Dialectics in carrier research: The ADP/ATP carrier and the uncoupling protein

A concise review is given of the research in our laboratory on the ADP/ATP carrier (AAC) and the uncoupling protein (UCP). Although homologous proteins, their widely different functions and contrasts are stressed. The pioneer role of research on the AAC, not only for the mitochondrial but also for other carriers, and the present state of their structure-function relationship is reviewed. The function of UCP as a highly regulated H⁺ carrier is described in contrast to the largely unregulated ADP/ATP exchange in AAC. General principles of carrier catalysis as derived from studies on the AAC and UCP are elucidated.     

Sorting pathways of mitochondrial inner membrane proteins

Two distinct pathways of sorting and assembly of nuclear-encoded mitochondrial inner membrane proteins are described. In the first pathway, precursor proteins that carry amino-terminal targeting signals are initially translocated via contact sites between both mitochondrial membranes into the mitochondrial matrix. They become proteolytically processed, interact with the 60-kDa heat-shock protein hsp60 in the matrix and are retranslocated to the inner membrane. The sorting of subunit 9 of Neurospora crassa F0-ATPase has been studied as an example. F0 subunit 9 belongs to that class of nuclear-encoded mitochondrial proteins which are evolutionarily derived from a prokaryotic ancestor according to the endosymbiont hypothesis. We suggest that after import into mitochondria, these proteins follow the ancestral sorting and assembly pathways established in prokaryotes (conservative sorting). On the other hand, ADP/ATP carrier was found not to require interaction with hsp60 for import and assembly. This agrees with previous findings that the ADP/ATP carrier possesses non-amino-terminal targeting signals and uses a different import receptor to other mitochondrial precursor proteins. It is proposed that the ADP/ATP carrier represents a class of mitochondrial inner membrane proteins which do not have a prokaryotic equivalent and thus appear to follow a non-conservative sorting pathway.     

Conserved structural domains among species and tissues-specific differences in the mitochondrial phosphate-transport protein and the ADP/ATP carrier

Peptide maps were generated of the CNBr-digested mitochondrial phosphate-transport protein and ADP/ATP carrier from bovine and rat heart, rat liver and blowfly flight muscle. Total mitochondrial proteins from the same sources plus pig heart were separated by SDS-polyacrylamide gel electrophoresis. The peptide maps and the total mitochondrial proteins were electroblotted onto nitrocellulose membranes and reacted with rabbit antisera raised against the purified bovine heart phosphate-transport protein and the ADP/ATP carrier. On the basis of antibody specificity, mobility in SDS-polyacrylamide gel electrophoresis, and peptide maps the following was concluded. Phosphate-transport protein alpha and phosphate-transport protein beta (pig and bovine heart) react equally with the first and also with the second of two independent phosphate-transport protein-antisera. Tissue-specific structural domains exist for both the phosphate-transport protein and the ADP/ATP carrier, i.e., one phosphate-transport protein-antiserum reacts with the phosphate-transport protein from all assayed sources, the other only with the cardiac phosphate-transport protein. These differences may reflect tissue-specific regulation of phosphate and adenine nucleotide transport. Homologies among the different species are found for the phosphate transport protein and the ADP/ATP carrier, except for the flight muscle ADP/ATP carrier. These conserved structural domains of the phosphate-transport protein may relate directly to catalytic activity. Alkylation of the purified phosphate-transport proteins and the ADP/ATP carriers by the transport inhibitor N-ethylmaleimide affects electrophoretic mobilities but not the antibody binding. Neither of the two phosphate-transport protein-antisera nor the ADP/ATP-carrier antiserum react with both phosphate transport protein and ADP/ATP carrier, even though these two proteins possess similarities in primary structure and function. Possible mechanisms for generating tissue-specific structural differences in the proteins are discussed.     

