Abstract
Glutathione (GSH), glutathione S-transferases (GSTs), and the multidrug resistance-associated protein 1 (MRP1) have been independently studied for their contributions to drug resistance. Single cDNA transfection experiments have provided inconsistent and disparate conclusions with respect to the importance of GSH and GST in conferring a resistant phenotype. Because these three proteins can act as a concerted coordinated pathway, we reasoned that equivalent increases may be required for enhanced resistance to be expressed. We have assembled these proteins together, or in various combinations, to determine whether they show cooperativity in determining drug response. Increased expression through single cDNA transfection of GSTπ, γ-glutamylcysteine synthetase (γ-GCS) (regulatory plus catalytic subunits), or MRP1 enhanced resistance to a number of anticancer drugs. Cotransfection of GSTπ and GCS, gave higher resistance to doxorubicin, etoposide, and vincristine than with either alone. Resistance toward chlorambucil and ethacrynic acid was similar in cells overexpressing either component or overexpressing GST alone. Coexpression of GSTπ with MRP1 conferred significant resistance above that seen for MRP1 alone to chlorambucil, etoposide, ethacrynic acid, and vincristine. The combination of GCS and MRP1 did not afford additional resistance above MRP1 alone. When all three were transfected, significantly higher levels of resistance were found for doxorubicin and etoposide. These results support the concept that coordinate enhancement of focal thiol elements of detoxification pathways provides a more efficient protective phenotype than do single components alone.
Resistance to chemotherapeutic agents has been a daunting problem to oncologists for decades. Major advances have been made in understanding drug metabolism and disposition, and how adaptive phase II metabolism can result in altered cytotoxicity to anticancer drugs. The glutathioneS-transferase (GST) enzyme system has been implicated in the development of resistance to several anticancer drugs (O'Brien and Tew, 1996). This family of isozymes can catalyze the conjugation of electrophilic compounds to the cellular tripeptide glutathione (GSH). A body of literature indicates that the levels of GST expression at the tissue or cellular level are important determinants for response to chemical insult. Often, increased GST expression is associated with a resistant phenotype in tumors, implicating GST as an adaptive response in cellular protection.
Primary evidence for the role of GST and GSH in drug resistance comes from three sources: 1) analysis of tumor cells from patients before and after the onset of clinical drug resistance, where an increase in GSH and GST occurs after development of resistance (Schisselbauer et al., 1990); 2) an increase in GSH/GST after the selection of acquired resistance to anticancer agents in tumor cell lines (Tew, 1994; Hayes and Pulford, 1995); and 3) analysis of resistance expressed after transfection of particular GST genes into cell lines (Tew, 1994; Hayes and Pulford, 1995). Existing transfection data are not without variability in both results and interpretation. Much of the disparity may result from a baseline variability in expression of the GSH/GST components in the cell lines used for transfection. Although it is important to think of GST as contributory within the whole system, the efficiency of metabolism may rest with the homeostatic interactions among all members of the relevant detoxification pathway. For example, if there is a limit in the amount of GSH available for conjugation, the presence of increased GST may not result in increased detoxification. Furthermore, the ultimate removal of GSH conjugates from the cell will also provide a more rapid clearance of toxic chemicals. There is substantial evidence that one such protein is multidrug resistance-associated protein 1 (MRP1), which functions to sequester and ultimately remove glutathione (GS)-conjugates or other products of phase II metabolism (Leier et al., 1994).
MRP1 is a member of the ATP-binding cassette transporter gene family. Its capacity to confer resistance has been well described in transfection studies (Cole et al., 1994; Breuninger et al., 1995). MRP1 appears to exhibit broad substrate specificity and has been shown to confer resistance to various natural product drugs, including anthracyclines, vinca alkaloids, and epipodophyllotoxins. Resistant lines that overexpress MRP1 can be sensitized by pretreatment with buthionine sulfoximine, an agent which depletes cellular GSH levels (Zaman et al., 1995). Recent experiments indicate that buthionine sulfoximine sensitization is based on the requirement of GSH for MRP1-mediated cellular efflux of some natural product drugs (Rappa et al., 1997). Interestingly, many cell lines selected for resistance to drugs that are part of the MRP1 resistance profile also have increased GSTπ (Tew, 1994; Hayes and Pulford, 1995). Thus, it is apparent that MRP1 serves as an integral component of thiol-based detoxification pathways.
