Identification of a glutathione peroxidase inhibitor that reverses resistance to anticancer drugs in human B-cell lymphoma cell lines

Cancer cells isolated from two patients with malignant non-Hodgkin B-cell lymphomas that became resistant to chemotherapy during clinical treatment were made ?fourfold resistant in culture to anticancer drugs, that is cisplatin, etoposide, methotrexate and bortezomib. Because most resistant lines showed significantly increased expression of the anti-oxidative enzyme glutathione peroxidase 1 (GPx1), GPx1 was investigated as a target for inhibitor development. Virtual screening of a library of diverse structures by docking them to the active site of the X-ray crystal structure of bovine GPx1 uncovered compounds that might block the enzyme. An enzyme assay confirmed an acylhydrazone heterocycle (3) with GPx inhibitory activity. Combinations of 3 with the anticancer drugs listed above led to reversal of resistance in the lymphoma cell lines.     

Analysis of gene expression profiles associated with cisplatin resistance in human ovarian cancer cell lines and tissues using cDNA microarray

Gene expression profiles were analyzed by using cDNA microarray for a cisplatin-sensitive cell line (KF), and three- and thirty-fold cisplatin-resistant ovarian cancer cell lines (KFr and KFrP200) both showing no p53 mutation within exon 5, 6, 7, 8 and no pglycoprotein overexpression. Expression of GST-pi mRNA increased as the level of resistance to cisplatin became high. Microarray analysis revealed that DNA repair associated genes, i.e., XRCC5, XRCC6, ERCC5, hMLH1 were over-expressed in three-fold cisplatin-resistant cell line, KFr as compared to cisplatin-sensitive parental cell line, KF. Apoptosis inhibitors, i.e., IGFR type I and II were over-expressed, and apoptosis inducer, i.e., caspase 3 and BAK were underexpressed in highly cisplatin-resistant cell line, KFrP200 as compared to KFr. As for clinical cases, cDNA microarray was used to compare gene expression profiles directly between two groups, i.e., the chemotherapy (CAP) sensitive group (n = 2) and the resistant group (n = 2). Six genes such as beta tubulin, high-mobility group (nonhistone chromosomal) protein 1, connective tissue growth factor, insulin-like growth factor binding protein 2, alpha tubulin, and RAS-related gene were overexpressed in CAP therapy resistance group, whereas seven genes such as CD9 antigen, alpha-2-macroglobulin, caveolin 2, interleukin 1 receptor antagonist, Rho GTPase activating protein 1, reticulon 3, cyclin-dependent kinase 10, keratin 7 were underexpressed in CAP therapy resistance group. By increasing clinical case number and gene number of microarray to be used in the analysis of expression profile of gene cluster affecting anticancer drug resistance and sensitivity of the ovarian cancer, it would be possible to apply microarray analysis to personalization of chemotherapy such as selection of effective chemotherapy protocol and prediction of therapeutic effect in the near future.     

Cardiac glycosides induce resistance to tubulin-dependent anticancer drugs in androgen-independent human prostate cancer

Due to high prevalence and mortality and the lack of effective therapies, prostate cancer is one of the most crucial health problems in men. Drug resistance aggravates the situation, not only in human prostate cancer but also in other cancers. In this study, we report for the first time that cardiac glycosides (e.g. ouabain and digitoxin) induced resistance of human prostate cancer cells (PC-3) in vitro to tubulin-binding anticancer drugs, such as paclitaxel, colchicine, vincristine and vinblastine. Cardiac glycosides exhibited amazing ability to reverse the G2/M arrest of the cell cycle and cell apoptosis induced by tubulin-binding agents. However, neither ionomycin (a Ca(2+) ionophore) nor veratridine (a Na(+) ionophore) mimicked the preventive action of cardiac glycosides, indicating that elevation of the intracellular Ca(2+) concentration and Na(+) accumulation were not involved in the cardiac glycoside action. Furthermore, cardiac glycosides showed little influence on the effects induced by actinomycin D, anisomycin and doxorubicin, suggesting selectivity for microtubule-targeted anticancer drugs. Using in situ immunofluorescent detection of mitotic spindles, our data showed that cardiac glycosides diminished paclitaxel-induced accumulation of microtubule spindles; however, in a non-cell assay system, cardiac glycosides had little influence on colchicine- and paclitaxel-induced microtubule dynamics. Using an isotope-labeled assay method, we found that ouabain modestly but significantly inhibited the transport of [(14)C]paclitaxel from the cytosol into the nucleus. It is suggested that cardiac glycosides inhibit the G2/M arrest induced by tubulin-binding anticancer drugs via an indirect blockade on microtubule function. The decline in transport of these drugs into the nucleus may partly explain the action of cardiac glycosides.     

