31 research outputs found
The role of the proteasome in the generation of MHC class I ligands and immune responses
The ubiquitin–proteasome system (UPS) degrades intracellular proteins into peptide fragments that can be presented by major histocompatibility complex (MHC) class I molecules. While the UPS is functional in all mammalian cells, its subunit composition differs depending on cell type and stimuli received. Thus, cells of the hematopoietic lineage and cells exposed to (pro)inflammatory cytokines express three proteasome immunosubunits, which form the catalytic centers of immunoproteasomes, and the proteasome activator PA28. Cortical thymic epithelial cells express a thymus-specific proteasome subunit that induces the assembly of thymoproteasomes. We here review new developments regarding the role of these different proteasome components in MHC class I antigen processing, T cell repertoire selection and CD8 T cell responses. We further discuss recently discovered functions of proteasomes in peptide splicing, lymphocyte survival and the regulation of cytokine production and inflammatory responses
Immunoproteasome LMP2 60HH Variant Alters MBP Epitope Generation and Reduces the Risk to Develop Multiple Sclerosis in Italian Female Population
Background: Albeit several studies pointed out the pivotal role that CD4+T cells have in Multiple Sclerosis, the CD8+ T cells
involvement in the pathology is still in its early phases of investigation. Proteasome degradation is the key step in the
production of MHC class I-restricted epitopes and therefore its activity could be an important element in the activation and
regulation of autoreactive CD8+ T cells in Multiple Sclerosis.
Methodology/Principal Findings: Immunoproteasomes and PA28-ab regulator are present in MS affected brain area and
accumulated in plaques. They are expressed in cell types supposed to be involved in MS development such as neurons,
endothelial cells, oligodendrocytes, macrophages/macroglia and lymphocytes. Furthermore, in a genetic study on 1262
Italian MS cases and 845 controls we observed that HLA-A*02+ female subjects carrying the immunoproteasome LMP2
codon 60HH variant have a reduced risk to develop MS. Accordingly, immunoproteasomes carrying the LMP2 60H allele
produce in vitro a lower amount of the HLA-A*0201 restricted immunodominant epitope MBP111\u2013119.
Conclusion/Significance: The immunoproteasome LMP2 60HH variant reduces the risk to develop MS amongst Italian HLAA*
02+ females. We propose that such an effect is mediated by the altered proteasome-dependent production of a specific
MBP epitope presented on the MHC class I. Our observations thereby support the hypothesis of an involvement of
immunoproteasome in the MS pathogenesis
CTL Escape Mediated by Proteasomal Destruction of an HIV-1 Cryptic Epitope
Cytotoxic CD8+ T cells (CTLs) play a critical role in controlling viral
infections. HIV-infected individuals develop CTL responses against epitopes
derived from viral proteins, but also against cryptic epitopes encoded by viral
alternative reading frames (ARF). We studied here the mechanisms of HIV-1 escape
from CTLs targeting one such cryptic epitope, Q9VF, encoded by an
HIVgag ARF and presented by HLA-B*07. Using PBMCs of
HIV-infected patients, we first cloned and sequenced proviral DNA encoding for
Q9VF. We identified several polymorphisms with a minority of proviruses encoding
at position 5 an aspartic acid (Q9VF/5D) and a majority encoding an asparagine
(Q9VF/5N). We compared the prevalence of each variant in PBMCs of
HLA-B*07+ and HLA-B*07- patients. Proviruses encoding Q9VF/5D were
significantly less represented in HLA-B*07+ than in HLA-B*07-
patients, suggesting that Q9FV/5D encoding viruses might be under selective
pressure in HLA-B*07+ individuals. We thus analyzed ex
vivo CTL responses directed against Q9VF/5D and Q9VF/5N. Around
16% of HLA-B*07+ patients exhibited CTL responses targeting Q9VF
epitopes. The frequency and the magnitude of CTL responses induced with Q9VF/5D
or Q9VF/5N peptides were almost equal indicating a possible cross-reactivity of
the same CTLs on the two peptides. We then dissected the cellular mechanisms
involved in the presentation of Q9VF variants. As expected, cells infected with
HIV strains encoding for Q9VF/5D were recognized by Q9VF/5D-specific CTLs. In
