Multidrug Resistance-Associated Protein MRP1 Expression in Human Gliomas: Chemosensitization to Vincristine and Etoposide by Indomethacin in Human Glioma Cell Lines Overexpressing MRP1

The 190 kDa multidrug resistance protein MRP1 is likely to be involved in the multidrug resistance phenotype of human gliomas. MRP1 expression was evaluated in surgical tumor samples from 17 patients with gliomas. In addition, the impact of the MRP's inhibitor, indomethacin, on the chemosensitivity to etoposide (VP16) and vincristine (VCR) of two glioblastoma cell lines expressing MRP1 (GL15 and 8MG) was investigated. When evaluated in tumor samples, MRP1 expression was observed in all of them with more than 90% of stained tumor cells in 14/15 high-grade gliomas. MRP1 was also strongly expressed at the membrane of the vascular endothelial cells in the same 14 tumor samples, suggesting that the permeability to anticancer drugs could be also limited across brain tumor vessels. At concentrations comprised between 5 and 50 microM, indomethacin significantly increased the cytotoxic effect of etoposide in both cell lines but it was more efficient in increasing the cytotoxicity of VCR on GL15 cells, as compared with 8MG cells. These results suggest that the association of indomethacin to VCR or etoposide could be of interest in the clinical management of gliomas.     

Expression of MDR1/P-glycoprotein,the multidrug resistance protein MRP,and the lung-resistance protein LRP in multiple myeloma

The purpose of this study was to determine the incidence of three genes associated with multidrug resistance (MDR) in multiple myeloma in relation to treatment status. MDR1/Pgp (P-glycoprotein) expression was detected in 41% of 93 myeloma samples. Generally, the incidence of MDR1/Pgp expression was higher in pretreated samples, and treatments with doxorubicin and/or vincristine were more effective in MDR1/Pgp expression than with alkylating agents. A significant association was observed between MDR1/Pgp-positiveness and the ability of verapmil to increase doxorubicin sensitivity, suggesting functional relevance of MDR1/Pgp expression. MRP (multidrug resistance protein) expression was detected in 20.5% of 88 myeloma samples, in 26% at the mRNA level analyzed by quantitative reverse transriptase-polymerase chain reaction, and in only 3 of 79 samples by immunohistochemistry. LRP (lung-resistance protein) protein expression was observed in 12.5% of 72 myeloma samples. MRP and LRP expression was similar in samples with and without prior therapy. Approximately 80% of the myeloma samples with detectable mRNA expression of MDR1 and MRP exhibited low expression levels corresponding to <10% of the Pgp- and MRP-overexpressing multidrug-resistant human myeloma cell lines 8226/Dox6 and 8226/DOXint40c, respectively. Some normal bone marrow samples showed higher levels of MRP mRNA as compared to myeloma specimens, whereas MDR1 mRNA expression in normal bone marrow was much lower (≤ 5%) than that in 8226/Dox6. These findings indicate a requirement to develop single-cell assays for MRP detection in multiple myeloma that are more sensitive than immunohistochemistry and might be useful to evaluate the incidence of genes associated with MDR.     

Establishment of new multidrug-resistant human osteosarcoma cell lines

Multidrug-resistant clones of human osteosarcoma MNNG/HOS and MG63 cells were isolated by stepwise selection on exposure to increasing doses of doxorubicin (DXR). The final clones MNNG/HOS/DXR1000 and MG63/DXR1000, established after ethylmethane sulfonate mutagenesis, showed 96-fold and 121-fold higer resistance to DXR than their parental cell lines. They were also cross-resistant to vincristine, but not to cisplatinum or methotrexate. The levels of multidrug-resistance-1 (MDR1) mRNA expression increased gradually according to the concentration of DXR in both cell lines. Although the parental MNNG/HOS cells expressed a low level of MDR1 mRNA, the parental MG63 cells showed no MDR1 expression. The IC50 values of MNNG/HOS and its resistant variant to DXR were higher than those of MG63 and its resistant clone. Multidrug-resistant associated protein (MRP) mRNA expression was detected in MNNG/HOS or MG63 parental cell lines, and in their resistant variants. MG63 and its resistant variants revealed stable expression of MRP, whereas the resistant phenotype of MNNG/HOS showed decreased MRP expression, compared to its parental cell line. No alteration in the levels of hepatocyte growth factor (HGF) or its receptor c-MET was recognized between parental lines and their resistant variants. The results indicate that our DXR-resistant variants of MNNG/HOS and MG63 reveal a classical MDR phenotype and can offer a model with which to investigate the mechanisms of multidrug resistance in osteosarcoma.     