Conserved structural domains among species and tissues-specific differences in the mitochondrial phosphate-transport protein and the ADP/ATP carrier

Peptide maps were generated of the CNBr-digested mitochondrial phosphate-transport protein and ADP/ATP carrier from bovine and rat heart, rat liver and blowfly flight muscle. Total mitochondrial proteins from the same sources plus pig heart were separated by SDS-polyacrylamide gel electrophoresis. The peptide maps and the total mitochondrial proteins were electroblotted onto nitrocellulose membranes and reacted with rabbit antisera raised against the purified bovine heart phosphate-transport protein and the ADP/ATP carrier. On the basis of antibody specificity, mobility in SDS-polyacrylamide gel electrophoresis, and peptide maps the following was concluded. (1) Phosphate-transport protein and phosphate-transport protein β (pig and bovine heart) react equally with the first and also with the second of two independent phosphate-transport protein-antisera. (2) Tissue-specific structural domains exist for both the phosphate-transport protein and the ADP/ATP carrier, i.e., one phosphate-transport protein-antiserum reacts with the phosphate-transport protein from all assayed sources, the other only with the cardiac phosphate-transport protein. These differences may reflect tissue-specific regulation of phosphate and adenine nucleotide transport. (3) Homologies among the different species are found for the phosphate transport protein and the ADP/ATP carrier, except for the flight muscle ADP/ATP carrier. These conserved structural domains of the phosphate-transport protein may relate directly to catalytic activity. (4) Alkylation of the purified phosphate-transport proteins and the ADP/ATP carriers by the transport inhibitor N-ethylmaleimide affects electrophoretic mobilities but not the antibody binding. (5) Neither of the two phosphate-transport protein-antisera nor the ADP/ATP-carrier antiserum react with both phosphate transport protein and ADP/ATP carrier, even though these two proteins possess similarities in primary structure and function. Possible mechanisms for generating tissue-specific structural differences in the proteins are discussed.     

The topology of the brown adipose tissue mitochondrial uncoupling protein determined with antibodies against its antigenic sites revealed by a library of fusion proteins.

The uncoupling protein (UCP) of brown adipose tissue mitochondria is a specialized member of the family of evolutionarily related mitochondrial membrane transporters, which also includes the ADP/ATP translocator and the phosphate carrier. We have generated a library of bacterial clones randomly expressing short subsequences of the UCP fused to the MalE periplasmic protein of Escherichia coli. Anti-UCP sera were used to select clones expressing antigenic sequences of the UCP. Ten different fusion proteins representing eight non-overlapping subsequences of the UCP were obtained. The ability of fusion proteins to select antibodies directed against a short segment of the UCP was used to study the topological organization of the UCP in the inner mitochondrial membrane. Four different fusion proteins were used to determine the orientation of the N-terminal extremities of the first, second, third and fourth predicted alpha-helices of the UCP. This topological study together with previous data on the UCP provides an experimental basis for the predicted structure of the UCP and for other homologous carrier proteins.     

Human uncoupling protein gene: structure, comparison with rat gene, and assignment to the long arm of chromosome 4

The uncoupling protein (UCP) gene encodes a unique mammalian mitochondrial proton carrier that induces heat production in brown adipocytes. Human UCP gene was isolated and its organization analyzed. A comparison was made with rat UCP gene. Human UCP gene spans 13 Kb and contains a transcribed region that covers 9 Kb of the human genome. All of the exons were also sequenced except the extreme end of the 3' untranslated region. Two Kb DNA upstream the TATA box were also sequenced. This region contains several fragments that are highly homologous to the gene of rat UCP. Neither CCAAT sequence nor Sp 1 binding motif were detected. Human UCP gene is split into six exons. The complete amino acid sequence of the protein was determined. Human UCP has 305 amino acids and a molecular weight of 32,786. It has no N-terminal targeting sequence. It is 79% homologous to rat UCP both at nucleotidic and amino acid levels. The primary structure of UCP is significantly homologous to the primary structure of the human T1 ADP/ATP carrier, particularly in the C-terminal extremity, which is supposed to contain a nucleotide-binding site in both proteins. Human UCP gene is single type, as it is in rodents. Two genomic fragments were used to detect a 1.9 Kb mRNA in human perirenal brown adipose tissue. Using in situ hybridization, UCP gene was assigned in humans to chromosome 4 in q31. Interestingly, the T1 gene encoding the heart-skeletal muscle ADP/ATP carrier has recently been shown to be on the same chromosome (Li et al. Biol Chem 264:13998, 1989).     

