Stimulation of mitochondrial pyruvate metabolism and citrulline synthesis by dexamethasone. Effect of isolation and incubation media.

Hepatic mitochondria isolated in 0.3 M-sucrose or 0.3 M-mannitol from rats treated for 3h with dexamethasone displayed stimulated rates of pyruvate carboxylation and decarboxylation and citrulline synthesis when compared with organelles from control animals. Mitochondria isolated in mannitol also displayed elevated rates of pyruvate carboxylation and decarboxylation when compared with those isolated in sucrose, and this stimulation was shown to be independent of the lengthy isolation procedure. Citrulline synthesis proceeded at similar rates in mitochondria isolated in either sugar. The concentration of exchangeable adenine nucleotides was identical in mitochondria isolated in sucrose or mannitol, suggesting that those prepared in the former sugar are not more permeable to metabolites than those prepared in the latter. The matrix volume of mitochondria isolated in mannitol was greater than that of mitochondria isolated in sucrose, and the effect of mannitol on pyruvate metabolism was mimicked by swelling the organelles in hypo-osmotic sucrose. Measurements of the extra-matrix volume by using [14C]sucrose or [14C]mannitol suggest that mannitol can permeate mitochondria to a greater extent than can sucrose. The possibility that mannitol elicits its effect by entering the mitochondrial matrix and so initiating swelling is discussed.     

The intramitochondrial volume measured using sucrose as an extramitochondrial marker overestimates the true matrix volume determined with mannitol.

The matrix volume of isolated liver and heart mitochondria has been estimated at various osmolarities and in various osmotic supports using 36Cl- and [14C]sucrose, D-mannitol, D-3-methoxyglucose and choline as extramitochondrial markers. The use of 3-methoxyglucose was only possible at 0 degree C since it entered mitochondria at physiological temperatures. All extramitochondrial markers used gave linear plots of apparent matrix volume against the reciprocal of the osmolarity, but the slope of this plot was greater when sucrose was used than with the other extramitochondrial markers. When extrapolated to infinite osmolarity the mean matrix volume was zero when mannitol was used, but about 0.6 microliter/mg of protein for sucrose and Cl- and -0.4 microliter/mg of protein when choline was used. At physiological osmolarity (about 330 m-osmol) the mean matrix volume of de-energized liver mitochondria in KCl medium estimated using mannitol was 0.46 microliter/mg of protein, whereas that obtained using sucrose was 1.68 microliters/mg of protein. Values in mannitol, choline and sucrose media were similar when mannitol but not sucrose was used as extramitochondrial marker. It is argued that the 3H2O/[14C]mannitol space more accurately reflects the true mitochondrial matrix volume than does the 3H2O/[14C]sucrose space. The consequences of this for measurements of the protonmotive force and the intramitochondrial concentration of metabolites are discussed.     

Measurements of mitochondrial volumes are affected by the amount of mitochondria used in the determinations.

Mitochondrial water spaces were determined by centrifugal filtration, by using 3H2O and [14C]-sucrose, -mannitol, -inulin and -dextran. The volume (in microliter/mg of mitochondrial protein) of each of the spaces was inversely proportional to the amount of mitochondria (mg of protein) centrifuged. The dextran space (representing extramitochondrial water carried down with the mitochondria) decreased the most, and accounted for most of the changes observed in the other spaces. However, the calculated matrix and intermembrane spaces also decreased when increasing amounts of mitochondria were centrifuged. For each space, the same value was obtained when centrifugal filtration was done at 8000 and at 15,600 g, and when the mitochondria were incubated with the markers for 15 s to 5 min, indicating that sucrose, mannitol and inulin do not penetrate the matrix, nor does dextran penetrate the intermembrane space, under the incubation and centrifugation conditions generally used to measure mitochondrial spaces.     

The reversible Ca2+-induced permeabilization of rat liver mitochondria.

