Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0027651 (tumor)
 685,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Non-steroidal anti-inflammatory drugs (NSAIDs) have repeatedly shown to be effective in tumor prevention, but important side-effects limit their wide clinical use. Nitric oxide-releasing derivatives (NO-NSAIDs) are a promising class of compounds synthesized by combining a classic NSAID molecule with an NO-releasing moiety to counteract side-effects. These new chemical entities exhibit a significantly higher activity and much lower toxicity with respect to the parental drug. In the present paper, we report the results obtained from in in vitro experimental systems aimed to evaluate the activity and mechanisms of action of the novel NO-releasing aspirin derivative, NCX 4040. The in vitro studies were carried out on a panel of human colon (LoVo, LoVo Dx, WiDr, LRWZ), bladder (HT1376, MCR), and pancreatic (Capan-2, MIA PaCa-2, T3M4) cancer cell lines. With regard to colon cancer, NCX 4040 activity was also investigated in vitro in combination with drugs currently used in clinical practice and was validated in vivo on tumor-bearing mice xenografted with the aforementioned colon cancer cell lines. The in vitro studies showed a high cytotoxic activity of NCX 4040 in all tumor histotypes and demonstrated the pivotal role of the NO component in drug activity. It was also observed that NCX 4040 exerts a pro-apoptotic activity via a mitochondria-dependent pathway. Moreover, the in vivo studies on xenografted mice further confirmed the antitumor efficacy and low toxicity of NCX 4040 in colon cancer and highlighted its role as sensitizing agent of oxaliplatin cytotoxicity.
Nitric Oxide 2008 Sep
PMID:NCX 4040, an NO-donating acetylsalicylic acid derivative: efficacy and mechanisms of action in cancer cells. 1847 19

Nitric oxide (NO) has been invoked in nearly every normal and pathological condition associated with human physiology. In tumor biology, nitrogen oxides have both positive and negative affects as they have been implicated in both promoting and preventing cancer. Our work has focused on NO chemistry and how it correlates with cytotoxicity and cancer. Toward this end, we have studied both concentration- and time-dependent NO regulation of specific signaling pathways in response to defined nitrosative stress levels that may occur within the tumor microenvironment. Threshold levels of NO required for activation and stabilization of key proteins involved in carcinogenesis including p53, ERK, Akt and HIF have been identified. Importantly, threshold NO levels are further influenced by reactive oxygen species (ROS) including superoxide, which can shift or attenuate NO-mediated signaling as observed in both tumor and endothelial cells. Our studies have been extended to determine levels of NO that are critical during angiogenic response through regulation of the anti-angiogenic agent thrombospondin-1 (TSP-1) and pro-angiogenic agent matrix metalloproteinase-9 (MMP-9). The quantification of redox events at the cellular level has revealed potential mechanisms that may either limit or potentiate tumor growth, and helped define the positive and negative function of nitric oxide in cancer.
Nitric Oxide 2008 Sep
PMID:Molecular mechanisms for discrete nitric oxide levels in cancer. 1847 20

Hypoxia is a principal signature of the tumor microenvironment and is considered to be the most important cause of clinical radioresistance and local failure. Oxygen is so far the best radiosensitizer, but tumor oxygenation protocols are compromised by its metabolic consumption and therefore limited diffusion inside tumors. Many chemical radiosensitizers can selectively target hypoxic tumor cells, but their systemic toxicity compromises their adequate clinical use. NO is an efficient hypoxic radiosensitizer, as it may mimic the effects of oxygen on fixation of radiation-induced DNA damage, but the required levels cannot be obtained in vivo because of vasoactive complications. Our laboratory explored whether this problem may be overcome by endogenous production of NO inside tumors. We demonstrated that iNOS, activated by pro-inflammatory cytokines, is capable of radiosensitizing tumor cells through endogenous production of NO, at non-toxic extracellular concentrations. We observed that this radiosensitizing effect is transcriptionally controlled by hypoxia and by NF-kappaB. Tumor-associated immune cells may contribute to the iNOS-mediated radiosensitization by the generation of pro-inflammatory cytokines and NO, which may diffuse towards bystander tumor cells. Our findings indicate a rationale for combining immunostimulatory and radiosensitizing strategies in the future.
Nitric Oxide 2008 Sep
PMID:Hypoxic tumor cell radiosensitization through nitric oxide. 1847 56

