Studien zur physiologischen Funktion löslicher Zytokinrezeptoren und zur Wirkungsweise viral kodierter Zytokine

Interleukin-6 (IL-6) aktiviert Zielzellen durch Bindung an den Interleukin-6-Rezeptor (IL-6R) und anschließende Homodimerisierung von gp130. IL-6 alleine kann nur Zellen aktivieren, die IL-6R exprimieren, der Komplex aus IL-6 und löslichem IL-6R (sIL-6R) kann gp130 auf Zellen aktivieren, die keinen IL-6R exprimieren. Von gp130 gibt es eine lösliche Form (sgp130), die in Komplexen mit sIL-6R und IL-6 vorliegen kann.Es wurden rekombinante Versionen von sgp130 konstruiert, exprimiert und aufgereinigt. Die sgp130 Proteine inhibieren die sIL-6R-abhängige Stimulation von Zellen, nicht jedoch über membrangebundenen IL-6R vermittelte IL-6-Aktivitäten. sgp130 inhibiert also selektiv sIL-6R-abhängige Antworten und hat keinen Einfluß auf IL-6-Antworten über membrangebundenen IL-6R.Das Genom von Humanem Herpesvirus-8 kodiert für ein virales IL-6 (vIL-6). Um zu klären, ob vIL-6 direkt an IL-6R oder gp130 bindet, wurden Immunpräzipitationen mit radioaktiv markiertem vIL-6 durchgeführt. Dabei zeigte vIL-6 eine direkte Interaktion mit gp130, nicht jedoch mit IL-6R.Die biologische Aktivität von vIL-6 ist IL-6R-unabhängig. Es gibt keinen Unterschied in der Effektivität von vIL-6 bei der Stimulation von Zellen die nur gp130 oder gp130 und IL-6R exprimieren. Die Ergebnisse demonstrieren, daß vIL-6 das erste bekannte Zytokin ist, welches direkt gp130 binden und aktivieren kann.

Evaluation of a viral vector system, based on a defective interfering RNA of tomato bushy stunt virus, for protein expression and the induction of gene silencing

A viral vector system was developed based on a DI-RNA, a sub-viral particle derived from TBSV-BS3-statice. This newly designed vector system was tested for its applicability in protein expression and induction of gene silencing. Two strategies were pursued. The first strategy was replication of the DI-RNA by a transgenically expressed TBSV replicase and the second was the replication by a so called helper virus. It could be demonstrated by northern blot analysis that the replicase, expressed by the transgenic N. benthamiana plant line TR4 or supplied by the helper virus, is able to replicate DI-RNA introduced into the plant cells. Various genes were inserted into different DI constructs in order to study the vector system with regard to protein expression. However, independent of how the replicase was provided no detectable amounts of protein were produced in the plants. Possible reasons for this failure are identified: the lack of systemic movement of the DI-RNA in the transgenic TR4 plants and the occurrence of deletions in the inserted genes in both systems. As a consequence the two strategies were considered unsuitable for protein expression. The DI-RNA vector system was able to induce silencing of transgenes as well as endogenous genes. Several different p19 deficient helper virus constructs were made to evaluate their silencing efficiency in combination with our DI-RNA constructs. However, it was found that our vector system can not compete with other existing VIGS (virus induced gene silencing) systems in this field. Finally, the influence of DI sequences on mRNA stability on transient GUS expression experiments in GUS silenced plants was evaluated. The GUS reporter gene system was found to be unsuitable for distinguishing between expression levels of wild type plants and GUS silenced transgenic plants. The results indicate a positive effect of the DI sequences on the level of protein expression and therefore further research into this area is recommended.

Gene therapy for a novel mouse model of Canavan disease

Canavan disease (CD) is a rare leukodystrophy caused by loss-of-function mutations in the gene encoding aspartoacylase (ASPA), an oligodendrocyte-enriched enzyme. It is characterised by the accumulation of the ASPA substrate N-acetylaspartate (NAA) in brain, blood and urine, leading to a spongiform vacuolisation of the brain, severe motoric and cognitive impairments and premature death. To date, no therapy is available due to the lack of a gene-transfer system allowing transgene expression in oligodendrocytes (OLs) and the restoration of the missing enzyme. Hence, the aim of this study was to establish a novel gene-transfer system and its preclinical evaluation in a CD animal model.rnIn the first part of this thesis, a novel ASPA mouse mutant was generated. A βgeo cassette (including the genes encoding β-galactosidase and neomycin) flanked by frt sites was inserted into intron 1 of the intact aspa gene. Additionally, exon 2 was flanked by loxP sites for optional conditional deletion of the targeted locus. The resulting ASPA-deficient aspalacZ/lacZ-mouse was found to be an accurate model of CD and an important tool to identify novel aspects of its complex pathology. Homozygous mutants showed a CD-like histopathology, neurological impairment, behavioural deficits as well as a reduced body weight. Additionally, MRI data revealed changes in brain metabolite composition. rnRecombinant adeno-associated viral (rAAV) vectors have become a versatile tool for gene transfer to the central nervous system because they are efficient, non-toxic and replication-deficient. Based on the natural neurotropism of AAV vectors, AAV-based gene delivery has entered the clinics for the treatment of neurodegenerative diseases. However, the lack of AAV vectors with oligodendroglial tropism has precluded gene therapy for leukodystrophies. In the second part of this work, it was shown that the transduction profile of established AAV serotypes can be targeted towards OLs in a transcriptional approach, using the oligodendrocyte-specific myelin basic protein (MBP) promoter to drive transgene expression in OLs.rnIn the last part of this work, the therapeutic efficacy of AAV-mediated aspa gene transfer to OLs of juvenile aspalacZ/lacZ mice was evaluated. AAV-aspa injections into multiple sites of the brain parenchyma resulted in transduction of OLs in the grey and white matter throughout the brain. Histological abnormalities in the brain of ASPA-deficient mice were ameliorated and accompanied by a reduction of NAA levels. Furthermore, the treatment resulted in normalisation of body weight, motor function and nest-building behaviour. These data provide a proof-of-concept for a successful gene therapy of Canavan disease. This might pave the way towards translation into clinical application and serve as the basis for the genetic treatment of other leukodystrophies.