Multiple drug-resistance in variant of a human non-small cell lung carcinoma cell line,DLKP-A

A 300-fold adriamycin resistant variant (DLKP-A) of the human lung squamous cell carcinoma line DLKP was established by stepwise selection in increasing concentrations of adriamycin. Different levels of cross-resistance were observed towards VP-16, VM-26, colchicine, vincristine and, somewhat unexpectedly, cis-platin. Resistance was stable for at least 3 months in culture in the absence of drug. P-glycoprotein overexpression was detected by immunofluorescence and Western Blotting, and a direct causal role for P-glycoprotein overexpression in the resistant phenotype was established by transfection with an mdr1 specific antisense oligonucleotide. A modified cryopreservation procedure was necessary for the resistant variant line. The resistant population displays clonal heterogeneity with respect to resistance level. A higher frequency of double minute chromosomes was observed in DLKP-A when compared with the parental cell line.Abbreviations ADR adriamycin - COLH colchicine - C-PT cis-platin - MDR multidrug resistance - NSCLC non-small cell lung carcinoma - VCR vincristine - VP-16 etoposide - VM-26 tenoposide     

LIPOSOMAL DAUNORUBICIN OVERCOMES DRUG RESISTANCE IN HUMAN BREAST,OVARIAN AND LUNG CARCINOMA CELLS

ABSTRACT

Multi-drug resistance due in part to membrane pumps such as P-glycoprotein (Pgp) is a major clinical problem in human cancers. We tested the ability of liposomally-encapsulated daunorubicin (DR) to overcome resistance to this drug. A widely used breast carcinoma cell line originally selected for resistance in doxorubicin (MCF7ADR) was 4-fold resistant to DR compared to the parent MCF7 cells (IC₅₀ 79 nM vs. 20 nM). Ovarian carcinoma cells (SKOV3) were made resistant by retroviral transduction of MDR1 cDNA and selection in vinblastine. The resulting SKOV3MGP1 cells were 130-fold resistant to DR compared to parent cells (IC₅₀ 5700 nM vs. 44 nM). Small-cell lung carcinoma cells (H69VP) originally selected for resistance to etoposide were 6-fold resistant to DR compared to H69 parent cells (IC₅₀ 180 nM vs. 30 nM). In all three cases, encapsulation of DR in liposomes as Daunoxome (Gilead) did not change the IC₅₀ of parent cells relative to free DR. However, liposomal DR overcame resistance in MCF7ADR breast carcinoma cells (IC₅₀ 20 nM), SKOV3MGP1 ovarian carcinoma cells (IC₅₀ 237 nM) and H69VP small-cell lung carcinoma cells (IC₅₀ 27 nM). Empty liposomes did not affect the IC₅₀ for free DR in the three resistant cell lines, nor did empty liposomes affect the IC₅₀ for other drugs that are part of the multi-drug resistance phenotype (etoposide, vincristine) in lung carcinoma cells. These data indicate the possible value of liposomal DR in overcoming Pgp-mediated drug resistance in human cancer.     

The ruthenium complexes cis-(dichloro)tetramineruthenium(III) chloride and cis-tetraammine(oxalato)ruthenium(III) dithionate overcome resistance inducing apoptosis on human lung carcinoma cells (A549)

Lung cancer is one of the leading causes of death in the world, and non-small cell lung carcinoma accounts for approximately 75–85 % of all lung cancers. In the present work, we studied the antitumor activity of the compound cis-(dichloro)tetramineruthenium(III) chloride {cis-[RuCl₂(NH₃)₄]Cl} against human lung carcinoma tumor cell line A549. The present study aimed to investigate the relationship between the expression of MDR1 and CYP450 genes in human lung carcinoma cell lines A549 treated with cisCarboPt, cisCRu(III) and cisDRu(III). The ruthenium-based coordinated complexes presented low cytotoxic and antiproliferative activities, with high IC₅₀ values, 196 (±15.49), 472 (±20.29) and 175 (±1.41) for cisCarboPt, cisCRu(III) and cisDRu(III), respectively. The tested compounds induced apoptosis in A549 tumor cells as evidenced by caspase 3 activation, but only at high concentrations. Results also revealed that the amplification of P-gp gene is greater in A549 cells exposed to cisCarboPt and cisCRu(III) than cisDRu(III). Taken together all these results strongly demonstrate that MDR-1 over-expression in A549 cells could be associated to a MDR phenotype of these cells and moreover, it is also contributing to the platinum, and structurally-related compound, resistance in these cells. The identification and characterization of novel mechanisms of drug resistance will enable the development of a new generation of anti-cancer drugs that increase cancer sensitivity and/or represent more effective chemotherapeutic agents.     