Binding of an optically pure photoaffinity analogue of verapamil, LU-49888, to P-glycoprotein from multidrug-resistant human leukemic cell lines

Verapamil enhances anticancer drug cytotoxicity in multidrug resistant (MDR) cells, apparently by competing with these agents for binding to P-glycoprotein (Pgp). In this study, we provide direct evidence for this competition. We studied the binding of an optically pure photoaffinity analogue of verapamil, (S)-5-[(3-azidophenylethyl)-[N-methyl-3H]- methylamino]-2-(3,4,5-trimethoxyphenyl)-2-isopropylvaleronitrile (LU-49888), to Pgp from MDR cell lines. LU-49888 specifically labeled a single Mr 170,0000 protein that was identified as Pgp on Western blots and also by specific immunoprecipitation with monoclonal antibody C-219. A 200-fold molar excess of vinblastine or vincristine specifically inhibited this binding by greater than 98%. LU-49888 labeling of Pgp was also inhibited by actinomycin D (45%), podophyllotoxin (47%), and amsacrine (82%), marginally by doxorubicin (25%), colchicine (22%), daunorubicin (18%), and etoposide (14%), but not by teniposide. Modulators of Pgp-MDR also compete with LU-49888 for binding to Pgp: verapamil (82%), diltiazem (73%), quinidine (91%), reserpine (91%), rescinnamine (88%), and trimethoxybenzoylyohimbine (89%). Chloroquine was moderately inhibitory (25%), whereas chlorpromazine and yohimbine, which are not modulators in our MDR cell lines, did not inhibit the binding of LU-49888 to Pgp. LU-49888 labeling of Pgp was also completely inhibited by (R)-, (S)-, and racemic desmethoxyverapamil, all with the same efficiency. Our results demonstrate that the verapamil analogue LU-49888 specifically binds to Pgp and suggest that verapamil and some MDR modulators exert their effects by interacting with Pgp.     

Inhibitory effect of the reversal agents V-104, GF120918 and Pluronic L61 on MDR1 Pgp-, MRP1- and MRP2-mediated transport

The human multidrug transporter MDR1 P-glycoprotein and the multidrug resistance proteins MRP1 and MRP2 transport a range of cytotoxic drugs, resulting in multidrug resistance in tumour cells. To overcome this form of drug resistance in patients, several inhibitors (reversal agents) of these transporters have been isolated. Using polarized cell lines stably expressing human MDR1, MRP1 or MRP2cDNA, and 2008 ovarian carcinoma cells stably expressing MRP1 cDNA, we have investigated in this study the specificity of the reversal agents V-104 (a pipecolinate derivative), GF120918 (an acridone carboxamide derivative also known as GG918), and Pluronic L61 (a (poly)oxypropethylene and (poly)oxypropylene block copolymer). Transport experiments with cytotoxic drugs with polarized cell lines indicate that all three compounds efficiently inhibit MDR1 Pgp. Furthermore, V-104 partially inhibits daunorubicin transport by MRP1 but not vinblastine transport by MRP2. V-104 reverses etoposide resistance of 2008/MRP1 cells, whereas GF120918 does not reverse resistance due to MRP1. V-104 partially inhibits the export of the organic anion dinitrophenyl S-glutathione by MDCKII-MRP1 but not by MDCKII-MRP2 cells. Unexpectedly, export of the organic anion calcein by MDCKII-MRP1 and MDCKII-MRP2 cells is stimulated by Pluronic L61, probably because it relieves the block on entry of calcein AM into the cell by endogenous MDR1 Pgp.     