Because electrophilic drugs may be catalytically conjugated to GSH by GST and the resultant thioether product effluxed from a cell by MRP1, we rationalized that each of these components may contribute to resistance in a coordinate manner. In addition, although drugs that have classically been viewed as part of the “multidrug resistant phenotype” are not obvious candidates for GSH conjugation, some may be cotransported with GSH by MRP. Thus, this report elucidates the importance of coordinating the overexpression of phase II detoxification with enhanced efflux. The data support the general conclusion that cooperativity among GSTπ, glutamylcysteine synthetase (γ-GCS), and MRP1 exists.
Materials and Methods
Plasmids.
Human GSTπ cDNA was polymerase chain reaction (PCR)-amplified from mRNA prepared from an ethacrynic acid resistant human colon HT29 cell line. One microgram of RNA was reverse transcribed using a standard protocol. Two rounds of PCR-amplified GSTP1 cDNA were prepared, and a Kozak sequence added before the initiation codon (Kozak, 1978). The primers used in the PCRs were as follows: first PCR amplification: forward, 5′-ATG-CCG-CCC-TAC-ACC-GTC-3′; reverse, 5′-TCA-CTG-TTT-CCC-GTT-GCC-3′; second PCR amplification: forward, 5′-CGC-GGA-TCC-GCA-CCA-TGC-CGC-CCT-ACA-CCG-TG-3′; reverse, 5′-GGG-CCA-GCA-CAG-TGG-TCA-CTG-TTT-CCC-GTT-GCC-3′. PCR products were resolved on a 1% SeaKem gel (FMC, Rockland, ME), and the fragment was excised. cDNA was purified by centrifugation through a Spin-X centrifuge tube filter (Corning Inc., Acton, MA) by standard procedures. The sequence of the GSTπ cDNA was confirmed by nucleotide sequence analysis.
Cell Lines and Transfection.
cDNAs for γ-GCS heavy and γ-GCS light subunits were kindly provided by Dr. Tim Mulcahy (University of Wisconsin, Madison). The cDNAs were cloned into the Not-1 site of pcDNA3.1/Hygro (Invitrogen, Carlsbad, CA). NIH3T3 cells and 3T3/MRP cells (Breuninger et al., 1995) were transfected using the lipofectAMINE (Life Technologies, Rockville, MD) lipid transfection method. The various DNA plasmid constructs were added either alone (GSTπ) or in combination. 3T3/pc and 3T3/MRP/pc lines were made by transfecting NIH3T3 and 3T3/MRP cells with the parental pcDNA3.1 vector. After a 20-h exposure of cells to DNA/lipidamine, cells were allowed to grow in drug-free media for 24 h before colony selection in media containing 175 ug/ml hygromycin (Sigma Chemical Co., St. Louis, MO). Several colonies were isolated and characterized for each type of transfected cell line made. Cells were maintained in Dulbecco's modified Eagle's medium containing 10% fetal calf serum, 100 μg/ml streptomycin, 100 U/ml penicillin, and 2 mM l-glutamine at 5% CO2 and 37°C.
Immunoblot Analysis.
Cytosolic fractions were used for the verification that the cytosolic enzymes GSTπ, γ-GCS heavy, and γ-GCS light were overexpressed in the appropriate cell lines. Fifty micrograms of protein was separated by 12% SDS-polyacrylamide gel electrophoresis. Proteins were transferred to Immobilon-P membranes (Millipore, Bedford, MA) for 4 h at 300 mA in buffer consisting of 0.38 M glycine, 50 mM Tris, 0.1% SDS, and 20% methanol. Gels were stained in Coomassie blue (Bio-Rad, Hercules, CA) to verify complete transfer. Blots were blocked overnight in 5% nonfat dry milk in Tris-buffered saline/Tween 20, followed by a 1-h incubation in primary antisera diluted 1:1000. The GSTπ antisera was provided by Biotrin (Dublin, Ireland), and the MRP1 antisera was previously described (Breuninger et al., 1995). Polyclonal antisera against γ-GCS heavy and γ-GCS light were generated against the peptides GLLSQGSPLSWEETK and LLTHNDPKELLSEAS, respectively, and were used at a 1:1000 dilution. Blots were washed three times for 10 min each before incubation with secondary antiserum. Anti-rabbit peroxidase-linked secondary antisera was purchased from Amersham (Piscataway, NJ) and used at a 1:5000 dilution. Blots were probed with antisera against actin (Amersham) to verify equivalent loading. After three washes for 30 min, blots were visualized using the enhanced chemiluminescence detection kit (NEN Life Science Products, Boston, MA) and quantified by scanning densitometry using NIH Image software.
