ABCMdb

ABCG2 p.Leu554Pro

Predicted by SNAP2:	A: D (80%), C: D (66%), D: D (91%), E: D (91%), F: N (53%), G: D (85%), H: D (91%), I: D (53%), K: D (91%), M: N (57%), N: D (91%), P: D (95%), Q: D (91%), R: D (91%), S: D (91%), T: D (91%), V: D (66%), W: D (91%), Y: D (80%),
Predicted by PROVEAN:	A: D, C: D, D: D, E: D, F: N, G: D, H: D, I: N, K: D, M: N, N: D, P: D, Q: D, R: D, S: D, T: D, V: N, W: D, Y: D,

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[hide] Dominant-negative inhibition of breast cancer resi... Int J Cancer. 2002 Feb 10;97(5):626-30. Kage K, Tsukahara S, Sugiyama T, Asada S, Ishikawa E, Tsuruo T, Sugimoto Y
Dominant-negative inhibition of breast cancer resistance protein as drug efflux pump through the inhibition of S-S dependent homodimerization.
Int J Cancer. 2002 Feb 10;97(5):626-30., 2002-02-10 [PMID:11807788]

Abstract [show]
Breast cancer resistance protein (BCRP) is a half-molecule ABC transporter highly expressed in mitoxantrone-resistant cells. In our study we established PA317 transfectants expressing Myc-tagged BCRP (MycBCRP) or HA-tagged BCRP (HABCRP). The exogenous BCRP protein migrated as a 70-kDa protein in SDS-PAGE under reducing condition, but migrated as a 140-kDa complex in the absence of reducing agents. The 140-kDa BCRP complex was heat-stable but dissociated into 70-kDa BCRP with the addition of 2-mercaptoethanol. The 140-kDa BCRP complex was immunoprecipitated with anti-Myc antibody from the lysates of PA317 cells double-transfected with MycBCRP and HABCRP. The 140-kDa complex reacted with anti-HA and anti-BCRP antibodies and after the addition of reducing agents, a 70-kDa protein reacting with anti-Myc, anti-HA and anti-BCRP antibodies was detected. These results clearly indicate that BCRP forms a homodimer bridged by disulfide bonds. To assess the possible dominant-negative inhibition of BCRP drug efflux pump, various mutant BCRP cDNAs were isolated by PCR mutagenesis. First, mutant BCRP cDNAs were introduced to parental PA317 cells and tested for their function as drug-resistance genes. Next, inactive BCRP cDNA clones were introduced to MycBCRP-transfected cells and tested for the ability to lower drug resistance. Among the 8 inactive mutant cDNA clones tested, HABCRP cDNA clone 15 with an amino acid change from Leu to Pro at residue 554 in the fifth transmembrane domain of BCRP partially reversed the drug resistance of MycBCRP-transfected cells. These results suggest that homodimer formation is essential for BCRP drug resistance, implicating this dominant-negative inhibition as a new strategy to circumvent drug resistance.

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9 Next, inactive BCRP cDNA clones were introduced to MycBCRP-transfected cells and tested for the ability to lower drug resistance. Among the 8 inactive mutant cDNA clones tested, HABCRP cDNA clone 15 with an amino acid change from Leu to Pro at residue 554 in the fifth transmembrane domain of BCRP partially reversed the drug resistance of MycBCRP-transfected cells. Login to comment
94 Next, these 8 inactive HABCRP cDNA clones were introduced to PA/MycBCRP to examine the ability to reverse drug resistance. Among the 8 inactive HABCRP cDNA clones tested, HABCRP cDNA clone 15 (HABCRP-15) that had an amino acid substitution from Leu to Pro at residue 554 reversed the drug resistance of MycBCRP. Login to comment
138 HABCRP-15 contained an amino acid substitution from Leu to Pro at residue 554 in the putative 5th transmembrane domain. Login to comment

[hide] Multidrug resistance mediated by the breast cancer... Oncogene. 2003 Oct 20;22(47):7340-58. Doyle LA, Ross DD
Multidrug resistance mediated by the breast cancer resistance protein BCRP (ABCG2).
Oncogene. 2003 Oct 20;22(47):7340-58., 2003-10-20 [PMID:14576842]

