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)

The 2-phenylaminopyrimidine derivative STI571 is a selective inhibitor of c-Abl, c-kit, and platelet-derived growth factor-receptor tyrosine kinases and is presently in phase II-III clinical studies. Here, this study reports on a novel pharmacologic activity of the compound, ie, enhancement of the cyto-differentiating, growth-inhibitory, and apoptogenic actions of all-trans-retinoic acid (ATRA). Whereas STI571 is not a cytodifferentiating agent by itself, the compound interacts with ATRA and enhances the myeloid maturation program set in motion by the retinoid in the PML-RARalpha(+) acute promyelocytic leukemia NB4 and the PML-RARalpha(-) myeloblastic HL60 and U937 cell lines. In addition, STI571 relieves the cyto-differentiation block observed in the ATRA-resistant cell lines, NB4.R1, NB4.306, and NB4.007. In NB4 promyelocytes, a RARalpha agonist, but not an RXR agonist, can substitute for ATRA and interact with STI571. By contrast, STI571 is unique among c-Abl-specific tyrosine kinase inhibitors in modulating the pharmacologic activity of ATRA. In NB4 cells, enhanced cyto-differentiation results in increased up-regulation of the expression of a number of genes coding for myeloid differentiation markers, including CD11b, CD11c, and some of the components of the nicotinamide adenine dinucleotide phosphate-oxidase enzymatic complex. All this is accompanied by inhibition of c-Abl tyrosine phosphorylation and retardation of the retinoid-dependent degradation of PML-RARalpha and RARalpha. Stabilization of the 2 retinoic acid receptors is likely to be the result of augmented and accelerated inhibition of the proteasome-dependent proteolytic activity observed on ATRA treatment.
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PMID:Tyrosine kinase inhibitor STI571 potentiates the pharmacologic activity of retinoic acid in acute promyelocytic leukemia cells: effects on the degradation of RARalpha and PML-RARalpha. 1134 54

Although there is evidence to suggest that PML/RARalpha expression is not the sole genetic event required for the development of acute promyelocytic leukemia (APL), there is little doubt that the fusion protein plays a central role in the initiation of leukemogenesis. The two therapeutic agents, retinoic acid and arsenic, that induce clinical remissions in APL, both target the oncogenic fusion protein, representing the first example of oncogene-directed cancer therapy. This review focuses on the molecular mechanisms accounting for PML/RARalpha degradation. Each drug targets a specific moiety of the fusion protein (RARalpha for retinoic acid, PML for arsenic) to the proteasome. Moreover, both activate a common caspase-dependent cleavage in the PML part of the fusion protein. Specific molecular determinants (the AF2 transactivator domain of RARalpha for retinoic acid and the K160 SUMO-binding site in PML for arsenic) are respectively implicated in RA- or arsenic-triggered catabolism. The respective roles of PML/RARalpha activation versus its catabolism are discussed with respect to differentiation or apoptosis induction in the context of single or dual therapies.
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PMID:Pathways of retinoic acid- or arsenic trioxide-induced PML/RARalpha catabolism, role of oncogene degradation in disease remission. 1170 54

We have compared the intracellular location of the HPV E6 and E7 proteins from high- and low-risk virus types. While high-risk HPV E7 displays diffuse nuclear expression, low-risk E7 has a nuclear punctuate pattern of expression. Similarly, while high-risk E6 is expressed throughout the cell, low-risk E6 is again predominantly nuclear with a punctuate pattern of expression. Both low-risk viral oncoproteins show colocalization with PML, whereas high-risk viral proteins do not. Finally, inhibition of the proteasome pathway results in a dramatic nuclear accumulation of high-risk E6 protein. These results demonstrate fundamental differences in the localization of these viral oncoproteins within the cell and offer alternative explanations for their respective differences in pathology.
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PMID:Comparative analysis of the intracellular location of the high- and low-risk human papillomavirus oncoproteins. 1185 95

