Evidence for a Molecular Diode-based Mechanism in a Multispecific ATP-binding cassette (ABC) Exporter: SER-1368 AS A GATEKEEPING RESIDUE IN THE YEAST MULTIDRUG TRANSPORTER Pdr5*

ATP-binding cassette multidrug efflux pumps transport a wide range of substrates. Current models suggest that a drug binds relatively tightly to a transport site in the transmembrane domains when the protein is in the closed inward facing conformation. Upon binding of ATP, the transporter can switch to an outward facing (drug off or drug releasing) structure of lower affinity. ATP hydrolysis is critically important for remodeling the drug-binding site to facilitate drug release and to reset the transporter for a new transport cycle. We characterized the novel phenotype of an S1368A mutant that lies in the putative drug-binding pocket of the yeast multidrug transporter Pdr5. This substitution created broad, severe drug hypersensitivity, although drug binding, ATP hydrolysis, and intradomain signaling were indistinguishable from the wild-type control. Several different rhodamine 6G efflux and accumulation assays yielded evidence consistent with the possibility that Ser-1368 prevents reentry of the excluded drug.     

Rationally Designed Transmembrane Peptide Mimics of the Multidrug Transporter Protein Cdr1 Act as Antagonists to Selectively Block Drug Efflux and Chemosensitize Azole-resistant Clinical Isolates of Candida albicans

Drug-resistant pathogenic fungi use several families of membrane-embedded transporters to efflux antifungal drugs from the cells. The efflux pump Cdr1 (Candida drug resistance 1) belongs to the ATP-binding cassette (ABC) superfamily of transporters. Cdr1 is one of the most predominant mechanisms of multidrug resistance in azole-resistant (AR) clinical isolates of Candida albicans. Blocking drug efflux represents an attractive approach to combat the multidrug resistance of this opportunistic human pathogen. In this study, we rationally designed and synthesized transmembrane peptide mimics (TMPMs) of Cdr1 protein (Cdr1p) that correspond to each of the 12 transmembrane helices (TMHs) of the two transmembrane domains of the protein to target the primary structure of the Cdr1p. Several FITC-tagged TMPMs specifically bound to Cdr1p and blocked the efflux of entrapped fluorescent dyes from the AR (Gu5) isolate. These TMPMs did not affect the efflux of entrapped fluorescent dye from cells expressing the Cdr1p homologue Cdr2p or from cells expressing a non-ABC transporter Mdr1p. Notably, the time correlation of single photon counting fluorescence measurements confirmed the specific interaction of FITC-tagged TMPMs with their respective TMH. By using mutant variants of Cdr1p, we show that these TMPM antagonists contain the structural information necessary to target their respective TMHs of Cdr1p and specific binding sites that mediate the interactions between the mimics and its respective helix. Additionally, TMPMs that were devoid of any demonstrable hemolytic, cytotoxic, and antifungal activities chemosensitize AR clinical isolates and demonstrate synergy with drugs that further improved the therapeutic potential of fluconazole in vivo.     

Functional characterization of Candida albicans ABC transporter Cdr1p

In view of the importance of Candida drug resistance protein (Cdr1p) in azole resistance, we have characterized it by overexpressing it as a green fluorescent protein (GFP)-tagged fusion protein (Cdr1p-GFP). The overexpressed Cdr1p-GFP in Saccharomyces cerevisiae is shown to be specifically labeled with the photoaffinity analogs iodoarylazidoprazosin (IAAP) and azidopine, which have been used to characterize the drug-binding sites on mammalian drug-transporting P-glycoproteins. While nystatin could compete for the binding of IAAP, miconazole specifically competed for azidopine binding, suggesting that IAAP and azidopine bind to separate sites on Cdr1p. Cdr1p was subjected to site-directed mutational analysis. Among many mutant variants of Cdr1p, the phenotypes of F774A and ΔF774 were particularly interesting. The analysis of GFP-tagged mutant variants of Cdr1p revealed that a conserved F774, in predicted transmembrane segment 6, when changed to alanine showed increased binding of both photoaffinity analogues, while its deletion (ΔF774), as revealed by confocal microscopic analyses, led to mislocalization of the protein. The mislocalized ΔF774 mutant Cdr1p could be rescued to the plasma membrane as a functional transporter by growth in the presence of a Cdr1p substrate, cycloheximide. Our data for the first time show that the drug substrate-binding sites of Cdr1p exhibit striking similarities with those of mammalian drug-transporting P-glycoproteins and despite differences in topological organization, the transmembrane segment 6 in Cdr1p is also a major contributor to drug substrate-binding site(s).     

