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 multisubunit enzyme complexes that reside in the cytoplasm and nucleus of eukaryotic cells. By selective protein degradation, proteasomes regulate many cellular processes including MHC class I antigen processing. Three constitutively expressed catalytic subunits are responsible for proteasome mediated proteolysis. These subunits are exchanged for three homologous subunits, the immunosubunits, in IFNgamma-exposed cells and in cells with specialized antigen presenting function. Both constitutive and immunoproteasomes degrade endogenous proteins into small peptide fragments that can bind to MHC class I molecules for presentation on the cell surface to cytotoxic T lymphocytes. However, immunoproteasomes seem to fulfill this function more efficiently. IFNgamma further induces the expression of a proteasome activator, PA28, which can also enhance antigenic peptide production by proteasomes. In this review, we will introduce the ubiquitin-proteasome system and summarize recent findings regarding the role of the IFNgamma-inducible proteasome subunits and proteasome regulators in antigen processing. We review the different ways by which tumors and viruses have been found to target the proteasome system to avoid MHC class I presentation of their antigens, and discuss recent progressions in the development of computer assisted approaches to predict CTL epitopes within larger protein sequences, based on proteasome cleavage specificity. The availability of such programs as well as a general insight into the proteasome mediated steps in MHC class I antigen processing provides us with a rational basis for the design of new antiviral and anticancer T cell vaccines.
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PMID:The role of the ubiquitin-proteasome pathway in MHC class I antigen processing: implications for vaccine design. 1189 55

Over the past decade there has been considerable progress in understanding how MHC class I-presented peptides are generated. The emerging theme is that the immune system has not evolved its own specialized proteolytic mechanisms but instead utilizes the phylogenetically ancient catabolic pathways that continually turnover proteins in all cells. Three distinct proteolytic steps have now been defined in MHC class I antigen presentation. The first step is the degradation of proteins by the ubiquitin-proteasome pathway into oligopeptides that either are of the correct size for presentation or are extended on their amino-termini. In the second step, aminopeptidases trim N-extended precursors into peptides of the correct length to be presented on class I molecules. The third step involves the destruction of peptides by endo- and exopeptidases, which limits antigen presentation, but is important for preventing the accumulation of peptides and recycling them back to amino acids for protein synthesis or production of energy. The immune system has evolved several components that modify the activity of these ancient pathways in ways that enhance the generation of class I-presented peptides. These include catalytically active subunits of the proteasome, the PA28 proteasome activator, and leucine aminopeptidase, all of which are upregulated by interferon-gamma. In addition to these pathways that operate in all cells, dendritic cells and macrophages can also generate class I-presented peptides from proteins internalized from the extracellular fluids by degrading them in endocytic compartments or transferring them to the cyotosol for degradation by proteasomes.
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PMID:Protein degradation and the generation of MHC class I-presented peptides. 1207 79

The proteasome is now recognized to be implicated in the generation of the vast majority of MHC class I ligands. Moreover, it is probably the only cytosolic protease generating their carboxyterminals. However, solid evidence documents a role of additional and only partly identified proteases in MHC class I antigen processing. Cytosolic tripeptidyl peptidase (TTP II) may be able to carry out some functions normally ascribed to the proteasome, including that of generating antigenic peptides. Several cytosolic enzymes, including bleomycin hydrolase (BH) and puromycin-sensitive aminopeptidase (PSA), but especially the IFNgamma-inducible leucyl aminopeptidase (LAP), can trim the aminoterminal ends of class I ligands. The vast majority of cytosolic peptides is degraded, a process likely to limit antigen presentation, in which thimet oligopeptidase (TOP) may play an important role. Proteolytic activity in the secretory pathway, though much more limited than in the cytosol, also contributes to class I antigen presentation. Signal peptide fragments and peptides at the carboxyterminal end of various proteins targeted to the endoplasmic reticulum can be highly efficient TAP-independent class I ligands. However, an as yet unidentified luminal trimming aminopeptidase may eventually turn out to play the most important role for class I ligand generation in the secretory pathway. Defining the extent of the involvement of cytosolic and luminal peptidases in class I antigen processing will be a challenging task for the future.
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PMID:Beyond the proteasome: trimming, degradation and generation of MHC class I ligands by auxiliary proteases. 1220 51

