ATP-Mg/Pi carrier activity in rat liver mitochondria.

The ATP-Mg/Pi carrier in liver mitochondria is activated by micromolar Ca2+ and mediates net adenine nucleotide transport into and out of the mitochondrial matrix. The purpose of this study was to characterize certain features of ATP-Mg/Pi carrier activity that are essential for understanding how the mitochondrial adenine nucleotide content is regulated. The relative importance of ATP and ADP as transport substrates was investigated using specific trap assays to measure their separate rates of carrier-mediated efflux with Pi as the external counterion. Under energized conditions ATP efflux accounted for 88% of total ATP+ADP efflux. With oligomycin present to lower the matrix ATP/ADP ratio, ATP efflux was eliminated and ADP efflux was relatively unaffected. Mg2+ was stoichiometrically required for ATP influx and is probably transported simultaneously with ATP. Ca2+ and Mn2+ could substitute for the stoichiometric Mg2+ requirement. ADP influx and Pi-induced adenine nucleotide efflux were unaffected by external Mg2+. Experiments with Pi analogues suggested that Pi is transported as the divalent anion, HPO4(2-). The results show that ATP-Mg and divalent Pi are the major transport substrates; the most probable transport mechanism for the ATP-Mg/Pi carrier is an electroneutral exchange. The results are consistent with the hypothesis that the direction and magnitude of net adenine nucleotide movements are determined mainly by the (ATP-Mg)2- and HPO4(2-) concentration gradients across the inner mitochondrial membrane.     

Calcium stimulates ATP-Mg/Pi carrier activity in rat liver mitochondria

Adenine nucleotide transport over the carboxyatractyloside-insensitive ATP-Mg/Pi carrier was assayed in isolated rat liver mitochondria with the aim of investigating a possible regulatory role for Ca2+ on carrier activity. Net changes in the matrix adenine nucleotide content (ATP + ADP + AMP) occur when ATP-Mg exchanges for Pi over this carrier. The rates of net accumulation and net loss of adenine nucleotides were inhibited when free Ca2+ was chelated with EGTA and stimulated when buffered [Ca2+]free was increased from 1.0 to 4.0 microM. The unidirectional components of net change were similarly dependent on Ca2+; ATP influx and efflux were inhibited by EGTA in a concentration-dependent manner and stimulated by buffered free Ca2+ in the range 0.6-2.0 microM. For ATP influx, increasing the medium [Ca2+]free from 1.0 to 2.0 microM lowered the apparent Km for ATP from 4.44 to 2.44 mM with no effect on the apparent Vmax (3.55 and 3.76 nmol/min/mg with 1.0 and 2.0 microM [Ca2+]free, respectively). Stimulation of influx and efflux by [Ca2+]free was unaffected by either ruthenium red or the Ca2+ ionophore A23187. Calmodulin antagonists inhibited transport activity. In isolated hepatocytes, glucagon or vasopressin promoted an increased mitochondrial adenine nucleotide content. The effect of both hormones was blocked by EGTA, and for vasopressin, the effect was blocked also by neomycin. The results suggest that the increase in mitochondrial adenine nucleotide content that follows hormonal stimulation of hepatocytes is mediated by an increase in cytosolic [Ca2+]free that activates the ATP-Mg/Pi carrier.     

The ATP-Mg/Pi carrier of rat liver mitochondria catalyzes a divalent electroneutral exchange.

