Reduced topoisomerase II and elevated alpha class glutathione S-transferase expression in a multidrug resistant CHO cell line highly cross-resistant to mitomycin C.

We have isolated a multidrug-resistant derivative of Chinese hamster ovary CHO-K1 cells by exposure to progressively increasing concentrations of Adriamycin. This cell line, designated CHO-Adrr, was 27-fold more resistant than the parental line to Adriamycin and showed similar degrees of cross-resistance to several other topoisomerase II (topo II) inhibitors, including mitoxantrone, daunomycin and etoposide. CHO-Adrr cells showed a lower (4-fold) level of cross-resistance to vincristine and colchicine, drugs associated with the multidrug-resistant phenotype. While CHO-Adrr cells showed no enhanced resistance to several mono- and bi-functional alkylating agents or to UV and ionizing radiation, they were greater than 80-fold resistant to mitomycin C (MMC). There was a 5-fold decreased level of daunomycin accumulation in CHO-Adrr cells compared to CHO-K1 cells and this was associated with increased drug efflux. The resistant cells had amplified multidrug resistance gene (mdr) sequences and overexpressed (mdr) mRNA. Verapamil was able to completely reverse Adriamycin resistance but reversal of MMC resistance was only partial, with residual 23-fold resistance. CHO-Adrr cells expressed a 4-fold reduced level of topo II protein but overexpressed an alpha class (basic) glutathione S-transferase (GST). Analysis of cell hybrids showed that while the level of resistance to Adriamycin dropped by a factor of 3 in CHO-K1/CHO-Adrr hybrids compared to CHO-Adrr/CHO-Adrr hybrids, resistance to MMC dropped 10-fold. Thus, CHO-Adrr cells appear to exhibit simultaneously several different drug resistance mechanisms including MDR and GST overexpression, and topo II reduction.     

Establishment and characterization of adriamycin-resistant human colorectal adenocarcinoma HCT-15 cell lines with multidrug resistance

The multidrug resistance (MDR) phenotype, either intrinsic and/or acquired, is discussed in relation to several MDR-associated markers such as P-glycoprotein (P-gp) encoded by mdr1, multidrug-resistance-associated protein (MRP) encoded by MRP and lung-resistance-associated protein (LRP) encoded by LRP. Well-characterized in vitro models are required to elucidate the mechanisms of MDR. The aim of the present study is the establishment of a drug-resistant subline from human colorectal adenocarcinoma HCT-15 that intrinsically expresses moderate levels of P-gp, MRP and LRP. Three adriamycin-resistant sublines (HCT-15/ADM1, HCT-15/ADM2 and HCT-15/ADM2-2) were established by stepwise exposure in growth medium that was supplemented with 25-200 ng/ml adriamycin-resulting in a 2.2- to 7.8-fold increase in IC(50) values by using the XTT assay. They were cross-resistant to MDR-related drugs, epirubicin, mitoxantrone, vincristine, etoposide and taxol, but not the MDR-unrelated drug, mytomycin C. The resistance to adriamycin was confirmed in vivo by a lack of sensitivity in athymic nude mice. Gene expression data for mdr1/P-gp, MRP/MRP and LRP/LRP on both mRNA and protein levels demonstrated that the molecules contributing to MDR in resistant sublines are mainly P-gp and partially MRP. The newly established adriamycin-resistant sublines of HCT-15 will provide clinically relevant tools to investigate how to overcome drug resistance and elucidate possible mechanisms of acquired MDR in human colon cancer.     

