UNIPROT:P10415 - FACTA Search

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Query: UNIPROT:P10415 (Bcl-2)
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The last decade has seen major advances in the acquisition of knowledge concerning both the cellular and molecular genetics of multiple myeloma. Although discrete and specific changes associated with the plasma cell disorders have yet to be identified, a pattern is emerging that one can associate with the plasma cell disorders. This pattern includes the frequent involvement of chromosomes 1 and 14, and in particular presence of the 14q+ abnormality. But in addition there are typically many other numeric and/or structural changes that can, in fact, involve almost any chromosome, but particularly chromosomes 3, 5, 6, and 7, as well as 11, 14, 17, and 18. The presence of one or more unidentified marker chromosomes is also a typical feature. The ongoing challenges include identification of a crucial initial genetic change (if such exists) as well as the factors contributing to the ongoing karyotypic evaluation that results in complex karyotypes in patients with advanced disease. There is no doubt that the complex karyotypic picture contributes to the major heterogeneity of plasma cells that occurs in malignant plasma cell disorders. Karyotypic complexity underlies heterogeneity in cell morphology, surface antigen expression, response to cytokines, and a variety of other functional characteristics. The aberrant expression of antigens normally found on other hematopoietic progenitors has led to speculation about the true nature of the stem cell in myeloma. The overriding challenge, however, is to fully understand the plasma cell disorders at the molecular level. Although changes have already been noted in the functions of C-myc, the ras family of oncogenes, Bcl-2 expression, and several so called anti-oncogenes such as p53, it is likely that we have only begun to scratch the surface in the area of molecular changes. The potential for involvement at multiple molecular sites and the possibility of complex interactions between gene segments is truly overwhelming. However, it is hoped that at the molecular level a pattern will ultimately emerge. It is most interesting, as previously discussed, that there is an interplay among C-myc, N-ras, Bcl-2, and the Epstein-Barr virus in the predilection for a plasma cell phenotype. Undoubtedly there is much more to learn, and it is truly exciting to finally have some tools and probes at hand to more effectively study the genome in multiple myeloma and related disorders.
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PMID:Cellular and molecular genetic features of myeloma and related disorders. 158 85

Normal and activated Ras proteins are known to act as signal transducers, mediating mitogenic responses. Interactions of p21ras and protein kinase C (PKC) are required in a number of mitogenic or activation signaling pathways. The constitutive expression of activated v-Haras in Jurkat cells, a human T lymphoblastoid cell line, renders the cells susceptible to apoptosis during transient down-regulation or inhibition of PKC. Similarly, the expression of v-Ki-ras in murine fibroblasts induces apoptosis during suppression of PKC activity. This Ras-specific cell death is dependent upon suppression of cellular PKC activity, and can be blocked by the survival-promoting bcl-2 gene product. In vivo phosphorylation studies indicate that Bcl-2 is a phosphoprotein, and the phosphorylation state of Bcl-2 is modulated in the setting of activated p21Ha-ras in response to inhibition of PKC. These findings suggest an interactive regulation of growth or apoptosis in cells which involves at least three molecules: p21ras, PKC and Bcl-2.
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PMID:Direction of p21ras-generated signals towards cell growth or apoptosis is determined by protein kinase C and Bcl-2. 747 73