Net transport of ATP-Mg or ADP in exchange for phosphate in isolated rat liver mitochondria has been shown to be an electroneutral process mediated by the ATP-Mg/Pi carrier. We compared the steady state distribution ratios of phosphate, ATP-Mg, and ADP at a pH of 7.4 to determine whether the divalent or monovalent form of these anions is the transported substrate. The log of the divalent ATP-Mg distribution ratio (in/out) approached the log of the divalent phosphate distribution ratio (approximately 0.85), which was approximately twice the value of the delta pH (approximately 0.40) across the inner mitochondrial membrane. This steady state relationship held under several different conditions, e.g. when the medium ATP concentration was varied or if the phosphate gradient was modified by partial uncoupling with the proton ionophore, carbonyl cyanide p-trifluoromethoxyphenylhydrazone. Unidirectional ADP efflux in exchange for external ADP or ATP-Mg was stimulated by an increase in matrix H+. The log of the trivalent ADP distribution ratio (approximately 1.20) approached 3 times the value of delta pH. All these data are consistent with the model of an electroneutral exchange of divalent phosphate (HPO2-4) for divalent ATP-Mg (ATP-Mg2-) or for divalent protonated ADP (HADP2-). We conclude that this transport mechanism accounts for the adenine nucleotide concentration gradient that normally exists between the matrix and external medium.     

Mechanism and regulation of the mitochondrial ATP-Mg/Pi carrier

The mitochondrial ATP-Mg/P_i carrier functions to modulate the matrix adenine nucleotide pool size (ATP + ADP + AMP). Micromolar Ca²⁺ is required to activate the carrier. Net adenine nucleotide transport occurs as an electroneutral divalent exchange of ATP-Mg^2– for HPO ₄ ^2– . A steady-state adenine nucleotide pool size is attained when the HPO ₄ ^2– and ATP-Mg^2– matrix/cytoplasm concentration ratios are the same. This means that ATP-Mg^2– can be accumulated against a concentration gradient in proportion to the [HPO ₄ ^2– ] gradient that is normally maintained by the P_i/OH^– carrier. In liver, changes in matrix adenine nucleotide concentrations that are brought about by the ATP-Mg/P_i carrier can affect the activity of adenine nucleotide-dependent enzymes that are in the mitochondrial compartment. These enzymes in turn contribute to the overall regulation of bioenergetic function, flux through the gluconeogenesis and urea synthesis pathways, and organelle biogenesis. The ATP-Mg/P_i carrier is distinct from other mitochondrial transport systems with respect to kinetics and to substrate and inhibitor sensitivity. It is the only carrier regulated by Ca²⁺. This carrier is present in kidney and liver mitochondria, but not in heart.     

Transport of adenine nucleotides in the mitochondria of Saccharomyces cerevisiae: Interactions between the ADP/ATP carriers and the ATP-Mg/Pi carrier

The ADP/ATP and ATP-Mg/Pi carriers are widespread among eukaryotes and constitute two systems to transport adenine nucleotides in mitochondria. ADP/ATP carriers carry out an electrogenic exchange of ADP for ATP essential for oxidative phosphorylation, whereas ATP-Mg/Pi carriers perform an electroneutral exchange of ATP-Mg for phosphate and are able to modulate the net content of adenine nucleotides in mitochondria. The functional interplay between both carriers has been shown to modulate viability in Saccharomyces cerevisiae. The simultaneous absence of both carriers is lethal. In the light of the new evidence we suggest that, in addition to exchange of cytosolic ADP for mitochondrial ATP, the specific function of the ADP/ATP carriers required for respiration, both transporters have a second function, which is the import of cytosolic ATP in mitochondria. The participation of these carriers in the generation of mitochondrial membrane potential is discussed. Both are necessary for the function of the mitochondrial protein import and assembly systems, which are the only essential mitochondrial functions in S. cerevisiae.     

Yeast mitochondria import ATP through the calcium-dependent ATP-Mg/Pi carrier Sal1p, and are ATP consumers during aerobic growth in glucose