Nitric oxide (NO) is a multifunctional regulator, critical to various biochemical processes, including inflammation, vasodilatation, intra- and intercellular signaling, apoptosis, and carcinogenesis. In particular, recent studies have indicated the association between elevated NO production and neoplastic cell transformation, suggesting procarcinogenic effects of NO. To investigate the mechanism by which NO facilitates oral carcinogenesis, we tested the effects of exogenous NO on the expression of hnRNP G, a novel protein demonstrating tumor suppressive effects against oral squamous cell carcinomas. Oral epithelial cells exposed to NO donor demonstrated significant reduction in the level of hnRNP G protein and mRNA expression. Also, exposure to NO donor led to decreased hnRNP G promoter activity in cells, indicating that NO negatively regulates hnRNP G expression at the level of transcription. Since hnRNP G expression is markedly decreased or completely abolished in precancerous and malignant oral lesions in situ, these results suggest the possibility that NO facilitates the progression of the disease by targeting hnRNP G expression. In this article, we review the role of hnRNP G in tumor suppression and maintenance of genetic integrity, with focus on its potential association with NO in the context of oral carcinogenesis.
Nitric Oxide 2008 Sep
PMID:Heterogeneous nuclear ribonucleoprotein G, nitric oxide, and oral carcinogenesis. 1847 62

Nitric oxide (NO) has been widely recognized as a positive regulator of tumorigenesis and cancer progression through its ability to regulate important proteins in various signal transduction pathways. S-Nitrosylation, or covalent attachment of NO to protein sulphydryl groups, has gained prominence as an important mechanism by which NO modulates physiologic and pathologic cellular responses. In this article, we discuss S-nitrosylation of two key apoptosis-regulatory proteins of the intrinsic and extrinsic death pathways, namely B-cell lymphoma-2 (Bcl-2) and FLICE-inhibitory protein (FLIP). These proteins have been shown to be upregulated in a variety of tumors and have been implicated with cancer chemoresistance through dysregulation of apoptosis. S-Nitrosylation of these proteins precludes their ubiquitination and subsequent degradation by the proteasome, thus accentuating their anti-apoptotic effect which is critical in the context of tumorigenic potential and cancer progression. We propose that such post-translational modifications of proteins by NO may be a general mechanism that tumor cells exploit to tilt the scales towards survival and proliferation by evading cell death.
Nitric Oxide 2008 Sep
PMID:Role of S-nitrosylation in apoptosis resistance and carcinogenesis. 1847 61

Metastatic spread, not primary tumor burden, is the leading cause of cancer death. Glutathione (L-gamma-glutamyl-L-cysteinyl-glycine; GSH) is the most prevalent non-protein thiol in mammalian cells, and in cancer cells is particularly relevant in regulating mutagenic mechanisms, DNA synthesis, growth, and multidrug and radiation resistance. In malignant tumors, as compared with normal tissues, that resistance associates in most cases with higher GSH levels. Interaction of metastatic cells with the vascular endothelium activates local release of proinflammatory cytokines, which act as signals promoting cancer cell adhesion, extravasation, and proliferation. A high% of metastatic cells with high GSH levels survive the nitrosative and oxidative stresses elicited by the endothelium and possibly by macrophages and granulocytes. Gamma-glutamyl transpeptidase overexpression and an interorgan flow of GSH, by increasing cysteine availability for tumor GSH synthesis, promote metastatic growth. The mechanism of NO- and H(2)O(2)-induced tumor cytotoxicity has been examined during murine B16 melanoma (B16M) adhesion to the vascular endothelium. H(2)O(2) was not cytotoxic in the absence of NO. But, NO-induced tumor cytotoxicity was increased by H(2)O(2) due to the formation of potent oxidants, likely (.)OH and ((-))OONO radicals, via a trace metal-dependent process. B16M cells with high GSH content were more resistant to NO and H(2)O(2). Cancer cell survivors showed higher Bcl-2 and GSH levels. Metastatic invaders, after surviving attack by tissue macrophages, may further enhance their resistance.
Nitric Oxide 2008 Sep
PMID:Tumoricidal activity of endothelium-derived NO and the survival of metastatic cells with high GSH and Bcl-2 levels. 1847 63

