Development and characterisation of novel human multidrug resistant mammary carcinoma lines in vitro and in vivo

Clinical chemotherapy of breast carcinomas must be considered insufficient, mainly due to the appearance of drug resistance. The multidrug resistance (MDR) phenotype, either intrinsically occurring or acquired, e.g., against a panel of different antineoplastic drugs, is discussed in relation to several MDR-associated genes such as the MDR-gene mdr1 encoding the P-glycoprotein (PGP), the MRP gene (multidrug resistance protein) encoding an MDR-related protein or the LRP gene encoding the lung resistance protein. Numerous experimental and clinical approaches aiming at reversing resistance require well-characterised in vitro and in vivo models. The aim of our work was to develop multidrug resistant sublines from human xenotransplanted breast carcinomas, in addition to the broadly used line MCF-7 and its multidrug resistant subline MCF-7/AdrR. MDR was induced in vitro with increasing concentrations of Adriablastin (ADR) for several weeks, resulting in a 3.5- to 35-fold increase in IC50 values using the MTT-test. Cell lines were cross-resistant toward another MDR-related drug, vincristine, but remained sensitive to non-MDR-related compounds such as cisplatin and methotrexate. The resistance toward Adriamycin and vincristine was confirmed in vivo by a lack of tumour growth inhibition in the nude mouse system. Gene expression data for the mdr1/PGP, MRP/MRP and LRP/LRP on both the mRNA (RT-PCR) and the protein levels (immunoflow cytometry) demonstrated that induction of mdr1 gene expression was responsible for the acquired MDR phenotype. Rhodamine efflux data, indicated by PGP overexpression, underlined the development of this MDR mechanism in the newly established breast carcinoma lines MT-1/ADR, MT-3/ADR and MaTu/ADR.     

Hyperosmolar nonketotic coma at the onset of type I diabetes in a child

The expression of multidrug resistance-associated protein (MRP) mRNA was examined in ten samples of Ewing's sarcoma of bone (ES) and in one nude mice transplantable ES and two malignant peripheral neuroectodermal tumor (MPNT) cell lines using an RT-PCR assay. MRP mRNA expression was recognized in eight of the ten clinical specimen and in all three cell lines. On the other hand, the expression of multidrug resistance gene (MDR1) was demonstrated in three of the ten clinical samples and all three cell lines. Our results may contribute to elucidation of the mechanism of anti-cancer-drug resistance in this tumor.     

Rapid recovery of a functional MDR phenotype caused by MRP after a transient exposure to MDR drugs in a revertant human lung cancer cell line

Prior studies have shown that, in some human tumour cells, increased expression of the multidrug resistance gene MDR1 can be induced in response to certain stress conditions such as a transient exposure to cytotoxic agents. Little is known about the possibility of increasing the expression of the recently cloned multidrug resistance-associated protein (MRP) in response to a transient exposure to cytotoxic drugs. In order to examine this possibility, we have used sensitive assays (RT-PCR, flow cytometry) and the sensitive large cell lung cancer cell line, COR-L23/P, and the revertant line (COR-L23/Rev), generated by growing the doxorubicin-selected, MRP-overexpressing resistant variant COR-L23/R without drug exposure for 24-28 weeks. COR-L23/Rev overexpresses MRP, but to a lesser extent than COR-L23/R. COR-L23/Rev rapidly recovered similar levels of MRP mRNA, protein expression, resistance and drug accumulation deficit as COR-L23/R after a 48-72 h exposure to cytotoxic concentrations of doxorubicin or vincristine but not cisplatin. The increase in MRP mRNA could only be detected 3 to 4 days after the transient exposure to drugs. However, when the parental line, COR-L23/P, was exposed to equitoxic doses of doxorubicin, vincristine or cisplatin, no increase in the levels of MRP mRNA could be observed at higher doses (5- to 10-fold the IC50) of doxorubicin or vincristine (but not of cisplatin), we detected a transient increase in the levels of MDR1 mRNA immediately after short-term exposure. In conclusion, we have shown that a human revertant lung cancer cell line (COR-L23/Rev) has the ability to recover quickly, similar levels of MRP expression and resistance as COR-L23/R after a transient exposure to the MDR-drugs doxorubicin and vincristine.     

