Purification of histidine-tagged mitochondrial ADP/ATP carrier: influence of the conformational states of the C-terminal region

A functional recombinant mitochondrial ADP/ATP carrier from the yeast Saccharomyces cerevisiae that bears a six-histidine tag at the C-terminus, Anc2(His(6))p, has been engineered to allow its purification by immobilized metal-ion affinity chromatography (IMAC). The tagged carrier was expressed at a level similar to that of unmodified Anc2p as determined by immunodetection and titration of the specific atractyloside binding sites. Anc2(His(6))p, enriched by chromatography on hydroxyapatite of detergent extracts of mitochondria, was still contaminated by mitochondrial proteins and a large amount of ergosterol. It was highly purified after adsorption on Ni-NTA resin and elution by imidazole buffer, with a 90-95% overall yield. Anc2(His(6))p interacted differently with immobilized ions depending on whether it was unliganded or bound to carboxyatractyloside (CATR) or bongkrekic acid (BA), two specific inhibitors of the ADP/ATP transport, thus indicating that accessibility of the C-terminus is markedly influenced by the conformational state of the carrier. Fluorometric assays demonstrated that purified unliganded Anc2(His(6))p was in a functional state since it underwent CATR- and BA-sensitive and ADP (or ATP)-induced conformational changes. Large-scale purification of Anc2(His(6))p-CATR and Anc2(His(6))p-BA complexes by IMAC will be of major interest for structural analysis of the ADP/ATP carrier.     

6'-O-dansyl-gamma-aminobutyryl atractyloside, a fluorescent probe of the ADP/ATP carrier: exploration of conformational changes of the membrane-bound ADP/ATP carrier elicited by substrates and inhibitors

A fluorescent atractyloside analogue, the 6'-O-dansyl-gamma-aminobutyryl atractyloside (DGA), has been used to probe the binding of the inhibitors carboxyatractyloside (CATR) and bongkrekic acid (BA) and nucleotide substrates to the membrane-bound ADP/ATP carrier protein in beef heart mitochondria. Binding and release of DGA were followed by fluorescence responses. Specifically bound DGA was fully released by CATR alone, or by BA in the presence of micromolar amounts of ADP. In the absence of the inhibitors, ADP increased the rate of the specific binding of DGA. The effect of ADP was shared by transportable nucleotides. Non transportable nucleotides were ineffective. These data are consistent with the previously described CATR and BA conformations of the ADP/ATP carrier that are able to bind CATR and BA respectively, the transition between the two conformations being accelerated by micromolar concentrations of transportable nucleotides.     

Functional characterization and purification of a Saccharomyces cerevisiae ADP/ATP carrier-iso 1 cytochrome c fusion protein

A recombinant fusion protein combining the mitochondrial ADP/ATP carrier (Anc2p) and the iso-1-cytochrome c (Cyc1p), both from Saccharomyces cerevisiae, has been genetically elaborated with the aim of increasing the polar surface area of the carrier to facilitate its crystallization. The gene encoding the his-tagged fusion protein was expressed in yeast under the control of the regulatory sequences of ScANC2. The chimeric carrier, Anc2-Cyc1(His6)p, was able to restore growth on a non-fermentable carbon source of a yeast strain devoid of functional ADP/ATP carrier, which demonstrated its transport activity. The kinetic exchange properties of Anc2-Cyc1(His6)p and the wild type his-tagged carrier Anc2(His6)p were very similar. However, Anc2-Cyc1(His6)p restored cell growth less efficiently than Anc2(His6)p which correlates with the lower amount found in mitochondria. Purification of Anc2-Cyc1(His6)p in complex with carboxyatractyloside (CATR), a high affinity inhibitor of ADP/ATP transport, was achieved by combining ion-exchange chromatography and ion-metal affinity chromatography in the presence of LAPAO, an aminoxide detergent. As characterized by absorption in the visible range, heme was found to be present in isolated Anc2-Cyc1(His6)p, giving the protein a red color. Large-scale purification of Anc2-Cyc1(His6)p-CATR complex opens up novel possibilities for the use of crystallographic approaches to the yeast ADP/ATP carrier.     

