Molecular aspects of the adenine nucleotide carrier from mitochondria

The ADP/ATP carrier (AAC) of mitochondria is a functionally central and characteristic component of the eukaryotic cell. By linking the thermodynamically divergent metabolites in the intra- and extramitochondrial compartments, it had to evolve with the emergence of the eukaryotic cell. Because of a number of unique properties, the AAC provided advanced insight into the molecular basis of solute transport through biomembrane carriers. With highly specific and unusually large substrates, ADP and ATP, and with high-affinity inhibitors binding selectively either from the inside or the outside, the first molecular demonstration of the single-binding-center gated pore mechanism was made. This framework can only partially be interpreted with the available yet rapidly increasing structural information on the AAC. The primary structure, first established for the AAC from beef heart mitochondria, showed a relatively wide distribution of hydrophilic residues which permits assignment of only two hydrophobic transmembrane stretches. However, a striking tripartition of the primary structure into about three 100-residue-long domains allows a more significant assignment of transmembrane elements. With alignment of these three domains for maximum conservation of structurally critical residues, each domain can be assigned to have two transmembrane alpha elements between 18 and 22 residues long. The interdomain homology between these alpha regions is low. The central regions flanked by these helices contain most of the polar residues and are significantly interdomain conserved. With lysine probes the central regions are assigned to the matrix side (m-side) and the two connecting regions as well as C and N termini to the cytosolic side (c-side). Out of the central regions a loop is assumed to protrude through the membrane, probably for lining the translocation channel. This localization of a major protein mass within the membrane agrees with hydrodynamic evidence, the carrier being an oblate ellipsoid with only about 50 A along the short axis. In accordance, the loops of domains 2 and 3 are affinity labeled by azido-ADP or azido-atractylate. Primary structures of AAC from other sources (fungi, plants) also exhibit the tripartition. The interdomain conserved residues are also interspecies conserved, thus showing that they are essential. These repeat domains have probably evolved from a common gene coding for about 100 residues. Isoforms of the AAC exist, as shown by primary structure analysis of human cDNA libraries from different organs. Three different isoforms are identified in human organs.(ABSTRACT TRUNCATED AT 400 WORDS)     

Inhibition of phosphoenolpyruvate transport via the tricarboxylate and adenine nucleotide carrier systems of rat liver mitochondria

The translocation of phosphoenolpyruvate by the tricarboxylate carrier system in rat liver mitochondria was shown to be inhibited by atractyloside and long chain fatty acyl CoA esters as well as benzene, 1, 2, 3 tricarboxylate. By contrast benzene 1, 2, 3 tricarboxylate did not inhibit atractyloside sensitive adenine nucleotide translocation catalyzed by phosphoenolpyruvate. These results indicate that although phosphoenoppyruvate is preferentially transported by the tricarboxylate carrier system, it may also be transported by the adenine nucleotide translocase. The inhibition of the adenine nucleotide and tricarboxylate carrier systems by atractyloside and long chain acyl CoA esters indicates a close functional interrelation-ship of these transport carriers in the inner mitochondrial membrane. Moreover, the potent inhibition of phosphoenolpyruvate, citrate, and adenine nucleotide transport by long chain acyl CoA's provides further evidence that these esters are natural effectors which participate in the regulation of gluconeogenesis, lipogenesis, and energy-linked respiration.     

