Purification and characterization of the N-terminal nucleotide binding domain of an ABC drug transporter of Candida albicans: uncommon cysteine 193 of Walker A is critical for ATP hydrolysis

The Candida drug resistance protein Cdr1p (approximately 170 kDa) is a member of ATP binding cassette (ABC) superfamily of drug transporters, characterized by the presence of 2 nucleotide binding domains (NBD) and 12 transmembrane segments (TMS). NBDs of these transporters are the hub of ATP hydrolysis activity, and their sequence contains a conserved Walker A motif (GxxGxGKS/T). Mutations of the lysine residue within this motif abrogate the ability of NBDs to hydrolyze ATP. Interestingly, the sequence alignments of Cdr1p NBDs with other bacterial and eukaryotic transporters reveal that its N-terminal NBD contains an unusual Walker A sequence (GRPGAGCST), as the invariant lysine is replaced by a cysteine. In an attempt to understand the significance of this uncommon positioning of cysteine within the Walker A motif, we for the first time have purified and characterized the N-terminal NBD (encompassing first N-terminal 512 amino acids) of Cdr1p as well as its C193A mutant protein. The purified NBD-512 protein could exist as an independent functional general ribonucleoside triphosphatase with strong divalent cation dependence. It exhibited ATPase activity with an apparent K(m) in the 0.8-1.0 mM range and V(max) in the range of 147-160 nmol min(-)(1) (mg of protein)(-)(1). NBD-512-associated ATPase activity was also sensitive to inhibitors such as vanadate, azide, and NEM. The Mut-NBD-512 protein (C193A) showed a severe impairment in its ability to hydrolyze ATP (95%); however, no significant effect on ATP (TNP-ATP) binding was observed. Our results show that C193 is critical for N-terminal NBD-mediated ATP hydrolysis and represents a unique feature distinguishing the ATP-dependent functionality of the ABC transporters of fungi from those found in bacteria and other eukaryotes.     

Functional characterization of N-terminal nucleotide binding domain (NBD-1) of a major ABC drug transporter Cdr1p of Candida albicans: uncommon but conserved Trp326 of Walker B is important for ATP binding

Using purified N-terminal NBD (NBD-512) domain of Cdr1p, a major multidrug extrusion pump of human pathogenic yeast Candida albicans, we show the relevance of the unique positioning of an atypical Trp326 residue. Similar to Cys193 in Walker A, Trp326 in the Walker B motif of Cdr1p is also a conserved feature of other fungal ATP Binding Cassette (ABC) transporters. By employing fluorescence spectroscopy, chemical modification, and site-directed mutagenesis, we demonstrate that of the five Trp residues in the NBD-512 domain, Trp326 alone is important for nucleotide binding and subsequent conformational changes within the domain. Furthermore, mutation of Trp326 to Ala results in an increased K(M) without appreciably affecting V(max) of ATPase activity. Thus, Trp326 in NBD-512 appears to be important for nucleotide binding and not for its hydrolysis. Additionally, the role of Trp326 in ATP binding is independent of the presence of the adjacent well-conserved Asp327 residue which, like Cys193, has a catalytic role in ATP hydrolysis. Considering that Trp326 of Cdr1p is a typical feature of fungal transporters alone, our study suggests that these ABC transporters may reflect mechanistic differences with regard to nucleotide binding and hydrolysis as compared to their counterparts of non-fungal origin.     

Candida drug resistance protein 1, a major multidrug ATP binding cassette transporter of Candida albicans, translocates fluorescent phospholipids in a reconstituted system

Candida albicans drug resistance protein 1 (Cdr1p), an ATP-dependent drug efflux pump, contributes to multidrug resistance in Candida-infected immunocompromised patients. Previous cell-based assays suggested that Cdr1p also acts as a phospholipid translocator. To investigate this, we reconstituted purified Cdr1p into sealed membrane vesicles. Comparison of the ATPase activities of sealed and permeabilized proteoliposomes indicated that Cdr1p was asymmetrically reconstituted such that approximately 70% of the molecules had their ATP binding sites accessible to the extravesicular space. Fluorescent glycerophospholipids were incorporated into the outer leaflet of the proteoliposomes, and their transport into the inner leaflet was tracked with a quenching assay using membrane-impermeant dithionite. We observed ATP-dependent transport of the fluorescent lipids into the inner leaflet of the vesicles. With approximately 6 molecules of Cdr1p per vesicle on average, the half-time to reach the maximal extent of transport was approximately 15 min. Transport was reduced in vesicles reconstituted with Cdr1p variants with impaired ATPase activity and could be competed out to different levels by a molar excess of drugs such as fluconazole and miconazole that are known to be effluxed by Cdr1p. Transport was not affected by ampicillin, a compound that is not effluxed by Cdr1p. Our results suggest a direct link between the ability of Cdr1p to translocate fluorescent phospholipids and efflux drugs. We note that only a few members of the ABC superfamily of Candida have a well-defined role as drug exporters; thus, lipid translocation mediated by Cdr1p could reflect its cellular function.     