Liposomal daunorubicin overcomes drug resistance in human breast,ovarian and lung carcinoma cells

Multi-drug resistance due in part to membrane pumps such as P-glycoprotein (Pgp) is a major clinical problem in human cancers. We tested the ability of liposomally-encapsulated daunorubicin (DR) to overcome resistance to this drug. A widely used breast carcinoma cell line originally selected for resistance in doxorubicin (MCF7ADR) was 4-fold resistant to DR compared to the parent MCF7 cells (IC50 79 nM vs. 20 nM). Ovarian carcinoma cells (SKOV3) were made resistant by retroviral transduction of MDR1 cDNA and selection in vinblastine. The resulting SKOV3MGP1 cells were 130-fold resistant to DR compared to parent cells (IC50 5700 nM vs. 44 nM). Small-cell lung carcinoma cells (H69VP) originally selected for resistance to etoposide were 6-fold resistant to DR compared to H69 parent cells (IC50 180 nM vs. 30 nM). In all three cases, encapsulation of DR in liposomes as Daunoxome (Gilead) did not change the IC50 of parent cells relative to free DR. However, liposomal DR overcame resistance in MCF7ADR breast carcinoma cells (IC50 20 nM), SKOV3MGP1 ovarian carcinoma cells (IC50 237 nM) and H69VP small-cell lung carcinoma cells (IC50 27 nM). Empty liposomes did not affect the IC50 for free DR in the three resistant cell lines, nor did empty liposomes affect the IC50 for other drugs that are part of the multi-drug resistance phenotype (etoposide, vincristine) in lung carcinoma cells. These data indicate the possible value of liposomal DR in overcoming Pgp-mediated drug resistance in human cancer.     

Targeting the mitochondrial pathway to induce apoptosis/necrosis through ROS by a newly developed Schiff's base to overcome MDR in cancer

Multidrug resistance (MDR) in cancer, a major obstacle to successful application of cancer chemotherapy, is often characterized by over-expression of multidrug resistance-related proteins such as MRP1, P-gp or elevated glutathione (GSH) level. Efflux of drugs by functional P-gp, MRP1 and elevated GSH level can confer resistance to apoptosis induced by a range of different stimuli. Therefore, it is necessary to develop new cell death inducers with relatively lower toxicity toward non-malignant cells that can overcome MDR by induction of apoptotic or non-apoptotic cell death pathways. Herein we report the synthesis and spectroscopic characterization of a GSH depleting, redox active Schiff’s base, viz., potassium-N-(2-hydroxy-3-methoxy-benzaldehyde)-alaninate (PHMBA). Cytotoxic potential of PHMBA has been studied in doxorubicin-resistant and -sensitive T lymphoblastic leukemia cells and Ehrlich ascites carcinoma (EAC) cells. PHMBA kills both the cell types irrespective of their drug-resistance phenotype following apoptotic/necrotic pathways. Moreover, PHMBA-induced cell death is associated with oxidative stress mediated mitochondrial pathway as the H₂O₂ inhibitor PEG-Catalase abrogated PHMBA-induced apoptosis/necrosis. PHMBA induces anti-tumor activity in both doxorubicin-sensitive and -resistant EAC-tumor-bearing Swiss albino mice. The non-toxicity of PHMBA was also confirmed through cytotoxicity studies on normal cell lines like PBMC, NIH3T3 and Chang Liver. To summarise, our data provide compelling rationale for future clinical use of this redox active Schiff’s base in treatment of cancer patients irrespective of their drug-resistance status.     

