Project description:Objective: To assess the role of aldoketoreductases and other doxorubicin pharmacokinetic or pharmacogenomic genes in doxorubicin cytotoxicity, resistance, DNA binding activity, and subcellular localization, Methods: We conducted a whole genome microarray study to identify differences in between doxorubicin-sensitive MCF-7cc cells and doxorubicin-resistant MCF-7Dox2-12 cells in terms of their expression of genes related to doxorubicin pharmacokinetics or pharmacodynamics. Targets were then validated by pharmacologic inhibition in conjunction with drug metabolite profiling, drug localization, drug cytotoxicity, and drug DNA binding studies. Results: 2063 differentially expressed transcripts were identified, including 17% and 43% of genes or gene families associated with doxorubicin pharmacokinetics or pharmacodynamics (p values of significance of 0.05 and <0.0001, respectively). The largest changes in the expression of genes associated with doxorubicin pharmacokinetics and pharmacodynamics were chiefly among the aldo-keto reductases (AKRs) Akr1c2, Akr1c3 and Akr1b10 which convert doxorubicin to doxorubicinol. We observed that doxorubicinol exhibits dramatically reduced drug toxicity, reduced drug DNA-binding activity, and altered drug subcellular localization to lysosomes. Pharmacologic inhibition of these AKRs in MCF-7Dox2-12 cells restored drug cytotoxicity, and drug localization to the nucleus. Conclusion: These findings demonstrate the utility of using curated pharmacokinetic and pharmacodynamic knowledgebases to identify highly relevant genes associated with doxorubicin resistance. The products of one or more of these genes could effectively be shown to alter the drug’s properties, while inhibiting them restored drug DNA binding, cytotoxicity, and subcellular localization. Doxorubicin resistant cell lines of breast MCF-7 cells were generated for gene expression profilling. Two colour microarray of Agilent whole human genome nucleotide arrays was conducted with four labelling replicates of both forward and reverse labellings plus another set of 8 arrays with forward labelling. Sixteen arrays were used for this experiments. The co-cultured control cells MCF-7cc12 was generated by parallel selection process in the absence of drug.

Project description:Objective: To assess the role of aldoketoreductases and other doxorubicin pharmacokinetic or pharmacogenomic genes in doxorubicin cytotoxicity, resistance, DNA binding activity, and subcellular localization, Methods: We conducted a whole genome microarray study to identify differences in between doxorubicin-sensitive MCF-7cc cells and doxorubicin-resistant MCF-7Dox2-12 cells in terms of their expression of genes related to doxorubicin pharmacokinetics or pharmacodynamics. Targets were then validated by pharmacologic inhibition in conjunction with drug metabolite profiling, drug localization, drug cytotoxicity, and drug DNA binding studies. Results: 2063 differentially expressed transcripts were identified, including 17% and 43% of genes or gene families associated with doxorubicin pharmacokinetics or pharmacodynamics (p values of significance of 0.05 and <0.0001, respectively). The largest changes in the expression of genes associated with doxorubicin pharmacokinetics and pharmacodynamics were chiefly among the aldo-keto reductases (AKRs) Akr1c2, Akr1c3 and Akr1b10 which convert doxorubicin to doxorubicinol. We observed that doxorubicinol exhibits dramatically reduced drug toxicity, reduced drug DNA-binding activity, and altered drug subcellular localization to lysosomes. Pharmacologic inhibition of these AKRs in MCF-7Dox2-12 cells restored drug cytotoxicity, and drug localization to the nucleus. Conclusion: These findings demonstrate the utility of using curated pharmacokinetic and pharmacodynamic knowledgebases to identify highly relevant genes associated with doxorubicin resistance. The products of one or more of these genes could effectively be shown to alter the drug’s properties, while inhibiting them restored drug DNA binding, cytotoxicity, and subcellular localization.