Anion Carriers in Fatty Acid-Mediated Physiological Uncoupling

Physiological aspects of uncoupling of oxidation and phosphorylation are reviewed in thecontext of involvement of mitochondrial anion carriers. It is assumed that the carriers facilitateelectrophoretic translation of fatty acid anion, RCOO^-, from the inner to the outer leaflet ofthe mitochondrial membrane, whereas back movement of the protonated fatty acid, RCOOH,from the outer to the inner leaflet represents flip-flop of RCOOH via the phospholipid bilayerof the membrane. The RCOO^- transport seems to be catalyzed by the ATP/ADP and aspartate/glutamate antiporters, dicarboxylate carrier, and uncoupling proteins (UCP1, UCP2, UCP3^L,UCP3^s, and plant UCP). The fatty acid uncoupling is shown to be involved in thethermoregulatory heat production in animals and plants exposed to cold, as well as in performance ofrespiratory functions other than ATP synthesis, i.e., formation of useful substances,decomposition of unwanted substances, and antioxidant defense. Moreover, partial uncoupling might takepart in optimization of the rate of ATP synthesis in aerobic cells.     

Redundancy in the function of mitochondrial phosphate transport in Saccharomyces cerevisiae and Arabidopsis thaliana

Most cellular ATP is produced within the mitochondria from ADP and Pi which are delivered across the inner-membrane by specific nuclearly encoded polytopic carriers. In Saccharomyces cerevisiae, some of these carriers and in particular the ADP/ATP carrier, are represented by several related isoforms that are distinct in their pattern of expression. Until now, only one mitochondrial Pi carrier (mPic) form, encoded by the MIR1 gene in S. cerevisiae, has been described. Here we show that the gene product encoded by the YER053C ORF also participates in the delivery of phosphate to the mitochondria. We have called this gene PIC2 for Pi carrier isoform 2. Overexpression of PIC2 compensates for the mitochondrial defect of the double mutant Deltamir1 Deltapic2 and restores phosphate transport activity in mitochondria swelling experiments. The existence of two isoforms of mPic does not seem to be restricted to S. cerevisiae as two Arabidopsis thaliana cDNAs encoding two different mPic-like proteins are also able to complement the double mutant Deltamir1 Deltapic2. Finally, we demonstrate that Pic2p is a mitochondrial protein and that its steady state level increases at high temperature. We propose that Pic2p is a minor form of mPic which plays a role under specific stress conditions.     

A sequence related to a DNA recognition element is essential for the inhibition by nucleotides of proton transport through the mitochondrial uncoupling protein.

The uncoupling protein (UCP) is uniquely expressed in brown adipose tissue, which is a thermogenic organ of mammals. The UCP uncouples mitochondrial respiration from ATP production by introducing a proton conducting pathway through the mitochondrial inner membrane. The activity of the UCP is regulated: nucleotide binding to the UCP inhibits proton conductance whereas free fatty acids increase it. The similarities between the UCP, the ADP/ATP carrier and the DNA recognition element found in the DNA binding domain of the estrogen receptor suggested that these proteins could share common features in their respective interactions with free nucleotides or DNA, and thus defined a putative 'nucleotide recognition element' in the UCP. This article provides demonstration of the validity of this hypothesis. The putative nucleotide recognition element corresponding to the amino acids 261-269 of the UCP was gradually destroyed, and these mutant proteins were expressed in yeast. Flow cytometry, measuring the mitochondrial membrane potential in vivo, showed increased uncoupling activities of these mutant proteins, and was corroborated with studies with isolated mitochondria. The deletion of the three amino acids Phe267, Lys268 and Gly269, resulted in a mutant where proton leak could be activated by fatty acids but not inhibited by nucleotides.     