A proteomic approach to paclitaxel chemoresistance in ovarian cancer cell lines

Ovarian cancer is the leading cause of gynaecological cancer mortality. Paclitaxel is used in the first line treatment of ovarian cancer, but acquired resistance represents the most important clinical problem and a major obstacle to a successful therapy. Several mechanisms have been implicated in paclitaxel resistance, however this process has not yet been fully explained. To better understand molecular resistance mechanisms, a comparative proteomic approach was undertaken on the human epithelial ovarian cancer cell lines A2780 (paclitaxel sensitive), A2780TC1 and OVCAR3 (acquired and inherently resistant). Proteins associated with chemoresistance process were identified by DIGE coupled with mass spectrometry (MALDI-TOF and LC-MS/MS). Out of the 172 differentially expressed proteins in pairwise comparisons among the three cell lines, 151 were identified and grouped into ten main functional classes. Most of the proteins were related to the category of stress response (24%), metabolism (22%), protein biosynthesis (15%) and cell cycle and apoptosis (11%), suggesting that alterations of those processes might be involved in paclitaxel resistance mechanisms. This is the first direct proteomic comparison of paclitaxel sensitive and resistant ovarian cancer cells and may be useful for further studies of resistance mechanisms and screening of resistance biomarkers for the development of tailored therapeutic strategies.     

End products of glucose and glutamine metabolism by cultured cell lines

Rates of CO2 production from glucose and glutamine, intracellular metabolite levels, and release of metabolic end products into the culture medium were determined for 13 cultured cell lines, including a glycolysis-defective mutant. All the non-mutant lines synthesized pyruvate, lactate, alanine, proline, aspartate, and citrate, so that the metabolism of glucose and glutamine resulted mainly in the production of these compounds and only to a lesser extent in complete oxidation to CO2. These data and the pattern of metabolites produced by the mutant line were consistent with a model characterized by incomplete glutamine oxidation leading to end product accumulation. Multiple linear regression analysis identified the metabolite levels most highly correlated with the intracellular citrate level and with the amount of citrate released into the medium. The analysis also showed that the rates of CO2 production from glucose and glutamine were themselves positively correlated, suggesting that the oxidation of the two substrates is coordinately controlled under normal culture conditions.     

Effect of metal-based anticancer drugs on wild type and metallothionein null cell lines

Metallothioneins (MT) are ubiquitous low-molecular-weight metal-binding intracellular proteins. We used wild type mouse embryo fibroblasts, GKA1, and its MT-null variant, named GKA2, in order to correlate the presence of MT to the response to a number of different antitumor drugs with different mechanisms of action. We studied sensitivity of GKA1 and GKA2 cells to metal-based compounds having alkylating property, or able to generate reactive oxygen species (ROS); as well as to drugs acting with different mechanisms. The absence of MT in GKA2 cells was correlated to higher sensitivity to the metal-based drugs compared to that of GKA1. No marked differences in sensitivity of two cell lines against gemcitabine, taxol, and vinblastine were observed. No significant change in sensitivity of either GKA1 or GKA2 cells to these non-alkylating drugs was seen after heavy metal pretreatments. In GKA1 cells, MT biosynthesis was induced by copper and cadmium but not by zinc treatment under the conditions of these experiments. Induction of MT was directly proportional to decrease in sensitivity of GKA1 cells to the compounds used in this experiment. In contrast to GKA1 cells, the MT-null cells (GKA2) expressed no detectable metallothionein either constitutively or after treatment with zinc, copper, or cadmium. Nonetheless, heavy metal pretreatment of GKA2 cells did not cause any change in their sensitivity.     

Vault-related resistance to anticancer drugs determined by the expression of the major vault protein LRP

In this review we analyze the data supporting the notion that vault-related MDR, as reflected by LRP/MVP overexpression, represents a marker of drug resistance in vitro and in the clinic. Vaults, besides playing a fundamental biological role, may be involved in a novel mechanism of MDR. This revised version was published online in August 2006 with corrections to the Cover Date.     

Association of genomic imbalances with resistance to therapeutic drugs in human melanoma cell lines

The reason why human malignant melanomas respond poorly to chemotherapy is not known. In an attempt to identify genes responsible for such resistance or sensitivity to therapeutic drugs, we studied the parental human melanoma cell line MeWo, as well as eight drug-resistant sublines of MeWo. These have low and high levels of resistance to four chemotherapeutic drugs with different modes of action: Vindesine, cisplatin, fotemustine and etoposide. Comparative genomic hybridizations with genomic DNA from these cell lines as probes revealed a number of chromosome gains and losses which occurred upon selective pressure during development of the sublines. The MeWo subline with high resistance to the topoisomerase II inhibitor, etoposide, exhibited the highest number of acquired chromosome imbalances. Interestingly, the two lines with high resistance to cisplatin and fotemustine, respectively, shared three additional imbalances, loss of 9p, loss of distal 12p and gain on distal 15q. The importance of these coincident imbalances is discussed.     