Emergency day hospital assessments

RT-PCR method was used to detect the expression level of multi-drug resistance gene (MDR1) and multi-drug resistance associated protein (MRP) in patients with malignant blood disease, including 19 cases of acute leukemia and 6 cases of multiple myeloma. The results showed: expression level of MDR1 in patients with known clinical drug resistance elevated obviously and was significantly associated with clinical drug resistance (r = 0.612, P < 0.01), which indicated that expression of MDR1 was the main mechanism of clinical drug resistance. There is no obvious relationship between expression level of MDR1 and MRP (r = 0.035, P > 0.05).     

Ionisation behaviour and solution properties of the potassium-channel blocker ShK toxin

Intrinsic or acquired drug resistance is a major limiting factor of the effectiveness of chemotherapy. Increased expression of either the MRP gene or the MDR1 gene has been demonstrated to confer drug resistance in vitro. In this study, we examined MRP and MDR1 gene expression in a panel of 17 small cell lung cancers (SCLC) xenografted into nude mice from treated and untreated patients using an RT-PCR technique. For some of them, the outcome of the corresponding patients was known and we related MDR1/MRP expression with the xenograft response to C'CAV (cyclophosphamide, cisplatin, adriamycin and etoposide) combined chemotherapy. Fifteen (88%) of the 17 cases of SCLC were found to be positive for either MDR1 or MRP. MRP gene expression was present in 12 (71%) of 17 cases, whereas MDR1 gene expression was detected in eight (50%) of 16 cases. For six SCLC, the survival duration of patients differed, with three patients surviving for more than 30 months after therapy. Among these six turnours, five expressed MRP and/or MDR1. These six xenografts responded to the C'CAV treatment but a significant rate of cure was obtained in only three cases. No obvious relationship was observed between the response to this treatment and MRP or MDR1 expression. However, the remarkably high levels and frequency of MRP expression in some SCLC samples indicate that future developments in chemotherapy of this tumour type should anticipate that drugs which are substrates of MRP may be of limited effectiveness.     

Significance of multidrug resistance in the therapy of malignant tumors

Some human malignant tumours respond poorly to initial chemotherapy, indicating that they possess intrinsic resistance. On the other hand, in a significant portion of tumours after early promising results of therapy, the patients relapse, metastases appear, and acquired resistance to chemotherapy develops. The broad spectrum-resistance against chemotherapy is called multidrug resistance (MDR), and due to its clinical significance, studying of proteins responsible for multidrug resistance has become one of the most active research areas in biomedicine. There are several molecular mechanisms responsible for multidrug resistance. A group of filogenetically conservative plasmamembrane proteins actively extrudes different toxic compounds, xenobiotics, and also cytotoxic drugs from drug-resistant cells by using the energy of ATP. The clinically and biochemically most thoroughly characterized member of these proteins is the P-glycoprotein, which pumps hydrophobic drugs of natural origin and different chemical structure out of the cells. The recently cloned multidrug resistance associated protein (MRP) has also a broad substrate specificity, thus resembling P-glycoprotein. However, besides hydrophobic compounds, organic anions, glucuronide and glutathione conjugates are also excellent substrates of the MRP. The basic and clinically relevant properties of proteins causing multidrug resistance and the state of the art of current diagnostic approaches are summarized in this literature review. The different malignancies are characterized from the point of view of their multidrug resistance and recent clinical and biochemical data concerning therapeutic approaches for reversal of multidrug resistance are also presented.     

