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.     

Membrane fluidity affects functions of Cdr1p, a multidrug ABC transporter of Candida albicans

Earlier, we have shown that the overexpression of an ABC transporter, CDR1, is involved in the emergence of multidrug resistance in Candida albicans. In this study, we checked its function in vivo by expressing it in different isogenic Saccharomyces cerevisiae erg mutants, which accumulated various intermediates of the ergosterol biosynthesis and thus altered the membrane fluidity. Functions like the accumulation of rhodamine 123, beta-estradiol, fluconazole and floppase activity associated with Cdr1p were measured to ascertain their responses to an altered membrane phase. The floppase activity appeared to be favoured by an enhanced membrane fluidity, while the effluxing of substrates and Cdr1p's ability to confer multidrug resistance were significantly reduced. We demonstrate that only some of the functions of Cdr1p were affected by an altered lipid environment.     

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).     

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.     

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.     

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.     

Chimeras of Candida albicans Cdr1p and Cdr2p reveal features of pleiotropic drug resistance transporter structure and function

Members of the pleiotropic drug resistance (PDR) family of ATP binding cassette (ABC) transporters consist of two homologous halves, each containing a nucleotide binding domain (NBD) and a transmembrane domain (TMD). The PDR transporters efflux a variety of hydrophobic xenobiotics and despite the frequent association of their overexpression with the multidrug resistance of fungal pathogens, the transport mechanism of these transporters is poorly understood. Twenty-eight chimeric constructs between Candida albicans Cdr1p (CaCdr1p) and Cdr2p (CaCdr2p), two closely related but functionally distinguishable PDR transporters, were expressed in Saccharomyces cerevisiae. All chimeras expressed equally well, localized properly at the plasma membrane, retained their transport ability, but their substrate and inhibitor specificities differed significantly between individual constructs. A detailed characterization of these proteins revealed structural features that contribute to their substrate specificities and their transport mechanism. It appears that most transmembrane spans of CaCdr1p and CaCdr2p provide or affect multiple, probably overlapping, substrate and inhibitor binding site(s) similar to mammalian ABC transporters. The NBDs, in particular NBD1 and/or the ～150 amino acids N-terminal to NBD1, can also modulate the substrate specificities of CaCdr1p and CaCdr2p.     

Allelic variants of ABC drug transporter Cdr1p in clinical isolates of Candida albicans

Candida drug resistance protein (Cdr1p) is a major drug efflux protein, which plays a key role in commonly encountered clinical azole resistance in Candida albicans. We have analyzed its sequence in several azole resistant clinical isolates to evaluate the allelic variation within CDR1 gene and to relate it to its functional activity. The sequence analysis revealed 53 single nucleotide polymorphisms (SNPs), out of which six were non-synonymous single nucleotide polymorphisms (NS-SNPs) implying a change in amino acid and were found in two or more than two allelic combinations in different sensitive or resistant isolates. We have identified three new NS-SNPs namely, E948P, T950S, and F1399Y, in isolates wherein F1399Y appeared to be unique and was present in one of the naturally occurring azole resistant isolates obtained from Indian diabetic patients. However, site-directed mutagenesis showed that the residue F1399 in between TMS 11 and TMS 12 does not affect the functionality of Cdr1p. Taken together, our SNPs analyses reveal that unlike human P-gp, the naturally acquired allelic variations are mostly present in non-conserved regions of the protein which do not allow Cdr1p to genetically evolve in a manner, that would allow a change in its functionality to affect substrate recognition, specificity, and drug efflux activity of C. albicans cells.     

