UMLS:C0017638 - FACTA Search

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Query: UMLS:C0017638 (glioma)
30,880 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The aliphatic dicarboxylic acid surprisingly afforded potent cytotoxicity and in vivo antineoplastic activity. The agents were active against the growth of a variety of leukemias, lymphomas, and suspended HeLa uterine carcinoma. Suppression of growth of cell lines derived from human solid cancers, e.g. SW-480 colon adenocarcinoma, lung MB- 9812, glioma HS-683, and rat osteosarcoma UMR-106 was observed. A mode of action study in L1210 lymphoid leukemia demonstrated that DNA and RNA syntheses were inhibited at multiple sites including ribonucleoside reductase, purine de novo synthesis at PRPP-amidotransferase and IMP dehydrogenase and nucleic acid kinases. These studies could not exclude the possibility that the agents also interacted with the DNA molecule itself interfering with the utilization of the template.
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PMID:Cytotoxicity and mode of action of aliphatic dicarboxylic acids in L1210 lymphocytic leukemia cells. 1022 44

Apoptosis is a physiological process wherein the cell initiates a sequence of events culminating in the fragmentation of its DNA, nuclear collapse, and finally disintegration of the cell into small, membrane-bound apoptotic bodies. Expression of Fas (APO-1, CD95) Receptor (FasR) and programmed or active cell (PCD) death was studied in childhood astrocytomas (ASTRs) with varying stages of malignancy, including pilocytic ASTR, low grade ASTR, anaplastic ASTR, and glioblastoma multiforme (GBM). The great majority of childhood glial tumors, particularly ASTRs express FasR whereas normal cells in the central nervous system (CNS) do not. FasR represents a transmembrane glycoprotein which belongs to the nerve growth factor/tumor necrosis factor (NGF/TNF) receptor superfamily. Apoptosis within ASTRs is triggered by the binding of FasR to its natural ligand (FasL) or by cross-linking with antibodies developed against FasR. Presence of FasL was also detected in childhood glial tumors. The expression of both FasR and FasL was also observed within the same ASTRs. Therefore, spontaneous, IP regulatory, intratumoral apoptotic cell death (autocrine suicide) is possible in childhood glial tumors. During a systematic, immunocytochemical screening of 42 childhood ASTRs tissues divided according to WHO classification: 6 WHO grade I or pilocytic ASTRs; 14 WHO grade II or low grade ASTRs; 16 WHO grade III or anaplastic ASTRs and 6 WHO grade IV or glioblastoma multiforme (GBM), we detected strong expression (intensity of staining: "A"--the highest possible; number of stained cells: +2 to +4, between 20% to 90%) of FasR, employing 4 microns thick, formalin fixed, paraffin-wax embedded tissue slides. FasR was present on 70% to 90% of tumor cells in pilocytic ASTRs, in 50% to 60% of the tumor cells in low grade ASTRs, in between 30% and 40% of the tumor cells in anaplastic ASTRs, and in between 20% to 35% of GBM cells. The panel of normal tissues employed as positive and negative tissue controls demonstrated presence of FasR in the prenatal thymus, mature tonsils and colonic epithelium. The use of a sensitive, indirect, six step immunoperoxidase or alkaline phosphatase conjugated streptavidin-biotin antigen detection technique provided excellent immunocytochemical results. A broad spectrum of neoplastic cells have been identified to express FasR: 1) carcinomas of epithelial origin, such as breast (ductal invasive, lobular invasive, mucinous), renal cell, gastric, colorectal, endometrial, prostate, pancreas, hepatocellular and large cell and squamous cell lung carcinomas: 2) non-epithelial neoplasms such as B cell mediastinal B cell and nodal non-Hodgkin's lymphomas large granular lymphocytic leukemia of T or NK cell origin malignant fibrous histiocytoma, malignant mesothelioma, leiomyosarcoma, epitheloid sarcoma and alveolar soft part sarcoma, as well as melanomas. Flow cytometry studies have also detected FasR expression on cells of adult T cell, and hairy cell leukemias, as well as in chronic B cell lymphocytic leukemia (BCLL). The coexpression of both FasR and FasL on several malignant cell types may represent an effective mechanism of tumor escape from the cellular immunological response of the host. It has been well established that brain tumors and melanomas produce their autocrine FasL, and even become capable of switching the signal transduction associated with FasL-FasR coupling from the PCD pathway to a tumor growth, proliferative pathway. It seems that the therapeutical use of FasR-FasL (main apoptotic pathway) may represent a new and exciting type of immunotherapy in the treatment of primary childhood glial tumors.
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PMID:Fas (Apo-1, CD95) receptor expression in childhood astrocytomas. Is it a marker of the major apoptotic pathway or a signaling receptor for immune escape of neoplastic cells? 1058 78

