EC:3.4.25.1 - FACTA Search

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Query: EC:3.4.25.1 (proteasome)
28,817 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

c-fos and c-jun proto-oncogenes have originally been found in mutated forms in murine and avian oncogenic retroviruses. They both define multigenic families of transcription factors. Both c-jun and c-fos proteins are metabolically unstable. In vivo and in vitro work by various groups suggests that multiple proteolytic machineries, including the lysosomes, the proteasome and the ubiquitous calpains, may participate in the destruction of c-fos and c-jun. The relative contribution of each pathway is far from being known and it cannot be excluded that it varies according to the cell context and/or the physiological conditions. It has been demonstrated that, in certain occurrences, the degradation of both c-fos and c-jun by the proteasome in vivo involves the ubiquitin pathway. However, the possibility that proteasomal degradation can also occur in a manner independent of the E1 enzyme of the ubiquitin cycle remains an open issue.
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PMID:Complex mechanisms for c-fos and c-jun degradation. 922 81

Human T-cell leukemia virus type 1 (HTLV-1) Tax targets I-kappaB alpha and I-kappaB beta for phosphorylation, ubiquitination, and proteasome-mediated degradation, causing the nuclear translocation of NF-kappaB/Rel proteins and transcription induction of many cellular genes. The mechanism by which a nuclear protein such as Tax stimulates I-kappaB phosphorylation and degradation remains unclear. Here, we describe two cytoplasmic mutants of Tax, designated TaxDeltaN81 and TaxDeltaN109, from which the domains important for cyclic AMP response element binding factor (CREB) and serum response factor (SRF) binding and nuclear transport have been removed. These mutants were unable to trans activate from the HTLV-1 21-bp repeats or the serum response element in the c-fos promoter. In contrast, they activated NF-kappaB reporters, suggesting that activation of NF-kappaB by Tax occurs in the cytoplasm. Incorporation of the nuclear localization signal (NLS) of the simian virus 40 large T antigen into TaxDeltaN81 and TaxDeltaN109 redirected both proteins predominantly to the nucleus yet did not restore trans activation via CREB or SRF. The NLS fusion had little effect on TaxDeltaN81 but reduced NF-kappaB trans activation by TaxDeltaN109, possibly because of its proximity to the NF-kappaB-activating domain of Tax. In contrast to wild-type Tax, the cytoplasmic TaxDeltaN mutants are not cytotoxic. Stable expression of TaxDeltaN109 in HeLa cells resulted in a significant reduction in the intracellular level of I-kappaB alpha, with the constitutive presence of NF-kappaB in the nucleus and concomitant activation of the NF-kappaB enhancer. These results are suggestive of a potential application of the TaxDeltaN109-like mutants in targeting I-kappaB degradation and NF-kappaB activation. Interestingly, a Tax species with a molecular mass similar to that of TaxDeltaN109 was identified in many HTLV-1-transformed T cells, suggesting that TaxDeltaN109-like species might play a role in HTLV-1-induced leukemogenesis.
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PMID:Cytoplasmic forms of human T-cell leukemia virus type 1 Tax induce NF-kappaB activation. 965 26

The multicatalytic protease complex or proteasome is a fundamental nonlysosomal tool that the cell uses to process or degrade proteins at a fast rate through the ubiquitin and ATP-dependent proteolytic pathway. Examples of these important proteins include the tumor suppressor protein p53, various cyclins, the cyclin-dependent kinase inhibitor p27, NFkappaB, IkappaB, c-fos, and c-jun. The activation of proteolytic enzymes, including certain cystein-proteases of the ced-3/ICE (interleukin-1beta-converting enzyme) family, is a characteristic feature of the apoptotic program. However, the role of the multicatalytic protease complex in apoptosis is not well known. In order to obtain further information regarding the participation of the ubiquitin-mediated pathway in the decision of the cell to execute the cell death program, we have used a specific inhibitor of the multicatalytic protease complex, lactacystin, in cultured cerebellar granule cells. Cells were obtained from the cerebellum of 6- to 8-day-old Wistar rats and cultured in Neurobasal medium supplemented with B-27. Addition of lactacystin to the cultures induced apoptosis of the granule cells in a time-dependent fashion. The morphological changes produced by the proteasome inhibitor included nuclear condensation and DNA fragmentation measured by the diphenylamine test, as well as a positive labeling by the TUNEL (terminal deoxynucleotidyltransferase mediated-dUTP nick end labeling) assay, all of them typical features of apoptosis. Concomitant with apoptosis, there were changes in the expression of the ubiquitin mRNA, a progressive depletion in the free ubiquitin pool, and an increase in the high molecular weight ubiquitin-protein conjugates. Caspase-3, a member of the ced-3/ICE family of cystein-proteases, showed a marked increase in activity in the lactacystin-treated cells. In flow cytometry studies, the amount of cells in the S phase of the cell cycle was smaller in the lactacystin-treated cells than in controls, suggesting that apoptosis could be due, in part, to an alteration of the cell cycle.
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PMID:Lactacystin, a specific inhibitor of the proteasome, induces apoptosis and activates caspase-3 in cultured cerebellar granule cells. 1068 88

