Multiple patterns of resistance of human leukemia cell sublines to amsacrine analogues

The antileukemia drug amsacrine and seven analogues were tested for in vitro activity against five multidrug-resistant human leukemia cell sublines (two derived from each of two Jurkat parent lines and one from the K562 line) and the corresponding parent lines (Jurkat, K562, and P388 leukemia). Resistant cell lines were derived by exposure to either amsacrine or doxorubicin. The resistance factor was calculated as the ratio of the mean IC50 value for the resistant cell line to that for the parent line. IC50 was defined as the concentration of drug inhibiting cell growth to 50% of that in control (drug-free) cultures. Patterns of cross-resistance were visualized by plotting the deviations of resistance factors from the mean resistance factor, on a logarithmic scale. Considerable variations in resistance factors were noted for each cell subline as the amsacrine substituents were altered. Four main patterns were evident: a transport-related multidrug-resistance pattern (three sublines), a pattern similar to that for a murine P388 leukemia subline resistant to amsacrine, and two patterns not observed previously. Since some of the sublines tested showed evidence of altered topoisomerase II activity, it appears that changes in the resistance pattern in these lines may reflect changes in the stability of the ternary complexes formed by the drug, the altered enzyme, and the DNA. The resistance factor was reduced from more than 100-fold to about 13-fold in three of the sublines tested and from eightfold to twofold in two others. This finding suggests that appropriate drug design may overcome several forms of multidrug resistance in human leukemia and other types of cancer.     

The relationship between multi-drug resistance and resistance to natural-killer-cell and lymphokine-activated killer-cell lysis in human leukemic cell lines.

Results concerning a possible link between susceptibility to natural-cell-mediated immune cytolysis and the multi-drug resistance (MDR) phenotype are conflicting. We evaluated in human acute lymphocytic leukemia the relationship between acquired drug resistance and susceptibility to cytolysis mediated by endogenous, interferon-activated, and interleukin-2-activated natural cytotoxic cells. Eight human leukemia drug-resistant/sensitive cell line pairs were evaluated; drug-resistant sub-lines included those selected for primary resistance to adriamycin, etoposide, teniposide, vincristine, and vinblastine. A majority of P-glycoprotein-positive MDR sub-lines displayed slight but statistically significant resistance to endogenous and/or interferon-activated natural-killer(NK)-cell-mediated lysis, as compared with the drug-sensitive parental type. P-glycoprotein-negative sub-lines displayed variable NK susceptibility; within this group, the variants selected for primary etoposide resistance were more susceptible to NK cytolysis than parental cells. Results of cold-target-inhibition experiments suggest that altered NK susceptibility does not arise solely from modulation of NK target recognition and adherence structures. IL2-activated killer (LAK) cells lysed both drug-sensitive and drug-resistant lines. Two MDR lines selected for primary etoposide resistance displayed enhanced LAK susceptibility. In contrast, the 2 variants selected for resistance to adriamycin exhibited partial resistance to LAK-mediated killing, which could be overcome at high effector-to-target ratios. Our results support the development of interleukin-2/LAK immunotherapy for the treatment of leukemias with acquired drug resistance.     

Direct relation of DNA lesions in multidrug-resistant human myeloma cells to intracellular doxorubicin concentration

Using a human myeloma cell line selected for resistance to doxorubicin (8226/DOX), which expresses the multidrug resistance phenotype, we studied the effects of drug accumulation on DNA damage and cytotoxicity in multidrug-resistant cells. The resistant 8226 subline showed a decrease in [14C]doxorubicin accumulation as compared to the sensitive (8226/S) subline at all time points investigated. DNA alkaline elution techniques were used to examine the formation of single and double strand breaks and DNA-protein cross-links following exposure to doxorubicin in both sensitive and resistant sublines. When 8226/S and 8226/DOX40 cells were exposed to the same extracellular concentration of doxorubicin there was a difference in the quantity of DNA lesions occurring, with the 8226/DOX40 line exhibiting less DNA damage. However, when the extracellular concentration of drug was adjusted to yield equivalent intracellular concentrations these differences were removed and both lines exhibited the same degree of damage for all three DNA lesions. The same DNA lesions were also studied in isolated nuclei from sensitive and resistant cells. Such a model removes any confounding factors due to drug accumulation such as altered cytosolic distribution and/or metabolism of drug. We observed no difference in the formation of single or double strand breaks, or DNA-protein cross-links when the nuclei were exposed to the same concentration of doxorubicin. Results from colony-forming assays have shown that when resistant and sensitive 8226 cells were exposed to high concentrations of doxorubicin, there was a good correlation between DNA damage, drug accumulation, and cytotoxicity. This relationship did not hold for lower concentrations of doxorubicin, for which there was a lack of correlation between drug accumulation and cytotoxicity. Such findings may possibly be due to a prolonged retention of drug by the sensitive cell line as compared to the resistant cells. Further studies are under way to examine this possibility.     

