(Received for publication, August 20, 1996, and in revised form, October 30, 1996)
From the John Wayne Cancer Institute, Saint John's Hospital and Health Center, Santa Monica, California 90404
We have previously shown that multidrug-resistant cancer cells display elevated levels of glucosylceramide (Lavie, Y., Cao, H., Bursten, S. L., Giuliano, A. E., and Cabot, M. C. (1996) J. Biol. Chem. 271, 19530-19536). In this study we used the multidrug-resistant human breast cancer cell line MCF-7-Adriamycin-resistant (AdrR), which exhibits marked accumulation of glucosylceramide compared with the parental MCF-7 wild type (drug-sensitive) cell line, to define the relationship between glycolipids and multidrug resistance (MDR). Herein it is shown that clinically relevant concentrations of tamoxifen, verapamil, and cyclosporin A, all circumventors of MDR, markedly decrease glucosylceramide levels in MCF-7-AdrR cells (IC50 values, 1.0, 0.8, and 2.3 µM, respectively). In intact cells, tamoxifen inhibited glycosphingolipid synthesis at the step of ceramide glycosylation. In cell-free assays for glucosylceramide synthase, tamoxifen (1:10 molar ratio with ceramide) inhibited glucosylceramide formation by nearly 50%. In cell cultures, inhibition of glucosylceramide synthesis by tamoxifen is correlated with its ability to sensitize MCF-7-AdrR cells to Adriamycin toxicity. Moreover, treatment of cells with 1-phenyl-2-palmitoylamino-3-morpholino-1-propanol, an inhibitor of glucosylceramide synthesis, likewise sensitized MCF-7-AdrR cells to Adriamycin. It is concluded that high cellular levels of glucosylceramide are correlated with MDR, and that glycolipids are a target for the action of MDR-reversing agents such as tamoxifen. The data entertain the notion that drug resistance phenomena are aligned with cell capacity to metabolize ceramide.
Multidrug resistance (MDR),1 believed to be the basis for tumor cell survival, exhibits intrinsic resistance to multiple drugs on primary exposure to a single drug (1). Of the various biological mechanisms associated with MDR, overexpression of P-gp, a plasma membrane glycoprotein proposed to act as a drug efflux pump, has been most studied (2, 3). We have recently observed that multidrug-resistant cancer cells characteristically display elevated levels of a glycolipid identified as glucosylceramide (4).
Some associations have been drawn regarding the role of lipids in MDR. Reports show that P-gp ATPase activity is dependent on the lipid environment (5), and lipids interact with P-gp substrates (6). Differences in glycerolipid and sphingomyelin compositions of multidrug-resistant and drug-sensitive cells have been reported (7-11), and ganglioside composition of multidrug-resistant and drug-sensitive cells has been examined. Whereas diversity in ganglioside composition was revealed, no definitive correlation with drug resistance was demonstrated (7, 12). Our recent work (4) revealed a correlation between the cellular content of glycosphingolipids and MDR. This indicates a potential role for glycosphingolipids in MDR.
Circumvention of MDR carries major clinical importance. A battery of diverse agents has been shown to inhibit MDR, rendering cells sensitive to chemotherapy (13). These MDR-reversing agents include the calcium channel blockers verapamil and SR33557 (13, 14), antiarrhythmic agents such as quinidine (15), the immunosuppressant cyclosporin A (15, 16), and the antiestrogen anticancer drug tamoxifen (17, 18). The mechanism by which these drugs influence MDR is thought to be via direct binding to P-gp (19, 20), but MDR reversers may also modify cellular components that regulate P-gp. For example, selective expression of protein kinase C isozymes has been correlated with MDR (21), and studies have suggested that P-gp activity may be regulated by protein kinase C (22). An association between inhibition of protein kinase C activity by safingol, a sphingoid base, and reversal of cellular doxorubicin resistance has been demonstrated (23). Other works have revealed a link between sphingomyelinase activity and MDR (24).
