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)

Escherichia coli can be used to study the expression signal of the gene aprE (alkaline protease E) according to its promoter strength to express the promoterless cat-86 gene in a promoter-probe plasmid, pGKV210. We have constructed a signal-sequence-probe plasmid, pBLa, based on the E. coli-B. subtilis plasmid pHP13, using the M. bla as a reporter. Two secretion vectors pSP1 and pSP2 were constructed subsequently based on pHP13 using the promoter and the signal sequence of aprE. DB104 carrying pSP1 showed much higher secretion rate of M. bla than that carrying pSP2. Analysis of DNA sequences surrounding the fusion junctions of the signal sequences and the M. bla gene in the two plasmids indicated that the signal sequence in pSP1 had a 30bp deletion at its 3' end. A new signal peptidase recognition site has been found in the linker-encoded amino acid sequence. The change in length of the signal peptide might somehow increase the secretion efficiency or the synthesis of M. bla.
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PMID:[Construction of secretion vectors using signal sequence of Bacillus subtilis alkaline protease E gene]. 791 35

The class I major histocompatibility complex (MHC class I) presents 8-10 residue peptides to cytotoxic T lymphocytes. Most of these antigenic peptides are generated during protein degradation in the cytoplasm and are then transported into the endoplasmic reticulum by the transporter associated with antigen processing (TAP). Several lines of evidence have indicated that the proteasome is the major proteolytic activity responsible for generation of antigenic peptides--probably most conclusive has been the finding that specific inhibitors of the proteasome block antigen presentation. However, other proteases (e.g. the signal peptidase) may also generate some epitopes, particularly those on certain MHC class I alleles. The proteasome is responsible for generating the precise C termini of many presented peptides, and appears to be the only activity in cells that can make this cleavage. In contrast, aminopeptidases in the cytoplasm and endoplasmic reticulum can trim the N terminus of extended peptides to their proper size. Interestingly, the cellular content of proteases involved in the production and destruction of antigenic peptides is modified by interferon-gamma (IFN-gamma) treatment of cells. IFN-gamma induces the expression of three new proteasome beta subunits that are preferentially incorporated into new proteasomes and alter their pattern of peptidase activities. These changes are likely to enhance the yield of peptides with C termini appropriate for MHC binding and have been shown to enhance the presentation of at least some antigens. IFN-gamma also upregulates leucine aminopeptidase, which should promote the removal of N-terminal flanking residues of antigenic peptides. Also, this cytokine downregulates the expression of a metallo-proteinase, thimet oligopeptidase, that actively destroys many antigenic peptides. Thus, IFN-gamma appears to increase the supply of peptides by stimulating their generation and decreasing their destruction. The specificity and content of these various proteases should determine the amount of peptides available for antigen presentation. Also, the efficiency with which a peptide is presented is determined by the protein's half life (e.g. its ubiquitination rate) and the sequences flanking antigenic peptides, which influence the rates of proteolytic cleavage and destruction.
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PMID:Proteolysis and class I major histocompatibility complex antigen presentation. 1063 36

The human cytomegalovirus US2 gene product targets major histocompatibility class I molecules for degradation in a proteasome-dependent fashion. Degradation requires interaction between the endoplasmic reticulum (ER) lumenal domains of US2 and class I. While ER insertion of US2 is essential for US2 function, US2 lacks a cleavable signal peptide. Radiosequence analysis of glycosylated US2 confirms the presence of the NH(2) terminus predicted on the basis of the amino acid sequence, with no evidence for processing by signal peptidase. Despite the absence of cleavage, the US2 NH(2)-terminal segment constitutes its signal peptide and is sufficient to drive ER translocation of chimeric reporter proteins, again without further cleavage. The putative US2 signal peptide c-region is responsible for the absence of cleavage, despite the presence of a suitable -3,-1 amino acid motif for signal peptidase recognition. In addition, the US2 signal peptide affects the early processing events of the nascent polypeptide, altering the efficiency of ER insertion and subsequent N-linked glycosylation. To our knowledge, US2 is the first example of a membrane protein that does not contain a cleavable signal peptide, yet otherwise behaves like a type I membrane glycoprotein.
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PMID:US2, a human cytomegalovirus-encoded type I membrane protein, contains a non-cleavable amino-terminal signal peptide. 1179 Jul 69