Abstract [show]
Observations of functional adenosine triphosphate (ATP)-dependent drug efflux in certain multidrug-resistant cancer cell lines without overexpression of P-glycoprotein or multidrug resistance protein (MRP) family members suggested the existence of another ATP-binding cassette (ABC) transporter capable of causing cancer drug resistance. In one such cell line (MCF-7/AdrVp), the overexpression of a novel member of the G subfamily of ABC transporters was found. The new transporter was termed the breast cancer resistance protein (BCRP), because of its identification in MCF-7 human breast carcinoma cells. BCRP is a 655 amino-acid polypeptide, formally designated as ABCG2. Like all members of the ABC G (white) subfamily, BCRP is a half transporter. Transfection and enforced overexpression of BCRP in drug-sensitive MCF-7 or MDA-MB-231 cells recapitulates the drug-resistance phenotype of MCF-7/AdrVp cells, consistent with current evidence suggesting that functional BCRP is a homodimer. BCRP maps to chromosome 4q22, downstream from a TATA-less promoter. The spectrum of anticancer drugs effluxed by BCRP includes mitoxantrone, camptothecin-derived and indolocarbazole topoisomerase I inhibitors, methotrexate, flavopiridol, and quinazoline ErbB1 inhibitors. Transport of anthracyclines is variable and appears to depend on the presence of a BCRP mutation at codon 482. Potent and specific inhibitors of BCRP are now being developed, opening the door to clinical applications of BCRP inhibition. Owing to tissue localization in the placenta, bile canaliculi, colon, small bowel, and brain microvessel endothelium, BCRP may play a role in protecting the organism from potentially harmful xenobiotics. BCRP expression has also been demonstrated in pluripotential "side population" stem cells, responsible for the characteristic ability of these cells to exclude Hoechst 33342 dye, and possibly for the maintenance of the stem cell phenotype. Studies are emerging on the role of BCRP expression in drug resistance in clinical cancers. More prospective studies are needed, preferably combining BCRP protein or mRNA quantification with functional assays, in order to determine the contribution of BCRP to drug resistance in human cancers.

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82 Furthermore, a dominant-negative mutant of BCRP, with an L554P alteration in the fifth transmembrane domain, was found to inhibit BCRP function partially when cotransfected with BCRP. Login to comment
293 A mutant with an amino-acid change from Leu to Pro at residue 554 in the fifth transmembrane domain of BCRP resulted in the loss of transporter function, and was able to reverse partially the drug resistance of cotransfected wild-type BCRP. Login to comment

[hide] Expression, localization, and functional character... Drug Metab Dispos. 2005 May;33(5):637-43. Epub 2005 Feb 16. Xia CQ, Liu N, Yang D, Miwa G, Gan LS
Expression, localization, and functional characteristics of breast cancer resistance protein in Caco-2 cells.
Drug Metab Dispos. 2005 May;33(5):637-43. Epub 2005 Feb 16., [PMID:15716365]

Abstract [show]
The function of breast cancer resistance protein (BCRP) and its role in drug absorption, distribution, and elimination has recently been evaluated. The objective of the present study was to examine the expression, localization, and functional characteristics of BCRP in Caco-2 cells, a widely used human intestinal epithelial cell model for investigating intestinal drug absorption. The expression of BCRP in Caco-2 cells was measured by Western blotting using the antibody BXP-21. Localization of BCRP was determined by an immunofluorescence technique using both antibodies BXP-21 and BXP-34. The drug efflux function of BCRP was evaluated via the epithelial transport of methotrexate (MTX) and estrone-3-sulfate (E3S) across Caco-2 cell monolayers in the presence or absence of the BCRP inhibitors Ko143 or GF120918 (N-(4-[2-(1,2,3,4-tetrahydro-6,7-dimethoxy-2-isoquinolinyl)ethyl]-phenyl)- 9,10-dihydro-5-methoxy-9-oxo-4-acridine carboxamide). Results from Western blot assay indicated that Caco-2 cells in the late passage (p56) expressed a higher level of BCRP as compared with the level in the early passages (p33). The total amount of BCRP protein did not change after the cells were confluent. Immunofluorescence studies revealed the positive staining of BCRP on the apical membrane of Caco-2 cells but not on the basolateral membrane after cell confluence. MTX and E3S showed a preferential basolateral-toapical (B-to-A) transport across Caco-2 cell monolayers. Both BCRP inhibitors Ko143 and GF120918 increased the apical-to-basolateral (A-to-B) transport but decreased the B-to-A transport of MTX and E3S. Caco-2 cells may therefore be used as an in vitro model to study the transport characteristics of BCRP.

