Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:P04637 (p53)
77,613 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We had previously shown that the expression of heparin/heparan sulfate interacting protein/ribosomal protein L29 (HIP/RPL29) was upregulated in colon cancer tissues. The present study investigated the role of HIP/RPL29 in differentiation in colon cancer cells. Inducing cellular differentiation in HT-29 cells by both sodium butyrate and glucose deprivation resulted in a significant downregulation of HIP/RPL29 expression. The beta-catenin/Tcf-4 pathway is the most important pathway controlling the switch between cellular differentiation and proliferation in intestinal epithelial cells. Inducing differentiation by dominant-negative inhibition of the beta-catenin/Tcf-4 complexes in LS174T cells also resulted in downregulation of HIP/RPL29. To determine whether a lower expression of HIP/RPL29 could induce differentiation in cancer cells, small interfering RNA (siRNA) targeting HIP/RPL29 was transfected into LS174T cells. The resultant knockdown of HIP/RPL29 expression induced cellular differentiation, as shown by the increased expression of two known markers of differentiation in LS174T cells, galectin-4 and mucin-2. In addition, the differentiation process induced by repression of HIP/RPL29 expression was accompanied by the upregulation of p21 and p53. In conclusion, HIP/RPL29 plays a role in the cellular differentiation process in colon cancer cells. The differentiation process is at least partially mediated by the upregulation of p21 and p53 pathways.
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PMID:Repression of HIP/RPL29 expression induces differentiation in colon cancer cells. 1647 73

PDCD5 (human programmed cell death 5) plays a significant role in apoptotic and paraptotic cell deaths. However, it was found that recombinant PDCD5 added exogenously to culture medium could also enhance programmed cell death triggered by certain stimuli. Here we show that PDCD5 has a remarkable role in intercellular transport in various cells (endogenous caveolin-1-positive and -negative cells) through a clathrin-independent endocytic pathway that originates from heparan sulfate proteoglycan binding and lipid rafts. These conclusions are supported by the studies of slow internalization kinetics of PDCD5 endosomes, by the resistance of endosomes to nonionic detergents, by the overexpression of the clathrin dominant negative mutant form, which did not block PDCD5-fluorescein isothiocyanate uptake, and by PDCD5 localization in lipid rafts by immunofluorescence, electron microscopy techniques, and sucrose density centrifugation. This is further supported by the findings that certain drugs that disrupt lipid rafts, compete with cell membrane heparan sulfate proteoglycans, or block the caveolae pathway, impair the PDCD5 internalization process. The translocation activity of PDCD5 may possess physiological significance and be a potential mechanism for its programmed cell death-promoting activity. PDCD5 protein also has the ability to drive the internalization of large protein cargo, depending on the residues 109-115 mapped by deletion mutagenesis, and can introduce the Mdm-2 binding domain of human p53 into living cells to induce cell death in human cancer cells, indicating that PDCD5 may serve as a vehicle and thus have potential in the field of protein delivery to the cells. This is the first evidence of such findings.
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PMID:Cellular uptake of exogenous human PDCD5 protein. 1675 80

Gateways to Clinical Trials are a guide to the most recent clinical trials in current literature and congresses. The data in the following tables have been retrieved from the Clinical Trials Knowledge Area of Prous Science Integrity, the drug discovery and development portal, http://integrity.prous.com. This issue focuses on the following selection of drugs: 131-I-chlorotoxin; Ad5CMV-p53, adalimumab, albumin interferon alfa, alemtuzumab, aliskiren fumarate, aminolevulinic acid methyl ester, anakinra, AR-C126532, atomoxetine hydrochloride; Bevacizumab, bosentan, botulinum toxin type B, brimonidine tartrate/timolol maleate; Calcipotriol/betamethasone dipropionate, cangrelor tetrasodium, cetuximab, ciclesonide, cinacalcet hydrochloride, collagen-PVP, Cypher; Darbepoetin alfa, darusentan, dasatinib, denosumab, desloratadine, dexosome vaccine (lung cancer), dexrazoxane, dextromethorphan/quinidine sulfate, duloxetine hydrochloride; ED-71, eel calcitonin, efalizumab, entecavir, etoricoxib; Falciparum merozoite protein-1/AS02A, fenretinide, fondaparinux sodium; gamma-Hydroxybutyrate sodium, gefitinib, ghrelin (human); hLM609; Icatibant acetate, imatinib mesylate, ipsapirone, irofulven; LBH-589, LE-AON, levocetirizine, LY-450139; Malaria vaccine, mapatumumab, motexafin gadolinium, muraglitazar, mycophenolic acid sodium salt; nab-paclitaxel, nelarabine; O6-Benzylguanine, olmesartan medoxomil, orbofiban acetate; Panitumumab, peginterferon alfa-2a, peginterferon alfa-2b, pemetrexed disodium, peptide YY3-36, pleconaril, prasterone, pregabalin; Ranolazine, rebimastat, recombinant malaria vaccine, rosuvastatin calcium; SQN-400; Taxus, tegaserod maleate, tenofovir disoproxil fumarate, teriparatide, troxacitabine; Valganciclovir hydrochloride, Val-Tyr sardine peptidase, VNP-40101M, vorinostat.
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PMID:Gateways to clinical trials. 1684 50