Overexpression of LIMK1 promotes migration ability of multidrug-resistant osteosarcoma cells

Multidrug resistance (MDR) to chemotherapy is a major obstacle in the treatment of cancer and the resistance process is multifactorial. Studies on multidrug resistance mechanisms relied on the availability of cancer multidrug resistance cell lines that have been established. In this study we successfully established a multidrug resistance cell line MG63/VCR derived from human osteosarcoma cell line MG63 based on the induction by vincristine. MG63/VCR cells exhibited high resistance to vincristine and other anticancer drugs, accompanied by upregulated expression of MDR-associated genes MDR1, MRP1, and Bcl-2. Notably, we found that MG63/VCR cells exhibited higher migration ability compared to parental MG63 cells. Moreover, we demonstrated that LIMK1, a key regulator of actin cytoskeleton, was overexpressed at both mRNA and protein levels in MG63/VCR cells and the higher LIMK1 protein level was correlated with higher level of phosphorylated cofilin. In addition, knockdown of LIMK1 abolished the higher migration ability of MG63/ VCR cells. These results suggest that LIMK1 overexpression contributes to the invasion and metastasis of drug-resistant osteosarcoma and reveal LIMK as a novel therapeutic target for drug resistant osteosarcoma.     

Overexpression of the ABC transporter TAP in multidrug-resistant human cancer cell lines.

Multidrug resistance (MDR) to anti-cancer drugs has been associated with the overexpression of P-glycoprotein (P-gp) and the multidrug resistance-associated protein (MRP), both being members of the ATP-binding cassette (ABC) superfamily of transporters. We investigated whether in addition to P-gp and MRP, another ABC transporter, the transporter associated with antigen processing (TAP), is associated with MDR. TAP plays a major role in MHC class I-restricted antigen presentation by mediating peptide translocation over the endoplasmic reticulum membrane. TAP1 and P-gp share a significant degree of homology among their transmembrane domains, which are thought to be the primary determinants of substrate specificity, and both can apparently mediate the translocation of peptides. Using immunocytochemistry and Western blot, TAP was overexpressed in parallel with MHC class I in several MDR human cancer cell lines. TAP was overexpressed more frequently in MRP-positive MDR cell lines (three out of three) than in P-gp positive MDR cells (two out of five). Reversal of resistance resulted in a decrease in TAP levels. Transfection of the TAP genes into TAP-deficient lymphoblastoid T2 cells conferred mild resistance to etoposide, vincristine and doxorubicin (2- to 2.5-fold). Furthermore, etoposide and vincristine inhibited TAP-dependent peptide translocation to the endoplasmic reticulum. Collectively, our results suggest that TAP may modestly contribute to the MDR phenotype, in particular in MRP- overexpressing MDR cells. Further insight into the role of TAP in MDR will require the study of other transfectants, as well as the investigation of TAP expression in P-gp and MRP-negative MDR cancer cell lines.     

Expression of Multidrug Resistance-associated Protein (MRP) in Human Gliomas

Drug resistance is a major clinical problem in the chemotherapy of human gliomas. The multidrug resistance-associated protein (MRP), a membrane transporter related to non-P-glycoprotein multidrug resistance, is overexpressed in some drug-selected cancer cell lines. To investigate whether MRP is involved in the intrinsic drug resistance of human gliomas, surgical specimens of 20 gliomas (11 glioblastomas, 6 anaplastic astrocytomas, and 3 astrocytomas), 3 normal brain specimens, and 4 glioma cell lines (U87MG, U251MG, U373MG, and T98G) were analyzed. The expression of MRP was studied by RT-PCR and immunohistochemistry in the surgical specimens. The MRP expression levels in the cell lines were assessed by the quantitative RT-PCR and Western blot analyses. Sensitivity to adriamycin (ADM), etoposide (VP-16), cisplatin (CDDP), and 1-(4-amino-2-methyl-5-pyrimidinyl) methyl-3-(2-chloroethyl)-3-nitrosourea (ACNU), were determined by MTT assay, and antisense treatment was evaluated in the cell lines. The expression of MRP was detected in 9 of 11 glioblastomas and 3 of 6 anaplastic astrocytomas. The quantitative analyses of the cell lines revealed that the MRP mRNA and protein levels were increased 4.5-fold in the T98G cells as compared to U87MG. T98G cells showed the highest resistance to all drugs. Western blot analysis revealed that treatment with the antisense oligonucleotide reduced the level of MRP expression to 25% of the sense oligonucleotide treatment in T98G cells. The sensitivity to ADM, VP-16 and CDDP was significantly increased in the antisense-treated cells as compared with the sense-treated cells. These results suggest that the MRP expression may be related to the intrinsic multidrug resistance in human gliomas.     