Rat liver mitochondria became permeabilized to sucrose according to an apparent first-order process after accumulating 35 nmol of Ca2+/mg of protein in the presence of 2.5 mM-Pi, but not in its absence. A fraction (24-32%) of the internal space remains sucrose-inaccessible. The rate constant for permeabilization to sucrose decreases slightly when the pH is decreased from 7.5 to 6.5, whereas the rate of inner-membrane potential (delta psi) dissipation is markedly increased, which indicates that H+ permeation precedes sucrose permeation. Permeabilization does not release mitochondrial proteins. [14C]Sucrose appears to enter permeabilized mitochondria instantaneously. Chelation of Ca2+ with EGTA restores delta psi and entraps sucrose in the matrix space. With 20 mM-sucrose at the instant of resealing, about 21 nmol of sucrose/mg of protein becomes entrapped. The amount of sucrose entrapped is proportional to the degree of permeabilization. Entrapped sucrose is not removed by dilution of the mitochondrial suspension. Resealed mitochondria washed three times retain about 74% of the entrapped sucrose. In the presence of Ruthenium Red and Ca2+ buffers permeabilized mitochondria reseal only partially with free [Ca2+] greater than 3 microM. [14C]Sucrose enters partially resealed mitochondria continuously with time, despite maintenance of delta psi, in accordance with continued interconversion of permeable and impermeable forms. Kinetic analyses of [14C]sucrose entry indicate two Ca2+-sensitive reactions in permeabilization. This conclusion is supported by the biphasic time courses of resealing and repolarization of permeabilized mitochondria and the acute dependence of the rapid repolarization on the free [Ca2+]. A hypothetical model of permeabilization and resealing is suggested and the potential of the procedure for matrix entrapment of substances is discussed.     

Glutamine transport and metabolism by mitochondria from dog renal cortex. General properties and response to acidosis and alkalosis.

Mitochondria from dog renal cortex were incubated with L-[14Cglutamine. Glutamate metabolism was prevented by inhibitors so that glutamate accumulated either in the mitochondrial matrix space or in the medium. The formation and accumuation of glutamate formed from glutamine and the distribution of glutamine in the mitochondrial fluid spaces were studied. In the matrix space glutamate rapidly reaches levels over 5 times that of glutamine in the medium. A more gradual accumulation occurs in the medium as glutamate is transported out of the mitochondria. Addition of an energy source such as succinate to the medium accelerates glutamate formation. A Km of 0.6 mM appears to govern the reaction at low concentrations of glutamine; at about 4 mM an abrupt change kinetics occurs with a Km of 5 mM above that level. Both NH4+ and glutamate inhibit glutamine metabolism and phosphate stimulates it, but little effect glutamate or phosphate occurs at low levels of these substances. The pH optimum of the reaction is between 7.4 and 7.8. Mersalyl and p-chloromercuribenzoate strongly inhibit glutamate formation; N-ethylmaleimide and bromcresol green have weaker inhibitory actions, and borate increases the reaction rate. In the presence of mersalyl, glutamine is striclly confined to the outer space of mitochondria and none is detectable in the matrix space. Similarly at ) degrees glutamine is confined to the simultaneously determined sucrose or mannitol spaces...     

Evidence that glucagon stabilizes rather than activates mitochondrial functions in rat liver

The present study is concerned with the question as to whether the acute treatment of intact rats or hepatocytes with glucagon and dibutyryl cAMP, respectively, leads to a stabilization or an activation of mitochondrial functions, such as state-3 respiration, succinate dehydrogenase activity and pyruvate carboxylase activity. For this purpose, the influence of various parameters of mitochondria preparation (isolation medium, washing steps, storage) as well as of phospholipase A inhibitors (cinchocain, chloroquine) on the expression of the hormone effect was examined. With regard to the above mentioned functions, the values displayed by control mitochondria were found to be considerably higher if mannitol instead of sucrose had been used for isolation. Accordingly, only small effects of hormone treatment became apparent. The addition of cinchocain or chloroquine to the sucrose medium yielded results similar to those obtained with mannitol. Furthermore, the hormone effect on state-3 respiration and succinate dehydrogenase activity was only small if the mitochondria had been prepared faster than usual and had been used without washing. Regarding pyruvate carboxylase, a considerably smaller glucagon effect was observed when it was assayed at 25 degrees C and not (as usual) at 37 degrees C. Our results indicate that glucagon application stabilizes rather than activates mitochondrial functions.     