mdr1基因在人肺腺癌多药耐药细胞系LC－3／DDP中的表达

目的研究多药耐药基因（ｍｄｒ１）表达与人肺腺癌多药耐药细胞系（ＬＣ－３／ＤＤＰ）耐药性产生的关系。方法应用地高辛标记的ｍｄｒ１ｃＤＮＡ探针，采用原位杂交方法，检测ｍｄｒ１基因在人肺腺癌多药耐药细胞系ＬＣ－３／ＤＤＰ中的表达水平。结果该细胞系与亲代细胞比较，存在ｍｄｒ１基因超表达。结论ｍｄｒ１基因表达是人肺腺癌多药耐药细胞系ＬＣ－３／ＤＤＰ产生耐药性的相关因素。     

Therapeutic efficacy of interleukin-2 activated killer cells against adriamycin resistant mouse B16-BL6 melanoma.

Development of multidrug-resistance (MDR) remains a major cause of failure in the treatment of cancer with chemotherapeutic agents. In our efforts to explore alternative treatment regimens for multidrug-resistant tumors we have examined the sensitivity of MDR tumor cell lines to lymphokine activated killer (LAK) cells. Adriamycin (ADM) resistant B16-BL6 melanoma, L1210 and P388 leukemic cell lines were tested for sensitivity to lysis by LAK cells in vitro. While ADM-resistant B16-BL6 and L1210 sublines were found to exhibit at least 2-fold greater susceptibility to lysis by LAK cells, sensitivity of ADM-resistant P388 cell was similar to that of parental cells. Since ADM-resistant B16-BL6 cells were efficiently lysed by LAK cells in vitro, the efficacy of therapy with LAK cells against the ADM-resistant B16-BL6 subline in vivo was evaluated. Compared to mice bearing parental B16-BL6 tumor cells, the adoptive transfer of LAK cells and rIL2 significantly reduced formation of experimental metastases (P less than 0.009) and extended median survival time (P less than 0.001) of mice bearing ADM-resistant B16-BL6 tumor cells. Results suggest that immunotherapy with LAK cells and rIL2 may be a useful modality in the treatment of cancers with the MDR phenotype.     

Inhibition of colony formation of drug-resistant human tumor cell lines by combinations of interleukin-2-activated killer cells and antitumor drugs

The cytotoxicity of interleukin-2-activated killer (LAK) cells with or without anticancer drugs against cell lines with acquired drug resistance was evaluated in vitro by colony assay. Human non-small cell lung cancer cell lines, PC-9 and PC-14, human leukemia cell line, K-562, and their sublines resistant to cisplatin (CDDP), PC-9/CDDP and PC-14/CDDP, and to adriamycin (ADM), K-562/ADM, were used as target cells. PC-9/CDDP demonstrated a marked increase in susceptibility to killing by both peripheral blood lymphocytes (PBL) and LAK cells, as compared to the parental cell line, PC-9. The cytotoxicity of PBL and LAK cells against PC-14/CDDP and K-562/ADM was similar to that against their parental cell lines. Moreover, the combination of LAK and CDDP had a synergistic effect on PC-14 and PC-14/CDDP.     

Cytogenetic alterations associated with P-glycoprotein- and non-P-glycoprotein-mediated multidrug resistance in SW-1573 human lung tumor cell lines.

