The Role of Half-Transporters in Multidrug Resistance

ATP-binding cassette proteins comprise a superfamily of transporter proteins, a subset of which have been implicated in multidrug resistance. Although P-glycoprotein was described over 15 years ago, the recent expansion in the number of transporters identified has prompted renewed interest in the role of drug transporters in clinical drug resistance. These newly identified transporters include additional members of the MRP family, ABC2, and a new half-transporter, MXR/BCRP/ABCP1. This half-transporter confers high levels of resistance to mitoxantrone, anthracyclines, and the camptothecins SN-38 and topotecan. At 72 kDa, MXR localizes to the plasma membrane in cells which highly overexpress the protein either through gene amplification or though gene rearrangement. Future studies will be aimed at identifying an inhibitor, and attempting to translate recognition of this new transporter into a target for anticancer treatment.     

Characterization of oligomeric human half-ABC transporter ATP-binding cassette G2

Human ATP-binding cassette G2 (ABCG2, also known as mitoxantrone resistance protein, breast cancer-resistance protein, ABC placenta) is a member of the superfamily of ATP-binding cassette (ABC) transporters that have a wide variety of substrates. Overexpression of human ABCG2 in model cancer cell lines causes multidrug resistance by actively effluxing anticancer drugs. Unlike most of the other ABC transporters which usually have two nucleotide-binding domains and two transmembrane domains, ABCG2 consists of only one nucleotide-binding domain followed by one transmembrane domain. Thus, ABCG2 has been thought to be a half-transporter that may function as a homodimer. In this study, we characterized the oligomeric feature of human ABCG2 using non-denaturing detergent perfluoro-octanoic acid and Triton X-100 in combination with gel filtration, sucrose density gradient sedimentation, and gel electrophoresis. Unexpectedly, we found that human ABCG2 exists mainly as a tetramer, with a possibility of a higher form of oligomerization. Monomeric and dimeric ABCG2 did not appear to be the major form of the protein. Further immunoprecipitation analysis showed that the oligomeric ABCG2 did not contain any other proteins. Taken together, we conclude that human ABCG2 likely exists and functions as a homotetramer.     

ABCG2 confers resistance to indolocarbazole compounds by ATP-dependent transport

The ABC half-transporter, ABCG2, is known to confer resistance to chemotherapeutic agents including indolocarbazole derivatives. MCF7 cells were introduced by either wild type ABCG2 (ABCG2-482R) or mutant ABCG2 (-482T), whose amino acid at position 482 is substituted to threonine from arginine, and their cross-resistance pattern was analyzed. Although this amino acid substitution seems to affect cross-resistance patterns, both 482T- and 482R-transfectants showed strong resistance to indolocarbazoles, confirming that ABCG2 confers resistance to them. For further characterization of ABCG2-mediated transport, we investigated indolocarbazole compound A (Fig. 1) excretion in cell-free system. Compound A was actively transported in membrane vesicles prepared from one of the 482T- transfectants and its uptake was supported by hydrolysis of various nucleoside triphosphates. This transport was inhibited completely by the other indolocarbazole compound, but not by mitoxantrone, implying that the binding site of mitoxantrone or the transport mechanisms for mitoxantrone is different from those of indolocarbazoles. These results showed that ABCG2 confers resistance to indolocarbazoles by transporting them in an energy-dependent manner.     

Functional characterization of the human multidrug transporter, ABCG2, expressed in insect cells.