GSH Measurements.
Intracellular GSH concentrations were measured using the GSH-400 assay kit from OXIS International Inc. (Portland, OR). Briefly, cells were grown to approximately 50 to 70% confluence in 80-cm2 flasks before trypsinization and counting (Coulter Corp., Miami, FL). Approximately 3 × 106 cells were pelleted and resuspended in freshly prepared 5% metaphosphoric acid. The suspension was sonicated for 30 s and spun at 3,000gfor 10 min at 4°C. One hundred microliters of the supernatant was used in the assay for the detection at 400 nm of thione formed from the conjugation of GSH to 4-chloro-1-methyl-7-trifluoromethyl-quinolinium methylsulfate.
Enzymatic Conjugation Assay.
Conjugation of reduced GSH to 1-chloro-2,4-dinitrobenzene (CDNB) was stimulated by the addition of cellular protein as described previously (Habig and Jakoby, 1981). Briefly, 100 μg of S-100 cellular fractions was added to cuvettes containing 1.0 mM CDNB and 1.0 mM GSH at a pH of 6.5 for a final volume of 1.0 ml. Change in absorbance (340 nm) was measured over a span of 3 min to calculate the rate of conjugation of CDNB.
Cell Survival Assays.
Drug sensitivities were determined by the Cell Titer 96 aqueous nonradioactive cell proliferation assay (Promega, Madison, WI). Cells were plated onto 96-well plates at a density of 1500 cells/well in 100 μl of Dulbecco's modified Eagle's medium plus 10% fetal calf serum. After cells were adherent, varying concentrations of drug were added, and the cells were maintained in drug for 72 h. After this period of drug exposure, 20 μl of 2 mg/ml 3-(4,5-dimethylthiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulfophenyl)-2H-tetrazolium, inner salt, and 45.9 ug/ml phenazine methosulfate were added to each well and incubated at 37°C for approximately 1 h. Production of formazan was detected at 490 nm on a 7520 Microplate reader (Cambridge Technology Inc., Cambridge, MA).
Statistical Analysis.
Data from multiple biochemical or cytotoxicity assays were compared by ANOVA analysis followed by Dunnett's multiple comparison tests (GraphPad Prism; GraphPad, San Diego, CA) with statistical differences judged at P < .01.
Results
Establishment of Cell Lines with Various Components of GSH/GST/MRP Detoxification Pathways.
The cDNAs for human GSTπ, γ-GCS heavy, and γ-GCS light subunits were transfected into NIH3T3 fibroblasts or the previously described 3T3/MRP1 transfected fibroblasts (Breuninger et al., 1995). The cDNAs were introduced alone or in combinations. After transfection of the fibroblasts with the various expression plasmids, cells were selected in hygromycin. After several weeks of colony expansion, immunoblots were used to determine which colonies expressed the requisite proteins. The cell lines generated are listed in Table 1. For all the transfectant lines, 4 to 6 separate clonal populations were established and characterized. Data for one clonal cell line was found to be representative of the others, and for reasons of clarity, one set of data is presented. For each culture, no significant differences were found for population doubling time and/or clonogenic potential.
Analysis of Protein Expression.
Figure1A shows the immunoblot of GSTπ in the cell lines in which only GSTπ was added. Expression levels of GSTπ increased approximately 5-fold over cells transfected with the parental vector (3T3/pc). Fig. 1B shows the expression of γ-GCS heavy and light subunits in the 3T3/GCS and 3T3/MRP/GCS lines. Levels of these proteins were increased 2- to 3-fold. Fig. 1C shows the increased expression of all three proteins, GSTπ, γ-GCS heavy, and γ-GCS light. Once again, GSTπ levels were elevated approximately 5-fold over the control 3T3/pc and 3T3/MRP lines, and γ-GCS levels were raised approximately 2- to 3-fold. The MRP immunoblot (Fig. 1D) shows that single cDNA transfectants had approximately 15-fold higher levels compared with 3T3/pc. This increase did not change in the multiple transfectants containing GSTπ, γ-GCS, or the combination thereof. Expression of actin was determined in all lanes to control for equivalent loading. A summary of the quantitative increase in these blots is provided in Table 1.