Phyllodes tumors are fibroepithelial neoplasms typified by stromal proliferation. We have previously shown the role of pathologic parameters and the prognostic significance of p53 and CD117 protein expression in these tumors. In this study, we evaluated the expression of heparan sulfate, which has been implicated in many biological processes such as cell adhesion, embryogenesis, and tumorigenesis (including malignant transformation of mammary cells) in 232 breast phyllodes tumors. We used a monoclonal antibody, 10E4, to examine the localization of heparan sulfate in phyllodes tumors by immunohistochemistry. The immunoreactivity of both epithelial and stromal components was examined and analyzed with pathological parameters and other immunohistochemical markers, including p53, MIB1, bcl2, and CD117. Stromal 10E4 expression was significantly associated with tumor grade, stromal p53, and MIB1 expression in proliferating cells, suggesting that heparan sulfate may participate in malignant tumor growth.
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PMID:Immunohistochemical expression of heparan sulfate correlates with stromal cell proliferation in breast phyllodes tumors. 1686 76

Heparanase is an endoglycosidase which cleaves heparan sulfate (HS) and hence participates in degradation and remodeling of the extracellular matrix (ECM). Heparanase is preferentially expressed in human tumors and its over-expression in tumor cells confers an invasive phenotype in experimental animals. The enzyme also releases angiogenic factors from the ECM and thereby induces an angiogenic response in vivo. Heparanase upregulation correlates with increased tumor vascularity and poor post-operative survival of cancer patients. Heparanase is synthesized as a 65 kDa inactive precursor that undergoes proteolytic cleavage, yielding 8 and 50 kDa protein subunits that heterodimerize to form an active enzyme. Human heparanase is localized primarily within late endosomes and lysosomes and occasionally on the cell surface and within the cell nucleus. Transcriptional activity of the heparanase promoter is stimulated by demethylation, early growth response 1 (EGR1) transcription factor, estrogen, inflammatory cytokines and inactivation of p53. N-acetylated glycol-split species of heparin as well as siRNA heparanase gene silencing inhibit tumor metastasis and angiogenesis in experimental models. These observations and the unexpected identification of a single functional heparanase, suggest that the enzyme is a promising target for anti-cancer and anti-inflammatory drug development. Heparanase exhibits also non-enzymatic activities, independent of its involvement in ECM degradation and changes in the extracellular microenvironment. For example, cell surface expression of heparanase elicits a firm cell adhesion, reflecting an involvement in cell-ECM interaction. Heparanase enhances Akt signaling and stimulates PI3K- and p38-dependent endothelial cell migration and invasion. It also promotes VEGF expression via the Src pathway. The enzyme may thus activate endothelial cells and elicits angiogenic and survival responses. Studies with heparanase over-expressing transgenic mice revealed that the enzyme functions in normal processes involving cell mobilization, HS turnover, tissue vascularization and remodeling. In this review, we summarize the current status of heparanase research, emphasizing molecular and cellular aspects of the enzyme, including its mode of processing and activation, control of heparanase gene expression, enzymatic and non-enzymatic functions, and causal involvement in cancer metastasis and angiogenesis. We also discuss clinical aspects and strategies for the development of heparanase inhibitors.
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PMID:Regulation, function and clinical significance of heparanase in cancer metastasis and angiogenesis. 1690 44