Sphingolipids and glycosphingolipids have obligatory functions in cell
proliferation (25-27), neuronal growth (28, 29), cell transformation
(26) and tumor progression (30). Glucosylceramide is the precursor of
all glucosphingolipids. The enzyme that catalyzes the synthesis of
glucosylceramide, glucosylceramide synthase, is central in
glycosphingolipid metabolism. Studies on inhibition of glucosylceramide
synthase by PPMP, a synthetic inhibitor that acts as a ceramide analog,
have revealed a diversity of physiological processes affected by
depleting cells of glucosylceramide and higher glycosphingolipids (27,
28, 31, 32). Deficiencies in -glucosidase, the degrading enzyme, are
the cause of Gaucher's disease (33).
In this work we show that multidrug-resistant cells, as opposed to drug-sensitive cells, glycosylate ceramide with enhanced capacity. Of particular biological relevance are the diverse effects of ceramide and glycosphingolipids on cell homeostasis. Whereas ceramide is suggested to serve as a second messenger for programmed cell death (34), glycosphingolipids are demonstrated to have a role in cell growth (27) and survival (29) and in escape from onset of apoptosis (35). Data from several studies have linked inhibition of glycosphingolipid synthesis to an array of cellular dysfunctions (29, 31, 36-38), thereby highlighting a role for glycolipids in cell health and stressing the importance of enzymes that regulate glycolipid metabolism. We show that accumulation of glucosylceramide in MCF-7-Adriamycin-resistant (AdrR) breast cancer cells is potently blocked by a myriad of chemically unrelated drugs that are known to circumvent MDR. An association between reduction in cellular glucosylceramide content and sensitization of MCF-7-AdrR cells to Adriamycin toxicity is demonstrated. In summation, these results reveal a new action of tamoxifen, pinpoint glucosylceramide synthase as a target for MDR-reversing agents, and define a potential role for glycosphingolipids and their metabolites in MDR.
Sphingosine, sphingomyelin, and ceramides were purchased from Avanti Polar Lipids (Alabaster, AL). C6-ceramide was purchased from LC Laboratories (Woburn, MA). Glucosylceramide (Gaucher's spleen), and DL-erythro-PPMP were from Matreya, Inc. (Pleasant Gap, PA). DL-Threo-PPMP was from Biomol (Plymouth Meeting, PA). Triphenylbutene was kindly provided by Prof. Michael Jarman (Center for Cancer Therapeutics, The Institute of Cancer Research, Sutton, Surrey, United Kingdom), and SDZ PSC 833 was from Sandoz Pharmaceutical Corp. EN3HANCE, L-[3H]serine (21.7 Ci/mmol), [9,10-3H]palmitic acid (56.5 Ci/mmol), and D-[6-3H(N)]galactose (29.5 Ci/mmol) were purchased from DuPont NEN. UDP-[6-3H]glucose (15 Ci/mmol) was from American Radiolabeled Chemicals, Inc. Liquid scintillation mixture (EcoLume) was from ICN Biomedical. Silica Gel G TLC plates were from Analtech (Newark, DE). Solvents were from Fisher Scientific. RPMI 1640 medium (CellgroTM) was purchased from Mediatech (Herndon, VA). FBS was from HyClone (Logan, UT), and culture ware was from Corning-Costar. All other biochemicals were from Sigma.
Cell CultureMCF-7 wild-type and MCF-7-AdrR cells were kindly provided by Dr. Kenneth H. Cowan and Dr. Merrill E. Goldsmith (National Cancer Institute). Cells were maintained in RPMI 1640 medium containing 10% (v/v) FBS, 50 units/ml penicillin, 50 µg/ml streptomycin, and 584 mg/liter L-glutamine. Cells were cultured in a humidified, 6.5% CO2 atmosphere tissue culture incubator and subcultured once a week, using a 0.05% trypsin, 0.53 mM EDTA solution.