Multidrug resistance can be induced in mammalian cells by selection with a single cytotoxic agent. Overproduction of the energy-dependent drug efflux pump P-glycoprotein, encoded by the mdr1 gene, has been identified as the cause of one form of multidrug resistance. The molecular basis of other forms of multidrug resistance is unknown. Doxorubicin selection of the human squamous lung cancer cell line SW-1573 resulted in multidrug-resistant sublines in which a non-P-glycoprotein-mediated form of multidrug resistance precedes mdr1 expression. Here we present a cytogenetic analysis of both non-P-glycoprotein-mediated multidrug-resistant and P-glycoprotein-mediated multidrug-resistant sublines derived from SW-1573. Three independently derived non-P-glycoprotein-mediated multidrug-resistant sublines showed a heterozygous deletion of the short arm of chromosome 2 (p23-pter), whereas alterations of chromosome 7 were present in the P-glycoprotein-mediated multidrug-resistant cell lines. In one series of clonally derived P-glycoprotein-mediated multidrug-resistant sublines, mdr1 overexpression was accompanied by various markers of chromosome 7 with breakpoints at 7q22, the mdr1 gene being known to be located at 7q21.1. Our data suggest that in SW-1573 cells acquisition of non-P-glycoprotein-mediated multidrug resistance is accompanied by a specific deletion or a translocation involving the short arm of chromosome 2, whereas in the emergence of P-glycoprotein-mediated multidrug resistance a rearrangement of the long arm of chromosome 7 is a critical event.     

Comparative effectiveness of mitoxantrone and doxorubicin in overcoming experimentally induced drug resistance in murine and human tumour cell lines in vitro

Summary Using a range of cell lines of murine and human tumour origin in which relatively modest levels (2- to 17-fold) of drug resistance have been selected in vitro by exposure to a range of standard antitumour drugs, we compared the cytotoxic effects of doxorubicin (DOX) and mitoxantrone (MITO). In general, significantly lower concentrations of MITO than of DOX were required to achieve comparable cytotoxicity, confirming previously published data. MITO appears more generally effective against the murine L5178Y drug-resistant sublines than DOX, although there was no expression of collateral sensitivity to this newer agent. In the various human tumour lines there was a lack of cross-resistance to both DOX and MITO in two 5-fluorouracil (FU)-resistant lines and one of two cisplatin (CDDP)-resistant cells, but cross-resistance was expressed in one subline resistant to vincristine (VCR) and two etoposide (VP-16)-resistant sublines. One murine and two human DOX-resistant sublines were effectively killed by MITO, whilst DOX proved effective against the human MITO-resistant subline. This apparent lack of cross-resistance between DOX and MITO in these resistant sublines expressing low levels of resistance in vitro therefore appears to contrast with previous reports involving highly multidrug-resistant DOX-selected sublines. However, since the latter lines generally exhibited profound cross-resistance to VCR and definite cross-resistance to VP-16, this may at least in part dictate their responses to MITO. Therefore, attempts to use experimentally derived drug-resistant sublines for preclinical drug screening should be approached with caution, since patterns of drug response appear to be influenced by the level of drug resistance expressed. The need remains to determine which type of model system provides the most relevant clinical information.     

Generation and partial characterization of melanoma sublines resistant to lymphokine activated killer (LAK) cells. Relevance to doxorubicin resistance

To see whether a tumor cell population may contain cells resistant to lymphokine-activated killer (LAK) lymphocytes, cells from a LAK-sensitive melanoma line (Me 665/2) were co-cultured with LAKs. Three sublines were obtained after 1, 2 or 3 immunoselection cycles. Immunoselected (IS) sublines show reduced proliferation, decreased reactivity to the monoclonal antibody (MAb) R24 and appeared morphologically more differentiated in comparison with the parental Me 665/2 line. A progressively reduced sensitivity to LAKs was observed in IS sublines with a more than 8-fold reduction in LAK susceptibility. A reduced complement (C)-mediated lysis was also observed in IS sublines. Since we have previously shown that LAK sensitivity of melanoma cells may be associated with Doxorubicin (Dx) resistance, the sensitivity to Dx was tested in these lines. An augmented sensitivity to Dx was noted in IS sublines as compared with Me 665/2. The differences in LAK susceptibility between the IS sublines and the parental Me 665/2 line remained stable for 2 weeks but declined and disappeared thereafter. These results indicate that (1) a LAK-sensitive tumor line may contain a subpopulation of cells which are significantly less lysed by LAKs; (2) a correlation between LAK sensitivity and susceptibility to C-mediated lysis is also present; and (3) increased sensitivity to Dx is evident in the IS sublines.     