The carboxyl-terminal two-thirds of the ADP/ATP carrier polypeptide contains sufficient information to direct translocation into mitochondria

The precursor of the mitochondrial inner membrane protein ADP/ATP carrier is cytoplasmically synthesized without an amino-terminal peptide extension. We constructed a truncated precursor lacking the 103 amino acids from the amino terminus (about a third of the protein). Import of the truncated precursor into mitochondria showed the import characteristics of the authentic precursor, including nucleoside triphosphate dependence, requirement for a protease-sensitive component on the mitochondrial surface, two-step specific binding to the outer membrane, and membrane potential-dependent translocation into the inner membrane. We conclude that, in contrast to all other mitochondrial precursor proteins studied so far, domains of the ADP/ATP carrier distant from the amino terminus can carry specific targeting information for transport into mitochondria.     

A divergent ADP/ATP carrier in the hydrogenosomes of Trichomonas gallinae argues for an independent origin of these organelles

The evolution of mitochondrial ADP and ATP exchanging proteins (AACs) highlights a key event in the evolution of the eukaryotic cell, as ATP exporting carriers were indispensable in establishing the role of mitochondria as ATP-generating cellular organelles. Hydrogenosomes, i.e. ATP- and hydrogen-generating organelles of certain anaerobic unicellular eukaryotes, are believed to have evolved from the same ancestral endosymbiont that gave rise to present day mitochondria. Notably, the hydrogenosomes of the parasitic anaerobic flagellate Trichomonas seemed to be deficient in mitochondrial-type AACs. Instead, HMP 31, a different member of the mitochondrial carrier family (MCF) with a hitherto unknown function, is abundant in the hydrogenosomal membranes of Trichomonas vaginalis. Here we show that the homologous HMP 31 of closely related Trichomonas gallinae specifically transports ADP and ATP with high efficiency, as do genuine mitochondrial AACs. However, phylogenetic analysis and its resistance against bongkrekic acid (BKA, an efficient inhibitor of mitochondrial-type AACs) identify HMP 31 as a member of the mitochondrial carrier family that is distinct from all mitochondrial and hydrogenosomal AACs studied so far. Thus, our data support the hypothesis that the various hydrogenosomes evolved repeatedly and independently.     

Heme oxygenase-1 enhances renal mitochondrial transport carriers and cytochrome C oxidase activity in experimental diabetes

Up-regulation of heme oxygenase (HO-1) by either cobalt protoporphyrin (CoPP) or human gene transfer improves vascular and renal function by several mechanisms, including increases in antioxidant levels and decreases in reactive oxygen species (ROS) in vascular and renal tissue. The purpose of the present study was to determine the effect of HO-1 overexpression on mitochondrial transporters, cytochrome c oxidase, and anti-apoptotic proteins in diabetic rats (streptozotocin, (STZ)-induced type 1 diabetes). Renal mitochondrial carnitine, deoxynucleotide, and ADP/ATP carriers were significantly reduced in diabetic compared with nondiabetic rats (p < 0.05). The citrate carrier was not significantly decreased in diabetic tissue. CoPP administration produced a robust increase in carnitine, citrate, deoxynucleotide, dicarboxylate, and ADP/ATP carriers and no significant change in oxoglutarate and aspartate/glutamate carriers. The increase in mitochondrial carriers (MCs) was associated with a significant increase in cytochrome c oxidase activity. The administration of tin mesoporphyrin (SnMP), an inhibitor of HO-1 activity, prevented the restoration of MCs in diabetic rats. Human HO-1 cDNA transfer into diabetic rats increased both HO-1 protein and activity, and restored mitochondrial ADP/ATP and deoxynucleotide carriers. The increase in HO-1 by CoPP administration was associated with a significant increase in the phosphorylation of AKT and levels of BcL-XL proteins. These observations in experimental diabetes suggest that the cytoprotective mechanism of HO-1 against oxidative stress involves an increase in the levels of MCs and anti-apoptotic proteins as well as in cytochrome c oxidase activity.     