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135 The same group also demonstrates the necessity of homodimerization for the BCRP function when using a dominant-negative mutation of BCRP with a L554P alteration in the fifth transmembrane domain (Kage et al., 2002). Login to comment

[hide] Effect of Walker A mutation (K86M) on oligomerizat... J Cell Sci. 2005 Apr 1;118(Pt 7):1417-26. Epub 2005 Mar 15. Henriksen U, Gether U, Litman T
Effect of Walker A mutation (K86M) on oligomerization and surface targeting of the multidrug resistance transporter ABCG2.
J Cell Sci. 2005 Apr 1;118(Pt 7):1417-26. Epub 2005 Mar 15., 2005-04-01 [PMID:15769853]

Abstract [show]
The ATP binding cassette (ABC) half-transporter ABCG2 (MXR/BCRP/ABCP) is associated with mitoxantrone resistance accompanied by cross-resistance to a broad spectrum of cytotoxic drugs. Here we investigate the functional consequences of mutating a highly conserved lysine in the Walker A motif of the nucleotide binding domain (NBD) known to be critical for ATP binding and/or hydrolysis in ABC transporters. The mutant (ABCG2-K86M) was inactive as expected but was expressed at similar levels as the wild-type (wt) protein. The mutation did not affect the predicted oligomerization properties of the transporter; hence, co-immunoprecipitation experiments using differentially tagged transporters showed evidence for oligomerization of both ABCG2-wt and of ABCG2-wt with ABCG2-K86M. We also obtained evidence that both ABCG2-wt and ABCG2-K86M exist in the cells as disulfide-linked dimers. Moreover, measurement of prazosin-stimulated ATPase activity revealed a dominant-negative effect of ABCG2-K86M on ABCG2-wt function in co-transfected HEK293 cells. This is consistent with the requirement for at least two active NBDs for transporter activity and suggests that the transporter is a functional dimer. Finally, we analyzed targeting of ABCG2-wt and ABCG2-K86M and observed that they localize to two distinct subcellular compartments: ABCG2-wt targets the cell surface whereas ABCG2-K86M is targeted to the Golgi apparatus followed by retrieval to the endoplasmic reticulum. This suggests an as yet unknown role of the NBDs in assisting proper surface targeting of ABC transporters.

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226 Interestingly, a dominant-negative effect on drug sensitivity has been reported for ABCG2 (Kage et al., 2002) upon mutation of Leu554 situated in transmembrane segment 5 to a proline (L554P). Login to comment

[hide] Breast cancer resistance protein: molecular target... Cancer Sci. 2005 Aug;96(8):457-65. Sugimoto Y, Tsukahara S, Ishikawa E, Mitsuhashi J
Breast cancer resistance protein: molecular target for anticancer drug resistance and pharmacokinetics/pharmacodynamics.
Cancer Sci. 2005 Aug;96(8):457-65., [PMID:16108826]

Abstract [show]
Breast cancer resistance protein (BCRP) is a half-molecule ATP-binding cassette transporter that forms a functional homodimer and pumps out various anticancer agents, such as 7-ethyl-10-hydroxycamptothecin, topotecan, mitoxantrone and flavopiridol, from cells. Estrogens, such as estrone and 17beta-estradiol, have been found to restore drug sensitivity levels in BCRP-transduced cells by increasing the cellular accumulation of such agents. Furthermore, synthetic estrogens, tamoxifen derivatives and phytoestrogens/flavonoids have now been identified that can effectively circumvent BCRP-mediated drug resistance. Transcellular transport experiments have shown that BCRP transports sulfated estrogens and various sulfated steroidal compounds, but not free estrogens. The kinase inhibitor gefitinib inhibited the transporter function of BCRP and reversed BCRP-mediated drug resistance both in vitro and in vivo. BCRP-transduced human epidermoid carcinoma A431 (A431/BCRP) and BCRP-transduced human non-small cell lung cancer PC-9 (PC-9/BCRP) cells showed gefitinib resistance. Physiological concentrations of estrogens (10-100 pM) reduced BCRP protein expression without affecting its mRNA levels. Two functional polymorphisms of the BCRP gene have been identified. The C376T (Q126Stop) polymorphism has a dramatic phenotype as active BCRP protein cannot be expressed from a C376T allele. The C421A (Q141K) polymorphism is also significant as Q141K-BCRP-transfected cells show markedly low protein expression levels and low-level drug resistance. Hence, individuals with C376T or C421A polymorphisms may express low levels of BCRP or none at all, resulting in hypersensitivity of normal cells to BCRP-substrate anticancer agents. In summary, both modulators of BCRP and functional single nucleotide polymorphisms within the BCRP gene affect the transporter function of the protein and thus can modulate drug sensitivity and substrate pharmacokinetics and pharmacodynamics in affected cells and individuals.