Yeast ADP/ATP carrier isoform 2: conformational dynamics and role of the RRRMMM signature sequence methionines

The mitochondrial ADP/ATP carrier, or Ancp, is a member of the mitochondrial carrier family responsible for exchanging ADP and ATP across the mitochondrial inner membrane. ADP/ATP transport involves Ancp switching between two conformational states. These can be analyzed using specific inhibitors, carboxyatractyloside (CATR) and bongkrekic acid (BA). The high resolution three-dimensional structure of bovine Anc1p (bAnc1p), as a CATR-carrier complex, has been solved. However, because the structure of the BA-carrier complex has not yet been determined, the detailed mechanism of transport remains unknown. Recently, sample processing for hydrogen/deuterium exchange experiments coupled to mass spectrometry was improved, providing novel insights into bAnc1p conformational transitions due to inhibitor binding. In this work we performed both hydrogen/deuterium exchange-mass spectrometry experiments and genetic manipulations. Because these are very difficult to apply with bovine Anc1p, we used Saccharomyces cerevisiae Anc isoform 2 (ScAnc2p). Significant differences in solvent accessibility were observed throughout the amino acid sequence for ScAnc2p complexed to either CATR or BA. Interestingly, in detergent solution, the conformational dynamics of ScAnc2p were dissimilar to those of bAnc1p, in particular for the upper half of the cavity, toward the intermembrane space, and the m2 loop, which is thought to be easily accessible to the solvent from the matrix in bAnc1p. Our study then focused on the methionyl residues of the Ancp signature sequence, RRRMMM. All our results indicate that the methionine cluster is involved in the ADP/ATP transport mechanism and confirm that the Ancp cavity is a highly dynamic structure.     

Dependence of the conformational state of the isolated adenine nucleotide carrier protein on the detergent used for solubilization

The mitochondrial adenine nucleotide (AdN) carrier can assume two conformational states that are trapped by the specific inhibitors of AdN transport carboxyatractyloside (CATR) and bongkrekic acid (BA). When the AdN carrier protein was extracted from beef heart mitochondria by the zwitterionic detergent 3-[(3-cholamidopropyl)dimethylammonio)]-1-propanesulfonate (CHAPS) and purified in the same detergent, the fluorescence of the tryptophanyl residue(s) of the protein was partially quenched by ATP (or ADP), but not by nontransportable nucleotides; CATR, which alone was ineffective, was able in the presence of ATP (ADP) to further quench the fluorescence, and BA reversed the quenched fluorescence to the original level. With 3'-O-naphthoyl-ATP (N-ATP) as an extrinsic fluorescence probe, it was shown that BA could release bound N-ATP but that CATR was ineffective. These results indicate that the AdN carrier in CHAPS is able to react readily with BA, but not with CATR. The opposite situation occurs with the carrier solubilized and purified in (laurylamido)-N,N-dimethylpropylamine oxide (LAPAO) [Brandolin, G., Dupont, Y., & Vignais, P.V. (1985) Biochemistry 24, 1991-1997]. These data taken together were interpreted to mean that the CATR and BA conformations of the isolated AdN carrier depend on the micellar structure in which it is embedded; the carrier in LAPAO is in the CATR conformation, and the carrier in CHAPS is in the BA conformation. For the transition between the CATR and BA conformations to occur in the carrier in CHAPS and in the carrier in LAPAO, ATP or ADP is required; nontransportable nucleotides were ineffective.(ABSTRACT TRUNCATED AT 250 WORDS)     

Chemical,immunological, enzymatic,and genetic approaches to studying the arrangement of the peptide chain of the ADP/ATP carrier in the mitochondrial membrane

In the process of oxidative phosphorylation, the exchange of cytosolic ADP^3– against mitochondrial ATP^4– across the inner mitochondrial membrane is mediated by a specific carrier protein. Two different conformations for this carrier have been demonstrated on the basis of interactions with specific inhibitors, namely carboxyatractyloside (CATR) and bongkrekic acid (BA). The two conformations, referred to as CATR and BA conformations, are interconvertible, provided that ADP or ATP are present. The functional ADP/ATP carrier is probably organized as a tetramer. In the presence of CATR or BA the tetramer is split into two dimers combined with either of the two inhibitors. The amino acid sequence of the beef heart carrier monomer (297 residues) contains three repeats of about 100 residues each. Experimental results obtained through different approaches, including photolabeling, immunochemistry, and limited proteolysis, can be interpreted on the basis of a model with five or six transmembrane helices per carrier monomer. Two mobile regions involved in the binding of nucleotides and accessible to proteolytic enzymes have been identified. Each of them may be visualized as consisting of two pairs of short amphipathic helices, which can be juxtaposed to form hydrophilic channels facilitating the nucleotide transport. Mutagenesis in yeast is currently being used to detect strategic amino acids in ADP/ATP transport.     