Early during infection, the herpes simplex regulatory protein ICP0 promotes the proteasome-dependent degradation of a number of cellular proteins and the loss of a number of SUMO-1-modified protein isoforms, including PML. Recently, ICP0 has been shown to induce the accumulation of conjugated ubiquitin and function as a ubiquitin E3 ligase. However, certain aspects of the biochemistry, cell biology and the links between SUMO-1 conjugation/deconjugation and protein degradation remain unclear. For example, it is not currently known whether SUMO-1 deconjugation is a prerequisite for ubiquitination or degradation and, if so, by what mechanism this may occur. To help address these questions, a SUMO-specific protease (SENP1) was cloned and its expression and localization in relation to ICP0 examined. A cell line was established which constitutively expresses SUMO-1 to facilitate studies of localization and biochemistry. SENP1 localized to the nucleus mainly in discrete subdomains, a subset of which co-localized with the PML bodies. Both ICP0 and SENP1 protease promoted the loss of SUMO-1 from the nucleus, observed both for the endogenous species and the cell line expressing the epitope-tagged SUMO-1. The tagged SUMO-1 was recruited into high molecular mass conjugates in the cell line, and expression of SENP1 promoted loss of these species, including the modified species of PML. Finally, in co-transfection experiments ICP0 promoted the recruitment of SENP1 to nuclear domains, a result which was also observed early during infection. The significance of these findings is discussed in relation to the function of ICP0.
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PMID:Herpes simplex virus 1 ICP0 co-localizes with a SUMO-specific protease. 1246 71

Although proteasomes are abundant in the nucleoplasm little is known of proteasome-dependent proteolysis within the nucleus. Thus, we monitored the subcellular distribution of nuclear proteins in correlation with proteasomes. The proteasomal pathway clears away endogenous proteins, regulates numerous cellular processes, and delivers immunocompetent peptides to the antigen presenting machinery. Confocal laser scanning microscopy revealed that histones, splicing factor SC35, spliceosomal components, such as U1-70k or SmB/B('), and PML partially colocalize with 20S proteasomes in nucleoplasmic substructures, whereas the centromeric and nucleolar proteins topoisomerase I, fibrillarin, and UBF did not overlap with proteasomes. The specific inhibition of proteasomal processing with lactacystin induced accumulation of histone protein H2A, SC35, spliceosomal components, and PML, suggesting that these proteins are normally degraded by proteasomes. In contrast, concentrations of centromeric proteins CENP-B and -C and nucleolar proteins remained constant during inhibition of proteasomes. Quantification of fluorescence intensities corroborated that nuclear proteins which colocalize with proteasomes are degraded by proteasome-dependent proteolysis within the nucleoplasm. These data provide evidence that the proteasome proteolytic pathway is involved in processing of nuclear components, and thus may play an important role in the regulation of nuclear structure and function.
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PMID:Proteasome-dependent processing of nuclear proteins is correlated with their subnuclear localization. 1249 Jan 67

Proteasomes are present in the cytoplasm and in the nuclei of all eukaryotic cells, however their relative abundance within those compartments is highly variable. In the cytoplasm, proteasomes associate with the centrosomes, cytoskeletal networks and the outer surface of the endoplasmic reticulum (ER). In the nucleus, proteasomes are present throughout the nucleoplasm but are void from the nucleoli. Sometimes they associate with discrete subnuclear domains called the PML nuclear bodies (POD domains). PML bodies in the nucleus, and the pericentrosomal area of the cytoplasm may function as proteolytic centers of the cell, since they are enriched in components of the proteasome system. Under conditions of impaired proteolysis proteasomes and ubiquitinated proteins further accumulate at these locations, forming organized aggregates. In case of the pericentrosomal area those aggregates have been termed "aggresomes". Once formed, aggresomes can impair the function of the proteasome system, which may promote apoptosis. Under favorable conditions they can be cleared, probably by autophagy.
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PMID:Intracellular localization of proteasomes. 1267 51