Are altered pHi and membrane potential in hu MDR 1 transfectants sufficient to cause MDR protein-mediated multidrug resistance?

Multidrug resistance (MDR) mediated by overexpression of the MDR protein (P-glycoprotein) has been associated with intracellular alkalinization, membrane depolarization, and other cellular alterations. However, virtually all MDR cell lines studied in detail have been created via protocols that involve growth on chemotherapeutic drugs, which can alter cells in many ways. Thus it is not clear which phenotypic alterations are explicitly due to MDR protein overexpression alone. To more precisely define the MDR phenotype mediated by hu MDR 1 protein, we co-transfected hu MDR 1 cDNA and a neomycin resistance marker into LR73 Chinese hamster ovary fibroblasts and selected stable G418 (geneticin) resistant transfectants. Several clones expressing different levels of hu MDR 1 protein were isolated. Unlike previous work with hu MDR 1 transfectants, the clones were not further selected with, or maintained on, chemotherapeutic drugs. These clones were analyzed for chemotherapeutic drug resistance, intracellular pH (pHi), membrane electrical potential (Vm), and stability of MDR 1 protein overexpression. LR73/hu MDR 1 clones exhibit elevated pHi and are depolarized, consistent with previous work with LR73/mu MDR 1 transfectants (Luz, J.G. L.Y. Wei, S. Basu, and P.D. Roepe. 1994. Biochemistry. 33:7239-7249). The extent of these perturbations is related to the level of hu MDR 1 protein that is expressed. Cytotoxicity experiments with untransfected LR73 cells with elevated pHi due to manipulating percent CO2 show that the pHi perturbations in the MDR 1 clones can account for much of the measured drug resistance. Membrane depolarization in the absence of MDR protein expression is also found to confer mild drug resistance, and we find that the pHi and Vm changes can conceivably account for the altered drug accumulation measured for representative clones. These data indicate that the MDR phenotype unequivocally mediated by MDR 1 protein overexpression alone can be fully explained by the perturbations in Vm and pHi that accompany this overexpression. In addition, MDR mediated by MDR protein overexpression alone differs significantly from that observed for MDR cell lines expressing similar levels of MDR protein but also exposed to chemotherapeutic drugs.     

ALPHA-FETOPROTEIN-MEDIATED TARGETING—A NEW STRATEGY TO OVERCOME MULTIDRUG RESISTANCE OF TUMOUR CELLSIN VITRO

The possibility of overcoming the multidrug resistance of human malignant cells by using doxorubicin conjugated to alpha-fetoprotein (AFP) was studied. It was shown that this type of antitumour drugs, penetrating the cell by receptor-mediated endocytosis with AFP as a vehicle, raises the sensitivity of the tumour cells that are resistant due to the expression of the multidrug resistance genemdr1. The sensitivity of antibiotic-resistant cell lines SKVLB (a human ovarian carcinoma) and MCF-7 AdrR (a human breast carcinoma) increased by 10- and 4-fold, respectively, when AFP-conjugated doxorubicin was used. The rationale of using human AFP-antitumour drug conjugates for the development of new chemotherapeutic approaches to cancer treatment is discussed.     

Rhamnetin induces sensitization of hepatocellular carcinoma cells to a small molecular kinase inhibitor or chemotherapeutic agents

