Projection structure of the atractyloside-inhibited mitochondrial ADP/ATP carrier of Saccharomyces cerevisiae

ADP/ATP carriers in the inner mitochondrial membrane catalyze the exchange of cytosolic ADP for ATP synthesized in the mitochondrial matrix by ATP synthase and thereby replenish the eukaryotic cell with metabolic energy. The yeast ADP/ATP carrier (AAC3) was overexpressed, inhibited by atractyloside, purified, and reconstituted into two-dimensional crystals. Images of frozen hydrated crystals were recorded by electron microscopy, and a projection structure was calculated to 8-A resolution. The AAC3 molecule has pseudo 3-fold symmetry in agreement with the 3-fold sequence repeats that are typical of members of the mitochondrial carrier family. The density distribution is consistent with a bundle of six transmembrane alpha-helices with two or three short alpha-helical extensions closing the central pore on the matrix side. The AAC3 molecules in the crystal are arranged in symmetrical homo-dimers, but the translocation pore for adenine nucleotides lies in the center of the molecule and not along the dyad axis of the dimer.     

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.     

Functional expression of the tandem-repeated homodimer of the mitochondrial ADP/ATP carrier in Saccharomyces cerevisiae.

The mitochondrial ADP/ATP carrier (AAC) is believed to function as a dimer. To characterize the oligomeric state of the yeast type 2 AAC (yAAC2), we tried to express its tandem-repeated homodimer, in which the C-terminus of the first repeat was fused to the N-terminus of the second repeat, in yeast mitochondria. The tandem dimer was expressed in the mitochondrial membrane at the same level as that of yAAC2, being inserted into the mitochondrial membrane as in yAAC2, and it showed very similar transport activity to that of yAAC2. It was suggested that the two carrier molecules in a dimeric form are located in the membrane facing each other in the same orientation.     

S. cerevisiae genes IRA1 and IRA2 encode proteins that may be functionally equivalent to mammalian ras GTPase activating protein

The IRA1 and IRA2 genes of S. cerevisiae encode closely related proteins that also share homology with mammalian GAP (ras GTPase activating protein). The RAS1 and RAS2 proteins overexpressed in ira mutants accumulated in the GTP-bound form, whereas in the wild-type strain the proteins were found mostly in the GDP-bound form, indicating that IRA1 and IRA2 negatively regulate the level of RAS-GTP. In contrast, the RAS2Val-19 or RAS2Thr-66 mutant protein was bound to GTP in high amounts irrespective of the IRA genotype. Overexpression of bovine GAP suppressed the phenotypes of ira mutants by reducing the level of RAS-GTP, suggesting that IRA proteins may be functionally analogous to mammalian GAP.     

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.     

Heterologous complementation of the Klaac null mutation of Kluyveromyces lactis by the Saccharomyces cerevisiae AAC3 gene encoding the ADP/ATP carrier

The KlAAC gene, encoding the ADP/ATP carrier, has been assumed to be a single gene in Kluyveromyces lactis, an aerobic, petite-negative yeast species. The Klaac null mutation, which causes a respiratory-deficient phenotype, was fully complemented by AAC2, the Saccharomyces cerevisiae major gene for the ADP/ATP carrier and also by AAC1, a gene that is poorly expressed in S. cerevisiae. In this study, we demonstrate that the Klaac null mutation is partially complemented by the ScAAC3 gene, encoding the hypoxic ADP/ATP carrier isoform, whose expression in S. cerevisiae is prevented by oxygen. Once introduced into K. lactis, the AAC3 gene was expressed both under aerobic and under partial anaerobic conditions but did not support the growth of K. lactis under strict anaerobic conditions.     

The substrate specificity of the human ADP/ATP carrier AAC1

Abstract

The mitochondrial ADP/ATP carrier imports ADP from the cytosol into the mitochondrial matrix for its conversion to ATP by ATP synthase and exports ATP out of the mitochondrion to replenish the eukaryotic cell with chemical energy. Here the substrate specificity of the human mitochondrial ADP/ATP carrier AAC1 was determined by two different approaches. In the first the protein was functionally expressed in Escherichia coli membranes as a fusion protein with maltose binding protein and the effect of excess of unlabeled compounds on the uptake of [³²P]-ATP was measured. In the second approach the protein was expressed in the cytoplasmic membrane of Lactococcus lactis. The uptake of [¹⁴C]-ADP in whole cells was measured in the presence of excess of unlabeled compounds and in fused membrane vesicles loaded with unlabeled compounds to demonstrate their transport. A large number of nucleotides were tested, but only ADP and ATP are suitable substrates for human AAC1, demonstrating a very narrow specificity. Next we tried to understand the molecular basis of this specificity by carrying out molecular-dynamics simulations with selected nucleotides, which were placed at the entrance of the central cavity. The binding of the phosphate groups of guanine and adenine nucleotides is similar, yet there is a low probability for the base moiety to be bound, likely to be rooted in the greater polarity of guanine compared to adenine. AMP is unlikely to engage fully with all contact points of the substrate binding site, suggesting that it cannot trigger translocation.     