Two distinct regions of the yeast mitochondrial ADP/ATP carrier are photolabeled by a new ADP analogue: 2-azido-3'-O-naphthoyl-[beta-32P]ADP. Identification of the binding segments by mass spectrometry

A novel photoactivatable radioactive ADP derivative, namely, 2-azido-3'-O-naphthoyl-[beta-(32)P]ADP (2-azido-N-[(32)P]ADP), was synthesized with the aim at mapping the substrate binding site(s) of the yeast mitochondrial ADP/ATP carrier. It was used with mitochondria isolated from genetically modified strains of Saccharomyces cerevisiae, producing the native or the His-tagged Anc2p isoform of the carrier. In darkness, 2-azido-N-[(32)P]ADP was reversibly bound to the carrier in mitochondria, without being transported. Upon photoirradiation, only the ADP/ATP carrier was covalently radiolabeled among all mitochondrial proteins. Specificity of labeling was demonstrated since carboxyatractyloside (CATR), a potent inhibitor of ADP/ATP transport, totally prevented the incorporation of the photoprobe. To localize the radioactive region(s), the purified photolabeled carrier was submitted to CNBr or hydroxylamine cleavage. The resulting fragments were characterized and identified by SDS-PAGE, Western blotting, amino acid sequencing, and MALDI-MS and ESI-MS analyses. Two short photolabeled distinct segments, eight and nine residues long, were identified: S183-R191, located in the central part of the ADP/ATP carrier; and I311-K318, belonging to its C-terminal end. Plausible models of organization of the nucleotide binding site(s) of the carrier involving the two regions specifically labeled by 2-azido-N-[(32)P]ADP are proposed.     

Subunits of the yeast mitochondrial ADP/ATP carrier: cooperation within the dimer

The mitochondrial ADP/ATP carrier, or Ancp, is a member of the mitochondrial carrier family (MCF). It exchanges ADP and ATP between matrix and intermembrane space. It is postulated from numerous experiments that the inactive Ancp bound to one of its inhibitors (CATR or BA) is a dimer, and it is inferred that the active unit is a dimer, too. However, the structure of beef Ancp bound to CATR obtained at high resolution is that of a monomer. To ascertain the dimeric organization of Ancp, we have constructed covalent tandem dimers of which one "subunit" (protomer) is the wild type and the other is inactive for ADP/ATP exchange. We have chosen either the op1 mutant or another member of the MCF, the phosphate carrier (Picp). Activities of the chimeras were first evaluated in vivo. The Ancp/op1 constructs exchange the adenine nucleotides. The Anc/Pic chimeras are considered as bifunctional forms since they exchange ADP and ATP and transport P(i) within the same cells. We have then controlled the fact that the chimeras are stable in vivo and in vitro. Proteinase K digestion showed that both protomers of Ancp/op1 have similar organization in the membrane. Analyses of kinetic properties indicated that protomers of Ancp/op1 chimeras crosstalk during the nucleotide exchange unlike those of Anc/Pic. However, full inhibition of phosphate uptake by CATR, a very specific inhibitor of Ancp, strongly suggests that the native functional unit of Ancp, and thus of Picp, is a dimer.     