BackgroundThe rapid development of multi-drug resistance (MDR) process has hindered the effectiveness of advanced hepatocellular carcinoma (HCC) treatments. Notch-1 pathway, which mediates the stress-response, promotes cell survival, EMT (epithelial–mesenchymal transition) process and induces anti-apoptosis in cancer cells, would be a potential target for overcoming MDR process. This study investigated the potential application of rhamnetin, a specific inhibitor of Notch-1 pathway, in anti-tumor drug sensitization of HCC treatment.MethodsThe expression of miR-34a, proteins belonging to Notch-1 signaling pathway or MDR-related proteins was detected by quantitative polymerase chain reaction (qPCR) and western blot assay. To identify whether rhamnetin induces the chemotherapeutic sensitization in HCC cells, the MTT-assays, flow cytometry, soft agar, trans-well and nude mice assays were performed.ResultsThe endogenous expression of miR-34a was significantly increased and the expression of Notch-1 and Survivin was downregulated after rhamnetin treatment. Treatment of rhamnetin also reduced the expression of MDR related proteins P-GP (P-glycoprotein) and BCRP (breast cancer resistance protein). Rhamnetin increased the susceptibility of HCC cells and especially HepG2/ADR, a MDR HCC cell line, to a small molecular kinase inhibitor sorafenib or chemotherapeutic drugs etoposide and paclitaxel. The IC₅₀ value of those drugs correspondingly decreased.ConclusionsTogether, our findings suggest that rhamnetin treatment may attenuate the MDR process in HCC cells. These findings may contribute to more effective strategies for HCC therapy.General significanceRhamnetin acts as a promising sensitizer to chemotherapy and may be a novel approach to overcome the MDR process of HCC.     

过表达BTG2增强人肺腺癌细胞的辐射敏感性

在肺癌类型中,肺腺癌占大多数,其总体生存率差,BTG2是抗增殖基因家族的一员,属于BTG/TOB家族。许多研究表明,B细胞易位基因2(BTG2)多种类型的肿瘤中存在异常表达,但其在肺腺癌放疗敏感性中发挥的调控作用尚不明确。本研究通过肺腺癌组织样本及在线数据库,探究BTG2在肺腺癌患者中的表达水平及其表达与临床预后之间的相关性,结果提示在具有放疗抗性的肺腺癌患者中,BTG2的表达水平显著降低,且在肺腺癌细胞系中,BTG2能对放疗产生响应,其在肺腺癌患者中的低表达状态与不良的预后相关(P＜0.05);在人肺腺癌A549和H1299细胞系中转染过表达BTG2(OE-BTG2)慢病毒,通过克隆形成检测过表达BTG2对肺腺癌细胞系的辐射敏感性的影响,实验证实过表达BTG2可显著增强A549和H1299细胞系的辐射敏感性(P＜0.05);并进一步通过WB、免疫组化检测BTG2及凋亡相关蛋白BAX的表达水平,结果证实:过表达BTG2可显著增加A549和H1299细胞辐射后的凋亡水平。最后通过裸鼠成瘤试验检测BTG2在活体中对肺腺癌辐射敏感性的影响,结果提示:在动物实验中,过表达BTG2可显著增强肺腺癌的辐射敏感性(P＜0.05)及增加辐射后BAX的表达水平。综上所述,BTG2在肺腺癌组织中处于低表达状态,并且与不良的临床预后紧密相关,过表达BTG2可促进凋亡过程,增加人肺腺癌细胞系的辐射敏感性,能为克服肺腺癌的辐射抗性提供新的靶点。     

Relationship of LRP-human major vault protein toin vitro and clinical resistance to anticancer drugs

Multidrug resistance (MDR) has been related to two members of the ABC-superfamily of transporters, P-glycoprotein (Pgp) and Multidrug Resistance-associated Protein (MRP). We have described a 110 kD protein termed the Lung Resistance-related Protein (LRP) that is overexpressed in several non-Pgp MDR cell lines of different histogenetic origin. Reversal of MDR parallels a decrease in LRP expression. In a panel of 61 cancer cell lines which have not been subjected to laboratory drug selection, LRP was a superior predictor forin vitro resistance to MDR-related drugs when compared to Pgp and MRP, and LRP's predictive value extended to MDR unrelated drugs, such as platinum compounds. LRP is widely distributed in clinical cancer specimens, but the frequency of LRP expression inversely correlates with the known chemosensitivity of different tumour types. Furthermore, LRP expression at diagnosis has been shown to be a strong and independent prognostic factor for response to chemotherapy and outcome in acute myeloid leukemia and ovarian carcinoma (platinum-based treatment) patients. Recently, LRP has been identified as the human major protein. Vaults are novel cellular organelles broadly distributed and highly conserved among diverse eukaryotic cells, suggesting that they play a role in fundamental cell processes. Vaults localise to nuclear pore complexes and may be the central plug of the nuclear pore complexes. Vaults structure and localisation support a transport function for this particle which could involve a variety of substrates. Vaults may therefore play a role in drug resistance by regulating the nucleocytoplasmic transport of drugs.Abbreviations LRP Lung Resistance-related Protein - MVP Major Vault Protein - MDR Multidrug resistance - MRP Multidrug resistance-associated Protein - NPC Nuclear Pore Complex - Pgp P-glycoprotein     