Cell Radiolabeling and Analysis of LipidsMCF-7 cells, grown in medium containing 10% FBS, were switched to medium containing 5% FBS. Cell lipids were radiolabeled by adding [3H]serine (2.0 µCi/ml), [3H]palmitic acid (1.0 µCi/ml), or [3H]galactose (1.0 µCi/ml) to the culture medium for the indicated times. After labeling, cell monolayers were rinsed twice with phosphate-buffered saline (pH 7.4), and 2 ml of ice-cold methanol containing 2% acetic acid was added. The cells were scraped free and transferred to glass test tubes (13 × 100 mm), and lipids were extracted (39). After brief centrifugation, the resulting organic lower phase was withdrawn and evaporated under a stream of nitrogen. Lipids were resuspended in 100 µl of chloroform/methanol (1:1, v/v), and aliquots were applied to TLC plates. When using [3H]galactose, radiolabeled cells were washed twice with phosphate-buffered saline and transferred to glass tubes with methanol (2 ml), and glucosylceramides and gangliosides (2.5 µg of each) were added to aid recovery. Lipids were extracted by the addition of water (2 ml) and 2 ml of chloroform. The lower phase was withdrawn, and the upper phase was washed two times with consecutive additions of chloroform. The pooled organic lower phase was treated as above. Lipid analysis was carried out by TLC using solvent system I (chloroform/methanol/ammonium hydroxide; 40:10:1, v/v/v), for glucosylceramide separation, solvent system II (chloroform/methanol/water; 60:40:8, v/v/v), for glycosphingolipid separation, or solvent system III (chloroform/methanol/acetic acid/water; 50:30:7:3, v/v/v/v) for sphingomyelin separation. For determination of ceramides, an aliquot of the chloroform-soluble lipid was base-hydrolyzed in 0.1 N KOH in methanol for 1 h at 37 °C. The lipids were re-extracted, and ceramide was separated by TLC using solvent system IV (hexane/diethyl ether/formic acid; 60:40:1, v/v/v).
Radiochromatograms were sprayed with EN3HANCE and exposed for 3-7 days for autoradiography. TLC areas, aligned with bands on the autoradiographs or with iodine-stained commercial lipid standards, were scraped from the plate. Water (0.5 ml) was added to the plate scrapings, followed by 4.5 ml of EcoLume counting fluid, and the samples were quantitated by liquid scintillation spectrometry.
Lipid Mass AnalysisCell lipids were analyzed by TLC separation and charring of the chromatogram. Briefly, total cellular lipids were extracted by the method of Bligh and Dyer (39), and equal aliquots (by weight) from each sample were spotted on TLC plates. Plates were developed in the desired solvent system, air dried for 1 h, and sprayed using a 35% (v/v) solution of sulfuric acid in water. The lipids were charred by heating in an oven at 180 °C for 30 min.
Glucosylceramide Synthase AssayThe assay was performed
according to the method of Shukla and Radin (40) with minor
modifications. Components of the lipoidal substrate were freed of
solvent under a stream of nitrogen (in borosilicate glass tubes) and
sonicated as described, omitting the overnight lyophilization step. The
enzymatic assay was performed with 100 µM UDP-glucose
(230,000 cpm/tube), 2 mM -NAD, 1 mM
dithiothreitol, 2 mM EDTA, 10 mM
MgCl2, 0.1 M Tris buffer (pH 7.4), 0.2 mg of MCF-7-AdrR cell homogenate protein/tube, and liposomal substrate (containing 200 nmol of ceramide), in a total volume of 0.2 ml. Drugs
(20 nmol) were added to components of the lipoidal substrate before
solvent evaporation and sonication. The reaction was incubated at
37 °C for 90 min, lipids were extracted, and radiolabeled
glucosylceramide formed was analyzed by TLC (solvent system I) and
liquid scintillation spectrometry.
