Alteration of the enzymatic properties of smooth muscle myosin by a monoclonal antibody against subfragment 2.

The fluorescent dye 10-N-nonyl acridine orange (NAO), known as specifically associated with mitochondria, has been reported to have a cytotoxic effect when high doses were applied to cells. Presently, the biochemical basis of its toxicity was investigated on isolated rat liver mitochondria. At low concentrations, NAO strongly inhibited state 3 respiration and ATP synthesis. At high concentrations, electron transport, ATP hydrolysis, P_i-transport and adenine nucleotide activities were also decreased. All these inhibitions can be explained by probe-cardiolipin interactions which could induce the collapse of energy conversion and/or the modification of membrane fluidity.     

The effects of oligomycin on content of adenylates in mesophyll protoplasts,chloroplasts and mitochondria from Pb<Superscript>2+</Superscript> treated pea and barley leaves

The effects of oligomycin on photosynthesis and respiration in relation to ATP production in chloroplasts and mitochondria were investigated in protoplasts isolated from the detached pea (Pisum sativum L cv. Iłowiecki.) and barley (Hordeum vulgare L. cv. Gunilla) leaves treated 5 mM Pb(NO₃)₂. The oligomycin (OM), an inhibitor of oxidative phosphorylation at 0.1 μM concentration caused the inhibition of photosynthesis rate in the protoplasts from both the control and the Pb-treated pea leaves. The respiration rate and ATP/ADP ratio in the protoplasts and the activity of ATPase in mitochondria, were also diminished in the control protoplasts. These effects were not observed in the protoplasts and mitochondria isolated from the Pb-treated leaves. Oligomycin, an inhibitor of photophosphorylation at 10 μM concentration decreased ATPase activity in chloroplasts from both the control and the Pb- treated leaves. Using the method of rapid fractionation of barley protoplasts it was shown that the ATP/ADP ratio in the mitochondria from Pb-treated leaves was largely suppressed (from 1.8 to 0.4) by OM under nonphotorespiratory conditions (high CO₂), whereas under photorespiratory conditions (low CO₂) this ratio was high (5.3) and under OM decreased less (to 3.1). Our results indicate that oligomycin, in organelle isolated from Pb-treated leaves, had no inhibitory effect on the mitochondrial ATPase, whereas it inhibited chloroplasts ATPase. We suggest that Pb ions affected the catalytic cycle and/or conformational changes of ATPase in pea chloroplasts differently than in mitochondria. The differences in Pb responses may reflect fine mechanisms for the regulation of ATP production in the plant cells under stress conditions.     

Phosphorylation of deoxyguanosine in intact and fractured mitochondria

The phosphorylation of deoxyguanosine was measured in fractured and intact mitochondria and an apparent K_m of 16 M for deoxyguanosine was calculated using fractured mitochondria. The effects of various deoxynucleotides on the phosphorylating activity in fractured organelles was tested at both a high and low ratio of NXP/ATP and at two pH values, 7.0 and 5.5. Exogenous dGTP, dGDP or dITP were inhibitory under all conditions tested. With a NXP/ATP ratio of 0.08 at pH 7.0, TTP, TDP, dADP, ADP, UTP and UDP were stimulatory, but at pH 5.5 only TTP elicited that response. When the NXP/ATP ratio was 10 at pH 5.5, TTP and UTP increased the activity more than 10-fold, whereas, at pH 7.0 TTP, TDP, dADP, ADP, UTP, UDP caused stimulation, but to a much lesser extent. When exogenous Mg²⁺, Mn²⁺ or Ca²⁺ were added to intact mitochondria, the rates of phosphorylation were lowered. In fractured mitochondria in the absence of exogenous ATP, little phosphorylation occurs, hence these metal ions caused little change. ATP-Mg, ATP-Mn and ATP-Ca, each at 0.05 mM caused a small inhibition with intact mitochondria, whereas, these compounds supported phosphorylation with fractured organelles. ATP-Mn (10 mM) or ATP-Ca (10 mM) stimulated phosphorylation in both intact and fractured mitochondria. Intact mitochondria synthesized dGMP, dGDP and dGTP when metal ion or ATP-Me concentrations were low (0.05 mM) or when Mg²⁺ concentration was high (10 mM). Additions of ATP-Ca, ATP-Mn, ATP-Mg, Mn²⁺ or Ca²⁺ at 10 mM cause the loss of dGDP and dGTP formation and, in most cases, an increase in the synthesis of dGMP. Fractured mitochondria make only dGMP and the levels of its synthesis are greater than that observed for intact mitochondria. These data suggest that intact mitochondria are required for the synthesis of dGTP and that its synthesis is regulated by mitochondria nucleotides.     

