Expression of cell surface P-glycoprotein by an adriamycin-resistant murine fibrosarcoma

2-APB and CBD-Mediated Targeting of Charged Cytotoxic Compounds Into Tumor Cells Suggests the Involvement of TRPV2 Channels

Targeted delivery of therapeutic compounds to particular cell types such that they only affect the target cells is of great clinical importance since it can minimize undesired side effects. For example, typical chemotherapeutic treatments used in the treatment of neoplastic disorders are cytotoxic not only to cancer cells but also to most normal cells when exposed to a critical concentration of the compound. As such, many chemotherapeutics exhibit severe side effects, often prohibiting their effective use in the treatment of cancer. Here, we describe a new means for facilitated delivery of a clinically used chemotherapy compound' doxorubicin, into hepatocellular carcinoma cell line (BNL1 ME). We demonstrate that these cells express a large pore, cation non-selective transient receptor potential (TRP) channel V2. We utilized this channel to shuttle doxorubicin into BNL1 ME cells. We show that co-application of either cannabidiol (CBD) or 2-APB, the activators of TRPV2 channels, together with doxorubicin leads to significantly higher accumulation of doxorubicin in BNL1 ME cells than in BNL1 ME cells that were exposed to doxorubicin alone. Moreover, we demonstrate that sub-effective doses of doxorubicin when co-applied with either 2-APB or CBD lead to a significant decrease in the number of living BNL1 ME cell and BNL1 ME cell colonies in comparison to application of doxorubicin alone. Finally, we demonstrate that the doxorubicin-mediated cell death is significantly more potent, requiring an order of magnitude lower dose, when co-applied with CBD than with 2-APB. We suggest that CBD may have a dual effect in promoting doxorubicin-mediated cell death by facilitating the entry of doxorubicin via TRPV2 channels and preventing its clearance from the cells by inhibiting P-glycoprotein ATPase transporter. Collectively, these results provide a foundation for the use of large pore cation-non selective channels as “natural” drug delivery systems for targeting specific cell types.

The third-generation bisphosphonates inhibit proliferation of murine osteosarcoma cells with induction of apoptosis

Third generation bisphosphonates (BPs), including YM175 and YM529, are known to inhibit bone resorption. The aim of this study was to evaluate the anti-tumor effects of these drugs on murine osteosarcoma cell lines, in terms of proliferation and apoptosis. We found that both YM175 and YM529 strongly inhibited the in vitro proliferation and induced apoptosis of murine osteosarcoma cells. YM529 was more effective than YM175 in inhibiting cell proliferation. These observations suggest that third-generation BPs directly affect on the proliferation and survival of osteosarcoma cells, which supports the possibility that they could be beneficial in the treatment of osteosarcoma patients.

Inhibition of DNA cross-linking by mitomycin C by peroxidase-mediated oxidation of mitomycin C hydroquinone

Mitomycin C requires reductive activation to cross-link DNA and express anticancer activity. Reduction of mitomycin C (40 microm) by sodium borohydride (200 microm) in 20 mm Tris-HCl, 1 mm EDTA at 37 degrees C, pH 7.4, gives a 50-60% yield of the reactive intermediate mitomycin C hydroquinone. The hydroquinone decays with first order kinetics or pseudo first order kinetics with a t(12) of approximately 15 s under these conditions. The cross-linking of T7 DNA in this system followed matching kinetics, with the conversion of mitomycin C hydroquinone to leuco-aziridinomitosene appearing to be the rate-determining step. Several peroxidases were found to oxidize mitomycin C hydroquinone to mitomycin C and to block DNA cross-linking to various degrees. Concentrations of the various peroxidases that largely blocked DNA cross-linking, regenerated 10-70% mitomycin C from the reduced material. Thus, significant quantities of products other than mitomycin C were produced by the peroxidase-mediated oxidation of mitomycin C hydroquinone or products derived therefrom. Variations in the sensitivity of cells to mitomycin C have been attributed to differing levels of activating enzymes, export pumps, and DNA repair. Mitomycin C hydroquinone-oxidizing enzymes give rise to a new mechanism by which oxic/hypoxic toxicity differentials and resistance can occur.