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53 Among the eight inactive mutant cDNAs, L554P-BCRP, with an amino acid change in TM5, was found to partially reverse drug resistance in MycBCRP-transfected cells (Fig. 1). Login to comment

[hide] Role of the breast cancer resistance protein (ABCG... AAPS J. 2005 May 11;7(1):E118-33. Mao Q, Unadkat JD
Role of the breast cancer resistance protein (ABCG2) in drug transport.
AAPS J. 2005 May 11;7(1):E118-33., [PMID:16146333]

Abstract [show]
The 72-kDa breast cancer resistance protein (BCRP) is the second member of the subfamily G of the human ATP binding cassette (ABC) transporter superfamily and thus also designated as ABCG2. Unlike P-glycoprotein and MRP1, which are arranged in 2 repeated halves, BCRP is a half-transporter consisting of only 1 nucleotide binding domain followed by 1 membrane-spanning domain. Current experimental evidence suggests that BCRP may function as a homodimer or homotetramer. Overexpression of BCRP is associated with high levels of resistance to a variety of anticancer agents, including anthracyclines, mitoxantrone, and the camptothecins, by enhancing drug efflux. BCRP expression has been detected in a large number of hematological malignancies and solid tumors, indicating that this transporter may play an important role in clinical drug resistance of cancers. In addition to its role to confer resistance against chemotherapeutic agents, BCRP actively transports structurally diverse organic molecules, conjugated or unconjugated, such as estrone-3-sulfate, 17beta-estradiol 17-(beta-D-glucuronide), and methotrexate. BCRP is highly expressed in the placental syncytiotrophoblasts, in the apical membrane of the epithelium in the small intestine, in the liver canalicular membrane, and at the luminal surface of the endothelial cells of human brain microvessels. This strategic and substantial tissue localization indicates that BCRP also plays an important role in absorption, distribution, and elimination of drugs that are BCRP substrates. This review summarizes current knowledge of BCRP and its relevance to multidrug resistance and drug disposition.

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171 In addition, a dominant-negative mutant of BCRP with amino acid change from Leu to Pro at position 554 in the TM5 segment was found to have partially reduced the ability to confer resistance to SN-38 and mitoxantrone when cotransfected with wild-type BCRP. Login to comment

[hide] Mutational studies of G553 in TM5 of ABCG2: a resi... Biochemistry. 2006 Apr 25;45(16):5251-60. Polgar O, Ozvegy-Laczka C, Robey RW, Morisaki K, Okada M, Tamaki A, Koblos G, Elkind NB, Ward Y, Dean M, Sarkadi B, Bates SE
Mutational studies of G553 in TM5 of ABCG2: a residue potentially involved in dimerization.
Biochemistry. 2006 Apr 25;45(16):5251-60., 2006-04-25 [PMID:16618113]

Abstract [show]
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.

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233 However, in the case of ABCG2, the inactive L554P mutant was reported to be able to partially reverse the drug resistance of PA317 cells cotransfected with the mutant and wild-type proteins, a result implying that residue 554 is critical for function, yet mutating this residue does not prevent dimerization. Login to comment

[hide] Towards understanding the mechanism of action of t... J Mol Graph Model. 2007 Mar;25(6):837-51. Epub 2006 Aug 30. Li YF, Polgar O, Okada M, Esser L, Bates SE, Xia D
Towards understanding the mechanism of action of the multidrug resistance-linked half-ABC transporter ABCG2: a molecular modeling study.
J Mol Graph Model. 2007 Mar;25(6):837-51. Epub 2006 Aug 30., [PMID:17027309]