mdr1 Ribozyme mediated reversal of the multi-drug resistant phenotype in human lung cell lines

Anmdr1 hammerhead was introduced into two adriamycin-selected multi-drug resistant human lung cell lines both of which over-express p-glycoprotein. Expression of the ribozyme resulted in a decrease inmdr1 mRNA expression and an increase in drug sensitivity in both cell lines. This would suggest that the use of specific ribozymes may represent an effective and specific approach in order to restore cellular sensitivity towards anti-cancer drugs.     

SnoN/SkiL,a TGFβ signaling mediator

Effective treatment of cancer cells with chemotherapeutic drugs relies on their ability to induce cell death, making the discovery of their mechanisms of action crucial. Arsenic trioxide (As₂O₃), used in the treatment of promyelocytic leukemia (PML), triggers cell death in several solid tumor cell lines including ovarian carcinomas. While As₂O₃ is remarkably cytotoxic in human ovarian cancer cells, its mechanism of action is poorly understood. We recently investigated the effects of As₂O₃ on several transforming growth factor-β (TGFβ) signaling mediators to better understand its cell death mechanism. Indeed, dysregulated (TGFβ) signaling is typical of ovarian cancers. Based on our findings, we propose that As₂O₃ induces a Beclin 1-independent autophagic pathway in ovarian carcinoma cells by modulating SnoN/SkiL expression, implicating SnoN as a novel therapeutic target for ovarian cancers.     

Induction of apoptosis by chemotherapeutic drugs: the role of FADD in activation of caspase-8 and synergy with death receptor ligands in ovarian carcinoma cells

Although ovarian tumours initially respond to chemotherapy, they gradually acquire drug resistance. The aims of this study were to identify how chemotherapeutic drugs with diverse cellular targets activate apoptotic pathways and to investigate the mechanism by which exposure to a combination of drugs plus death receptor ligands can increase tumour cell kill. The results show that drugs with distinct cellular targets differentially up-regulate TRAIL and TNF as well CD95L, but do not require interaction of these ligands with their receptor partners to induce cell death. Factors that were critical in drug-induced apoptosis were activation of caspases, with caspase-8 being activated by diverse drugs in a FADD-independent manner. Certain drugs also demonstrated some dependence on FADD in the induction of cell death. Caspase-9 was activated more selectively by chemotherapeutic agents. Combining ligation of death receptors with exposure to drugs increased tumour cell kill in both drug resistant cell lines and primary ovarian carcinoma cells, even though these cells were not sensitive to death receptor ligation alone. CD95L was more consistent at combining with drugs than TRAIL or TNF. Investigation of the mechanism by which a combination of drugs plus CD95 ligation can increase cell death showed that caspase-8 was activated in cells exposed to a combination of cisplatin and anti-CD95, but not in cells exposed to either agent alone.     

