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)

Proteasomes are intricate cellular proteases that are able to degrade many protein and peptide substrates in vitro. These particles are structurally complex; they are assembled from at least 14 small molecular mass polypeptide subunits to form mature 20S proteasomes. Recently, we demonstrated that proteasome subsets may be discriminated by serological criteria, and have found that subtle differences in the subunit composition of proteasomes can alter their cleavage specificity. Proteasome structural complexity is further enhanced when some proteasomes associate with additional proteins to form a 26S ATP- and ubiquitin-dependent protease. Herein we confirm the existence of distinct cellular forms of proteasomes, and show that they differ in their hydrophobic characteristics. We have reproducibly purified, using solely biochemical techniques, distinct proteasome subsets similar to the serologically defined LMP2+ and LMP2- proteasomes. These proteasome subsets differ in their expression of at least three polypeptides, and both lack several additional polypeptides as compared to the serologically defined LMP2+ and LMP2- proteasomes. Finally, we demonstrate that these structurally unique proteasomes differ in their capacity to cleave a defined panel of fluorogenic peptide substrates. It appears that mammalian cells might recruit and modify proteasomes to perform distinct cellular tasks.
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PMID:Biochemical purification of distinct proteasome subsets. 769 32

Recent studies have demonstrated that the proteasome, in addition to functioning in the complete degradation of cell proteins, is the source of most antigenic peptides presented to the immune system on major histocompatibility complex (MHC)-class I molecules. In this process, intracellular and viral proteins are degraded in the cytosol to 8- to 9-amino acid fragments, which are then transported into the endoplasmic reticulum, where they become associated with MHC-class I molecules and are thus delivered to the cell surface. A variety of evidence has shown that the proteasome and ATP-ubiquitin-dependent pathway are critical in this process: (1) In cells, selective inhibitors of proteasome function inhibit the bulk of protein degradation and thus prevent the generation of peptides necessary for class I presentation and the appearance of MHC on the cell surface. (2) Mutations that block ubiquitin conjugation prevent the generation of an antigenic peptide. (3) Modifications that lead to rapid degradation of a protein by the ubiquitin pathway enhance antigen presentation. (4) gamma-Interferon (gamma-IFN) induces new proteasome subunits, LMP2 and LMP7, encoded in the MHC region that are incorporated in place of constitutive proteasome subunits. Their incorporation does not affect rates of protein breakdown but causes changes in peptidase activities, i.e. they increase rates of cleavage after basic and hydrophobic residues and decrease cleavage after acidic residues. Transfections of cells with LMP2 or LMP7 cause similar changes in these peptidase activities as are caused by gamma-IFN. These modifications in peptidase activities should enhance the production of those types of peptides which are preferentially transported into endoplasmic reticulum and selectively bound to MHC-class I molecules.
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PMID:Role of proteasomes in antigen presentation. 769 33

The N-end rule relates the in vivo half-life of a protein to the identity of its N-terminal residue. In eukaryotes, the N-end rule pathway is a ubiquitin-dependent, proteasome-based system that targets and processively degrades proteins bearing certain N-terminal residues. Arg-DHFR, a modified dihydrofolate reductase bearing an N-terminal arginine (destabilizing residue in the N-end rule), is short lived in ATP-supplemented reticulocyte extract. It is shown here that methotrexate, which is a folic acid analog and high affinity ligand of DHFR, inhibits the degradation but not ubiquitination of Arg-DHFR by the N-end rule pathway. The degradation of other N-end rule substrates is not affected by methotrexate. We discuss implications of these results for the mechanism of proteasome-mediated protein degradation.
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PMID:Methotrexate inhibits proteolysis of dihydrofolate reductase by the N-end rule pathway. 771 22

Most of the increased protein degradation in muscle atrophy caused by starvation and denervation is due to activation of a non-lysosomal ATP-dependent proteolytic process. To determine whether expression of the ubiquitin-proteasome-dependent pathway is activated in atrophying muscles, we measured the levels of mRNA for ubiquitin (Ub) and proteasome subunits, and Ub content. After rats had been deprived of food for 1 or 2 days, the concentration of the two polyubiquitin (polyUb) transcripts increased 2-4-fold in the pale extensor digitorum longus muscle and 1-2.5-fold in the red soleus, whereas total muscle RNA and total mRNA content fell by 50%. After denervation of the soleus, there was a progressive 2-3-fold increase in polyUb mRNA for 1-3 days, whereas total RNA content fell. On starvation or denervation, Ub concentration in the muscles also rose by 60-90%. During starvation, polyUb mRNA levels also increased in heart, but not in liver, kidney, spleen, fat, brain or testes. Although the polyUb gene is a heat-shock gene that is induced in muscles under certain stressful conditions, the muscles of starving rats or after denervation did not express other heat-shock genes. On starvation or denervation, mRNA for several proteasome subunits (C-1, C-3, C-5, C-8 and C-9) also increased 2-4-fold in the atrophying muscles. When the food-deprived animals were re-fed, levels of Ub and proteasome mRNA in their muscles returned to control values within 1 day. In contrast, no change occurred in the levels of muscle mRNAs encoding cathepsin L, cathepsin D and calpain 1 on denervation or food deprivation. Thus polyUb and proteasome mRNAs increased in atrophying muscles in co-ordination with activation of the ATP-dependent proteolytic process.
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PMID:Increase in levels of polyubiquitin and proteasome mRNA in skeletal muscle during starvation and denervation atrophy. 774 90

