxidizing ethanol also accumulate Ca(2+) when ETH 129 is present, but the cation is not retained depending on the medium conditions. This finding confirms the presence of a Ca(2+) release mechanism that requires free fatty acids as previously described [P.C. Bradshaw et al. (2001) J. Biol. Chem. 276, 40502-40509]. When a respiratory substrate is not present, Ca(2+) enters and leaves yeast mitochondria slowly, at a specific activity near 0.2 nmol/min/mg protein. Transport under these conditions equilibrates the internal and external concentrations of Ca(2+) and is not affected by ruthenium red, uncouplers, or ionophores that perturb transmembrane gradients of charge and pH. This activity displays sigmoid kinetics and a K(1/2) value for Ca(2+) that is near to 900 nM, in the absence of ethanol or when it is present. It is furthermore shown that the activity coefficient of Ca(2+) in yeast mitochondria is a function of the matrix Ca(2+) content and is substantially larger than that in mammalian mitochondria. Characteristics of the aequorin-expressing strain appear suitable for its use in expression-based methods directed at cloning Ca(2+) transporters from mammalian mitochondria and for further examining the interrelationships between mitochondrial and cytoplasmic Ca(2+) in yeast.     

Lipid protein interactions in mitochondria. VII. A comparison of the effects of lipid removal and lipid perturbation of the kinetic properties of mitochondrial ATPase.

We investigated the kinetics of mitochondrial ATPase in bovine heart mitochondria and submitochondrial particles upon treatment with phospholipase A2, or upon addition of n-butanol to perturb the lipid protein interactions. The changes observed are the following: (1) Lipid removal or perturbation with butanol is accompanied by loss of ATPase activity with decrease of both V and of the KM for ATP. (2) There are changes of activation energy of ATPase activity at temperatures above the discontinuity normally observed for membrane-bound enzymes in mitochondria. In particular, butanol abolishes the discontinuity, and induces a constant activation energy of about 32 kcal/mol in the range 8--37 degrees C. (3) Butanol modifies the pH dependence of ATPase shifting the pH optimum from around 10 to less alkaline values. The optimum for Mg2+ concentrations is increased by the solvent. (4) Treatment with phospholipase A2 results in a removal of oligomycin-sensitive ATPase, whereas butanol addition prevents oligomycin inhibition of ATPase. (5) In beef heart mitochondria, a spin-labelled analog of the inhibitor, dicyclohexyl carbodiimide, did not show any change in environment upon butanol addition, unlike that found in mitochondria from Saccharomyces cerevisiae.