The potential of N-[2-(dimethylamino)ethyl]acridine-4-carboxamide]to circumvent three multidrug-resistance phenotypes in vitro

 The effectiveness of N-[2-(dimethylamino) ethyl]acridine-4-carboxamide (DACA) relative to that of amsacrine, idarubicin, daunorubicin and paclitaxel against three different forms of multidrug resistance (MDR) was determined using two sublines of the CCRF-CEM human leukaemia cell line, the P-glycoprotein-expressing CEM/VLB100 subline and the MRP-expressing CEM/E1000 subline, and two extended-MDR sublines of the HL60 human leukaemia cell line, HL60/E8 and HL60/V8. DACA was effective against P-glycoprotein-mediated MDR and MRP- mediated MDR, whereas the extended-MDR pheno- type showed only low levels of resistance (<2-fold) to DACA. In comparison, idarubicin was ineffec- tive against the MRP and extended-MDR phenotypes. Repeated exposure of the K562 human leukaemia cell line to DACA (55, 546 or 1092 nM for 3 days over 10 weeks) did not result in the development of any significant drug resistance. We conclude that DACA has the potential to treat refractory leukaemia. Received: 5 May 1996/Accepted: 16 August 1996     

Cytotoxic effects of folate antagonists against methotrexate-resistant human leukemic lymphoblast CCRF-CEM cell lines

A human T-lymphoblast cell line, CCRF-CEM/R1, resistant to methotrexate by virtue of increased dihydrofolate reductase activity, was grown in stepwise increasing concentrations of methotrexate. This additional selection pressure resulted in a cell line, CCRF-CEM/R2, resistant to methotrexate by virtue of both an elevation of dihydrofolate reductase activity and a marked decrease in methotrexate transport. The R1 and R2 cells were approximately 70- and 350-fold more resistant to methotrexate than were the parent cells. The effects of three folate antagonists were studied on these cell lines and also on CCRF-CEM/R3 cells, characterized by impaired methotrexate transport but normal levels of dihydrofolate reductase. The elevated reductase subline CCRF-CEM/R1 was cross-resistant to triazinate [Baker's antifol, NSC 139105; ethanesulfonic acid compounded with alpha-(2-chloro-4-[4,6-diamino-2,2-dimethyl-S-triazine-1-(2H)-yl] phenoxyl)-N,N-dimethyl-m-toluamide (1:1)] and trimetrexate (NSC 249008, JB-11, TMQ; 2,4-diamino-6-[(3,4,5-trimethoxyanilino)methyl]quinazoline), two nonclassical folate antagonists. In contrast, the transport defective subline, CCRF-CEM/R3 was not cross-resistant to these two compounds. In cells resistant to MTX by virtue of both mechanisms, CCRF-CEM/R2, triazinate, and trimetrexate were partially cross-resistant. All three methotrexate-resistant sublines showed minor cross-resistance to isoaminohydroxyquinazoline (IAHQ, NSC 289517; 5,8-dideazaisopteroylglutamate), a folate antagonist inhibitor of thymidylate synthase. These data demonstrate that methotrexate-resistant tumor cells may be effectively inhibited by antifolates with different route of entry into cells or with different enzyme targets.     

Altered expression of P-glycoprotein and cellular adhesion molecules on human multi-drug-resistant tumor cells does not affect their susceptibility to NK- and LAK-mediated cytotoxicity.