Increase of membrane permeability of mitochondria isolated from water stress adapted potato cells

In order to gain some insight into mitochondria permeability under water stress, intact coupled mitochondria were isolated from water stress adapted potato cells and investigations were made of certain transport processes including the succinate/malate and ADP/ATP exchanges, the plant mitochondrial ATP-sensitive potassium channel (PmitoK_ATP) and the plant uncoupling mitochondrial protein (PUMP). The V _maxL values measured for succinate/malate and ADP/ATP carriers, as photometrically investigated, as well as the same values for the Pmito_ATP and the PUMP were found to increase; this suggested that mitochondria adaptation to water stress can cause an increase in the membrane permeability.     

Brief antecedent anoxia preserves mitochondrial function after sustained undersupply: A subcellular correlate to ischemic preconditioning?

Background: There is increasing evidence that mitochondria – owning a high degree of autonomy within the cell – might represent the target organelles of the myocardial protection afforded by ischemic preconditioning. It was the aim of the study to investigate a possible subcellular correlate to ischemic preconditioning at the mitochondrial level. In addition, we tested whether this protection depends on mitochondrial ATP-dependent potassium channels (K _ATP) and an might involve an attenuation of mitochondrial ATP hydrolysis during sustained anoxia.Methods and Results: Sustained anoxia (A, 14 min) and reoxygenation (R) completely inhibited state 3 and state 4 respiration of isolated ventricular mitochondria from Wistar rats. An antecedent brief anoxic incubation (4 min) followed by reoxygenation (2 min) prevented this loss of mitochondrial function. The protection afforded by anoxic preconditioning could be mimicked by the K _ATP opener diazoxide (30 μmol/l) and was completely inhibited by the K _ATP blocker 5-hydroxydecanoic acid (300 μmol/l). Structural mitochondrial integrity, as estimated from externalization of the mitochondrial enzymes creatine kinase and glutamateoxalacetate transaminase, remained unchanged between the groups, as did mitochondrial ATP loss during anoxia.Conclusion: For the first time, we provide direct evidence for a subcellular preconditioning-like functional mitochondrial adaptation to sustained anoxia. This effect apparently depends on opening of K_ATP but is independent of ATP preservation.     