The activity of GSTπ was determined by assaying the cell lysates for conjugation of CDNB with GSH. Figure 2A shows that compared with either 3T3/pc or 3T3/MRP cells, enzymatic activity increased significantly for each transfectant. These increases are lower than could be expected from the immunoblots. However, CDNB is a general GST substrate, and the specific GSTπ effects may be muted by the other endogenous enzymes in NIH3T3 cells.
As a functional measure of γ-GCS activity, intracellular GSH levels were assessed. Figure 2B shows that 3T3/GCS and 3T3/MRP/GCS cells have significantly higher intracellular GSH levels compared with 3T3/pc. MRP1-transfected cells had generally lower intracellular GSH concentrations, independent of the presence of γ-GCS, a finding that is consistent with the principle that elevated MRP levels may produce an increased efflux of GSH and/or conjugates (Schneider et al., 1995). This would have the net effect of counteracting the increased de novo synthesis enacted by γ-GCS.
Analysis of Drug Sensitivity of Cell Lines Overexpressing GSTπ.
Figure 3shows the survival curves for the various transfectant cell lines. To facilitate comparative analyses, the panels show either 3T3/pc or 3T3/MRP as “controls”. In each case, cell survival was determined after a 72-h exposure to drug. Figure 3 shows the survival curves toward chlorambucil, doxorubicin, ethacrynic acid, vincristine, and etoposide. For each drug, the addition of GSTπ to NIH3T3 cells enhanced resistance, although the increase was not statistically significant for doxorubicin. The greatest change in drug sensitivity for 3T3/π cells was seen with etoposide (9-fold) and chlorambucil (3-fold). Transfection of MRP alone (3T3/MRP) caused a significant enhancement of resistance compared with 3T3/pc for all drugs tested. Addition of GSTπ to MRP caused a further small increase in resistance for all drugs except doxorubicin. The most striking effect was with etoposide, where a further, approximate 4-fold, enhancement in resistance occurred.
Transfection of the γ-GCS holoenzyme also resulted in significant changes in resistance. The cell line 3T3/GCS was generated by transfection of NIH3T3 cells with cDNAs for both the γ-GCS heavy and light subunits. The forced expression of both subunits resulted in elevated levels of GSH (Fig. 2). Survival curves for 3T3/GCS cells indicate modest enhanced resistance to ethacrynic acid and etoposide (∼2-fold) and vincristine and chlorambucil (∼3-fold). When γ-GCS was cotransfected with MRP1, no enhancement in resistance above that associated with MRP1 was found. Enhanced resistance in 3T3/GCS/π cells was equal to or greater than that for 3T3/π or 3T3/GCS cells. For vincristine, the resistance factor associated with the addition of both proteins was additive when compared with either alone, whereas for doxorubicin a greater effect was found with the addition of both GSTπ and GCS. Generally, 3T3/MRP/GCS/π cells did not display a greater resistance to ethacrynic acid, chlorambucil, or vincristine beyond that demonstrated in 3T3/MRP cells. However, more resistance was shown toward etoposide and doxorubicin. For etoposide, the resistance factor in the 3T3/MRP/GCS/π lines was equivalent to that seen in the 3T3/MRP/π line, approximately 4-fold more resistant than the 3T3/MRP cells. As in the 3T3/GCS/π line, the coexpression of GSTπ, γ-GCS, and MRP1 resulted in a greater than additive resistance toward doxorubicin when compared with either GSTπ or γ-GCS with MRP1. The resistance factor increased from approximately 13-fold in 3T3/MRP cells to an overall 100-fold in 3T3/MRP/GCS/π cells (see also Fig.4).
A quantitative comparison of the IC50 values generated from the survival curves is shown in Fig. 4. For each of the five drugs, MRP transfection (3T3/MRP) resulted in a statistically significant enhancement in resistance. In many cases, this was further enhanced by cotransfection of γ-GCS and/or GSTπ. For both doxorubicin and etoposide, 3T3/MRP/GCS/π cells expressed a resistance factor of approximately 100, the highest for any of the drugs tested.