ABCG2 (also called MXR (3), BCRP (4), or ABCP (5) is a recently-identified ABC half-transporter, which causes multidrug resistance in cancer. Here we report that the expression of the ABCG2 protein in Sf9 insect cells resulted in a high-capacity, vanadate-sensitive ATPase activity in isolated membrane preparations. ABCG2 was expressed underglycosylated, and its ATPase activity was stimulated by daunorubicin, doxorubicin, mitoxantrone, prazosin and rhodamine 123, compounds known to be transported by this protein. ABCG2-ATPase was inhibited by low concentrations of Na-orthovanadate, N-ethylmaleimide and cyclosporin A. Verapamil had no effect, while Fumitremorgin C, reversing ABCG2-dependent cancer drug resistance, strongly inhibited this ATPase activity. The functional expression of ABCG2 in this heterologous system indicates that no additional partner protein is required for the activity of this multidrug transporter, probably working as a homodimer. We suggest that the Sf9 cell membrane ATPase system is an efficient tool for examining the interactions of ABCG2 with pharmacological agents.     

N-Linked glycosylation of the human ABC transporter ABCG2 on asparagine 596 is not essential for expression, transport activity, or trafficking to the plasma membrane

The human ATP-binding cassette half-transporter ABCG2 is a 72 kDa plasma membrane protein that can confer multidrug resistance to cells in culture when overexpressed. Both transiently and stably expressed ABCG2 are glycosylated, and treatment with peptide N-glycosidase F reduces the apparent molecular mass on SDS-PAGE gels to approximately 60 kDa. Sequence analysis revealed three potential N-linked glycosylation sites in human ABCG2 at amino acids 418, 557, and 596. Site-directed mutagenesis experiments, in which each Asn was changed to Gln independently, revealed that only asparagine 596 is N-linked glycosylated. These data provide the first direct identification of the modified residue in ABCG2 and evidence for the localization of loop 5 to the extracellular space, previously only predicted from hydropathy analysis. Immunoblot and pulse-chase analyses revealed that the glycosylation-deficient ABCG2 (N596Q) variant and the glycosylated parent transporter are expressed equivalently at steady state and have similar half-lives. Cell surface analysis of ABCG2 expression showed comparable amounts of the N596Q variant present at the plasma membrane compared to the glycosylated ABCG2 protein. The ABCG2 (N596Q) variant is also functional, demonstrating rhodamine 123 transport in intact cells comparable to that in cells expressing glycosylated ABCG2. Furthermore, in crude membrane preparations, neither the basal nor the prazosin-stimulated ( approximately 2-fold) ATPase activities of ABCG2 (N596Q) were affected compared to glycosylated ABCG2. Although subtle defects in transporter trafficking and function may exist, these data taken together suggest that N-glycosylation at arginine 596 is not essential for the expression, trafficking to the plasma membrane, or the overall function of ABCG2.     

A novel ATP-binding cassette transporter from Leishmania is involved in transport of phosphatidylcholine analogues and resistance to alkyl-phospholipids

ATP-binding cassette (ABC) transporters represent an important family of membrane proteins involved in drug resistance and other biological activities. The present work reports the characterization of the first ABC subfamily G (ABCG)-like transporter, LiABCG4, in the protozoan parasite Leishmania. LiABCG4 localized mainly to the parasite plasma membrane. Overexpression of this half-transporter reduced the accumulation of phosphatidylcholine analogues and conferred resistance to alkyl-phospholipids. Likewise, when expressed in Saccharomyces cerevisiae, the protein localized to the yeast plasma membrane and conferred resistance to alkyl-phospholipids. Post-Golgi secretory vesicles isolated from a LiABCG4-overexpressing yeast mutant contained the leishmanial ABC transporter and exhibited ATP-dependent, vanadate-sensitive transport of phosphatidylcholine analogues from the cytosolic to the lumenal leaflet of the vesicle membrane. Cross-linking showed dimerization of LiABCG4. These results suggest that LiABCG4 is involved in the active transport of phosphatidylcholine and resistance to alkyl-phospholipids in Leishmania.     