Purification and properties of a novel azide-sensitive ATPase of Exiguobacterium aurantiacum

Exiguobacterium aurantiacum BL77/1 possesses at least two distinct membrane-bound ATPases. One of them was solubilized with decanoyl N-methylglucamide, a non-ionic detergent, and purified by successive chromatography on DEAE-Sepharose and hydroxyapatite. The purified ATPase appears to consist of a single polypeptide component with an apparent molecular mass of 54 kDa. Among the triphosphates of various nucleosides tested, ATP was the best substrate. The enzyme exhibited a Km of 0.5 mM for ATP and a Vmax of 109 micromol ATP (mg protein)(-1) min(-1); the optimum pH for activity was near 6.5. The enzyme was sensitive to azide and inactivated by N,N'-dicyclohexylcarbodiimide. Analysis of the inhibition kinetics by N,N'-dicyclohexylcarbodiimide suggested that binding of the drug to a single carboxyl group per ATPase molecule is sufficient for inactivation.     

Conserved Asp327 of walker B motif in the N-terminal nucleotide binding domain (NBD-1) of Cdr1p of Candida albicans has acquired a new role in ATP hydrolysis

The Walker A and B motifs of nucleotide binding domains (NBDs) of Cdr1p though almost identical to all ABC transporters, has unique substitutions. We have shown in the past that Trp326 of Walker B and Cys193 of Walker A motifs of N-terminal NBD of Cdr1p have distinct roles in ATP binding and hydrolysis, respectively. In the present study, we have examined the role of a well conserved Asp327 in the Walker B motif of the N-terminal NBD, which is preceded (Trp326) and followed (Asn328) by atypical amino acid substitutions and compared it with its equivalent well conserved Asp1026 of the C-terminal NBD of Cdr1p. We observed that the removal of the negative charge by D327N, D327A, D1026N, D1026A, and D327N/D1026N substitutions, resulted in Cdr1p mutant variants that were severely impaired in ATPase activity and drug efflux. Importantly, all of the mutant variants showed characteristics similar to those of the wild type with respect to cell surface expression and photoaffinity drug analogue [125I] IAAP and [3H] azidopine labeling. Although the Cdr1p D327N mutant variant showed comparable binding with [alpha-32P] 8-azido ATP, Cdr1p D1026N and Cdr1p D327N/D1026N mutant variants were crippled in nucleotide binding. That the two conserved carboxylate residues Asp327 and Asp1026 are functionally different was further evident from the pH profile of ATPase activity. The Cdr1p D327N mutant variant showed approximately 40% enhancement of its residual ATPase activity at acidic pH, whereas no such pH effect was seen with the Cdr1p D1026N mutant variant. Our experimental data suggest that Asp327 of N-terminal NBD has acquired a new role to act as a catalytic base in ATP hydrolysis, a role normally conserved for Glu present adjacent to the conserved Asp in the Walker B motif of all the non-fungal transporters.     

Disulfiram is a potent modulator of multidrug transporter Cdr1p of Candida albicans

To find novel drugs for effective antifungal therapy in candidiasis, we examined disulfiram, a drug used for the treatment of alcoholism, for its role as a potential modulator of Candida multidrug transporter Cdr1p. We show that disulfiram inhibits the oligomycin-sensitive ATPase activity of Cdr1p and 2.5mM dithiothreitol reverses this inhibition. Disulfiram inhibited the binding of photoaffinity analogs of both ATP ([alpha-(32)P]8-azidoATP; IC(50)=0.76 microM) and drug-substrates ([(3)H]azidopine and [(125)I]iodoarylazidoprazosin; IC(50) approximately 12 microM) to Cdr1p in a concentration-dependent manner, suggesting that it can interact with both ATP and substrate-binding site(s) of Cdr1p. Furthermore, a non-toxic concentration of disulfiram (1 microM) increased the sensitivity of Cdr1p expressing Saccharomyces cerevisiae cells to antifungal agents (fluconazole, miconazole, nystatin, and cycloheximide). Collectively these results demonstrate that disulfiram reverses Cdr1p-mediated drug resistance by interaction with both ATP and substrate-binding sites of the transporter and may be useful for antifungal therapy.     