Resveratrol potentially increased the tumoricidal effect of doxorubicin on SKOV3 cancer stem cells in vitro

Ovarian cancer is associated with a high percentage of recurrence of tumor and resistance to chemotherapy. Cancer stem cells (CSCs) form a rare population with a significant capacity to begin and expand malignant diseases. Eliminating the drug resistance of CSCs by factors that have fewer side effects to the patient is vital. To investigate the effect of resveratrol (RES) and doxorubicin (DOX) on drug resistance and apoptosis of CSCs; at the first, isolation of CSCs from SKOV3 ovarian carcinoma cells and their dosage adjustment (IC₅₀) with RES and DOX was performed. Then, isolated CSCs were treated with RES and DOX IC ₅₀ of 55 and 250 nM, respectively. Subsequently, their effects on drug resistance and cell death were evaluated using real-time polymerase chain reaction, rhodamine 123 uptakes. The results of the present study demonstrated that treatment of SKOV3 with 55 μM of RES and 250 nM of DOX simultaneously increased cell viability in CSCs to DOX after 24 and 48 hours by increasing the expression of Bcl-2-associated X protein (BAX) and caspase-3 genes, and decreased the expression and function of multidrug resistance protein 1 (MDR1) and multidrug resistance-associated protein 1 (MRP1) genes indicated by intracellular the rhodamine 123 content. Treatment of RES could increase the activity of DOX cell viability in CSCs originated from SKOV3 ovarian carcinoma and decrease drug resistance capacity to DOX.     

Heterogeneity in antigenic expression and radiosensitivity in human colon carcinoma cell lines

Summary A panel of human colon carcinoma cell lines were characterized regarding both antigenic heterogeneity and variations in radiosensitivity. Monoclonal antibodies were used to study the expression of carcinoembryonic antigen (CEA), gastrointestinal cancer antigen (GICA or CA 19-9) and carcinoma-associated antigen (CA-50). Radiosensitivity was studied with the clonogenic survival technique. Three cell lines, LS 174T, HCTC, and SW 1116 stained positive for all three antigens. HT-29 was positive for CA 19-9 and CA-50 whereas Caco-2 was positive for CEA and CA 19-9. The cell lines SW 620 and LIM 1215 only stained positive for one of the antigens, CA-50 and CEA, respectively. In nearly all positive cases the stainings were very heterogeneous with mixtures of positive and negative cells. One exception was the HCTC cells which stained homogeneously for the CA 19-9 and CA-50 antigens. The neuroendocrinelike COLO 320 cells were negative in all cases. The radiosensitivity varied strongly between the cell lines with D_q-values between 0.8 and 1.9, extrapolation numbers between 2.0 and 4.7, D_o-values between 1.1 and 2.8. The surviving fraction at 2 Gy varied between 0.3 and 0.7 with HCTC as the most radiosensitive and HT-29 as the most radioresistant cell line. Thus, there were differences in antigenic expression and intrinsic radiosensitivity between the cell-lines and antigenic heterogeneities within each cell line. The analyzed panel of cell lines will be valuable in studies of dose-effect relations for monoclonal antibodies labeled with toxic radionuclides simulating both antigenic heterogeneity and variations in radiosensitivity.     

Mechanisms of altered sequestration and efflux of chemotherapeutic drugs by multidrug-resistant cells

This review considers the mechanisms associated with the pleiotropic resistance of cancer cells to chemotherapeutic drugs, and more particularly those related to intracellular pH (pHi). The multidrug resistance (MDR) phenomenon responsible for the decreased accumulation and increased efflux of cytotoxic drugs is generally associated with excess levels of P-glycoproteins (Pgps) encoded by MDR genes and/or the multidrug resistance-associated protein (MRP). MDR cell lines, derived from normal or tumor cells, frequently exhibit abnormally elevated pHi and changes in the production of various proteins. Recent studies have suggested that, in addition to the impact of the ATP-dependent membrane transporters Pgp and MRP on drug transport, other mechanisms linked to pHi changes in MDR cells may play an important role in drug resistance. We have shown that alkalinization of the acidic compartments (endosomes and lysosomes) by lysosomotropic agents could stimulate the efflux of vinblastine from drug-resistant mouse renal proximal tubule cells. The fact that weak base chemotherapeutic drugs can be sequestered within the acidic organelles of MDR cells sheds new light on the cellular mechanisms of drug resistance. This revised version was published online in July 2006 with corrections to the Cover Date.