Identification of intra- and intermolecular disulfide bridges in the multidrug resistance transporter ABCG2

ABCG2 is an ATP binding cassette (ABC) half-transporter that plays a key role in multidrug resistance to chemotherapy. ABCG2 is believed to be a functional homodimer that has been proposed to be linked by disulfide bridges. We have investigated the structural and functional role of the only three cysteines predicted to be on the extracellular face of ABCG2. Upon mutation of Cys-592 or Cys-608 to alanine (C592A and C608A), ABCG2 migrated as a dimer in SDS-PAGE under non-reducing conditions; however, mutation of Cys-603 to Ala (C603A) caused the transporter to migrate as a single monomeric band. Despite this change, C603A displayed efficient membrane targeting and preserved transport function. Because the transporter migrated as a dimer in SDS-PAGE, when only Cys-603 was present (C592A-C608A), the data suggest that Cys-603 forms a symmetrical intermolecular disulfide bridge in the ABCG2 homodimer that is not essential for protein expression and function. In contrast to C603A, both C592A and C608A displayed impaired membrane targeting and function. Moreover, when only Cys-592 or Cys-608 were present (C592A/C603A and C603A/C608A), the transporter displayed impaired plasma membrane expression and function. The combined mutation (C592A/C608A) partially restored plasma membrane expression; however, although transport of mitoxantrone was almost normal, we observed impairment of BODIPY-prazosin transport. This supports the conclusion that Cys-592 and Cys-608 form an intramolecular disulfide bridge in ABCG2 that is critical for substrate specificity. Finally, mutation of all three cysteines simultaneously resulted in low expression and no measurable function. Altogether, our data are consistent with a scenario in which an inter- and an intramolecular disulfide bridge together are of fundamental importance for the structural and functional integrity of ABCG2.     

Mutational studies of G553 in TM5 of ABCG2: a residue potentially involved in dimerization

ABCG2 is an ATP-binding cassette half-transporter conferring resistance to chemotherapeutic agents such as mitoxantrone, irinotecan, and flavopiridol. With its one transmembrane and one ATP-binding domain, ABCG2 is thought to homodimerize for function. One conserved region potentially involved in dimerization is a three-amino acid sequence in transmembrane segment 5 (residues 552-554). Mutations in the corresponding residues in the Drosophila white protein (an orthologue of ABCG2) are thought to disrupt heterodimerization. We substituted glycine 553 with leucine (G553L) followed by stable transfection in HEK 293 cells. The mutant was not detectable on the cell surface, and markedly reduced protein expression levels were observed by immunoblotting. A deficiency in N-linked glycosylation was suggested by a reduction in molecular mass compared to that of the 72 kDa wild-type ABCG2. Similar results were observed with the G553E mutant. Confocal microscopy demonstrated mostly ER localization of the G553L mutant in HEK 293 cells, even when coexpressed with the wild-type protein. Despite its altered localization, the G553L and G553E mutants were cross-linked using amine-reactive cross-linkers with multiple arm lengths, suggesting that the monomers are in the proximity of each other but are unable to complete normal trafficking. Interestingly, when expressed in Sf9 insect cells, G553L moves to the cell membrane but is unable to hydrolyze ATP or transport the Hoechst dye. Still, when coexpressed, the mutant interferes with the Hoechst transport activity of the wild-type protein. These data show that glycine 553 is important for protein trafficking and are consistent with, but do not yet prove, its involvement in ABCG2 homodimerization.     

ABCG2 -- a transporter for all seasons

The human ABCG2 (ABCP/MXR/BCRP) protein is a recently recognized ABC half-transporter, which forms homodimers in the plasma membrane and actively extrudes a wide variety of chemically unrelated compounds from the cells. This protein protects our cells and tissues against various xenobiotics, with a crucial role in the intestine, liver, placenta, and the blood-brain barrier. Moreover, ABCG2 seems to have a key function in stem cell protection/regulation, and also in hypoxic defense mechanisms. Widely occurring single nucleotide polymorphisms in ABCG2 may affect absorption and distribution, altering the effectiveness and toxicity of drugs in large populations. At the clinics, overexpression of ABCG2 in tumor cells confers cancer multidrug resistance to a variety of newly developed anticancer agents. On the other hand, specific substrate mutants of ABCG2 are advocated for use as selectable markers in stem-cell based gene therapy.     