Gateways to Clinical Trials are a guide to the most recent clinical trials in current literature and congresses. The data in the following tables have been retrieved from the Clinical Trials Knowledge Area of Prous Science Integrity, the drug discovery and development portal, http://integrity.prous.com This issue focuses on the following selection of drugs: A-007, A6, adalimumab, adenosine triphosphate, alefacept, alemtuzumab, AllerVax Ragweed, amphora, anakinra, angiotensin-(1-7), anidulafungin, apomine, aripiprazole, atomoxetine hydrochloride, avanafil; BAL-8557, becatecarin, bevacizumab, biphasic insulin aspart, BMS-188797, bortezomib, bosentan, botulinum toxin type B, brivudine; Calcipotriol/betamethasone dipropionate, caspofungin acetate, catumaxomab, certolizumab pegol, cetuximab, CG-0070, ciclesonide, cinacalcet hydrochloride, clindamycin phosphate/benzoyl peroxide, cryptophycin 52, Cypher; Dabigatran etexilate, darapladib, darbepoetin alfa, decitabine, deferasirox, desloratadine, dexanabinol, dextromethorphan/quinidine sulfate, DMF, drotrecogin alfa (activated), duloxetine hydrochloride; E-7010, edaravone, efalizumab, emtricitabine, entecavir, eplerenone, erlotinib hydrochloride, escitalopram oxalate, estradiol valerate/dienogest, eszopiclone, exenatide, ezetimibe; Fondaparinux sodium, fulvestrant; Gefitinib, gestodene, GYKI-16084; Hyaluronic acid, hydralazine hydrochloride/isosorbide dinitrate; Imatinib mesylate, indiplon, insulin glargine; Juzen-taiho-to; Lamivudine/zidovudine/abacavir sulfate, L-arginine hydrochloride, lasofoxifene tartrate, L-BLP-25, lenalidomide, levocetirizine, levodopa/carbidopa/entacapone, lexatumumab, lidocaine/prilocaine, lubiprostone, lumiracoxib; MAb-14.18, mitoquidone; Natalizumab, neridronic acid, neuradiab; Olpadronic acid sodium salt, omalizumab; p53-DC vaccine, parathyroid hormone (human recombinant), peginterferon alfa-2a, peginterferon alfa-2b, pemetrexed disodium, perifosine, pimecrolimus, prasterone, prasugrel, PRO-2000, Pseudostat; R24, rasburicase, RHAMM R3 peptide, rilonacept, rosuvastatin calcium, rotavirus vaccine, rufinamide; Sabarubicin hydrochloride, SHL-749, sirolimus-eluting stent, SLx-2101, sodium butyrate, sorafenib, SU-6668; TachoSil, tadalafil, taxus, tegaserod maleate, telbivudine, tenofovir disoproxil fumarate, teriparatide, tetramethylpyrazine, teverelix, tiotropium bromide, tipifarnib, tirapazamine, tolvaptan, TransvaxTM hepatitis C vaccine, treprostinil sodium; Valganciclovir hydrochloride, valsartan/amlodipine, vandetanib, vardenafil hydrochloride hydrate, vatalanib succinate, veglin, voriconazole; Yttrium 90 (90Y) ibritumomab tiuxetan; Zileuton, zotarolimus, zotarolimus-eluting stent.
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PMID:Gateways to clinical trials. 1700 51

Pathogenic mechanisms responsible for inflammatory bowel disease (IBD) are poorly understood. In an IBD animal model, the oral administration of polysaccharides such as dextran sulfate sodium (DSS) induces colitis, which exhibit several clinical and histological features for IBD. However, pathogenic factors in the development of colitis remain unclear. Therefore, we investigated possible mechanisms for DSS-induced colitis, and mainly focused on biological responses from an intestinal epithelial cell line, Caco-2. Cytotoxicity and cytokine release were measured using MTS assays and ELISA, respectively. The effect of DSS on the transepithelial electrical resistance (TEER) of Caco-2 cell monolayers was also evaluated. Cell cycle progression was estimated using antibodies directed against p53 and cdc-2 proteins. The generation of reactive oxygen species (ROS) was measured using a DCFH-DA method. Pyridylamino-DSS (PA-DSS) was used as a fluorometric label in order to investigate fluorescence-microscopically the location of DSS in Caco-2 cells. DSS induced cytotoxicity on Caco-2 cells at 5%. DSS also induced strong TEER decrease at 3%. DSS induced the weak release of IL-8, IL-6, and TGF-beta1. Remarkably DSS arrested Caco-2 cell cycle and reduced the intracellular generation of ROS. Under fluorescence microscopy, PA-DSS entered cells and bound to the nucleus, indicating this binding of DSS may be involved in the cell cycle arrest of Caco-2 cells. The cell cycle arrest and reduced intracellular generation of ROS may be involved during initiation or throughout the early stages of DSS-induced colitis.
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PMID:In vitro effects of dextran sulfate sodium on a Caco-2 cell line and plausible mechanisms for dextran sulfate sodium-induced colitis. 1708 61