The rapid loss of skeletal-muscle protein during starvation and after denervation occurs primarily through increased rates of protein breakdown and activation of a non-lysosomal ATP-dependent proteolytic process. To investigate whether protein flux through the ubiquitin (Ub)-proteasome pathway is enhanced, as was suggested by related studies, we measured, using specific polyclonal antibodies, the levels of Ub-conjugated proteins in normal and atrophying muscles. The content of these critical intermediates had increased 50-250% after food deprivation in the extensor digitorum longus and soleus muscles 2 days after denervation. Like rates of proteolysis, the amount of Ub-protein conjugates and the fraction of Ub conjugated to proteins increased progressively during food deprivation and returned to normal within 1 day of refeeding. During starvation, muscles of adrenalectomized rats failed to increase protein breakdown, and they showed 50% lower levels of Ub-protein conjugates than those of starved control animals. The changes in the pools of Ub-conjugated proteins (the substrates for the 26S proteasome) thus coincided with and can account for the alterations in overall proteolysis. In this pathway, large multiubiquitinated proteins are preferentially degraded, and the Ub-protein conjugates that accumulated in atrophying muscles were of high molecular mass (> 100 kDa). When innervated and denervated gastrocnemius muscles were fractionated, a significant increase in ubiquitinated proteins was found in the myofibrillar fraction, the proteins of which are preferentially degraded on denervation, but not in the soluble fraction. Thus activation of this proteolytic pathway in atrophying muscles probably occurs initially by increasing Ub conjugation to cell proteins. The resulting accumulation of Ub-protein conjugates suggests that their degradation by the 26S proteasome complex subsequently becomes rate-limiting in these catabolic states.
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PMID:Increase in ubiquitin-protein conjugates concomitant with the increase in proteolysis in rat skeletal muscle during starvation and atrophy denervation. 774 91

Ornithine decarboxylase (ODC), a key enzyme in the biosynthesis of polyamines, is an extremely short-lived protein. This attribute is important for the regulation of the activity of the enzyme and implies that the mechanisms involved in its degradation play an important role in the control of the cellular processes in which the enzyme is involved. Recently, it has been shown that ODC is degraded by the 26S proteasome complex in a process that requires antizyme, but not ubiquitin. With one reported exception, ODC, the 26S complex recognizes and degrades specifically ubiquitinated proteins. Their unconjugated counterparts are not targeted. The 26S complex is composed of a core catalytic unit, the 20S proteasome complex, and two additional, and apparently distinct, subcomplexes. The two additional subcomplexes are regulatory subunits that are required in order to confer specificity and control. In this study, we demonstrate that, like the degradation of ubiquitin-conjugated proteins, ubiquitin-independent degradation of ODC also requires prior assembly of the mammalian 26S proteasome from all the three subunits, the 20S proteasome and the two subcomplexes. The combination of any two subunits does not support generation of a proteolytically active complex. This is also true for the yeast 26S complex. Like the mammalian 20S proteasome, the yeast 20S complex can cleave short peptides in an ATP-independent mode, but cannot degrade ODC or ubiquitin-conjugated proteins. These proteins are degraded only following addition of the regulatory subunits and generation of the high-molecular-mass 26S complex. In a distinct, but related, set of experiments, we demonstrate that the degradation of ODC by the assembled 26S proteasome in vitro reproduces faithfully proteolysis of the enzyme in the intact cell. Namely, (a) a C-terminal-deleted mouse ODC and trypanosome ODC are stable both in vitro and in vivo, and (b) like proteolysis in the intact cell, degradation in the reconstituted cell-free system is also dependent upon the addition of antizyme.
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PMID:Degradation of ornithine decarboxylase by the mammalian and yeast 26S proteasome complexes requires all the components of the protease. 774 41

