UMLS:C0178874 - FACTA Search

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Query: UMLS:C0178874 (tumor progression)
40,807 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The current paradigm states that cancer progression is caused by random independent mutations, each selected for its survival advantages. The accelerated rates of phenotypic changes, the pleiotropic effect of several genes involved in progression--which need not be necessarily mutated for inducing the observed changes in cancer cell behaviour--lead us to propose an alternative hypothesis. Malignant progression might be a result of the unveiling of a cell-survival program, induced by various aggressions in the same way as the SOS system is induced and regulated in bacteria. This hypothesis depends on the homology between several genes involved in cancer progression (such as bcl2, mdm2, the mismatch repair genes, the heat shock protein genes, the pleiotropic resistance genes, the telomerase gene ...) and several genes involved in the survival of prokaryotes and eukaryotes under stress. The development of multicellular organisms could not take place without the building of a control program, exemplified by the so-called anti-oncogenes. However, this control program had to integrate some weaknesses, in order to allow for embryogenesis, growth, and wound healing. These weaknesses, neutral from an evolutionary point of view--since most cancers are sporadic and kill their hosts long after the birth of the offspring--are exploited by the survival program of individual cells, inherited from the genome of prokaryotes and unicellular eukaryotes, and repressed but not suppressed in animals. If this theory is true, it is probable that (i) no anti-oncogenes will be found in unicellular organisms, (ii) the sensitivity to mutations will be higher in genes involved in proliferation and in anti-oncogenes such as p53 and Rb, than in genes not involved in the cancer process, (iii) a process of transfer of genetic information exists in cancer cells as it exists in bacteria. The identification of the genes governing the survival program could lead to new therapeutic approaches.
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PMID:Tumour progression: random mutations or an integrated survival response to cellular stress conserved from unicellular organisms? 873 76

The human oesophageal epithelium is subject to damage from thermal stresses and low extracellular pH that can play a role in the cancer progression sequence, thus identifying a physiological model system that can be used to determine how stress responses control carcinogenesis. The classic heat shock protein HSP70 is not induced but rather is down-regulated after thermal injury to squamous epithelium ex vivo; this prompted a longer-term study to address the nature of the heat shock response in this cell type. An ex vivo epithelial culture system was subsequently used to identify three major proteins of 78, 70, and 58 kDa, whose steady-state levels are elevated after heat shock. Two of the three heat shock proteins were identified by mass spectrometric sequencing to be the calcium-calmodulin homologue transglutaminase-3 (78 kDa) and a recently cloned oesophageal-specific gene called C1orf10, which encodes a 53-kDa putative calcium binding protein we have named squamous epithelial heat shock protein 53 (SEP53). The 70-kDa heat shock protein (we have named SEP70) was not identifiable by mass spectrometry, but it was purified and studied immunochemically to demonstrate that it is distinct from HSP70 protein. Monoclonal antibodies to SEP70 protein were developed to indicate that: (a) SEP70 is induced by exposure of cultured cells to low pH or glucose starvation, under conditions where HSP70 protein was strikingly down-regulated; and (b) SEP70 protein exhibits variable expression in preneoplastic Barrett's epithelium under conditions where HSP70 protein is not expressed. These results indicate that human oesophageal squamous epithelium exhibits an atypical heat shock protein response, presumably due to the evolutionary adaptation of cells within this organ to survive in an unusual microenvironment exposed to chemical, thermal and acid reflux stresses.
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PMID:The human oesophageal squamous epithelium exhibits a novel type of heat shock protein response. 1160 97