Two functional alpha-tubulin genes of the yeast Saccharomyces cerevisiae encode divergent proteins.

Two alpha-tubulin genes from the budding yeast Saccharomyces cerevisiae were identified and cloned by cross-species DNA homology. Nucleotide sequencing studies revealed that the two genes, named TUB1 and TUB3, encoded gene products of 447 and 445 amino acids, respectively, that are highly homologous to alpha-tubulins from other species. Comparison of the sequences of the two genes revealed a 19% divergence between the nucleotide sequences and a 10% divergence between the amino acid sequences. Each gene had a single intervening sequence, located at an identical position in codon 9. Cell fractionation studies showed that both gene products were present in yeast microtubules. These two genes, along with the TUB2 beta-tubulin gene, probably encode the entire complement of tubulin in budding yeast cells.     

The molecular basis for relative physiological functionality of the ADP/ATP carrier isoforms in Saccharomyces cerevisiae

AAC2 is one of three paralogs encoding mitochondrial ADP/ATP carriers in the yeast Saccharomyces cerevisiae, and because it is required for respiratory growth it has been the most extensively studied. To comparatively examine the relative functionality of Aac1, Aac2, and Aac3 in vivo, the gene encoding each isoform was expressed from the native AAC2 locus in aac1Delta aac3Delta yeast. Compared to Aac2, Aac1 exhibited reduced capacity to support growth of yeast lacking mitochondrial DNA or of yeast lacking the ATP/Mg-P(i) carrier, both conditions requiring ATP import into the mitochondrial matrix through the ADP/ATP carrier. Sixteen AAC1/AAC2 chimeric genes were constructed and analyzed to determine the key differences between residues or sections of Aac1 and Aac2. On the basis of the growth rate differences of yeast expressing different chimeras, the C1 and M2 loops of the ADP/ATP carriers contain divergent residues that are responsible for the difference(s) between Aac1 and Aac2. One chimeric gene construct supported growth on nonfermentable carbon sources but failed to support growth of yeast lacking mitochondrial DNA. We identified nine independent intragenic mutations in this chimeric gene that suppressed the growth phenotype of yeast lacking mitochondrial DNA, identifying regions of the carrier important for nucleotide exchange activities.     

Yeast ADP/ATP carrier (AAC) proteins exhibit similar enzymatic properties but their deletion produces different phenotypes.

Saccharomyces cerevisiae strains expressing a single type of ADP/ATP carrier (AAC) protein were prepared from a mutant in which all AAC genes were disrupted, by transformation with plasmids containing a chosen AAC gene. As demonstrated by measurements of [14C]ADP specific binding and transport, all three translocator proteins, AAC1, AAC2 and AAC3 when present in the mitochondrial membrane, exhibited similar translocation properties. The disruption of some AAC genes, however, resulted in phenotypes indicating that the function of these proteins in whole cells can be quite different. Specifically, we found that the disruption of AAC1 gene, but not AAC2 and AAC3, resulted in a change in colony phenotype.     

Mitochondrial import of the ADP/ATP carrier protein in Saccharomyces cerevisiae. Sequences required for receptor binding and membrane translocation

The ADP/ATP carrier of yeast (309 amino acids) is an abundant transmembrane protein of the mitochondrial inner membrane whose import involves well-defined steps (Pfanner, N., and Neupert, W. (1987) J. Biol. Chem. 262, 7528-7536). Analysis of the in vitro import of gene fusion products containing ADP/ATP carrier (AAC) sequences at the amino terminus and mouse dihydrofolate reductase (DHFR) at the carboxyl terminus indicates that the first 72 amino acids of the soluble carrier protein, a hydrophilic region of the protein, are not by themselves sufficient for initial binding to the AAC receptor on the mitochondrial surface. However, an AAC-DHFR gene fusion containing the first 111 residues of the ADP/ATP carrier protein exhibited binding to mitochondria at low temperature (2 degrees C) and internalization at 25 degrees C to a mitochondrial space protected from proteinase K in the same manner as the wild-type ADP/ATP carrier protein. The AAC-DHFR protein, in contrast to the wild-type AAC protein imported into mitochondria under optimal conditions, remained extractable at alkaline pH and appeared to be blocked at an intermediate step in the AAC import pathway. Based on its extraction properties, this AAC-DHFR hybrid is proposed to be associated with a proteinaceous component of the import apparatus within mitochondria. These data indicate that the import determinants for the AAC protein are not located at its extreme amino terminus and that protein determinants distal to the first 111 residues of the carrier may be necessary to move the protein beyond the alkali-extractable step in the biogenesis of a functional AAC protein.     

The isolation and reconstitution of the ADP/ATP carrier from wild-type Saccharomyces cerevisiae. Identification of primarily one type (AAC-2)

Methods for isolation of the ADP/ATP carrier (AAC) from yeast (Saccharomyces cerevisiae) are described which allow separation of the carrier from the initially copurified porin which poses a specific problem in yeast. The procedure varies according to whether one wishes to obtain a stable CAT-AAC complex, the free and active AAC for reconstitution, or the SDS-denatured pure AAC peptide. CNBr cleavage of AAC enabled us to differentiate clearly between isogenes AAC-1 and AAC-2 recently found in yeast, due to the exclusive occurrence of a methionine (M-115) residue at the end of the first domain in AAC-2. Thus the AAC isolated from wild-type yeast is primarily or exclusively AAC-2. The isolated AAC is active in ADP/ATP exchange in reconstituted liposomes with a Vmax of 1100 mumol/min per g protein and Km = 15 microM for ADP, and a Vmax of 900 mumol/min per g protein and Km = 9 microM for ATP.     