Characterization of Cdr1p, a major multidrug efflux protein of Candida albicans: purified protein is amenable to intrinsic fluorescence analysis

Candida drug resistance protein 1 (Cdr1p), an ATP-dependent drug efflux pump, confers multidrug resistance in immunocompromised and debilitated patients. A member of the ATP-binding cassette (ABC) superfamily of membrane transporters, Cdr1p contains two nucleotide binding/utilization sites (NBDs) and two transmembrane domains (TMDs). We had earlier characterized Cdr1p by its overexpression as a GFP-tagged fusion protein that elicits oligomycin-sensitive ATPase activity and is linked to drug extrusion. However, it is essential to have highly purified Cdr1p to understand the detailed molecular basis of structure and functions of this protein. In this study, we have developed a two-step purification protocol using stably overexpressed His-tagged Cdr1p in Saccharomyces cerevisiae. Purified Cdr1p exhibited divalent cation-dependent ATPase activity [approximately 1.2 micromol (mg of protein)(-)(1) min(-)(1)] with an apparent K(M) in the range of 1.8 to 2.1 mM and V(max) between 1.0 and 1.4 micromol (mg of protein)(-)(1) min(-)(1). Unlike its close homologue human P-gp/MDR1, purified Cdr1p only moderately displayed drug stimulated ATPase activity. By exploiting intrinsic fluorescence intensity of purified Cdr1p, which contains 24 tryptophan residues, we could monitor defined conformational changes upon substrate drug and ATP binding. It is observed that ATP binding to Cdr1p (K(d) = approximately 1.7 mM) is not a prerequisite for drug binding, and both the mechanisms of drug as well as ATP binding, which induce specific conformational changes, occur independent of each other. Our study for the first time provides a catalytically active purified ABC transporter from a fungal pathogen, which is amenable to fluorescence measurements and thus would be useful in understanding the molecular basis of antifungal transport.     

Modelling,substrate docking and mutational analysis identify residues essential for function and specificity of the major fungal purine transporter AzgA

The AzgA purine/H⁺ symporter of Aspergillus nidulans is the founding member of a functionally and phylogenetically distinct transporter family present in fungi, bacteria and plants. Here a valid AzgA topological model is built based on the crystal structure of the Escherichia coli uracil transporter UraA, a member of the nucleobase‐ascorbate transporter (NAT/NCS2) family. The model consists of 14 transmembrane, mostly α‐helical, segments (TMSs) and cytoplasmic N‐ and C‐tails. A distinct compact core of 8 TMSs, made of two intertwined inverted repeats (TMSs 1–4 and 8–11), is topologically distinct from a flexible domain (TMSs 5–7 and 12–14). A putative substrate binding cavity is visible between the core and the gate domains. Substrate docking, molecular dynamics and mutational analysis identified several residues critical for purine binding and/or transport in TMS3, TMS8 and TMS10. Among these, Asn131 (TMS3), Asp339 (TMS8) and Glu394 (TMS10) are proposed to directly interact with substrates, while Asp342 (TMS8) might be involved in subsequent substrate translocation, through H⁺ binding and symport. Thus, AzgA and other NAT transporters use topologically similar TMSs and amino acid residues for substrate binding and transport, which in turn implies that AzgA‐like proteins constitute a distant subgroup of the ubiquitous NAT family.     

The amino acid residues of transmembrane helix 5 of multidrug resistance protein CaCdr1p of Candida albicans are involved in substrate specificity and drug transport

In view of the importance of Candida Drug Resistance Protein (Cdr1p) of pathogenic Candida albicans in azole resistance, we have characterized its ability to efflux variety of substrates by subjecting its entire transmembrane segment (TMS) 5 to site directed mutagenesis. All the mutant variants of putative 21 amino acids of TMS 5 and native CaCdr1p were over expressed as a GFP-tagged protein in a heterologous host Saccharomyces cerevisiae. Based on the drug susceptibility pattern, the mutant variants could be grouped into two categories. The variants belonging to first category were susceptible to all the tested drugs, as compared to those belonging to second category which exhibited resistance to selective drugs. The mutant variants of both the categories were analyzed for their ATP catalysis and drug efflux properties. Irrespective of the categories, most of the mutant variants of TMS 5 showed an uncoupling between ATP hydrolysis and drug efflux. The mutant variants such as M667A, F673A, I675A and P678A were an exception since they reflected a sharp reduction in both K_m and V_max values of ATPase activity when compared with WT CaCdr1p-GFP. Based on the competition experiments, we could identify TMS 5 residues which are specific to interact with select drugs. TMS 5 residues of CaCdr1p thus not only impart substrate specificity but also selectively act as a communication link between ATP hydrolysis and drug transport.     