Discussion
Information from drug-selected cell lines often gives the first indication that a particular protein has a role in resistance. However, when chronically exposed to drug insult, a pleiotropic response usually produces an up-regulation of multiple detoxification gene products, which can make evaluation of the contribution of any one protein difficult to assess. Single cDNA transfection experiments offer a more defined system but will not always mimic the in vivo situation. In particular, single transfection of cDNAs for members of the GST family has produced conflicting reports concerning the importance of this gene family (in particular GSTπ) to drug resistance (reviewed in Tew, 1994and in Hayes and Pulford, 1995). At least one plausible explanation for the earlier discrepancies could be the absence of a coordination of cellular metabolism and clearance required to enhance resistance. To demonstrate how coordinate expression influences anticancer drugs, we transfected components of the GSH-based detoxification system in various combinations in recipient cells. We selected a cross-section of anticancer drugs with some relevance to GSH-based metabolism that have been the subject of previous single cDNA transfection analyses. For example, chlorambucil and ethacrynic acid are subject to GST-mediated conjugation with GSH and eventual efflux by MRP (Ciaccio et al., 1991,1996). Doxorubicin, vincristine, and etoposide are component drugs of the multidrug resistant phenotype, and their detoxification/efflux has been linked with GSH/GST and MRP, although the nature of the association is not completely defined.
Ethacrynic acid has a β-unsaturated carbonyl group that provides Michael addition properties. It can react either spontaneously or catalytically (GST) with GSH, and the thioether conjugate is a substrate for MRP. Only low degrees of resistance can be achieved in acquired resistant cells (∼5-fold), and the phenotype is characterized by an increased expression of γ-GCS, GSTπ, and MRP (Ciaccio et al., 1996). The transfection data are consistent with these adaptive changes, where GSTπ, γ-GCS, or MRP as single transfectants give a modest, but significant, increase in resistance. The multiple transfectants show some degree of additivity with an approximate 5-fold resistance achieved for 3T3/MRP/π and 3T3/MRP/GCS/π. Thus, there is a direct relationship between the transfectant data and the acquired resistant phenotype.
A similar response pattern was shown for chlorambucil. GSTπ can catalyze the formation of GS-conjugates with the aziridinium-alkylating species of chlorambucil (Ciaccio et al., 1991). 3T3/π cells had a 2.6-fold increase in GSTπ activity over the control 3T3/pc cells, which gave a 3-fold increase in resistance to chlorambucil. Although GSH levels are typically 1 to 10 mM in most cells (Anderson, 1989), 3T3/GCS cells achieved a 2-fold increase in intracellular GSH that translated to a 3-fold increase in resistance. The combination of GSTπ and γ-GCS produced equivalent resistance to GSTπ or γ-GCS alone. MRP1 alone conferred resistance when compared with 3T3/pc, whereas the combination in 3T3/MRP/π cells showed further enhancement. This finding is the first to demonstrate MRP1 conferred resistance to an alkylating agent and is consistent with previous reports citing MRP1 as a transporter of chlorambucil only when conjugated to GSH (Barnouin et al., 1998; Morrow et al., 1998). Overall, the data suggest that GSH conjugation may be sufficient for decreasing chlorambucil toxicity and that the presence of the MRP1 impacts on cell survival only marginally. As for ethacrynic acid, the maximal degree of resistance reflected the concordance of transfection and acquired resistance data (Tew, 1994; Hayes and Pulford, 1995;O'Brien and Tew, 1996).
The production of reactive oxygen species (ROS) and lipid peroxides is one mechanism by which anthracyclines such as doxorubicin are thought to exert toxicity (Sinha et al., 1987; Poot et al., 1988). Products of oxidative stress, such as acrolein and base propenals, are documented substrates for GSTπ catalysis to GS-conjugates (Berhane et al., 1994). Previous reports have shown that transfection of GSTπ (Nakagawa et al., 1990) or the light subunit of GCS (Tipnis et al., 1999) alone can produce an approximate 2-fold resistance to doxorubicin. In other cases, GSTπ transfection had no impact on survival, particularly when compared with cotransfection of P-glycoprotein (Fairchild et al., 1990). Although the P-glycoprotein can transport a broad range of natural product drugs, there was no indication that transfection conditions altered its expression in any of the cell lines used (data not shown). GS-conjugates of doxorubicin are transported by MRP1, but although it has been suggested that their in vivo occurrence may be possible (Koch et al., 1994), such conjugates have not been identified in cells. Although quantitatively less significant than MRP, incremental increases in resistance are found when GSTπ or γ-GCS are transfected individually or together, implying that thiols affect doxorubicin response. Interestingly, the 3T3/MRP/GCS/π cells show a significant 3-fold increase in resistance compared with 3T3/MRP, a value similar to that for 3T3/GCS/π compared with 3T3/pc. Thus, MRP confers significant resistance, perhaps as a result of direct efflux of doxorubicin (+/−GSH). The additional 3-fold increment provided by γ-GCS and GSTπ may be a function of detoxification of ROS as by-products of doxorubicin metabolism.