Control of oxidative phosphorylation in rat heart mitochondria. The role of the adenine nucleotide carrier

Inhibitor titration experiments carried out with carboxyatractyloside, oligomycin and rotenone show that in the case of heart mitochondria the membrane-bound ATPase and the respiratory chain are the major factors controlling the rate of oxidative phosphorylation whereas the adenine nucleotide carrier exhibits no control strength. As shown by carboxyatractyloside titration curves under different conditions, the relative importance of the adenine nucleotide carrier depends on the mode of regeneration (F1-ATPase or glucose plus hexokinase) of ADP from ATP exported outside mitochondria, on the total concentration of adenine nucleotides present in the medium and on the mode of limitation of the rate of respiration (cyanide, rotenone, oligomycin or mersalyl). Concomitantly with the inhibition of O2 consumption, carboxyatractyloside brings about a rise in membrane potential. The inverse relationship between the two processes is observed for carboxyatractyloside concentrations ranging between 0.7 and 1.5 nmol per mg protein. Carboxyatractyloside concentrations below and above this range increase the membrane potential without affecting significantly the rate of respiration. Titration experiments aimed at comparing the effects of ADP, carboxyatractyloside and the uncoupler, carbonyl cyanide p-trifluoromethoxyphenylhydrazone, corroborate the conclusion that in heart mitochondria a major limiting factor in oxidative phosphorylation is the capacity of the respiratory chain.     

Control of oxidative phosphorylation in rat heart mitochondria: The role of the adenine nucleotide carrier

1. Inhibitor titration experiments carried out with carboxyatractyloside, oligomycin and rotenone show that in the case of heart mitochondria the membrane-bound ATPase and the respiratory chain are the major factors controlling the rate of oxidative phosphorylation whereas the adenine nucleotide carrier exhibits no control strength. 2. As shown by carboxyatractyloside titration curves under different conditions, the relative importance of the adenine nucleotide carrier depends on the mode of regeneration (F₁-ATPase or glucose plus hexokinase) of ADP from ATP exported outside mitochondria, on the total concentration of adenine nucleotides present in the medium and on the mode of limitation of the rate of respiration (cyanide, rotenone, oligomycin or mersalyl). 3. Concomitantly with the inhibition of O₂ consumption, carboxyatractyloside brings about a rise in membrane potential. The inverse relationship between the two processes is observed for carboxyatractyloside concentrations ranging between 0.7 and 1.5 nmol per mg protein. Carboxyatractyloside concentrations below and above this range increase the membrane potential without affecting significantly the rate of respiration. 4. Titration experiments aimed at comparing the effects of ADP, carboxyatractyloside and the uncoupler, carbonyl cyanide p-trifluoromethoxyphenylhydrazone, corroborate the conclusion that in heart mitochondria a major limiting factor in oxidative phosphorylation is the capacity of the respiratory chain.     

Control of adenine nucleotide metabolism in hepatic mitochondria from rats with ethanol-induced fatty liver

Male rats developed fatty liver after being fed on an ethanol-containing diet for 31 days. Liver mitochondria from these animals catalysed ATP synthesis at a slower rate when compared with mitochondria from pair-fed control rats (control mitochondria), and demonstrated lowered respiratory control with succinate as substrate, owing to a decrease in the State-3 respiratory rate. Respiration in the presence of uncoupler was comparable in mitochondria from both groups of rats. Translocation of both ATP and ADP was decreased in mitochondria from ethanol-fed rats, with ADP uptake being lowered more dramatically by ethanol feeding. Parameters influencing adenine nucleotide translocation were investigated in mitochondria from ethanol-fed rats. Experiments performed suggested that lowered adenine nucleotide translocation in these mitochondria is not the result of inhibition of the translocase by either long-chain acyl-CoA derivatives or unesterified fatty acids. Analysis of endogenous adenine nucleotides in these mitochondria revealed lowered ATP concentrations, but no decrease in total adenine nucleotides. In experiments where the endogenous ATP in these mitochondria was shifted to higher concentrations by incubation with oxidizable substrates or defatted bovine serum albumin, the rate of ADP translocation was increased, with a linear correlation being observed between endogenous ATP concentrations and the rate of ADP translocation. The depressed ATP concentration in mitochondria from ethanol-fed rats suggests that the ATP synthetase complex is replenishing endogenous ATP at a slower rate. The lowered ATPase activity of the ATP synthetase observed in submitochondrial particles from ethanol-fed animals suggests a decrease in the function of the synthetase complex. A decrease in the rate of ATP synthesis in mitochondria from ethanol-fed rats is sufficient to explain the decreased ADP translocation and State-3 respiration.     