The transmembrane domains of the ABC multidrug transporter LmrA form a cytoplasmic exposed,aqueous chamber within the membrane

The ABC multidrug transporter LmrA of Lactococcus lactis consists of six putative transmembrane segments (TMS) and a nucleotide binding domain. LmrA functions as a homodimer in which the two membrane domains form the solute translocation path across the membrane. To obtain structural information of LmrA a cysteine scanning accessibility approach was used. Cysteines were introduced in the cysteine-less wild-type LmrA in each hydrophilic loop and in TMS 6, and each membrane-embedded aromatic residue was mutated to cysteine. Of the 41 constructed single cysteine mutants, only one mutant, L301C, was not expressed. Most single-cysteine mutants were capable of drug transport and only three mutants, F37C, M299C, and N300C, were inactive, indicating that none of the aromatic residues in the transmembrane regions of LmrA are crucial for substrate binding or transport. Modification of the active mutants with N-ethylmaleimide blocked the transport activity in five mutants (S132C, L174C, S206C, S234C, and L292C). All cysteine residues in external and internal loops were accessible to fluorescein maleimide. The labeling experiments also showed that this thiol reagent cannot cross the membrane under the conditions used and confirmed the presence of six TMSs in each monomeric half of the transporter. Surprisingly, several single cysteines in the predicted TMSs could also be labeled by the bulky fluorescein maleimide molecule, suggesting unrestricted accessibility via an aqueous pathway. The periodicity of fluorescein maleimide accessibility of residues 291 to 308 in TMS 6 showed that this membrane-spanning alpha-helix has one face of the helix exposed to an aqueous cavity along its full-length. This finding, together with the solvent accessibility of 11 of 15 membrane-embedded aromatic residues, indicates that the transmembrane domains of the LmrA transporter form, under nonenergized conditions, an aqueous chamber within the membrane, which is open to the intracellular milieu.     

W1038 near D-loop of NBD2 is a focal point for inter-domain communication in multidrug transporter Cdr1 of Candida albicans

Candida drug resistance 1 (Cdr1), a PDR subfamily ABC transporter mediates efflux of xenobiotics in Candida albicans. It is one of the prime factors contributing to multidrug resistance in the fungal pathogen. One hallmark of this transporter is its asymmetric nature, characterized by peculiar alterations in its nucleotide binding domains. As a consequence, there exists only one canonical ATP-binding site while the other is atypical. Here, we report suppressor analysis on the drug-susceptible transmembrane domain mutant V532D that identified the suppressor mutation W1038S, close to the D-loop of the non-catalytic ATP-binding site. Introduction of the W1038S mutation in the background of V532D mutant conferred resistance for most of the substrates to the latter. Such restoration is accompanied by a severe reduction of ATPase activity, of about 85%, while that of the V532D mutant is half-reduced. Conversely, alanine substitution of the highly conserved aspartate D1033A in that D-loop rendered cells selectively hyper-susceptible to miconazole without an impact on steady-state ATPase activity, suggesting altogether that ATP hydrolysis may not hold the key to restoration mechanism. Analysis of the ABCG5/ABCG8-based 3D-model of Cdr1p suggested that the W1038S substitution leads to the loss of hydrophobic interactions and H-bond with residues of the neighbor NBD1, in the non-catalytic ATP-binding site area. The compensatory effect within TMDs accounting for transport restoration in the V532D-W1038S variant may, therefore, be mainly due to an increase in NBDs mobility at the non-catalytic interface.     