Resistance to vincristine was enhanced by each of the component cDNAs as individual transfectants. GS-conjugates of vincristine have not been described and in the absence of anthracycline quinone cycling, it is less likely that ROS will play a large role in vincristine toxicity. There is evidence that vinca alkaloids are subject to oxidation by monoamine oxidases and P-450 microsomal preparations (Rosazza et al., 1992). Clearance of oxidized metabolites of vincristine may in part explain why the addition of GSTπ renders cells less sensitive to cytotoxicity associated with the drug. Increased expression of γ-GCS in 3T3/MRP/GCS cells imparted only a slight increase in resistance to vincristine compared with 3T3/MRP. Although intracellular GSH levels are doubled in 3T3/MRP/GCS cells compared with 3T3/MRP cells, there may be sufficient GSH in the latter to accommodate efficient efflux of vincristine, with further increase in GSH having no additional impact. Consistent with this possibility, biochemical experiments suggest that MRP1-mediated vincristine transport reaches steady state when the GSH concentrations approximate 5 mM (Loe et al., 1998).
Etoposide is another drug for which GS-conjugates have not been described, yet many resistant lines selected in the drug have elevated GSTπ (Tew, 1994). Etoposide also increases GSH export from cells expressing MRP1, suggesting cotransport of etoposide and GSH in a manner similar to that of vincristine (Rappa et al., 1997). We found, once again, that each of the single transfections significantly influenced resistance to etoposide, whether expressed alone or in combination with other members of the GSH detoxification pathway (∼8-fold in 3T3/π, 14-fold in 3T3/GCS/π, escalating to 20-fold in 3T3/MRP, and 100-fold in 3T3/MRP/GCS/π). There is evidence for quinone and semiquinone metabolites of etoposide, and the latter can form conjugates with GSH. Hydroxyl radicals are generated from this metabolism, and as with anthracyclines, it is possible that GSTπ and MRP1 serve protective roles.
For most of the natural product drugs tested, coordinate forced overexpression of MRP1 with GSTπ and the holoenzyme of GCS provided the highest resistance factors. Precise correlations between extent of expression and degree of resistance would be of only limited value because cellular homeostasis of both the endogenous and introduced gene products will complicate any direct stoichiometric assessment. Perhaps of more importance, the general patterns of response support the principle that γ-GCS, GSTπ, and MRP1 function in series for the detoxification of anticancer drugs or products of oxidative stress. The data generated support the concept that a coordinated increase in expression of gene products, which participate in a concerted step-wise detoxification of a drug, provide a generally more effective means of cellular protection. It should be recognized that GSH and thiols in general have a broad role in controlling kinase pathways that lead to cell survival or apoptosis. Many transcription factors are regulated by redox conditions, and recent studies have shown that a NH2-terminal c-jun kinase (JNK) is directly regulated by GSTπ (Adler et al., 1999). Because the multiple transfections significantly influence intracellular redox balance, future experiments will consider how survival may be influenced by more general stress response pathways leading to survival or apoptosis.
Footnotes
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Send reprint requests to: Dr. Kenneth D. Tew, Department of Pharmacology, Fox Chase Cancer Center, 7701 Burholme Ave., Philadelphia, PA 19111. E-mail: kd_tew{at}fccc.edu
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↵1 This work was supported in part by National Institutes of Health Grants CA06927 and RR05539, by National Institutes of Health Grant CA53893 to K.D.T., and by an appropriation from the Commonwealth of Pennsylvania.
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↵2 Present address: New York Medical College, Valhalla, NY 10595
- Abbreviations:
- GST
- glutathioneS-transferase
- GS-conjugate
- glutathione conjugate
- GSH
- glutathione
- MRP1
- multidrug resistance-associated protein 1
- γ-GCS
- γ-glutamylcysteine sythetase
- CDNB
- 1-chloro-2,4-dinitrobenzene
- PCR
- polymerase chain reaction
- ROS
- reactive oxygen species
- Received January 21, 2000.
- Accepted April 17, 2000.
- The American Society for Pharmacology and Experimental Therapeutics