On the mechanism and functional significance of the ADP/ATP carrier (AAC) dimerization

According to previous studies, ADP/ATP carrier (AAC) can possibly exist as a monomer or in a dimer state in the inner mitochondrial membrane; however, the question on its functional oligomeric state is still open. The aim of the present work is to establish the external factors that could control the functional oligomeric state of AAC (i.e., monomer or dimer). The study is based on the results of our previous work, which revealed that the volume regulation system of mitochondria (MVRS) affects the oxidative phosphorylation (OXPHOS) system: MVRS could transfer OXPHOS system functioning in a state of supercomplex. Consequently, one may expect that the volume regulation system could also control the functional state of AAC during phosphorylation. Here, on rat liver mitochondria we show that, depending on the incubation medium tonicity, AAC functions in two different ways: either as a monomer (in hypotonic and isotonic media) or as a dimer (in a hypertonic medium). Thus, the transition between the monomeric and dimeric forms of AAC is regulated by MVRS, as well as by functioning of OXPHOS. We conclude that the structural reorganization of AAC is associated with the entire OXPHOS reorganization into a supercomplex. It was also found that dimerization of AAC can occur not only due to the action of MVRS (in hypotonic media) but also under hypoxic conditions.     

Expression of the ADP/ATP carrier encoding genes in aerobic yeasts; phenotype of an ADP/ATP carrier deletion mutant of Schizosaccharomyces pombe

The expression of a key mitochondrial membrane component, the ADP/ATP carrier, was investigated in two aerobic yeast species, Kluyveromyces lactis and Schizosaccharomyces pombe. Although the two species differ very much in their respiratory capacity, the expression of the carrier in both yeast species was decreased under partially anaerobic conditions and was induced by nonfermentable carbon sources. The single ADP/ATP carrier encoding gene was deleted in S. pombe. The null mutant exhibits impaired growth properties, especially when cultivated at reduced oxygen tension, and is unable to grow on a nonfermentable carbon source. Our results suggest that the inability of K. lactis and S. pombe to grow under anaerobic conditions can be related in part to the absence of a functional ADP/ATP carrier due to repression of the corresponding gene expression.     

Cysteine labeling studies detect conformational changes in region 106-132 of the mitochondrial ADP/ATP carrier of Saccharomyces cerevisiae

To know the structural and functional features of the cytosolic-facing first loop (LC1) including its surrounding region of the mitochondrial ADP/ATP carrier (AAC), we prepared 27 mutants, in which each amino acid residue between residues 106 and 132 of the yeast type 2 AAC (yAAC2) was replaced by a cysteine residue. For mutant preparation, we used a Cys-less AAC mutant, in which all four intrinsic cysteine residues were substituted with alanine residues, as a template [Hatanaka, T., Kihira, Y., Shinohara, Y., Majima, E., and Terada, H. (2001) Biochem. Biophys. Res. Commun. 286, 936-942]. From the labeling intensities of the membrane-impermeable SH-reagent eosin-5-maleimide (EMA), sequence Lys(108)-Phe(127) was suggested to constitute the LC1. The N-terminal half of this region (Lys(108)-Phe(115)) was suggested to change its location from the cytosol to a region close to the membrane on conversion from the c-state to the m-state in association with disruption or unwinding of its alpha-helical structure, whereas the C-terminal half region (Gly(116)-Phe(127)) was considered to extrude essentially into the cytosol, while keeping its alpha-helical structure. Hence, the conformation of m-state LC1 is greatly different from that of c-state LC1. Possibly the LC1 changes its location between the membranous region and the cytosol during ADP/ATP transport. Lys(108) in the LC1 of the yAAC2 was found to be associated with binding of the transport substrates, and its -NH(3)(+) moiety, to be of importance for the transport function. On the basis of these results, possible roles of the conformational changes of the LC1 in the transport activity are discussed.     

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.     

ADP/ATP translocator is essential only for anaerobic growth of yeast Saccharomyces cerevisiae

All three genes (AAC1, AAC2 and AAC3) encoding the mitochondrial ADP/ATP translocator, were inactivated in a haploid yeast strain by a gene disruption technique. The triple mutant was still able to grow on fermentable carbon sources but only in the presence of oxygen. Under aerobic conditions neither translocator-protein nor carrier-mediated transport was detected in all mutants in which the AAC2 gene was disrupted. It was further shown that a functional AAC genes product is essential only for anaerobic growth of Saccharomyces cerevisiae but not for growth under derepressed conditions. Under anaerobic conditions a non-detectable amount of AAC3 gene product is sufficient to ensure the cell growth and multiplication.