Functional integration of mitochondrial and hydrogenosomal ADP/ATP carriers in the Escherichia coli membrane reveals different biochemical characteristics for plants, mammals and anaerobic chytrids.

The expression of mitochondrial and hydrogenosomal ADP/ATP carriers (AACs) from plants, rat and the anaerobic chytridiomycete fungus Neocallimastix spec. L2 in Escherichia coli allows a functional integration of the recombinant proteins into the bacterial cytoplasmic membrane. For AAC1 and AAC2 from rat, apparent Km values of about 40 microm for ADP, and 105 microm or 140 microm, respectively, for ATP have been determined, similar to the data reported for isolated rat mitochondria. The apparent Km for ATP decreased up to 10-fold in the presence of the protonophore m-chlorocarbonylcyanide phenylhydrazone (CCCP). The hydrogenosomal AAC isolated from the chytrid fungus Neocallimastix spec. L2 exhibited the same characteristics, but the affinities for ADP (165 microm) and ATP (2.33 mm) were significantly lower. Notably, AAC1-3 from Arabidopsis thaliana and AAC1 from Solanum tuberosum (potato) showed significantly higher external affinities for both nucleotides (10-22 microm); they were only slightly influenced by CCCP. Studies on intact plant mitochondria confirmed these observations. Back exchange experiments with preloaded E. coli cells expressing AACs indicate a preferential export of ATP for all AACs tested. This is the first report of a functional integration of proteins belonging to the mitochondrial carrier family (MCF) into a bacterial cytoplasmic membrane. The technique described here provides a relatively simple and highly reproducible method for functional studies of individual mitochondrial-type carrier proteins from organisms that do not allow the application of sophisticated genetic techniques.     

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.     

MRS3 and MRS4, two suppressors of mtRNA splicing defects in yeast, are new members of the mitochondrial carrier family.

When present in high copy number plasmids, the nuclear genes MRS3 and MRS4 from Saccharomyces cerevisiae can suppress the mitochondrial RNA splicing defects of several mit- intron mutations. Both genes code for closely related proteins of about Mr 32,000; they are 73% identical. Sequence comparisons indicate that MRS3 and MRS4 may be related to the family of mitochondrial carrier proteins. Support for this notion comes from a structural analysis of these proteins. Like the ADP/ATP carrier protein (AAC), the mitochondrial phosphate carrier protein (PiC) and the uncoupling protein (UCP), the two MRS proteins have a tripartite structure; each of the three repeats consists of two hydrophobic domains that are flanked by specific amino acid residues. The spacing of these specific residues is identical in all domains of all proteins of the family, whereas spacing between the hydrophobic domains is variable. Like the AAC protein, the MRS3 and MRS4 proteins are imported into mitochondria in vitro and without proteolytic cleavage of a presequence and they are located in the inner mitochondrial membrane. In vivo studies support this mitochondrial localization of the MRS proteins. Overexpression of the MRS3 and MRS4 proteins causes a temperature-dependent petite phenotype; this is consistent with a mitochondrial function of these proteins. Disruption of these genes affected neither mitochondrial functions nor cellular viability. Their products thus have no essential function for mitochondrial biogenesis or for whole yeast cells that could not be taken over by other gene products. The findings are discussed in relation to possible functions of the MRS proteins in mitochondrial solute translocation and RNA splicing.     