Effects of PEMF on a murine osteosarcoma cell line: drug-resistant (P-glycoprotein-positive) and non-resistant cells

After pulsed exposure of Dunn osteosarcoma cells (nonresistant cells) to Adriamycin (ADR) at increasing concentrations and single-cell cloning of surviving cells, ADR-resistant cells were obtained. These resistant cells expressed P-glycoprotein and had resistance more than 10 times that of their nonresistant parent cells. Compared to the nonresistant cells not exposed to pulsing electromagnetic fields (PEMF) in ADR-free medium, their growth rates at ADR concentrations of 0.01 and 0.02 micrograms/ml, which were below IC50, were 83.0% and 61.8%, respectively. On the other hand, in the nonresistant cells exposed to PEMF (repetition frequency, 10 Hz; rise time, 25 microsec, peak magnetic field intensity, 0.4-0.8 mT), the growth rate was 111.9% in ADR-free medium, 95.5% at an ADR concentration of 0.01 micrograms/ml, and 92.2% at an ADR concentration of 0.02 micrograms/ml. This promotion of growth by PEMF is considered to be a result of mobilization of cells in the non-proliferative period of the cell cycle due to exposure to PEMF. However, at ADR concentrations above the IC50, the growth rate tended to decrease in the cells not exposed to PEMF. This may be caused by an increase in cells sensitive to ADR resulting from mobilization of cells in the non-proliferative period to the cell cycle. The growth rate in the resistant cells exposed to PEMF was significantly lower than that in the non-exposed resistant cells at all ADR concentrations, including ADR-free culture (P</=0.0114). Therefore, this study suggests that PEMF promotes the growth of undifferentiated cells but progressively suppresses the growth of more differentiated cells, i.e., PEMF controls cell growth depending on the degree of cell differentiation. This study also shows the potentiality of PEMF as an adjunctive treatment method for malignant tumors.

Experimental models for the study of drug resistance in osteosarcoma: P-glycoprotein-positive, murine osteosarcoma cell lines

P-glycoprotein is an adenosine triphosphate-dependent drug-efflux pump that extrudes drugs from cells and causes drug-resistance. P-glycoprotein is believed to mediate drug-resistance in a wide variety of tumors. In this study, we developed two P-glycoprotein-positive, murine osteosarcoma cell lines that were resistant to Adriamycin (doxorubicin) (MOS/ADR1 and MOS/ADR2). We created the cell lines by short-term pulse exposures of the parent cell line to Adriamycin followed by single-cell cloning. The MOS/ADR1 and MOS/ADR2 cells were sevenfold and eighteenfold more resistant to Adriamycin than the cells from the parent line. Expression of P-glycoprotein, as examined with an immunofluorescence method, was detected in most of the MOS/ADR1 and MOS/ADR2 cells but not in the parent cells. After the cells had been incubated with Adriamycin for one hour, there was less accumulation of the drug in the resistant cell lines than in the parent cell line. The reduced accumulation was due to the increased efflux of Adriamycin. The Adriamycin-resistant cell lines demonstrated greater alkaline phosphatase activity than the parent cell line and produced more differentiated osteoblastic sarcomas in mice. Dose survival studies with use of a tetrazolium colorimetric assay showed that the MOS/ADR1 cells were cross-resistant to vincristine, vinblastine, etoposide, bleomycin, mitomycin C, and actinomycin D but not to dacarbazine, cisplatin, carboplatin, cytosine arabinoside, carmustine, cyclophosphamide, ifosfamide, methotrexate, and 5-fluorouracil. Although the MOS/ADR2 cells exhibited a similar spectrum of cross-resistance, they were more resistant than the MOS/ADR1 cells. We also tested the effect of three different resistance-modifying agents on the reversal of resistance to Adriamycin. We found that verapamil and trifluoperazine substantially reversed resistance to Adriamycin in the P-glycoprotein positive cell lines, whereas cyclosporin A was relatively ineffective. Because these cell lines retain the histological and biochemical features of bone-producing sarcomas and display the multidrug-resistant phenotype, they may be useful models for additional investigations of drug resistance in osteosarcoma.