Multiple mechanisms of adriamycin resistance in the human leukemia cell line CCRF-CEM

CEM cells exhibiting a 25-fold (C25X) or 80-fold (C80X) increase in resistance to adriamycin were isolated and characterized. C25X cells were cross-resistant to daunomycin and etoposide (VP-16) but not to vincristine or colchicine. These cells were not defective in the cellular accumulation of drug and did not contain detectable levels of P-glycoprotein. Continued exposure of C25X cells to adriamycin resulted in increased levels of resistance and additional phenotypic changes. These cells (C80X) now contained high levels of P-glycoprotein and were cross-resistant to a variety of agents including vincristine and colchicine. A fluorometric assay for DNA unwinding was used to measure levels of drug-induced DNA breaks in sensitive and C25X resistant cells. Studies carried out with VP-16, 4'9-acridinyl-aminomethanesulfon-m-anisidide (m-AMSA), adriamycin, or daunomycin showed that the level of drug-induced DNA strand breakage in resistant cells was considerably less than that occurring in drug-treated sensitive cells. These studies, therefore, show that treatment of CEM cells with adriamycin resulted in a nuclear alteration that contributed to drug resistance. They also demonstrate that prolonged treatment of cells with adriamycin resulted in membrane alterations that affect cellular drug accumulation. Adriamycin resistance in CEM cells can thus occur as a result of at least two distinct mechanisms.     

Spontaneous Reversal of P‐Glycoprotein Expression in Multidrug Resistant Cell Lines*

Abstract: Increased expression of P‐glycoprotein encoded by the mdr‐1 gene is a well‐characterised mechanism for resistance to cancer chemotherapeutic drugs in cell lines. However, the P‐glycoprotein expression after removal of the selection pressure has not fully been elucidated. The stability of P‐glycoprotein expression in the presence (+) and absence (?) of vincristine (30 or 150 nM) was studied in multidrug resistant K562 cell lines (VCR30+, VCR150+, VCR30? and VCR150?) for 11 months. The P‐glycoprotein protein and mdr‐1 mRNA levels were determined at regular intervals using flow cytometry and real‐time PCR, respectively. Chemosensitivity to a panel of antineoplastic drugs was measured using an MTT assay. The presence of vincristine (VCR30+ and VCR150+) resulted in high and stable levels of P‐glycoprotein and mdr‐1 mRNA during the whole period compared to wild type. As for the VCR30? and VCR150? subcultures, the expressions of P‐glycoprotein and mdr‐1 mRNA were stable for five months, and then the levels decreased rapidly. Concomitantly, the sensitivity to drugs known as P‐glycoprotein substrates was restored. In conclusion, resistant cells growing in the presence of the inducing drug have a stable P‐glycoprotein expression and resistance level, but removing the inducing drug may result in a sudden and rapid lowering of P‐glycoprotein and mdr‐1 mRNA levels as long as five months after drug withdrawal.     

Development and properties of an etoposide-resistant human leukaemic CCRF-CEM cell line

Etoposide (VP-16) and several other unrelated anti-tumour agents appear to act by inhibiting the enzyme DNA topoisomerase II. We report here the development and characterization of an etoposide-resistant human leukaemic CCRF-CEM cell line, CEM/VP-1. The cell line was 15-fold more resistant to etoposide than the parental CEM cells and exhibited cross-resistance to other topoisomerase II inhibitors including teniposide, m-AMSA, and doxorubicin. CEM/VP-1 cells exhibited only a low level cross-resistance to the Vinca alkaloids, vinblastine and vincristine, known inhibitors of mitotic spindle formation. As a first step in defining the mechanism of resistance to etoposide, we compared the levels of topoisomerase II activity and its drug sensitivity in nuclear extracts from the resistant and sensitive CEM cells. As determined by a kinetoplast DNA decatenation assay, the level of DNA topoisomerase II activity in CEM/VP-1 nuclear extracts was approximately 2-fold lower than that in CEM cells, and the activity appeared to be resistant to inhibition by etoposide. Furthermore, the DNA topoisomerase II activity in CEM/VP-1 nuclear extracts did not promote the etoposide-dependent cleavage of pBR322 DNA observed with extract from sensitive cells. These results suggest that etoposide resistance in the CEM/VP-1 cell line may at least in part be due to an altered topoisomerase II, or associated factor, resulting in a reduced ability to induce DNA cleavage in the presence of drug.     