Abstract [show]
The ATP-binding cassette protein ABCG2 is a member of a broad family of ABC transporters with potential clinical importance as a mediator of multidrug resistance. We carried out a homology and knowledge-based, and mutationally improved molecular modeling study to establish a much needed structural framework for the protein, which could serve as guidance for further genetic, biochemical, and structural analyses. Based on homology with known structures of both full-length and nucleotide-binding domains (NBD) of ABC transporters and structural knowledge of integral membrane proteins, an initial model of ABCG2 was established. Subsequent refinement to conform to the lipophilic index distributions in the transmembrane domain (TMD) and to the results of site-directed mutagenesis experiments led to an improved model. The complete ABCG2 model consists of two identical subunits facing each other in a closed conformation. The dimeric interface in the nucleotide-binding domain (NBD) involves a characteristic nucleotide sandwich and the interface in the TMD consists of the TM helices 1-3 of one subunit and the helices 5 and 6 of the other. The interface between the NBD and the TMD is bridged by the conserved structural motif between TM2 and TM3, the intracellular domain 1 (ICD1), and the terminal beta-strand (S6) of the central beta-sheet in the NBD. The apparent flexibility of the ICD1 may play a role in transmitting conformational changes from the NBD to the TMD or from the TMD to the NBD.

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182 In sf9 cell, it is expressed on cell surface, but with no ATPase activity [56] L554P TM5 Lowered drug resistance [42] N557D,E TM5 Functional [21] S566Aa ECL (between TM5 and 6) Lowered drug resistance for the cell line [42] N596Q Between TM5 and 6 N-glycosylation site [65] Y605Ca Loop between TM5 and 6 Lowered drug resistance for the cell line [42] D620N Loop between TM5 and 6 SNP polymorphism [22] H630E,L TM6 Functional [21] A632Va TM Lowered drug resistance for the cell line [42] a Mutants not well characterized. Login to comment

[hide] Homology modeling of breast cancer resistance prot... J Struct Biol. 2008 Apr;162(1):63-74. Epub 2007 Dec 15. Hazai E, Bikadi Z
Homology modeling of breast cancer resistance protein (ABCG2).
J Struct Biol. 2008 Apr;162(1):63-74. Epub 2007 Dec 15., [PMID:18249138]

Abstract [show]
BCRP (also known as ABCG2, MXR, and ABC-P) is a member of the ABC family that transports a wide variety of substrates. BCRP is known to play a key role as a xenobiotic transporter. Since discovering its role in multidrug resistance, considerable efforts have been made in order to gain deeper understanding of BCRP structure and function. The recent study was aimed at predicting BCRP structure by creating a homology model. Based on sequence similarity with known structures of full-length, NB and TM domain of ABC transporters, TM, NB, and linker regions of BCRP were defined. The NB domain of BCRP was modeled using MalK as a template. Based on secondary structure prediction of BCRP and comparison of the transmembrane connecting regions of known structures of ABC transporters, the TM domain arrangement of BCRP was established and was found to resemble to that of the recently published crystal structure of Sav1866. Thus, an initial alignment of TM domain of BCRP was established using Sav1866 as a template. This alignment was subsequently refined using constrains derived from secondary structure and TM predictions and the final model was built. Finally, the complete homodimer ABCG2 model was generated using Sav1866 as template. Furthermore, known ligands of BCRP were docked to our model in order to define possible binding sites. The results of molecular dockings of known BCRP substrates to the BCRP model were in agreement with recently published experimental data indicating multiple binding sites in BCRP.