Biochemical characterization of a mitomycin C resistant colon cancer cell line variant

Resistance may limit the clinical usefulness of a variety of chemotherapeutic drugs including mitomycin C (MMC). The MMC-sensitive HT-29 colon cancer cell line and its MMC-resistant subline, HT-29R13, were studied in vitro under aerobic conditions to help characterize the mechanisms associated with MMC resistance. HT-29R13 cells exhibit approximately 2-fold resistance to MMC compared with HT-29 cells and lack the typical multidrug-resistance pattern; resistance is stable in the absence of drug exposure. Levels of glutathione (GSH) and total glutathione-S-transferase (GST) activity were not different between the two cell lines; however, levels of GSH reductase and GSH peroxidase were increased significantly in HT-29R13. Although total GST activity was unchanged, GST-pi and GST-alpha isoenzyme expression as measured using western blot were increased significantly in HT-29R13 compared with HT-29. DT-diaphorase levels and topoisomerase II activity were decreased significantly in HT-29R13. Both cell lines had equal P-glycoprotein expression. Multiple drug resistance mechanisms are present in HT-29R13 including decreased drug activation (decreased DT-diaphorase), increased drug detoxification (increased GST-pi and GST-alpha, GSH reductase, GSH peroxidase), and decreased accessibility of DNA targets (decreased topoisomerase II). Further work will be necessary to determine the degree to which each of these mechanisms contribute to MMC resistance in this model.

Development and initial characterization of a mitomycin C-resistant colon cancer cell line variant

Resistance may limit the clinical usefulness of a variety of chemotherapeutic drugs, including mitomycin C (MMC). In order to study resistance to MMC, a variant of the HT-29 human colon cell line was isolated by exposure to repeated doses of MMC. The 95% inhibitory concentration of MMC for this isolate (HT-29R13) was found to be approximately twice that for the parent line. The level of resistance did not increase with additional drug exposure, and resistance was stable for at least 6 months in the absence of drug exposure. HT-29R13 cells exhibit cross-resistance to melphalan and 5-FU but not to doxorubicin, cis-platinum, or etoposide. HT-29R13 cells are characterized by slightly decreased plating efficiency and slightly increased total protein compared with the parent line. This model of stable, low-level MMC resistance with an unusual cross-resistance pattern may prove useful for the study and characterization of MMC resistance mechanisms.

P-glycoprotein as multidrug transporter: a critical review of current multidrug resistant cell lines

MDR has been studied extensively in mammalian cell lines. According to usual practice, the MDR phenotype is characterized by the following features: cross resistance to multiple chemotherapeutic agents (lipophilic cations), defective intracellular drug accumulation and retention, overexpression of P-gp (often accompanied by gene amplification), and reversal of the phenotype by addition of calcium channel blockers. An hypothesis for the function of P-gp has been proposed in which P-gp acts as a carrier protein that actively extrudes MDR compounds out of the cells. However, basic questions, such as what defines the specificity of the pump and how is energy for active efflux transduced, remain to be answered. Furthermore, assuming that P-gp acts as a drug transporter, one will expect a relationship between P-gp expression and accumulation defects in MDR cell lines. A review of papers reporting 97 cell lines selected for resistance to the classical MDR compounds has revealed that a connection exists in most of the reported cell lines. However, several exceptions can be pointed out. Furthermore, only a limited number of well characterized series of sublines with different degrees of resistance to a single agent have been reported. In many of these, a correlation between P-gp expression and transport properties can not be established. Co-amplification of genes adjacent to the mdr1 gene, mutations [122], splicing of mdr1 RNA [123], modulation of P-gp by phosphorylation [124] or glycosylation [127], or experimental conditions [26,78] could account for some of the complexity of the phenotype and the absence of correlation in some of the cell lines. However, both cell lines with overexpression of P-gp without increased efflux [i.e., 67,75] and cell lines without P-gp expression and accumulation defects/increased efflux [i.e., 25,107] have been reported. Thus, current results from MDR cell lines contradict--but do not exclude--that P-gp acts as multidrug transporter. Other models for the mechanism of resistance have been proposed: (1) An energy-dependent permeability barrier working with greater efficacy in resistant cells. This hypothesis is supported by studies of influx which, although few, all except one demonstrate decreased influx in resistant cells; (2) Resistant cells have a greater endosomal volume, and a greater exocytotic activity accounts for the efflux.(ABSTRACT TRUNCATED AT 400 WORDS)