Expression of multidrug resistance-associated protein (MRP), MDR1 and DNA topoisomerase II in human multidrug-resistant bladder cancer cell lines.

The acquisition of the multidrug resistance phenotype in human tumours is associated with an overexpression of the 170 kDa P-glycoprotein encoded by the multidrug resistance 1 (MDR1) gene, and also with a 190 kDa membrane ATP-binding protein encoded by a multidrug resistance-associated protein (MRP) gene. Human bladder cancer is a highly malignant neoplasm which is refractory to anti-cancer chemotherapy. In order to understand the mechanism underlying multidrug resistance in bladder cancer, we established three doxorubicin-resistant cell lines, T24/ADM-1, T24/ADM-2 and KK47/ADM, and one vincristine-resistant cell line, T24/VCR, from human bladder cancer T24 and KK47 cells respectively. Both T24/ADM-1 and T24/ADM-2 cells which had elevated MRP mRNA levels showed both a cross-resistance to etoposide and a decreased intracellular accumulation of etoposide. T24/VCR cells which had elevated levels of MDR1 mRNA and P-glycoprotein but not of MRP mRNA, showed cross-resistance to doxorubicin. On the other hand, KK47/ADM cells, which had elevated levels of both MRP and MDR1 mRNA and a decreased level of topoisomerase II mRNA, were found to be cross-resistant to etoposide, vincristine and a camptothecin derivative, CPT-11. Our present study demonstrates a concomitant induction of increased levels of MRP mRNA, decreased levels of topoisomerase II mRNA and decreased drug accumulation during development of multidrug resistance in human bladder cancer cells. The enhanced expression of the MRP gene is herein discussed in a possible correlation with the decreased expression of the topoisomerase II gene.     

Involvement of the Multidrug Resistance Protein 3 in Drug Sensitivity and Its Expression in Human Glioma

The multidrug resistance protein (MRP) family belongs to the ATP-binding cassette superfamily (ABC) of transporters, which are involved in ATP-dependent transport of hydrophobic compounds. One of the MRP family, MRP1 , is partially associated with the multidrug resistance phe-notype in brain tumors. In this study, we asked whether another MRP family gene, MRP3 , could affect drug sensitivity to anticancer agents in human glioma cell lines and clinical glioma specimens. We first produced two antisense transfectants by introduction of antisense MRP3 cDNA into the glioma cell line NHG2, which endogenously expresses MRP3. The two MRP3 antisense transfectants showed 2- to 5-fold increases in drug sensitivity to etoposide and cisplatin compared with NHG2 cells, but their sensitivity to vincristine or nitrosourea was not changed. Two MRP3 cDNA sense transfectants of pig kidney cell lines showed 4- to 6-fold drug resistance to etoposide, but only 1.4- to 1.5-fold to cisplatin. We next compared the mRNA levels of four ABC transporters, multi-drug resistance 1 ( MDR1 ), MRP1, MRP2 and MRP3 in clinical samples, including 34 patients with gliomas, by quantitative RT-PCR analysis. In some of the clinical samples, increased expression of MRP1 and MRP3 was apparent in malignant gliomas. In situ hybridization revealed that glioma cells were stained with MRP3 probe. MRP3 may modulate drug sensitivity to certain anticancer agents in human gliomas.     