Measurement of the intramitochondrial volume in hepatocytes without cell disruption and its elevation by hormones and valinomycin.

Methods have been developed to measure the lysophospholipid content and matrix volume of liver cell mitochondria in situ in order to test the hypothesis that these parameters may be important in the hormonal control of mitochondrial function [Armston, Halestrap & Scott (1982) Biochim. Biophys. Acta 681, 429-439]. No change in the labelling of mitochondrial lysophospholipids with [32P]Pi was detected after treatment of liver cells with glucagon, phenylephrine or vasopressin. Incorporation of [32P]Pi into mitochondrial phosphatidylinositol was enhanced by phenylephrine and vasopressin. Mitochondrial volumes were measured using rapid disruption of cells by sonication into 3H2O and [14C]sucrose or without cell disruption using 3H2O and [14C]mannitol. In control cells the two methods gave values of 1.09 and 0.40 microliters/mg of mitochondrial protein respectively, which represent 19 and 7% respectively of the total cell volume measured with 3H2O and inulin [14C]carboxylic acid. Both methods showed that glucagon, phenylephrine and 1 nm-valinomycin produced significant increases (13% and 26% using sucrose and mannitol respectively) in mitochondrial volume. The increase was coincident with the stimulation of gluconeogenesis from L-lactate and pyruvate and of mitochondrial respiratory chain activity. The effects of glucagon and phenylephrine were additive on both mitochondrial volume and respiratory chain activity, but not on gluconeogenesis. Liver cells exposed to gluconeogenic hormones or low concentrations of valinomycin showed a decrease in light scattering at 520 nM correlating with the change in mitochondrial volume but without a change in whole-cell volume. The time course and hormone sensitivity of this response were similar to those for the hormonal stimulation of gluconeogenesis. The light-scattering response to glucagon, phenylephrine and vasopressin, but not to valinomycin, were greatly reduced or abolished in Ca2+-free media.     

Apparent unmasking of [3H]GDP binding in rat brown-fat mitochondria is due to mitochondrial swelling

The presence of and biochemical background for the so-called 'unmasking' phenomenon in rat brown-fat mitochondria was investigated (i.e. the apparent increase in [3H]GDP binding to the 'uncoupling' protein thermogenin, without a concomitant increase in the amount of the protein). It was found that an unmasking could be observed both 1 h after norepinephrine injection and after 1 h cold stress, provided that the rats were preacclimated to 28 degrees C. The unmasking could be observed both when a filtration method and when a centrifugation method for determination of [3H]GDP-binding capacity were used; however, the absolute values were higher with the filtration method. Based on observations of slower cytochrome-c oxidase sedimentation during centrifugation, the possibility that the matrix volume of brown-fat mitochondria isolated from warm-acclimated animals was smaller than that of cold-stressed animals was investigated with 3H2O. The cold stress increased the matrix volume from being nearly non-existent to about 1 microliter/mg. A preswelling procedure in an ionic medium could similarly increase the matrix volume in mitochondria from warm-acclimated animals but was without significant effect in the already swollen mitochondria from cold-stressed animals or from animals adapted to a lower temperature. In mitochondria from warm-acclimated animals, the ionic preswelling procedure was fully able to increase the apparent amount of GDP binding to that observed in mitochondria from cold-stressed animals, but it was practically without effect on GDP binding in mitochondria from cold-stressed animals or from animals acclimated to a lower temperature. It is concluded that the apparent 'unmasking' phenomenon, observed when the tissue is less activated than in normal control situations, is not (as hitherto anticipated) due to a specific change in thermogenin as such, but is a reflection of a general mitochondrial phenomenon.     