Genomic organization of DHR38 gene in Drosophila: presence of Alu-like repeat in a translated exon and expression during embryonic development

Treatment-induced secondary drug resistance of tumor cells is a major cause of relapsed disease and therapeutic failure in cancer patients. It has been shown that the expression of the multidrug resistance MDR1/P-glycoprotein gene could be induced by short-term in vitro exposure of cells to protein kinase C (PKC) agonists or different chemotherapeutic drugs. We studied whether other genes involved in drug resistance are regulated by similar signaling pathways. Transient (up to 24 h) treatment of HL-60 or K562 leukemia cells with phorbol 12-myristate 13-acetate (TPA) resulted in increased steady-state level of LRP (lung resistance-related protein) mRNA and protein. Among conventional chemotherapeutic drugs tested, only cytarabine (Ara C) induced the LRP mRNA expression though no increase in LRP protein was detected. LRP gene activation was not detectable in either H9 T-cell leukemia or in solid carcinoma cell lines (BT-20, ZR-75-1, and SW 1573). None of the agents influenced the levels of MRP (multidrug resistance-associated protein) mRNA in any cell line tested. In HL-60 cells, the LRP activation by TPA or Ara C was sustained for at least 23 days after withdrawal of inducing agents. bis-Indolylmaleimide I, a potent PKC inhibitor, attenuated TPA-induced LRP activation. In contrast, the inhibitor had no effect on the LRP induction by Ara C. These data indicate that the LRP gene can be activated by different mechanisms, some of which involve PKC.     

Fuzzy-logic control of blood pressure through enflurane anesthesia

BACKGROUND: A 190k (190-kilodalton) membrane protein has been identified in several multidrug-resistant (MDR) cell lines that show decreased drug accumulation without expression of P-glycoprotein. It is not clear whether this 190k protein is involved directly in drug efflux. Recently, a gene for a putative transporter protein, MRP (multidrug resistance-associated protein) has been sequenced and localized to chromosome 16. The protein encoded by this gene contains a 7-amino-acid sequence present in the synthetic peptide used to generate the antiserum recognizing the 190k protein. PURPOSE: The study was undertaken to clarify the relationship of the 190k protein to MRP gene expression in non-P-glycoprotein-containing MDR cells of the large-cell and adenocarcinoma lung cancer lines, COR-L23 and MOR. METHODS: Expression of the 190k protein was determined by Western blot analysis and that of the MRP gene by polymerase chain reaction amplification of complementary DNA reverse transcribed from RNA. Abnormalities of chromosome 16 were investigated in chromosome spreads by fluorescence in situ hybridization. RESULTS: The amount of detectable 190k protein is closely associated with degree of drug resistance. Cell lines surviving in higher drug concentrations have greater amounts of protein, and revertant lines grown without drug for up to 28 weeks show reduced expression of the protein together with enhanced drug sensitivity. The 190k protein appears to be one of the major proteins differentially expressed in membranes of drug-resistant cells. The amount of MRP messenger RNA correlates closely with that of the 190k protein. The MDR cells contain amplified chromosome 16 material with many double minutes in the large-cell lung tumor lines and an enlarged chromosome 16 in the adenocarcinoma lines. CONCLUSION: The 190k protein detected immunologically is likely to be the protein, encoded by the MRP gene, which becomes overexpressed in these cells as a consequence of chromosomal amplification and fragmentation. IMPLICATION: Though associated with drug resistance, enhanced drug efflux, and decreased drug accumulation in cell lines, the role of this protein in clinical resistance has yet to be determined.     