In this study we demonstrate that a disarmed version of the cytotoxin ricin can deliver exogenous CD8(+) T cell epitopes into the MHC class I-restricted pathway by a TAP-independent, signal peptidase-dependent pathway. Defined viral peptide epitopes genetically fused to the N terminus of an attenuated ricin A subunit (RTA) that was reassociated with its partner B subunit were able to reach the early secretory pathway of sensitive cells, including TAP-deficient cells. Successful processing and presentation by MHC class I proteins was not dependent on proteasome activity or on recycling of MHC class I proteins, but rather on a functional secretory pathway. Our results demonstrated a role for signal peptidase in the generation of peptide epitopes associated at the amino terminus of RTA. We showed, first, that potential signal peptide cleavage sites located toward the N terminus of RTA can be posttranslationally cleaved by signal peptidase and, second, that mutation of one of these sites led to a loss of peptide presentation. These results identify a novel MHC class I presentation pathway that exploits the ability of toxins to reach the lumen of the endoplasmic reticulum by retrograde transport, and suggest a role for endoplasmic reticulum signal peptidase in the processing and presentation of MHC class I peptides. Because TAP-negative cells can be sensitized for CTL killing following retrograde transport of toxin-linked peptides, application of these results has direct implications for the development of novel vaccination strategies.
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PMID:Exogenous peptides delivered by ricin require processing by signal peptidase for transporter associated with antigen processing-independent MHC class I-restricted presentation. 1207 34

The nonclassical major histocompatibility complex class I molecule HLA-E acts as a ligand for CD94/NKG2 receptors on the surface of natural killer cells and a subset of T cells. HLA-E presents closely related nonameric peptide epitopes derived from the highly conserved signal sequences of classical major histocompatibility complex class I molecules as well as HLA-G. Their generation requires cleavage of the signal sequence by signal peptidase followed by the intramembrane-cleaving aspartic protease, signal peptide peptidase. In this study, we have assessed the subsequent proteolytic requirements leading to generation of the nonameric HLA-E peptide epitopes. We show that proteasome activity is required for further processing of the peptide generated by signal peptide peptidase. This constitutes the first example of capture of a naturally derived short peptide by the proteasome, producing a class I peptide ligand.
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PMID:Requirement of the proteasome for the trimming of signal peptide-derived epitopes presented by the nonclassical major histocompatibility complex class I molecule HLA-E. 1282 59

P42, encoded by a colinear transcript of Influenza C virus RNA segment 6 (M gene), is an integral membrane protein which is cleaved by signal peptidase to generate M1' and CM2 composed of N-terminal 259 amino acids and C-terminal 115 amino acids, respectively. Herein, the biochemical features of P42 were investigated. N-glycosylated form of P42, designated P44, forms disulphide-linked dimers and tetramers. P44 is transported to the Golgi apparatus, but not to the trans-Golgi, since P44 is completely sensitive to endoglycosidase H. P44 and P42 are unstable irrespective of N-glycosylation or oligomerization. 26S proteasome inhibitor, lactacystin prevented the degradation of P42 as well as M1', but not that of P44 efficiently, suggesting that P44 is degraded by another protease besides the 26S proteasome.
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PMID:Biochemical properties of the P42 protein encoded by RNA segment 6 of influenza C virus. 1474 95

Polypeptide folding and quality control in the endoplasmic reticulum (ER) are mediated by protein chaperones, including calreticulin (CRT). ER localization of CRT is specified by two types of targeting signals, an N-terminal hydrophobic signal sequence that directs insertion into the ER and a C-terminal KDEL sequence that is responsible for retention in the ER. CRT has been implicated in a number of cytoplasmic and nuclear processes, suggesting that there may be a pathway for generating cytosolic CRT. Here we show that CRT is fully inserted into the ER, undergoes processing by signal peptidase, and subsequently undergoes retrotranslocation to the cytoplasm. A transcription-based reporter assay revealed an important role for the C-terminal Ca(2+) binding domain in CRT retrotranslocation. Neither ubiquitylation nor proteasome activity was necessary for retrotranslocation, which indicates that the pathway is different from that used by unfolded proteins targeted for destruction. Forced expression of cytosolic CRT is sufficient to rescue a cell adhesion defect observed in mouse embryo fibroblasts from crt(-/-) mice. The ability of CRT to retrotranslocate from the ER lumen to the cytosol explains how CRT can change compartments and modulate cell adhesion, transcription, and translation.
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PMID:Retrotranslocation of the chaperone calreticulin from the endoplasmic reticulum lumen to the cytosol. 1619 64