Vaccination of mice with GRP94/gp96, the endoplasmic reticulum Hsp90, elicits a variety of immune responses sufficient for tumor rejection and the suppression of metastatic tumor progression. Macrophages are a prominent GRP94/gp96 target, with GRP94/gp96 reported to activate macrophage NF-kappa B signaling and nitric oxide production, as well as the MAP kinase p38, JNK, and ERK signaling cascades. However, recent studies report that heat shock protein elicited macrophage activation is due, in large part, to contaminating endotoxin. To examine the generality of this finding, we have investigated the role of endotoxin in GRP94/gp96-elicited macrophage activation. We report that GRP94/gp96 binds endotoxin in a high-affinity, saturable, and specific manner. Low endotoxin calreticulin and GRP94/gp96 were purified, the latter using a novel method of depyrogenation; this resulted in GRP94/gp96 and calreticulin preparations with endotoxin levels substantially lower than those of previously reported preparations. Low endotoxin GRP94/gp96 retained its native conformation, ligand binding activity, and in vitro chaperone function, yet did not activate macrophage NF-kappa B signaling, nitric oxide production or inducible nitric-oxide synthase production. Low endotoxin GRP94/gp96 and calreticulin did, however, elicit a marked increase in ERK phosphorylation at protein concentrations as low as 2 microg/ml. These results are discussed with respect to current understanding of the contributions of endotoxin and heat shock/chaperone proteins to the stimulation of innate immune responses.
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PMID:GRP94/gp96 elicits ERK activation in murine macrophages. A role for endotoxin contamination in NF-kappa B activation and nitric oxide production. 1280 68

Using global gene expression analyses, multiple novel tumor markers overexpressed in infiltrating ductal adenocarcinomas of the pancreas have recently been identified. However, the expression of these markers in morphologically similar adenocarcinomas of the biliary tree has not been investigated. The purpose of the present study was 3-fold. First, we used 8 markers that have been shown to be overexpressed in whole tissue sections of pancreatic adenocarcinomas to validate tissue microarrays (TMAs) created from a series of pancreatic adenocarcinomas (n=68). The labeling patterns of 6 epithelial markers (fascin, mucin 4, 14-3-3sigma, prostate stem cell antigen, topoisomerase IIalpha, and cdc2/p34) were concordant with previously published studies on whole tissue sections, yet required far fewer slides and reagents. Mesothelin, an epithelial marker, and heat shock protein 47, a marker of peritumoral desmoplasia, showed lower levels of expression in the TMAs when compared with whole tissue sections. Second, we examined the previously unknown expression of the same 8 novel tumor proteins in cancers of the biliary tree by using TMAs created from a series of intrahepatic cholangiocarcinomas, gallbladder adenocarcinomas, and adenocarcinomas of the distal common bile duct (n=38). Each of the 8 markers was overexpressed in the biliary cancers, ranging from 14% demonstrating at least focal labeling with prostate stem cell antigen to 100% labeling with cdc2/p34. Most of the markers showed lower frequencies of expression in the biliary tract carcinomas in comparison to the pancreatic adenocarcinomas. In addition, expression patterns varied with location in the biliary system (intrahepatic versus gallbladder versus distal common bile duct). These differences were statistically significant (P<0.05) for mesothelin, mucin 4, and heat shock protein 47. Finally, the expression of selected markers in neoplastic progression of gallbladder cancer was examined. Two markers, fascin and mesothelin, showed up-regulation of expression with transition from carcinoma in situ to invasive adenocarcinoma, implicating a role for these markers in neoplastic progression. The results of this study indicate that TMA technology provides valid and cost-effective means to screen large numbers of novel tumor markers, even in tumors such as pancreatic and biliary adenocarcinomas that characteristically have abundant desmoplastic stroma. In addition, novel tumor markers of pancreatic adenocarcinomas show similar, yet not identical, expression patterns in biliary carcinomas. Therefore, these markers are potentially useful in developing diagnostic tests and treatment paradigms for tumors involving the biliary system.
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PMID:Analysis of novel tumor markers in pancreatic and biliary carcinomas using tissue microarrays. 1501 93