Cells were seeded in 96-well plates (2000 cells/well), in 0.1 ml of RPMI 1640 medium containing 5% FBS, and incubated at 37 °C for 24 h before drug addition. A drug was added in medium (0.1 ml), and the cells were incubated at 37 °C for an additional 4 days. The cytotoxic activity of a drug was determined using the Promega CellTiter 96TM AQueous cell proliferation assay kit. Each experimental point was performed in six replicates. Solution (20 µl) was aliquoted to each well, and the cells were incubated for 2-3 h, or until an optical density of 0.9-1.0 was obtained as a highest reading. Absorbance at 490 nm was recorded using an enzyme-linked immunosorbent assay plate reader (Molecular Devices, San Diego, CA).
Vehicles for ReagentsTamoxifen and triphenylbutene were
prepared as 20 mM stock solutions in acetone. Cyclosporin A
was prepared as a 1.0 mM stock solution in ethanol.
Verapamil was prepared as a 10 mM stock solution in water.
Adriamycin was prepared as a 1.0 mM stock solution in water, and PPMP was prepared as a 2.0 mM stock solution in
ethanol/water (1:1, v/v). All stock solutions were stored at 20 °C
until use. Media containing drugs were prepared just prior to use.
Vehicle was present in control (minus drug) cultures.
In a previous article (4) we showed that glucosylceramide
accumulates in multidrug-resistant cancer cells. This work has been
extended to assess the relationship of glycolipids to MDR. The effect
of tamoxifen, an antiestrogen with MDR-reversing properties (17, 18),
on glucosylceramide metabolism was examined in MCF-7-AdrR cells.
Initial experiments revealed that inclusion of tamoxifen in the culture
medium largely depressed cellular glucosylceramide levels, as
determined by mass analysis (TLC and charring). Verification of this
effect is shown in cells labeled with [3H]galactose (Fig.
1). Cells were preincubated, without or with tamoxifen,
and the extent of glycosphingolipid formation was surveyed by TLC
autoradiography. As shown (Fig. 1), tamoxifen treatment caused a
reduction in labeling of glycosphingolipids, subduing glucosylceramide,
lactosylceramide, and ganglioside levels by 69, 74, and 33%,
respectively (data based on TLC analysis of tritium).
MDR-reversing Drugs Inhibit Cellular Glucosylceramide Formation
In addition to tamoxifen, we evaluated two other
MDR-reversing agents, verapamil and cyclosporin A, and assessed a
structural analog of tamoxifen, triphenylbutene, which is devoid of the
basic amino side chain. [3H]Glucosylceramide formation
was markedly inhibited by all MDR-reversing drugs but not by the
tamoxifen analog (Fig. 2). Based on cpm of tritium, the
order of potency for inhibition of glucosylceramide formation in intact
cells was tamoxifen > cyclosporin A verapamil (65, 49, and 38% inhibition, respectively). Triphenylbutene had only a minor
effect (13% inhibition), indicating that the basic amino side chain is
essential. Inhibition of glucosylceramide formation by agents that
circumvent MDR is not restricted to MCF-7-AdrR cells, as similar
results have been obtained in KB-V-1 (vinblastine-resistant) epidermoid
carcinoma cells (data not shown).
The concentration dependence of drugs for inhibition of
glucosylceramide formation in MCF-7-AdrR cells is shown in Fig.
3. During a 24-h incubation, tamoxifen, verapamil, and
cyclosporin A induced half-maximal inhibition (IC50) of
cellular [3H]glucosylceramide formation at 1.0, 0.8, and
2.3 µM, respectively. Tamoxifen was the most efficient
inhibitor of glucosylceramide formation, with the highest maximal
effect and a low IC50 value. The effective concentrations
used here are within the range of clinical use, since treatment with
these drugs typically results in 0.5-5 µM drug
concentrations in sera of patients (15, 41, 42). The time frame for
tamoxifen-induced inhibition of glucosylceramide formation is shown in
Fig. 4. Uptake and incorporation of the radiolabeled
precursor, [3H]palmitic acid, was similar in control and
tamoxifen-treated cells (Fig. 4A), showing that tamoxifen
does not interfere with transport or overall use of palmitic acid. Fig.