Central nervous system (CNS) tumors are the most common solid neoplasms in children. Medulloblastomas (MEDs) resemble embryonic neuroectodermal stem cells and their immature, uncommitted neuronal and glial progeny. Apoptosis is a basic physiological process wherein the cell initiates a sequence of events culminating in the fragmentation of its DNA, nuclear collapse, and finally, disintegration of the cell into small, membrane-bound apoptotic bodies. Expression of Fas (APO-1, CD95) receptor (FasR) and programmed or active cell death (PCD) was studied in childhood MEDs with varying stages of malignancy, and cell differentiation features. The majority of neoplastically transformed, neuroectodermal in origin cells, particularly in MEDs, express FasR, whereas normal cells in the CNS do not. FasR is a transmembrane glycoprotein, which belongs to the nerve growth factor/tumor necrosis factor (NGF/TNF) receptor superfamily. Apoptosis within childhood PNETs/MEDs is triggered by the binding of FasR to its natural ligand (FasL) or by cross-linking with anti-section i FasR antibodies. The resence of FasL has also been detected in childhood glial tumors. Therefore, a spontaneous, cellular immunophenotype (IP) regulatory, intratumoral apoptotic cell death (autocrine suicide) is possible in childhood brain tumors during neoplastic growth and progression. During our systematic immunocytochemical screening, we employed formalin fixed, paraffin-wax embedded tissue sections, as well as frozen sections of 34 primary human childhood PNETs/MEDs. The use of a sensitive, indirect, six step immunoperoxidase or alkaline phosphatase conjugated streptavidin-biotin antigen detection technique, modified by us, provided excellent immunocyto-chemical results. A systematic observation of the presence of apoptosis related markers (especially FasR) and cells in PCD was carried out. A strong expression (intensity of staining: "A"-the highest possible; number of stained neoplastic cells: +3 to +4, between 50% to 90%) of FasR, was detected employing 4 microns thick, formalin fixed, paraffin-wax embedded tissue slides. The panel of normal tissues employed as positive and negative tissue controls demonstrated presence of FasR in the prenatal thymus, mature tonsils and colon epithelium. Certainly, the coexpression of FasR, FasL, and other PCD-related proteins have also been reported in other human malignancies: breast cancer, colorectal carcinomas, large granular lymphocytic leukemia of T or NK cell origin, melanomas, lung, prostate, pancreas, and hepatocellular carcinomas. The coexpression of both FasR and FasL on several neoplastic cell types may represent an effective mechanism for tumor escape of the cellular immunological response of the host. It has been well established that brain tumors and melanomas produce their autocrine FasL, and even become capable of switching their signal transduction from the PCD pathway to a tumor growth, proliferative pathway. It seems that the therapeutical use of FasR-FasL (main apoptotic pathway) represents a new and exciting immunotherapeutical possibility in the treatment of primary childhood neuroectodermal tumors.
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PMID:Fas (APO-1, CD95) receptor expression and new options for immunotherapy in childhood medulloblastomas. 1065 26

2-Etheny1-2,3-dihydrophthalazine-1,4-diones were successfully synthesized and proved to be effective cytotoxic agents against the growth of suspended murine and human leukemias and lymphomas. Selected compounds were also active in human HeLa uterine carcinoma, suspended effusion breast MCF-7 and glioma HS683 screens. These agents suppressed P388 lymphocytic leukemia DNA synthesis after 60 min at 100 microM. Their target appeared to be the de novo synthesis pathway with significant inhibition of the activities of both regulatory enzymes of the pathway, i.e. PRPP-amide transferase and IMP dehydrogenase resulting in a reduction in the d[NTP] pool levels for DNA incorporation. The compounds did not affect de novo pyrimidine synthesis and its regulatory enzymes. Very minor reduction by the agents was noted for the nucleoside kinases and the DNA and RNA polymerase activities within 60 min. DNA was not a target of the agents in that there was no alkylation of the nucleotide bases, intercalation between base pairs or cross-linking of the DNA strands; however, the agents did cause P388 DNA strand scission after 24 h at 100 microM.
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PMID:Cytotoxicity of 2-ethenyl-2,3-dihydrophthalazine-1,4-diones in murine and human tumor cultured cells. 1123 48