Drug resistance has been associated with resistance to NK- and LAK-cell-mediated cytotoxicity. We evaluated this issue in human cell lines, using multiple myeloma cells (8226) and 2 multi-drug-resistant (MDR) sublines selected using doxorubicin (8226/Dox40) and mitoxantrone (8226/MR40). In parallel, we studied the human breast carcinoma cell line series MCF7, MCF7/D40 and MCF7/Mitox. Unlike the sensitive parental cell lines, all 4 sublines display MDR-patterns of resistance, with the P-glycoprotein pump (P-170) detected only in the doxorubicin-selected sublines. Flow cytometric and immunocytochemical analyses showed expression of cellular adhesion molecules ICAM-I and LFA-3, and MHC-Class-I (MCF7/D40 only), to be decreased in the doxorubicin-selected MDR-sublines, whereas expression of CD56 (Leu 19) was strongly up-regulated in 8226/Dox40. Lysis of P-170-positive MDR tumor cells by NK or LAK cells was, however, unaffected by these alterations, suggesting redundancy in effector:target-cell adhesion pathways. Mitoxantrone-selected tumor cells did not display P-170, nor did they show altered expression of cellular adhesion molecules. Their susceptibility to NK or LAK cytolysis was also unimpaired as compared to the parental cell lines. Clinically, these results imply that immunotherapeutic modalities aiming at increased natural killer functions deserve full consideration even in patients who have become refractory to further cytostatic drug treatment.     

Natural killer cell resistance in K-562 cell sublines

Sublines of the hematopoietic stem cell line K-562 were tested for their susceptibility to human natural killer (NK) cell activity. A correlation was found between the degree of NK-mediated lysis and the presence or absence of particular chromosomal markers. K-562 subline susceptible to lysis by NK were found to express karyotypically a deletion 9- and a marker 8(t1-18), whereas resistant sublines did not express these markers. A cloned K-562 subline B1V was chosen as representative of a resistant subline. This subline was resistant to lysis even after prolonged incubation and activation of the NK cells with interferon. However, it was found that B1V was lysed by both antibody-dependent, complement-mediated and antibody-dependent cellular mechanisms at levels comparable to those seen with NK-sensitive K-562 sublines. Subline B1V did compete poorly with NK-sensitive K-562 in cold-target inhibition; however, conjugate-formation assays demonstrated that the binding of NK cells to B1V cells is comparable to that of NK-sensitive K-562 cells. We suggest that cells of the cloned line B1V are recognized normally by NK cells but do not activate the lytic mechanism of the bound NK cell. Treatment of the resistant clone B1V with neuraminidase did not lead to enhanced levels of lysis. Protein extracts of NK-sensitive K-562 sublines efficiently inhibited lysis by NK cells but extracts of the resistant clone, B1V, did not inhibit lysis, suggesting that the clone lacks cell surface determinants involved in the post-recognitive activation of the NK cytolytic mechanism.     

Collateral susceptibility of adriamycin-, melphalan- and cisplatin-resistant human ovarian tumor cells to bleomycin

Three cell lines resistant to adriamycin, melphalan and cisplatin were established in vitro from human ovarian cancer cell line A2780. Each subline showed a resistance to its inducing drug of 75-fold in the case of adriamycin, 6-fold in the case of melphalan and 11-fold in the case of cisplatin. However, all of these sublines showed collateral sensitivity to bleomycin. Approximately a 2-fold higher susceptibility to bleomycin was observed generally. The biochemical mechanisms of this collateral sensitivity are not clear at present, but the higher concentration of glutathione in these resistant tumor cell lines might be related to the high susceptibility of these resistant cells to bleomycin.     

Cytotoxicity of Trimetrexate against Antifolate-resistant Human T-Cell Leukemia Cell Lines Developed in Oxidized or Reduced Folate