A novel catalytic mechanism for ATP hydrolysis employed by the N-terminal nucleotide-binding domain of Cdr1p, a multidrug ABC transporter of Candida albicans

Although essentially conserved, the N-terminal nucleotide-binding domain (NBD) of Cdr1p and other fungal transporters has some unique substitutions of amino acids which appear to have functional significance for the drug transporters. We have previously shown that the typical Cys193 in Walker A as well as Trp326 and Asp327 in the Walker B of N-terminal NBD (NBD-512) of Cdr1p has acquired unique roles in ATP binding and hydrolysis. In the present study, we show that due to spatial proximity, fluorescence resonance energy transfer (FRET) takes place between Trp326 of Walker B and MIANS [2-(4-maleimidoanilino) naphthalene-6-sulfonic acid] on Cys193 of Walker A motif. By exploiting FRET, we demonstrate how these critical amino acids are positioned within the nucleotide-binding pocket of NBD-512 to bind and hydrolyze ATP. Our results show that both Mg2+ coordination and nucleotide binding contribute to the formation of the active site. The entry of Mg2+ into the active site causes the first large conformational change that brings Trp326 and Cys193 in close proximity to each other. We also show that besides Trp326, typical Glu238 in the Q-loop also participates in coordination of Mg2+ by NBD-512. A second conformational change is induced when ATP, but not ADP, docks into the pocket. Asn328 does sensing of the gamma-phosphate of the substrate in the extended Walker B motif, which is essential for the second conformational change that must necessarily precede ATP hydrolysis. Taken together our results imply that the uniquely placed residues in NBD-512 have acquired critical roles in ATP catalysis, which drives drug extrusion.     

Specific interactions between the Candida albicans ABC transporter Cdr1p ectodomain and a d-octapeptide derivative inhibitor

Overexpression of the Candida albicans ATP‐binding cassette transporter CaCdr1p causes clinically significant resistance to azole drugs including fluconazole (FLC). Screening of a ～ 1.89 × 10⁶ member d ‐octapeptide combinatorial library that concentrates library members at the yeast cell surface identified RC21v3, a 4‐methoxy‐2,3,6‐trimethylbenzenesulphonyl derivative of the d ‐octapeptide d ‐NH₂‐FFKWQRRR‐CONH₂, as a potent and stereospecific inhibitor of CaCdr1p. RC21v3 chemosensitized Saccharomyces cerevisiae strains overexpressing CaCdr1p but not other fungal ABC transporters, the C. albicans MFS transporter CaMdr1p or the azole target enzyme CaErg11p, to FLC. RC21v3 also chemosensitized clinical C. albicans isolates overexpressing CaCDR1 to FLC, even when CaCDR2 was overexpressed. Specific targeting of CaCdr1p by RC21v3 was confirmed by spontaneous RC21v3 chemosensitization‐resistant suppressor mutants of S. cerevisiae expressing CaCdr1p. The suppressor mutations introduced a positive charge beside, or within, extracellular loops 1, 3, 4 and 6 of CaCdr1p or an aromatic residue near the extracytoplasmic end of transmembrane segment 5. The mutations did not affect CaCdr1p localization or CaCdr1p ATPase activity but some increased susceptibility to the CaCdr1p substrates FLC, rhodamine 6G, rhodamine 123 and cycloheximide. The suppressor mutations showed that the drug‐like CaCdr1p inhibitors FK506, enniatin, milbemycin α11 and milbemycin β9 have modes of action similar to RC21v3.     

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.     

Farnesol-induced apoptosis in Candida albicans is mediated by Cdr1-p extrusion and depletion of intracellular glutathione

Farnesol is a key derivative in the sterol biosynthesis pathway in eukaryotic cells previously identified as a quorum sensing molecule in the human fungal pathogen Candida albicans. Recently, we demonstrated that above threshold concentrations, farnesol is capable of triggering apoptosis in C. albicans. However, the exact mechanism of farnesol cytotoxicity is not fully elucidated. Lipophilic compounds such as farnesol are known to conjugate with glutathione, an antioxidant crucial for cellular detoxification against damaging compounds. Glutathione conjugates act as substrates for ATP-dependent ABC transporters and are extruded from the cell. To that end, this current study was undertaken to validate the hypothesis that farnesol conjugation with intracellular glutathione coupled with Cdr1p-mediated extrusion of glutathione conjugates, results in total glutathione depletion, oxidative stress and ultimately fungal cell death. The combined findings demonstrated a significant decrease in intracellular glutathione levels concomitant with up-regulation of CDR1 and decreased cell viability. However, addition of exogenous reduced glutathione maintained intracellular glutathione levels and enhanced viability. In contrast, farnesol toxicity was decreased in a mutant lacking CDR1, whereas it was increased in a CDR1-overexpressing strain. Further, gene expression studies demonstrated significant up-regulation of the SOD genes, primary enzymes responsible for defense against oxidative stress, with no changes in expression in CDR1. This is the first study describing the involvement of Cdr1p-mediated glutathione efflux as a mechanism preceding the farnesol-induced apoptotic process in C. albicans. Understanding of the mechanisms underlying farnesol-cytotoxicity in C. albicans may lead to the development of this redox-cycling agent as an alternative antifungal agent.     