The 90-kDa heat shock protein (Hsp90) is a ubiquitous, evolutionarily highly conserved, molecular chaperone in the eukaryotic cytosol. Hsp90, together with a number of other chaperones, promotes the conformational maturation of a large variety of protein kinases. Inhibition of Hsp90 function results in the collapse of the metastable conformation of most of these kinases and leads to their proteolytic elimination by the proteasome. Numerous natural and synthetic Hsp90 inhibitors have been developed in recent years. Some of these inhibitors are also involved in sensitizing tumor cells to pro-apoptotic insults, hence serve as anti-cancer drugs. Here we review these novel protein kinase inhibitors and their emerging role in various cellular processes, apart from their inhibition of Hsp90 protein function. We focus not only on Hsp90-tumor progression, but also on cytoarchitecture, as the higher levels of cellular organization need constant remodeling, where the role of Hsp90 requires investigation. Our last major aspect deals with protein oxidation, since several Hsp90 inhibitors exert pro-oxidant effects.
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PMID:Inhibition of Hsp90: a new strategy for inhibiting protein kinases. 1502 64

The multichaperone heat shock protein (Hsp) 90 complex mediates the maturation and stability of a variety of proteins, many of which are crucial in oncogenesis, including epidermal growth factor receptor (EGF-R), Her-2, AKT, Raf, p53, and cdk4. These proteins are referred to as "clients" of Hsp90. Under unstressed conditions these proteins form complexes with Hsp90 and the cochaperones to attain their active conformations or enhance stability. Inhibition of Hsp90 function disrupts the complex and leads to degradation of client proteins in a proteasome-dependent manner. This results in simultaneous interruption of many signal transduction pathways pivotal to tumor progression and survival. Based on the unique role of the Hsp90 complex, extensive effort has been made in identifying Hsp90 inhibitors. Several compounds have been shown to inhibit Hsp90 in vitro and in vivo and the most advanced, 17-allylamino-17-demethoxygeldanamycin (AAG), is in phase I/II clinical trials. Recent findings with 17-AAG indicate that tumor cells utilize Hsp90 quite differently from normal cells, explaining the selectivity of the drug and suggesting a central role of Hsp90 in malignant progression. Thus these small molecule inhibitors have proved not only to be of great value in identifying new Hsp90 client proteins and in understanding the biology of Hsp90 but are also promising therapeutics in a variety of tumors.
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PMID:Targeting multiple signal transduction pathways through inhibition of Hsp90. 1516 26

Tumor development and progression consist of a series of complex processes involving multiple changes in gene expression (Paolo et al. Physiol. Rev., 1993, 73, 161-195; Lance et al. Cell., 1991, 64, 327-336). Tumor cells acquire an invasive and metastatic phenotype that is the main cause of death for cancer patients. Therefore, for early diagnosis and effective therapeutic intervention, we need to detect the alterations associated with transition from benign to malignant tumor cells on a molecular basis. To unravel alterations concerned with tumor progression, the proteomic approach has attracted great attention because it can identify qualitative and quantitative changes in protein composition, including post-translational modifications. In this study, we performed proteomic differential display analysis for the expression of intracellular proteins in the regressive cancer cell line QR-32 and the inflammatory cell-promoting progressive cancer cell line QRsP-11 of murine fibrosarcoma by two-dimensional gel electrophoresis and mass spectrometry using an Agilent 1100 LC/MSD Trap XCT. We found 11 protein spots whose expression was different between QR-32 and QRsP-11 cells and identified nine proteins, seven of which, calreticulin precursor, tropomyosin 1 alpha chain, annexin A5, heat shock protein (HSP)90-alpha, HSP90-beta, PEBP, and Prx II, were over-expressed, and two, Anp32e and HDGF, which were down-regulated. The results suggest an important complementary role for proteomics in identification of molecular abnormalities in tumor progression.
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PMID:Proteomic profiling for cancer progression: Differential display analysis for the expression of intracellular proteins between regressive and progressive cancer cell lines. 1571 40