Multidrug resistance protein 1 protects the oropharyngeal mucosal layer and the testicular tubules against drug-induced damage

The multidrug resistance protein 1 (MRP1) gene encodes a transporter protein that helps to protect cells against xenobiotics. Elevated levels of MRP1 in tumor cells can result in active extrusion of a wide range of (anticancer) drugs with different cellular targets, a phenomenon called multidrug resistance (MDR). To explore the protective function of the mouse mrp1 protein during drug treatment, we investigated the toxicity caused by the anticancer drug etoposide-phosphate (ETOPOPHOS) in mice lacking the mrp1 gene (mrp1(-/-) mice). We show here that the lack of mrp1 protein results in increased etoposide-induced damage to the mucosa of the oropharyngeal cavity and to the seminiferous tubules of the testis. The high concentrations of mrp1 that we find in the basal layers of the oropharyngeal mucosa and in the basal membrane of the Sertoli cells in the testis apparently protect wild-type mice against this tissue damage. We also find drug-induced polyuria in mrp1(-/-) mice, which correlates with the presence of mrp1 protein in the urinary collecting tubules, the major site of kidney water reabsorption. Our results indicate that specific inhibitors of MRP1 used to reverse MDR, in combination with carcinostatic drugs transported by MRP1, might lead to drug-induced mucositis, (temporary) infertility, and diabetes insipidus.     

Activity of P-glycoprotein in B-cell chronic lymphocytic leukemia determined by a flow cytometric assay

BACKGROUND: Chemoresistance in some hematologic malignancies has been associated with overexpression of P-glycoprotein, which is encoded by the MDR1 gene (also known as PGY1). However, inconsistencies in data on frequency and clinical relevance of multidrug resistance in B-cell chronic lymphocytic leukemia (B-CLL) may reflect a need for improved techniques to detect this overexpression. PURPOSE: Our purpose was to measure P-glycoprotein activity in peripheral blood cells of B-CLL patients and to analyze possible clinical correlations (disease duration, prior treatment, Rai disease stage, lymphocyte counts, and disease progression). METHODS: P-glycoprotein activity was assayed in peripheral blood cells of 42 consecutive B-CLL patients (22 treated and 20 untreated). We used dual fluorescence in a flow cytometric assay that detects efflux of the fluorescent dye rhodamine 123, which is transported from the cell by the P-glyprotein pump. Leukemia cells were costained with monoclonal antibody Leu12/CD19, and rhodamine 123 efflux was measured. Expression of MDR1 and MDR3 (also known as PGY3) messenger RNA (mRNA) was quantitatively evaluated by polymerase chain reaction (PCR) in 26 cases. RESULTS: Marked rhodamine 123 efflux was observed in 34 (81%) of the 42 cases and was abolished in the presence of multidrug resistance inhibitors. Rhodamine 123 efflux was not associated with Rai stage, lymphocyte counts, duration of disease, or disease progression. Although rhodamine 123-negative cases were about equally distributed among untreated and previously treated patients, the percentage of cells with rhodamine 123 efflux was significantly lower for untreated patients than for those treated with chemotherapy regimens including at least one multidrug resistance-associated drug. MDR1 mRNA was detected in 25 of 26 cases and MDR3 mRNA in all 26. MDR1 mRNA expression was significantly correlated with rhodamine 123 efflux, whereas MDR3 mRNA expression was not significantly correlated; MDR1 and MDR3 mRNA expression was not significantly associated with Rai stage, prior treatment, or disease progresssion. CONCLUSIONS: These findings suggest that P-glycoprotein overexpression in B-CLL is intrinsic rather than acquired and that P-glycoprotein activity is enhanced after exposure to multidrug resistance-associated drugs. This enhanced activity does not seem to be associated with more aggressive disease. Our results also indicate that an assay of P-glycoprotein function combined with PCR is suitable for clinical multidrug resistance screening. IMPLICATIONS: Additional studies are needed to determine whether functional activity of P-glycoprotein, measured by rhodamine 123 efflux, is directly related to clinical drug resistance.     