Cytotoxicity of trimetrexate (TMQ), a lipophilic dihydrofolate reductase inhibitor, was examined in antifolate-resistant human T-cell leukemia cell lines developed in oxidized or reduced folate. An approximately 60-fold methotrexate (MTX)-resistant subline was developed in oxidized folate (pter-oylglutamic acid: PGA) (CCRF-CEM/MTX₆₀-PGA) from human T-cell leukemia cell line CCRF-CEM; this line exhibited impaired membrane transport of the drug. Further enhancement of MTX resistance resulted in selection of an approximately 5000-fold MTX-resistant subline (CCRF-CEM/ MTX₅₀₀₀-PGA), which showed increased dihydrofolate reductase activity due to gene amplification in addition to further impairment of MTX transport. An approximately 140-fold MTX-resistant subline, and then a 1500-fold MTX-resistant subline were developed in reduced folate (10 nM leucovorin) (CCRF-CEM/MTXm-LV and CCRF-CEM/MTX₁₄₀-LV); they exhibited increased dihydrofolate reductase due to gene amplification accompanied by increased intracellular drug accumulation of MTX. While CCRF-CEM/MTX₁₄₀-LV and CCRF-CEM/MTX₁₅₀₀-LV cells showed cross-resistance to TMQ, CCRF-CEM/MTX₆₀-PGA and CCRF-CEM/MTX₅₀₀₀-PGA cells were at least as sensitive to TMQ as the parent cells. TMQ was more potent against approximately 200-fold N¹⁰-propargyl-5,8-dideazafolic-acid (CB3717)-resistant human T-cell leukemia MOLT-3 sublines developed in PGA (MOLT-3/CB3717₂₀₀-PGA) or leucovorin (MOLT-3/CB3717₂₀₀-LV), as compared to the parent cells; MOLT-3/CB3717₂₀₀-PGA and MOLT-3/CB3717₂₀₀-LV cells were resistant to CB3717 by virtue of impaired transport, only the former possessing gene amplification of thymidylate synthase. The Cytotoxicity of TMQ in both MOLT-3/CB3717₂₀₀-PGA and MOLT-3/CB3717₂₀₀-LV cells was reduced by addition of leucovorin in a dose-dependent manner, suggesting intracellular folate deficiency as a cause of TMQ sensitivity. These results demonstrate that TMQ overcomes transport-impaired antifolate resistance, irrespective of gene amplification of dihydrofolate reductase or thymidylate synthase. Types of folate used during the development of antifolate resistance seem to be important in relation to the mechanism of TMQ responsiveness as well as that of antifolate resistance.     

Large diversity in transport-mediated methotrexate resistance in human leukemia cell line CCRF-CEM established in a high concentration of leucovorin

To elucidate the mechanism(s) of methotrexate (MTX) resistance as a possible reason underlying treatment failure in high-dose MTX regimens combined with leucovorin (LV) rescue, we established MTX-resistant human T-cell leukemia cell line CCRF-CEM cells in the presence of excess LV, and characterized their properties. Continuous exposure of the cells to escalating concentrations of MTX up to 20 μM in the presence of 1000 n M LV resulted in establishment of three MTX-resistant sublines with a wide disparity of resistance degree over a 4 logarithmic range (approximately 40-, 900- and 44 000-fold, respectively). Transmembrane transport of MTX in these sublines was diminished to 52%, 35% and 12%, respectively. Intracellular retention of MTX in these sublines was not different from that of the parent cells. A cell growth study in various concentrations of LV showed that cells with higher resistance to MTX required more LV for optimal growth. In parallel with the resistance levels, there was an increase in mRNA expression of dihydrofolate reductase gene and a decrease in that of thymidylate synthase gene, but no change in that of reduced folate carrier ( RFC1 ) gene, as assessed by northern blot analysis. Sequencing of the RFC1 gene in all 3 sublines revealed a point mutation in codon 47 (TCC→TTC) resulting in substitution of Phe for Ser residue, and additional deletion of CTG of codon 112 in the subline with the highest resistance. In summary, MTX exposure to CCRF-CEM cells in the presence of 1000 n M LV resulted in the establishment of heterogeneous cell populations with a wide range of transport-mediated MTX resistance, which was associated with differential alterations of RFC gene. These cell lines may serve as models for investigation of the molecular mechanism(s) underlying refractory tumors in high-dose MTX regimens with LV rescue. (Cancer Sci 2003; 94: 210–214)     

Inhibition of Colony Formation of Drug-resistant Human Tumor Cell Lines by Combinations of Interleukin-2-activated Killer Cells and Antitumor Drugs

The cytotoxicity of interleukin-2-activated killer (LAK) cells with or without anticancer drugs against cell lines with acquired drug resistance was evaluated in vitro by colony assay. Human non-small cell lung cancer cell lines, PC-9 and PC-14, human leukemia cell line, K-562, and their sublines resistant to cisplatin (CDDP), PC-9/CDDP and PC-14/CDDP, and to adriamycin (ADM), K-562/ADM, were used as target cells. PC-9/CDDP demonstrated a marked increase in susceptibility to killing by both peripheral blood lymphocytes (PBL) and LAK cells, as compared to the parental cell line, PC-9. The cytotoxicity of PBL and LAK cells against PC-14/CDDP and K-562/ADM was similar to that against their parental cell lines. Moreover, the combination of LAK and CDDP had a synergistic effect on PC-14 and PC-14/CDDP.     

