Proinflammatory cytokines cause FAT10 upregulation in cancers of liver and colon.

The mRNA of the ubiquitin-like modifier FAT10 has been reported to be overexpressed in 90% of hepatocellular carcinoma (HCC) and in over 80% of colon, ovary and uterus carcinomas. Elevated FAT10 expression in malignancies was attributed to transcriptional upregulation upon the loss of p53. Moreover, FAT10 induced chromosome instability in long-term in vitro culture, which led to the hypothesis that FAT10 might be involved in carcinogenesis. In this study we show that interferon (IFN)-gamma and tumor necrosis factor (TNF)-alpha synergistically upregulated FAT10 expression in liver and colon cancer cells 10- to 100-fold. Real-time RT-PCR revealed that FAT10 mRNA was significantly overexpressed in 37 of 51 (72%) of human HCC samples and in 8 of 15 (53%) of human colon carcinomas. The FAT10 cDNA sequences in HCC samples were not mutated and intact FAT10 protein was detectable. FAT10 expression in both cancer tissues correlated with expression of the IFN-gamma- and TNF-alpha-dependent proteasome subunit LMP2 strongly suggesting that proinflammatory cytokines caused the joint overexpression of FAT10 and LMP2. NIH3T3 transformation assays revealed that FAT10 had no transforming capability. Taken together, FAT10 qualifies as a marker for an interferon response in HCC and colon carcinoma but is not significantly overexpressed in cancers lacking a proinflammatory environment.

Cutting edge: neosynthesis is required for the presentation of a T cell epitope from a long-lived viral protein.

CTLs recognize peptide epitopes which are proteolytically generated by the proteasome and presented on MHC class I molecules. According to the defective ribosomal product (DRiP) hypothesis, epitopes originate from newly synthesized polypeptides which are degraded shortly after their translation. The DRiP hypothesis would explain how epitopes can be generated from long-lived proteins. We examined whether neosynthesis is required for presentation of the immunodominant epitope NP118 of the lymphocytic choriomeningitis virus nucleoprotein, which has a half-life of >3 days. Two days after nucleoprotein biosynthesis was terminated in a tetracycline-regulated transfectant, the presentation of the NP118 epitope ceased. This indicates that NP118 epitopes are generated from newly synthesized nucleoproteins rather than from the long-lived pool of nucleoproteins in the cell. Therefore, the lymphocytic choriomeningitis virus nucleoprotein is the first substrate for which a major prediction of the DRiP hypothesis, namely the requirement for neosynthesis, is shown to hold true.

The ubiquitin-like protein FAT10 forms covalent conjugates and induces apoptosis.

FAT10 is a ubiquitin-like protein that is encoded in the major histocompatibility complex class I locus and is synergistically inducible with interferon-gamma and tumor necrosis factor alpha. The molecule consists of two ubiquitin-like domains in tandem arrangement and bears a conserved diglycine motif at its carboxyl terminus commonly used in ubiquitin-like proteins for isopeptide linkage to conjugated proteins. We investigated the function of FAT10 by expressing murine FAT10 in a hemagglutinin-tagged wild type form as well as a diglycine-deficient mutant form in mouse fibroblasts in a tetracycline-repressible manner. FAT10 expression did not affect major histocompatibility complex class I cell surface expression or antigen presentation. However, we found that wild type but not mutant FAT10 caused apoptosis within 24 h of induction in a caspase-dependent manner as indicated by annexin V cell surface staining and DNA fragmentation. Wild type FAT10, but not its diglycine mutant, was covalently conjugated to thus far unidentified proteins, indicating that specific FAT10 activating and conjugating enzymes must be operative in unstimulated fibroblasts. Because FAT10 expression causes apoptosis and is inducible with tumor necrosis factor alpha, it may be functionally involved in the programmed cell death mediated by this cytokine.

Expression of hepatitis C virus proteins does not interfere with major histocompatibility complex class I processing and presentation in vitro.

