Jonathan Coulter

RNAi-Mediated Silencing of Nuclear Factor Erythroid-2–Related Factor 2 Gene Expression in Non–Small Cell Lung Cancer Inhibits Tumor Growth and Increases Efficacy of Chemotherapy

Nuclear factor erythroid-2-related factor 2 (Nrf2) is a redox-sensitive transcription factor that regulates the expression of electrophile and xenobiotic detoxification enzymes and efflux proteins, which confer cytoprotection against oxidative stress and apoptosis in normal cells. Loss of function mutations in the Nrf2 inhibitor, Kelch-like ECH-associated protein (Keap1), results in constitutive activation of Nrf2 function in non-small cell lung cancer. In this study, we show that constitutive activation of Nrf2 in lung cancer cells promotes tumorigenicity and contributes to chemoresistance by up-regulation of glutathione, thioredoxin, and the drug efflux pathways involved in detoxification of electrophiles and broad spectrum of drugs. RNAi-mediated reduction of Nrf2 expression in lung cancer cells induces generation of reactive oxygen species, suppresses tumor growth, and results in increased sensitivity to chemotherapeutic drug-induced cell death in vitro and in vivo. Inhibiting Nrf2 expression using naked siRNA duplexes in combination with carboplatin significantly inhibits tumor growth in a subcutaneous model of lung cancer. Thus, targeting Nrf2 activity in lung cancers, particularly those with Keap1 mutations, could be a promising strategy to inhibit tumor growth and circumvent chemoresistance.

High levels of the Mps1 checkpoint protein are protective of aneuploidy in breast cancer cells

Most human cancers are aneuploid and have chromosomal instability, which contrasts to the inability of human cells to normally tolerate aneuploidy. Noting that aneuploidy in human breast cancer correlates with increased expression levels of the Mps1 checkpoint gene, we investigated whether these high levels of Mps1 contribute to the ability of breast cancer cells to tolerate this aneuploidy. Reducing Mps1 levels in cultured human breast cancer cells by RNAi resulted in aberrant mitoses, induction of apoptosis, and decreased ability of human breast cancer cells to grow as xenografts in nude mice. Remarkably, breast cancer cells that survive reductions in levels of Mps1 have relatively less aneuploidy, as measured by copies of specific chromosomes, compared with cells that have constitutively high levels of Mps1. Thus, high levels of Mps1 in breast cancer cells likely contribute to these cells tolerating aneuploidy.

Selective Inhibition of Fatty Acid Synthase for Lung Cancer Treatment

Purpose: Fatty acid synthase (FAS) is overexpressed in many human cancers and is considered to be a promising target for therapy. However, in vitro use of previous generations of FAS inhibitors has been limited by severe, but reversible, anorexia in treated animals, which is thought to be related to a parallel stimulation of fatty acid oxidation by these agents. This study investigated pharmacologic inhibition of FAS using C93, a rationally designed molecule that inhibits FAS activity without affecting fatty acid oxidation in preclinical models of lung cancer. Experimental Design: Activity of C93 on FAS and fatty acid oxidation was evaluated in cultured non–small cell lung cancer (NSCLC) cells. Antineoplastic activity of the compound, given orally or by i.p. injection, was evaluated in s.c. and orthotopic NSCLC xenografts. Results: Our experiments confirm that C93 effectively inhibits FAS without stimulating fatty acid oxidation in lung cancer cells. More importantly, C93 significantly inhibits the growth of both s.c. and orthotopic xenograft tumors from human NSCLC cell lines without causing anorexia and weight loss in the treated animals. Conclusions: We conclude that inhibition of FAS can be achieved without parallel stimulation of fatty acid oxidation and that inhibition of tumor growth in vivo can be achieved without anorexia and weight loss. Thus, this therapeutic strategy holds promise for clinical treatment of cancers, including non–small cell lung cancer, the leading cause of cancer mortality in the United States and Europe.

Inhibiting Fatty Acid Synthase for Chemoprevention of Chemically Induced Lung Tumors