Epstein-Barr virus (EBV) carrying lymphoblastoid cells of normal origin express the full program of all 9 virus-encoded, growth transformation associated proteins. They have an intact p53 pathway as a rule. This raises the question of whether any of the viral proteins impair the pathway functionally. Using a yeast 2-hybrid system, we have shown that EBNA-5 but not the other EBNAs interacts with the p14ARF protein, a regulator of the p53 pathway. The interaction was confirmed in vitro using a GST pull-down assay. Moreover, expression of EBNA-5 increased the survival of p14ARF-transfected cells. EBV infection of resting B cells induced the expression of p14ARF mRNA without increased level of the protein. A fraction of the p14ARF localized to the nucleoli but the bulk of the protein accumulated in nuclear but extranucleolar inclusions. Formation of the extranucleolar inclusions led to complete relocalization of EBNA-5 from nucleoplasm to these structures. The inclusions also contained p53 and HDM2, and were surrounded by PML bodies and proteasomes, which suggests that these inclusions could be targets for proteasome dependent protein degradation.
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PMID:EBV-encoded EBNA-5 associates with P14ARF in extranucleolar inclusions and prolongs the survival of P14ARF-expressing cells. 1274 Sep 13

PML-RARalpha protein, the leukemogenic product of t(15,17) in acute promyelocytic leukemia, is cleaved into a truncated form termed deltaPML-RARalpha during all-trans retinoic acid (ATRA)-induced differentiation of NB4 cells. DeltaPML-RARalpha is not formed in ATRA differentiation resistant NB4 subclones. As(2)O(3) inhibits deltaPML-RARalpha formation and differentiation-induction when given in combination with ATRA. Treatment with hexamethylene bisacetamide (HMBA) combined with ATRA enhances ATRA-induced differentiation in ATRA-insensitive NB4-CI and arsenic-resistant NB4/As cells, and is associated with stabilization of PML-RARalpha protein and increased deltaPML-RARalpha formation. Unlike forced expression of PML-RARalpha, forced deltaPML-RARalpha expression based on an estimated deletion of the N-terminal PML portion does not repress RARE-tk-luc reporter activity mediated by endogenous retinoic acid receptors. The cleavage of PML-RARalpha is blocked by RARalpha antagonist Ro-41-5253 and cycloheximide and therefore requires a RARalpha transactivation-dependent pathway. Proteasome inhibitor MG-132 and caspase inhibitor Z-VAD-FMK do not block ATRA-induced PML-RARalpha cleavage and differentiation. These data suggest that (a) ATRA treatment induces PML-RARalpha cleavage by induction of unknown enzymes independent of proteasome- and caspase-mediated pathways; (b) deltaPML-RARalpha might function differently from both PML-RARalpha and RARalpha; (c) failure to cleave PML-RARalpha and form deltaPML-RARalpha after ATRA treatment may contribute to ATRA resistance in APL cells.
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PMID:The cleavage product deltaPML-RARalpha contributes to all-trans retinoic acid-mediated differentiation in acute promyelocytic leukemia cells. 1282 42