The response of plant mitochondria to media of high solute content

The state-3 rate of respiration of potato tuber mitochondria is inhibited by concentrations of KCl or NaCl above 125 mM, and by concentrations of sucrose, lactose, or maltose above 500 mM, but not at all by mannitol, glucose, glycine, or proline up to a concentration of 1500 mM in the medium. Mitochondria from cauliflower, beetroot, cucumber, rock melon, and watermelon behave very similarly to those from potato tuber. The variable response to different solutes proves that the reduction in respiration is not a simple function of the chemical potential of water in the medium. Disruption of potato mitochondria by ultrasonic vibration does not relieve the inhibition of succinate oxidation caused by KCl or sucrose. However, treatment with detergent abolishes completely the inhibition of respiration by sucrose. Inhibition of succinate dehydrogenase [Succinate:PMS, oxidoreductase (EC.1.3.99.1)] and malate dehydrogenase [L-Malate:NAD oxidoreductase (EC.1.1.1.37)] activities by sucrose is less than the inhibition of succinate- and malate-dependent oxygen uptake by the potato mitochondria. Limited substrate uptake and, alternatively, reduced electron flow as a consequence of a direct effect of solute on the mitochondrial membrane are considered as possible mechanisms of inhibition.     

The nature of the changes in liver mitochondrial function induced by glucagon treatment of rats. The effects of intramitochondrial volume,aging and benzyl alcohol

(1) The effects of changes in the intramitochondrial volume, benzyl alcohol treatment and calcium-induced mitochondrial aging on the behaviour of liver mitochondria from control and glucagon-treated rats are reported. (2) The stimulatory effects of glucagon on mitochondrial respiration, pyruvate metabolism and citrulline synthesis could be mimicked by hypo-osmotic treatment of control mitochondria and reversed by calcium-induced aging of mitochondria or by treatment with 20 mM benzyl alcohol. Hypo-osmotic treatment increased the matrix volume whilst aging but not benzyl alcohol decreased this parameter. (3) Liver mitochondria from glucagon and adrenaline-treated rats were shown to be less susceptible to damage by exposure to calcium than control mitochondria and frequently showed slightly (15%) elevated intramitochondrial volumes. (4) Aging, benzyl alcohol and hypo-osmotic media increased the susceptibility of mitochondria to damage caused by exposure to calcium. (5) Glucagon-treated mitochondria were less leaky to adenine nucleotides than control mitochondria. (6) These results suggest that glucagon may exert its action on a wide variety of mitochondrial parameters through a change in the disposition of the inner mitochondrial membrane, possibly by stabilisation against endogenous phospholipase A₂ activity. This effect may be mimicked by an increase in the matrix volume or reversed by calcium-dependent mitochondrial aging.     

Factors limiting mitochondrial respiration in media of high solute content

The state-3 rate of respiration of rat-liver mitochondria was depressed in media containing KCl, sucrose, or mannitol at concentrations in excess of 125 mM. At equivalent concentrations, glucose caused less inhibition than sucrose or mannitol, and no inhibition was observed with glycine. These observations establish that solute inhibition of respiration is not a consequence of the reduced chemical potential of water in the system. The accumulation of succinate by mitochondria was not reduced by high sucrose concentrations. Sonication only partially relieved inhibition by sucrose or mannitol, and not at all that by KCl, and the evidence indicates that solute inhibition is not primarily an inhibition of substrate entry into mitochondria. Sucrose in the assay media inhibited succinate dehydrogenase [succinate: PMS oxidoreductase (EC.1. 3. 91)] and malate dehydrogenase [l-malate: NAD oxidoreductase (EC.1.1.1.37)] activities, but these inhibitions were less than those of succinate-and malate-dependent oxygen uptake by mitochondria. Disruption of the mitochondrial membrane by detergent abolished the inhibition of respiration by sucrose, and the evidence indicates that solute inhibits the functional capacity of the membrane-associated respiratory system.     

Functional relationship between the ADP/ATP-carrier and the F1-ATPase in mitochondria.