A fourth gene from the Candida albicans CDR family of ABC transporters

Using primers derived from a region of the Candida albicans CDR1 (Candida drug resistance) gene that is conserved in other ABC (ATP-binding cassette) transporters, a DNA fragment from a previously unknown CDR gene was obtained by polymerase chain reaction (PCR). After screening a C. albicans genomic library with this fragment as a probe, the complete CDR4 gene was isolated and sequenced. CDR4 codes for a putative ABC transporter of 1490 amino acids with a high degree of homology to Cdr1p, Cdr2p and Cdr3p from C. albicans (62, 59 and 57% amino acid sequence identity, respectively). Cdr4p has a predicted structure typical for cluster I.1 of yeast ABC transporters, characterized by two homologous halves, each comprising an N-terminal hydrophilic domain with consensus sequences for ATP binding and a C-terminal hydrophobic domain with six transmembrane helices. In contrast to the CDR1/CDR2 genes, the genetic structure of the CDR4 gene was conserved in 59 C. albicans isolates from six different patients. Northern hybridization analysis showed that the CDR4 gene was expressed in most isolates, but no correlation between CDR4 mRNA levels and the degree of fluconazole resistance of the isolates was found. In addition, a C. albicans mutant in which both copies of the CDR4 gene were disrupted by insertional mutagenesis was not hypersusceptible to fluconazole as compared to the parent strain. Unlike CDR1 and CDR2, CDR4 does not, therefore, seem to be involved in fluconazole resistance in C. albicans.     

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.     

Translocation mechanism of P-glycoprotein and conformational changes occurring at drug-binding site: Insights from multi-targeted molecular dynamics

P-glycoprotein (P-gp) is well known for multidrug resistance in drug therapy. Its over-expression results into the increased efflux of therapeutic agents rendering them inefficacious. A clear understanding of P-gp efflux mechanism and substrate/inhibitor interactions during the course of efflux cycle will be crucial for designing effective P-gp inhibitors, and therapeutic agents that are non-substrate to P-gp. In the present work, we have modeled P-gp in three different catalytic states. These models were utilized for elucidation of P-gp translocation mechanism using multi-targeted molecular dynamics (MTMD). The gradual changes occurring in P-gp structure from inward open to outward open conformation were sampled out. A detailed investigation of conformational changes occurring in trans-membrane domains (TMDs) during the course of catalytic cycle was carried out. Movements of each TM helices in response to pronounced twisting and translatory motion of NBDs were measured quantitatively. The role of intracellular coupling helices (ICHs) during the structural transition of P-gp was studied, and observed as vital links for structural transition. A close observation of displacements and conformational changes in the residues lining drug-binding pocket was also carried out. Further, we have analyzed the molecular interactions of P-gp substrates/inhibitors during the P-gp translocation to find out how stable binding interactions of a compound at drug-binding site(s) in open conformation, becomes highly destabilized in closed conformation. The study revealed striking differences between the molecular interactions of substrate and inhibitor; inhibitors showed a tendency to maintain stable binding interactions during the catalytic transition cycle.     

Human P-glycoprotein is active when the two halves are clamped together in the closed conformation

The P-glycoprotein (P-gp, ABCB1) drug pump protects us from toxic compounds and confers multidrug resistance. Each of the two homologous halves of P-gp is composed of a transmembrane domain (TMD) with six TM segments followed by a nucleotide-binding domain (NBD). The drug- and ATP-binding sites reside at the interface between the TMDs and NBDs, respectively. Crystal structures show drug pumps in the open and closed conformations, where the drug-binding pocket and NBDs are open or closed at the cytoplasmic side, respectively. Although it has been postulated that drug substrates enter the drug-binding pocket in the open conformation, it is unknown if they can enter in the closed conformation. To determine this, we introduced cysteines into regions of TM3 (residues 175-178) and TM9 (residues 820-822) that extend into the cytoplasm and are 4 Å and 20 Å apart in the closed and open conformations, respectively. The 12 double cysteine mutants were then cross-linked with a short cross-linker, M1M (4 Å) at 0 °C to reduce thermal motion in the protein. Only mutant L175C/N820C was cross-linked. Cross-linking was not increased in the presence of ATP or drug substrates. Cross-linking increased its basal ATPase activity about 3-fold. Activity could be increased further by drug substrates such as verapamil and rhodamine B. These results suggest that P-gp in the membrane is in the closed conformation that has a high affinity for drug substrates.     