Mechanisms of multidrug resistance in HL60 cells. Analysis of resistance associated membrane proteins and levels of mdr gene expression

HL60 cells isolated for resistance to Adriamycin do not contain P-glycoprotein, as determined with immunological probes. These cells, however, are multidrug resistant and defective in the cellular accumulation of drug. In view of these findings, we have examined in greater detail certain properties of the HL60/Adr cells and have compared these properties to an HL60 drug-resistant isolate (HL60/Vinc) which contains high levels of P-glycoprotein. The results of these studies demonstrated that verapamil induces a major increase in cellular drug accumulation in both HL60/Adr and HL60/Vinc isolates. An 125I-labeled photoaffinity analog of verapamil labeled P-glycoprotein contained in membranes of HL60/Vinc cells. In contrast, this agent did not label any protein selectively associated with drug resistance in membranes of the HL60/Adr isolate. The photoactive dihydropyridine calcium channel blocker [3H]azidopine and [125I]NASV, a photoaffinity analog of vinblastine, labelled P-glycoprotein in membranes from HL60/Vinc cells, whereas in experiments with the HL60/Adr isolate there was no detectable labeling of a drug resistance associated membrane protein. Additional studies have been carried out to analyze membrane proteins of HL60/Adr cells labeled with the photoaffinity agent 8-azido-alpha-[32P]ATP (AzATP32). The results demonstrate that this agent labeled a resistance associated membrane protein of 190 kilodaltons (P190). P190 is essentially absent in membranes of drug-sensitive cells. Labeling of P190 with AzATP32 in membranes of resistant cells was blocked completely when incubations were carried out in the presence of excess unlabeled ATP. Additional studies were carried out to analyze mdr gene amplification and expression in sensitive and resistant cells. Experiments carried out with human 5',mdr1 (1.1 kb) and mdr3 (1.0 kb) cDNAs demonstrate that both of these sequences were highly amplified in the HL60/Vinc isolate. Only the mrd1 gene sequence however, was overexpressed. In contrast, there was no detectable amplification or overexpression of mdr1 or mdr3 sequences in HL60/Adr cells. The results of this study thus identify a new nucleotide binding protein which is overexpressed in membranes of HL60 cells isolated for resistance to Adriamycin. P190, which exhibits properties distinct from P-glycoprotein, possibly functions in the energy-dependent drug efflux system contained in the HL60/Adr resistant isolate.     

Multidrug resistance in a small cell lung cancer line: rapid selection with etoposide and differential chemosensitization with cyclosporin A.

We developed a multidrug resistant small cell lung cancer line, VPR-2, by exposing H69 parent cells to etoposide (20 microM) for 1 h daily for 3 days every 21-28 days, a schedule similar to that used in the clinic. Resistance (20-fold) to the cytostatic and DNA cleavage activities of etoposide emerged after the third treatment, and this phenotype was stable in the absence of drug exposure for 2.5 years. VPR-2 cells exhibited cross resistance to intercalating agents and vinca alkaloids, but remained sensitive to X-radiation, cisplatin and 5-fluorouracil. The human mdr1 gene was overexpressed in the resistant line, but steady-state concentrations of etoposide were reduced only 1.5-fold. Topoisomerase II catalytic and etoposide stimulated DNA cleavage activity in nuclear extracts from both lines were identical despite retention of a 3-fold level of resistance to etoposide-induced strand breaks in isolated nuclei from VPR-2 cells. Cyclosporin A and verapamil, both of which bind to P-glycoprotein, enhanced accumulation of etoposide in VPR-2 cells, and H69 cells to a lesser extent. Yet only cyclosporin A was effective in differentially enhancing etoposide cytostasis in VPR-2 relative to H69. In VPR-2 whole cells, cyclosporin A enhanced etoposide-induced DNA single-strand break frequency 9-fold but had no effect in isolated nuclei. Rapid selection of this line with a clinically relevant drug exposure schema and stability of the resistant phenotype suggest these cells may have been a steady subpopulation of the parent line through years of serial passage in vitro.(ABSTRACT TRUNCATED AT 250 WORDS)     