Adenylate kinase is a source of ATP for tumor mitochondrial hexokinase

It has proposed that hexokinase bound to mitochondria occupies a preferred site to wich ATP from oxidative phosphorylation is channeled directly (Bessman, S. (1966) Am. J. Medicine 40, 740–749). We have investigated this problem in isolated Zajdela hepatoma mitochondria. Addition of ADP to well-coupled mitochondria in the presence of an oxidizable substrate initiates the synthesis of glucose 6-phosphate via bound hexokinase. This reaction is only partially inhibited by oligomycin, carboxyatractyloside, carbonyl cyanide m-chlorophenylhydrazone (CCCP) ot any combination of these, suggesting a source of ATP in addition to oxidative phosphorylation. This source appears to be adenylate kinase, since Ado₂P₅, an inhibitor of the enzyme, suppresses hexokinase activity by about 50% when added alone or suppresses activity completely when added together with any of the inhibitors of oxidative phosphorylation. Ado₂P₅ does not uncouple oxidative phosphorylation nor does it inhibit ADP transport (state 3 respiration) or hexokinase. The relative amount of ATP contributed by adenylate kinase is dependent upon the ADP concentration. At low ADP concentraions, glucose phosphorylation is supported by oxidative phosphorylation, but as the adenine nucleotide translocator becomes saturated the ATP contributed by adenylate kinase increases due to the higher apparent K_m of the enzyme. Under conditions of our standard experiment ([ADP] = 0.5 mM), adenylate kinase provides about 50% of the ATP used by hexokinase in well-coupled mitochondria. In spite of this, externally added ATP supported higher rates of hexokinase activity than ADP. Our findings demonstrate that oxidative phosphorylation is not a specific or preferential source of ATP for hexokinase bound to hepatoma mitochondria. The apparent lack of a channeling mechanism for ATP to hexokinase in these mitochondria is discussed.     

Interaction of homogeneous mitochondrial ATPase from rat liver with adenine nucleotides and inorganic phosphate

Mitochondrial ATPase from rat liver mitochondria contains multiple nucleotide binding sites. At low concentrations ADP binds with high affinity (1 mole/mole ATPase, K_D = 1–2 μM). At high concentrations, ADP inhibits ATP hydrolysis presumably by competing with ATP for the active site (K_I = 240–300 μM). As isolated, mitochondrial ATPase contains between 0.6 and 2.5 moles ATP/mole ATPase. This “tightly bound” ATP can be removed by repeated precipitations with ammonium sulfate without altering hydrolytic activity of the enzyme. However, the ATP-depleted enzyme must be redissolved in high concentrations of phosphate to retain activity. AMP-PNP (adenylyl imidodiphosphate) replaces tightly bound ATP removed from the enzyme and inhibits ATP hydrolysis. AMP-PNP has little effect on high affinity binding of ADP. Kinetic studies of ATP hydrolysis reveal hyperbolic velocity vs. ATP plots, provided assays are done in bicarbonate buffer or buffers containing high concentrations of phosphate. Taken together, these studies indicate that sites on the enzyme not directly associated with ATP hydrolysis bind ATP or ADP, and that in the absence of bound nucleotide, P_i can maintain the active form of the enzyme.     

Bioenergetics of the heart at high altitude: environmental hypoxia imposes profound transformations on the myocardial process of ATP synthesis

The low concentration of O₂ in the thin air at high altitude is undoubtedly the reason for the remarkable modifications in the structure and function of the heart, lung, and blood of humans permanently living under these conditions. The effect of natural hypoxia on the energy metabolism of the cell is however not well understood. Here we study the proces of ATP synthesis in the heart of guinea pigs native to high altitude (4500 m) as compared with those native to sea level. The following are the novel findings of this study. (1) The rates and extents of ATP synthesis in the presence of low concentrations of ADP (<30 M) are significantly higher at high altitude than at sea level. (2) The Hill coefficient, i.e. the degree of cooperativity between the three catalytic sites of the ATP synthase, is lower at high altitude (n = 1.36) than at sea level (n = 1.94). (3) Both, the affinity for ADP and the fractional occupancy of the catalytic sites by ATP, are higher at high altitude than at sea level but the P ₅₀, i.e. the concentration of ADP at which 50% of the catalytic sites are filled with ADP and/or ATP, is the same (74.7 M). (4) In the physiological range of ADP concentrations, the phosphorylation potential G _P is significantly higher at high altitude than at sea level. It is concluded that the molecular mechanism of energy transduction is profoundly modified at high altitude in order to readily and efficiently generate ATP in the presence of low concentrations of O₂ and ADP.     

