Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P10415 (Bcl-2)
 33,771 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Herpesvirus saimiri (HVS) transforms human T cells to stable growth in vitro. Since HVS codes for two different antiapoptotic proteins, growth transformation by HVS might be expected to confer resistance to apoptosis. We found that the expression of both viral antiapoptotic genes was restricted to cultures with viral replication and absent in growth-transformed human T cells. A comparative examination of HVS-transformed T-cell clones and their native parental clones revealed that the expression of Bcl-2, Bcl-X(L), Bax, and members of the tumor necrosis factor receptor (TNF-R) superfamily with a death domain, namely, TNF-RI, CD95, and TRAMP, were not modulated by HVS. Expression of CD30 was induced in HVS-transformed T cells, and these cells also expressed the CD30 ligand. Uninfected and transformed T cells were sensitive to CD95 ligation but resistant to apoptosis mediated by TRAIL or soluble TNF-alpha. CD95 ligand was constitutively expressed on transformed but not uninfected parental T cells. Both cell types showed similar sensitivity to cell death induction or inhibition of T-cell activation mediated by irradiation, oxygen radicals, dexamethasone, cyclosporine, and prostaglandin E2. Altogether, this study strongly suggests that growth transformation by HVS is based not on resistance to apoptosis but, rather, on utilization of normal cellular activation pathways.
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PMID:Herpesvirus saimiri transforms human T-cell clones to stable growth without inducing resistance to apoptosis. 952 39

TRAIL, the ligand for the newly discovered DR-4 and DR-5 receptor is a member of the tumour necrosis factor (TNF) family of death signal tranduction proteins with a mechanism of cell death, similar to the Fas and Fas ligand (Fas-L) system. Here, we provide first time evidence that TRAIL and TNF-alpha are potent inducers of apoptosis in multiple myeloma (MM) cell lines and freshly isolated myeloma cells. TRAIL effectively induced extensive apoptosis in 8226 and ARP-1 MM cells in a time- and dose-dependent manner reaching 80% within 48 h of treatment with a dose of 160 ng/ml. Bcl-2 transfected 8226 and ARP-1 cells were equally sensitive to apoptosis by TRAIL. Apoptosis with TNFalpha, reached >60% within 48 h of treatment with a dose of 160 ng/ml. In addition to MM cell lines, freshly isolated, flow-sorted myeloma cells from 8 different MM patients expressing variable levels of bcl-2 were equally sensitive to both TRAIL and TNF-alpha. We have previously shown that anti-Fas-induced apoptosis is not blocked by endogenous or ectopic bcl-2 in MM cell lines. Here we extend our observation with Fas to include TNF-alpha and TRAIL to the apoptotic signals that are not be blocked by bcl-2, in MM cells.
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PMID:Apoptosis-induced by TRAIL AND TNF-alpha in human multiple myeloma cells is not blocked by BCL-2. 1062 26

Tumour necrosis factor (TNF)-related apoptosis-inducing ligand (TRAIL) is a member of the TNF family of cytokines that promotes apoptosis and NF-kappaB activation. Here we show that recombinant hu-TRAIL initiates the activation of multiple caspases, the loss of mitochondrial transmembrane potential, the cleavage of BID and the redistribution of mitochondrial cytochrome c. However, whereas Bcl-2 efficiently blocked UV radiation-induced cytochrome c release and consequent apoptosis of CEM cells, it failed to do either in the context of TRAIL treatment. Thus, TRAIL engages a death pathway that is at least partially routed via the mitochondria, but in contrast with other stimuli that engage this pathway, TRAIL-induced cytochrome c release is not regulated by Bcl-2.
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PMID:Failure of Bcl-2 to block cytochrome c redistribution during TRAIL-induced apoptosis. 1076 May 20