Structure and function analysis of CaMdr1p, a major facilitator superfamily antifungal efflux transporter protein of Candida albicans: identification of amino acid residues critical for drug/H+ transport

We have cloned and overexpressed multidrug transporter CaMdr1p as a green fluorescent protein-tagged protein to show its capability to extrude drug substrates. The drug extrusion was sensitive to pH and energy inhibitors and displayed selective substrate specificity. CaMdr1p has a unique and conserved antiporter motif, also called motif C [G(X6)G(X3)GP(X2)GP(X2)G], in its transmembrane segment 5 (TMS 5). Alanine scanning of all the amino acids of the TMS 5 by site-directed mutagenesis highlighted the importance of the motif, as well as that of other residues of TMS 5, in drug transport. The mutant variants of TMS 5 were placed in four different categories. The first category had four residues, G244, G251, G255, and G259, which are part of the conserved motif C, and their substitution with alanine resulted in increased sensitivity to drugs and displayed impaired efflux of drugs. Interestingly, first category mutants, when replaced with leucine, resulted in more dramatic loss of drug resistance and efflux. Notwithstanding the location in the core motif, the second category included residues which are part of the motif, such as P260, and those which were not part of the motif, such as L245, W248, P256, and F262, whose substitution with alanine resulted in a severe loss of drug resistance and efflux. The third category included G263, which is a part of motif C, but unlike other conserved glycines, its replacement with alanine or leucine showed no change in the phenotype. The replacement of the remaining 11 residues of the fourth category did not result in any change. The putative helical wheel projection showed clustering of functionally critical residues to one side and thus suggests an asymmetric nature of TMS 5.     

The Candida albicans CDR3 gene codes for an opaque-phase ABC transporter.

We report the cloning and functional analysis of a third member of the CDR gene family in Candida albicans, named CDR3. This gene codes for an ABC (ATP-binding cassette) transporter of 1,501 amino acids highly homologous to Cdr1p and Cdr2p (56 and 55% amino acid sequence identity, respectively), two transporters involved in fluconazole resistance in C. albicans. The predicted structure of Cdr3p is typical of the PDR/CDR family, with two similar halves, each comprising an N-terminal hydrophilic domain with consensus sequences for ATP binding and a C-terminal hydrophobic domain with six predicted transmembrane segments. Northern analysis showed that CDR3 expression is regulated in a cell-type-specific manner, with low levels of CDR3 mRNA in CAI4 yeast and hyphal cells, high levels in WO-1 opaque cells, and undetectable levels in WO-1 white cells. Disruption of both alleles of CDR3 in CAI4 resulted in no obvious changes in cell morphology, growth rate, or susceptibility to fluconazole. Overexpression of Cdr3p in C. albicans did not result in increased cellular resistance to fluconazole, cycloheximide, and 4-nitroquinoline-N-oxide, which are known substrates for different transporters of the PDR/CDR family. These results indicate that despite a high degree of sequence conservation with C. albicans Cdr1p and Cdr2p, Cdr3p does not appear to be involved in drug resistance, at least to the compounds tested which include the clinically relevant antifungal agent fluconazole. Rather, the high level of Cdr3p expression in WO-1 opaque cells suggests an opaque-phase-associated biological function which remains to be identified.     

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.     

β-Lactam Selectivity of Multidrug Transporters AcrB and AcrD Resides in the Proximal Binding Pocket

β-Lactams are mainstream antibiotics that are indicated for the prophylaxis and treatment of bacterial infections. The AcrA-AcrD-TolC multidrug efflux system confers much stronger resistance on Escherichia coli to clinically relevant anionic β-lactam antibiotics than the homologous AcrA-AcrB-TolC system. Using an extensive combination of chimeric analysis and site-directed mutagenesis, we searched for residues that determine the difference in β-lactam specificity between AcrB and AcrD. We identified three crucial residues at the “proximal” (or access) substrate binding pocket. The simultaneous replacement of these residues in AcrB by those in AcrD (Q569R, I626R, and E673G) transferred the β-lactam specificity of AcrD to AcrB. Our findings indicate for the first time that the difference in β-lactam specificity between AcrB and AcrD relates to interactions of the antibiotic with residues in the proximal binding pocket.     

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.     