Hepatitis C virus (HCV) infection takes a chronic course in the majority of patients. The mechanisms underlying the evasion of the host immune response and viral persistence are poorly understood. In this context, we investigated interactions of HCV proteins with major histocompatibility complex (MHC) class I processing and presentation pathways using cell lines that allow the tetracycline-regulated expression of viral structural and nonstructural proteins. These well-characterized inducible cell lines were found to efficiently process and present endogenously synthesized HCV proteins via MHC class I. Functional MHC class I cell-surface expression and intracellular proteasome activity were not affected by the expression of HCV proteins. These results suggest that viral evasion of the host immune response does not involve interactions of HCV with MHC class I processing and presentation. Other mechanisms, such as interference with the interferon system, may be operative in HCV infection, leading to viral persistence.

Interferon-gamma inducible exchanges of 20S proteasome active site subunits: why?

When cells are stimulated with the cytokines IFN-gamma or TNF-alpha, the synthesis of three proteasome subunits LMP2 (beta1i), LMP7 (beta5i), and MECL-1 (beta2i) is induced. These subunits replace the three subunits delta (beta1), MB1 (beta5), and Z (beta2), which bear the catalytically active sites of the proteasome, during proteasome neosynthesis. The cytokine-induced exchanges of three active site subunits of a complex protease is unprecedented in biology and one may expect a strong functional driving force for this system to evolve. These cytokine-induced replacements of proteasome subunits are believed to favour the production of peptide ligands of major histocompatibility complex (MHC) class I molecules for the stimulation of cytotoxic T cells. Although the peptide production by constitutive proteasomes is able to maintain peptide-dependent MHC class I cell surface expression in the absence of LMP2 and LMP7, these subunits were recently shown to be pivotal for the generation or destruction of several unique epitopes. In this review we discuss the recent data on LMP2/LMP7/MECL-1-dependent epitope generation and the functions of each of these subunit exchanges. We propose that these subunit exchanges have evolved not only to optimize class I peptide loading but also to generate LMP2/LMP7/MECL-1-dependent epitopes in inflammatory sites which are not proteolytically generated in uninflamed tissues. This difference in epitope generation may serve to better stimulate T cells in the sites of an ongoing immune response and to avoid autoimmunity in uninflamed tissues.

Structural plasticity of the proteasome and its function in antigen processing.

The proteasome is the main provider of peptide ligands for major histocompatibility complex class I molecules. During an immune response to pathogens, the proinflammatory cytokine interferon (IFN)-gamma and tumor necrosis factor (TNF)-alpha are released, which induce the proteasome subunits LMP2, LMP7, and MECL-1. These replace the constitutively expressed active site subunits of the proteasome (delta, MB1, and Z) leading to a marked change in the cleavage preference of the proteasome and the production of T-cell epitopes. Proteasome activity is further changed by the IFN-gamma-mediated induction of the proteasome regulator PA28alpha/beta and the downregulation of PA28gamma. Why such an extensive exchange of proteasome active site subunits and regulators occurs is still poorly understood. In this article we discuss recent insights in the structural consequences of proteasome reorganization and their effects on epitope generation and shaping of the cytotoxic immune response. Moreover, we review the latest data on how the ubiquitin pathway targets protein antigens for peptide processing and discuss the potential of proteasome inhibitors for the modulation of antigen presentation.

Overexpression of the proteasome subunits LMP2, LMP7, and MECL-1, but not PA28 alpha/beta, enhances the presentation of an immunodominant lymphocytic choriomeningitis virus T cell epitope.

The proteasome is a large protease complex that generates most of the peptide ligands of MHC class I molecules either in their final form or in the form of N-terminally extended precursors. Upon the stimulation of cells with IFN-gamma, three constitutively expressed subunits of the 20S proteasome are replaced by the inducible subunits LMP2 (low-molecular mass polypeptide 2), LMP7, and MECL-1 (multicatalytic endopeptidase complex-like-1) to form so-called immunoproteasomes. We show in this study that overexpression of these three subunits in triple transfectants led to a marked enhancement in the H-2Ld-restricted presentation of the immunodominant nonameric epitope NP118, which is derived from the nucleoprotein (NP) of lymphocytic choriomeningitis virus. Overexpression of the alpha and beta subunits of the IFN-gamma-inducible proteasome regulator PA28, in contrast, did not have a comparable effect. In vitro, immunoproteasomes as compared with constitutive proteasomes generated higher amounts of 11- and 12-mer fragments containing the NP118 epitope. These are likely to be cytosolic precursors of NP118, as a proline anchor residue in the second position of NP118 may interfere with TAP-mediated transport of the nonameric epitope itself. In conclusion, we provide evidence that up-regulation of the three inducible subunits, LMP2, LMP7, and MECL-1, can result in a marked improvement of Ag presentation and that, depending on the epitope, PA28 and immunoproteasomes may differentially affect Ag processing.