Bag-1 is a heat shock 70 kDa (Hsp70)-binding protein that can collaborate with Bcl-2 in suppressing apoptosis under some conditions. Here, we report that 11 of 12 human glioma cell lines express Bag-1 protein in vitro. Moreover, 15 of 19 human glioblastomas expressed Bag-1 as assessed by immunohistochemistry in primary tumor specimens. To examine the biological effects of Bag-1 in glioma cells, we expressed Bag-1 or Bcl-2 transgenes in 2 human malignant glioma cell lines, LN-18 and LN-229. Bag-1 significantly slowed glioma cell growth and reduced clonogenicity of both cell lines in vitro. Coexpressed Bcl-2 abrogated these effects of Bag-1. Intracranial LN-229 glioma xenografts implanted into nude mice revealed a substantial growth advantage afforded by Bcl-2. Bag-1 had no such effect, either in the absence or presence of Bcl-2. Upon serum starvation in vitro, Bcl-2 prevented cell death whereas Bag-1 did not. Both Bcl-2 and Bag-1 slowed proliferation of serum-starved cells when expressed alone. Importantly, coexpression of Bcl-2 and Bag-1 provided a distinct growth advantage under conditions of serum starvation that is probably the result of (i) the death-preventing activity of Bcl-2 and (ii) the property of Bag-1 to overcome a Bcl-2-mediated enhancement of exit from the cell cycle. In contrast to these Bcl-2/Bag-1 interactions observed under serum starvation conditions, Bag-1 did not further enhance the strong protection from staurosporine-, CD95 (Fas/Apo1) ligand-, Apo2 ligand (TRAIL)- or chemotherapeutic drug-induced apoptosis afforded by Bcl-2. Taken together, these results indicate a role for Bag-1/Bcl-2 interactions in providing a survival advantage to cancer cells in a deprived microenvironment that may be characteristic of ischemic/hypoxic tumors such as human glioblastoma multiforme, and suggest that Bcl-2/Bag-1 interactions also modulate cell proliferation.
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PMID:Bag-1 and Bcl-2 gene transfer in malignant glioma: modulation of cell cycle regulation and apoptosis. 1076 42

Previously we have reported a differential expression of CD95/CD95L and Bcl-2 family of genes in multidrug resistant tumor cells. TRAIL, a member of the TNF receptor family, induces apoptosis in many tumor cells by binding to DR4 (TRAIL receptor 1) and DR5 (TRAIL receptor 2). In contrast, TRAIL-induced apoptosis is prevented by a decoy receptor (DcR1, TRID or TRAIL receptor 3). In the present study, we compared the expression of TRAIL, DR4, DR5, and TRID between a drug sensitive HL60, a myeloid leukemia cell line, and its multidrug resistant (MDR) sublines that either overexpressed MDR 1 gene (HL60/Tax) or MRP gene (HL60/AR), using RT-PCR. TRAIL mRNA was expressed in HL60 cells but was present in low levels in HL60/AR cells and was completely lacking in HL60/Tax cells. Both DR4 and DR5 were undetectable in HL60/Tax but were present at comparable levels in HL60/AR and drug sensitive HL60 cells. TRID were absent in HL60 and HL60/Tax cells, but was present in low but comparable levels in peripheral blood mononuclear cells and HL60/AR cells. These data suggest that the multidrug resistance in MDR HL60 cell lines, regardless of overexpression of MDR 1 or MRP, may be due to different mechanisms. In HL60/AR cells it appears that MDR may be due to decreased expression of TRAIL and constitutive expression of TRID, whereas in HL60/Tax cells, MDR could be due to the absence of TRAIL and/or DR4 and DR5.
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PMID:Expression of TRAIL (Apo2L), DR4 (TRAIL receptor 1), DR5 (TRAIL receptor 2) and TRID (TRAIL receptor 3) genes in multidrug resistant human acute myeloid leukemia cell lines that overexpress MDR 1 (HL60/Tax) or MRP (HL60/AR). 1081 86

CD95L-induced apoptosis involves caspase activation and is facilitated when RNA and protein synthesis are inhibited. Here, we report that hyperthermia sensitizes malignant glioma cells to CD95L- and APO2L-induced apoptosis in the absence, but not in the presence, of inhibitors of RNA and protein synthesis. Hyperthermia does not alter CD95 expression at the cell surface and does not modulate the morphology of CD95-mediated cell death on electron microscopy. Bcl-2 gene transfer inhibits apoptosis and abrogates the sensitization mediated by hyperthermia. Hyperthermia does not overcome resistance to apoptosis conferred by the viral caspase inhibitor, crm-A, indicating the absolute requirement for the activation of crm-A-sensitive caspases, probably caspase 8, for apoptosis. CD95L-evoked DEVD-amc-cleaving caspase activity is enhanced by hyperthermia, suggesting that hyperthermia operates upstream of caspase processing to promote apoptosis. There is no uniformly enhanced processing of three caspase 3 substrates, poly-ADP ribose polymerase (PARP), protein kinase C (PKC) delta and DNA fragmentation factor (DFF) 45. Yet, hyperthermia promotes CD95L-evoked DNA fragmentation. Interestingly, hyperthermia enhances the CD95L-evoked release of cytochrome c in the absence, but not in the presence, of CHX. In contrast, the reduction of the mitochondrial membrane potential is enhanced by hyperthermia both in the absence and presence of CHX, and enhanced cytochrome c release is not associated with significantly enhanced caspase 9 processing. The potentiation of cytochrome c release at hyperthermic conditions in the absence of CHX is abrogated by Bcl-2. Thus, either hyperthermia or inhibition of protein synthesis by CHX potentiate cytotoxic cytokine-induced apoptosis. These pathways show no synergy, but rather redundance, indicating that CHX may function to promote apoptosis in response to cytotoxic cytokines by inhibiting the synthesis of specific proteins whose synthesis, function or degradation is temperature-sensitive.
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PMID:Sensitization to CD95 ligand-induced apoptosis in human glioma cells by hyperthermia involves enhanced cytochrome c release. 1082 85