p53 is the most frequently mutated protein in human cancers and the accumulation of its high levels is a potential novel marker for malignancy. Recently, its homologues such as p63 and p73 have been reported in human, mice and fish. Environmentally induced alterations in p53 protein have been reported to contribute to pathogenesis of leukemia in soft-shell clam Mya arenaria inhabiting polluted water, suggesting that p53 proteins can also be used as pollution markers. In the present study, the presence of p53 protein or its homologues was investigated in tissues of bivalve molluscs Lamellidens corrianus that are predominant in the freshwater riverine environment and are well suited to act as test organisms for evaluation of habitat degradation. The molluscs were collected live from the river Ganga at three sampling sites viz., Kanpur, Allahabad and Varanasi and different tissues (foot, gill and mantle) were collected. Proteins were analyzed by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). On immunoblot analysis, a 45 kDa protein (p45) was recognized by the monoclonal anti-p53 antibody in the molluscan tissues. The p45 showed immunoreactivity in all the three tissues of molluscs collected at Kanpur, in foot and gill tissues in those collected at Allahabad, and in foot tissue only, in those collected at Varanasi. Since monoclonal anti-p53 recognizes a denaturation-resistant epitope on the p53 (53 kDa) nuclear protein and does not react with other cellular proteins, the molluscan p45 is a p53-homologue or p53-like protein. Further, the differential expression of p45 in the different organs might serve as a useful biomarker that would help in establishing pollution gradient for environmental monitoring in the large aquatic ecosystems.
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PMID:A p53-like protein from a freshwater mollusc Lamellidens corrianus. 1713 70