Project description:Alternative Splicing regulation protein subcellular localization

Project description:We investigated the regulation by doxorubicin of HuR binding to RNA near intronic polyadenylation (IPA) sites in several subcellular compartments of breast cancer cells.

Project description:A common limitation of cancer treatments is chemotherapy resistance. We have previously identified a molecular mechanism where chemotherapy resistance is regulated by endothelial cells. Endothelial cell specific knockout of focal adhesion kinase (FAK) sensitises tumour cells to DNA-damaging therapies, reducing tumour growth in mice. Our current study addresses the kinase dependent component of endothelial cell FAK sensitisation to the DNA damaging chemotherapeutic drug doxorubicin. FAK is recognised as a therapeutic target in tumour cells, leading to the development of a range of inhibitors, the majority being ATP competitive kinase inhibitors. We demonstrate that specific inactivation of the FAK kinase domain in endothelial cells of blood vessels in established subcutaneous B16F0 tumours sensitises melanoma cells to doxorubicin. Tumour growth was reduced in response to doxorubicin treatment in FAK kinase-dead but not in wild-type mice. Furthermore, we demonstrate that doxorubicin reduces perivascular proliferation, enhances apoptosis and DNA-damage in endothelial cell FAK kinase dead tumours. When we treated human pulmonary microvascular endothelial cells with the FAK kinase inhibitors defactinib, PF-562,271 and PF-573,228 in combination with doxorubicin, we observed a reduction in cytokine levels, implying a possible mechanism for FAK kinase domain in chemosensitisation. Together, these results confirm the role of the kinase domain of EC-FAK in chemosensitising tumour cells to doxorubicin.

Project description:Recent studies have suggested that elevated expression of aldoketoreductase (AKR) 1C1 or 1C2 in tumour cells is associated with increased resistance to DNA damaging agents such as cisplatin and doxorubicin. However, it has not been shown whether selection of tumour cells for resistance to DNA-damaging anthracyclines actually results in increased expression of AKRs and increased conversion of anthracyclines to 10-fold less toxic 13-hydroxy metabolites. It is also unclear whether the induction of aldokeoreductases is temporally correlated with the onset of anthracycline resistance and whether there is a direct relationship between the level of AKR expression or activity and the magnitude of drug resistance. Through microarray profiling of MCF-7 breast cancer cells selected for progressive resistance to doxorubicin or epirubicin, we have identified several genes whose expression has been correlated with both the onset and magnitude of drug resistance, including a “1C” AKR. AKR 1C overexpression was verified by quantitative PCR. Also associated with the onset of anthracycline resistance were genes involved in drug transport (ABCB1), cell signaling and transcription (RDC1, CXCR4), cell proliferation or apoptosis (BMP7, CAV1), ROS protection (TXNRD1, MT2A), and structural or immune system proteins (IFI30, STMN1). Consistent with the role of AKRs in anthracycline resistance, doxorubicin- and epirubicin-resistant breast tumour cells exhibited 2.2-fold and 6.1-fold higher levels of the 13-hydroxy metabolite of doxorubicin (doxorubicinol) than wildtype MCF-7 cells. In addition, an inhibitor of AKR 1C2 (5- cholanic acid) almost completely restored sensitivity to doxorubicin in Abcb1-deficient doxorubicin-resistant cells, while having no effect on Abcb1-expressing epirubicin-resistant cells. Taken together, our findings strongly suggest the involvement of multiple genes in the acquisition of anthracycline resistance in breast tumor cells---in particular redox genes such as the 1C AKRs. Keywords: Drug resistance of breast cancer cells In order to identify genes whose expression strongly correlates with the acquisition or magnitude of drug resistance or are temporally related with the acquisition of resistance, we selected MCF-7 breast tumor cells for survival in increasing concentrations (doses) of doxorubicin or epirubicin. Panels of cells exhibiting progressive resistance to either doxorubicin (MCF-7DOX-2) or epirubicin (MCF-7EPI) were obtained. Cells were also “selected” in the absence of drug at each step during selection to serve as co-cultured control (MCF-7CC) cells. In this study, we have used cDNA microarray analysis of these cell lines to identify a variety of “redox” genes whose expression can be correlated with the acquisition or magnitude of drug resistance in MCF-7DOX-2 and MCF-7EPI cells, including a “1C” aldoketoreductase (AKR).