Sal1p, a novel Ca²⁺-dependent ATP-Mg/Pi carrier, is essential in yeast lacking all adenine nucleotide translocases. By targeting luciferase to the mitochondrial matrix to monitor mitochondrial ATP levels, we show in isolated mitochondria that both ATP-Mg and free ADP are taken up by Sal1p with a K _m of 0.20 ± 0.03 mM and 0.28 ± 0.06 mM respectively. Nucleotide transport along Sal1p is strictly Ca²⁺ dependent. Ca²⁺ increases the V _max with a S _0.5 of 15 μM, and no changes in the K _m for ATP-Mg. Glucose sensing in yeast generates Ca²⁺ transients involving Ca²⁺ influx from the external medium. We find that carbon-deprived cells respond to glucose with an immediate increase in mitochondrial ATP levels which is not observed in the presence of EGTA or in Sal1p-deficient cells. Moreover, we now report that during normal aerobic growth on glucose, yeast mitochondria import ATP from the cytosol and hydrolyse it through H⁺-ATP synthase. We identify two pathways for ATP uptake in mitochondria, the ADP/ATP carriers and Sal1p. Thus, during exponential growth on glucose, mitochondria are ATP consumers, as those from cells growing in anaerobic conditions or deprived of mitochondrial DNA which depend on cytosolic ATP and mitochondrial ATPase working in reverse to generate a mitochondrial membrane potential. In conclusion, the results show that growth on glucose requires ATP hydrolysis in mitochondria and recruits Sal1p as a Ca²⁺-dependent mechanism to import ATP-Mg from the cytosol. Whether this mechanism is used under similar settings in higher eukaryotes is an open question.     

A Biophysical Model of the Mitochondrial ATP-Mg/Pi Carrier

Mitochondrial adenine nucleotide (AdN) content is regulated through the Ca²⁺-activated, electroneutral ATP-Mg/P_i carrier (APC). The APC is a protein in the mitochondrial carrier super family that localizes to the inner mitochondrial membrane (IMM). It is known to modulate a number of processes that depend on mitochondrial AdN content, such as gluconeogenesis, protein synthesis, and citrulline synthesis. Despite this critical role, a kinetic model of the underlying mechanism has not been developed and validated. Here, a biophysical model of the APC is developed that is thermodynamically balanced and accurately reproduces a number of reported data sets from isolated rat liver and rat kidney mitochondria. The model is based on an ordered bi-bi mechanism for heteroexchange of ATP and P_i and includes homoexchanges of ATP and P_i to explain both the initial rate and time course data on ATP and P_i transport via the APC. The model invokes seven kinetic parameters regarding the APC mechanism and three parameters related to matrix pH regulation by external P_i. These parameters are estimated based on 19 independent data curves; the estimated parameters are validated using six additional data curves. The model takes into account the effects of pH, Mg²⁺, and Ca²⁺ on ATP and P_i transport via the APC, and supports the conclusion that the pH gradient across the IMM serves as the primary driving force for AdN uptake or efflux. Moreover, computer simulations demonstrate that extramatrix Ca²⁺ modulates the turnover rate of the APC and not the binding affinity of ATP, as previously suggested.     

Chenodeoxycholate is a potent inducer of the permeability transition pore in rat liver mitochondria

Several reports support the concept that bile acids may be cytotoxic during cholestatic disease process by causing mitochondrial dysfunction. Here we report additional data and findings aimed at a better understanding of the involvement of the permeability transition pore (PTP) opening in bile acids toxicity. The mitochondrial PTP is implicated as a mediator of cell injury and death in many situations. In the presence of calcium and phosphate, chenodeoxycholic acid (CDCA) induced a permeability transition in freshly isolated rat liver mitochondria, characterized by membrane depolarization, release of matrix calcium, and osmotic swelling. All these events were blocked by cyclosporine A (CyA) and the calcium uniporter inhibitor ruthenium red (RR). The results suggest that CDCA increases the sensitivity of isolated mitochondria in vitro to the calcium-dependent induction of the PTP.     