In the process of positive selection, immature CD4+8+ double positive (DP) thymocytes expressing TCR reactive to self-MHC by appropriate avidity develop into mature thymocytes. Positive selection involves not only down-regulation of either CD4 or CD8 but also acquisition of immunocompetent potential such as cell proliferation and cytokine production. To understand the molecular basis for such functional maturation during the positive selection process, we examined whether nonselected DP, selected DP, and CD4+8- single positive thymocytes possess the activation potential for signaling pathways from mitogen-activated protein kinases (extracellular signal-regulated kinase and c-Jun N-terminal kinase) to AP-1. In response to stimulation, a marked induction of c-Fos protein expression as well as cell proliferation is detected only in CD4+8- single positive cells but not in selected and nonselected DP cells, though mitogen-activated protein kinase activities and c-fos transcripts are equally induced. In the presence of proteasome inhibitors, c-Fos protein became detectable in selected DP cells but still not in nonselected DP cells, suggesting that DP cells receiving positive selection signals acquire the capacity to translate the c-fos gene, but it may not be sufficiently high to overcome the degradation of c-Fos protein. These data indicate that the translating ability of the c-fos gene is up-regulated in the thymic positive selection process, from nonselected DP to CD4+8- single positive cells through positively selected DP cells. The distinguished responsiveness to stimulation in thymocytes with and without positive selection may be a result in part of the distinct regulation of the c-fos gene at the translational level.
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PMID:Molecular basis for functional maturation of thymocytes: increase in c-fos translation with positive selection. 1082 Feb 33

Release of calcium from the endoplasmic reticulum (ER) signals an increase in transcription of both the early response gene, c-fos, and the late response gene, grp78. We have used thapsigargin (TG), an ER calcium-ATPase pump inhibitor that induces calcium release from the ER, to investigate the possible involvement of c-Fos, a component of the AP-1 transcription factor, in grp78 induction. Two cell lines with markedly different responses to TG treatment were employed: the WEHI7.2 mouse lymphoma line in which TG fails to induce grp78, and the MDA-MB-468 mammary epithelial line in which TG induces grp78. In WEHI7.2 cells, TG-induced calcium release triggers a rapid increase in c-fos mRNA, but the level of c-Fos protein decreases due to degradation by the multicatalytic proteasome. C-FosdeltaC, a proteasome resistant c-Fos mutant with AP-1 activity similar to that of wild type c-Fos, restores grp78 induction in WEHI7.2 cells, detected by both Northern hybridization and a grp78 promoter-luciferase reporter assay. In MDA-MB-468 cells, TG-mediated calcium release induces a sustained elevation of c-Fos protein that precedes grp78 induction. A region of the grp78 promoter containing both ERSE and CORE regions, but missing TRE and CRE regions, is sufficient to mediate induction of reporter luciferase activity. Induction of this reporter was blocked by A-Fos, a dominant negative inhibitor of c-Fos. Also, the induction of grp78-luciferase reporter activity was inhibited by c-fos antisense mRNA. In summary, the findings indicate that c-Fos is involved in signaling grp78 induction following TG treatment, and that grp78 induction is inhibited by proteasome-mediated c-Fos degradation.
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PMID:Involvement of c-Fos in signaling grp78 induction following ER calcium release. 1112 25