Interaction of yeast mitochondria with fatty acids and mitochondria-targeted lipophilic cations

The effect of fatty acids and mitochondria-targeted lipophilic cations (SkQ1, SkQ3, MitoQ, and C₁₂TPP) on tightly-coupled mitochondria from yeasts Dipodascus (Endomyces) magnusii and Yarrowia lipolytica was investigated. Micromolar concentrations of saturated and unsaturated fatty acids were found to decrease the membrane potential, which was recovered almost totally by ATP and BSA. At low, micromolar concentrations, mitochondria-targeted lipophilic cations are “relatively weak, mild uncouplers”, at higher concentrations they inhibit respiration in state 3, and at much higher concentrations they induce swelling of mitochondria, possibly due to their prooxidant and detergent action. At very low, not uncoupling concentrations, mitochondria-targeted lipophilic cations profoundly promote (potentiate) the uncoupling effect of fatty acids. It is conceivable that the observed uncoupling effect of lipophilic cations can be, at least partially, due to their interactions with the endogenous pool of fatty acids.     

Mitochondrial Generation of Oxygen Radicals During Reoxygenation of Ischemic Tissues

Ischemia and reperfusion causes severe mitochondrial damage, including swelling and deposits of hyd-roxyapatite crystals in the mitochondrial matrix. These crystals are indicative of a massive influx of Ca²⁺ into the mitochondrial matrix occurring during reoxygenation. We have observed that mitochondria isolated from rat hearts after 90 minutes of anoxia followed by reoxygenation, show a specific inhibition in the electron transport chain between NADH dehydrogenase and ubiquinone in addition to becoming uncoupled (unable to generate ATP). This inhibition is associated with an increased H₂O₂ formation at the NADH dehydrogenase level in the presence of NADH dependent substrates. Control rat mitochondria exposed for 15 minutes to high Ca²⁺ (200 nmol/mg protein) also become uncoupled and electron transport inhibited between NADH dehydrogenase and ubiquinone. a lesion similar to that observed in post-ischem-ic mitochondria. This Ca²⁺ -dependent effect is time dependent and may be partially prevented by albumin, suggesting that it may be due to phospholipase A₂ activation. releasing fatty acids, leading to both inhibition of electron transport and uncoupling. Addition of arachidonic or linoleic acids to control rat heart mitochondria, inhibits electron transport between Complex I and III. These results are consistent with the following hypothesis: during ischemia, the intracellular energy content drops severely, affecting the cytoplasic concentration of ions such as Na⁺ and Ca²⁺. Upon reoxygenation, the mitochondrion is the only organelle capable of eliminating the excess cytoplasmic Ca²⁺ through an electrogenic process requiring oxygen (the low ATP concentration makes other ATP-dependent Ca^?' lransport systems non-operational). Ca²⁺-overload of mitochondria activates phospholipase A₂ releasing free fatty acids, leading to uncoupling and inhibition of the interactions between Complex I and III of the respiratory chain. As a consequence, the NADH-dehydrogenase becomes highly reduced, and transfers electrons directly to oxygen generating O₂.     

Supramolecular organization of the yeast F1Fo-ATP synthase

Background information. The yeast mitochondrial F₁F_o‐ATP synthase is a large complex of 600 kDa that uses the proton electrochemical gradient generated by the respiratory chain to catalyse ATP synthesis from ADP and P_i. For a large range of organisms, it has been shown that mitochondrial ATP synthase adopts oligomeric structures. Moreover, several studies have suggested that a link exists between ATP synthase and mitochondrial morphology. Results and discussion. In order to understand the link between ATP synthase oligomerization and mitochondrial morphology, more information is needed on the supramolecular organization of this enzyme within the inner mitochondrial membrane. We have conducted an electron microscopy study on wild‐type yeast mitochondria at different levels of organization from spheroplast to isolated ATP synthase complex. Using electron tomography, freeze‐fracture, negative staining and image processing, we show that cristae form a network of lamellae, on which ATP synthase dimers assemble in linear and regular arrays of oligomers. Conclusions. Our results shed new light on the supramolecular organization of the F₁F_o‐ATP synthase and its potential role in mitochondrial morphology.     