Proteins bearing an endoplasmic reticulum (ER) leader are inserted into the ER followed by cleavage of the signal peptide. Major histocompatibility complex class I-restricted T-cell epitopes can be generated from these proteins by the proteasome after retrotranslocation into the cytosol. Here, we show that an HLA-A(*)0201-restricted epitope from prostate stem cell antigen contains the cleavage site of the ER signal peptidase. The resulting cleavage products fail to bind to HLA-A(*)0201 and are not recognized by T lymphocytes. As processing of prostate stem cell antigen by signal peptidase occurs immediately after co-translational insertion, the epitope must be processed from polypeptides that have never reached the ER. The processing of this epitope depends on the proteasome and the transporter associated with antigen processing and shows a novel pathway of class I processing that relies on the failure of ER-targeted proteins to reach their target compartment.
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PMID:A novel cytosolic class I antigen-processing pathway for endoplasmic-reticulum-targeted proteins. 1785 4

Polypeptides are organized into distinct substructures, termed protein domains, that are often associated with diverse functions. These modular units can act as binding sites, areas of post-translational modification, and sites of complex multimerization. The human cytomegalovirus US2 gene product is organized into discrete domains that together catalyze the proteasome-dependent degradation of class I major histocompatibility complex heavy chains. US2 co-opts the endogenous ER quality control pathway in order to dispose of class I. The US2 endoplasmic reticulum (ER)-lumenal region is the class I binding domain, whereas the carboxyl terminus can be referred to as the degradation domain. In the present study, we examined the role of the US2 transmembrane domain in virus-mediated class I degradation. Replacement of the US2 transmembrane domain with that of the CD4 glycoprotein completely blocked the ability of US2 to induce class I destruction. A more precise mutagenesis revealed that subregions of the US2 transmembrane domain differ in their ability to trigger class I degradation. Collectively, the data support a model in which US2-mediated class I degradation occurs as a highly regulated process where the US2 transmembrane domain and cytoplasmic tail work in concert to eliminate class I molecules. Host factors, including a signal peptidase complex, probably associate with the US2 molecule in a coordinated fashion to create a predislocation complex to promote the extraction of class I out of the ER. The results imply that the ER quality control machinery may recognize and eliminate misfolded proteins using a similar multistep regulated process.
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PMID:A bipartite trigger for dislocation directs the proteasomal degradation of an endoplasmic reticulum membrane glycoprotein. 1808 79

N-terminal signal sequences mediate nascent protein targeting to and protein insertion into the membrane of the endoplasmic reticulum. They are typically 15-30 amino acid residues long with a core hydrophobic region flanked by an N-terminal (n-) and a C-terminal region. Following cleavage by signal peptidase, some of the resulting signal peptides are further processed by signal peptide peptidase (SPP) and fragments are liberated into the cytosol. Such fragments can have independent, post-targeting functions affecting diverse cellular processes. We show that Drosophila melanogaster Crumbs, a transmembrane protein controlling cell polarity and morphogenesis, is synthesized with an 83 residues-long signal sequence. To our knowledge, this is currently the longest signal sequence described for an eukaryotic protein. The unusual length is caused by an extended n-region, but the extension does neither affect protein targeting nor signal sequence cleavage. The signal sequence is cleaved off and the resulting signal peptide, SP(Crb), is proteolytically processed by SPP, thus representing the first substrate described for the Drosophila enzyme. We further show that signal peptide fragments can be degraded by the proteasome. Expression of transgenes encoding tagged variants of Crumbs in Drosophila embryos suggests that the signal peptide is short-lived in vivo. Our findings support a model suggesting that besides generating fragments with post-targeting functions, SPP-mediated processing is the first step in the degradation of signal peptides.
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PMID:The Drosophila Crumbs signal peptide is unusually long and is a substrate for signal peptide peptidase. 2018 78

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