Proteasome inhibitors, the well-known inhibitors of NF-kappaB, are recently considered therapeutic agents for inflammation. However, the anti-inflammatory properties of these agents have not been fully evaluated. In this report we describe a novel effect of proteasome inhibitors on the expression of monocyte chemoattractant protein 1 (MCP-1) in mesangial cells. We found that proteasome inhibitor MG132 dose-dependently induced expression of MCP-1 at the transcriptional level. The stimulatory effect was similarly observed with other proteasome inhibitors (proteasome inhibitor 1 and lactacystin) and in other cell types (NRK fibroblasts). The 5'-flanking region of the MCP-1 gene contains multiple AP-1 sites. To explore the mechanisms involved, we examined the effects of proteasome inhibition on the AP-1 pathway. Northern blot analysis showed that MG132 rapidly induced the expression of c-jun, but not c-fos. Immunoblot analysis showed that MG132 prevented degradation of c-Jun protein. Kinase assay revealed that c-Jun N-terminal kinase (JNK) was rapidly activated by MG132. Consistent with these results, a reporter assay showed that AP-1 activity was up-regulated after treatment with MG132. Curcumin, a pharmacological inhibitor of the JNK-AP-1 pathway, abrogated the induction of MCP-1 by MG132. Similarly, stable transfection with a dominant-negative mutant of c-Jun attenuated both MG132-induced activation of AP-1 and expression of MCP-1. The transcriptional activation by proteasome inhibitors was observed not only in MCP-1, but also in other AP-1-dependent genes, including stromelysin and mitogen-activated protein kinase phosphatase 1. These data revealed that proteasome inhibition triggered the expression of MCP-1 and other genes via the multistep induction of the JNK-c-Jun/AP-1 pathway.
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PMID:Unexpected transcriptional induction of monocyte chemoattractant protein 1 by proteasome inhibition: involvement of the c-Jun N-terminal kinase-activator protein 1 pathway. 1146 28

c-Fos proto-oncoprotein is rapidly and transiently expressed in cells undergoing the G(0)-to-S phase transition in response to stimulation for growth by serum. Under these conditions, the rapid decay of the protein occurring after induction is accounted for by efficient recognition and degradation by the proteasome. PEST motifs are sequences rich in Pro, Glu, Asp, Ser and Thr which have been proposed to constitute protein instability determinants. c-Fos contains three such motifs, one of which comprises the C-terminal 20 amino acids and has already been proposed to be the major determinant of c-Fos instability. Using site-directed mutagenesis and an expression system reproducing c-fos gene transient expression in transfected cells, we have analysed the turnover of c-Fos mutants deleted of the various PEST sequences in synchronized mouse embryo fibroblasts. Our data showed no role for the two internal PEST motifs in c-Fos instability. However, deletion of the C-terminal PEST region led to only a twofold stabilization of the protein. Taken together, these data indicate that c-Fos instability during the G0-to-S phase transition is governed by a major non-PEST destabilizer and a C-terminal degradation-accelerating element. Further dissection of c-Fos C-terminal region showed that the degradation-accelerating effect is not contributed by the whole PEST sequence but by a short PTL tripeptide which cannot be considered as a PEST motif and which can act in the absence of any PEST environment. Interestingly, the PTL motif is conserved in other members of the fos multigene family. Nevertheless, its contribution to protein instability is restricted to c-Fos suggesting that the mechanisms whereby the various Fos proteins are broken down are, at least partially, different. MAP kinases-mediated phosphorylation of two serines close to PTL, which are both phosphorylated all over the G(0)-to-S phase transition, have been proposed by others to stabilize c-Fos protein significantly. We, however, showed that the PTL motif does not exert its effect by counteracting a stabilizing effect of these phosphorylations under our experimental conditions.
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PMID:Identification of a C-terminal tripeptide motif involved in the control of rapid proteasomal degradation of c-Fos proto-oncoprotein during the G(0)-to-S phase transition. 1170 28

An AU rich element (ARE) in the 3' noncoding region promotes the rapid degradation of mammalian cytokine and proto-oncogene mRNAs, such as tumor necrosis factor-alpha, granulocyte-macrophage colony-stimulating factor (GM-CSF) and c-fos. Destabilization of ARE-mRNAs involves the association of ARE-binding proteins tristetraprolin or AUF1 and proteasome activity, of which the latter has not been characterized. Here, we show that the stability of a model short-lived mRNA containing the GM-CSF ARE was regulated by the level of ubiquitin-conjugating activity in the cell, which links ARE-mRNA decay to proteasome activity. Increased expression of a cytokine-inducible deubiquitinating protein (DUB) that impairs addition of ubiquitin to proteins fully blocked ARE-mRNA decay, whereas increased expression of a DUB that promotes ubiquitin addition to proteins strongly accelerated ARE-mRNA decay. ARE-mRNA turnover was found to be activated by the ubiquitin-addition reaction and blocked by the ubiquitin-removal reaction. Saturation of the ARE-mRNA decay machinery by high levels of ARE-mRNA, which is well established but not understood, was found to be relieved by increased expression of a DUB that promotes ubiquitin addition to proteins. Finally, inhibition of proteasome activity also blocked accelerated ARE-mRNA decay that is mediated by increased ubiquitin recycling. These results demonstrate that both ubiquitinating activity and proteasome activity are essential for rapid turnover of a model cytokine ARE-mRNA containing the GM-CSF ARE.
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PMID:Ubiquitin-dependent mechanism regulates rapid turnover of AU-rich cytokine mRNAs. 1184