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245 However, in our model, R482 cannot form interaction with rhodamine, but L484 is in interacting distance Table 3 Mutations on BCRP and their effect on its function Mutation Effect/results Reference V12M Did not effect Hemato and MTX transport Tamura et al. (2006) G51C Did not effect Hemato and MTX transport Tamura et al. (2006) K86M Inactivates transporter (dominant negative effect on ATPase activity); alters subcellular distribution Henriksen et al. (2005a) K86M Transporter inactive, but still able to bind ATP Ozvegy et al. (2002) Q126stop Defective porphyrin transport Tamura et al. (2006) Q141K Did not effect Hemato and MTX transport Tamura et al. (2006) T153M Did not effect Hemato and MTX transport Tamura et al. (2006) Q166E Did not effect Hemato and MTX transport Tamura et al. (2006) I206L Did not effect Hemato and MTX transport Tamura et al. (2006) F208S Defective porphyrin transport Tamura et al. (2006) S248P Defective porphyrin transport Tamura et al. (2006) E334stop Defective porphyrin transport Tamura et al. (2006) F431L Effects MTX transport Tamura et al. (2006) S441N Defective porphyrin transport Tamura et al. (2006) E446-mutants No drug resistance Miwa et al. (2003) R482G, R482T Effects MTX transport Tamura et al. (2006) R482T Substrate drug transport and inhibitor efficiency is not mediated by changes in drug-binding Pozza et al. (2006) R482G, R482T Substitution influence the substrate specificity of the transporter Ozvegy et al. (2002) R482G, R482T Altered substrate specificity Honjo et al. (2001) R482G Methotrexate not transported Chen et al. (2003b) Mitomo et al. (2003) R482G Resistance to hydrophilic antifolates in vitro, G482-ABCG2 mutation confers high-level resistance to various hydrophilic antifolates Shafran et al., (2005) R482G Three distinct drug, binding sites Clark et al. (2006) R482G Altered substrate specificity, granulocyte maturation uneffected Ujhelly et al. (2003) R482 mutants Higher resistance to mitoxantrone and doxorubicin than wt Miwa et al. (2003) R482X Affects substrate transport and ATP hydrolysis but not substrate binding Ejendal et al. (2006) F489L Impaired porphyrin transport Tamura et al. (2006) G553L; G553E Impaired trafficing, expression, and N-linked glycosylation Polgar et al. (2006) L554P Dominant negative effect on drug sensitivity Kage et al. (2002) N557D Resistance to MTX, but decreased transport of SN-38; N557E no change in transport compared to wt Miwa et al. (2003) F571I Did not effect Hemato and MTX transport Tamura et al. (2006) N590Y Did not effect Hemato and MTX transport Tamura et al. (2006) C592A Impaired function and expression Henriksen et al. (2005b) C592A/C608A Restored plasma mb expression; MTX transport normal, BODIPY-prazosin impaired Henriksen et al. (2005b) C603A Disulfide bridge; no functional or membrane targeting change Henriksen et al. (2005b) C608A Impaired function and expression Henriksen et al. (2005b) D620N Did not effect Hemato and MTX transport Tamura et al. (2006) H630X No change in transport Miwa et al. (2003) Cand N-terminal truncated Impaired trafficing Takada et al. (2005) with the ligand. Login to comment

[hide] Different roles of TM5, TM6, and ECL3 in the oligo... Biochemistry. 2012 May 1;51(17):3634-41. Epub 2012 Apr 19. Mo W, Qi J, Zhang JT
Different roles of TM5, TM6, and ECL3 in the oligomerization and function of human ABCG2.
Biochemistry. 2012 May 1;51(17):3634-41. Epub 2012 Apr 19., [PMID:22497316]

Abstract [show]
ABCG2 is a member of the ATP-binding cassette transporter superfamily, and its overexpression causes multidrug resistance (MDR) in cancer chemotherapy. ABCG2 may also protect cancer stem cells by extruding cytotoxic materials. ABCG2 has previously been shown to exist as a high-order homo-oligomer consisting of possibly 8-12 subunits, and the oligomerization domain was mapped to the C-terminal domain, including TM5, ECL3, and TM6. In this study, we further investigate this domain in detail for the role of each segment in the oligomerization and drug transport function of ABCG2 using domain swapping and site-directed mutagenesis. We found that none of the three segments (TM5, TM6, and ECL3) is essential for the oligomerization activity of ABCG2 and that any one of these three segments in the full-length context is sufficient to support ABCG2 oligomerization. While TM5 plays an important role in the drug transport function of ABCG2, TM6 and ECL3 are replaceable. Thus, each segment in the TM5-ECL3-TM6 domain plays a distinctive role in the oligomerization and function of ABCG2.

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178 For example, it has been shown that the L554P mutation in TM5 reduces the drug resistance function of ABCG2.27 TM5 has also been found to contain a steroid binding element,28 further suggesting that TM5 may be important in substrate recognition and binding. Login to comment