The selective proteasome inhibitors lactacystin and epoxomicin can be used to either up- or down-regulate antigen presentation at nontoxic doses.

The complete inhibition of proteasome activities interferes with the production of most MHC class I peptide ligands as well as with cellular proliferation and survival. In this study we have investigated how partial and selective inhibition of the chymotrypsin-like activity of the proteasome by the proteasome inhibitors lactacystin or epoxomicin would affect Ag presentation. At 0.5-1 microM lactacystin, the presentation of the lymphocytic choriomeningitis virus-derived epitopes NP118 and GP33 and the mouse CMV epitope pp89-168 were reduced and were further diminished in a dose-dependent manner with increasing concentrations. Presentation of the lymphocytic choriomeningitis virus-derived epitope GP276, in contrast, was markedly enhanced at low, but abrogated at higher, concentrations of either lactacystin or epoxomicin. The inhibitor-mediated effects were thus epitope specific and did not correlate with the degradation rates of the involved viral proteins. Although neither apoptosis induction nor interference with cellular proliferation was observed at 0.5-1 microM lactacystin in vivo, this concentration was sufficient to alter the fragmentation of polypeptides by the 20S proteasome in vitro. Our results indicate that partial and selective inhibition of proteasome activity in vivo is a valid approach to modulate Ag presentation, with potential applications for the treatment of autoimmune diseases and the prevention of transplant rejection.

Evidence for the existence of a non-catalytic modifier site of peptide hydrolysis by the 20 S proteasome.

The 20 S proteasome is an endoprotease complex that preferentially cleaves peptides C-terminal of hydrophobic, basic, and acidic residues. Recently, we showed that these specific activities, classified as chymotrypsin-like, trypsin-like, and peptidylglutamyl peptide-hydrolyzing (PGPH) activity, are differently affected by Ritonavir, an inhibitor of human immunodeficiency virus-1 protease. Ritonavir competitively inhibited the chymotrypsin-like activity, whereas the trypsin-like activity was enhanced. Here we demonstrate that the Ritonavir-mediated up-regulation of the trypsin-like activity is not affected by specific active site inhibitors of the chymo-trypsin-like and PGPH activity. Moreover, we show that the mutual regulation of chymotrypsin-like and PGPH activities by their substrates as described previously by a "cyclical bite-chew" model is not affected by selective inhibitors of the respective active sites. These data challenge the bite-chew model and suggest that effectors of proteasome activity can act by binding to non-catalytic sites. Accordingly, we propose a kinetic "two-site modifier" model that assumes that the substrate (or effector) may bind to an active site as well as to a second non-catalytic modifier site. This model appears to be valid as it describes the complex kinetic effects of Ritonavir very well. Since Ritonavir partially inhibits major histocompatibility complex class I restricted antigen presentation, the postulated modifier site may be required to coordinate the active centers of the proteasome for the production of class I peptide ligands.

How an inhibitor of the HIV-I protease modulates proteasome activity.

The human immunodeficiency virus, type I protease inhibitor Ritonavir has been used successfully in AIDS therapy for 4 years. Clinical observations suggested that Ritonavir may exert a direct effect on the immune system unrelated to inhibition of the human immunodeficiency virus, type I protease. In fact, Ritonavir inhibited the major histocompatibility complex class I restricted presentation of several viral antigens at therapeutically relevant concentrations (5 microM). In search of a molecular target we found that Ritonavir inhibited the chymotrypsin-like activity of the proteasome whereas the tryptic activity was enhanced. In this study we kinetically analyzed how Ritonavir modulates proteasome activity and what consequences this has on cellular functions of the proteasome. Ritonavir is a reversible effector of proteasome activity that protected the subunits MB-1 (X) and/or LMP7 from covalent active site modification with the vinyl sulfone inhibitor(125)I-NLVS, suggesting that they are the prime targets for competitive inhibition by Ritonavir. At low concentrations of Ritonavir (5 microM) cells were more sensitive to canavanine but proliferated normally whereas at higher concentrations (50 microM) protein degradation was affected, and the cell cycle was arrested in the G(1)/S phase. Ritonavir thus modulates antigen processing at concentrations at which vital cellular functions of the proteasome are not yet severely impeded. Proteasome modulators may hence qualify as therapeutics for the control of the cytotoxic immune response.