Using a highly tumorigenic human breast cancer model (Ha-ras-transfected MCF7 cell line) we analyzed the efficacy of the differentiation-inducing agent sodium phenylacetate (NaPA), both in vitro and in vivo. NaPA-treated MCF7ras cells showed dose-dependent growth inhibition from 2.5 to 15 mM without apparent toxicity. Western blot analysis showed a Bcl-2 down-regulation after 48 h treatment with 5 mM NaPA, together with apparition of apoptotic nuclei by DAPI staining. Mice bearing MCF7ras xenografts (n = 40) were treated for 2 weeks through s.c.-delivering osmotic pumps, followed by 6 weeks of daily i.p. NaPA administration. After 3 weeks, the treated tumors showed growth arrest without regression for the whole observation time, e.g., 12 weeks. Immunohistochemical analysis showed Bcl-2 down-regulation and differentiation patterns: decrease of Ki-67 and increase of steroid receptors (estrogen and progesterone receptors) compared to controls. Cells cultured from treated tumors (II.b) displayed pseudotrabecular disposition as MCF7ras cells treated in vitro. They also showed a higher NaPA sensitivity, together with 70% Bcl-2 down-regulation as compared to the derived cells of untreated tumors (II.a). When reinjected into nude mice, II.b cells induced only one poorly vascularized, noninvasive tumor (8%) with lower proliferation index, 100% progesterone receptor positive cells, and 35% terminal deoxynucleotidyltransferase-mediated dUTP-X nick end labeling (+) nuclei, as compared to 100% induction of highly vascularized and invasive tumors with 3% terminal deoxynucleotidyltransferase-mediated dUTP-X nick end labeling (+) nuclei induced by II.a cells.
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PMID:Sodium phenylacetate induces growth inhibition and Bcl-2 down-regulation and apoptosis in MCF7ras cells in vitro and in nude mice. 758 64

The adenovirus E1A oncogene products stimulate DNA synthesis and cell proliferation but fail to transform primary baby rat kidney (BRK) cells because of the induction of p53-mediated programmed cell death (apoptosis). Overexpression of dominant mutant p53 (to abrogate wild-type p53 function) or introduction of apoptosis inhibitors, such as adenovirus E1B 19K or Bcl-2 oncoproteins, prevents E1A-induced apoptosis and permits transformation of BRK cells. The ability of activated Harvey-ras (H-ras) to cooperate with E1A to transform BRK cells suggests that H-ras is capable of overcoming the E1A-induced, p53-dependent apoptosis. We demonstrate here that activated H-ras was capable of suppressing apoptosis induced by E1A and wild-type p53. However, unlike Bcl-2 and the E1B 19K proteins, which completely block apoptosis but not p53-dependent growth arrest, H-ras expression permitted DNA synthesis and cell proliferation in the presence of high levels of wild-type p53. The mechanism by which H-ras regulates apoptosis and cell cycle progression is thereby strikingly different from that of the E1B 19K and Bcl-2 proteins. BRK cells transformed with H-ras and the temperature sensitive murine mutant p53(val 135), which lack E1A, underwent growth arrest at the permissive temperature for wild-type p53. p53-dependent growth arrest, however, could be relieved by E1A expression. Thus, H-ras alone was insufficient and cooperation of H-ras and E1A was required to override growth suppression by p53. Our data further suggest that two complementary growth signals from E1A plus H-ras can rescue cell death and thus permit transformation.
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PMID:Activated H-ras rescues E1A-induced apoptosis and cooperates with E1A to overcome p53-dependent growth arrest. 762 44

Mad is a bHLH/Zip protein that, as a heterodimer with Max, can repress Myc-induced transcriptional transactivation. Expression of Mad is induced upon terminal differentiation of several cell types, where it has been postulated to down-regulate Myc-induced genes that drive cell proliferation. Here we show that Mad also blocks transformation of primary rat embryo fibroblasts by c-Myc and the activated c-Ha-Ras oncoproteins. Mad mutants lacking either the basic region, the leucine zipper, or an intact NH2-terminal protein interaction domain fail to inhibit Myc-Ras cotransformation. These results indicate that the repression of cotransformation requires DNA-binding and is mediated by multiple protein-protein interactions involving both Max and mSin3, a putative mammalian corepressor protein. With increasing amounts of the cotransfected myc gene, the numbers of transformed foci are reduced and the ability of Mad to inhibit focus formation is attenuated. Moreover, cell lines derived from such foci constitutively express both Myc and Mad proteins. Whereas Bcl-2 can significantly increase the numbers of transformed foci by enhancing the survival of myc-ras-transfected cells, it does not counteract the repressive effects of Mad on transformation, suggesting that Mad affects the growth properties rather than the viability of cells. Taken together, our results demonstrate that Mad is capable of antagonizing the biological effects of Myc and thereby suggest that Mad could function as a tumor suppressor gene.
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PMID:Repression of Myc-Ras cotransformation by Mad is mediated by multiple protein-protein interactions. 766 17

