The Candida albicans CDR1 and CDR2 genes code for highly homologous ATP-binding cassette (ABC) transporters which are overexpressed in azole-resistant clinical isolates and which confer resistance to multiple drugs by actively transporting their substrates out of the cells. These transporters are formed by two homologous halves, each with an intracellular domain containing an ATP-binding site followed by a membrane-associated domain. We have expressed Cdr1p and Cdr2p in Saccharomyces cerevisiae to investigate their functions. The two proteins were properly expressed and functional, as determined by Western blotting, drug susceptibility assays, and rhodamine efflux. Using total membrane proteins from these transformants, we showed that Cdr1p and Cdr2p bind to the photoreactive analogue of rhodamine 123, [125 I]iodoaryl azidorhodamine 123 (IAARh123). IAARh123 photoaffinity labeling of membranes prepared from cells expressing either the N half or the C half of Cdr2p, or both, demonstrated that both halves contribute to rhodamine binding and can bind to rhodamine independently. Interestingly, Cdr1p was found to confer hypersusceptibility to FK520, an immunosuppressant and antifungal agent, whereas Cdr2p conferred resistance to this compound, uncovering a major functional difference between the two transporters. Furthermore, when administered in combination with azoles, FK520 sensitized cells expressing CDR1 but not those expressing CDR2. Finally, we showed that Cdr2p confers hypersusceptibility to hydrogen peroxide and resistance to diamide, while Cdr1p has no effect against these oxidative agents. Taken together, our results demonstrate that, despite a high level of structural conservation, Cdr1p and Cdr2p exhibit major functional differences, suggesting distinct biological functions.Multidrug resistance (MDR) or pleiotropic drug resistance (PDR) is characterized by cellular cross-resistance to a broad spectrum of structurally and functionally unrelated cytotoxic compounds. It operates in a wide variety of cell types and involves the overexpression of membrane-associated transporters functioning as drug efflux pumps. Many of these transporters belong to the ATP-binding cassette (ABC) superfamily and contain highly conserved consensus sequences for ATP binding and hydrolysis (34). Well-characterized ABC transporters involved in MDR in mammalian cells include P glycoprotein type 1 (P-gp1) and the MDR-associated protein type 1 (MRP1), whose overexpression causes resistance to several anticancer drugs (2, 35). In the yeast Saccharomyces cerevisiae, overexpression of the ABC transporters Pdr5p and Snq2p has been shown to confer resistance to several different compounds with antifungal activities (6). Pdr5p and Snq2p are homologous proteins formed by two similar halves, each with an N-terminal hydrophilic domain that contains the ABC motif followed by a C-terminal hydrophobic domain with six predicted transmembrane (TM) segments, a structure characteristic of the PDR subfamily of ABC transporters ([ABC-TM] 2 ) (14, 67). ...
ABCG2 [also known as BCRP (breast cancer resistance protein) or MXR] is an ABC (ATP-binding cassette) protein shown to confer multidrug resistance. ABCG2 was initially identified in resistant breast carcinoma cells (MCF-7/AdrVp1000) selected with doxorubicin and verapamil. Later studies demonstrated the presence of a point mutation (Arg482 to Thr) in ABCG2 in MCF-7/AdrVp1000 cells. This mutation was shown to modulate the transport of Rh123 (rhodamine 123). In the present study, we have used a previously characterized photoreactive drug analogue of Rh123, IAARh123 (iodoaryl-azido-Rh123), to examine the effects of the Arg482Thr mutation on Rh123 binding and transport by ABCG2. Our results show that both wild-type (ABCG2R482) and mutant (ABCG2T482) ABCG2 bound directly to IAARh123. Surprisingly, however, wild-type ABCG2R482, which does not transport Rh123, was more intensely photolabelled than mutant ABCG2T482. In addition, inhibition of IAARh123 photolabelling using various drug substrates of ABCG2 revealed some differences between wild-type and mutant ABCG2. For example, a molar excess of mitoxantrone was more effective at inhibiting IAARh123 labelling of wild-type than of mutant ABCG2, while excess cisplatin, taxol and methotrexate showed significant inhibition of IAARh123 binding to both wild-type and mutant ABCG2. Taken together, the results of this study provide the first demonstration of the direct binding of drugs to ABCG2.