Characterization of drug transport,ATP hydrolysis,and nucleotide trapping by the human ABCG2 multidrug transporter. Modulation of substrate specificity by a point mutation

The overexpression of the human ATP-binding cassette half-transporter, ABCG2 (placenta-specific ABC transporter, mitoxantrone resistance-associated protein, breast cancer resistance protein), causes multidrug resistance in tumor cells. An altered drug resistance profile and substrate recognition were suggested for wild-type ABCG2 and its mutant variants (R482G and R482T); the mutations were found in drug-selected tumor cells. In order to characterize the different human ABCG2 transporters without possible endogenous dimerization partners, we expressed these proteins and a catalytic center mutant (K86M) in Sf9 insect cells. Transport activity was followed in intact cells, whereas the ATP binding and hydrolytic properties of ABCG2 were studied in isolated cell membranes. We found that the K86M mutant had no transport or ATP hydrolytic activity, although its ATP binding was retained. The wild-type ABCG2 and its variants, R482G and R482T, showed characteristically different drug and dye transport activities; mitoxantrone and Hoechst 33342 were transported by all transporters, whereas rhodamine 123 was only pumped by the R482G and R482T mutants. In each case, ABCG2-dependent transport was blocked by the specific inhibitor, fumitremorgin C. A relatively high basal ABCG2-ATPase, inhibited by fumitremorgin C, was observed in all active proteins, but specific drug stimulation could only be observed in the case of R482G and R482T mutants. We found that ABCG2 is capable of a vanadate-dependent adenine nucleotide trapping. Nucleotide trapping was stimulated by the transported compounds in the R482G and R482T variants but not in the wild-type ABCG2. These experiments document the applicability of the Sf9 expression system for parallel, quantitative examination of the specific transport and ATP hydrolytic properties of different ABCG2 proteins and demonstrate significant differences in their substrate interactions.     

半分子转运蛋白ABCG2的肿瘤多药耐药性研究及其应用

肿瘤常对临床上传统使用的多种化学治疗显示其内源性或获得性的药物耐受性即多药耐药性(multidrug resistance,MDR)．这种多药耐药性主要是由一类称为ABC(ATP-binding cassette)转运体蛋白超家族的跨膜蛋白引起的,它们结合并利用水解ATP提供的能量来转运药物,导致肿瘤细胞呈现抗药性．半分子转运蛋白ABCG2是近年来才发现的可归于ABC转运体大家族中的一个新成员,在肠、肝、胎盘和血脑屏障等部位大量表达,与全分子转运蛋白如P-gp (P-glycoprotein)和多药耐药蛋白(multi-drug resistance protein,MRP)相似,可以主动地把具有不同化学结构和作用于细胞内不同靶位点的化疗药物泵出胞外,从而引起肿瘤对多种抗癌药物(包括最新开发的药物)产生抗性．最近的一些十分有趣的研究还表明,ABCG2可能与干细胞分化状态和保护干细胞发育过程中免受周围环境的影响有关,而且还发现,它在侧群骨髓和神经干细胞内大量存在,因此,ABCG2可能在基因治疗中作为选择性的蛋白质标记正受到研究者们的极大关注．同时,ABCG2的单核苷酸多态性影响其结合并转运不同的底物/药物．鉴于ABCG2在肿瘤抗药性研究中的重要性以及它的一些新功能的初步研究表明,对ABCG2的生物学功能和作用机理以及在医学实践中的应用研究必将受到更大的关注．主要阐述了半分子ABC转运蛋白ABCG2的发现、重要的生化特性和生理功能及其相关的新研究进展和问题．     

Flow cytometric analysis of breast cancer resistance protein expression and function