To determine whether the apoptotic machinery of thyroid cancer cells is functional and could be activated for tumoricidal purposes, we examined the apoptosis induced by the cytokines TNF-alpha, Fas and TRAIL in thyroid cancer cell lines, NPA and SW579. Interestingly, out of these cytokines, only TRAIL was able to trigger significant apoptosis. The tumoricidal effect of TRAIL was further enhanced by CHX, suggesting the presence of CHX-sensitive inhibitor(s) of apoptosis in these thyroid cancer cell lines. The anti-apoptotic proteins like FLAME-1, Bcl-2 and Bcl-xL are believed to be such CHX-sensitive inhibitors in various types of cancer cells. We, however, provide the evidence using NPA and SW579 cell lines that these proteins were not affected by the CHX treatment in thyroid cancer cells. The apoptosis of thyroid cancer cells was mediated by the classical activation of caspases that in turn activated the DNA Fragmentation Factor (DFF-45). To elucidate the role of individual caspases in TRAIL-mediated apoptosis, the inhibitory effects of several general and specific tetrapeptide caspase inhibitors were studied. The inhibitors of caspase-1, -6, -8, and -9 as well as general upstream inhibitors of apoptosis could dramatically inhibit TRAIL-induced apoptosis in thyroid cancer cells. Caspase-2 and -3 inhibitors, on the other hand, had no significant effect. When the cells were treated with either agonistic Fas antibody (CH11) or TNF-alpha, no apoptotic changes were observed. The apoptosis induced by agonistic Fas Ab could be seen only after a prolonged exposure (24 h) to CHX, whereas TNF-alpha had no effect even in the presence of CHX. The efficacy of TRAIL was also tested on other types of thyroid cancer cells like ARO, FRO (anaplastic carcinoma) and TPC-1 (papillary carcinoma) and compared to that triggered by other death inducing cytokines FasL and TNF-alpha. Again TRAIL was more potent in triggering apoptosis than Fas and TNF-alpha. Since TRAIL is effective in selectively killing thyroid tumor cells without affecting normal thyrocytes and also does not cause organ toxicity and inflammation in vivo, its potential for the treatment of thyroid cancer seems very promising.
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PMID:TRAIL-induced apoptosis of thyroid cancer cells: potential for therapeutic intervention. 1091 93

Programmed cell death or apoptosis is central both in physiology during development and in disease. The mechanism of apoptosis is under the control of antiapoptotic survival genes of the Bcl-2 family and proapoptotic death receptors of the TNF superfamily (Fas, TNFR, TRAILR). Following death signal, the death receptor binds to its own receptor and initiates, through binding of adaptors, a cascade of events mediated by the autoproteolytic activation of specific enzymes called caspases. This enzyme activation is ultimately responsible for the dissembly of basic nuclear and cytoplasmic cell structures leading to cell death. In certain cell systems, antiapoptotic genes of the Bcl-2 family prevent the proapoptotic pathway. One of their roles is to maintain mitochondrial function integrity. In autoimmune destructive thyroiditis high levels of apoptosis have been demonstrated particularly within the destructed follicles near the infiltrated areas in comparison to Graves' disease and non autoimmune glands. In Hashimoto's thyroiditis Fas expression has been found increased on thyrocytes and in vitro can be modulated by proinflammatory cytokines. FasL expression on thyrocytes remains controversial. Thyroid cells from Graves' disease and multinodular glands are known to kill Fas expressing target cells although Hashimoto's thyrocytes are not efficient effector cells. Intrathyroidal lymphocytes from Hashimoto's thyroids maintain functional killer activity. These findings would suggest that intrathyroidal lymphocytes could be responsible for thyrocyte death in vivo. Whether this mechanism is Fas/FasL, TRAIL/TRAILR dependent can not be confirmed as specific blocking reagents were not able to inhibit cell induced death. In Hashimoto's thyroiditis an impairment of Bcl-2 and Bcl-X anitapoptotic genes on thyrocytes has also been detected. Bcl-X expression can be down-regulated in vitro by incubation with cytokines. These findings suggest that thyrocyte death may not exclusively be the result of specific interactions between death receptor and their ligands but it may involve simultaneous impairment of protective genes of the Bcl-2 family. Whether the impairment of the Bcl-2 family is a direct consequence of environmental stimuli or is the result of an intrinsic thyrocyte (mitochondrial?) alteration is as yet not known.
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PMID:Death of the autoimmune thyrocyte: is it pushed or does it jump? 1144 11