Mechanisms of multidrug resistance in tumor cells and analytical methods for its detection

We reviewed mechanisms of multidrug resistance (MDR) phenotype in tumor cells and evaluated analytical methods for detection of clinical MDR. A well-recognized mechanism of MDR phenotype is the induction and increased expression of P-glycoprotein (P-gp) which is a 170 kDa cellular transmembrane protein encoded by a multidrug-resistance 1 gene (MDR1) and works as a drug efflux pump. Cellular MDR phenotype through P-gp/MDR1 can be detectable at protein level by: (1) using immunohistochemical method, flow cytometric assay and Western blot analysis with monoclonal antibodies against human P-gp, and (2) measuring Rhodamine 123 dye-efflux as a functional assay of P-gp. Molecular knowledge and recent technical progress enable to determine MDR1 gene expression by RT-PCR-based analytical methods as well as conventional quantification methods of gene expression such as Northern blot analysis. In the evaluation of P-gp/MDR1 expression in clinical samples, in which amount of materials was limited, utilization of simple and sensitive methods like competitive RT-PCR assay might be efficacious for its quantitative detection in clinical laboratories. Evidences which showed the positive correlation between the expression of P-gp/MDR1 and clinical resistance or refractoriness of tumor cells to anticancer drugs involved in MDR have been accumulated and support the clinical importance of its detection to circumvent resistance with alternate use of non-MDR drugs.     

Effect of fibronectin amount and conformation on the strength of endothelial cell adhesion to HEMA/EMA copolymers

P-Glycoprotein (P-gp) and multidrug resistance protein (MRP) are plasma membrane associated proteins which can confer multidrug resistance (MDR) to cancer cells by lowering the intracellular amount of drug. Although clinical trials with MDR-reverting agents have been initiated, not much attention has been paid to blood components which may modulate the activity of P-gp or MRP. The present investigation was performed to identify and characterize blood components which may influence the drug content and the drug cytotoxicity of MDR cells. Human plasma, from healthy volunteers, was tested for its effects on the daunorubicin (DNR) accumulation and cytotoxicity in the MDR cell lines SW-1573/2R160 (2R160) and GLC4/ADR containing P-gp and MRP, respectively. The data were compared to the effects observed in wild-type cells. MDR-modifying plasma components were isolated by extraction procedures and characterized using ultrafiltration, high-performance liquid chromatography (HPLC) and mass spectrometry. An increase in the proportion of plasma in the culture medium led to a reduction of the ratio between the DNR content of wild-type and corresponding MDR cells. At 100% plasma we observed an increase in the cellular DNR content of 2R160 cells, which was 10-30% (median 18%) of the maximum possible increase induced by well-known MDR-reverting agents, such as verapamil (for GLC4/ADR cells: 10-20%, median 15%). The DNR cytotoxicity in MDR cells also increased with an increasing amount of plasma included in the culture media. There was neither an increase in the cellular DNR content nor an effect on the DNR cytotoxicity in wild-type cells. Plasma extract analysis by HPLC showed a major peak which increased the DNR content of MDR cells. The HPLC column retention time of this fraction was identical to that of a standard of cortisol and it was further confirmed to be cortisol using mass spectrometry. Moreover, inclusion of a standard of cortisol in culture media induced a similar effect. We analyzed the data for one of the plasma pools and found that blood cortisol was responsible for the MDR-modulating effect only for 35% of the effect of 100% plasma. Other plasma components were responsible for the remaining modulation effect on MDR cells. In conclusion, the DNR pumping activity of P-gp and MRP is inhibited by human plasma, resulting in 10-30% of the maximum possible increase in cellular drug content. Based on cellular pharmacokinetic calculations this percentage will most likely increase at clinical levels of drug resistance (reaching 40-50%). In one sample blood cortisol accounted for 35% of the effect of plasma on the DNR content in MDR 2R160 cells. These data show the need for additional studies to test plasma samples for their MDR modulating effects before the administration of MDR-reverting agents in chemotherapy. The data suggest that the effectiveness of chemotherapeutic drugs may be enhanced when administered in accordance with the circadian peak of endogenous corticoids.