c-Fos protooncoprotein is a short-lived transcription factor with oncogenic potential. It is massively degraded by the proteasome in vivo under various experimental conditions. Those include consititutive expression in exponentially growing cells and transient induction in cells undergoing the G0/G1 phase transition upon stimulation by serum. Though there is evidence that c-Fos can be ubiquitinylated in vitro, the unambigous demonstration that prior ubiquitinylation is necessary for degradation by the proteasome in vivo is still lacking. c-Jun, one of the main dimerization partners of c-Fos within the AP-1 transcription complex, is also an unstable protein. Its degradation is clearly proteasome dependent. However, several lines of evidence indicate that the mechanisms by which it addresses the proteasome are different from those operating on c-Fos. Moreover, genetic analysis has indicated that c-Fos is addressed to the proteasome via pathways that differ depending on the conditions of expression. c-Fos has been transduced by two murine osteosarcomatogenic retroviruses in mutated forms, which are more stable and more oncogenic. The stabilization is not simply accounted for by simple deletion of one of the main c-Fos destabilizers but, rather, by a complex balance between opposing destabilizing and stabilizing mutations. However, although viral Fos proteins have acquired full resistance to proteasomal degradation, stabilization is limited because the mutations they have accumulated, during or after c-fos gene transduction, confer sensitivity to an unidentified proteolytic system(s). This observation is consistent with the idea that fos-expressing viruses have evolved expression machineries to ensure controlled protein levels in order to maintain an optimal balance between prooncogenic and proapoptotic activities of v-Fos proteins.
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PMID:Multiple degradation pathways for Fos family proteins. 1248 5

c-fos gene is expressed constitutively in a number of tissues as well as in certain tumor cells and is inducible, in general rapidly and transiently, in virtually all other cell types by a variety of stimuli. Its protein product, c-Fos, is a short-lived transcription factor that heterodimerizes with various protein partners within the AP-1 transcription complex via leucine zipper/leucine zipper interactions for binding to specific DNA sequences. It is mostly, if not exclusively, degraded by the proteasome. To localize the determinant(s) responsible for its instability, we have conducted a genetic analysis in which the half-lives of c-Fos mutants and chimeras made with the stable EGFP reporter protein were compared under two experimental conditions taken as example of continous and inducible expression. Those were constitutive expression in asynchronously growing Balb/C 3T3 mouse embryo fibroblasts and transient induction in the same cells undergoing the G0/G1 phase transition upon stimulation by serum. Our work shows that c-Fos is degraded faster in synchronous- than in asynchronous cells. This difference in turnover is primarily accounted for by several mechanisms. First, in asynchronous cells, a unique C-terminal destabilizer is active whereas, in serum-stimulated cells two destabilizers located at both extremities of the protein are functional. Second, heterodimerization and/or binding to DNA accelerates protein degradation only during the G0/G1 phase transition. Adding another level of complexity to turnover control, phosphorylation at serines 362 and 374, which are c-Fos phosphorylation sites largely modified during the G0/G1 phase transition, stabilizes c-Fos much more efficiently in asynchronous than in serum-stimulated cells. In both cases, the reduced degradation rate is due to inhibition of the activity of the C-terminal destabilizer. However, in serum-stimulated cells, this effect is partially masked by the activation of the N-terminal destabilizer and basic domain/leucine zipper-dependent mechanisms. Taken together, our data show that multiple degradation mechanisms, differing according to the conditions of expression, may operate on c-Fos to ensure a proper level and/or timing of expression. Moreover, they also indicate that the half-life of c-Fos during the G0/G1 phase transition is determined by a delicate balance between opposing stabilizing and destabilizing mechanisms operating at the same time.
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PMID:The structural determinants responsible for c-Fos protein proteasomal degradation differ according to the conditions of expression. 1262 9

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