Phenotypic and cytogenetic analysis of atypical multidrug resistance in human leukaemic cells selected with methotrexate at high concentration

A series of CCRF-CEM sublines selected for extreme resistance to methotrexate has been shown previously to exhibit cross resistance to a number of agents belonging to the multidrug resistance phenotype. The mechanism(s) underlying resistance to vincristine, vinblastine and actinomycin D in the most resistant subline (CEM/MTX R3) has now been investigated. Efflux of [3H]vincristine was more rapid in CEM/MTX R3 than in either CCRF-CEM cells or a methotrexate-resistant subline not refractory to Vinca alkaloids. In addition, verapamil completely reversed resistance to vincristine, vinblastine and actinomycin D in the CEM/MTX R3 cells. While these results are suggestive of P-glycoprotein-mediated multidrug resistance, Northern analysis revealed no detectable expression of the mdr 1/gene in CEM/MTX R3 cells. Likewise, karyotypic analysis of the resistant subline, while revealing certain clonal abnormalities, provided no evidence of alteration in the mdr 1/gene locus on chromosome 7. The data suggest therefore the operation, in these cells, of a novel mechanism of resistance.     

Membrane gangliosides and immuno-mediated cytolysis in drug sensitive and treatment-induced multidrug resistant human ovarian cancer cells.

The pattern of cytoplasmic membrane gangliosides and two cellular features which have been reported to be related to the expression of different membrane gangliosides, namely adhesion to solid substrates and susceptibility to the lytic activity of immune effector cells, have been investigated in drug sensitive A2780 human ovarian cancer cells and in two treatment-induced multidrug resistant sublines (A2780-DX1 and A2780-DX3). The total membrane gangliosides content of A2780 sensitive cells was comparable to that of the two multidrug resistant (MDR) sublines, but the acquisition of the MDR phenotype was characterized by an increased expression of the polysialylated gangliosides (particularly the disialoganglioside GDIa) and decreased expression of the monosialoganglioside GM2. The kinetics of cellular adhesion (both to plastic culture dishes and to extracellular matrix coated dishes) were similar in the three cell lines, indicating that the gangliosides profile seems not to be relevant for cell adhesivity to the above mentioned substrates. When human peripheral blood lymphocytes in toto (PBL) and two lymphokine activated (LAK) T cell subpopulations (CD3+4-8- and CD3-16+) were used as effector cells against A2780 (sensitive) and A2780-DX3 (highly resistant) cells, cytolysis of target cells was more efficient against the A2780-DX3 subline, suggesting a possible role of the ganglioside GD1a as a target structure for LAK immunotherapy.     

Impaired polyglutamylation of methotrexate as a cause of resistance in CCRF-CEM cells after short-term, high-dose treatment with this drug

Two methotrexate-resistant sublines, CCRF-CEM R3/7 and CCRF-CEM R30/6, were selected from the human leukemia T-lymphoblast cell line, CCRF-CEM, after repeated exposures (7 and 6 times, respectively) for 24 h to constant concentrations (3 and 30 microM) of the drug. Analysis of the mechanism of resistance revealed no differences in levels of dihydrofolate reductase activity, its binding affinity for methotrexate, or in methotrexate transport between the CCRF-CEM parent and methotrexate-resistant cell lines. The development of resistance to methotrexate was associated with a marked decrease in the intracellular level of methotrexate polyglutamates. Although the resistant sublines were able to form substantial amounts of folate polyglutamates when measured with [3H]folic acid, the level of polyglutamates formed was decreased to about 50% of that formed by the parent cell line. No qualitative differences in folate polyglutamates formed were noted between the parental and resistant sublines. This is the first example of a cell line which displays resistance which is solely attributable to defective methotrexate polyglutamate synthesis.