Characterization of SCaMC-3-like/slc25a41, a novel calcium-independent mitochondrial ATP-Mg/Pi carrier

The SCaMCs (small calcium-binding mitochondrial carriers) constitute a subfamily of mitochondrial carriers responsible for the ATP-Mg/P(i) exchange with at least three paralogues in vertebrates. SCaMC members are proteins with two functional domains, the C-terminal transporter domain and the N-terminal domain which harbours calcium-binding EF-hands and faces the intermembrane space. In the present study, we have characterized a shortened fourth paralogue, SCaMC-3L (SCaMC-3-like; also named slc25a41), which lacks the calcium-binding N-terminal extension. SCaMC-3L orthologues are found exclusively in mammals, showing approx. 60% identity to the C-terminal half of SCaMC-3, its closest paralogue. In mammalian genomes, SCaMC-3 and SCaMC-3L genes are adjacent on the same chromosome, forming a head-to-tail tandem array, and show identical exon-intron boundaries, indicating that SCaMC-3L could have arisen from an SCaMC-3 ancestor by a partial duplication event which occurred prior to mammalian radiation. Expression and functional data suggest that, following the duplication event, SCaMC-3L has acquired more restrictive functions. Unlike the broadly expressed longer SCaMCs, mouse SCaMC-3L shows a limited expression pattern; it is preferentially expressed in testis and, at lower levels, in brain. SCaMC-3L transport activity was studied in yeast deficient in Sal1p, the calcium-dependent mitochondrial ATP-Mg/P(i) carrier, co-expressing SCaMC-3L and mitochondrial-targeted luciferase, and it was found to perform ATP-Mg/P(i) exchange, in a similar manner to Sal1p or other ATP-Mg/P(i) carriers. However, metabolite transport through SCaMC-3L is calcium-independent, representing a novel mechanism involved in adenine nucleotide transport across the inner mitochondrial membrane, different to ADP/ATP translocases or long SCaMC paralogues.     

Kinetic mechanism of antiports catalyzed by reconstituted ornithine/citrulline carrier from rat liver mitochondria

The transport mechanism of the reconstituted ornithine/citrulline carrier purified from rat liver mitochondria was investigated kinetically. A complete set of half-saturation constants (K(m)) was established for ornithine, citrulline and H(+) on both the external and internal side of the liposomal membrane. The internal affinity for ornithine was much lower than that determined on the external surface. The exclusive presence of a single transport affinity for ornithine on each side of the membrane indicated a unidirectional insertion of the ornithine/citrulline carrier into liposomes, probably right-side-out with respect to mitochondria. Two-reactant initial velocity studies of the homologous (ornithine/ornithine) and heterologous (ornithine/citrulline) exchange reactions resulted in a kinetic pattern which is characteristic of a simultaneous antiport mechanism. This type of mechanism implies that the carrier forms a ternary complex with the substrates before the transport reaction occurs. A quantitative analysis of substrate interaction revealed that rapid-equilibrium random conditions were fulfilled, characterized by a fast and independent binding of internal and external substrates.     

Kinetics of the reconstituted dicarboxylate carrier from rat liver mitochondria

The dicarboxylate carrier from rat liver mitochondria was purified by the Amberlite/hydroxyapatite procedure and reconstituted in egg yolk phospholipid vesicles by removing the detergent with Amberlite. The efficiency of reconstitution was optimized with respect to the ratio of detergent/phospholipid, the concentration of phospholipid and the number of Amberlite column passages. In the reconstituted system the incorporated dicarboxylate carrier catalyzed a first-order reaction of malate/phosphate exchange. V of the reconstituted malate/phosphate exchange was determined to be 6000 mumol/min per g protein at 25 degrees C. This value was independent of the type of substrate present at the external or internal space of the liposomes (malate, phosphate or malonate). The half-saturation constant was 0.49 mM for malate, 0.54 mM for malonate and 1.41 mM for phosphate. The activation energy of the exchange reaction was determined to be 95.8 kJ/mol. The transport was independent of the external pH in the range between pH 6 and 8.     