Kinetic enhancement of bound hexokinase activity by mitochondrial respiration

These studies were designed to examine the functional relationship between respiring rat liver mitochondria and bound hexokinase. Kinetic studies were peformed varying either exogenously supplied ATP or ATP synthesized endogenously by respiring mitochondria and varied concentrations of ADP. Michaelis-Menten constants and maximum velocities were determined at two, five, and ten minutes after initiating the reactions. The K_m's and Vmax's were invariant with respect to added ATP, but the apparent K_m's varied considerably when endogenous substrate was utilized. At two minutes, the K_m for endogenous ATP was 25% of the K_m for provided ATP, but, by ten minutes, it had reached 70%. The Vmax's varied far less markedly. This is a clear demonstration of preferential utilization of mitochondrial ATP by bound hexokinase.     

Sulphide detoxification in Hediste diversicolor and Marenzelleria viridis, two dominant polychaete worms within the shallow coastal waters of the southern Baltic Sea

The polychaete worms Marenzelleria viridis (Verrill 1873) and Hediste diversicolor (O.F. Müller) form the main part of the macro-zoobenthos in soft-bottomed shallow inlets of the Baltic Sea. Due to high eutrophication within these waters the animals are exposed to low oxygen and high sulphide concentrations. Specimens of both species from a low salinity location (S 8 ‰) were compared concerning their physiological abilities in coping with this hostile environment. Sulphide detoxification occurred in both polychaetes even during severe hypoxia with the main end-product being thiosulphate. In absence of sulphide nearly no end-products of anaerobic metabolism were found in the worms during moderate hypoxia (pO₂=7 kPa). In presence of hydrogen sulphide, succinate, a sensitive indicator of anaerobic metabolism, was accumulated in higher amounts at low sulphide concentrations (0.3 mM) already. Oxygen consumption and ATP production was determined in isolated mitochondria of both species. Both polychaetes were able to perform enzymatic sulphide oxidation in the mitochondria at concentrations up to 50 μM. This process was coupled with oxidative phosphorylation. At least in M. viridis sulphide respiration was not completely inhibited by cyanide, suggesting an alternative oxidation pathway, which by-passes the cytochrome-c-oxidase. The two species did not differ in the rate of sulphide detoxification, but H. diversicolor produced about as twice as much ATP from mitochondrial sulphide oxidation. Differences in mitochondrial sulphide oxidation are probably related to the different life strategies of the worms.     

Endogenous Protein Phosphorylation in Rat Brain Mitochondria: Occurrence of a Novel ATP-Dependent Form of the Autophosphorylated Enzyme Succinyl-CoA Synthetase

Abstract: When rat brain mitochondria are incubated with [γ-³²P]ATP, there is a rapid (10 s) phosphorylation of proteins designated E, and F of M.W. 42,000 and 32,000, respectively. Although [γ-³²P]ATP was the preferred substrate for protein F, a small amount of labeling did occur with [γ-³²P]GTP. Phosphorylation of E₁ was absolutely ATP-dependent. On the other hand, a 32,000 M.W. protein from rat liver mitoplasts (mitochondria devoid of an outer membrane) was highly phosphorylated when [γ-³²P]GTP was used but not at all phosphorylated within short time periods with [γ-³²P]ATP. Both the ATP-labeled brain phosphoprotein F and GTP-labeled liver protein migrated to identical positions on high-resolution two-dimensional polyacrylamide gels, and both contained acid-labile phosphoryl groups. Furthermore, both phosphoproteins were identified as the autophosphorylated subunit of succinyl-CoA synthetase (SCS, EC 6.2.1.4) by using antibody directed against purified GTP-dependent porcine SCS. However, immunotitration experiments with anti-porcine SCS revealed that ATP- and GTP-labeled protein F in brain differed in their interactions with antibody, suggesting that in rat brain mitochondria two different forms of the enzyme exist that are immunologically distinct and differ in substrate specificity. When mitochondrial preparations enriched in particular brain cell or subcellular types were examined, an unequal distribution of E₁ and the two forms of protein F were observed. A brain subfraction containing neuronal cell body and glial mitochondria (CM) was found to contain E₁ and approximately equal amounts of the ATP- and GTP-dependent forms of protein F. Light synaptic mitochondria(SM₁) contained ATP-dependent protein F almost exclusively and were depleted in E₁. Dense synaptic mitochondria (SM₂) are rich in the ATP form of SCS but also contain low amounts of the GTP enzyme.     