In general, tumors cells that are resistant to apoptosis and increase angiogenesis are a result of the hypoxic responses contributing to the malignant phenotype. In this study, we developed a chronic hypoxic cell model (HMLL), by incubating the prostate cancer MatLyLu cells in a hypoxic chamber (1% O(2)) over 3 weeks. Surviving cells were selected through each cell passage and were grown in the hypoxic condition up to 8 weeks. This strategy resulted in survival of only 5% of the cells. The surviving hypoxic cells displayed a greater stimulation on hypoxic adaptive response, including a greater expression of glucose transporter1 (Glut1) and VEGF secretion. In addition, higher invasion activity was observed in the chronic hypoxic HMLL cells as compared to MatLyLu cells exposed to acute hypoxia (1% O(2), 5 h) using the matrigel assay. To further examine the role of HIF-1alpha in tumor progression, both MatLyLu and HMLL cells were transfected with dominant-negative form of HIF-1alpha (DNHIF-1alpha). The Matrigel invasion activity induced by chronic hypoxia was significantly attenuated by DNHIF-1alpha. These results suggest that signaling pathways leading to hypoxic response may be differentially regulated in chronic hypoxic cells and acute hypoxic cells. Chronic hypoxia may play a greater role than acute hypoxia in promoting the aggressive phenotype of tumor cells. This observation mimics the clinical scenario where tumor cells following treatment with radiation are subjected to hypoxic conditions. The reemergence of tumor following treatment usually results in tumor cells that are more aggressive and metastatic.
Mutations in the MRP gene family member MRP6 cause pseudoxanthoma elasticum (PXE) in humans, a disease affecting elasticity of connective tissues. The normal function of MRP6, including its physiological substrate(s), remains unknown. To address these issues, recombinant rat Mrp6 (rMrp6) was expressed in the methylotrophic yeast Pichia pastoris. The protein was expressed in the membrane fraction as a stable 170 kDa protein. Its nucleotide binding and hydrolysis properties were investigated using the photoactive ATP analogue 8-azido-[alpha-(32)P]ATP and compared to those of the drug efflux pump MRP1. rMrp6 can bind 8-azido-[alpha-(32)P]ATP in a Mg(2+)-dependent and EDTA-sensitive fashion. Co(2+), Mn(2+), and Ni(2+) can also support 8-azido-[alpha-(32)P]ATP binding by rMrp6 while Ca(2+), Cd(2+), and Zn(2+) cannot. Under hydrolysis conditions (at 37 degrees C), the phosphate analogue beryllium fluoride (BeF(x)()) can stimulate trapping of the 8-azido-[alpha-(32)P]adenosine nucleotide in rMrp6 (and in MRP1) in a divalent cation-dependent and temperature-sensitive fashion. This suggests active ATPase activity, followed by trapping and photo-cross-linking of the 8-azido-[alpha-(32)P]ADP to the protein. By contrast to MRP1, orthovanadate-stimulated nucleotide trapping in rMrp6 does not occur in the presence of Mg(2+) but can be detected with Ni(2+) ions, suggesting structural and/or functional differences between the two proteins. The rMrp6 protein can be specifically photolabeled by a fluorescent photoactive drug analogue, [(125)I]-IAARh123, with characteristics similar to those previously reported for MRP1 (1), and this photolabeling of rMrp6 can be modulated by several structurally unrelated compounds. The P. pastoris expression system has allowed demonstration of ATP binding and ATP hydrolysis by rMrp6. In addition to providing large amounts of active protein for detailed biochemical studies, this system should also prove useful to identify potential rMrp6 substrates in [(125)I]-IAARh123 photolabeling competition studies, as well as to study the molecular basis of PXE mutations, which are most often found in the NBD2 of MRP6.
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