A ubiquitin-like protein which is synergistically inducible by interferon-gamma and tumor necrosis factor-alpha.

A means of regulating the fate of intracellular proteins is their covalent conjugation to ubiquitin-like proteins. A recently discovered ubiquitin-like protein is called "diubiquitin" because it consists of two ubiquitin-like domains in head-to-tail arrangement. Human diubiquitin is encoded at the telomeric end of the MHC class I locus and was previously found to be expressed in dendritic cells and mature B cells. We have extended the expression analysis of diubiquitin by reverse transcriptase-PCR and Northern blotting in primary endothelial cells and human cancer cell lines derived from nine different tissues. Diubiquitin expression was found to be generally and synergistically inducible with the cytokines IFN-gamma and TNF-alpha but not with IFN-alpha. Diubiquitin mRNA expression was induced within 2 h after cytokine stimulation and was independent of protein neosynthesis but dependent on proteasome activity. The mouse homologue of diubiquitin which is also encoded in the MHC class I locus was likewise induced with IFN-gamma and TNF-alpha. A general and synergistic induction with IFN-gamma and TNF-alpha suggests that diubiquitin may exert its functions in antigen presentation or other cellular processes controlled by these two cytokines.

[Intracellular processing of viral and tumor antigens by proteasomes]. / Die intrazelluläre Prozessierung von Virus- und Tumorantigenen durch das Proteasom.

Cytotoxic T cells are able to recognise whether a cell of our body is infected by a virus or whether it has acquired mutations leading to tumour formation. The cells show on their surface what kind of proteins are synthesised intracellularly and whether non-self proteins encoded by a virus or tumour antigens are among them. The proteins are presented not as functionally intact proteins but as peptide fragments which originate from their regular intracellular degradation. This fragmentation is accomplished by the proteasome, a large proteinase complex in the cytoplasm and nucleus of all cells. Upon stimulation with the antiviral cytokine interferon-gamma, subunits of the proteasome are exchanged, thus leading to optimised production of peptide antigens. In this review we introduce the system of antigen processing by the proteasome and sum up our latest results on the question how the interferon-gamma-mediated reorganisation of the proteasome occurs and what consequences and benefits this has for the cytotoxic immune response against viruses and tumours.

Characterization of neutralizing anti-pre-S1 and anti-pre-S2 (HBV) monoclonal antibodies and their fragments.

Single-chain Fv fragments (scFv) were generated from two murine monoclonal antibodies directed to the neutralizing epitopes of the pre-S1 and pre-S2 region of hepatitis B virus, respectively, using different assembly cloning strategies. The scFv fragments were solubly expressed in E. coli. Dissociation constants were in the nanomolar range for all forms (whole IgG antibodies, Fab fragment and scFv fragments). The epitopes of both antibodies were mapped using solid phase peptide synthesis on continuous cellulose membranes and turned out to be linear determinants. The minimal epitope for the anti-pre-S2 antibody 1F6 was identified to be DPRVRGLYF (amino acid 133-141 of the pre-S region). For the anti-pre-S1 antibody MA 18/7 the minimal epitope proved to be the hexamer LDPAFR (amino acid 30-35 of the pre-S region). Complete substitutional analyses as well as truncation experiments revealed key residues for these antibody-antigen interactions. On the basis of those results we used computer-assisted modeling techniques to suggest models for both antibody-peptide interactions providing insight into the structural basis of these molecular recognitions.

Comparative flow cytometric study of clonal excess in leukaemic peripheral blood from patients suffering from chronic lymphocytic leukaemia (B-CLL) by different antibodies, staining techniques and the effects of blood storage.