Oncogenes and oncogene products in urogenital cancer cells

Recent development in microbiology and genetic engineering has provided the identification and characterization of so-called 'oncogenes'. The concept of oncogenes has much stimulated intense interest in searching the cause of uncontrolled cell growth and factors responsible for formation of tumors. Because of the fact that oncogenes were first discovered in an established cell line derived from patient with bladder tumor, the association between oncogenes and genitourinary cancer has much attention. Variety of pathways of tumor development in bladder cancer can be divided in two major forms, low grade papillary tumor and high grade infiltrating tumor. Activation and a sequence of oncogenes may be relevant to the ultimate expression of these separate pathways. Concept of initiation and promotion may also be factored into these consideration. The application of these principles to the different pathways of tumor development such as in bladder, kidney and prostate cancers, supports the concept that oncogenes may be required to production of malignant tumors. The purpose of this paper is to review recent evidence that has enhanced our understanding of the genetic basis of cancer development in the genitourinary tract cancer.     

Correlation between classification of human urothelial cell lines and HLA-A,B,C expression

Summary Quantitative changes in major histocompatibility class I antigen expression in tumour cells are believed to affect the host immune response against the tumour. In tumourigenic (TGrIII) human urothelial cell lines the apparent loss of polymorphic HLA-A,B epitopes has previously been demonstrated. In the present study, 3 non-tumourigenic (TGrII) and 6 tumourigenic (TGrIII) human urothelial cell lines have been investigated for their quantitative expression of monomorphic HLA-A,B,C and B₂-microglobulin. Evidence is provided that an inverse correlation exists between tumourigenicity and HLA-A,B,C and B₂-microglobulin expression. Furthermore, treatment of the cells with neuraminidase partly restored the expression of monomorphic HLA-A,B,C suggesting that at least some of the observed quantitative differences could be due to masking of the membrane bound HLA antigens by sialic acid-containing glycoconjugates.     

Correlation between PTEN and P62 gene expression in rat colorectal cancer cell

ObjectiveAutophagy is a cellular pathway that regulates the transportation and degradation of cytoplasmic macromolecules and organelles towards lysosome, which is often related to the tumorigenesis and tumor suppression. Here, we investigate the regulating effect of PTEN gene on autophagy-related protein P62 in rat colorectal cancer (CRC) cells and explore the application value of PTEN gene in clinic.MethodsRat colorectal cancer was induced by intraperitoneal injection of 1,2-dimethyl hydrazine in male ACI rats. A total of 20 rats were randomly selected from those successfully induced with CRC as the experimental group, while 10 healthy rats as control. The rat CRC cells were isolated and cultured. After transfecting the rat CRC cells with pEGFP-N1-PTEN plasmid, RT-PCR was adopted to examine that gene expression of p62 and PTEN, while Western blotting was used to detect the protein expression of p62 and PTEN. Also, the proliferation of CRC cells was measured by MTT assay.ResultsThe expression of PTEN gene in the experimental group was significantly inhibited as compared with the control group, while the expression of P62 gene was significantly increased (p < 0.05). Western blotting demonstrated that the PTEN protein in the experimental group was lower, while the expression of P62 protein was higher. When the CRC cells were transfected with pEGFP-N1-PTEN plasmid, the PTEN expressions were elevated, while p62 was down-regulated. Also, the proliferation of CRC cells was inhibited.ConclusionThe expression of PTEN gene is negatively correlated with the expression of P62 gene in rat CRC cells. And the expression of PTEN gene can inhibit the occurrence and development of colorectal cancer, thus providing theoretical basis for future clinical treatment.     

Glycoproteomics of paclitaxel resistance in human epithelial ovarian cancer cell lines: Towards the identification of putative biomarkers

Glycosylation, one of the most common post translational modifications (PTMs) of proteins, is often associated with carcinogenesis and tumor malignancy. Ovarian cancer is the sixth cause of cancer-related death in Western countries. Currently, it is treated by debulking surgery followed by chemotherapy based on paclitaxel, alone or in combination with other drugs. However, chemoresistance represents a major obstacle to positive clinical outcome. We used two approaches, Multiplexed Proteomics (MP) technology and Multilectin Affinity Chromatography (MAC) to characterize the glycoproteome of the human ovarian cancer cell line A2780 and its paclitaxel resistant counterpart A2780TC1. Furthermore proteins were separated by traditional 2DE or DIGE and identified by MS (MALDI TOF or LC MS/MS). Seventy glycoproteins were successfully identified in ovarian cancer cells and 10 were found to be differentially expressed between sensitive and resistant cell lines. We focused on four glycoproteins (tumor rejection antigen (gp96) 1, triose phosphate isomerase, palmitoyl-protein thioesterase 1 precursor and ER-associated DNAJ) which were remarkably upregulated in A2780TC1 compared to A2780 cell line and which may represent biomarkers for paclitaxel resistance in ovarian cancer.     