4B shows that tamoxifen retards glucosylceramide synthesis
as early as 15 min (572 ± 102 cpm in tamoxifen-treated cells
versus 1237 ± 53 cpm in control cells). In contrast,
sphingomyelin formation was not altered by tamoxifen during the 4-h
incubation period (Fig. 4C).
Mechanism of Tamoxifen Action
Pulse-chase experiments using
[3H]galactose-labeled MCF-7-AdrR cells revealed that the
degradation rates of [3H]glucosylceramide were similar in
the presence and absence of tamoxifen. The data suggest that
tamoxifen-governed changes in glycosphingolipid levels result from
inhibition of synthesis. Tamoxifen inhibition of glucosylceramide
synthesis may result from influences on ceramide generation; however,
experiments revealed that levels of radiolabeled ceramide paralleled
one another in tamoxifen-treated and tamoxifen-naive cultures during
the 4-h time frame (data not shown), similar to the experiment of Fig. 4. This raised the possibility that tamoxifen action is targeted to
glycosylation of ceramide. A short chain analog of ceramide, C6-ceramide, which is readily transported into cultured
cells (43), was used to evaluate the influence of tamoxifen on ceramide glycosylation. Fig. 5 shows the spectrum, by
autoradiograph, of cellular [3H]galactose-labeled
glycosphingolipids formed in the presence (middle lane) or
absence (left lane) of C6-ceramide. The
formation of C6-glucosylceramide, migrating just below the
natural glucosylceramide doublet, was clearly visible in cells
incubated with C6-ceramide (Fig. 5, middle
lane). In the presence of tamoxifen (Fig. 5, right lane), conversion of C6-ceramide to
C6-glucosylceramide was inhibited by 54% (based on tritium
incorporation). These results imply that tamoxifen inhibits ceramide
glycosylation, a reaction catalyzed by glucosylceramide synthase (25).
Cell-free assays of glucosylceramide synthase demonstrated that
tamoxifen, at a 1:10 molar ratio with ceramide, inhibited
glucosylceramide formation by 45% (1,467 ± 104 versus
809 ± 114 pmol [3H]glucosylceramide synthesized/mg
protein; n = 3). The tamoxifen analog triphenylbutene
was devoid of inhibitory activity. The threo enantiomer of
PPMP, known to be the active form (44), inhibited glucosylceramide
synthase activity by 85% in the cell-free reaction, whereas the
erythro isomer was ineffective.
Correlation between Recovery of Adriamycin Toxicity and Modified Glucosylceramide Metabolism
The ability of tamoxifen to reverse
MDR was evaluated by exposing MCF-7-AdrR cells to increasing
concentrations of Adriamycin in the absence or presence of a sublethal
concentration of tamoxifen (or analog). The effect of tamoxifen and
triphenylbutene on Adriamycin toxicity in MCF-7-AdrR cells is shown in
Fig. 6A. In the presence of tamoxifen, the
dose-response curve for Adriamycin toxicity was shifted to lower
concentrations. The maximal cytotoxic effect of Adriamycin alone was
achieved at 5.0 µM (28% cell death), whereas in the
presence of tamoxifen, the same concentration of Adriamycin (5.0 µM) caused 60% cell death. In contrast, triphenylbutene
had no effect on Adriamycin toxicity (Fig. 6A). Cellular
[3H]glucosylceramide levels were analyzed at 48 h
under the same conditions as the experiment in Fig. 6A. As
shown in Fig. 6B, Adriamycin alone (2.5 µM)
caused minor diminution (17%) of glucosylceramide; this is similar
with the minor effect of Adriamycin (2.5 µM) on MCF-7-AdrR cell survival (Fig. 6A). Tamoxifen at 5.0 µM markedly retarded glucosylceramide synthesis (Figs
1, 2, 3, 4, 5) but alone was not toxic (Fig. 6A). However, addition
of tamoxifen to the Adriamycin regimen caused 72% inhibition of
glucosylceramide production (Fig. 6B), and together these
agents were cytotoxic (Fig. 6A). Triphenylbutene, when mixed
with Adriamycin, did not enhance cell killing, nor was this combination
effective in inhibiting glucosylceramide production.