Distinct patterns of phorbol ester-induced downregulation of protein kinase C activity in adriamycin-selected multidrug resistant and parental murine fibrosarcoma cells

Specific activators of protein kinase C (PKC), including the phorbol-ester tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA), can reduce the chemosensitivities of a variety of mammalian tumor cell lines and their cytotoxic drug-selected multidrug resistant (MDR) variants to MDR-linked drugs, thus implicating PKC in the MDR phenotype. Previously, we reported that the adriamycin-selected MDR murine fibrosarcoma cell line UV-2237M-ADRR has approximately twice as much PKC activity as the parental UV-2237M line. In this report, we show that the level of [3H]phorbol-12,13-dibutyrate specific binding activity was elevated 3.5-fold in the MDR cells, thus establishing that phorbol-ester responsive PKC is overexpressed in the MDR line. Phorbol esters mediate downregulation of PKC by stimulating proteolysis of the enzyme, without altering the rate of PKC synthesis. We report that the kinetics of TPA-induced downregulation of PKC activity differ markedly in parental and MDR UV-2237M cells, providing evidence that the overexpression of phorbol-ester responsive PKC in adriamycin-selected MDR UV-2237M-ADRR cells results, at least in part, from a reduced rate of PKC degradation in the cells.

Transient enhancement of multidrug resistance by the bile acid deoxycholate in murine fibrosarcoma cells in vitro

Recent studies have implicated protein kinase C (PKC) activation in drug resistance in vitro. PKC can be activated directly by phorbol-ester tumor promoters as well as by the bile acid deoxycholate. In this report, we demonstrate that deoxycholate, at concentrations that are chronically present in the lumen of the colon in vivo, mimicked phorbol-ester tumor promoters by protecting Adriamycin (ADR)-sensitive and multidrug-resistant (MDR) murine fibrosarcoma UV-2237M cells from ADR cytotoxicity. Deoxycholate also enhanced the resistance of the MDR cell line UV-2237M-ADRR to the cytotoxic effects of vincristine and vinblastine. In contrast to cytotoxic drug-selected MDR phenotypes, deoxycholate-induced drug resistance was transient and required continuous exposure to the bile acid. The protein kinase inhibitor H7 completely reversed the protection against ADR cytotoxicity conferred on UV-2237M-ADRR cells by deoxycholate, providing evidence that deoxycholate exerts its protective effects by a mechanism that involves stimulation of protein phosphorylation and not merely by detergent effects on membrane permeability. PKC consists of a family of at least seven isozymes with distinct modes of activation and substrate specificities. We previously reported that MDR UV-2237M cell lines contain higher levels of PKC activity than the parental ADR-sensitive UV-2237M cell line (O'Brian et al., FEBS Lett 246: 78-82, 1989). The present report shows that PKC-III is a major PKC isozyme in ADR-sensitive and MDR UV-2237M cell lines. Thus, the resistance to ADR induced by the phorbol esters in UV-2237M cell lines provides strong evidence that PKC-III activation confers protection against ADR on ADR-sensitive and MDR UV-2237M cell lines. Furthermore, since deoxycholate is an endogenous molecule in the colonic epithelium, our finding that physiological concentrations of deoxycholate can render cells more resistant to chemotherapeutic drugs in vitro may have implications for the biology and therapy of intestinal cancers.