The Saccharomyces cerevisiae ADP/ATP carrier-iso 1 cytochrome c fusion protein: one-step purification and functional analysis in vitro

Genetic expression versus plasmidic overexpression of a functional recombinant fusion protein combining the yeast Saccharomyces cerevisiae mitochondrial ADP/ATP carrier (Anc2p) and the iso-1-cytochrome c (Cyc1p) has been investigated, with the main aim of increasing the polar surface of the carrier to improve its crystallization properties. The gene encoding the his6-tagged fusion protein was expressed in yeast under the control of the regulatory sequences of ScANC2 or under the control of the strong yeast PMA1 promoter. In both cases, the chimeric carrier, Anc2-Cyc1(His6)p, was able to restore growth on a non-fermentable carbon source of a yeast strain devoid of functional ADP/ATP carrier, demonstrating its transport activity. Nevertheless, when the expression vector was used, the level of expression of Anc2-Cyc1(His6)p was no greater than that of the chimeric carrier obtained in yeast mitochondria after homologous recombination. Optimal conditions to extract and to purify Anc2-Cyc1(His6)p were determined. A series of detergents was screened for their ability to extract and to preserve in vitro the chimeric carrier. A rapid, single step purification of Anc2-Cyc1(His6)p was developed, using n-dodecyl-beta-d-maltoside (DoDM) as the best detergent to solubilize the chimeric protein. Carboxyatractyloside- (CATR-) and nucleotide-binding sites were preserved in the purified protein. Moreover, the Cyc1p moiety of Anc2-Cyc1(His6)p-CATR complex solubilized in DoDM was still able to interact in vitro with the cytochrome c oxidase (COX), with the same affinity as yeast Cyc1p. Improved production and purification of Anc2-Cyc1(His6)p-CATR complex opens up new possibilities for the use of this protein in crystallographic approaches to the yeast ADP/ATP carrier. Furthermore, Anc2-Cyc1(His6)p may be an useful molecular tool to investigate in vivo interactions between components of the respiratory chain complexes such as COX and the proteins implicated in ATP biogenesis, such as the ATP/ADP carrier.     

Conformation-dependent swinging of the matrix loop m2 of the mitochondrial Saccharomyces cerevisiae ADP/ATP carrier

Structure-function relationships of the membrane-embedded Saccharomyces cerevisiae mitochondrial ADP/ATP carrier were investigated through two independent approaches, namely, limited proteolysis and cysteine labeling. Experiments were carried out in the presence of either carboxyatractyloside (CATR) or bongkrekic acid (BA), two specific inhibitors of the ADP/ATP transport that bind to two distinct conformers involved in the translocation process. The proteolysis approach allowed us to demonstrate (i) that N- and C-terminal extremities of ADP/ATP carrier are facing the intermembrane space and (ii) that the central region of the carrier corresponding to the matrix loop m2 is accessible to externally added trypsin in a conformation-sensitive manner, being cleaved at the Lys163-Gly164 and Lys178-Thr179 bonds in the carrier-CATR and the carrier-BA complexes, respectively. The cysteine labeling approach was carried out on the S161C mutant of the ADP/ATP carrier. This variant of the carrier is fully active, displaying nucleotide transport kinetic parameters and inhibitor binding properties similar to that of wild-type carrier. Alkylation experiments, carried out on mitochondria with the nonpermeable reagents eosin-5-maleimide and iodoacetamidyl-3,6-dioxaoctanediamine-biotin, showed that Cys 161 is accessible from the outside in the carrier-CATR complex, whereas it is masked in the carrier-BA complex. Taken together, our results indicate that the matrix loop m2 connecting the transmembrane helices H3 to H4 intrudes to some extent into the inner mitochondrial membrane. Its participation in the translocation of ADP/ATP is strongly suggested, based on the finding that its accessibility to reagents added outside mitochondria is modified according to the conformational state of the carrier.     

Substrate-induced modifications of the intrinsic fluorescence of the isolated adenine nucleotide carrier protein: demonstration of distinct conformational states