Alanine scanning of all cysteines and construction of a functional cysteine-less Cdr1p, a multidrug ABC transporter of Candida albicans

Herein, we discuss the role of the native cysteines present in a major multidrug ABC transporter of Candida albicans, Cdr1p, and describe the construction of this transporter's functional cysteine-less (cysless) protein version for cross-linking studies. In the experiments in which all 23 cysteines were replaced individually, we observed that most of the cysteine replacements were tolerated by the protein, but the replacement of C1056, C1091, C1106, C1294 or C1336 resulted in an enhanced drug susceptibility together with an abrogated drug efflux. Notably, the ATPase activity was uncoupled, which largely remained unaffected in these variants. The substitution of the critical cysteines with serines restored the normal expression and functionality of Cdr1p because serine can effectively mimic the hydrogen bonding properties of cysteine. Finally, we constructed a functional cysless His-tagged Cdr1p in which all the cysteines of the native protein were replaced with alanines and the critical cysteines were replaced with serines. Notably, cysless GFP-tagged variant of Cdr1p was non-functional. The cysless His-tagged variant of Cdr1p is the first example of a cysless ABC transporter in yeast, and it will lead to a greater understanding of the architecture of this important protein and provide insight into the nature of drug binding and interdomain communication.     

Phosphorylation of candida glabrata ATP-binding cassette transporter Cdr1p regulates drug efflux activity and ATPase stability

Fungal ATP-binding cassette transporter regulation was investigated using Candida glabrata Cdr1p and Pdh1p expressed in Saccharomyces cerevisiae. Rephosphorylation of Pdh1p and Cdr1p was protein kinase A inhibitor-sensitive but responded differentially to Tpk isoforms, stressors, and glucose concentration. Cdr1p Ser(307), which borders the nucleotide binding domain 1 ABC signature motif, and Ser(484), near the membrane, were dephosphorylated on glucose depletion and independently rephosphorylated during glucose exposure or under stress. The S484A enzyme retained half the wild type ATPase activity without affecting azole resistance, but the S307A enzyme was unstable to plasma membrane isolation. Studies of pump function suggested conformational interaction between Ser(484) and Ser(307). An S307A/S484A double mutant, which failed to efflux the Cdr1p substrate rhodamine 6G, had a fluconazole susceptibility 4-fold greater than the Cdr1p expressing strain, twice that of the S307A mutant, but 64-fold less than the control null strain. Stable intragenic suppressors indicative of homodimer nucleotide binding domain 1-nucleotide binding domain 1 interactions partially restored rhodamine 6G pumping and increased fluconazole and rhodamine 6G resistance in the S307A/S484A mutant. Nucleotide binding domain 1 of Cdr1p is a sensor of important physiological stimuli.     

Expression and characterization of the N- and C-terminal ATP-binding domains of MRP1

The His(6)-tagged N- and C-terminal nucleotide binding (ATP Binding Cassette, ABC) domains of the human multidrug resistance associated protein, MRP1, were expressed in bacteria in fusion to the bacterial maltose binding protein and a two-step affinity purification was utilized. Binding of a fluorescent ATP-analogue occurred with micromolar dissociation constants, MgATP was able to inhibit the ATP-analogue binding with 70 and 200 micromolar apparent inhibition constants, while AMP was nearly ineffective. Both MRP1 nucleotide binding domains showed ATPase activities (V(max) values between 5-10 nmoles/mg protein/min), which is fifty to hundred times lower than that of parent transporter. The K(M) value of the ATP hydrolysis by the nucleotide binding domains were 1.5 mM and 1.8 mM, which is similar to the K(M) value of the native or the purified and reconstituted transporter, N-ethylmaleinimide and A1F(4) inhibited the ATPase activity of both nucleotide binding domains.     