Gateways to Clinical Trials are a guide to the most recent clinical trials in current literature and congresses. The data the following tables have been retrieved from the Clinical Trials Knowledge Area of Prous Science Integrity, the drug discovery and development portal, http://integrity.prous.com. This issues focuses on the following selection of drugs: (-)-Epigallocatechin gallate, (-)-gossypol, 2-deoxyglucose, 3,4-DAP, 7-monohydroxyethylrutoside; Ad5CMV-p53, adalimumab, adefovir dipivoxil, ADH-1, alemtuzumab, aliskiren fumarate, alvocidib hydrochloride, aminolevulinic acid hydrochloride, aminolevulinic acid methyl ester, amrubicin hydrochloride, AN-152, anakinra, anecortave acetate, antiasthma herbal medicine intervention, AP-12009, AP-23573, apaziquone, aprinocarsen sodium, AR-C126532, AR-H065522, aripiprazole, armodafinil, arzoxifene hydrochloride, atazanavir sulfate, atilmotin, atomoxetine hydrochloride, atorvastatin, avanafil, azimilide hydrochloride; Bevacizumab, biphasic insulin aspart, BMS-214662, BN-83495, bortezomib, bosentan, botulinum toxin type B; Caspofungin acetate, cetuximab, chrysin, ciclesonide, clevudine, clofarabine, clopidogrel, CNF-1010, CNTO-328, CP-751871, CX-717, Cypher; Dapoxetine hydrochloride, darifenacin hydrobromide, dasatinib, deferasirox, dextofisopam, dextromethorphan/quinidine sulfate, diclofenac, dronedarone hydrochloride, drotrecogin alfa (activated), duloxetine hydrochloride, dutasteride; Edaravone, efaproxiral sodium, emtricitabine, entecavir, eplerenone, epratuzumab, erlotinib hydrochloride, escitalopram oxalate, etoricoxib, ezetimibe, ezetimibe/simvastatin; Finrozole, fipamezole hydrochloride, fondaparinux sodium, fulvestrant; Gabapentin enacarbil, gaboxadol, gefitinib, gestodene, ghrelin (human); Human insulin, human papillomavirus vaccine; Imatinib mesylate, immunoglobulin intravenous (human), indiplon, insulin detemir, insulin glargine, insulin glulisine, intranasal insulin, istradefylline, i.v. gamma-globulin, ivabradine hydrochloride, ixabepilone; LA-419, lacosamide, landiolol, lanthanum carbonate, lidocaine/prilocaine, liposomal cisplatin, lutropin alfa; Matuzumab, MBP(82-98), mecasermin, MGCD-0103, MMR-V, morphine hydrochloride, mycophenolic acid sodium salt; Natalizumab, NCX-4016, neridronic acid, nesiritide, nilotinib, NSC-330507; O6-benzylguanine, olanzapine/fluoxetine hydrochloride, omalizumab; Panitumumab, parathyroid hormone (human recombinant), parecoxib sodium, PEG-filgrastim, peginterferon alfa-2a, peginterferon alfa-2b, pegvisomant, pemetrexed disodium, perospirone hydrochloride, pexelizumab, phorbol 12-myristate 13-acetate, pneumococcal 7-valent conjugate vaccine, posaconazole, pramiconazole, prasugrel, pregabalin, prilocaine; rAAV-GAD65, raclopride, rasagiline mesilate, retapamulin, rosuvastatin calcium, rotigotine, rufinamide; SarCNU, SB-743921, SHL-749, sirolimus-eluting stent, sitaxsentan sodium, sorafenib; TachoSil, tadalafil, talampanel, Taxus, tegaserod maleate, telithromycin, telmisartan/hydrochlorothiazide, temsirolimus, tenatoprazole, teriflunomide, tetrathiomolybdate, ticilimumab, timcodar dimesilate, tipifarnib, tirapazamine, TPI, tramiprosate, trifluridine/TPI, trimethoprim; Ularitide, Urocortin 2; Valdecoxib, valganciclovir hydrochloride, valproate magnesium, valspodar, vardenafil hydrochloride hydrate, vitespen, vofopitant hydrochloride, volociximab, vorinostat; Yttrium 90 (90Y) ibritumomab tiuxetan; Ziprasidone hydrochloride, zotarolimus, zotarolimus-eluting stent.
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PMID:Gateways to clinical trials. 1713 34

FUS1 is a novel tumor suppressor gene identified in human chromosome 3p21.3 region. Loss of expression and deficiency of posttranslational modification of FUS1 protein have been found in a majority of human lung cancers. Restoration of wild-type FUS1 in 3p21.3-deficient human lung cancer cells exhibited a potent tumor suppression function in vitro and in vivo. In this study, we evaluated the combined effects of FUS1 and tumor suppressor p53 on antitumor activity and explored the molecular mechanisms of their mutual actions in human non-small cell lung cancer (NSCLC) cells. We found that coexpression of FUS1 and p53 by N-[1-(2,3-dioleoyloxyl)propyl]-NNN-trimethylammoniummethyl sulfate:cholesterol nanoparticle-mediated gene transfer significantly and synergistically inhibited NSCLC cell growth and induced apoptosis in vitro. We also found that a systemic treatment with a combination of FUS1 and p53 nanoparticles synergistically suppressed the development and growth of tumors in a human H322 lung cancer orthotopic mouse model. Furthermore, we showed that the observed synergistic tumor suppression by FUS1 and p53 concurred with the FUS1-mediated down-regulation of murine double minute-2 (MDM2) expression, the accumulation and stabilization of p53 protein, as well as the activation of the apoptotic protease-activating factor 1 (Apaf-1)-dependent apoptotic pathway in human NSCLC cells. Our results therefore provide new insights into the molecular mechanism of FUS1-mediated tumor suppression activity and imply that a molecular therapy combining two or more functionally synergistic tumor suppressors may constitute a novel and effective strategy for cancer treatment.
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PMID:Synergistic tumor suppression by coexpression of FUS1 and p53 is associated with down-regulation of murine double minute-2 and activation of the apoptotic protease-activating factor 1-dependent apoptotic pathway in human non-small cell lung cancer cells. 1723 82


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