The effects of ATP or ADP and the specific inhibitors carboxyatractyloside (CATR) and bongkrekic acid (BA) on the conformation of the isolated adenine nucleotide (AdN) carrier protein were studied by fluorescence spectroscopy. The addition of ATP to the AdN carrier resulted in a rapid fluorescence increase of the tryptophanyl residue(s) at 355 nm, which leveled up in less than 1 s at 22 degrees C. Among the natural nucleotides, only ATP and ADP were effective. At 10 degrees C or below, the kinetics of the fluorescence increase induced by ATP were biphasic, consisting of a rapid phase of less than 1 s, followed by a slower phase that lasted for a few seconds and had virtually the same amplitude as the rapid one. Both phases were abolished when CATR was added prior to ATP or fully reversed when CATR was added after the fluorescence response to ATP had been elicited. The number of CATR binding sites present on the carrier protein was determined by CATR specific inhibition of the ATP-induced increase in intrinsic fluorescence. The calculated number of CATR sites was equal to that found by another method based on the use of the same preparation of AdN carrier loaded with fluorescent nucleotide naphthoyl-ATP and on the CATR-induced release of the bound naphthoyl-ATP, demonstrating the reliability of the intrinsic fluorescence assay. Addition of BA prior to or together with ATP nearly doubled the amplitude of the ATP-induced fluorescence signal. At 10 degrees C or below, the fluorescence response to ATP in the presence of BA could also be decomposed into rapid and slow phases.(ABSTRACT TRUNCATED AT 250 WORDS)     

Topography of the membrane-bound ADP/ATP carrier assessed by enzymatic proteolysis.

The folding of the peptide chain of the beef heart ADP/ATP carrier in the inner mitochondrial membrane was investigated by enzymatic and immunochemical approaches, using specific proteases and polyclonal antibodies directed against the whole protein and specific regions of the carrier. The accessibility of the membrane-bound ADP/ATP carrier to proteases was followed by immunodetection of the cleavage products, using mitochondria devoid of outer membrane (mitoplasts) and inside-out submitochondrial particles (SMP) in the presence of either carboxyatractyloside (CATR) or bongkrekic acid (BA), two specific inhibitors which are able to bind to the outer face or the inner face of the carrier, respectively. Four types of particles were investigated, namely, mitoplasts-CATR, mitoplasts-BA, SMP-CATR, and SMP-BA. Only the ADP/ATP carrier in SMP-BA was cleaved by two specific proteases, namely, trypsin and lysine C endoprotease, at low doses for short periods of time. Two initial cleavage sites were found between Lys-42 and Glu-43, and between Lys-244 and Gly-245. After a longer period of incubation, an additional cleavage site between Lys-146 and Gly-147 could be demonstrated. Despite cleavage of the membrane-embedded carrier, the binding capacity and affinity of SMP for BA were not altered. A number of other proteases tested, including V8 protease, proline C endoprotease, thrombin, alpha-chymotrypsin, and thermolysin had virtually no effect. These results are explained by a dynamic model of the arrangement of the peptide chain of the ADP/ATP carrier.(ABSTRACT TRUNCATED AT 250 WORDS)     

Functional Characterization of TbMCP5, a Conserved and Essential ADP/ATP Carrier Present in the Mitochondrion of the Human Pathogen Trypanosoma brucei

Trypanosoma brucei is a kinetoplastid parasite of medical and veterinary importance. Its digenetic life cycle alternates between the bloodstream form in the mammalian host and the procyclic form (PCF) in the bloodsucking insect vector, the tsetse fly. PCF trypanosomes rely in the glucose-depleted environment of the insect vector primarily on the mitochondrial oxidative phosphorylation of proline for their cellular ATP provision. We previously identified two T. brucei mitochondrial carrier family proteins, TbMCP5 and TbMCP15, with significant sequence similarity to functionally characterized ADP/ATP carriers from other eukaryotes. Comprehensive sequence analysis confirmed that TbMCP5 contains canonical ADP/ATP carrier sequence features, whereas they are not conserved in TbMCP15. Heterologous expression in the ANC-deficient yeast strain JL1Δ2Δ3u⁻ revealed that only TbMCP5 was able to restore its growth on the non-fermentable carbon source lactate. Transport studies in yeast mitochondria showed that TbMCP5 has biochemical properties and ADP/ATP exchange kinetics similar to those of Anc2p, the prototypical ADP/ATP carrier of S. cerevisiae. Immunofluorescence microscopy and Western blot analysis confirmed that TbMCP5 is exclusively mitochondrial and is differentially expressed with 4.5-fold more TbMCP5 in the procyclic form of the parasite. Silencing of TbMCP5 expression in PCF T. brucei revealed that this ADP/ATP carrier is essential for parasite growth, particularly when depending on proline for energy generation. Moreover, ADP/ATP exchange in isolated T. brucei mitochondria was eliminated upon TbMCP5 depletion. These results confirmed that TbMCP5 functions as the main ADP/ATP carrier in the trypanosome mitochondrion. The important role of TbMCP5 in the T. brucei energy metabolism is further discussed.     