KB细胞耐药株的建立及其耐药机制的探讨

用对长春新碱(VCR)敏感的KB细胞为亲本,通过诱变剂甲基磺酸乙酯刺激,然后在培养液中加入浓度递增的CVR,得到耐药细胞株KB_V200。此细胞株对VCR的耐受程度约为KB细胞的175倍。对其它抗肿瘤药物如紫杉醇、秋水仙碱和阿霉素等也有不同程度的交叉耐药性。进一步研究表明,KB_V200对³H-VCR的蓄积明显减少,且耐药基因(mdr1)表达增加。钙通道阻滞剂维拉帕米(Ver)可增加KB_V200对³H-VCR的蓄积和对VCR的敏感性。这些结果提示,KB_V200耐药的机制可能是由于mdr1基因表达增加,产生过量的p-糖蛋白,使药物外排增多所致。     

Acquired drug resistance in human lung carcinoma xenografts

The development of resistance to vincristine and dactinomycin has been investigated in a human epidermoid lung xenograft line grown in nude mice. With 1 mg/kg BW vincristine and 0.5 mg/kg BW dactinomycin per passage, resistance of the solid tumors was visible already at the second transplantation. The vincristine-resistant subline showed cross-resistance to dactinomycin and doxorubicin, and the dactinomycin-resistant subline only to vincristine. To determine whether multidrug resistance genes were overexpressed in the resistant sublines, slot blots were performed using the cDNA probe pcDR 1.5. Slightly elevated RNA levels could be detected in the vincristine-resistant subline and in the dactinomycin-resistant subline.     

Effects of ginseng saponin on modulation of multidrug resistance

Multidrug resistance (MDR) has been a major problem in cancer chemotherapy. To overcome this problem, we prepared minor ginsenosides stereoselectively from ginseng saponins and searched for a ginseng component which is effective for inhibition of MDR. MDR inhibition activity was determined by measuring cytotoxicity to MDR cells using multidrug resistant human fibrocarcinoma KB V20C, which is resistant to 20 nM vincristine and expresses high level ofmdr1 gene. Of several ginseng components, 20(S)-ginsenoside Rg₃, a red ginseng saponin, was found to have the most potent inhibitory activity on MDR and it’s concentration capable of inhibiting 50% growth was 82 μM.     

Contribution of mdr1b-type P-glycoprotein to okadaic acid resistance in rat pituitary GH3 cells

Okadaic acid as well as other, structurally different, inhibitors of serine/threonine phosphatases 1 and 2A induce apoptosis in pituitary GH3 cells. Incubation with stepwise raised concentrations of okadaic acid resulted in the isolation of cells that were increasingly less sensitive to the cytotoxic effect of this agent. After about 18 months cells were selected that survived at 300 nM okadaic acid, which is about 30 times the initially lethal concentration. This study revealed that a major pharmacokinetic mechanism underlying cell survival was the development of a P-glycoprotein-mediated multidrug resistance (MDR) phenotype. The increase in mRNA levels of the mdr1b P-glycoprotein isoform correlated with the extent of drug resistance. Functional assays revealed that increasing drug resistance was paralleled by a decreased accumulation of rhodamine 123, a fluorescent dye which is a substrate of mdr1-mediated efflux activity. Resistance could be abolished by structurally different chemosensitizers of P-glycoprotein function like verapamil and reserpine but not by the leukotriene receptor antagonist MK571 which is a modulator of the multidrug resistance-associated protein (MRP). Okadaic acid resistance included cross-resistance to other cytotoxic agents that are substrates of mdr1-type P-glycoproteins, like doxorubicin and actinomycin D, but not to non-substrates of mdr1, e.g. cytosine arabinoside. Thus, functional as well as biochemical features support the conclusion that okadaic acid is a substrate of the mdr1-mediated efflux activity in rat pituitary GH3 cells. Maintenance of resistance after withdrawal of okadaic acid as well as metaphase spreads of 100 nM okadaic acid-resistant cells suggested a stable MDR genotype without indications for the occurrence of extrachromosomal amplifications, e.g. double minute chromosomes.     