HHV-6 infected immature T (HSB2) and Hodgkin (HDLM2) cells and biopsy tissues from lymph nodes of patients with Hodgkin's disease (HD) and Kikuchi lymphadenitis (KL) were studied immunohistologically for virus antigen expression and for the oncogene/anti-oncogene products ras, bcl-2 and p53. Cell proliferation and cell death were tentatively monitored in tissue culture by PCNA staining, by viability testing and in situ end labeling of fragmented DNA. PCNA was also used in biopsy samples. KL is characterized by high incidences of focal cell death (i.e. histiocytic necrotizing lymphadenitis), while HD is apparently more a proliferative disease. The techniques used revealed no significant differences in the cellular expression of viral DNA or antigens among cell lines, HD or KL. The HDLM2 cell line with the superior survival after HHV-6 infection showed a significantly lower expression of p53 and PCNA than HSB2 cells. Biopsy samples from patients with KL did not express p53, and ras and PCNA were observed in fewer cells than in HD. Bcl-2, however, was significantly more frequently seen than in HD. The interpretation of the data is difficult; they suggest that there are additional regulatory influences in control of cell proliferation and cell death, such as cytokines and growth factors, which are altered after viral infection. Also, virus-induced cell death probably includes other mechanisms besides apoptosis, such as cell damage caused by oxygen radicals.
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PMID:[Apoptosis and cell proliferation in HHV-6 infections. Regulatory mechanisms of p53/bcl-2/ras interactions]. 776 57

R-ras is a member of the ras family of small GTPases that associates with the apoptosis-suppressing proto-oncogene product Bcl-2. Using the yeast two-hybrid system we provide evidence for an interaction between R-ras and the Raf-1 kinase. This interaction requires only the N-terminal regulatory domain (amino acids 1-256) of Raf-1, and is observed with both the wild type and a constitutively active R-ras mutant, but not with a deletion mutant that lacks the potential effector domain or a mutant of R-ras impaired for GTP binding. Moreover, using an in vitro binding assay we show a direct GTP-dependent interaction of purified R-ras with a purified Raf-1 fragment corresponding to the proposed 81-amino-acid H-Ras-binding domain of Raf-1 (amino acids 51-131). Taken together, these data indicate that R-ras may exert its biological effect by means of modulating the activity of the Raf-1 kinase as its direct downstream effector.
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PMID:The Ras-related protein R-ras interacts directly with Raf-1 in a GTP-dependent manner. 800 32

Ras proteins are members of a superfamily of small GTPases that are involved in many aspects of cell growth control. The ras p21 protooncogene products, H-ras, K-ras, and N-ras, transmit signals from growth factor receptors to a cascade of protein kinases that begins with the Raf protooncogene product, and leads to alterations in transcription factors and cell cycle proteins in the nucleus. This cascade is controlled at several points: Ras p21 proteins are regulated by GAPs and by exchange factors, whose activities are altered by growth factor receptor activation (Boguski and McCormick, 1993: Nature 366:643-654). Transmission of signals from Ras to Raf is regulated by the Ras-related protein Rap1 (a protein capable of reverting cell transformation) and by cAMP. Other aspects of Ras p21 regulation will be discussed, including the existence of RasGDl proteins that inhibit GDP dissociation from Ras, and may thus regulate the level of active Ras in the cell. The role of Ras in activation of Raf kinase appears to be limited to the recruitment of Raf to the plasma membrane, at which time Raf becomes stably modified to render it active (Leevers et al., 1994: Nature 369:411-414; Stokoe et al., 1994: Science 264:1463-1467). The nature of these modifications is unclear. Raf in the plasma membrane becomes associated with insoluble structural cell components that may be part of the activation. Furthermore, Raf is associated with proteins of the 14-3-3 family that appear necessary for kinase activation. The 14-3-3 proteins interact with all three conserved regions of Raf, including the kinase domain. In addition to Raf, Ras proteins interact with two known classes of proteins in a manner consistent with effector functions: these are the GAPs and regulators of the Ras-related protein Ral referred to as RalGDS. These biochemical data suggest that other functional pathways are regulated by Ras, including, perhaps, pathways involved in regulating cell shape and motility. The protein R-Ras p21 is about 50% identical to the Ras p21 protooncogene product. This protein is incapable of transforming cells, even though it interacts with Raf and other putative Ras effectors (Fernandez-Sarabia and Bischoff, 1993: Nature 366:274-275). On the other hand, it has recently been shown that R-Ras binds to the protooncogene product Bcl-2, a protein that transforms B cells by blocking apoptosis. R-Ras is regulated by the same GAP molecules as H-Ras and the other Ras protooncogene products, and may therefore be activated in a manner co-ordinate with these growth-promoting proteins. The possible connection between R-Ras and apoptosis will be discussed.
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PMID:Ras-related proteins in signal transduction and growth control. 860 82