Researchers at the University of California at San Diego (UCSD) are developing alanosine as a potential treatment for cancer [227466], [408222]. The compound was originally under development in collaboration with Triangle, which initiated its development in 1996 [227466], but later discontinued development of the compound [406677]. As of May 2001, UCSD's ongoing clinical trials of alanosine included phase II trials for non-small cell lung cancer (NSCLC) and phase I trials for acute lymphoid leukemia (ALL), while a phase II trial for glioma at UCSD had been suspended [408222]. Alanosine is an amino acid analog originally derived from Streptomyces alanosinicus. It interferes with the de novo synthesis of adenosine in both malignant and normal cells. In cancer cells that lack methyladenosine phosphorylase (MTAP, required in the salvage pathway), alanosine should deprive such cells (but not normal cells) of de novo synthesized adenosine [277968]. In early 1997, patients were being recruited for a phase II pilot efficacy trial of alanosine as a treatment for glioma and NSCLC, since a significant number of these tumor types lack MTAP and, it was hoped, would therefore be sensitive to alanosine [239280], [248260]. Phase I and II trials were completed in the 1980s by the NCI before they were discontinued because alanosine caused toxicity typically associated with chemotherapy, and did not produce significant response rates in common tumors such as breast or colon cancers. Researchers at UCSD found that some types of cancer lack MTAP, which was responsible for alanosine's previous clinical failure [227466]; phase II trials were being carried out at the university in 1997 [269338]. Triangle obtained an option for a worldwide license from the Regents of the University of California that expired in September 1998 (but had an option to extend the period for a further one year) [277968].
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PMID:Alanosine (UCSD). 1176 67

Drug resistance remains a major impediment in the development of durable cancer therapies. Studies in acute myelogenous leukemia (AML) patients revealed a new form of multidrug resistance. Here, increased glioma-associated protein GLI1 leads to elevation of the UDP-glucuronosyl transferase (UGT) enzymes. UGTs add glucuronic acid to xenobiotics and metabolites. Traditionally, the loss of these enzymes is thought to contribute to cancer as a result of impaired clearance of environmental carcinogens. However, we demonstrate that overexpression of UGTs can contribute to oncogenesis by promoting drug resistance. Indeed, UGT levels in AML patients treated with ribavirin and/or cytarabine were elevated at relapse relative to diagnosis. This was reversed by GLI1 inhibition, suggesting a clinically relevant strategy to overcome drug resistance. Further, overexpression of UGTs can also lead to drug resistance in other cancers, such as certain Hsp90 inhibitors and vorinostat in colorectal and chronic lymphoblastic leukemia, respectively. Not all drugs are targets of glucuronidation, suggesting that UGT status could be relevant to treatment choice. Here, we describe several facets of UGT biology and how these could be exploited clinically. These studies demonstrate how drugs in cancer cells can be metabolized differentially than their normal counterparts. In summary, we describe a new form of drug resistance relevant to a variety of cancer contexts.
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PMID:Molecular Pathways: GLI1-Induced Drug Glucuronidation in Resistant Cancer Cells. 2581 Mar 73

As a result of the recent advances in molecular immunology, virology, genetics, and cell processing, chimeric antigen receptor (CAR)-directed cancer therapy has finally arrived for clinical application. CAR-directed adoptive immunotherapy represents a novel form of gene therapy, cellular therapy, and immunotherapy, a combination of three in one. Early phase clinical trial was reported in patients with refractory chronic lymphoid leukemia with 17p deletion. Accompanying the cytokine storm and tumor lysis syndrome was the shocking disappearance of the leukemia cells refractory to chemotherapy and monoclonal antibodies. CAR therapy was reproduced in both children and adults with refractory acute lymphoid leukemia. The CAR technology is being explored for solid tumor therapy, such as glioma. Close to 30 clinical trials are underway in the related fields (www.clinicaltrials.gov). Further improvement in gene targeting, cell expansion, delivery constructs (such as using Sleeping Beauty or Piggyback transposons) will undoubtedly enhance clinical utility. It is foreseeable that CAR-engineered T cell therapy will bring targeted cancer therapy into a new era.
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PMID:Chimeric antigen receptor (CAR)-directed adoptive immunotherapy: a new era in targeted cancer therapy. 2352 58

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