PPMP Sensitizes MCF-7-AdrR Cells to Adriamycin
There is
currently no evidence that PPMP, a chemical inhibitor of
glucosylceramide synthase, possesses MDR-reversing activity. Fig.
7A shows the dose response for PPMP influence
on glucosylceramide synthesis in MCF-7-AdrR cells. The enzyme inhibitor
PPMP shows a strikingly similar dose-response relationship with
tamoxifen (Fig. 3) for inhibition of glucosylceramide synthesis in
intact cells. Maximal reduction in cellular glucosylceramide levels
(86% inhibition) occurred at 5.0 µM PPMP, with a
calculated IC50 of 0.9 µM. A concurrent
effect of PPMP as a chemosensitizer is revealed by the data of Fig.
7B, demonstrating an enhancement of Adriamycin toxicity in
MCF-7-AdrR cells when used in combination. Whereas Adriamycin was
largely without influence on diminishing cell survival, the addition of
PPMP to the Adriamycin regimen effectively decreased cell survival.
Ceramide Metabolism
Although at 4 h after tamoxifen addition, the levels of radiolabeled ceramide were not altered, compared with control, combination treatment of MCF-7-AdrR cells with tamoxifen and Adriamycin for extended time led to an elevation in ceramide. Following the protocol of Fig. 6, a 2-day exposure of cells to tamoxifen (5.0 µM) and Adriamycin (2.5 µM) caused a 300% increase in cellular radiolabeled ceramide. Therefore, the increased cell death, elicited by tamoxifen plus Adriamycin, correlated with a depletion of glucosylceramide (Fig. 6B) and a concomitant increase in ceramide. Preliminary data using the cyclosporin A analog SDZ PSC 833 solely shows that it too increased the levels of ceramide in MCF-7-AdrR cells.
Multidrug-resistant cells are characterized by high resistance to drug toxicity (1). The resistance is mediated at the cellular level by several mechanisms, including overexpression of proteins (i.e. P-gp), alteration of drug transport and metabolism, and repair of drug-induced damage (2). The present study is the first to introduce alteration of glucosylceramide metabolism with the action of MDR-reversing agents. The concept of glycosphingolipid involvement in cellular MDR was put forth in our recent study that identified glucosylceramide as the principle lipid accumulating in a number of multidrug-resistant cell types (4).
Chemosensitizers, agents that increase the sensitivity of multidrug-resistant cells to the toxic influence of previously less effective drugs, are intriguing in their mode of action. One challenge in cancer chemotherapy is to understand the molecular mechanisms by which chemosensitizers circumvent drug resistance. Tamoxifen has been reported to reverse MDR via direct binding to P-gp (18, 20). Here a new cellular target of tamoxifen, the glycosphingolipid pathway, has been identified. Tamoxifen is shown to potently inhibit production of glucosylceramide and concomitantly to suppress synthesis of some higher gangliosides in MCF-7-AdrR cells. Tamoxifen may be a general modulator of glycosphingolipid metabolism, as a similar inhibitory effect was elicited by the drug in KB-V-1, a vinblastine-resistant epidermoid carcinoma cell line (data not shown). In addition, verapamil and cyclosporin A, two well known MDR-reversing agents, also retarded glucosylceramide formation, suggesting that this mechanism of action is a common denominator in the chemosensitizing process.