1. The distribution of labeled and unlabeled adenine-nucleotides inside and outside mitochondria was followed after addition of [14C]ADP to rat liver mitochondria. Two types of mitochondria were used: 1, respiring mitochondria which were carrying out oxidative phosphorylation and which had been replenished in ATP by incubation in a medium supplemented with succinate and phosphate; 2, non-respiring mitochondria which had been partially depleted of ATP by incubation in a medium supplemented with rotenone and phosphate. During the first minute following addition of [14C]ADP to the respiring mitochondria, the pre-existing intramitochondrial (internal) [12C]ATP was released into the medium and replaced by newly synthesized [14C]ATP. No [14C]ADP accumulated in the mitochondria. It is suggested that extramitochondrial (external) ADP entering respiring mitochondria in exchange for internal ATP is phosphorylated to ATP before its complete release in the matrix space. In non-respiring mitochondria, the entry of [14C]ADP into the mitochondria was accompanied by the appearance in the external space of [12C]ADP and [12C]ATP, with a marked predominance of [12C]ADP. Thus in non-respiring mitochondria, the residual internal ATP is dephosphorylated to ADP in the inner membrane before being released outside the mitochondria. 2. When mitochondria were incubated with glutamate, ADP and [32P]phosphate, the [32P]ATP which accumulated in the matrix space became rapidly labeled in both the P gamma and P beta groups of the ATP, due to the presence of a transphosphorylation system in the mitochondrial matrix. The [32P]ATP which accumulated outside the mitochondria was also labeled in the P beta group, although less rapidly than the internal ATP. Our data show that a large fraction (75-80%) of the ATP produced by phosphorylation of added ADP within the inner mitochondrial membrane is released into the matrix space before being transported out from the mitochondria; only a small part (20-25%) is released directly outside the mitochondria without penetrating the matrix space. 3. In respiring and phosphorylating mitochondria, the value of the Km of the ADP-carrier for external ADP was 2-4 times lower than its value in non-respiring and non-phosphorylating mitochondria. 4. The above experimental data are discussed with reference to the topological and functional relationships between the ADP-carrier and the oxidative phosphorylation complex in the inner mitochondrial membrane. They strongly suggest that the ADP-carrier comes to the close neighbourhood of the ATP synthetase on the matrix side of the inner membrane.     

A heart mitochondrial Ca2(+)-dependent pore of possible relevance to re-perfusion-induced injury. Evidence that ADP facilitates pore interconversion between the closed and open states.

The permeability properties of a putative Ca2(+)-activated pore in heart mitochondria, of possible relevance to re-perfusion-induced injury, have been investigated by a pulsed-flow solute-entrapment technique. The relative permeabilities of [14C]mannitol, [14C]sucrose and arsenazo III are consistent with permeation via a pore of about 2.3 nm diameter. Ca2+ removal with EGTA induced pore closure, and the mitochondria became 'resealed'. The permeability of the unresealed mitochondria during resealing was markedly stimulated by 200 microM-ADP, and the relative permeabilities to solutes of different size were stimulated equally, indicating an increase in open-pore number, rather than an increase in pore dimensions. This is paradoxical, since ADP also stimulated the rate of resealing. The rate of EGTA-induced resealing was also stimulated by the Ca2+ ionophore A23187, which indicates that the rate of removal of matrix free Ca2+ is limiting for pore closure. An explanation for the paradox is suggested in which ADP facilitates pore interconversion between the closed and open states in permeabilized mitochondria, and pore closure in Ca2(+)-free mitochondria occurs much faster than previously thought.     

Functional studies on in situ-like mitochondria isolated in the presence of polyvinyl pyrrolidone

Mitochondria isolated and maintained in sucrose mannitol medium show a large intermembrane space and a condensed matrix unlike the appearance of in situ mitochondria. Mitochondria resembling in situ organelles are obtained when the isolation medium is supplemented with certain macromolecules such as polyvinyl pyrrolidone. We found that the in situ appearance was acquired also by the conventionally isolated mitochondria when they were exposed to 2% polyvinyl pyrrolidone supplemented medium. Paradoxically, however, these in situ looking mitochondria proved functionally inferior in that their brief incubation without substrates led to a marked loss of their ability to respire with subsequently added substrates such as pyruvate, acylcarnitines or glutamate. The oxidation of succinate was, however, not so affected. This phenomenon was shared by heart and skeletal muscle mitochondria of different animal species but not by rat liver mitochondria. The inhibition of respiration could not be related to the failure to oxidize NADH, to the tieing up of mitochondrial free CoASH, or to the increased matrix space of mitochondria that was observed in the presence of polyvinyl pyrrolidone. The polyvinyl pyrrolidone-exposed mitochondria regained their respiratory ability on being freed from polyvinyl pyrrolidone. The same phenomenon was seen also when the medium contained 2% albumin or 20% Ficoll.     