P-Glycoprotein mediated resistance to 5′-nor-anhydro-vinblastine (Navelbine®)

Summary Navelbine^? (NVB, vinorelbine tartrate) is a semisyntheticVinca alkaloid in which the catharanthine moiety contains an eight-membered ring in place of the nine-membered ring that is present in all naturally occurring members of the vinblastine group. This modification selectively reduces interaction with anoxalvs mititotic microtubules and may account for the lower neurotoxicity with improved antitumor activity that has been observed in clinical trials with breast, lung and ovarian cancer. We were interested in whether the structural modification in NVB would also alter the drug resistance profile. Specifically, our aim was to determine whether NVB, like vinblastine (VBL), participates in P-glycoprotein (P-gp)-mediated multidrug resistance (MDR). NVB-resistant, murine P388 cells (P388/NVB), were derivedin vivo and used in conjunction with a battery of drug-resistant P388 cell linesin vivo and murine and human tumor cell linesin vitro to develop a resistance profile for NVB. P388/NVB bells were cross-resistant to drugs involved in MDR (doxorubicin, etoposide, amsacrine, vinblastine, vincristine and actinomycin D), but not to the alkylating agents, cyclophosphamide, carmustine, and cisplatin, or to the antimetabolites, 5-fluorouracil and methotrexate. P388/NVB cellular resistance to NVB was stable without drug pressure during continuous passagein vivo for more than ten weeks andin vitro for at least five weeks. These cells exhibited increased expression of P-gp, and a 30-fold level of resistance of NVBin vitro, which was completely reversable with verapamil. The MDR phenotype was confirmed in other tumor models. P388 tumors resistant to vinblastine, vincristine, doxorubicin, and etoposide were cross-resistant to NVBin vivo. Likewise, human KB carcinoma cells resistant to colchicine, MDA-A1^R breast carcinoma cells resistant to doxorubicin, and murine B16/F10 melanoma cells transfected with the humanmdr1 gene were cross-resistant to NVBin vitro. Finally, P388 cells resistantin vivo to melphalan, a drug that does not participate in MDR, were cross-resistant to NVB. Therefore, cellular resistance to NVB, like otherVinca alkaloids, may arise by a P-glycoprotein-mediated MDR mechanism, but may also involve non-MDR mechanisms in cells that do not overexpress P-gp.     

阿霉素对裸小鼠人肝癌原位移植瘤多药耐药性的影响

目的　探讨阿霉素对裸小鼠原位移植人肝癌多药耐药性的影响 ,并研究其耐药机制。方法　人肝癌 (BEL 740 2 )裸小鼠原位移植 ,用阿霉素腹腔注射诱导耐药 ,经MTT法检测原代培养的耐药细胞对抗癌药的敏感性 ,以流式细胞仪检测癌细胞表面mdr1基因产物P170的表达及功能。以裸小鼠原位移植人肝癌模型观察阿霉素对耐药组的疗效。结果　移植瘤组织形态及生物学方面符合人肝癌特征 ,耐药细胞表面P170表达为 75 45 %± 5 6 7% ,而对照组表达仅 4 2 5 %± 1 2 8% (P <0 0 1) ,对阿霉素的耐药倍数提高了 16 7倍 ,对羟基喜树碱和表阿霉素具有交叉耐受性(13 7倍和 7 5倍 )。耐药细胞表面P170有较强的药物外排功能。诱导后的肝癌在体内对阿霉素获得了明显的抗性。结论　阿霉素较易诱导原位移植于裸小鼠的人肝癌多药耐药性的产生 ,耐药机制主要与P170的过度表达有关     

A study of the mechanism of resistance to Adriamycin in vivo. Glutathione metabolism, P-glycoprotein expression, and drug transport