Nucleotide binding domain 1 of the human retinal ABC transporter functions as a general ribonucleotidase.

Members of the ATP binding cassette (ABC) superfamily are transmembrane proteins that are found in a variety of tissues which transport substances across cell membranes in an energy-dependent manner. The retina-specific ABC protein (ABCR) has been linked through genetic studies to a number of inherited visual disorders, including Stargardt macular degeneration and age-related macular degeneration (ARMD). Like other ABC transporters, ABCR is characterized by two nucleotide binding domains and two transmembrane domains. We have cloned and expressed the 522-amino acid (aa) N-terminal cytoplasmic region (aa 854-1375) of ABCR containing nucleotide binding domain 1 (NBD1) with a purification tag at its amino terminus. The expressed recombinant protein was found to be soluble and was purified using single-step affinity chromatography. The purified protein migrated as a 66 kDa protein on SDS-PAGE. Analysis of the ATP binding and hydrolysis properties of the NBD1 polypeptide demonstrated significant differences between NBD1 and NBD2 [Biswas, E. E., and Biswas, S. B. (2000) Biochemistry 39, 15879-15886]. NBD1 was active as an ATPase, and nucleotide inhibition studies suggested that nucleotide binding was not specific for ATP and all four ribonucleotides can compete for binding. Further analysis demonstrated that NBD1 is a general nucleotidase capable of hydrolysis of ATP, CTP, GTP, and UTP. In contrast, NBD2 is specific for adenosine nucleotides (ATP and dATP). NBD1 bound ATP with a higher affinity than NBD2 (K(mNBD1) = 200 microm vs K(mNBD2) = 631 microm) but was less efficient as an ATPase (V(maxNBD1) = 28.9 nmol min(-)(1) mg(-)(1) vs V(maxNBD2) = 144 nmol min(-)(1) mg(-)(1)). The binding efficiencies for CTP and GTP were comparable to that observed for ATP (K(mCTP) = 155 microm vs K(mGTP) = 183 microm), while that observed for UTP was decreased 2-fold (K(mUTP) = 436 microm). Thus, the nucleotide binding preference of NBD1 is as follows: CTP > GTP > ATP > UTP. These studies demonstrate that NBD1 of ABCR is a general nucleotidase, whereas NBD2 is a specific ATPase.     

Insight into Pleiotropic Drug Resistance ATP-binding Cassette Pump Drug Transport through Mutagenesis of Cdr1p Transmembrane Domains

The fungal ATP-binding cassette (ABC) transporter Cdr1 protein (Cdr1p), responsible for clinically significant drug resistance, is composed of two transmembrane domains (TMDs) and two nucleotide binding domains (NBDs). We have probed the nature of the drug binding pocket by performing systematic mutagenesis of the primary sequences of the 12 transmembrane segments (TMSs) found in the TMDs. All mutated proteins were expressed equally well and localized properly at the plasma membrane in the heterologous host Saccharomyces cerevisiae, but some variants differed significantly in efflux activity, substrate specificity, and coupled ATPase activity. Replacement of the majority of the amino acid residues with alanine or glycine yielded neutral mutations, but about 42% of the variants lost resistance to drug efflux substrates completely or selectively. A predicted three-dimensional homology model shows that all the TMSs, apart from TMS4 and TMS10, interact directly with the drug-binding cavity in both the open and closed Cdr1p conformations. However, TMS4 and TMS10 mutations can also induce total or selective drug susceptibility. Functional data and homology modeling assisted identification of critical amino acids within a drug-binding cavity that, upon mutation, abolished resistance to all drugs tested singly or in combinations. The open and closed Cdr1p models enabled the identification of amino acid residues that bordered a drug-binding cavity dominated by hydrophobic residues. The disposition of TMD residues with differential effects on drug binding and transport are consistent with a large polyspecific drug binding pocket in this yeast multidrug transporter.     