Most chemotherapeutic drugs can induce tumor cell death by apoptosis. Analysis of the molecular mechanisms that regulate apoptosis has indicated that anticancer agents simultaneously activate several pathways that either positively or negatively regulate the death process. The main pathway from specific damage induced by the drug to apoptosis involves activation of caspases in the cytosol by pro-apoptotic molecules such as cytochrome c released from the mitochondrial intermembrane space. At least in some cell types, anticancer drugs also upregulate the expression of death receptors and sensitize tumor cells to their cognate ligands. The Fas-mediated pathway could contribute to the early steps of drug-induced apoptosis while sensitization to the cytokine TRAIL could be used to amplify the response to cytotoxic drugs. The Bcl-2 family of proteins, that includes anti- and pro-apoptotic molecules, regulates cell sensitivity mainly at the mitochondrial level. Anticancer drugs modulate their expression (eg through p53-dependent gene transcription), their activity (eg by phosphorylating Bcl-2) and their subcellular localization (eg by inducing the translocation of specific BH3-only pro-apoptotic proteins). Very early after interacting with tumor cells, anticancer drugs also activate lipid-dependent signaling pathways that either increase or decrease cell ability to die by apoptosis. In addition, cytotoxic agents can activate protective pathways that involve activation of NFkappaB transcription factor, accumulation of heat shock proteins such as Hsp27 and activation of proteins involved in cell cycle regulation. This review discusses how modulation of the balance between noxious and protective signals that regulate drug-induced apoptosis could be used to improve the efficacy of current therapeutic regimens in hematological malignancies.
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PMID:Positive and negative regulation of apoptotic pathways by cytotoxic agents in hematological malignancies. 1102 59

Ionizing radiation is a major tool for cancer treatment. The response of eukaryotic cells to ionizing radiation includes apoptosis, a process which requires activation of multiple genes. We sought to determine whether radiation-induced gene expression plays a role in radiation-induced apoptosis. We found Apo2 ligand (Apo2L, also called TRAIL) mRNA induction following gamma-irradiation of Jurkat, MOLT-4, CEM, and PBMC, all human T lineage-derived cells. Increased Apo2L protein levels were found in MOLT-4 and Jurkat cells. Radiation also activated the Apo2L death receptor (DR)5 (also called Apo2, TRAIL-R2, or KILLER) in MOLT-4 cells, which harbor a wild-type p53. We isolated 1152 bp of 5' flanking region of the Apo2L gene and a shorter fragment of 716 bp, both of which showed promoter activity driving the expression of a luciferase reporter gene; however, the response to radiation in MOLT-4 cells was lost when only 430 bp of 5' proximal flanking sequence was maintained. Exogenous Apo2L induced phosphatidylserine exposure on cell membranes, caspase 8 and caspase 3 activation, key markers of apoptosis, confirming that the Apo2L/DR5 pathway is functional in these cells. Bid, a Bcl-2 family protein also known to contribute to receptor-mediated apoptosis, was also activated. To determine whether Apo2L and DR5 were critical for radiation signaling to apoptosis, we stably expressed a dominant negative DR5delta-receptor in Jurkat cells. Cell survival was significantly augmented, indicating that increased Apo2L expression contributed to radiation-induced apoptosis. Clonogenic assays demonstrated that purified, recombinant soluble Apo2L enhanced the lethality of low, therapeutic doses (1-2 Gy) of gamma-irradiation. These data suggest that production of Apo2L may cooperate synergistically with the cytotoxic effect of radiation, and that combinations of Apo2L and radiation may become a powerful tool in clinical therapy.
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PMID:Apo2 ligand/TNF-related apoptosis-inducing ligand and death receptor 5 mediate the apoptotic signaling induced by ionizing radiation in leukemic cells. 1105 70


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