Degradation of rapidly turned over cellular proteins is commonly thought to be energy dependent, to require tagging of protein substrates by multi-ubiquitin chains, and to involve the 26 S proteasome, which is the major neutral proteolytic activity in both the cytosol and the nucleus. The c-Jun oncoprotein is very unstable in vivo. Using cell-free degradation assays, we show that ubiquitinylation, along with other types of tagging, is not an absolute prerequisite for ATP-dependent degradation of c-Jun by the 26 S proteasome. This indicates that a protein may bear intrinsic structural determinants allowing its selective recognition and breakdown by the 26 S proteasome. Moreover, taken together with observations by different groups, our data point to the notion of the existence of multiple degradation pathways operating on c-Jun.
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PMID:Ubiquitinylation is not an absolute requirement for degradation of c-Jun protein by the 26 S proteasome. 774 2

Escherichia coli FtsH is an essential integral membrane protein that has an AAA-type ATPase domain at its C-terminal cytoplasmic part, which is homologous to at least three ATPase subunits of the eukaryotic 26S proteasome. We report here that FtsH is involved in degradation of the heat-shock transcription factor sigma 32, a key element in the regulation of the E. coli heat-shock response. In the temperature-sensitive ftsH1 mutant, the amount of sigma 32 at a non-permissive temperature was higher than in the wild-type under certain conditions due to a reduced rate of degradation. In an in vitro system with purified components, FtsH catalyzed ATP-dependent degradation of biologically active histidine-tagged sigma 32. FtsH has a zinc-binding motif similar to the active site of zinc-metalloproteases. Protease activity of FtsH for histidine-tagged sigma 32 was stimulated by Zn2+ and strongly inhibited by the heavy metal chelating agent o-phenanthroline. We conclude that FtsH is a novel membrane-bound, ATP-dependent metalloprotease with activity for sigma 32. These findings indicate a new mechanism of gene regulation in E. coli.
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PMID:Escherichia coli FtsH is a membrane-bound, ATP-dependent protease which degrades the heat-shock transcription factor sigma 32. 778 8

The intersegmental muscles (ISMs) of the tobacco hawkmoth Manduca sexta are a well-characterized model system for examining the biochemical changes that accompany programmed cell death during development. These giant muscles die during a 30-hr period in response to a decline in the circulating titer of the insect molting hormone 20-hydroxyecdysone. When the ISMs become committed to die, there are dramatic increases in both ubiquitin expression and ubiquitin-dependent proteolysis. Since the multicatalytic proteinase (MCP) is responsible for ATP/ubiquitin-dependent proteolysis in cells, we examined its composition and properties. The purified enzyme from whole larval integumentary tissues resembles MCPs isolated from other species with respect to subunit composition and general catalytic properties. However, when MCP was isolated from condemned ISMs, we observed an approximately ninefold increase in proteinase activity compared to MCP from precommitment muscles. This increase in proteolytic activity was correlated with an approximately eightfold increase in the absolute amounts of MCP protein as determined by Western blotting and densitometry. When purified MCP from condemned muscles was examined by two-dimensional polyacrylamide gel electrophoresis, four new subunits that were not detected in the precommitment muscles were present. Correlated with the addition of these new subunits was a dramatic increase in the levels of immunodetectable MCP throughout the cytoplasm and within the nuclei of dying muscles. These changes in MCP were regulated by the same hormonal signals that mediate cell death. These data are consistent with the hypothesis that when the ISMs become committed to die, more MCP accumulates in cells and new subunits are synthesized that change both the enzymatic properties and the conformation of MCP, which in turn participates in the dramatic proteolysis that accompanies cell death.
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PMID:Changes in the structure and function of the multicatalytic proteinase (proteasome) during programmed cell death in the intersegmental muscles of the hawkmoth, Manduca sexta. 778 89

The absence of functional Yme1p, a putative ATP and zinc-dependent protease localized to mitochondria of yeast, results in abnormal mitochondrial function and morphology. Yeast lacking Yme1p lose DNA from mitochondria at an accelerated rate, fail to grow on nonfermentable carbon sources at 37 degrees C, and have severely deficient growth if mitochondrial DNA suffers large deletions or is completely lost. In place of the normal reticulated mitochondrial network, strains lacking Yme1p have punctate mitochondria with some grossly swollen compartments. The growth phenotypes and morphological alterations evident in these mutant yeast can be compensated by a mutation in YNT1, an essential gene in yeast. The sequence of the YNT1 gene product indicates that it is one of a number of related regulatory subunits of the 26S protease. This proteolytic activity is necessary for progression through the cell cycle and has been implicated in the regulation of transcription. Ynt1p is more distantly related to Yme1p.
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PMID:Mitochondrial morphological and functional defects in yeast caused by yme1 are suppressed by mutation of a 26S protease subunit homologue. 780 57

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