This investigation studied the effects of cell preparation methods, different antibody panels and blood storage on antigen expression of abnormal B lymphocytes from patients with B-CLL. Blood specimens collected in Heparin de novo were processed by using conventional Hypaque-Ficoll density gradient centrifugation and whole blood lysis. These were stored for 3 days at 4 degrees C, 24 degrees C and 30 degrees C. Although clonal excess was detected by all antibody panels, significant differences could be observed in terms of molecules of equivalent fluorochromes (MEF/MESF units). Evaluation of 'weak and strong' staining is dependent on the antibody panel used. Immunofluorescent values for CD19 and CD45 were unchanged at 4 degrees C and 24 degrees C but immunoglobulin staining showed best results when blood was stored at 4 degrees C. Storage at 30 degrees C produced unreliable results. Abnormal B lymphocytes should be analysed immediately after the specimen is obtained. If shipment is necessary they should be kept at 4 degrees C. Surface immunoglobulins are the 'antigens' most sensitive to storage alterations. Sample alterations alone are sufficient to the correct classification of NHL, especially in the case of low-grade NHL.

Selective proteasome inhibitors: modulators of antigen presentation?

The proteasome is the main nonlysosomal endoprotease in the cytoplasm and nucleus of all eukaryotic cells. It is responsible for the generation of most antigenic peptides as ligands for major histocompatibility complex (MHC) class I proteins. The proteasome hence qualifies as a target for modifying or silencing antigen processing and presentation to cytotoxic T cells, which are important players in transplant rejection and autoimmune disease. The authors summarize recent progress in the understanding of antigen processing by the proteasome and discuss the potential of novel and selective proteasome inhibitors as drugs for suppressing or modifying the cytotoxic immune response.

Inactivation of a defined active site in the mouse 20S proteasome complex enhances major histocompatibility complex class I antigen presentation of a murine cytomegalovirus protein.

Proteasomes generate peptides bound by major histocompatibility complex (MHC) class I molecules. Avoiding proteasome inhibitors, which in most cases do not distinguish between individual active sites within the cell, we used a molecular genetic approach that allowed for the first time the in vivo analysis of defined proteasomal active sites with regard to their significance for antigen processing. Functional elimination of the delta/low molecular weight protein (LMP) 2 sites by substitution with a mutated inactive LMP2 T1A subunit results in reduced cell surface expression of the MHC class I H-2Ld and H-2Dd molecules. Surface levels of H-2Ld and H-2Dd molecules were restored by external loading with peptides. However, as a result of the active site mutation, MHC class I presentation of a 9-mer peptide derived from a protein of murine cytomegalovirus was enhanced about three- to fivefold. Our experiments provide evidence that the delta/LMP2 active site elimination limits the processing and presentation of several peptides, but may be, nonetheless, beneficial for the generation and presentation of others.

Maturation of mammalian 20 S proteasome: purification and characterization of 13 S and 16 S proteasome precursor complexes.

The maturation of the eukaryotic 20 S proteasome complex occurs via 13 S and 16 S precursor complexes in a multistep assembly pathway. These precursor complexes contain alpha-subunits as well as unprocessed beta-subunit proproteins. We have purified and characterized the different proteasome assembly intermediates and analysed their ability to support beta-subunit proprotein processing in vitro. Our data show that 13 S and 16 S proteasome precursor complexes differ not only in size but also in their protein content and behaviour during hydrophobic chromatography. By establishing conditions which allowed us to analyse beta-prosubunit maturation in vitro we demonstrate that the processing of the homologous proproteins of the beta-subunits LMP2 and delta essentially takes place in 16 S precursor complexes. No proprotein processing activity was observed in 13 S precursor complexes. Furthermore, proprotein processing in vitro can be inhibited with a proteasome specific inhibitor, but with different efficiency for LMP2 and delta. A peptide, which represents the sequence of the proprotein processing site HGTT, exhibited no inhibitory effect on the processing of either subunit. These data provide further evidence that proprotein processing occurs via an autocatalytic mechanism. Our experiments also demonstrate that the chaperone protein hsc73 is associated with 16 S but not with 13 S precursor complexes. In support of the specificity of this interaction incubation with ATP leads to the dissociation of hsc73 from 16 S complexes and to the formation of high molecular weight aggregates. Prosubunit processing in isolated 16 S complexes does not, however, result in the formation of proteolytically active 20 S proteasomes which may be due to the fact that not all beta-subunits can be efficiently processed in vitro. In contrast to previous assumptions subunit processing and formation of proteolytic activity do not coincide and final 20 S complex assembly seems to represent in part a separate event which requires additional factors or proteins which are not present or active in the purified 16 S precursor complexes.