Purpose: Fatty acid synthase (FAS) is overexpressed in lung cancer, and we have investigated the potential use of FAS inhibitors for chemoprevention of lung cancer. Experimental Design: Expression of FAS was evaluated in preinvasive human lung lesions (bronchial squamous dysplasia and atypical adenomatous hyperplasia) and in murine models of lung tumorigenesis [4-(methylnitrosamino)-I-(3-pyridyl)-1-butanone–induced and urethane-induced lung tumors in A/J mice]. Then, the ability of pharmacologic inhibitors of FAS to prevent development of the murine tumors was investigated. Finally, the effect of the FAS inhibitor treatment of levels of phosphorylated Akt in the murine tumors was evaluated by immunohistochemistry. Results: Immunohistochemical studies show that human bronchial dysplasia and atypical adenomatous hyperplasia express high levels of FAS compared with normal lung tissues, suggesting that FAS might be a target for intervention in lung carcinogenesis. FAS is also expressed at high levels in chemically induced murine lung tumors, and the numbers and sizes of those murine tumors are significantly reduced by treating carcinogen-exposed mice with pharmacologic inhibitors of FAS, C75 and C93. C93 treatment is associated with reduced levels of phosphorylated Akt in tumor tissues, suggesting that inhibition of this signal transduction pathway might be involved in the chemopreventative activity of this compound. Conclusions: We conclude that increased levels of FAS are common in human preinvasive neoplasia of the lung. Based on studies in mouse models, it seems that inhibiting FAS is an effective strategy in preventing and retarding growth of lung tumors that have high expression of this enzyme.

Coix seed extract, A commonly used treatment for cancer in china, inhibits NFκB and protein kinase C signaling

A pharmaceutical grade extract of Coix lachryma-jobi seeds is currently the most commonly used treatment for cancer in China. Although clinical data supports the use of this preparation of a Traditional Chinese Medicine for cancer treatment, biological basis for the activity of this preparation has not been previously established. To address this issue, we first evaluated the anti-neoplastic activity of a Coix extract emulsion in xenografts of MDA-MB-231 breast cancer cells and found that the extract significantly inhibits growth of MDA-MB-231 xenografts in athymic nude mice. Using oligonucleotide microarrays, we determined that Coix seed extract extract also significantly affects gene expression in these cells, including down-regulation of genes (such as COX-2 and matrixmetalloproteinases) that are considered to be important in neoplasia. The specific gene expression changes noted after Coix treatment are characteristic of inhibition of NFκB-dependant transcription, leading us to evaluate how the treatment affects that pathway. An NFκB-dependant reporter assay demonstrated dose-dependant inhibition of NFκB signaling by treatment of cultures with the extract, and immunofluorescent microscopy found that these effects are associated with reduced translocation of the Rel-A/p65 subunit of NFκB to the nucleus. Coix extract also inhibits activity of protein kinase C, a major mediator of signal transduction and activator of NFκB. Thus, this Traditional Chinese Medicine-based cancer treatment affects cellular pathways of recognized importance in neoplasia.

Hydroquinone Increases 5-Hydroxymethylcytosine Formation through Ten Eleven Translocation 1 (TET1) 5-Methylcytosine Dioxygenase

Background: Hydroquinone is a benzene metabolite shown to lead to decreased DNA methylation. Results: Hydroquinone exposure increases Ten Eleven Translocation 1 methylcytosine dioxygenase activity and 5-hydroxymethylcytosine levels and decreases DNA methylation. Conclusion: Hydroquinone leads to DNA demethylation through a Ten Eleven Translocation 1-dependent mechanism. Significance: This mechanism may explain observations of decreased DNA methylation and cytotoxicity following exposure to benzene and hydroquinone. DNA methylation regulates gene expression throughout development and in a wide range of pathologies such as cancer and neurological disorders. Pathways controlling the dynamic levels and targets of methylation are known to be disrupted by chemicals and are therefore of great interest in both prevention and clinical contexts. Benzene and its metabolite hydroquinone have been shown to lead to decreased levels of DNA methylation, although the mechanism is not known. This study employs a cell culture model to investigate the mechanism of hydroquinone-mediated changes in DNA methylation. Exposures that do not affect HEK293 cell viability led to genomic and methylated reporter DNA demethylation. Hydroquinone caused reactivation of a methylated reporter plasmid that was prevented by the addition of N-acetylcysteine. Hydroquinone also caused an increase in Ten Eleven Translocation 1 activity and global levels of 5-hydroxymethylcytosine. 5-Hydroxymethylcytosine was found enriched at LINE-1 prior to a decrease in both 5-hydroxymethylcytosine and 5-methylcytosine. Ten Eleven Translocation-1 knockdown decreased 5-hydroxymethylcytosine formation following hydroquinone exposure as well as the induction of glutamate-cysteine ligase catalytic subunit and 14-3-3σ. Finally, Ten Eleven Translocation 1 knockdown decreased the percentage of cells accumulating in G2+M following hydroquinone exposure, indicating that it may have a role in cell cycle changes in response to toxicants. This work demonstrates that hydroquinone exposure leads to active and functional DNA demethylation in HEK293 cells in a mechanism involving reactive oxygen species and Ten Eleven Translocation 1 5-methylcytosine dioxygenase.