A spontaneously originated murine mammary adenocarcinoma (16C), selected for its sensitivity to agents active against breast cancer in women, and one of the very few experimental solid tumor models responsive to Adriamycin (ADR) was used to study the mechanism of induced ADR resistance in vivo. A resistant variant of the tumor was obtained from the explant of a regrown tumor following a dose of ADR (12 mg/kg) that caused complete tumor repression but not cure. Progressive refractoriness to ADR was observed following up to six repeated cycles of treatment, regression and regrowth. However, beyond the sixth treatment, no further degree of resistance could be obtained. The cell line so established, designated 16C/ADRR, has a glutathione (GSH) content 1.67 times greater than the parent 16C line. Depletion of GSH by buthionine sulfoximine (BSO) enhanced the cytoxicity of ADR in both cell lines. The sensitization effect appeared to be dependent on the degree of GSH depletion, requiring a threshold level of depletion to approximately 30% of control. The resistance of 16C/ADRR, however, appeared not to be directly related to the increased absolute GSH level per se since reduction of the GSH content of the 16C/ADRR line to levels similar to that of the parent 16C line did not restore the original sensitivity to ADR. However, the activities of two important elements in the GSH detoxification system, GSH peroxidase and S-transferase, were found to be elevated in resistant cells by factors of 2.4 and 4.7-5.6 respectively. In vivo studies with a diverse spectrum of antineoplastic drugs revealed a pattern of cross-resistance consistent with the idea that elevated GSH S-transferase and peroxidase activities may be responsible for the decreased (2.8- to 5.3-fold) sensitivity to ADR. 16C/ADRR exhibited cross-resistance with melphalan (MEL), but none with vincristine (VCR), vinblastine (VBL) or etoposide (VP-16). These results clearly demonstrate non-adherence by the 16C/ADRR tumors to the well characterized multidrug resistance (mdr) phenotype. Further affirmation of this conclusion was obtained by immunochemical and pharmacological studies. When a monoclonal antibody prepared against the mdr associated, 170 kD P-glycoprotein (170 P-gp), was used, the presence of the 170 kD P-gp in both the sensitive and resistant 16C lines could not be detected, although the presence of a lower molecular weight form of P-gp could not be ruled out entirely. High performance liquid chromatographic measurement of ADR accumulation and elimination also failed to reveal any significant differences between the sensitive and resistant variants.(ABSTRACT TRUNCATED AT 400 WORDS)     

人肺癌组织多药耐药基因的探讨

本文采用RT-PCR方法检测了38例NSCLC肿瘤组织,10例良性瘤样病变争35例病灶旁正常肺组织中mdrl基因的表达水平。结果表明,肺癌组织中mdrl mRNA过度表达,因此推测mdrl基因表达是肺癌产生耐药性的主要机制之一。     

P-glycoprotein-independent mechanism of resistance to VP-16 in multidrug-resistant tumor cell lines: pharmacokinetic and photoaffinity labeling studies

The interaction of etoposide (VP-16), Vinca alkaloids, and verapamil with the P-glycoprotein (P-gp) was studied in human breast (MCF-7) and Chinese hamster lung (DC3F) cell lines and the corresponding multidrug-resistant MCF-7/ADR and DC3F/ADX tumor cell lines, selected for resistance to Adriamycin and actinomycin D, respectively, and overexpressing P-gp. Verapamil (10 microM) markedly reversed resistance to vincristine (11-fold in DC3F/ADX and 125-fold in MCF-7/ADR; 1-hr exposure), but it had a very modest effect on resistance to VP-16 (3- to 4-fold; 1-hr exposure). Resistant cells accumulated 2- to 4-fold less VP-16 and vincristine than the parental cell lines. Verapamil (10 microM) significantly increased accumulation and retention of vincristine, but not of VP-16, in resistant cell lines. Photoaffinity labeling of resistant cell lines with radioactive analogs of verapamil [N(p-azido-3-125I-salicyl)-N'-beta-aminoethylverapamil (NASVP)] and vinblastine[N-(p-azido-3-125I-salicyl)-N'-beta-aminoethylvindesine (NASV)] showed distinctly labeled P-gp bands in both resistant cell lines, compared with wild-type cells. Excess nonradioactive vinblastine or verapamil effectively competed with the P-gp photolabeling by either NASVP or NASV, with IC50 levels of 0.6 and 10 microM, respectively. In contrast, nonradioactive VP-16 was 100- to 500-fold less potent than vinblastine in competing with P-gp photolabeling, suggesting that VP-16 has significantly lower affinity for P-gp than Vinca alkaloids have. Taken together, our data indicate that P-gp glycoprotein by itself may not be important in the transport/efflux of VP-16 and, thus, in the mechanism of resistance to VP-16 in these cells.     