Heat shock suppresses the permeability transition in rat liver mitochondria

Heat shock proteins inhibit apoptotic and necrotic cell death in various cell types. However, the specific mechanism underlying protection by heat shock proteins remains unclear. To test the hypothesis that heat shock proteins inhibit cell death by blocking opening of mitochondrial permeability transition (MPT) pores, mitochondria from heat-preconditioned rat livers were isolated by differential centrifugation. Heat shock inhibited MPT pore opening induced by 50 microm CaCl(2) plus 5 microm HgCl(2) or 1 microm mastoparan and by 200 microm CaCl(2) alone. Half-maximal swelling was delayed 15 min or more after heat shock compared with control. Heat shock also increased the threshold of unregulated (Ca(2+)-independent and cyclosporin A-insensitive) MPT pore opening induced by higher doses of HgCl(2) and mastoparan. Heat shock treatment decreased mitochondrial reactive oxygen species formation by 27% but did not change mitochondrial respiration, membrane potential, Ca(2+) uptake, or total glutathione in mitochondrial and cytosolic extracts of liver. Western blot analysis showed that mitochondrial Hsp25 increased, whereas Hsp10, Hsp60, Hsp70, Hsp75, cyclophilin D, and voltage-dependent anion channel did not change after heat shock. These results indicate that heat shock causes resistance to opening of MPT pores, which may contribute to heat shock protection against cellular injury.     

Kinetic characterization of the reconstituted carnitine carrier from rat liver mitochondria

The carnitine carrier was purified from rat liver mitochondria and reconstituted into liposomes by removing the detergent from mixed micelles by Amberlite. Optimal transport activity was obtained with 1 microgram/ml and 12.5 mg/ml of protein and phospholipid concentration, respectively, with a Triton X-100/phospholipid ratio of 1.8 and with 16 passages through the same Amberlite column. The activity of the carrier was influenced by the phospholipid composition of the liposomes, being increased in the presence of cardiolipin and decreased in the presence of phosphatidylinositol. In the reconstituted system the incorporated carnitine carrier catalyzed a carnitine/carnitine exchange which followed a first-order reaction. The maximum transport rate of external [3H]carnitine was 1.7 mmol/min per g protein at 25 degrees C and was independent of the type of countersubstrate. The half-saturation constant (Km) for carnitine was 0.51 mM. The affinity of the carrier for acylcarnitines was in the microM range and depended on the carbon chain length. The activation energy of the carnitine/carnitine exchange was 133 kJ/mol. The carrier function was independent of the pH in the range between 6 and 8 and was inhibited at pH below 6.     

Identification and purification of the tricarboxylate carrier from rat liver mitochondria

The tricarboxylate carrier from rat liver mitochondria was solubilized with Triton X-100 and purified by chromatography on hydroxyapatite and celite. SDS-gel electrophoresis of the purified fraction showed a single polypeptide band with an apparent Mr of 30,000. When reconstituted into liposomes, the tricarboxylate transport protein catalyzed a 1,2,3-benzenetricarboxylate-sensitive citrate/citrate exchange. We obtained a 1070-fold purification with respect to the mitochondrial extract, the recovery was 22% and the protein yield 0.02%. The properties of the reconstituted carrier, i.e., requirement for a counteranion, substrate specificity and inhibitor sensitivity, were similar to those of the tricarboxylate transport system as characterized in intact mitochondria.     

Kinetic characterization of the reconstituted tricarboxylate carrier from rat liver mitochondria

The tricarboxylate carrier from rat liver mitochondria was purified by chromatography on hydroxyapatite/celite and reconstituted in phospholipid vesicles by removing the detergent using hydrophobic chromatography on Amberlite. Optimal transport activity was obtained by using a Triton X-114/phospholipid ratio of 0.8, 6% cardiolipin and 24 passages through a single Amberlite column. In the reconstituted system the incorporated tricarboxylate carrier catalyzed a first-order reaction of citrate/citrate or citrate/malate exchange. The activation energy of the exchange reaction was 70.1 kJ/mol. The rate of the exchange had a pH optimum between 7 and 8. The half-saturation constant was 0.13 mM for citrate and 0.76 mM for malate. All these properties were similar to those described for the tricarboxylate transport system in intact mitochondria. In proteoliposomes the maximum exchange rate at 25 degrees C reached 2000 mumols/min per g protein. This value was independent of the type of substrate present at the external or internal space of the liposomes (citrate or malate).