A functional screen identifies miRNAs that inhibit DNA repair and sensitize prostate cancer cells to ionizing radiation

MicroRNAs (miRNAs) have been implicated in DNA repair pathways through transcriptional responses to DNA damaging agents or through predicted miRNA regulation of DNA repair genes. We hypothesized that additional DNA damage regulating miRNAs could be identified by screening a library of 810 miRNA mimetics for the ability to alter cellular sensitivity to ionizing radiation (IR). A prostate cancer Metridia luciferase cell model was applied to examine the effects of individual miRNAs on IR sensitivity. A large percentage of miRNA mimetics were found to increase cellular sensitivity to IR, while a smaller percentage were protective. Two of the most potent IR sensitizing miRNAs, miR-890 and miR-744–3p, significantly delayed IR induced DNA damage repair. Both miRNAs inhibited the expression of multiple components of DNA damage response and DNA repair. miR-890 directly targeted MAD2L2, as well as WEE1 and XPC, where miR-744–3p directly targeted RAD23B. Knock-down of individual miR-890 targets by siRNA was not sufficient to ablate miR-890 radiosensitization, signifying that miR-890 functions by regulating multiple DNA repair genes. Intratumoral delivery of miR-890 mimetics prior to IR therapy significantly enhanced IR therapeutic efficacy. These results reveal novel miRNA regulation of DNA repair and identify miR-890 as a potent IR sensitizing agent.

High levels of fatty acid synthase expression in esophageal cancers represent a potential target for therapy.

Fatty acid synthase (FAS) is overexpressed in many human cancers and is considered to be a promising target for therapy. To investigate the expression of this candidate target in esophageal cancer, we evaluated expression of FAS protein in 22 cases of esophageal squamous cancer, 79 cases of esophageal adenocarcinoma, and 16 cases of Barretts esophagus with high-grade dysplasia - a lesion thought to represent a pre-invasive precursor to esophageal cancer. Using immunohistochemistry, we found significantly higher levels of FAS expression in 77 % of the squamous cancers, 96% of the adenocarcinomas, and 94% of the Barretts lesions with high-grade dysplasia, when compared to levels in normal esophageal epithelium and non-dysplastic Barrett mucosa. To evaluate the potential for inhibiting this enzyme as a treatment of esophageal cancer, we treated mice bearing xenografts of the Colo680N esophageal squamous cell carcinoma cell line using C93, a rationally designed molecule that inhibits FAS activity. In these experiments, C93 significantly inhibited the growth of orthotopic xenograft tumors without causing anorexia and weight loss in the treated animals. We conclude that, similar to several other common types of human cancer, FAS is expressed at very high levels in esophageal cancer, and growth of these cancers can be inhibited by pharmacological agents that target this enzyme. Moreover, this high expression of FAS is also seen in high-risk, pre-invasive lesions of the esophagus, leading us to propose considering FAS-inhibitors for purposes of esophageal cancer chemoprevention.

GSTP1 Loss Results in Accumulation of Oxidative DNA Base Damage and Promotes Prostate Cancer Cell Survival Following Exposure to Protracted Oxidative Stress

Epigenetic silencing of glutathione S‐transferase π (GSTP1) is a hallmark of transformation from normal prostatic epithelium to adenocarcinoma of the prostate. The functional significance of this loss is incompletely understood. The present study explores the effects of restored GSTP1 expression on glutathione levels, accumulation of oxidative DNA damage, and prostate cancer cell survival following oxidative stress induced by protracted, low dose rate ionizing radiation (LDR).

Induction of a trophoblast-like phenotype by hydralazine in the p19 embryonic carcinoma cell line

Chemicals that affect cellular differentiation through epigenetic mechanisms have potential utility in treating a wide range of diseases. Hydralazine decreases DNA methylation in some cell types but its effect on differentiation has not been well explored. After five days of exposure to hydralazine, P19 embryocarcinoma cells displayed a giant cell morphology and were binucleate, indicative of a trophoblast-like morphology. Other trophoblast-like properties included the intermediary filament Troma-1/cytokeratin 8 and the transcription factor Tead4. A decrease in CpG methylation at three sites in the TEAD4 promoter and the B1 repeated sequence was observed. Knocking down expression of Tead4 with siRNA blocked the increase in Troma-1/cytokeratin 8 and over expression of Tead4 induced the expression of Troma-1/cytokeratin 8. Cells treated for 5days with hydralazine were no longer capable of undergoing retinoic acid-mediated neuronal differentiation. An irreversible loss of the pluripotent transcription factor Oct-4 was observed following hydralazine exposure. In summary, hydralazine induces P19 cells to assume a trophoblast-like phenotype by upregulating Tead4 expression through a mechanism involving DNA demethylation.