Isolation of a multidrug resistance inhibitor fromAconitum pseudo-laeve var.erectum

To overcome multidrug resistance (MDR) in cancer chemotherapy, we prepared various plant extracts and searched for a component which is effective for inhibition of MDR. MDR inhibition activity was determined by measuring cytotoxicity to MDR cells using multidrug resistant human fibrocarcinoma KB V20C, which is resistant to 20 nM vincristine and expresses high level ofmdr1 gene. Of various plant extracts, the MeOH extract of the root ofAconitum pseudo-laeve var.erectum was found to have potent inhibitory activity on MDR. The bioassay-guided fractionation of the MeOH extract of the plant led to the isolation of an alkaloid, lycaconitine, as an active principle. And the IC₅₀ of lycaconitne for KB V20C cells was 74 μg/ml.     

Potent induction of human colon cancer cell uptake of chemotherapeutic drugs by N-myristoylated protein kinase C-α (PKC-α) pseudosubstrate peptides through a P-glycoprotein-independent mechanism

Phorbol ester protein kinase C (PKC) activators and PKC isozyme over-expression have been shown to significantly reduce intracellular accumulation of chemotherapeutic drugs, in association with the induction of multidrug resistance (MDR) in drug-sensitive cancer cells and enhancement of drug resistance in MDR cancer cells. These observations constitute solid evidence that PKC plays a significant role in the MDR phenotype of cancer cells. PKC-catalyzed phosphorylation of the drug-efflux pump P-glycoprotein was recently ruled out as a contributing factor in MDR. At present, the sole drug transport-related event that has been identified as a component of the role of PKC in MDR is PKC-induced expression of the P-glycoprotein-encoding gene mdr1. The objective of this study was to test the hypothesis that PKC can modulate the uptake of chemotherapeutic drugs in cancer cells independently of P-glycoprotein. We analyzed the effects of selective PKC activators/inhibitors on the uptake of radiolabelled cytotoxic drugs by cultured human colon cancer cells that lacked P-glycoprotein activity and did not express the drug efflux pump at the level of message (mdr1) or protein. We found that the selective PKC activator 12-O-tetradecanoylphorbol-13-acetate (TPA) significantly reduced uptake of [¹⁴C] Adriamycin and [³H] vincristine in human colon cancer cells devoid of P-glycoprotein activity, and that PKC-inhibitory N-myristoylated PKC- pseudosubstrate synthetic peptides potently and selectively induced uptake of the cytotoxic drugs in the phorbol ester-treated and non-treated colon cancer cells. TPA treatment of the cells did not induce expression of either P-glycoprotein or its message mdr1. In contrast with [¹⁴C]Adriamycin and [³H] vincristine uptake, [³H] 5-fluorouracil uptake by the cells was unaffected by TPA and reduced by the PKC-inhibitory peptides. These results indicate that PKC activation can significantly reduce the uptake of multiple cytotoxic drugs by cancer cells independently of P-glycoprotein, and that N-myristoylated PKC- pseudosubstrate peptides potently and selectively induce uptake of multiple cytotoxic drugs in cultured human colon cancer cells by a novel mechanism that does not involve P-glycoprotein and may involve PKC isozyme inhibition. Thus, N-myristoylated PKC- pseudosubstrate peptides may offer a basis for the development of agents that reverse intrinsic drug resistance in human colon cancer.