Recent evidence from our laboratory suggests that the fraction of cells with lethal mutations is lost from the population by apoptosis. The relationship of this process to genetic instability and carcinogenesis is unclear. To examine this, tumorigenic cell populations derived from spontaneously occurring, neoplastically transformed C3H 1OT1/2 foci and from radiation-induced foci were compared with wild-type C3H 10T1/2 cell populations to determine the frequency of induction of lethal mutations postirradiation. Lethal mutations did not occur in the progeny of cells from type 3 foci derived from cultures of spontaneously occurring or radiation-induced neoplastically transformed cells but were very frequent in the progeny of irradiated wild-type cells. Normal human cells (HPV-immortalized human keratinocytes and primary human normal uroepithelium) were then treated with carcinogens or transfected with the Ha-ras oncogene to see if these carcinogenic events affected the yield of lethal mutations postirradiation. In each case, cells which were exposed to a carcinogenic agent had reduced numbers of lethal mutations, elevated levels of stable p53 and Bcl-2 proteins and reduced evidence of apoptosis. It is suggested that lethal mutations may represent an active safety mechanism which may deal with radiation-induced genomic instability and which is disabled early in carcinogenesis.
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PMID:Expression of lethal mutations is suppressed in neoplastically transformed cells and after treatment of normal cells with carcinogens. 864 31

Cellular oncogenes have been shown to play crucial roles in the cell death process induced by cytotoxic agents. In this study, we have demonstrated that v-H-ras transformed NIH 3T3 cells but not other transformants (v-raf, v-src, v-erbB-2, v-fes and v-mos) exhibited a survival advantage to treatment by a DNA-damaging agent, methylmethanesulfonate (MMS). Subsequently, the biochemical and morphologic criteria of MMS-treated cells were examined. It was found that MMS induced v-H-ras transformants to go through necrosis, but it induced other transformed cells to undergo apoptosis. The levels of glutathione (GSH) within each transformant as well as in NIH 3T3 cells, were determined. The results showed that GSH levels within ras transformants were 2- to 7-fold higher than the levels in other transformants and normal NIH 3T3 cells. By using the GSH synthesis inhibitor buthionine sulfoximine, GSH levels were artificially reduced. This depletion, however, made ras transformed cells more sensitive to MMS killing, but the mode of cell death was still necrosis. Western blot analysis demonstrated that the anti-apoptotic protein Bcl-2 was constitutively expressed in ras transformed cells but not in NIH 3T3 or other transformed cells. The level of Bcl-2 was correlated with the resistant phenotype of ras transformants during MMS treatment. These observations suggest that GSH and Bcl-2 levels may cooperatively confer the resistant phenotype of ras transformants in response to MMS. In addition, the mode of cell death may possibly be determined at least in part by Bcl-2 protein.
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PMID:Differential induction of apoptosis in oncogene-transformed NIH 3T3 cells by methylmethanesulfonate. 868 3

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