Structure and structure formation of the 20S proteasome.

Eukaryotic 20S proteasomes are complex oligomeric proteins. The maturation process of the 14 different alpha- and beta-subunits has to occur in a highly coordinate manner. In addition beta-subunits are synthesized as proproteins and correct processing has to be guaranteed during complex maturation. The structure formation can be subdivided in different phases. The knowledge of the individual phases is summarized in this publication. As a first step the newly synthesized monomers have to adopt the correct tertiary structure, a process that might be supported in the case of the beta-subunits by the intramolecular chaperone activity postulated for the prosequences. Subsequently the alpha-subunits form ring-like structures thereby providing docking sites for the different beta-subunits. The result most likely is a double ring structure (13S precursor) representing half-proteasomes, which contain immature proproteins. Two 13S precursors associate to form the proteolytically inactive 16S assembly intermediate which still contains unprocessed beta-monomers. In addition the chaperone Hsc73 is present within these particles suggesting an essential role during the structure formation process. The processing of monomers with an N-terminal threonine occurs within the 16S particles and is achieved autocatalytically by two subsequent processing events finally leading to the mature, active 20S proteasome.

Analysis of mammalian 20S proteasome biogenesis: the maturation of beta-subunits is an ordered two-step mechanism involving autocatalysis.

Maturation of eukaryotic 20S proteasomes involves the processing of beta-subunits by limited proteolysis. To study the processing mechanism we analysed different point mutations of the beta-subunit LMP2 in transfected human T2 cells. Here we show that the presence of the intact Gly-1Thr1 consensus motif and Lys33 are essential for correct processing. Mutation of Thr1, the active site residue in mature subunits, or of Lys33, results in complete inhibition of processing at the consensus site. In addition, proprotein processing in vitro of wild-type LMP2, incorporated in immature 16S precursor complexes, can be blocked by a proteasome-specific inhibitor. While the processing of inhibitor-treated wild-type proprotein was completely prevented, the site-directed mutagenesis of LMP2 results in processing intermediates carrying an extension of 8-10 residues preceding Thr1, suggesting an additional cleavage event within the prosequence. Furthermore, exchange of mammalian prosequences interferes with processing efficiency and suggests subunit specificity. Based on our data we propose a model for self-activation of proteasomal beta-subunits in which residue Thr1 serves as nucleophile and Lys33 as proton donor/acceptor. We provide evidence that subunit processing of mammalian beta-subunits proceeds via a novel ordered two-step mechanism involving autocatalysis.

Proteasome alpha-type subunit C9 is a primary target of autoantibodies in sera of patients with myositis and systemic lupus erythematosus.

Autoantibodies occur in low frequencies among patients with myositis characterizing only distinct subsets of this disease. Most of these known antibodies are directed to enzymatically active complexes. The 20S proteasome represents an essential cytoplasmatic protein complex for intracellular nonlysosomal protein degradation, and is involved in major histocompatibility complex class I restricted antigen processing. In this study we investigated whether the 20S proteasome complex is an antibody target in myositis and in other autoimmune diseases. 34 sera of poly/dermatomyositis patients were assayed for antiproteasomal antibodies using enzyme-linked immunosorbent assay, immunoblot, and two-dimensional non-equilibrium pH gradient electrophoresis (NEPHGE). Sera was from patients with systemic lupus erythematosus (SLE), mixed connective tissue disease, and rheumatoid arthritis; healthy volunteers served as controls. In 62% (21/34) of the cases sera from patients with myositis and in 58% (30/52) of the cases sera from patients with SLE reacted with the 20S proteasome. These frequencies exceeded those of sera from patients with mixed connective tissue disease, rheumatoid arthritis, and healthy controls. The alpha-type subunit C9 of the 20S proteasome was determined to be the predominant target of the autoimmune sera in myositis and SLE. Lacking other frequent autoantibodies in myositis, the antiproteasome antibodies are the most common humoral immune response so far detected in this disease entity.