contrast, Q9VF/5N-encoding strains were neither recognized by Q9VF/5N- nor by
Q9VF/5D-specific CTLs. Using in vitro proteasomal digestions
and MS/MS analysis, we demonstrate that the 5N variation introduces a strong
proteasomal cleavage site within the epitope, leading to a dramatic reduction of
Q9VF epitope production. Our results strongly suggest that HIV-1 escapes CTL
surveillance by introducing mutations leading to HIV ARF-epitope destruction by
proteasomes
Impairment of Immunoproteasome Function by β5i/LMP7 Subunit Deficiency Results in Severe Enterovirus Myocarditis
Proteasomes recognize and degrade poly-ubiquitinylated proteins. In infectious disease, cells activated by interferons (IFNs) express three unique catalytic subunits β1i/LMP2, β2i/MECL-1 and β5i/LMP7 forming an alternative proteasome isoform, the immunoproteasome (IP). The in vivo function of IPs in pathogen-induced inflammation is still a matter of controversy. IPs were mainly associated with MHC class I antigen processing. However, recent findings pointed to a more general function of IPs in response to cytokine stress. Here, we report on the role of IPs in acute coxsackievirus B3 (CVB3) myocarditis reflecting one of the most common viral disease entities among young people. Despite identical viral load in both control and IP-deficient mice, IP-deficiency was associated with severe acute heart muscle injury reflected by large foci of inflammatory lesions and severe myocardial tissue damage. Exacerbation of acute heart muscle injury in this host was ascribed to disequilibrium in protein homeostasis in viral heart disease as indicated by the detection of increased proteotoxic stress in cytokine-challenged cardiomyocytes and inflammatory cells from IP-deficient mice. In fact, due to IP-dependent removal of poly-ubiquitinylated protein aggregates in the injured myocardium IPs protected CVB3-challenged mice from oxidant-protein damage. Impaired NFκB activation in IP-deficient cardiomyocytes and inflammatory cells and proteotoxic stress in combination with severe inflammation in CVB3-challenged hearts from IP-deficient mice potentiated apoptotic cell death in this host, thus exacerbating acute tissue damage. Adoptive T cell transfer studies in IP-deficient mice are in agreement with data pointing towards an effective CD8 T cell immune. This study therefore demonstrates that IP formation primarily protects the target organ of CVB3 infection from excessive inflammatory tissue damage in a virus-induced proinflammatory cytokine milieu
20S proteasome from LMP7 knock out mice reveals altered proteolytic activities and cleavage site preferences
Immunoproteasome subunit LMP2 expression is deregulated in Sjögren's syndrome but not in other autoimmune disorders
BACKGROUND: The proteasome system has a pivotal role in the control of the immune response, which suggests that it might be involved in the pathogenesis of autoimmune disorders. OBJECTIVE: To investigate the expression profile of selected proteasomal genes in human peripheral blood mononuclear cells in patients with a variety of autoimmune diseases compared with healthy subjects. METHODS: Real time quantitative RT‐PCR was used to analyse the mRNA expression pattern of the proteasome activator subunits PA28α and PA28β and of constitutive proteasome and interferon‐γ‐inducible immunoproteasome subunits in peripheral blood mononuclear cells. Simultaneously, protein expression of selected proteasome subunits was quantified by immunoblotting. RESULTS: Under systemic inflammatory conditions the proteasome subunits LMP2 (β1i), LMP7 (β5i), MECL1 (β2i), and PA28α were expressed abundantly at the protein level in the vast majority of systemic autoimmune disorders. However, simultaneous mRNA and protein quantification showed a characteristic proteasome expression signature in primary Sjögren's syndrome. At the transcript level, the interferon‐γ‐responsive subunits LMP2 (β1i), MECL1 (β2i), and the proteasome activator subunit PA28α were markedly up regulated. In contrast, LMP2 (β1i) deficiency was evident at the protein level, indicating deregulation of proteasome expression in Sjögren's syndrome. CONCLUSIONS: These data provide evidence for a regulatory defect in the proteasome system in human autoimmune disorders, pointing to a unique role for LMP2 (β1i) in the pathogenesis of primary Sjögren's syndrome