BACKGROUND: The breast cancer resistance protein (BCRP) is an ATP-binding cassette (ABC) half-transporter that mediates energy-dependent drug efflux. Assessing the clinical relevance of the BCRP will require sensitive and specific methods for detecting its expression and function that allow high-volume specimen throughput and employ widely available instrumentation. METHODS: The BXP-34 and BXP-21 monoclonal antibodies were evaluated for flow cytometric detection of BCRP expression. The modulation of efflux of rhodamine-123, 3,3'-diethyloxacarbocyanine iodide, doxorubicin, and mitoxantrone by fumitremorgin C was studied as an assay for BCRP function in BCRP-overexpressing cell lines and controls. RESULTS: BXP-34 and BXP-21 allowed detection of BCRP expression by flow cytometry in all BCRP-expressing cell lines. Mitoxantrone was the only substrate transported by BCRP in all lines, and with mitoxantrone at a 3-microM concentration, light emission (>670 nm) caused by excitation at 488 nm was sufficiently intense to allow detection of differences in retention associated with low levels of BCRP expression. CONCLUSIONS: Immunophenotyping with BXP-21 or BXP-34 and fumitremorgin C modulation of mitoxantrone retention allow detection of BCRP expression and function by flow cytometry with standard instrumentation. These assays will facilitate determination of the role of BCRP in clinical drug resistance.     

ABCG2 Transports and Transfers Heme to Albumin through Its Large Extracellular Loop

ABCG2 is an ATP-binding cassette (ABC) transporter preferentially expressed by immature human hematopoietic progenitors. Due to its role in drug resistance, its expression has been correlated with a protection role against protoporhyrin IX (PPIX) accumulation in stem cells under hypoxic conditions. We show here that zinc mesoporphyrin, a validated fluorescent heme analog, is transported by ABCG2. We also show that the ABCG2 large extracellular loop ECL3 constitutes a porphyrin-binding domain, which strongly interacts with heme, hemin, PPIX, ZnPPIX, CoPPIX, and much less efficiently with pheophorbide a, but not with vitamin B12. K_d values are in the range 0.5–3.5 μm, with heme displaying the highest affinity. Nonporphyrin substrates of ABCG2, such as mitoxantrone, doxo/daunorubicin, and riboflavin, do not bind to ECL3. Single-point mutations H583A and C603A inside ECL3 prevent the binding of hemin but hardly affect that of iron-free PPIX. The extracellular location of ECL3 downstream from the transport sites suggests that, after membrane translocation, hemin is transferred to ECL3, which is strategically positioned to release the bound porphyrin to extracellular partners. We show here that human serum albumin could be one of these possible partners as it removes hemin bound to ECL3 and interacts with ABCG2, with a K_d of about 3 μm.     

Arginine 383 is a crucial residue in ABCG2 biogenesis

ABCG2 is an ATP-binding cassette half-transporter initially identified in multidrug-resistant cancer cell lines and recently suggested to play an important role in pharmacokinetics. Here we report studies of a conserved arginine predicted to localize near the cytoplasmic side of TM1. First, we determined the effect of losing charge and bulk at this position via substitutions with glycine and alanine. The R383G mutant when transfected into HEK cells was not detectable on immunoblot or by functional assay, while the R383A mutant exhibited detectable but significantly decreased levels compared to wild-type, partial retention in the ER and altered glycosylation. Efflux of the ABCG2-substrates mitoxantrone and pheophorbide a was observed. Our experiments suggested rapid degradation of the R383A mutant by the proteasome via a kifunensine-insensitive pathway. Interestingly, overnight treatment of the R383A mutant with mitoxantrone assisted in protein maturation as evidenced by a shift to the N-glycosylated form. The R383A mutant when expressed in insect cells, though detected on the surface, had no measurable ATPase activity. In addition, substitution with the positively charged lysine resulted in significantly decreased protein expression levels in HEK cells, while retaining function. In conclusion, arginine 383 is a crucial residue for ABCG2 biogenesis, where even the most conservative mutations have a large impact.     