Über hydrophobe Acridinfarbstoffe zur Fluorochromierung von Mitochondrien in lebenden Zellen

Summary The hydrophobic fluorescence dye 10-n-nonyl-acridinium-orange-chloride, NAO, stains specifically the mitochondria of living HeLa-cells. A dye concentration of 1·10^–8 M is sufficient for vital staining and at 5·10^–7 M an incubation time less than 1 min is enough to generate the bright green fluorescence of the mitochondria. The retention of NAO by the mitochondria is longer than 7 days.The dye accumulation is not affected by the ionophores valinomycin, nigericin, gramicidin, the uncoupling agents DNP, CCCP or by ouabain. In contrast to Rh 123 the trans-membrane potential is not the driving force of the NAO accumulation. We assume that NAO is bound to the hydrophobic lipids and proteins in the mitochondrial membranes by hydrophobic interaction.With valinomycin, 500 ng/ml, 10 min, the mitochondria in HeLa-cells swell. Now it is possible to observe some details in the enlarged mitochondria by light microscopy. After vital staining with NAO, 5·10^–7 M, 10 min, the periphery of the swollen mitochondria shows an intense green fluorescence, the inner part is dark. Obviously the dye is bound to the membranes. By electron microscopy it can be shown that the valinomycin treated and NAO stained mitochondria have outer and inner membranes and cristae. They differ from untreated mitochondria mainly in the size.After incubation of the HeLa-cells with relatively high NAO concentrations, 5·10^–6 M, 10 min, the mitochondria show a weak orange fluorescence. It is generated by the dimers D of NAO. Therefore the dye concentration in the mitochondrial membranes is locally very high and causes dye dimerisation. The weak orange fluorescence is instable and disappeares within a few seconds. Instead we observe a green fluorescence with growing intensity that is generated by the monomers M of NAO. The intensity has its maximum value after a few seconds. Using low NAO concentrations for incubation, 1·10^–7 M, 10 min, we observe only the green fluorescence with increasing intensity. In this case the orange fluorescence is too weak for observation (concentration quenching). It can be shown by experiments and quantum mechanics that the orange fluorescence is assigned to an optical forbidden, the green fluorescence to an allowed electronic transition of D or M respectively. Our results indicate a dissoziation of D in 2 M by irradiation of the mitochondria under the fluorescence microscope.The intensity changes of the orange and the green fluorescence of bound D and M by irradiation has been measured in living cells with a microspectrophotometer. The experimental data agree quantitatively with a first-order reaction mechanism for the dissoziation of D in 2 M by irradiation. There is some evidence for energy transfer between dimers at higher NAO concentration.The oxygen consumption of HeLa-cell suspensions has been measured electrochemically at various NAO concentrations and incubation times with an oxygen electrode. Up to 5·10^–7 M NAO, 10 min, the respiratory activity is not affected. After that we observe an increasing inhibition of the oxygen consumption with growing NAO concentration and incubation time. At 5·10^–6 M, 30 min, the inhibition is 40% relative to the untreated cells.The ultrastructure of the mitochondria in incubated HeLa-cells has been investigated by electron microscopy and compared with untreated cells. Similar to the resiratory experiments there is no difference in ultrastructure up to 5·10^–7 M NAO, 10 min. Then the ultrastructure changes rapidly with increasing NAO concentration and incubation time. At the final stage, 5·10^–6 M, 1 h, the cristae totally or partially disappeared. The outer and inner membranes are still visible. Obviously the mitochondria without cristae are instable and collapse. They change into liposomes with stacks of four, eight and more membranes on the periphery. They enclose cytoplasm. The genesis of the liposomes is discussed in some detail.These experiments show that the dye NAO is accumulated at the inner mitochondrial membrane and the cristae. It blocks the enzymes of the oxydative phosphorylation in the inner membranes and affects the self-organization of the cristae. NAO is specifically bound to the membranes of the mitochondria. Neither by fluorescence microscopy nor by electron microscopy we observe binding of NAO to the membranes of the nuclei.     