Twisting of the second transmembrane alpha-helix of the mitochondrial ADP/ATP carrier during the transition between two carrier conformational states

To investigate the structural and functional features of the second alpha-helical transmembrane segment (TM2) of the mitochondrial ADP/ATP carrier (AAC), we adopted cysteine scanning mutagenesis analysis. Single-cysteine mutations of yeast AAC were systematically introduced at residues 98-106 in TM2, and the mutants were treated with the fluorescent SH reagent eosin-5-maleimide (EMA). EMA modified different amino acid residues of alpha-helical TM2 between the two distinct carrier conformations, called the m-state and the c-state, in which the substrate recognition site faces the matrix and cytosol, respectively. When amino acids in the helix were projected on a wheel plot, these EMA-modified amino acids were observed at distinct sides of the wheel. Since the SH reagent specifically modified cysteine in the water-accessible environment, these results indicate that distinct helical surfaces of TM2 faced the water-accessible space between the two conformations, possibly as a result of twisting of this helix. In the recently reported crystal structure of bovine AAC, several amino acids faced cocrystallized carboxyatractyloside (CATR), a specific inhibitor of the carrier. These residues correspond to those modified with EMA in the yeast carrier in the c-state. Since the binding site of CATR is known to overlap that of the transport substrate, the water-accessible space was thought to be a substrate transport pathway, and hence, the observed twisting of TM2 between the m-state and the c-state may be involved in the process of substrate translocation. On the basis of the results, the roles of TM2 in the transport function of AAC were discussed.     

Structure-function relationships of the C-terminal end of the Saccharomyces cerevisiae ADP/ATP carrier isoform 2

The adenine nucleotide carrier (Ancp) catalyzes the transport of ADP and ATP across the mitochondrial inner membrane, thus playing an essential role in the cellular energy metabolism. Two regions of Anc2p from Saccharomyces cerevisiae are specifically photolabeled using a photoactivable ADP derivative; they are the central matrix loop, m2, and the C-terminal end. To get more insights into the structure-function relationships of the C-terminal region during nucleotide transport, we have developed two independent approaches. In the first we have deleted the last eight amino acids of Anc2p (Anc2pDeltaCter) and demonstrated that the C-terminal end of Anc2p plays an essential role in yeast growth on a non-fermentable carbon source. This resulted from impaired nucleotide binding properties of the Anc2pDeltaCter variant in line with conversion of ADP binding sites from high to low affinity. In the second we probed the ligand-induced conformational changes of Anc2p C-terminal end (i) by assessing its accessibility to anti-C-terminal antibodies and (ii) by measuring intrinsic fluorescence changes of an Anc2p mutant containing only one tryptophan residue located at its C-terminal end (Anc2p3Y-u). We show that the C-terminal region is no further accessible to antibodies when Anc2p binds non-transportable analogues of ADP. Besides, Trp-316 fluorescence is highly increased upon ligand binding, suggesting large conformational changes. Taken together, our results highlight the involvement of the Anc2p C-terminal region in nucleotide recognition, binding, and transport.     

Exploration of the nucleotide binding sites of the isolated ADP/ATP carrier protein from beef heart mitochondria. 1. Probing of the nucleotide sites by Naphthoyl-ATP, a fluorescent nontransportable analogue of ATP