Purification and characterization of the reconstitutively active adenine nucleotide carrier from maize mitochondria.

The adenine nucleotide carrier from maize (Zea mays L. cv B 73) shoot mitochondria was solubilized with Triton X-100 and purified by sequential chromatography on hydroxyapatite and Matrex Gel Blue B in the presence of cardiolipin and asolectin. Sodium dodecyl sulfate-gel electrophoresis of the purified fraction showed a single polypeptide band with an apparent molecular mass of 32 kD. When reconstituted in liposomes, the adenine nucleotide carrier catalyzed a pyridoxal 5'-phosphate-sensitive ATP/ATP exchange. It was purified 168-fold with a recovery of 60% and a protein yield of 0.25% with respect to the mitochondrial extract. Among the various substrates and inhibitors tested, the reconstituted protein transported only ADP, ATP, GDP, and GTP, and was inhibited by atractyloside, bongkrekate, phenylisothiocianate, pyridoxal 5'-phosphate, and mersalyl (but not N-ethylmaleimide). Maximum initial velocity of the reconstituted ATP/ATP exchange was determined to be 2.2 mumol min-1 mg-1 protein at 25 degrees C. The half-saturation constants and the corresponding inhibition constants were 17 microM for ATP, 26 microM for ADP, 59 microM for GTP, and 125 microM for GDP. The activation energy of the ATP/ATP exchange was 48 kilojoule/mol between 0 and 15 degrees C, and 22 kilojoule/mol between 15 and 35 degrees C. Partial amino acid sequences showed that the purified protein was the product of the ANT-G1 gene sequenced previously (B. Bathgate, A. Baker, C.J. Leaver [1989] Eur J Biochem 183: 303-310).     

The adenine nucleotide carrier of plant mitochondria: contraction induced by adenosine diphosphate

Energised mitochondria show an ADP-induced contraction which is partially resistant to oligomycin, uncouplers or respiratory inhibitors but sensitive to atractyloside.The addition of ADP or ATP, but not AMP, to non-energised corn mitochondria induces a contraction with a K_d of approx. 1 μM. Titration of the ADP-induced contraction with atractyloside produces an inhibition curve closely resembling the atractyloside inhibition curve of phosphorylating respiration. Partial recovery of atractyloside-inhibited contraction occurs in the presence of bongkrekic acid.It is suggested that these changes reflect changes in orientation of the adenine nucleotide (AdN) carrier in the inner mitochondrial membrane.     

Involvement of adenine nucleotide carrier in the mechanism of the apolipoprotein C induced decrease of membrane potential in rat liver mitochondria

Apolipoprotein C (apo C) was shown to decrease the Ca2+ capacity and membrane potential of mitochondria isolated from rat liver. The specific ligands of adenine nucleotide carrier, ADP and carboxyatractyloside (CAT), inhibited the effect of apo C on the mitochondrial membrane potential. The effect of ADP and CAT was revealed in the absence of Ca2+. We conclude that in the presence of apo C, adenine nucleosides carrier transforms into a pore, and this causes the decrease in the membrane potential of the mitochondria. ADP and CAT support the primary conformation of the carrier and therefore inhibit the effect of apolipoprotein C.     