Inhibition by cyclosporin A of a Ca2+-dependent pore in heart mitochondria activated by inorganic phosphate and oxidative stress.

The capacity of cyclosporin A to inhibit opening of a Ca2+-dependent pore in the inner membrane of heart mitochondria was investigated. Whereas in the presence of 25 nmol of Ca2+/mg of mitochondrial protein and 5 mM-Pi mitochondria were unable to maintain accumulated Ca2+, inner-membrane potential and sucrose impermeability, all three parameters were preserved when cyclosporin was included. Pore opening was assayed directly by [14C]sucrose entry and entrapment in the matrix space. [14C]Sucrose entry induced by both Ca2+ plus Pi and Ca2+ plus t-butyl hydroperoxide was almost completely inhibited by 60 pmol of cyclosporin/mg of mitochondrial protein. It is concluded that cyclosporin A is a potent inhibitor of the pore.     

Adenine nucleotide translocation in yeast mitochondria. Effect of inhibitors of mitochondrial biogenesis on the ADP translocase

1. Optimal test conditions for adenine nucleotide translocation in Candida utilis mitochondria are a standard medium, consisting of 0.63 M mannitol, 2 mM EDTA (or ethylene glycol tetraacetic acid, EGTA), 10 mM morpholinopropane sulfonic acid (pH 6.8), and a temperature of 0 °C.

2. Adenine nucleotide translocation in C. utilis mitochondria is an exchange-diffusion process. The whole pool of internal adenine nucleotides is exchangeable, ADP being the most readily exchangeable nucleotide. The rate of mitochondrial ADP exchange, but not the K_m value, depends on growth conditions. At 0 °C, the rate is about 3 to 4 nmoles ADP/min per mg protein for mitochondria obtained from yeast grown in the presence of 1.5% glucose; it rises to 11.5 nmoles when glucose is replaced by 3% ethanol in the growth medium. The K_m value for ADP is 2 μM. The Q₁₀ is about 2 between 0 and 20 °C. Among other exchangeable adenine nucleotides are ATP, dADP and the methylene and the hypophosphate analogues of ADP. Unlike mammalian mitochondria, C. utilis mitochondria are able to transport external UDP by a carboxyatractyloside-sensitive process.

3. Under conditions of oxidative phosphorylation (phosphate and substrate present in an aerated medium), added ADP is exchanged with internal ATP. A higher ATP/ADP ratio was found in the extramitochondrial space than in the intramito-chondrial space. The difference between the calculated phosphate potentials in the two spaces was 0.9–1.7 kcal/mole.

4. Atractyloside, carboxyatractyloside, bongkrekic acid and palmityl-CoA inhibit mitochondrial adenine nucleotide translocation in C. utilis as they do in mammalian mitochondria, but 2 to 4 times less efficiently. The inhibition due to atractyloside or palmityl-CoA is competitive with respect to ADP whereas that due to bongkrekic acid and carboxyatractyloside is non-competitive. Carboxyatractyloside and atractyloside inhibitions are additive. The apparent K_d for the binding of [³⁵S]-carboxyatractyloside and [¹⁴C]bongkrekic acid is 10–15 nM and the concentration of sites 0.4–0.6 nmole/mg protein in both cases. [³⁵S]Carboxyatractyloside binding is competitively displaced by atractyloside and vice versa.

5. Binding of [¹⁴C]ADP has been carried out with mitochondria depleted of their endogenous adenine nucleotides by incubation with phosphate and Mg²⁺ at 20 °C. The amount of bound [¹⁴C]ADP which is atractyloside removable is 0.08–0.16 nmole/mg protein.