The treatment of primary tumors results in an initial response to approved conventional therapeutics. However, recurrences and malignancies develop as a result of tumors' acquisition of anti-apoptotic mechanisms of resistance. Hence, there is an urgent need of novel therapeutics that can reverse resistance. One approach of interest is the inhibition of cell survival and anti-apoptotic pathways by sensitizing agents that can render resistant tumor cells sensitive to respond to various cytotoxic therapies. We have found that nitric oxide donors, similar to DETANONOate, inhibit cell survival anti-apoptotic pathways, such as the constitutively activated NF-kappaB and sensitize drug-resistant tumor cells to apoptosis by both chemotherapy and immunotherapy. Sensitization by DETANONOate was shown to inhibit the transcription repressor Yin Yang1 (YY1) shown to regulate resistance to both Fas ligand and TRAIL. In addition, DETANONOate-induced inhibition of NF-kappaB results downstream in the inhibition of several anti-apoptotic gene products, thus facilitating the activation of the apoptotic pathways with both chemotherapy and immunotherapy. In addition, DETANONOate induces the expression of the metastatic tumor suppressor gene product, Raf-1 Kinase Inhibitor Protein (RKIP), which inhibits the survival pathways induced by NF-kappaB and Raf-1/MEK which also contributes to the sensitizing activity. This indicates a novel finding that RKIP may also play an important role in the prevention of metastasis. Inhibition of NF-kappaB activation by DETANONOate results downstream in the inhibition of the RKIP transcription repressor Snail, resulting in upregulation of RKIP. Inhibition of Snail results in downstream inhibition of the metastatic cascade initiated by the epithelial-mesenchymal transition (EMT). Thus, nitric oxide donors have the dual functions of both sensitizing tumor cells to chemotherapy and immunotherapy and are also involved in the regulation and inhibition of metastasis.
Nitric Oxide 2008 Sep
PMID:Novel therapeutic applications of nitric oxide donors in cancer: roles in chemo- and immunosensitization to apoptosis and inhibition of metastases. 1847 83

Decreased oxygen availability evokes adaptive responses, which are primarily under the gene regulatory control of hypoxia inducible factor-1 (HIF-1). Hypoxic cores of a growing tumor cell mass use this signaling circuit to gain access to further blood and nutrient supply that guarantees their continuing growth. Interestingly, NO shares with hypoxia the ability to block prolyl-hydroxylase (PHD) activity, and thus the ability to stabilize hypoxia inducible factor 1 alpha (HIF-1 alpha). Under these conditions NO mimics hypoxia, which might contribute to tumor development. Stimulating/triggering innate immune responses associated with macrophage activation often correlated with iNOS induction and massive NO release, which is known to kill NO-sensitive tumors. However, this safeguard mechanism will only be effective if all tumor cells are eliminated because apoptotic death of tumor cells implies mechanisms to stop macrophages from attacking the survivors. Apoptotic cells release factors, among others sphingosine-1-phosphate (S1P), which reprogram macrophages. Macrophage reprogramming shifts responses from a M1 and thus pro-inflammatory and killing phenotype, to a M2 phenotype, which is anti-inflammatory and pro-angiogenic. These polarized tumor associated macrophages (TAM) are actively contributing to tumor development. Apparently NO uses distinct signaling pathways that could serve as an explanation to understand how NO affects tumor development. Some of these pathways, especially the ability of NO to mimic hypoxia at the level of HIF-1 alpha, as well as the role of macrophage polarization by apoptotic cells with accompanying changes in the iNOS versus arginase ratio and activities, will be discussed to better understand how NO affects tumor growth.
Nitric Oxide 2008 Sep
PMID:Nitric oxide, apoptosis and macrophage polarization during tumor progression. 1848 31

Nitric oxide-donating nonsteroidal anti-inflammatory drugs (NO-NSAIDs) consist of a conventional NSAID to which an NO-releasing moiety is attached covalently, often via a spacer molecule. NO-NSAIDs represent an emerging class of compounds with chemopreventive properties against a variety of cancers, demonstrated in preclinical models including cell culture systems and animal tumor models; their potential efficacy in humans has not been assessed. Their mechanism of action appears complex and involves the generation of reactive oxygen species, suppression of microsatellite instability in mismatch repair-deficient cells, and modulation of several signaling cascades that culminate in inhibited cell renewal and enhanced apoptosis. NO, long appreciated to be able to protect from and also promote cancer, is released form NO-NSAIDs and constitutes their defining property. Existing data are consistent with the notion that NO may mediate their anticancer effect. In addition there is evidence that long-term administration of NO-donating compounds is not associated with increased incidence of colon cancer. Whether NO release is required for the anticancer effect of NO-NSAIDs has being questioned by recent data indicating that, at least in the case of NO-aspirin, the NO-releasing moiety may serve as a leaving group while the spacer actually being the moiety responsible for its pharmacological action. Regardless of mechanistic issues, these compounds promise to contribute to the control of cancer.
Nitric Oxide 2008 Sep
PMID:NO-donating NSAIDs and cancer: an overview with a note on whether NO is required for their action. 1848 30

This report summarizes the present state of our knowledge pertaining to the NO-induced resistance or sensitization of tumor cell death. The effects of NO and its synergy with members of the TNF family, with cytotoxic drugs, and with ionizing radiations have been investigated. The dual effect of NO-induced resistance or sensitization and the underlying molecular mechanisms are discussed.
Nitric Oxide 2008 Sep
PMID:Nitric oxide-induced resistance or sensitization to death in tumor cells. 1849 79


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