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.     

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.     

Phenotypic switching in Candida albicans is controlled by a SIR2 gene

We report the cloning of a gene from the human fungal pathogen Candida albicans with sequence and functional similarity to the Saccharomyces cerevisiae SIR2 gene. Deletion of the gene in C. albicans produces a dramatic phenotype: variant colony morphologies arise at frequencies as high as 1 in 10. The morphologies resemble those described previously as part of a phenotypic switching system proposed to contribute to pathogenesis. Deletion of SIR2 also produces a high frequency of karyotypic changes. These and other results are consistent with a model whereby Sir2 controls phenotypic switching and chromosome stability in C.albicans by organizing chromatin structure.     

The IQGAP Iqg1 is a regulatory target of CDK for cytokinesis in Candida albicans

Cyclin-dependent kinases (CDKs) drive and coordinate multiple cell-cycle events, including construction and contraction of the actomyosin ring during cytokinesis. However, it remains unclear whether CDKs regulate cytokinesis by directly targeting components of the ring. In a search for proteins containing consensus CDK phosphorylation sites in Candida albicans, we found that the IQGAP Iqg1 contains two dense clusters of 19 such sites flanking the actin-interacting CH domain. Here, we show that Iqg1 is indeed a phosphoprotein that undergoes cell-cycle-dependent phosphorylation and can be phosphorylated by purified Clb-Cdc28 kinases in vitro. Mass spectrometry identified several phosphoserine and phosphothreonine residues among these CDK sites. Mutating 15 of the CDK phosphorylation sites with alanine markedly reduced Iqg1 phosphorylation in vivo. The 15A mutation greatly stabilized Iqg1, caused both premature assembly and delayed disassembly of the actomyosin ring, blocked Iqg1 interaction with the actin-nucleating proteins Bni1 and Bnr1, and resulted in defects in cytokinesis. Our data therefore strongly support the idea that the Cdc28 CDK regulates cytokinesis partly by directly phosphorylating the actomyosin ring component Iqg1.     

CaSPA2 is important for polarity establishment and maintenance in Candida albicans

Saccharomyces cerevisiae Spa2p is a component of polarisome that controls cell polarity. Here, we have characterized the role of its homologue, CaSpa2p, in the polarized growth in Candida albicans. During yeast growth, GFP-tagged CaSpa2p localized to distinct growth sites in a cell cycle-dependent manner, while during hyphal growth it persistently localized to hyphal tips throughout the cell cycle. Persistent tip localization of the protein was also observed in Catup1Delta and Canrg1Delta, mutants constitutive for filamentous growth. Caspa2Delta exhibited defects in polarity establishment and maintenance, such as random budding and failure to confine growth to a small surface area leading to round cells with wide, elongated bud necks and markedly thicker hyphae. It was also defective in nuclear positioning, presumably a result of defective interactions between cytoplasmic microtubules with certain polarity determinants. The highly conserved SHD-I and SHD-V domains were found to be important and responsible for different aspects of CaSpa2p function. Caspa2Delta exhibited no virulence in the mouse systemic candidiasis model. Because of the existence of distinct growth forms and the easy control of the switch between them in vitro, C. albicans may serve as a useful model in cell polarity research.