Macromolecules increase the channelling of ADP from externally associated hexokinase to the matrix of mitochondria

Macromolecules can restore the morphological changes in the outer mitochondrial compartment that occur upon isolation of the organelle. They decrease the volume of the intermembrane space and increase the number of intermembrane contact sites. In this study, we investigated the effects of macromolecules on one of the processes occurring in the mitochondrial outer compartment and for which the native structure might be important, i.e. the ADP supply from outer-membrane-bound hexokinase-I to oxidative phosphorylation. With the use of a reconstituted system in which rat liver mitochondria and extramitochondrial pyruvate kinase compete for ADP generated by hexokinase, it was shown that (a) part of the ADP generated by mitochondrially associated hexokinase is not accessible to pyruvate kinase and is channeled into the mitochondrion, (b) in the presence of 10% (mass/vol.) macromolecules (i.e. dextran M20 or BSA) the pyruvate kinase inaccessible fraction increases from 19% to 31 % of the ADP produced by hexokinase, (c) the ADP channeling is a characteristic property of bound hexokinase, and (d) the increased channeling induced by macromolecules can neither be explained by direct effects of these macromolecules on the basic respiratory properties of rat liver mitochondria, nor by direct effects on the kinetic properties of hexokinase-I. ATP and ADP determinations were performed in hexokinase/mitochondria incubation mixtures in the presence of macromolecules. These determinations showed that an important consequence of the channeling capacity of bound hexokinase is that lower extramitochondrial ADP levels and consequently higher extramitochondrial ATP/ADP ratios are maintained than when hexokinase is not bound. The experimental data demonstrate that the ADP channeling activity associated with bound hexokinase leads to the formation of two ADP concentration gradients, one across the outer membrane and one between bound hexokinase and the bulk phase

ADP delivery from adenylate kinase in the mitochondrial intermembrane space to oxidative phosphorylation increases in the presence of macromolecules

Macromolecules were added to isolated rat liver mitochondria to mimic cytosolic macromolecules and tested for their effects on the ADP delivery from adenylate kinase in the intermembrane space to oxidative phosphorylation. In the presence of 10% (w/v) dextran M20 or bovine serum albumin, approximately 60% of the maximal ADP flux from adenylate kinase to oxidative phosphorylation was not accessible to an extramitochondrial ADP scavenger. In the absence of macromolecules this was 34%. ADP determinations from incubations with macromolecules demonstrated the existence of flux-dependent ADP concentration gradients across the outer membrane which can be as high as 12 µM

Experimental evidence for dynamic compartmentation of ADP at the mitochondrial periphery: Coupling of mitochondrial adenylate kinase and mitochondrial hexokinase with oxidative phosphorylation under conditions mimicking the intracellular colloid osmotic pressure

Dextran M20 was added to isolated rat liver mitochondria to mimic cytosolic macromolecules. Under these conditions, the morphological changes in the mitochondrial periphery that occur upon isolation of the organelle are restored, i.e. the volume of the intermembrane space decreases and the contact site frequency increases. The ADP routing from mitochondrial kinases at various locations was investigated by using the activities of oxidative phosphorylation and externally added pyruvate kinase as sensors for ADP transport into the matrix and extramitochondrial compartment, respectively. The studies reveal that a significant fraction of the ADP generated by either adenylate kinase in the intermembrane space or by outer membrane bound hexokinase isozyme I, is not accessible to extramitochondrial pyruvate kinase. Quantitative information on the ADP compartmentation in rat liver mitochondria was obtained by comparing the ADP supply from mitochondrial kinases to oxidative phosphorylation with that of non-bound, extramitochondrially located kinases. This approach allowed us to estimate the ADP diffusion gradients which were present across the outer membrane and between the compartment formed by bound hexokinase and the extramitochondrial compartment. In the presence of 10% dextran M20 these ADP gradients amounted to approximately 12 µM. The possible role of mitochondrial kinases in ADP transport into mitochondria in vivo is discussed

The quantitation of ADP diffusion gradients across the outer membrane of heart mitochondria in the presence of macromolecules

We have previously provided evidence that diffusion of metabolites across the porin pores of mitochondrial outer membrane is hindered. A functional consequence of this diffusion limitation is the dynamic compartmentation of ADP in the intermembrane space. These earlier studies were done on isolated mitochondria suspended in isotonic media without macromolecules, in which intermembrane space of mitochondria is enlarged. The present study was undertaken to assess the diffusion limitation of outer membrane in the presence of 10% (w/v) dextran M20, in order to mimick the action of cytosolic macromolecules on mitochondria. Under these conditions, mitochondria have a more native, condensed configuration. Flux-dependent concentration gradients of ADP were estimated by measuring the ADP diffusion fluxes across the porin pores of isolated rat heart mitochondria incubated together with pyruvate kinase (PK), both of which compete for ADP regenerated by mitochondrial creatine kinase (mtCK) within the intermembrane space or by yeast hexokinase (HK) extramitochondrially. From diffusion fluxes and bulk phase concentrations of ADP, its concentrations in the intermembrane space were calculated using Fick's law of diffusion. Flux-dependent gradients up to 23 µM ADP (for a diffusion rate of JDif=1.9 µmol ADP/min/mg mitochondrial protein) were observed. These gradients are about twice those estimated in the absence of dextran and in the same order of magnitude as the cytosolic ADP concentration (30 µM), but they are negligibly low for cytosolic ATP (5 mM). Therefore, it is concluded that the dynamic ADP compartmentation is of biological importance for intact heart cells. If mtCK generates ADP within the intermembrane space, the local ADP concentration can be clearly higher than in the cytosol resulting in higher extramitochondrial phosphorylation potentials. In this way, mtCK contributes to ensure optimal kinetic conditions for ATP-splitting reactions in the extramitochondrial compartment