6. The rate of ADP transport is quite different in mitochondria isolated from C. utilis, according to whether it is grown on glucose, or on ethanol or in the presence of chloramphenicol; for instance, it decreases by 10 times when 3% ethanol in the growth medium is replaced by 10% glucose and by 5 times when chloramphenicol is added to the medium. These variations are accompanied by parallel variations in cytochrome aa₃. The number of atractyloside-sensitive ADP binding sites is not modified by the above conditions of culture, nor the number of [³⁵S]carboxyatractyloside binding sites. The affinity for ADP is apparently not significantly modified, nor the size of the endogenous adenine nucleotide pool. In contrast to glucose repression or chloramphenicol inhibition, semi-anaerobiosis in C. utilis lowers significantly the mitochondrial binding capacity for carboxyatractyloside. Strict anaerobiosis in S. cerevisiae results in a practical loss of the cytochrome oxidase activity, and also of the carboxyatractyloside and ADP binding capacity. Transition from anaerobiosis to aerobiosis restores the cytochrome oxidase activity and the ADP and carboxyatractyloside binding capacities.     

The regulation of the matrix volume of mammalian mitochondria in vivo and in vitro and its role in the control of mitochondrial metabolism

The purpose of this article is to describe briefly the methods by which the intra-mitochondrial volume may be measured both in vitro and in situ, to summarise the mechanisms thought to regulate the mitochondrial volume and then to review in more detail the evidence that changes in the intra-mitochondrial volume play an important part in the regulation of liver mitochondrial metabolism by glucogenic hormones such as glucagon, adrenaline and vasopressin. It will be shown that these hormones cause an increase in matrix volume sufficient to produce significant activation of fatty acid oxidation, respiration and ATP production, pyruvate carboxylation, citrulline synthesis and glutamine hydrolysis. These are all processes activated by such hormones in vivo. I will go on to demonstrate that the increase in matrix volume is brought about by an increase in mitochondrial [PPi]. This is able to stimulate K+ entry into the matrix, perhaps through an interaction with the adenine nucleotide translocase. The rise in matrix [PPi] is a consequence of an increase in cytosolic and hence mitochondrial [Ca2+] which inhibits mitochondrial pyrophosphatase. In the final section of the review I provide evidence that changes in mitochondrial volume may be important in the responses of a variety of tissues to hormones and other stimuli. I write as a metabolist with a working knowledge of bioenergetics rather than the converse, and this will certainly be reflected in the approach taken. If I cause offence to any dedicated experts in the field of bioenergetic by my ignorance or lack of understanding of their studies I can only offer my apologies and ask to be corrected.     

Regulation of the mitochondrial matrix volume in vivo and in vitro. The role of calcium.

The ability of alpha-adrenergic agonists and vasopressin to increase the mitochondrial volume in hepatocytes is dependent on the presence of extracellular Ca2+. Addition of Ca2+ to hormone-treated cells incubated in the absence of Ca2+ initiates mitochondrial swelling. In the presence of extracellular Ca2+, A23187 (7.5 microM) induces mitochondrial swelling and stimulates gluconeogenesis from L-lactate. Isolated liver mitochondria incubated in KCl medium in the presence of 2.5 mM-phosphate undergo energy-dependent swelling, which is associated with electrogenic K+ uptake and reaches an equilibrium when the volume has increased to about 1.3-1.5 microliter/mg of protein. This K+-dependent swelling is stimulated by the presence of 0.3-1.0 microM-Ca2+, leading to an increase in matrix volume at equilibrium that is dependent on [Ca2+]. Ca2+-activated K+-dependent swelling requires phosphate and shows a strong preference for K+ over Na+, Li+ or choline. It is not associated with either uncoupling of mitochondria or any non-specific permeability changes and cannot be produced by Ba2+, Mn2+ or Sr2+. Ca2+-activated K+-dependent swelling is not prevented by any known inhibitors of plasma-membrane ion-transport systems, nor by inhibitors of mitochondrial phospholipase A2. Swelling is inhibited by 65% and 35% by 1 mM-ATP and 100 microM-quinine respectively. The effect of Ca2+ is blocked by Ruthenium Red (5 micrograms/ml) at low [Ca2+]. Spermine (0.25 mM) enhanced the swelling seen on addition of Ca2+, correlating with its ability to increase Ca2+ uptake into the mitochondria as measured by using Arsenazo-III. Mitochondria derived from rats treated with glucagon showed less swelling than did control mitochondria. In the presence of Ruthenium Red and higher [Ca2+], the mitochondria from hormone-treated animals showed greater swelling than did control mitochondria. These data imply that an increase in intramitochondrial [Ca2+] can increase the electrogenic flux of K+ into mitochondria by an unknown mechanism and thereby cause swelling. It is proposed that this is the mechanism by which alpha-agonists and vasopressin cause an increase in mitochondrial volume in situ.     