Possible involvement of multidrug-resistance-associated protein (MRP) gene expression in spontaneous drug resistance to vincristine,etoposide and adriamycin in human glioma cells

The multidrug-resistance phenotype in human tumors is partly associated with over-expression of the 170 kDa-P-glycoprotein encoded by the multidrug-resistance-1 (MDRI) gene. Another related, but non-P-glycoprotein, multidrug-resistance-associated protein (MRP) gene encodes a 190 kDa membrane ATP-binding protein. Glioblastoma multiforme is a highly malignant primary neoplasm of the central nervous system which is refractory to anti-cancer chemotherapy, but the mechanism underlying this drug resistance is unknown. Out of glioma cell lines, 2, namely IN500 and T98G, which had elevated MRP mRNA levels, showed the highest resistance to multiple anti-cancer agents such as etoposide, vincristine and adriamycin, and decreased intracellular accumulation of etoposide. In the remaining 5 cell lines, various degrees of sensitivity to adriamycin and etoposide appeared to correlate with their respective MRP mRNA levels. Our study proposes that MRP may be involved in spontaneous multidrug resistance in human gliomas.     

In vitro prevention of the emergence of multidrug resistance in a pediatric rhabdomyosarcoma cell line.

We have established preclinical models for the development of drug resistance to vincristine (a major drug used in the treatment of pediatric rhabdomyosarcoma) using cell lines. The RD cell line has a mutant P53 phenotype and does not have detectable P-glycoprotein (P-gp) or multidrug resistance-related protein (MRP) despite expressing low levels of mdr-1 mRNA, which encodes P-gp and mrp1 mRNA. Resistant variants of RD were derived by exposure to increasing concentrations of vincristine. This was repeated on six occasions, resulting in three cell lines which could tolerate 64 x the IC(50) concentration. Six independent agents were tested for their ability to prevent the development of resistance in this model. Despite at least 10 attempts, resistance did not develop in the presence of the multidrug resistance (MDR) modulators PSC833, VX710, and XR9576. This strongly suggests that these agents may delay or even prevent the development of resistance to vincristine. This was also confirmed in a second rhabdomyosarcoma cell line, Rh30. In contrast, the agents indomethacin (MRP1 modulator), CGP41251 (protein kinase C inhibitor), and dexrazoxane (putative MDR prevention agent) did not affect the development of resistance in the RD model. Characterization of the resistant cell lines indicated the presence of increased mdr-1 and P-gp expression, which resulted in resistance to the agents doxorubicin, etoposide, and vincristine but not cisplatin. The resistance could be modulated using PSC833 or VX710, confirming that functional P-gp is present. No apparent differences were seen between the resistant cell lines derived in the absence and presence of the various agents. These experiments strongly suggest that the development of MDR may be preventable using modulators of MDR and merit clinical studies to test this hypothesis.     

多药耐药相关蛋白2及其在肿瘤耐药中的研究进展

肿瘤对化疗药物多药耐药是肿瘤治疗失败的重要原因之一。多药耐药的主要原因是由Pgp、多药耐药相关蛋白（MRP）、肺耐药相关蛋白（LRP）、乳腺癌耐药相关蛋白（BCRP）等转运蛋白表达异常增高所致。MRP包含9个成员：MRP1-MRP9。多药耐药相关蛋白2（MRP2）是三磷酸腺苷（A1甲）结合盒运载体蛋白家族成员之一，本文就MRP2基因的特性及其在肿瘤耐药中的作用作一综述.     

A very early induction of major vault protein accompanied by increased drug resistance in U-937 cells.