Project description:Recent studies have suggested that elevated expression of aldoketoreductase (AKR) 1C1 or 1C2 in tumour cells is associated with increased resistance to DNA damaging agents such as cisplatin and doxorubicin. However, it has not been shown whether selection of tumour cells for resistance to DNA-damaging anthracyclines actually results in increased expression of AKRs and increased conversion of anthracyclines to 10-fold less toxic 13-hydroxy metabolites. It is also unclear whether the induction of aldokeoreductases is temporally correlated with the onset of anthracycline resistance and whether there is a direct relationship between the level of AKR expression or activity and the magnitude of drug resistance. Through microarray profiling of MCF-7 breast cancer cells selected for progressive resistance to doxorubicin or epirubicin, we have identified several genes whose expression has been correlated with both the onset and magnitude of drug resistance, including a “1C” AKR. AKR 1C overexpression was verified by quantitative PCR. Also associated with the onset of anthracycline resistance were genes involved in drug transport (ABCB1), cell signaling and transcription (RDC1, CXCR4), cell proliferation or apoptosis (BMP7, CAV1), ROS protection (TXNRD1, MT2A), and structural or immune system proteins (IFI30, STMN1). Consistent with the role of AKRs in anthracycline resistance, doxorubicin- and epirubicin-resistant breast tumour cells exhibited 2.2-fold and 6.1-fold higher levels of the 13-hydroxy metabolite of doxorubicin (doxorubicinol) than wildtype MCF-7 cells. In addition, an inhibitor of AKR 1C2 (5beta-cholanic acid) almost completely restored sensitivity to doxorubicin in Abcb1-deficient doxorubicin-resistant cells, while having no effect on Abcb1-expressing epirubicin-resistant cells. Taken together, our findings strongly suggest the involvement of multiple genes in the acquisition of anthracycline resistance in breast tumor cells---in particular redox genes such as the 1C AKRs. Keywords: Drug resistance of breast cancer cells

Project description:Genes involved in doxorubicin drug resistance in 143b osteosarcoma cell line

Project description:RNA molecules are localized to subcellular regions through interactions between localization-regulatory cis-elements and trans-acting RNA binding proteins (RBPs). However, the identities of RNAs whose localization is regulated by a specific RBP as well as the impacts of that RNA localization on cell function have generally remained unknown. Here, we demonstrate that the RBP HNRNPA2B1 acts to keep specific RNAs out of neuronal projections. Using subcellular fractionation, high-throughput sequencing, and single molecule RNA FISH, we find that hundreds of RNAs demonstrate markedly increased abundance in neurites in HNRNPA2B1 knockout cells. These RNAs often encode motor proteins and are enriched for known HNRNPA2B1 binding sites and motifs in their 3′ UTRs. The speed and processivity of microtubule-based transport is impaired in these cells, specifically in their neurites. HNRNPA2B1 point mutations that increase its cytoplasmic abundance relative to wildtype lead to stronger suppression of both RNA mislocalization and transport defects than seen with wildtype HNRNPA2B1. We further find that the subcellular localizations of HNRNPA2B1 target RNAs are sensitive to perturbations of RNA decay machinery, suggesting that it is HNRNPA2B1’s known role in regulating RNA stability that may explain these observations. These findings establish HNRNPA2B1 as a negative regulator of neurite RNA abundance and link the subcellular activities of motor proteins with the subcellular abundance of the RNAs that encode them.

Project description:GAR-Driven Subcellular Localization of the Growth Controlling RNA Binding Protein Nucleolin