Dextran strongly increases the Michaelis constants of oxidative phosphorylation and of mitochondrial creatine kinase in heart mitochondria

Macromolecules restore the morphological changes which occur upon isolation of mitochondria in normally used isolation media. It was shown that in the presence of dextrans the permeability of mitochondrial outer membrane for adenine nucleotides decreases which may have considerable implications for the transport of ADP into the mitochondria. In this study the effect of dextran on the apparent Michaelis constants of oxidative phosphorylation and mitochondrial creatine kinase (mi-CK) of rat heart mitochondria was investigated. Mitochondria were isolated either in normally used isolation media or in the additional presence of 15 % dextran 20 in order to avoid changes in the oncotic conditions on the mitochondria during preparation and investigation. Except for an increased contamination with extramitochondrial ATPases the basic functional properties of these mitochondria were normal. With oxygraphic measurements it was found that .cf2.K.cf2..cf1..esADP.rb.eim.rb of oxidative phosphorylation increased from 16 ± 4 µM ADP (without dextran) to 50 ± 15 µM (15 % dextran 20) and to 122 ± 62 µM (25 % dextran 20) irrespective of the mode of preparation of the mitochondria. Using spectrophotometric measurements the effect of dextran on the .cf2.K.cf2..cf1..esATP.rb.eim.rb of mi-CK was investigated in three systems (a) as soluble enzyme, (b) bound to mitoplasts, (c) and in intact rat heart mitochondria. The addition of 10 % dextran had no effect on kinetic properties of solubilized mi-CK. In intact heart mitochondria, however, the addition of dextran caused an augmentation of .cf2.K.cf2..cf1..esATP.rb.eim.rb from 332 ± 91 µM (control) to 525 ± 150 µM ATP (10 % dextran) and 641 ± 160 µM ATP (30 % dextran). In mitoplasts the effect of dextran disappeared (control, 230 ± 19 µM ATP; 10 % dextran, 238 ± 28 µM ATP) indicating that the outer mitochondrial membrane is a prerequisite for the modulation of the transport of adenine nucleotides into the intermembrane space by macromolecules. To investigate the effects of viscosity of dextran solutions on the diffusion of adenine nucleotides across the outer membrane, dextrans with different molecular size (20, 40 70 and 500 kDa) were used. The viscosity of the 10 % solutions drastically increased with the molecular size of the dextrans used, but the effects of different dextran solutions on the kinetic constants were the same. From these results it was concluded that neither the viscosity nor the molar concentration but the content of macromolecules (mass/vol.) correlates with restrictions of diffusion into the intermembrane space of mitochondria with intact outer membranes. Assuming that a dextran concentration of 15 % mimicks the intracellular oncotic pressure on mitochondria in vivo, the apparent .cf2.K.cf2..cf1..esADP.rb.eim.rb of oxidative phosphorylation within the intact cell seems to be about 50 µM ADP which is somewhat higher than the cytoplasmic free ADP concentration as reported for the intact heart

The influence of the cytosolic oncotic pressure on the permeability of the mitochondrial outer membrane for ADP

Cytosolic proteins as components of the physiological mitochondrial environment were substituted by dextrans added to media normally used for incubation of isolated mitochondria. Under these conditions the volume of the intermembrane space decreases and the contact sites between the both mitochondrial membranes increase drastically. These morphological changes are accompanied by a reduced permeability of the mitochondrial outer compartment for adenine nucleotides as it was shown by extensive kinetic studies of mitochondrial enzymes (oxidative phosphorylation, mi-creatine kinase, mi-adenylate kinase). The decreased permeability of the mitochondrial outer membrane causes increased rate dependent concentration gradients in the micromolar range for adenine nucleotides between the intermembrane space and the extramitochondrial space. Although all metabolites crossing the outer membrane exhibit the same concentration gradients, considerable compartmentations are detectable for ADP only due to its low extramitochondrial concentration. The consequences of ADP-compartmentation in the mitochondrial intermembrane space for ADP-channelling into the mitochondria are discussed

Broad AOX expression in a genetically tractable mouse model does not disturb normal physiology.

Plants and many lower organisms, but not mammals, express alternative oxidases (AOX) that branch the mitochondrial respiratory chain, transferring electrons directly from ubiquinol to oxygen without proton pumping. Thus, they maintain electron flow under conditions when the classical respiratory chain is impaired, limiting excess production of oxygen radicals and supporting redox and metabolic homeostasis. AOX from Ciona intestinalis has been used to study and mitigate mitochondrial impairments in mammalian cell-lines, Drosophila disease models and, most recently, in the mouse, where multiple, lentivector-AOX transgenes conferred substantial expression in specific tissues. Here we describe a genetically tractable mouse model in which Ciona AOX has been targeted to the Rosa26 locus for ubiquitous expression. The AOXRosa26 mouse exhibited only subtle phenotypic effects on respiratory complex formation, oxygen consumption or the global metabolome, and showed an essentially normal physiology. AOX conferred robust resistance to inhibitors of the respiratory chain in organello, whilst animals exposed to a systemically applied LD50 dose of cyanide did not succumb. The AOXRosa26 mouse is a useful tool to investigate respiratory control mechanisms and to decipher mitochondrial disease aetiology in vivo