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      Die Rolle von Proteasomen in der Antigenpräsentation in der Coxsackievirus B3 induzierten akuten und chronischen Myokarditis

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          Abstract

          Der Großteil MHC Klasse I restringierter Epitope wird bei der Proteindegradation durch das Ubiquitin Proteasom System (UPS) generiert. In der vorliegenden Arbeit wurde die Rolle des UPS in der Antigenpräsenation in einer Coxsackievirus B3 (CVB3) induzierten akuten und chronischen Myokarditis untersucht. Für in vitro Degradationsexperimente mit isolierten 20S Proteasomen wurden CVB3 Polypeptide synthetisiert und die Degradationsprodukte massenspektrometrisch analysiert. Eine erhöhte Substratumsatzrate und eine Verschiebung von Schnittpräferenzen durch Immunoproteasomen oder unter dem Einfluss von PA28 führten zu einer verbesserten Generierung immunrelevanter CVB3 Fragmente. Inflammatorische Kardiomyopathien können in Mäusen durch eine CVB3 Infektion ausgelöst werden. Resistente Stämme (C57BL/6) eliminieren das Virus vollständig, in anfälligen Mäusen (A.BY/SnJ) erfolgt keine vollständige Elimination. In Herzen gesunder Mäuse werden vorwiegend konstitutive 20S Proteasomen exprimiert. Eine myokardiale Entzündung, ausgelöst durch eine CVB3 Infektion, führte in den Herzen beider Mausstämme zu der Bildung von Immunoproteasomen, was zu einer gesteigerten Generierung immunrelevanter CVB3 Fragmente führte. Die größte Menge immunrelevanter Fragmente wurden durch Proteasomen gebildet, die am Tag vier aus den Herzen akut erkrankender C57BL/6 Mäuse und am Tag acht aus chronisch erkrankenden A.BY/SnJ Mäusen isoliert wurden. Dies korrelierte mit der Inkorporation von Immunountereinheiten in de novo assemblierende Proteasomen und einer unterschiedlichen Interferon (IFN) Typ I Kinetik. In Geweben lymphatischen Ursprungs hingegen waren Zusammensetzung und proteolytische Aktivität der Proteasomen im Verlauf der Infektion in beiden Mausstämmen unverändert. Die vorliegende Arbeit unterstreicht die Bedeutung einer zeitlich optimalen IFN Sekretion an der Infektionsstelle, die zu der Anpassung des UPS an die inflammatorischen Bedingungen führt.

          Abstract

          The recognition of viral antigens bound to major histocompatibility complex (MHC) class I molecules by CD8+ T cells is crucial for virus elimination. Most MHC class I restricted antigenic peptides are produced by the Ubiquitin Proteasome System (UPS). In the present study, the impact of the UPS in antigen presentation during Coxsackievirus B3 (CVB3) induced acute and chronic myocarditis has been investigated. To examine whether the proteasome is involved in the generation of MHC class I ligands derived from the CVB3 polyprotein, polypeptides were synthesized for in vitro processing by 20S proteasomes. Mass spectrometry analysis demonstrated an enhanced generation of immunorelevant CVB3 fragments due to an increased substrate degradation rate and altered cleavage site preferences by immunoproteasomes or in the presence of PA28. Murine models of CVB3 induced myocarditis mimic human disease pattern with diverse outcomes. Permissive mice (A.BY/SnJ) develop chronic myocarditis with cardiac CVB3 persistence whereas resistant mice (C57BL/6) recover and eliminate the virus after acute infection. Constitutive 20S proteasomes are mainly expressed in hearts of healthy mice. Myocardial inflammation, caused by a CVB3 infection, resulted in immunoproteasome formation in hearts of both, resistant C57BL/6 and susceptible A.BY/SnJ mice, and was correlated with enhanced generation of immunorelevant CVB3 peptides. In concurrence with distinctive type I interferon kinetics, immunoproteasome formation and improved epitope generation peaked on day 4 post infection in resistant mice, and was delayed in susceptible mice. No alterations were observed in assembly and proteolytic activity of 20S proteasomes in lymphatic tissues during CVB3 infection, independent from mouse strain. The results emphasise the impact of a rapid adjustment of the UPS to viral infection due to early secretion of type I interferon at site of infection.

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          Most cited references8

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          Structure of 20S proteasome from yeast at 2.4 A resolution.

          The crystal structure of the 20S proteasome from the yeast Saccharomyces cerevisiae shows that its 28 protein subunits are arranged as an (alpha1...alpha7, beta1...beta7)2 complex in four stacked rings and occupy unique locations. The interior of the particle, which harbours the active sites, is only accessible by some very narrow side entrances. The beta-type subunits are synthesized as proproteins before being proteolytically processed for assembly into the particle. The proforms of three of the seven different beta-type subunits, beta1/PRE3, beta2/PUP1 and beta5/PRE2, are cleaved between the threonine at position 1 and the last glycine of the pro-sequence, with release of the active-site residue Thr 1. These three beta-type subunits have inhibitor-binding sites, indicating that PRE2 has a chymotrypsin-like and a trypsin-like activity and that PRE3 has peptidylglutamyl peptide hydrolytic specificity. Other beta-type subunits are processed to an intermediate form, indicating that an additional nonspecific endopeptidase activity may exist which is important for peptide hydrolysis and for the generation of ligands for class I molecules of the major histocompatibility complex.
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            Myocarditis.

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              Gamma-interferon and expression of MHC genes regulate peptide hydrolysis by proteasomes.

              The presentation of intracellular proteins to the immune system requires their degradation to small peptides that then become associated with major histocompatibility complex (MHC) class I molecules. The generation of these peptides may involve the 20S or 26S proteasome particles, which contain multiple proteolytic activities including distinct sites that preferentially cleave small peptides on the carboxyl side of hydrophobic, basic or acidic residues. Degradation of most cell proteins requires their conjugation to ubiquitin before hydrolysis by the 26S proteasome. This large complex contains the 20S proteasome as its proteolytic core. This ubiquitin-dependent proteolytic pathway is implicated in MHC class I presentation. gamma-Interferon (gamma-IFN), a stimulator of antigen presentation, induces a subclass of proteasomes that contain two MHC-encoded subunits, LMP2 and 7 (refs 5-10). Here we show that gamma-interferon alters the peptidase activities of the 20S and 26S proteasomes without affecting the rates of breakdown of proteins or of ubiquitinated proteins. By enhancing the expression of MHC genes, gamma-IFN increases the proteasomes' capacity to cleave small peptides after hydrophobic and basic residues but reduces cleavage after acidic residues. Moreover, proteasomes of mutants lacking LMP subunits show decreased rates of cleavage after hydrophobic and basic residues. Thus, gamma-IFN and expression of these MHC genes should favour the production by proteasomes of the types of peptides found on MHC class I molecules, which terminate almost exclusively with hydrophobic or basic residues.
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                Author and article information

                Journal
                Mathematisch-Naturwissenschaftliche Fakultät I, Humboldt-Universität (kvv )
                1 November 2010
                Article
                oai:HUBerlin.de:37239
                319684af-eca5-4abc-86e9-b781ef108406
                History

                Biologie,Antigenprozessierung,antigen processing,Biowissenschaften, Biologie,PA28,Myokarditis,myocarditis,YC 7500,20S Proteasom,Coxsackievirus B3,dilatative Kardiomyopathie,20S proteasome,dilatative cardiomyopathy

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