Reversal of ABCG2-mediated multidrug resistance by human cathelicidin and its analogs in cancer cells

Multidrug resistance (MDR) of cancer cells to a wide spectrum of anticancer drugs is a major obstacle to successful chemotherapy. It is usually mediated by the overexpression of one of the three major ABC transporters actively pumping cytotoxic drugs out of the cells. There has been great interest in the search for inhibitors toward these transporters with an aim to circumvent resistance. This is usually achieved by screening from natural product library and the subsequent structural modifications. This study reported the reversal of ABCG2-mediated MDR in drug-selected resistant cancer cell lines by a class of host defense antimicrobial peptides, the human cathelicidin LL37 and its fragments. The effective human cathelicidin peptides (LL17-32 and LL13-37) were found to increase the accumulation of mitoxantrone in cancer cell lines with ABCG2 overexpression, thereby circumventing resistance to mitoxantrone. At the effective concentrations of the cathelicidin peptides, cell proliferation of the parental cells without elevated ABCG2 expression was not affected. Result from drug efflux and ATPase assays suggested that both LL17-32 and LL13-37 interact with ABCG2 and inhibit its transport activity in an uncompetitive manner. The peptides were also found to downregulate ABCG2 protein expression in the resistant cells, probably through a lysosomal degradation pathway. Our data suggest that the human cathelicidin may be further developed for sensitizing resistant cancer cells to chemotherapy.     

Design,synthesis and biological evaluation of benzamide and phenyltetrazole derivatives with amide and urea linkers as BCRP inhibitors

Breast cancer resistant protein (BCRP/ABCG2), a 72 kDa plasma membrane transporter protein is a member of ABC transporter superfamily. Increased expression of BCRP causes increased efflux and therefore, reduced intracellular accumulation of many unrelated chemotherapeutic agents leading to multidrug resistance (MDR). A series of 31 benzamide and phenyltetrazole derivatives with amide and urea linkers has been synthesized to serve as potential BCRP inhibitors in order to overcome BCRP-mediated MDR. The target derivatives were tested for their cytotoxicity and reversal effects in human non-small cell lung cancer cell line H460 and mitoxantrone resistant cell line H460/MX20 using the MTT assay. In the benzamide series, compounds 6 and 7 exhibited a fold resistance of 1.51 and 1.62, respectively at 10 µM concentration which is similar to that of FTC, a known BCRP inhibitor. Compounds 27 and 31 were the most potent analogues in the phenyltetrazole series with amide linker with a fold resistance of 1.39 and 1.32, respectively at 10 µM concentration. For the phenyltetrazole series with urea linker, 38 exhibited a fold resistance of 1.51 which is similar than that of FTC and is the most potent compound in this series. The target compounds did not exhibit reversal effect in P-gp overexpressing resistant cell line SW620/Ad300 suggesting that they are selective BCRP inhibitors.     

Subcellular localization of Nm23/NDPK A and B isoforms: a reflection of their biological function?

ABCG2 is a half-transporter initially described in multidrug-resistant cancer cells and lately identified as an important factor in the pharmacokinetics of its substrates. Q141K is by far the most intensively studied single nucleotide polymorphism of ABCG2 with potential clinical relevance. Here we used stably transfected HEK cells to study the Q141K polymorphism together with the deletion of amino acids 315–316, which were recently reported to coexist in two cancer cell lines (A549 and SK-OV-3). Functional studies confirmed our previous report that when normalized to surface expression, Q141K has impaired transport of mitoxantrone. This result was extended to include the ABCG2-specific substrate pheophorbide a. While we found no functional consequence of deleting amino acids 315 and 316, we did find that the deletion mutant is no longer recognized by the BXP-21 antibody. We conclude that amino acids 315 and 316 form part of the epitope for the BXP-21 antibody.     