To examine the mechanism of glucosylceramide depletion by tamoxifen, a cell-permeable short chain analog of ceramide (C6-ceramide) was incubated with intact cells. Glycosylation of C6-ceramide to C6-glucosylceramide clearly occurs in MCF-7-AdrR cells; however, this glycosylation step was inhibited by tamoxifen. Additionally, direct measurements of cell-free glucosylceramide formation revealed inhibition by tamoxifen. Structural specificity for inhibition was demonstrated using triphenylbutene, a tamoxifen analog devoid of the dimethylethanolamine moiety.
An objective of the present study was to determine whether inhibition of glucosylceramide synthesis was associated with MDR circumvention. To assess the MDR reversal efficacy of tamoxifen, the sensitivity of MCF-7-AdrR cells to Adriamycin toxicity was studied in an in vitro growth assay (45, 46). Tamoxifen sensitized MCF-7-AdrR cells to Adriamycin and strongly inhibited glucosylceramide synthesis. These experiments also afforded the opportunity to investigate glycolipid metabolism at longer times after drug addition. Although at early times after tamoxifen addition (up to 4 h), ceramide metabolism was similar in control and tamoxifen-treated cultures, data from preliminary experiments demonstrated that at extended times cellular ceramide increased when Adriamycin and tamoxifen were used in combination. An increase in cell ceramide was likewise elicited by the MDR-reversing agent SDZ PSC 833 (data not shown). In light of recent work showing that daunorubicin promotes cellular ceramide elevation and apoptosis (47), our data present the intriguing theory that Adriamycin and tamoxifen work together to enhance the levels of cellular ceramide. Our results align the capacity of drugs that modify glucosylceramide metabolism with circumvention of MDR. This idea was extended using PPMP, an inhibitor of glucosylceramide synthase (31). In our study, PPMP inhibited glucosylceramide synthesis in the low micromolar range (IC50, 0.9 µM). Intriguingly, PPMP, at a concentration shown to maximally inhibit glucosylceramide synthesis, although having no influence on cell viability, induced sensitization of MCF-7-AdrR cells to Adriamycin (Fig. 7). It should be noted that at high concentrations (>30 µM), PPMP acts as a toxic lipophilic amine (48).
Although the phenomenon of MDR involves multiple cellular adjustments, it is now compelling to assign, as an important facet, the interplay of glycosphingolipids. Glucosylceramide may play a role in acquiring and/or maintaining MDR (4), as reducing the levels of glucosylceramide in multidrug-resistant cells treated with tamoxifen appears to render cells sensitive to the toxic insult of chemotherapeutic agents (Figs. 6 and 7). In addition, increases in ceramide, which accompanied glucosylceramide depletion when cells were treated with Adriamycin and tamoxifen, ascribe a glycolipid relationship in MDR reversal of a more complex nature. With regard to neoplasia, expression of various glycosphingolipids on the cell surface has been correlated with mechanisms of acquiring and maintaining a cancer phenotype and tumor progression (26, 30-32, 49). In work divorced from MDR, the glucosylceramide content of cells has been shown to be influential on epidermal homeostasis (50).
Drug resistance continues to be a major obstacle to successful chemotherapy. Clues to the molecular aspects of drug resistance will supply valuable tools to combat MDR. At present it is not known whether glycolipids influence P-gp activity or whether P-gp, in some fashion, regulates glycolipid metabolism. On the other hand, regarding estrogen receptor-independent actions (51-54), tamoxifen has long been viewed with curiosity, particularly with reference to reversal of MDR (55) and synergy in combination chemotherapy (56, 57). In view of the data presented herein, it is suggested that tamoxifen can increase cellular susceptibility to chemotherapeutic agents via a glycosphingolipid-governed avenue, and we propose that tamoxifen-induced MDR reversal is, in part, dependent on fine-tuned regulation of ceramide metabolism.