Localization and Substrate Selectivity of Sea Urchin Multidrug (MDR) Efflux Transporters

In this study, we cloned, expressed and functionally characterized Stronglycentrotus purpuratus (Sp) ATP-binding cassette (ABC) transporters. This screen identified three multidrug resistance (MDR) transporters with functional homology to the major types of MDR transporters found in humans. When overexpressed in embryos, the apical transporters Sp-ABCB1a, ABCB4a, and ABCG2a can account for as much as 87% of the observed efflux activity, providing a robust assay for their substrate selectivity. Using this assay, we found that sea urchin MDR transporters export canonical MDR susbtrates such as calcein-AM, bodipy-verapamil, bodipy-vinblastine, and mitoxantrone. In addition, we characterized the impact of nonconservative substitutions in the primary sequences of drug binding domains of sea urchin versus murine ABCB1 by mutation of Sp-ABCB1a and treatment of embryos with stereoisomeric cyclic peptide inhibitors (QZ59 compounds). The results indicated that two substitutions in transmembrane helix 6 reverse stereoselectivity of Sp-ABCB1a for QZ59 enantiomers compared with mouse ABCB1a. This suggests that subtle changes in the primary sequence of transporter drug binding domains could fine-tune substrate specificity through evolution.     

Candida glabrata ATP-binding cassette transporters Cdr1p and Pdh1p expressed in a Saccharomyces cerevisiae strain deficient in membrane transporters show phosphorylation-dependent pumping properties

The expression and drug efflux activity of the ATP binding cassette transporters Cdr1p and Pdh1p are thought to have contributed to the recent increase in the number of fungal infections caused by Candida glabrata. The function of these transporters and their pumping characteristics, however, remain ill defined. We have evaluated the function of Cdr1p and Pdh1p through their heterologous hyperexpression in a Saccharomyces cerevisiae strain deleted in seven major drug efflux transporters to minimize the background drug efflux activity. Although both Cdr1p- and Pdh1p-expressing strains CDR1-AD and PDH1-AD acquired multiple resistances to structurally unrelated compounds, CDR1-AD showed, in most cases, higher levels of resistance than PDH1-AD. CDR1-AD also showed greater rhodamine 6G efflux and resistance to pump inhibitors, although plasma membrane fractions had comparable NTPase activities. These results indicate that Cdr1p makes a larger contribution than Phd1p to the reduced susceptibility of C. glabrata to xenobiotics. Both pump proteins were phosphorylated in a glucose-dependent manner. Whereas the phosphorylation of Cdr1p affected its NTPase activity, the protein kinase A-mediated phosphorylation of Pdh1p, which was necessary for drug efflux, did not. This suggests that phosphorylation of Pdh1p may be required for efficient coupling of NTPase activity with drug efflux.     

Flavone-resistant Leishmania donovani Overexpresses LdMRP2 Transporter in the Parasite and Activates Host MRP2 on Macrophages to Circumvent the Flavone-mediated Cell Death

In parasites, ATP-binding cassette (ABC) transporters represent an important family of proteins related to drug resistance and other biological activities. Resistance of leishmanial parasites to therapeutic drugs continues to escalate in developing countries, and in many instances, it is due to overexpressed ABC efflux pumps. Progressively adapted baicalein (BLN)-resistant parasites (pB²⁵R) show overexpression of a novel ABC transporter, which was classified as ABCC2 or Leishmania donovani multidrug resistance protein 2 (LdMRP2). The protein is primarily localized in the flagellar pocket region and in internal vesicles. Overexpressed LdABCC2 confers substantial BLN resistance to the parasites by rapid drug efflux. The BLN-resistant promastigotes when transformed into amastigotes in macrophage cells cannot be cured by treatment of macrophages with BLN. Amastigote resistance is concomitant with the overexpression of macrophage MRP2 transporter. Reporter analysis and site-directed mutagenesis assays demonstrated that antioxidant response element 1 is activated upon infection. The expression of this phase II detoxifying gene is regulated by NFE2-related factor 2 (Nrf2)-mediated antioxidant response element activation. In view of the fact that the signaling pathway of phosphoinositol 3-kinase controls microfilament rearrangement and translocation of actin-associated proteins, the current study correlates with the intricate pathway of phosphoinositol 3-kinase-mediated nuclear translocation of Nrf2, which activates MRP2 expression in macrophages upon infection by the parasites. In contrast, phalloidin, an agent that prevents depolymerization of actin filaments, inhibits Nrf2 translocation and Mrp2 gene activation by pB²⁵R infection. Taken together, these results provide insight into the mechanisms by which resistant clinical isolates of L. donovani induce intracellular events relevant to drug resistance.