During the early stages of herpes simplex virus type 1 (HSV-1) infection, viral immediate-early regulatory protein ICP0 localizes to and disrupts cellular nuclear structures known as PML nuclear bodies or ND10. These activities correlate with the functions of ICP0 in stimulating lytic infection and reactivating quiescent HSV-1. The disruption of ND10 occurs because ICP0 induces the loss of the SUMO-1-modified forms of PML and the subsequent proteasome-mediated degradation of the PML protein. The functions of ICP0 are largely dependent on the integrity of its zinc-binding RING finger domain. Many RING finger proteins have been found to act as ubiquitin E3 ligase enzymes, stimulating the production of conjugated polyubiquitin chains in the presence of ubiquitin, the ubiquitin-activating enzyme E1, and the appropriate E2 ubiquitin-conjugating enzyme. Substrate proteins that become polyubiquitinated are then subject to degradation by proteasomes. We have previously shown that purified full-length ICP0 acts as an efficient E3 ligase in vitro, producing high-molecular-weight polyubiquitin chains in a RING finger-dependent but substrate-independent manner. In this paper we report on investigations into the factors governing the degradation of PML induced by ICP0 in a variety of in vivo and in vitro assays. We found that ICP0 expression increases the levels of ubiquitinated PML in transfected cells. However, ICP0 does not interact with or directly ubiquitinate either unmodified PML or SUMO-1-modified PML in vitro, suggesting either that additional factors are required for the ICP0-mediated ubiquitination of PML in vivo or that PML degradation is an indirect consequence of some other activity of ICP0 at ND10. Using a transfection-based approach and a family of deletion and point mutations of PML, we found that efficient ICP0-induced PML degradation requires sequences within the C-terminal part of PML and lysine residue 160, one of the principal targets for SUMO-1 modification of the protein.
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PMID:PML residue lysine 160 is required for the degradation of PML induced by herpes simplex virus type 1 regulatory protein ICP0. 1288 87

Lytic-cycle replication of Kaposi's sarcoma-associated herpesvirus (KSHV) in PEL cells causes G(1) cell cycle arrest mediated by the virus-encoded replication-associated protein (RAP) (or K8 protein), which induces high-level expression of the cellular C/EBPalpha and p21 proteins. Here we have examined the mechanism of this induction at both the transcriptional and posttranslational levels. RAP proved to bind very efficiently to both C/EBPalpha and p21 and stabilized them by up to 10-fold from proteasome-mediated degradation in vitro. Cross-linking revealed that RAP itself forms stable dimers and tetramers in solution and forms higher-order complexes but not heterodimers with C/EBPalpha. Cotransfection of RAP with C/EBPalpha cooperatively stimulated both the C/EBPalpha and p21 promoters in luciferase reporter gene assays. Only the basic/leucine zipper region of RAP was needed for interaction with and stabilization of C/EBPalpha, but both the N-terminal and C-terminal domains were required for transcriptional augmentation. In vitro-translated RAP interfered with DNA binding by C/EBPalpha in electrophonetic mobility shift assay (EMSA) experiments but did not itself bind to the target C/EBPalpha sites or form supershifted bands. However, in endogenous chromatin immunoprecipitation (ChIP) assays with tetradecanoyl phorbol acetate-induced PEL cells, RAP proved to specifically associate with the C/EBPalpha promoter in vivo, but only in a C/EBPalpha-dependent manner, implying an in vivo piggyback interaction with DNA-bound C/EBPalpha. Expression of exogenous RAP (Ad-RAP) caused G(1)/S cell cycle arrest in human dermal microvascular endothelial cells and also induced both the C/EBPalpha and p21 proteins, which formed punctate nuclear patterns that colocalized with RAP in PML nuclear bodies. In the presence of RAP, C/EBPalpha was also efficiently recruited into viral DNA replication compartments in both infected and cotransfected cells. In support of a direct role for this interaction in viral DNA replication, three C/EBPalpha binding sites were identified by in vitro EMSA experiments within a 220-bp core segment of the duplicated KSHV Ori-Lyt region, and although RAP did not bind to Ori-Lyt DNA directly in vitro, both endogenous RAP and C/EBPalpha were found to be associated with the Ori-Lyt region by ChIP assays in lytically induced PEL cells. Finally, we found that the KSHV lytic cycle could not be triggered by either synchronizing KSHV latently infected PEL cells in G(1) phase or inducing p21 in a C/EBPalpha-independent process.
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PMID:Cell cycle arrest by Kaposi's sarcoma-associated herpesvirus replication-associated protein is mediated at both the transcriptional and posttranslational levels by binding to CCAAT/enhancer-binding protein alpha and p21(CIP-1). 1288 7

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