Inorganic pyrophosphate is located primarily in the mitochondria of the hepatocyte and increases in parallel with the decrease in light-scattering induced by gluconeogenic hormones, butyrate and ionophore A23187.

1. The effects of a variety of hormones on the PPi content and light-scattering of isolated rat liver cells was studied. 2. The basal PPi content was about 130 pmol/mg of cell protein, and increased after hormone addition, in parallel with a decrease in light-scattering which we have observed previously [Quinlan, Thomas, Armston & Halestrap (1983) Biochem. J. 214, 395-404]. 3. The mean increases in PPi content with the agonists shown (as pmol/mg of protein) were: 0.1 microM-glucagon, 25; 20 microM-phenylephrine, 30; 25 nM-vasopressin, 127; glucagon + phenylephrine, 115; glucagon + vasopressin, 382; 100 microM-ADP, 50; 15 microM-A23187, 72; 1 mM-butyrate, 80. 4. In the absence of extracellular Ca2+, vasopressin had little effect on either the PPi content or the light-scattering of hepatocytes. 5. The magnitude of the increase in PPi content correlated with that of the decrease in light-scattering irrespective of the stimulating agent, provided that the PPi did not exceed 300 pmol/mg of protein. Above this value little additional change in light-scattering was observed. 6. Subcellular fractionation showed that over 90% of the cellular PPi was intramitochondrial in both control and stimulated cells. 7. The data support the conclusions of previous experiments using isolated liver mitochondria [Davidson & Halestrap (1987) Biochem. J. 246, 715-723] that hormones increase the mitochondrial matrix volume through a Ca2+-induced rise in matrix [PPi]. 8. It is further proposed that this increase in mitochondrial [PPi] allows entry of ADP into the mitochondria in exchange for PPi and is therefore responsible for the increase in total mitochondrial adenine nucleotides observed after hormone treatment.     

Phytochrome-mediated development of mitochondria in the cotyledons of mustard (Sinapis alba L.) seedlings

Summary The development of mitochondria from promitochondria is regulated by phytochrome. This conclusion is based on four lines of evidence: 1. The activity of representative mitochondrial marker enzymes (fumarase, EC 4.2.1.2; succinate dehydrogenase, EC 1.3.99.1; cytochrome oxidase, EC 1.9.3.1) is increased by continuous far-red light and (in 2 of the 3 enzymes) by brief red pulses, the effect of which is reversible by brief far-red pulses. These effects do not merely represent a general growth or proliferation of mitochondria already present but specific responses of individual enzymes. Inhibitors of protein synthesis but not of RNA synthesis suppress the increase of these enzyme activities. 2. Continuous far-red light changes some structural properties of the mitochondrial membranes, detectable by an increased requirement of detergent (Triton X-100) for the solubilization of cytochrome oxidase and a more efficient retainment of the matrix enzyme fumarase during isolation of mitochondria. Continuous far-red light increases the apparent buoyant density of mitochondria on a sucrose density gradient. 3. Continuous far-red light has a strong effect on the morphology of the inner mitochondrial membrane system. Electron micrographs from dark-grown cotyledons show arrays of parallel, plate-like cristae while typical plant mitochondria with irregularly oriented sacculi are formed in the light. These responses indicate the involvement of mitochondria in cytophotomorphogenesis during the transition of the cotyledons from dissimilatory to assimilatory metabolism.Abbreviations DCPIP 2.6-dichlorophenole indophenole - EDTA Na₂-ethylenediaminetetraacetate - HEPES 2-[4-(2-hydroxyethyl)-piperazine-(1)ethanesulfonic acid - PMS phenazine methosulfate