Functional characterization and ATP-induced dimerization of the isolated ABC-domain of the haemolysin B transporter

Nucleotide-binding domains (NBD) are highly conserved constituents of ATP-binding cassette (ABC) transporters. Members of this family couple ATP hydrolysis to the transfer of various molecules across cell membranes. The NBD of the HlyB transporter, HlyB-NBD, was characterized with respect to its uncoupled ATPase activity, oligomeric state, and stability in solution. Experimental data showed that both the nature and pH of an assay buffer influenced the level of protein activity. Comparative analysis of protein stability and ATPase activity in various buffers suggests an inverse relationship between the two. The highest ATPase activity was detected in HEPES, pH 7.0. A kinetic analysis of the ATPase activity in this buffer revealed an enzyme concentration dependence and ATP-induced protein oligomerization. Assuming that the dimer is the active form of enzyme, at least half of the purified HlyB-NBD was estimated to be a dimer at 1.2 microM under the most optimal conditions for ATP hydrolysis. This is about 2 orders of magnitude lower than reported for other canonical ABC-ATPases. The maximum reaction velocity of 0.6 micromol/mg x min at 22 degrees C and the apparent kinetic constant K(app)(0.5) of 0.26 mM for ATP were determined for the dimerized HlyB-NBD. Gel filtration experiments with the wild-type protein and HlyB-NBD mutated in a key catalytic residue, H662A, provided further evidence for ATP-induced protein dimerization. ATPase activity experiments with protein mixtures composed of wild-type and the ATPase-deficient H662A mutant demonstrated that one intact NBD within a dimer is sufficient for ATP hydrolysis. This single site turnover might suggest a sequential mechanism of ATP hydrolysis in the intact HlyB transporter.     

The C-terminal nucleotide binding domain of the human retinal ABCR protein is an adenosine triphosphatase

The rod outer segment ATP binding cassette (ABC) transporter protein (ABCR) plays an important role in retinal rod cells presumably transporting retinal. Genetic studies in humans have linked mutations in the ABCR gene to a number of inherited retinal diseases particularly Stargardt macular degeneration and age-related macular degeneration (ARMD). The ABCR protein is characterized by two nucleotide binding domains and two transmembrane domains, each consisting of six membrane-spanning helices. We have cloned and expressed the 376 amino acid (aa) C-terminal end of this protein (amino acid residues 1898-2273) containing the second nucleotide binding domain (NBD2) with a purification tag at its amino terminus. The expressed protein was found to be soluble and was purified using a rapid and high-yield single-step procedure. The purified protein was monomeric and migrated as a 43 kDa protein in SDS-PAGE. The purified NBD2 protein had strong ATPase activity with a K(m) of 631 microM and V(max) of 144 nmol min(-1) mg(-1). This ATPase activity on normalization was kinetically comparable to that observed for purified and reconstituted native ABCR. Nucleotide inhibition studies suggest that the binding of NBD2 is specific for ATP/dATP, and that none of the other ribonucleotides appeared to compete for binding at this site. These studies demonstrate that cloned and expressed NBD2 protein is a fully functional ATPase in the absence of the remainder of the molecule. The level of ATPase activity was comparable to that of trans-retinal-stimulated ABCR ATPase. The NBD2 expression plasmid was used to generate a Leu2027Phe mutation associated with Stargardt disease. Analysis of the ATPase activity of the mutant protein demonstrated that it had a 14-fold increase in binding affinity (K(m) = 46 microM) with a corresponding 9-fold decrease in the rate of hydrolysis (V(max) = 16.6 nmol min(-1) mg(-1)), indicating a significant alteration of the ATPase function. It also provided a molecular basis of Stargardt disease involving this mutation.     

Interaction of asymmetric ABCC9-encoded nucleotide binding domains determines KATP channel SUR2A catalytic activity

Nucleotide binding domains (NBDs) secure ATP-binding cassette (ABC) transporter function. Distinct from traditional ABC transporters, ABCC9-encoded sulfonylurea receptors (SUR2A) form, with Kir6.2 potassium channels, ATP-sensitive K+ (K ATP) channel complexes. SUR2A contains ATPase activity harbored within NBD2 and, to a lesser degree, NBD1, with catalytically driven conformations exerting determinate linkage on the Kir6.2 channel pore. While homodomain interactions typify NBDs of conventional ABC transporters, heterodomain NBD interactions and their functional consequence have not been resolved for the atypical SUR2A protein. Here, nanoscale protein topography mapped assembly of monodisperse purified recombinant SUR2A NBD1/NBD2 domains, precharacterized by dynamic light scattering. Heterodomain interaction produced conformational rearrangements inferred by secondary structural change in circular dichroism, and validated by atomic force and transmission electron microscopy. Physical engagement of NBD1 with NBD2 translated into enhanced intrinsic ATPase activity. Molecular modeling delineated a complemental asymmetry of NBD1/NBD2 ATP-binding sites. Mutation in the predicted catalytic base residue, D834E of NBD1, altered NBD1 ATPase activity disrupting potentiation of catalytic behavior in the NBD1/NBD2 interactome. Thus, NBD1/NBD2 assembly, resolved by a panel of proteomic approaches, provides a molecular substrate that determines the optimal catalytic activity in SUR2A, establishing a paradigm for the structure-function relationship within the K ATP channel complex.     