Inhibition by local anaesthetics of adenine nucleotide translocation in rat liver mitochondria

1. The mechanism of adenine nucleotide translocation in mitochondria isolated from rat liver was further examined by using the local anaesthetics procaine, butacaine, nupercaine and tetracaine as perturbators of lipid-protein interactions. Each of these compounds inhibited translocation of ADP and of ATP; butacaine was the most effective with 50% inhibition occurring at 30mum for 200mum-ATP and at 10mum for 200mum-ADP. The degree of inhibition by butacaine of both adenine nucleotides was dependent on the concentration of adenine nucleotide present; with low concentrations of adenine nucleotide, low concentrations of butacaine-stimulated translocation, but at high concentrations (greater than 50mum) low concentrations of butacaine inhibited translocation. Butacaine increased the affinity of the translocase for ATP to a value which approached that of ADP. 2. Higher concentrations of nupercaine and of tetracaine were required to inhibit translocation of both nucleotides; 50% inhibition of ATP translocation occurred at concentrations of 0.5mm and 0.8mm of these compounds respectively. The pattern of inhibition of ADP translocation by nupercaine and tetracaine was more complex than that of ATP; at very low concentrations (less than 250mum) inhibition ensued, followed by a return to almost original rates at 1mm. At higher concentrations inhibition of ADP translocation resulted. 3. That portion of ATP translocation stimulated by Ca(2+) was preferentially inhibited by each of the local anaesthetics tested. In contrast, inhibition by the anaesthetics of ADP translocation was prevented by low concentrations of Ca(2+). 4. The data provide further support for our hypothesis that lipid-protein interactions are important determinants in the activity of the adenine nucleotide translocase in mitochondria.     

Modification by calcium ions of adenine nucleotide translocation in rat liver mitochondria

1. Added Ca(2+) stimulates the translocation of ATP by isolated rat liver mitochondria. 2. The apparent K(m) for added Ca(2+) in stimulating the translocation of 200mum-ATP is approx. 160mum (75mum ;free' Ca(2+)). 3. The greatest stimulation of ATP translocation by Ca(2+) occurs at the lower concentrations of ATP. 4. Sr(2+) (and to a lesser extent Ba(2+)) can replace Ca(2+) whereas Mg(2+) and Mn(2+) have only little ability to stimulate ATP translocation. 5. Translocation of dATP is also stimulated by Ca(2+) whereas that of ADP is stimulated to only a relatively small degree. 6. Studies with metabolic inhibitors and uncouplers provide evidence that stimulation by Ca(2+) and by uncouplers is additive and that the mechanism of Ca(2+) stimulation does not seem to involve the high-energy intermediate of oxidative phosphorylation. 7. In the presence of Ca(2+), ATP is able to effectively compete with ADP for translocation. 8. Added K(+) further enhances the ability of Ca(2+) to stimulate ATP translocation. 9. These findings are discussed in relation to the potential involvement of Ca(2+) in modifying enzymic reactions involved in the regulation of cell metabolism.     

Interaction of fluorescent adenine nucleotide derivatives with the ADP/ATP carrier in mitochondria. 1. Comparison of various 3'-O-ester adenine nucleotide derivatives

Fluorescent 3'-O-acyl-substituted adenine nucleotide (dimethylamino)naphthoyl and trinitrophenyl groups were studied for binding to the ADP/ATP carrier in mitochondria and submitochondrial particles. The changes in fluorescence intensity and emission maximum are for the most part similar to those observed in nonaqueous solvents. The (dimethylamino)naphthoyl derivatives from a largely quenched aqueous state have a shortwave shift up to 85 nm and increase up to 90-fold (1,5 derivative), whereas the little quenched naphthoyl derivatives show a fluorescence decrease and the weakly fluorescent trinitrophenyl derivative shows only a small increase on binding. All derivatives are good inhibitors (K1 = 1-10 microM) of nucleotide transport. The fluorescence titrations have an apparent K1/2 = 2-7 microM. The fluorescence of the 1,5-DAN nucleotide is fully suppressed by bongkrekate but only partially suppressed by carboxyatractylate. The fluorescence response is much stronger in submitochondrial particles than in mitochondria. Both facts suggest fluorescent binding to the "m" state of the carrier site at the inner face of the membrane. 1,5-DAN-AMP shows a slightly more efficient binding than DAN-ADP or DAN-ATP.