Yeast mitochondrial ADP/ATP carriers are monomeric in detergents as demonstrated by differential affinity purification

Most mitochondrial carriers carry out equimolar exchange of substrates and they are believed widely to exist as homo-dimers. Here we show by differential tagging that the yeast mitochondrial ADP/ATP carrier AAC2 is a monomer in mild detergents. Carriers with and without six-histidine or hemagglutinin tags were co-expressed in defined molar ratios in yeast mitochondrial membranes. Their specific transport activity was unaffected by tagging or by co-expression. The co-expressed carriers were extracted from the membranes with mild detergents and purified rapidly by affinity chromatography. All of the untagged carriers were in the flow-through of the affinity column, whereas all of the tagged carriers bound to the column and were eluted subsequently, showing that stable dimers, consisting of associated tagged and untagged carriers, were not present. The specific inhibitors carboxyatractyloside and bongkrekic acid and the substrates ADP, ATP and ADP plus ATP were added during the experiments to determine whether lack of association might have been caused by carriers being prevented from cycling through the various states in the transport cycle where dimers might form. All of the protein was accounted for, but stable dimers were not detected in any of these conditions, showing that yeast ADP/ATP carriers are monomeric in detergents in agreement with their hydrodynamic properties and with their structure. Since strong interactions between monomers were not observed in any part of the transport cycle, it is highly unlikely that the carriers function cooperatively. Therefore, transport mechanisms need to be considered in which the carrier is operational as a monomer.     

Cardiolipin dynamics and binding to conserved residues in the mitochondrial ADP/ATP carrier

Cardiolipin in eukaryotes is found in the mitochondrial inner membrane, where it interacts with membrane proteins and, although not essential, is necessary for the optimal activity of a number of proteins. One of them is the mitochondrial ADP/ATP carrier, which imports ADP into the mitochondrion and exports ATP. In the crystal structures, cardiolipin is bound to three equivalent sites of the ADP/ATP carrier, but its role is unresolved. Conservation of residues at these cardiolipin binding sites across other members of the mitochondrial carrier superfamily indicates cardiolipin binding is likely to be important for the function of all mitochondrial carriers. Multiscale simulations were performed in a cardiolipin-containing membrane to investigate the dynamics of cardiolipin around the yeast and bovine ADP/ATP carriers in a lipid bilayer and the properties of the cardiolipin-binding sites. In coarse-grain simulations, cardiolipin molecules bound to the carriers for longer periods of time than phosphatidylcholine and phosphatidylethanolamine lipids—with timescales in the tens of microseconds. Three long-lived cardiolipin binding sites overlapped with those in the crystal structures of the carriers. Other shorter-lived cardiolipin interaction sites were identified in both membrane leaflets. However, the timescales of the interactions were of the same order as phosphatidylcholine and phosphatidylethanolamine, suggesting that these sites are not specific for cardiolipin binding. The calculation of lipid binding times and the overlap of the cardiolipin binding sites between the structures and simulations demonstrate the potential of multiscale simulations to investigate the dynamics and behavior of lipids interacting with membrane proteins.     

Uncoupling protein-1 (UCP1) contributes to the basal proton conductance of brown adipose tissue mitochondria

Proton leak pathways uncouple substrate oxidation from ATP synthesis in mitochondria. These pathways are classified as basal (not regulated) or inducible (activated and inhibited). Previously it was found that over half of the basal proton conductance of muscle mitochondria was catalyzed by the adenine nucleotide translocase (ANT), an abundant mitochondrial anion carrier protein. To determine whether ANT is the unique protein catalyst, or one of many proteins that catalyze basal proton conductance, we measured proton leak kinetics in mitochondria isolated from brown adipose tissue (BAT). BAT can express another mitochondrial anion carrier, UCP1, at concentrations similar to ANT. Basal proton conductance was measured under conditions where UCP1 and ANT were catalytically inactive and was found to be lower in mitochondria from UCP1 knockout mice compared to wild-type. Ablation of another abundant inner membrane protein, nicotinamide nucleotide transhydrogenase, had no effect on proton leak kinetics in mitochondria from liver, kidney or muscle, showing that basal proton conductance is not catalyzed by all membrane proteins. We identify UCP1 as a second protein propagating basal proton leak, lending support to the hypothesis that basal leak pathways are perpetrated by members of the mitochondrial anion carrier family but not by other mitochondrial inner membrane proteins.