U-937 human leukemia cells were selected for resistance to doxorubicin in the presence or absence of a specific drug modulator that inhibits the activity of P-glycoprotein (Pgp), encoded by the multidrug-resistance gene (MDR1). Parental cells expressed low basal levels of the multidrug-resistance-associated gene (MRP1) and major vault protein (MVP) mRNAs and no MDR1 mRNA. Two doxorubicin-resistant cell lines were selected. Both drug-resistant cell lines upregulated the MVP mRNA level 1.5-fold within 1 cell passage. The MVP mRNA level continued to increase over time as the doxorubicin selection pressure was increased. MVP protein levels generally paralleled the mRNA levels. The 2 high molecular weight vault protein mRNAs were always expressed at constitutive levels. Fully formed vault particles consisting of the MVP, the 2 high molecular weight proteins and the vault RNA assembled and accumulated to increased levels in drug-selected cells. MVP induction is therefore the rate-limiting step for vault particle formation in U-937 cells. By passage 25 and thereafter, the selected cells were resistant to doxorubicin, etoposide, mitoxantrone and 5-fluorouracil by a pathway that was independent of MDR1, MRP1, MRP2 and breast cancer resistance protein. In summary, U-937 doxorubicin-selected cells are programmed to rapidly upregulate MVP mRNA levels, to accumulate vault particles and to become multidrug resistant.     

Regulation of cellular glutathione modulates nuclear accumulation of daunorubicin in human MCF7 cells overexpressing multidrug resistance associated protein

Multidrug resistance (MDR) is frequently associated with the overexpression of P-glycoprotein (Pgp) and/or multidrug resistance associated protein (MRP1), both members of the ABC superfamily of transporters. Pgp and MRP1 function as ATP-dependent efflux pumps that extrude cytotoxic drugs from tumour cells. Glutathione (GSH) has been considered to play an important role in the MRP1-mediated MDR. In our study, we examined the effects of buthionine sulphoximine (BSO), an inhibitor of GSH biosynthesis, on the nuclear accumulation of daunorubicin (DNR), in etoposide (VP16) and doxorubicin (ADR) resistant MCF7 cell lines, overexpressing respectively MRP1 (MCF7/VP) and Pgp (MCF7/ADR). The study of DNR transport was carried out using scanning confocal microspectrofluorometry. This technique allows the determination of the nuclear accumulation of anthracyclines in single living tumour cells. Treatment of MCF7/VP cells with BSO increased the sensitivity of these cells to DNR whilst the cytotoxicity of the drug in MCF7/ADR cells remained unchanged. In MCF7 resistant cells treated with BSO, their GSH level decreased as observed by confocal microscopy. DNR nuclear accumulation in MCF7/VP cells was increased by BSO whereas in MCF7/ADR cells BSO was unable to significantly increase the DNR nuclear accumulation. These data suggest a requirement for GSH in MRP1-mediated resistance whilst the nuclear efflux of GSH conjugates is probably not the primary mechanism of Pgp-mediated MDR. Finally, BSO might be a useful agent in clinical assays for facilitating detection of MRP1 expression.     

Involvement of the multidrug resistance protein 3 in drug sensitivity and its expression in human glioma.

The multidrug resistance protein (MRP) family belongs to the ATP-binding cassette superfamily (ABC) of transporters, which are involved in ATP-dependent transport of hydrophobic compounds. One of the MRP family, MRP1, is partially associated with the multidrug resistance phenotype in brain tumors. In this study, we asked whether another MRP family gene, MRP3, could affect drug sensitivity to anticancer agents in human glioma cell lines and clinical glioma specimens. We first produced two antisense transfectants by introduction of antisense MRP3 cDNA into the glioma cell line NHG2, which endogenously expresses MRP3. The two MRP3 antisense transfectants showed 2- to 5-fold increases in drug sensitivity to etoposide and cisplatin compared with NHG2 cells, but their sensitivity to vincristine or nitrosourea was not changed. Two MRP3 cDNA sense transfectants of pig kidney cell lines showed 4- to 6-fold drug resistance to etoposide, but only 1.4- to 1.5-fold to cisplatin. We next compared the mRNA levels of four ABC transporters, multidrug resistance 1 (MDR1), MRP1, MRP2 and MRP3 in clinical samples, including 34 patients with gliomas, by quantitative RT-PCR analysis. In some of the clinical samples, increased expression of MRP1 and MRP3 was apparent in malignant gliomas. In situ hybridization revealed that glioma cells were stained with MRP3 probe. MRP3 may modulate drug sensitivity to certain anticancer agents in human gliomas.