The ADP/ATP carrier protein was extracted and purified from beef heart mitochondria, and its binding parameters with respect to 3'-O-naphthoyladenosine 5'-triphosphate (N-ATP), a fluorescent nontransportable analogue of ATP, were studied. The binding of N-ATP to the isolated carrier protein was accompanied by a decrease in fluorescence. Conversely, the release of bound N-ATP upon addition of carboxyatractyloside (CATR) or ATP resulted in a fluorescence increase. The bound N-ATP that was released upon addition of an excess of CATR or ATP was referred to as specifically bound N-ATP, i.e., N-ATP bound to the nucleotide sites of the carrier protein. Two classes of binding sites for N-ATP could be identified; the number of high-affinity sites (Kd less than 10 nM) was equal to the number of low-affinity sites (Kd = 0.45 microM). CATR behaved apparently as a noncompetitive inhibitor of the binding of N-ATP. The amount of N-ATP released increased linearly with the amount of CATR added, indicating an extremely high affinity of the carrier protein for CATR. The number of CATR binding sites was equal to half the total number of N-ATP binding sites (high- and low-affinity sites); at saturating concentrations of N-ATP, the binding of 1 mol of CATR resulted in the release of 2 mol of bound N-ATP, one from the high-affinity site and the other from the low-affinity site, showing unambiguously that each CATR site is interacting with a pair of probably interdependent N-ATP sites. A clear competition between N-ATP and ATP for binding to the carrier protein was demonstrated. The Kd values of the high- and low-affinity sites for ATP were less than 50 nM and 5 microM, respectively. In the presence of high concentrations of ATP, the two classes of N-ATP binding sites became indistinguishable, suggesting interconversion. It is proposed that the asymmetry in affinity for N-ATP binding is induced by the binding step itself, the carrier protein exhibiting a negative cooperativity for N-ATP binding.     

A covalent tandem dimer of the mitochondrial ADP/ATP carrier is functional in vivo

The adenine nucleotide carrier, or Ancp, is an integral protein of the inner mitochondrial membrane. It is established that the inactive Ancp bound to one of its inhibitors (CATR or BA) is a dimer, but different contradictory models were proposed over the past years to describe the organization of the active Ancp. In order to decide in favor of a single model, it is necessary to establish the orientations of the N- and C-termini and thus the parity of the Ancp transmembrane segments (TMS). According to this, we have constructed a gene encoding a covalent tandem dimer of the Saccharomyces cerevisiae Anc2p and we demonstrate that it is stable and active in vivo as well as in vitro. The properties of the isolated dimer are strongly similar to those of the native Anc2p, as seen from nucleotide exchange and inhibitor binding experiments. We can therefore conclude that the native Anc2p has an even number of TMS and that the N- and C-terminal regions are exposed to the same cellular compartment. Furthermore, our results support the idea of a minimal dimeric functional organization of the Ancp in the mitochondrial membrane and we can suggest that TMS 1 of one monomer and TMS 6 of the other monomer in the native dimer are very close to each other.     

Conformational Dynamics of the Bovine Mitochondrial ADP/ATP Carrier Isoform 1 Revealed by Hydrogen/Deuterium Exchange Coupled to Mass Spectrometry

The mitochondrial adenine nucleotide carrier (Ancp) catalyzes the transport of ADP and ATP across the mitochondrial inner membrane, thus playing an essential role in cellular energy metabolism. During the transport mechanism the carrier switches between two different conformations that can be blocked by two toxins: carboxyatractyloside (CATR) and bongkrekic acid. Therefore, our understanding of the nucleotide transport mechanism can be improved by analyzing structural differences of the individual inhibited states. We have solved the three-dimensional structure of bovine carrier isoform 1 (bAnc1p) in a complex with CATR, but the structure of the carrier-bongkrekic acid complex, and thus, the detailed mechanism of transport remains unknown. Improvements in sample processing in the hydrogen/deuterium exchange technique coupled to mass spectrometry (HDX-MS) have allowed us to gain novel insights into the conformational changes undergone by bAnc1p. This paper describes the first study of bAnc1p using HDX-MS. Results obtained with the CATR-bAnc1p complex were fully in agreement with published results, thus, validating our approach. On the other hand, the HDX kinetics of the two complexes displays marked differences. The bongkrekic acid-bAnc1p complex exhibits greater accessibility to the solvent on the matrix side, whereas the CATR-bAnc1p complex is more accessible on the intermembrane side. These results are discussed with respect to the structural and biochemical data available on Ancp.     

Unambiguous structure of atractyloside and carboxyatractyloside

Atractyloside (ATR) was characterized in 1868 and until now structural studies on diterpenic moiety had been done through the characterization of ATR derivatives; while the glycosidic moiety seemed to be a β-D-glucopyranose a recent crystal structure of the mitochondrial ATP/ADP carrier in complex with CATR showed an α-D-glucopyranose. We decided to re-examine the ATR and CATR structures by crystallographic study of ATR.