Synergistic anticancer action of quercetin and curcumin against triple-negative breast cancer cell lines

Women with the breast cancer type 1 susceptibility protein (BRCA1) mutation and loss of BRCA1 expression are reported to have an increased risk of triple-negative breast cancer (TNBC). Targeting BRCA1 modulation might offer a therapeutic option to treat TNBC patients. Our studies detected that BRCA1 is poorly expressed in TNBC cell lines and highly expressed in ER⁺ breast cancer cell lines. To modulate BRCA1 expression, we tested two different dietary components to find out if any would induce tumor suppressor genes. We detected that quercetin and curcumin dose-dependently enhanced the BRCA1 expression. Further, a synergistic action of quercetin and curcumin was observed in modulating the BRCA1 level and in inhibiting the cell survival and migration of TNBC cell lines. Quercetin and curcumin appeared to induce BRCA1 promoter histone acetylation. Furthermore, BRCA1 knockdown induced cell survival and cell migration in ER ⁺ cells were significantly decreased by the combined treatment of quercetin and curcumin. Our present study concluded that the combination treatment of quercetin and curcumin acts synergistically to induce anticancer activity against TNBC cells by modulating tumor suppressor genes.     

Correlation of the cell phenotype of cultured cell lines with their adhesion to components of the extracellular matrix

The differential adhesion of cultured mammalian clonal cell lines to components of the extracellular matrix was examined by kinetic adhesion and long-term growth assays. Uniform artificial matrices were prepared by air drying collagen Type I solution (C) onto a microtiter well and then air drying a solution containing a single glycosaminoglycan (GAG): hyaluronic acid (HA), chondroitin sulfate-4 (CHS-4), or chondroitin sulfate-6 (CHS-6). The adhesion of [3H]thymidine-prelabeled cells suspended in fibronectin (FN) depleted medium was measured at 2 and 6 hr. Neuroblastoma (N18, Lan 1) and melanoma (B16, G361, S91) cell lines exhibited a significantly greater percentage of cells adhering to one or more C-GAG matrices compared with C matrices. Maximal adhesion at 2 hr was to C-HA. In contrast at 2 hr, two glial, two epithelial, and one fibroblastic cell line showed unchanged or significantly decreased binding to C-GAG compared with C matrices. Further experiments using a neuroblastoma (N18) and a glioma (C6) cell line indicated that the adhesion patterns were not altered either by the method of dissociation from the tissue culture dish, preincubation with exogenous GAG, or the addition of exogenous fibronectin. Assays of N18 and C6 adhesion to matrices made from a non-GAG polyanionic compound, polygalacturonic acid (PGA), did not yield the same adhesion patterns as C-HA matrices. Long-term growth studies of a neuroblastoma (N18) melanoma (S91), and glioma (C6) cell line on nonuniform matrices deliberately prepared with GAG-rich and GAG-poor regions complemented the observations from the kinetic adhesion assays. N18 and S91 cells did not grow on areas which did not contain GAG by toluidine blue staining. However, the C6 cells did not grow on areas which did strongly stain for GAG. A quantitative analysis of the long term growth of N18 and C6 cells substantiated these observations. All these data indicate that the cellular phenotype may be correlated with matrix adhesion. Neuroblastomas and melanomas have a greater affinity for GAG-containing matrices while glial, epithelial, and fibroblastic cells appear to have a greater or equal affinity for collagen matrices.     

JFCR39, a panel of 39 human cancer cell lines, and its application in the discovery and development of anticancer drugs

Over the past few decades, panels of human cancer cell lines have made a significant contribution to the discovery and development of anticancer drugs. The National Cancer Institute 60 (NCI60), which consists of 60 cell lines from various human cancer types, remains the most powerful human cancer cell line panel for high throughput screening of anticancer drugs. The development of JFCR39, comprising a panel of 39 human cancer cell lines coupled with a drug-activity database, was based on NCI60. Like NCI60, JFCR39 not only provides disease-oriented information but can also predict the action mechanism or molecular target of a given antitumor agent by utilizing the COMPARE algorithm. The molecular targets of ZSTK474 as well as several other antitumor agents have been identified by using JFCR39 and some of these compounds have since entered clinical trials. In this review, we will describe human cancer cell line panels particularly JFCR39 and its application in the discovery and/or development of anticancer drug candidates.