Regulation of the proteasome system, which is responsible for the generation of most MHC class I-bound peptides, occurs through the interaction of the 20S proteasome with several regulatory proteins. One of these is PI31, which acts in vitro as an inhibitor of proteasome activity. Here, we demonstrate that, rather than inhibiting proteasome function, PI31 acts as a selective modulator of the proteasome-mediated steps in MHC class I antigen processing. Overexpression of PI31 in mouse embryonic cells has no impact on proteasome-mediated proteolysis. Instead, PI31, which localizes at the nuclear envelope/endoplasmic reticulum membrane, selectively interferes with the maturation of immunoproteasome precursor complexes. Consequently, overexpression of PI31 abrogates MHC class I presentation of an immunoproteasome-dependent cytotoxic T lymphocyte epitope and reduces the surface MHC class I levels on IFN-gamma-treated mouse embryonic cells. Thus, PI31 represents a cellular regulator of proteasome formation and of proteasome-mediated antigen processing.
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PMID:PI31 is a modulator of proteasome formation and antigen processing. 1237 61

Because of its amplification and/or overexpression in many human tumors, the HER-2/neu proto-oncogene represents an attractive target for T-cell-mediated vaccination strategies. However, overexpression of oncogenes is often associated with defective expression of components of the MHC class I antigen-processing machinery (APM), thereby resulting in an immune escape phenotype of oncogene-transformed cells. To determine whether HER-2/neu influences the MHC class I antigen-processing pathway, the expression pattern of different APM components was examined in murine in vitro models of constitutive and tetracycline-controlled HER-2/neu expression. In comparison with HER-2/neu(-) control cells, HER-2/neu(+) fibroblasts exhibit reduced levels of MHC class I surface antigens that were associated with impaired expression and/or function of the peptide transporter associated with antigen processing, the proteasome subunits low molecular weight protein 2 and low molecular weight protein 10, the proteasome activators PA28alpha and PA28beta, and tapasin. These APM abnormalities resulted in reduced sensitivity to lysis by CTLs. The HER-2/neu-mediated immune escape phenotype could be corrected by IFN-gamma treatment. The clinical relevance of this finding was supported by an inverse correlation between HER-2/neu and the peptide transporter associated with antigen-processing protein expression as determined by immunhistochemical analysis of a series of HER-2/neu(-) and HER-2/neu(+) breast cancer specimens. Thus, a functional link between deficient APM component expression and HER-2/neu overexpression is proposed that might influence the design of HER-2/neu-targeted T-cell-based immunotherapeutic strategies.
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PMID:HER-2/neu-mediated regulation of components of the MHC class I antigen-processing pathway. 1472 27

The initiation of most cytotoxic immune responses requires MHC class I-restricted presentation of internalized antigens to CD8(+) T lymphocytes, a process called cross-presentation. In dendritic cells (DC), the only antigen-presenting cells that activate naive T cells, cross-presentation is particularly efficient after internalization of opsonized antigens or immune complexes, which are cross-presented through a proteasome- and transporter associated with antigen processing (TAP)-dependent MHC class I antigen presentation pathway. We now show that FcgammaR-mediated cross-presentation is tightly regulated during DC maturation. Cross-presentation increases soon after activation by lipopolysaccharides, and it is then inhibited in fully mature cells. The initial induction of cross-presentation results from an increase of both antigen internalization and delivery to the cytosol, and from a slight rise in the activity of the proteasome and TAP. The subsequent block of cross-presentation in mature DC is a consequence of the selective down-modulation of antigen internalization and cytosolic delivery, while proteasome and TAP activities continue to rise. Therefore, FcgammaR-mediated cross-presentation is regulated during DC maturation by the selective control of antigen internalization and transport to the cytosol.
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PMID:Control of cross-presentation during dendritic cell maturation. 1476 44

The Epstein-Barr virus (EBV)-encoded nuclear antigen 1 (EBNA1) is expressed in all EBV-associated tumors, making it an important target for immunotherapy. However, evidence for major histocompatibility complex (MHC) class I-restricted EBNA1 peptides endogenously presented by EBV-transformed B and tumor cells remains elusive. Here we describe for the first time the identification of an endogenously processed human histocompatibility leukocyte antigen (HLA)-B8-restricted EBNA1 peptide that is recognized by CD8+ T cells. T cell recognition could be inhibited by the treatment of target cells with proteasome inhibitors that block the MHC class I antigen processing pathway, but not by an inhibitor (chloroquine) of MHC class II antigen processing. We also demonstrate that new protein synthesis is required for the generation of the HLA-B8 epitope for T cell recognition, suggesting that defective ribosomal products (DRiPs) are the major source of T cell epitopes. Experiments with protease inhibitors indicate that some serine proteases may participate in the degradation of EBNA1 DRiPs before they are further processed by proteasomes. These findings not only provide the first evidence of the presentation of an MHC class I-restricted EBNA1 epitope to CD8+ T cells, but also offer new insight into the molecular mechanisms involved in the processing and presentation of EBNA1.
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PMID:Evidence for the presentation of major histocompatibility complex class I-restricted Epstein-Barr virus nuclear antigen 1 peptides to CD8+ T lymphocytes. 1476 50