A comparative study of the transport of pyruvate in liver mitochondria from normal and diabetic rats

A comparative study of the transport of pyruvate in liver mitochondria from normal and diabetic rats has been carried out. TheK _m for net pyruvate uptake in diabetic, ketotic mitochondria is practically equal to that measured in normal mitochondria, while theV _max is significantly lower. The lower activity of the pyruvate translocator in diabetic mitochondria compared to normal mitochondria is also shown by swelling experiments as well as by following the rate of pyruvate-supported respiration. Pre-exposure of mitochondria from normal rats to the ketone body acetoacetate and to 2-oxobutyrate results in a decrease of theK _m for pyruvate uptake. This effect is impaired in mitochondria from diabetic animals. The results indicate that the activity and the properties of the mitochondrial pyruvate translocator are modified in the diabetic, ketotic condition.Supported by a joint grant from Consiglio Nazionale delle Ricerche, Rome, Italy, and the Polish Academy of Sciences, Warsaw, Poland.     

AMP promotes oxygen consumption and ATP synthesis in heart mitochondria through the adenylate kinase reaction: an NMR spectroscopy and polarography study

Adenylate kinase plays an important role in cellular energy homeostasis by catalysing the interconversion of adenine nucleotides. The goal of present study was to evaluate the contribution of the adenylate kinase reaction to oxidative ATP synthesis by direct measurements of ATP using ³¹P NMR spectroscopy. Results show that AMP can stimulate ATP synthesis in the presence or absence of ADP. In particular, addition of 1 mM AMP to the 0.6 mM ADP superfusion system of isolated superfused mitochondria (contained and maintained in agarose beads) led to a 25% increase in ATP synthesis as measured by the increase in βATP signal. More importantly, we show that AMP can support ATP synthesis in the absence of ADP, demonstrated as follows. Superfusion of mitochondria without ADP led to the disappearance of ATP γ, α and β signals and the increase of P_i. Addition of AMP to the medium restored the production of ATP, as demonstrated by the reappearance of γ, α and β ATP signals, in conjunction with a decrease in P_i, which is being used for ATP synthesis. Polarographic studies showed Mg²⁺ dependence of this process, confirming the specificity of the adenylate kinase reaction. Furthermore, data obtained from this study demonstrate, for the first time, that different aspects of the adenylate kinase reaction can be evaluated with ³¹P NMR spectroscopy. Copyright © 2015 John Wiley & Sons, Ltd. SIGNIFICANCE OF RESEARCH PARAGRAPH The data generated in the present study indicate that ³¹P NMR spectroscopy can effectively be used to study the adenylate kinase reaction under a variety of conditions. This is important because understanding of adenylate kinase function and/or malfunction is essential to understanding its role in health and disease. The data obtained with ³¹P NMR were confirmed by polarographic studies, which further strengthens the robustness of the NMR findings. In summary, ³¹P NMR spectroscopy provides a sensitive tool to study adenylate kinase activity in different physiological and pathophysiological conditions, including but not exclusive of, cancer, ischemic injury, hemolytic anemia and neurological problems such as sensorineural deafness.     