Characterization of Saccharomyces cerevisiae Atm1p: functional studies of an ABC7 type transporter

Saccharomyces cerevisiae Atm1p has been cloned, over-expressed and purified from a yeast expression system. The sequence includes both the soluble ATPase and transmembrane-spanning domains. With the introduction of an N-terminal Kozak sequence and a C-terminal (His)(6)-tag, a yield of 1 mg of Atm1p was obtained from 3 g wet yeast cells, which is comparable to other membrane-associated proteins isolated from eukaryotic expression systems. The ATPase activity of Atm1p is sensitive to sodium vanadate, a P-type ATPase inhibitor, with an IC(50) of 4 microM. MgADP is a product inhibitor for Atm1p with an IC(50) of 0.9 mM. The Michaelis-Menten constants V(max), K(M) and k(cat) of Atm1p were measured as 8.7+/-0.3 microM/min, 107+/-16 microM and 1.24+/-0.06 min(-1), respectively. A plot of ATPase activity versus concentration of Atm1p exhibits a nonlinear relationship, suggesting an allosteric response and an important role for the transmembrane domain in mediating both ATP hydrolysis and MgADP release. The metal dependence of Atm1p ATPase activity demonstrated a reactivity order of Mg(2+)>Mn(2+)>Co(2+), while each divalent ion was found to be inhibitory at higher concentrations. The activation and inhibitory effect of phospholipids suggest that formation of a lipid-micelle complex is important for enzymatic activity and stability. Structural analysis of Atm1p by CD spectroscopy suggested a similarity of secondary structure to that found for other members of this ABC protein family.     

ABC multidrug transporter Cdr1p of Candida albicans has divergent nucleotide-binding domains which display functional asymmetry

In order to ascertain the molecular basis of ATP-mediated drug extrusion by Cdr1p, a multidrug transporter of Candida albicans, we recently have reported that the Walker A motif of the N-terminal nucleotide biding domain (NBD) of this protein contains an uncommon cysteine residue (C193; GXXGXGCS/T) which is indispensable for ATP hydrolysis. This residue is exceptionally conserved in N-terminal NBDs of fungal ABC transporters and hence makes these transporters an evolutionarily divergent group. However, the presence of a conventional lysine residue at a similar position in the Walker A motif of the C-terminal NBD warrants the individual contribution of both the NBDs in the ATP-driven efflux function of such transporters. In this study we have investigated the contribution of this divergent Walker A motif in the context of the full Cdr1p protein under in vivo conditions by swapping these two crucial amino acids (C193K in Walker A motif of N-terminal NBD and K901C in Walker A motif of C-terminal NBD) between the two NBDs. Both the native and the mutant variants of Cdr1p were integrated at the PDR5 locus as GFP-tagged fusion proteins and were hyper-expressed. Our study shows that both C193K- and K901C-expressing cells elicit a severe impairment of Cdr1p's ATPase function. However, both these mutations have distinct phenotypes with respect to other functional parameters such as substrate efflux and drug resistance profiles. In contrast to C193K, K901C mutant cells were substantially hypersensitive to the tested drugs (fluconazole, ansiomycin, miconazole and cycloheximide) and were unable to expel rhodamine 6G. Our results for the first time show that both NBDs influence the Cdr1p function asymmetrically, and that the positioning of the cysteine and lysine residues within the respective Walker A motifs is functionally not interchangeable.     