Single amino acid (482) variants of the ABCG2 multidrug transporter: major differences in transport capacity and substrate recognition

The human ABCG2 protein is an ATP binding cassette half-transporter, which protects our cells and tissues against various xenobiotics, while overexpression of ABCG2 in tumor cells confers multidrug resistance. It has been documented that single amino acid changes at position 482 resulted in altered drug resistance and transport capacity. In this study, we have generated nine Arg-482 mutants (G, I, M, S, T, D, N, K, Y) of ABCG2, and expressed them in insect cells. All ABCG2 variants showed cell surface expression and, in isolated membranes, an ABCG2-specific ATPase activity. When methotrexate accumulation was measured in inside-out membrane vesicles, this transport was supported only by the wild-type ABCG2. In intact cells, mitoxantrone was transported by all ABCG2 variants, except by R482K. Rhodamine 123 was extruded by most of the mutants, except by R482K, Y and by wild-type ABCG2. Hoechst 33342 was pumped out from cells expressing the wild-type and all Arg-482 variants, but not from those expressing R482K and Y. Our study demonstrates that the substrate specificity of the Arg (wild-type) form is unique and that amino acid replacements at position 482 induce major alterations in both the transport activity and substrate specificity of this protein.     

Single amino acid (482) variants of the ABCG2 multidrug transporter: major differences in transport capacity and substrate recognition

The human ABCG2 protein is an ATP binding cassette half-transporter, which protects our cells and tissues against various xenobiotics, while overexpression of ABCG2 in tumor cells confers multidrug resistance. It has been documented that single amino acid changes at position 482 resulted in altered drug resistance and transport capacity. In this study, we have generated nine Arg-482 mutants (G, I, M, S, T, D, N, K, Y) of ABCG2, and expressed them in insect cells. All ABCG2 variants showed cell surface expression and, in isolated membranes, an ABCG2-specific ATPase activity. When methotrexate accumulation was measured in inside-out membrane vesicles, this transport was supported only by the wild-type ABCG2. In intact cells, mitoxantrone was transported by all ABCG2 variants, except by R482K. Rhodamine 123 was extruded by most of the mutants, except by R482K, Y and by wild-type ABCG2. Hoechst 33342 was pumped out from cells expressing the wild-type and all Arg-482 variants, but not from those expressing R482K and Y. Our study demonstrates that the substrate specificity of the Arg (wild-type) form is unique and that amino acid replacements at position 482 induce major alterations in both the transport activity and substrate specificity of this protein.     

Fluorescence resonance energy transfer (FRET) analysis demonstrates dimer/oligomer formation of the human breast cancer resistance protein (BCRP/ABCG2) in intact cells

The human breast cancer resistance protein (BCRP/ABCG2) is a half ATP-binding cassette (ABC) efflux transporter that plays an important role in drug resistance and disposition. Although BCRP is believed to function as a homodimer or homooligomer, this has not been demonstrated in vivo in intact cells. Therefore, in the present study, we investigated dimer/oligmer formation of BCRP in intact cells. Wild-type BCRP and the mutant C603A were attached to cyan or yellow fluorescence protein and expressed in HEK293 cells by transient transfection. Protein levels, cell surface expression, and efflux activities of wild-type and mutant BCRP were determined by immunoblotting, 5D3 antibody binding, and flow cytometric efflux assay, respectively. Dimer/oligomer formation of BCRP in intact cells was analyzed using fluorescence resonance energy transfer (FRET) microscopy. Wild-type BCRP and C603A were expressed in HEK293 cells at comparable levels. C603A was predominantly expressed in the plasma membrane as was wild-type protein. Furthermore, C603A retained the same mitoxantrone efflux activity and the ability of dimer/oligmer formation as wild-type BCRP. Finally, cross-linking experiments yielded data consistent with the FRET analysis. In conclusion, we have, for the first time, demonstrated that BCRP can form a dimer/oligomer in vivo in intact cells using the FRET technique. We have also shown that Cys⁶⁰³ alone does not seem to be essential for dimer/oligomer formation of BCRP.