Retention of vital dyes correlates inversely with the multidrug-resistant phenotype of adriamycin-selected murine fibrosarcoma variants

Retention of the vital dyes rhodamine 123 (R-123) and hydroethidine (HET) correlates inversely with the multidrug resistant phenotypes of the adriamycin (ADM)-selected variants of a uv-induced murine fibrosarcoma cell line (UV-2237M). The differential affinity of these dyes for specific cellular organelles makes them unique compounds for studies of cellular transport. HET enters viable cells freely, is dehydrogenated to ethidium bromide (EtBr), and is subsequently accumulated in the nucleus. Viable cells are impermeable to extracellular EtBr, facilitating kinetic analysis of the efflux of intracellular EtBr. We found that the metabolite EtBr was rapidly cleared by ADM-resistant but not by ADM-sensitive cells. R-123 has a high affinity to mitochondria. Our results show that ADM-sensitive cells retain R-123 whereas the ADM-resistant cells do not. The clearance of both R-123 and EtBr from these cells was inhibited by verapamil. Therefore, R-123 and HET may be considered MDR-associated compounds useful in studying the MDR phenotype of cancer cells. Previously we reported a direct correlation between the level of activity of the calcium- and phospholipid-dependent protein kinase (protein kinases C) and ADM resistance in UV-2237M variant lines. In this report, we demonstrate a direct correlation between cellular calcium and MDR in these cells. Although chelation of extracellular calcium by EDTA did not alter the fluorescence profile of R-123 of the various cell lines, treating the ADM-resistant variants with verapamil restored cellular calcium to the same level as that of the parental cells and, at the same time, retarded the facilitated efflux of R-123 and EtBr and partially reversed cancer cell resistance to ADM.

Increased cellular internalization of amphiphiles in a multidrug-resistant CHO cell line

The uptake of labeled palmitoyl carnitine and palmitoyl lysophosphatidylcholine by CHO cells was studied by measuring the extractability of these amphiphiles by bovine serum albumin. A multidrug-resistant cell line, CHRC5, showed a more rapid uptake, compared with the parental line, of these amphiphiles into a pool that was no longer susceptible to extraction with bovine serum albumin. The more rapid uptake by the drug-resistant cell line was reversed back to the rates observed with the parental cell line in the presence of verapamil, quinacrine or cyclosporin A. These latter three drugs also reverse the multidrug-resistant phenotype. These results demonstrate a relationship between the rate of amphiphile uptake and multidrug resistance.

Level of protein kinase C activity correlates directly with resistance to adriamycin in murine fibrosarcoma cells

In this report, we demonstrate a direct correlation between protein kinase C (PKC) activity and adriamycin (ADR) resistance in mouse fibrosarcoma cells. PKC activity was measured in four murine UV-2237M fibrosarcoma cell lines that differed in the degrees to which they expressed resistance to ADR, which is an inhibitor of PKC. A comparison of the four cell lines revealed a positive correlation between the level of PKC activity and resistance to ADR. Incubation of the cells with the PKC inhibitor H-7 produced a partial reversal of ADR resistance. Taken together, these results suggest a role for PKC in the mechanism of ADR resistance.

Induced multidrug resistance in murine leukemia L1210 and associated changes in a surface-membrane glycoprotein