Characterization of the catalytic subunit of an anion pump

The ArsA protein, the 63-kDa catalytic subunit of an oxyanion-translocating ATPase, was purified by successive chromatography using Q-Sepharose, red agarose, and phenyl-Sepharose to a specific activity in excess of 1 mumol of ATP hydrolyzed per min per mg of protein. ATPase activity was dependent on the presence of the oxyanionic substrates. Inhibitors of other classes of ion-translocating ATPases had no effect on ArsA ATPase activity, including N,N'-dicyclohexyl-carbodiimide, azide, vanadate, and nitrate. The apparent Km for ATP was determined to be 0.13 mM. The optimal pH range for ATP hydrolysis was 7.5 to 7.8. ATPase activity required Mg2+ at a molar ratio of 2 ATP:1 Mg2+. Limited proteolysis by trypsin was used to study conformational changes produced upon binding of substrates to the ArsA protein. In the absence of substrates, the ArsA protein was rapidly cleaved by trypsin to a major product of 30 kDa. ATP was partially protected from trypsin digestion, while the anionic substrate antimonite alone had no effect on proteolysis. Combination of the two substrates nearly completely protected the ArsA protein from proteolysis. Proteolytic cleavage correlated with loss of anion-stimulated ATPase activity and substrate protection from cleavage correlated with retention of activity. These results demonstrate that ATP and antimonite together produce a conformational change which is different from that of the ArsA protein in the presence of either substrate alone and suggest interaction between the oxyanion and ATP binding sites.     

Stimulation of the ATPase activity of the yeast mitochondrial ABC transporter Atm1p by thiol compounds

The ATP binding cassette (ABC) transporter Atm1p of the mitochondrial inner membrane performs crucial roles in both the biogenesis of cytosolic/nuclear iron-sulfur proteins and cellular iron homeostasis. Since the function of the mitochondrial iron-sulfur cluster (ISC) assembly machinery is also required for these two processes, Atm1p is thought to translocate a still unknown product of this pathway to the cytosol. Here, we provide a detailed in vitro characterization of Atm1p in order to better understand its function. Atm1p was purified using an expression system in E. coli. The detergent-solubilised protein exhibits a stable ATPase activity. Reconstitution of Atm1p into proteoliposomes allowed us to determine the biochemical characteristics of the ATPase such as: (i) the strong inhibition by the transition state analogue vanadate, (ii) a Km value of 0.1 mM, and (iii) a turnover number of 127 min-1. The ATPase activity of ABC transporters is generally stimulated by their specific substrate. We used this property to define the chemical properties of the substrate transported by Atm1p. ATPase hydrolysis by Atm1p-containing proteoliposomes was specifically increased 3-5-fold by thiol-containing compounds, in particular by micromolar concentrations of cysteine thiol groups in peptides, even though Atm1p is not a general peptide transporter such as yeast Mdl1p or mammalian TAP which share sequence similarity with Atm1p. We speculate that the physiological substrate of Atm1p may contain multiple sulfhydryl groups in a peptidic environment.     

ABC multidrug transporter Cdr1p of Candida albicans has divergent nucleotide-binding domains which display functional asymmetry

In order to ascertain the molecular basis of ATP-mediated drug extrusion by Cdr1p, a multidrug transporter of Candida albicans, we recently have reported that the Walker A motif of the N-terminal nucleotide biding domain (NBD) of this protein contains an uncommon cysteine residue (C193; GXXGXGCS/T) which is indispensable for ATP hydrolysis. This residue is exceptionally conserved in N-terminal NBDs of fungal ABC transporters and hence makes these transporters an evolutionarily divergent group. However, the presence of a conventional lysine residue at a similar position in the Walker A motif of the C-terminal NBD warrants the individual contribution of both the NBDs in the ATP-driven efflux function of such transporters. In this study we have investigated the contribution of this divergent Walker A motif in the context of the full Cdr1p protein under in vivo conditions by swapping these two crucial amino acids (C193K in Walker A motif of N-terminal NBD and K901C in Walker A motif of C-terminal NBD) between the two NBDs. Both the native and the mutant variants of Cdr1p were integrated at the PDR5 locus as GFP-tagged fusion proteins and were hyper-expressed. Our study shows that both C193K- and K901C-expressing cells elicit a severe impairment of Cdr1p’s ATPase function. However, both these mutations have distinct phenotypes with respect to other functional parameters such as substrate efflux and drug resistance profiles. In contrast to C193K, K901C mutant cells were substantially hypersensitive to the tested drugs (fluconazole, ansiomycin, miconazole and cycloheximide) and were unable to expel rhodamine 6G. Our results for the first time show that both NBDs influence the Cdr1p function asymmetrically, and that the positioning of the cysteine and lysine residues within the respective Walker A motifs is functionally not interchangeable.