Some Biochemical Properties of Mitochondria Isolated from Euglena gracilis*

SYNOPSIS. Mitochondria were isolated from Euglena gracilis strain Z by pressure-breakage of the cells and sucrose-cushion centrifugation. Multiple peaks (2-4) were observed in the rate of phosphorylation with Mg-ADP-phosphate concentration curves. The phosphorylative and oxidative activities were highest with NADH as the substrate, moderate with succinate, and lowest with glutamate. Inhibition of phosphorylation with 2,4-dinitrophenol and carbonyl cyanide, m-chlorophenylhydrazone gave sigmoidal concentration curves, with the extent of inhibition by DNP depending on the substrate used. Inhibition of phosphorylation by valinomycin, atractyloside, or carboxyatractyloside was only ～ 60%. Oligomycin inhibited phosphorylation in 2 phases at low and high concentrations; it inhibited Mg-ATPase in a sigmoidal fashion. Both phosphorylation and oxidation had discontinuities in Arrhenius plots at 34 C and 18 C. The relative Mg²⁺-dependent nucleoside triphosphatase activity was: 1 for ATP and GTP, 0.6 for ITP, 0.15 for CTP and and UTP; with Ca²⁺ in place of Mg²⁺ this activity was 0.35. Both DNP and CCCP stimulated the Mg-ATPase 50-200%. The optimal pH for the stimulation was ～ 7 regardless of the uncoupler used, and ～ 8 without the uncouplers. The few differences observed between mitochondria from Euglena and those from other sources are probably due to the fragmentation of the reticular mitochondrial structure during isolation and not to unique characteristics of these mitochondria.     

Regulation of mitochondrial pyruvate uptake by alternative pyruvate carrier complexes

At the pyruvate branch point, the fermentative and oxidative metabolic routes diverge. Pyruvate can be transformed either into lactate in mammalian cells or into ethanol in yeast, or transported into mitochondria to fuel ATP production by oxidative phosphorylation. The recently discovered mitochondrial pyruvate carrier (MPC), encoded by MPC1, MPC2, and MPC3 in yeast, is required for uptake of pyruvate into the organelle. Here, we show that while expression of Mpc1 is not dependent on the carbon source, expression of Mpc2 and Mpc3 is specific to fermentative or respiratory conditions, respectively. This gives rise to two alternative carrier complexes that we have termed MPC_FERM and MPC_OX. By constitutively expressing the two alternative complexes in yeast deleted for all three endogenous genes, we show that MPC_OX has a higher transport activity than MPC_FERM, which is dependent on the C‐terminus of Mpc3. We propose that the alternative MPC subunit expression in yeast provides a way of adapting cellular metabolism to the nutrient availability.     

Mitochondrial F-type ATP synthase: multiple enzyme functions revealed by the membrane-embedded FO structure

Abstract

Of the two main sectors of the F-type ATP synthase, the membrane-intrinsic F_O domain is the one which, during evolution, has undergone the highest structural variations and changes in subunit composition. The F_O complexity in mitochondria is apparently related to additional enzyme functions that lack in bacterial and thylakoid complexes. Indeed, the F-type ATP synthase has the main bioenergetic role to synthesize ATP by exploiting the electrochemical gradient built by respiratory complexes. The F_O membrane domain, essential in the enzyme machinery, also participates in the bioenergetic cost of synthesizing ATP and in the formation of the cristae, thus contributing to mitochondrial morphology. The recent enzyme involvement in a high-conductance channel, which forms in the inner mitochondrial membrane and promotes the mitochondrial permeability transition, highlights a new F-type ATP synthase role. Point mutations which cause amino acid substitutions in F_O subunits produce mitochondrial dysfunctions and lead to severe pathologies. The F_O variability in different species, pointed out by cryo-EM analysis, mirrors the multiple enzyme functions and opens a new scenario in mitochondrial biology.