The aim of this study was to find out whether only resistant cells of the "multidrug-resistant" phenotype show the described changes of plasma membrane glycoprotein (170 kDa) or whether resistant cells that do not express this phenotype reveal corresponding results. Doxorubicin-resistant (L1210dox) and daunorubicin-resistant L1210 ascites tumor cells (L1210dnr) (multidrug-resistant tumor cells) were therefore compared with cytosine-arabino-side-resistant (L1210AraC) and cyclophosphamide-resistant L1210 ascites tumor cells (L1210ctx) (not multi-drug-resistant tumor cells). The resistant cell lines were generated in vivo in tumor-bearing mice and the resistance to cytostatic agents was evaluated in vivo and in vitro. Using the accumulation assay with rhodamine-123, the multidrug resistance can be detected. In order to determine alterations in the plasma membranes we used the monoclonal antibodies 265/F4 and C219, which were prepared against the membrane glycoprotein P170 (170 kDa) in colchicin-resistant Chinese hamster ovary cells. The results demonstrate that L1210dox and L1210dnr tumor cells show an intense immunostaining by the streptavidin/biotinylated-peroxidase-complex method and by the streptavidin/biotin/phycoerythrin immunofluorescence method. In contrast no specific immunostaining was observed in parental (sensitive) and L1210AraC or L1210ctx tumor lines. The results were confirmed by immunoblotting. To determine whether multidrug-resistant DNA sequences were expressed in the multidrug-resistant tumor cells, Northern blots with RNA od sensitive and resistant cells were performed using the clone pcDR1.5. Elevated RNA levels were detected only in resistant cells with the multidrug-resistant phenotype. Thus, the results of this study demonstrate that only resistant cells with the multidrug-resistant phenotype show an increased expression of the membrane 170-kDa glycoprotein.

Expressions of resistance and cross-resistance in teniposide-resistant L1210 cells

Resistance to teniposide (VM-26) by VM-26 selected resistant L1210 cells in culture was attributed to alterations in the flux of VM-26 across the plasma membrane and to functions of homogeneously staining regions that appeared on one or more chromosomes. In the present study, electrophoresis of membrane-cytosol fractions of these resistant sublines demonstrated a protein band, Mr 22 kd, that was not evident in similar fractions of drug-sensitive L1210 cells or three revertant sublines. The distribution of this protein among various cellular fractions could be altered by manipulation of the concentration of calcium ions. A representative subline, LIa5 microM, was observed to have vesicles that reacted with Sudan black B stain, an indication of altered lipid metabolism. The LIa5 microM subline was cross-resistant to etoposide, vincristine, doxorubicin, amsacrine, and actinomycin D. Concentrations of VM-26 that inhibited cell division to the same extent caused an accumulation of fewer cells in the G2 stage of cell division in LIa5 microM cultures than in L1210 cultures. These observations indicate that the LIa5 microM subline expressed multiple drug resistance, as well as changes in the expression of cytotoxicity to VM-26.

Chromosomal location of human P-glycoprotein gene sequences

Nonresponse to chemotherapy may result from the acquisition of multidrug resistance by malignant cells. Overexpression of the 170,000 dalton cell surface P-glycoprotein is associated with this phenotype and this appears to result from amplification of a multigene family coding for this protein. A cDNA encoding a conserved portion of P-glycoprotein has been cloned from hamster cells, and this was used in the present study to localize human P-glycoprotein gene sequences to chromosome 7q36.

Detection of P-glycoprotein in multidrug-resistant cell lines by monoclonal antibodies

One reason for the failure of chemotherapy in the treatment of advanced cancers may be the outgrowth of multidrug-resistant tumour cells. Multidrug resistance has been modelled in numerous mammalian cell lines in which the phenotype is characterized by a pleiotropic cross-resistance to unrelated drugs. In the study reported here, we have produced monoclonal antibodies whose binding to plasma membranes of different multidrug-resistant mammalian cells correlates with the degree of drug resistance. All these antibodies are specific for P-glycoprotein, a cell surface component of relative molecular mass (Mr) 170,000 (170K) that has been described previously, and are directed against three spatially distinct epitopes which define a conserved cytoplasmic domain in the C-terminal region of the P-glycoprotein polypeptide. The conserved nature of P-glycoprotein and its low-level expression is drug-sensitive cells suggest that it has an important function at the cell surface. The monoclonal antibodies against P-glycoprotein described here might serve as diagnostic reagents for clinically unresponsive tumours.