The promyelocytic leukemia (PML) protein is the product of the PML gene that fuses with the retinoic acid receptor-alpha (RARalpha) gene in acute promyelocytic leukemia (APL) and produces disruption of PML bodies. Wild-type PML localizes in the nucleus with a typical speckled pattern. PML bodies accumulate several proteins involved in multiple cellular pathways such as apoptosis, transcriptional regulation, and proteasomal degradation of ubiquitinated proteins. The ubiquitin-proteasome pathway at PML bodies is dependent on proteasome component recruitment. Proteasome components such as low-molecular weight proteins (LMPs) are frequently downregulated in different tumor tissues that present impaired major histocompatibility complex (MHC) class I expression. We have recently documented LMP7 downregulation in colorectal tumors with total loss of MHC class I antigen. An immunohistochemical study of PML protein in these tumors revealed a disrupted pattern of PML bodies in a nuclear diffuse form, as observed in APL cells. Therefore, the disruption of the PML bodies was clearly associated with LMP7 downregulation.
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PMID:Promyelocytic leukemia (PML) nuclear bodies are disorganized in colorectal tumors with total loss of major histocompatibility complex class I expression and LMP7 downregulation. 1510 75

The proteasome is the major protease for intracellular protein degradation. The influx rate of protein substrates and the exit rate of the fragments/products are regulated by the size of the axial channels. Opening the channels is known to increase the overall degradation rate and to change the length distribution of fragments. We develop a mathematical model with a flux that depends on the gate size and a phenomenological cleavage mechanism. The model has Michaelis-Menten kinetics with a V(max) that is inversely related to the length of the substrate, as observed in the in vitro experiments. We study the distribution of fragment lengths assuming that proteasomal cleavage takes place at a preferred distance from the ends of a protein fragment, and find multipeaked fragment length distributions similar to those found experimentally. Opening the gates in the model increases the degradation rate, increases the average length of the fragments, and increases the peak in the distribution around a length of 8-10 amino acids. This behavior is also observed in immunoproteasomes equipped with PA28. Finally, we study the effect of re-entry of processed fragments in the degradation kinetics and conclude that re-entry is only expected to affect the cleavage dynamics when short fragments enter the proteasome much faster than the original substrate. In summary, the model proposed in this study captures the known characteristics of proteasomal degradation, and can therefore help to quantify MHC class I antigen processing and presentation.
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PMID:A mathematical model of protein degradation by the proteasome. 1566 21

Rational design of epitope-driven vaccines is a key goal of immunoinformatics. Typically, candidate selection relies on the prediction of MHC-peptide binding only, as this is known to be the most selective step in the MHC class I antigen processing pathway. However, proteasomal cleavage and transport by the transporter associated with antigen processing (TAP) are essential steps in antigen processing as well. While prediction methods exist for the individual steps, no method has yet offered an integrated prediction of all three major processing events. Here we present WAPP, a method combining prediction of proteasomal cleavage, TAP transport, and MHC binding into a single prediction system. The proteasomal cleavage site prediction employs a new matrix-based method that is based on experimentally verified proteasomal cleavage sites. Support vector regression is used for predicting peptides transported by TAP. MHC binding is the last step in the antigen processing pathway and was predicted using a support vector machine method, SVMHC. The individual methods are combined in a filtering approach mimicking the natural processing pathway. WAPP thus predicts peptides that are cleaved by the proteasome at the C terminus, transported by TAP, and show significant affinity to MHC class I molecules. This results in a decrease in false positive rates compared to MHC binding prediction alone. Compared to prediction of MHC binding only, we report an increased overall accuracy and a lower rate of false positive predictions for the HLA-A*0201, HLA-B*2705, HLA-A*01, and HLA-A*03 alleles using WAPP. The method is available online through our prediction server at http://www-bs.informatik.uni-tuebingen.de/WAPP
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PMID:Integrated modeling of the major events in the MHC class I antigen processing pathway. 1598 83

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