N-acetyl-cysteine (NAC) has been reported to have anticancer properties such as counteractions against mutagens and prevention of tumor progression by scavenging reactive oxygen species (ROS). However, here we report that NAC can enhance the anchorage-independent growth of cells transformed by activated ABL tyrosine kinases or Ras. This effect was not dependent on loss of focal adhesion kinase activation. NAC rescued cell growth that was suppressed by heat shock protein (Hsp) 90 inhibitors possibly by chemical modification of their quinone moiety. NAC rendered Rat1/BCR-ABL cells resistance to a Ras inhibitor manumycin in soft agar colony formation. In the absence of Hsp90 inhibitors, NAC stimulated the activation of MAP kinase in BCR-ABL-transformed but not in the parental Rat1 cells. We propose that NAC should be used carefully in cancer treatment.
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PMID:N-acetyl-cysteine enhances growth in BCR-ABL-transformed cells. 1581 23

Genistein is a candidate cancer chemopreventive drug being tested in clinical trials. We have shown that genistein blocks prostate cancer (PCa) cell invasion, that p38 mitogen-activated protein (MAP) kinase regulates activation of matrix metalloproteinase type 2 (MMP-2) and cell invasion, and that genistein prevents transforming growth factor beta (TGFbeta) from activating p38 MAP kinase. More recently, we identified MAP kinase-activated protein kinase 2 (MAPKAPK2) and the 27-kDa heat shock protein (HSP27) as downstream regulators of p38 MAP kinase. However, MAPKAPK2 and HSP27 can be regulated by factors other than p38 MAP kinase, and HSP27 is up-regulated during PCa progression. The current study was undertaken to examine the role of MAPKAPK2 and HSP27 in modulating genistein-mediated regulation of PCa cell invasion. Genistein inhibited TGFbeta-mediated phosphorylation of MAPKAPK2 and HSP27. Inhibitory effects by genistein upon cell signaling, inhibition of MMP-2, and inhibition of invasion were retained when both PC3 and PC3-M cells were transfected with either wild-type MAPKAPK2 or HSP27. However, transfection with dominant-negative MAPKAPK2 or nonphosphorylatable mutant HSP27 led to decreases in cell invasion and to abrogation of responsiveness to either TGFbeta-mediated increases or genistein-mediated decreases in MMP-2 and cell invasion. It is noteworthy that, after transfection with constitutive active MAPKAPK2 or with pseudophosphorylated HSP27, levels of MMP-2 activation and cell invasion were high and overcame any inhibitory effect of genistein. These findings demonstrate that genistein-mediated inhibition of cell invasion rests upon blocking activation of the MAPKAPK2-HSP27 pathway, and that its activation during cancer progression has the potential to mitigate therapeutic efficacy.
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PMID:Genistein inhibits matrix metalloproteinase type 2 activation and prostate cancer cell invasion by blocking the transforming growth factor beta-mediated activation of mitogen-activated protein kinase-activated protein kinase 2-27-kDa heat shock protein pathway. 1677 19

Identification of the key roles of protein kinases in signaling pathways leading to development of cancer has caused pharmacological interest to concentrate extensively on targeted therapies as a more specific and effective way for blockade of cancer progression. This review will mainly focus on inhibitors targeting these key components of cellular signaling by employing a technology-based point of view with respect to ATP- and non-ATP-competitive small molecule inhibitors and monoclonal antibodies of selected protein kinases, particularly, mammalian target of rapamycin (mTOR), BCR-ABL, MEK, p38 MAPK, EGFR PDGFR, VEGFR, HER2 and Raf. Inhibitors of the heat shock protein Hsp90 are also included in a separate section, as this protein plays an essential role for the maturation/proper activation of cancer-related protein kinases. In the following review, the molecular details of the mode of action of these inhibitors as well as the emergence of drug resistance encountered in several cases are discussed in light of the structural, molecular and clinical studies conducted so far.
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PMID:Protein kinases as drug targets in cancer. 1710 May 68

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