A single chain antibody against a viral RNA polymerase (TBSV-BS3-Statice)

Expression of antibodies in plant against essential viral proteins could provide an alternative approach to engineered viral resistance. Engineered single chain Fv antibodies scFV are particularly suitable for expression in plant because of their small size and the lack of assembly requirements. RNA-dependent RNA polymerases (RdRps) function as the catalytic subunit of viral replicases required for the replication of all positive strand RNA viruses. By using Phage technology we selected scFvs from a phage library using purified E.coli expressed TBSV(Tomato bushy stunt virus) replicase as antigen. The scFvs mediated-inhibition of RdRp activity was studied in vitro and in planta. In vitro experiments showed the inhibition of CNV(Cucumber necrosis virus) and TCV(Turnip crinkle virus) RdRp. Transient in planta assays based on agroinfiltration and an infectious clone of TBSV demonstrated the inhibition of the replication of TBSV(Tomato bushy stunt virus). Epitope mapping showed that the selected scFvs target the motif E of RdRp which is involved in template binding.Moreover T1 plants of transgenic lines of N. benthamiana expressing different scFvs either in the cytoplasm or the ER (endoplasmic reticulum) showed a high level of resistance against infection with TBSV and RCNMV(Red clover necrotic mosaic virus) upon inoculation with virus particles. This is the first report that scFvs against a RdRp of a plant viruses can inhibit viral replication in vivo. The resistance is even efficient against viruses belonging to different virus families.

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.

Induktion und Analyse spezifischer Immunantworten nach intranodaler Immunisierung mit RNA im murinen Modell

Die Wirksamkeit einer Vakzine ist von vielen Parametern abhängig. Dazu gehören unter anderen: das ausgewählte Antigen, die Formulation in der das Antigen benutzt wird sowie die Applikationsroute. Antigen-kodierende Ribonukleinsäuren (RNA) gilt heutzutage als eine sichere und effiziente Alternative zu traditionellen Impfstoff-Formulierungen, wie Peptiden, rekombinanten Proteinen, viralen Systemen oder DNA basierten Impfstoffen. Bezüglich des Applikationsortes repräsentiert der Lymphknoten ein optimales Milieu für die Interaktion zwischen antigenpräsentierenden Zellen und T-Zellen. Vor diesem Hintergrund war die Zielsetzung dieser Arbeit, ein auf direktem in vivo Transfer von Antigen-kodierender in vitro transkribierter RNA (IVT-RNA) basierendes Impfverfahren zu entwickeln, zu charakterisieren und auf seine anti-tumorale Wirksamkeit zu testen. In der vorliegenden Arbeit konnte gezeigt werden, dass dendritische Zellen (DCs) in vitro hocheffizient mit IVT-RNA transfiziert werden können und eine hohe stimulatorische Kapazität besitzen. Durch Sequenzmodifikation der IVT-RNA konnten wir die Transkriptstabilität und Translationseffizienz erhöhen was zu einer Steigerung der stimulatorischen Kapazität in vivo führte. Darüber hinaus untersuchten wir die Auswirkung der Insertion eines Signalpeptides 5’ sowie einer C-terminalen transmembran- und zytosolischen-Domäne eines MHC-Klasse-I-Moleküls am 3’ der Antigen-kodierenden Sequenz auf die Effizienz der MHC-Klasse-I und -II Präsentation. Wir konnten in vitro und in vivo nachweisen, dass diese Modifikation zu einer gesteigerten, simultanen Stimulation von antigenspezifischen CD4+ und CD8+ T-Zellen führt. Auf der Basis der optimierten Vektorkassetten etablierten wir die intranodale (i.n.) Transfektion von antigenpräsentierenden Zellen in der Maus. Dazu nutzten wir verschiedene Reportersysteme (eGFP-RNA, fluoreszensmarkierte RNA) und konnten zeigen, dass die intranodale Applikation von IVT-RNA zu selektiven Transfektion und Maturation lymphknotenresidenter DCs führt. Zur Untersuchung der immunologischen Effekte wurden in erster Linie auf Influenza-Hemagglutinin-A und Ovalbumin basierende Modellantigensysteme verwendet. Beide Antigene wurden als Antigen-MHC-Fusionskonstrukte genutzt. Als Responderzellen wurden TCR-transgene Lymphozyten verwendet, die MHC-Klasse-I oder -Klasse-II restringierte Epitope des Influenza-Hemagglutinin-A bzw. des Ovalbumin-Proteins erkennen. Wir konnten in vivo zeigen, dass die intranodale Immunisierung mit IVT-RNA zu einer effizienten Stimulation und Expansion von antigenspezifischen CD4+ und CD8+ T-Zellen in einer dosisabhängigen Weise führt. Funktionell konnte gezeigt werden, dass diese T-Zellen Zytokine sezernieren und zur Zytolyse befähigt sind. Wir waren in der Lage durch repetitive i.n. RNA Immunisierung ein ‚Priming’ CD8+ T-Zellen in naiven Mäusen sowohl gegen virale als auch gegen Tumor assoziierte Antigene zu erreichen. Die geprimten T-Zellen waren befähigt eine zytolytische Aktivität gegen mit spezifischem Peptid beladene Targetzellen zu generieren. Darüber hinaus waren wir in der Lage Gedächtnisszellen expandieren zu können. Abschließend konnten wir in Tumormodellen sowohl in prophylaktischen als auch in therapeutischen Experimenten zeigen dass die i.n. RNA Vakzination die Potenz zur Induktion einer anti-tumoralen Immunität besitzt.

Evaluation of polymeric nanocarriers for RNA delivery

Therapeutic RNAs, especially siRNAs, are a promising approach for treating diseases like cancer, neurodegenerative disorders and viral infections. Their application, however, is limited due to a lack of safe and efficient delivery systems. Nanosized carriers with the ability to either complex or entrap RNA species are a promising option. rn rn rnSuch a carrier has to meet a lot of requirements, some of which are even partly contradictive. Understanding and controlling the interplay between the different demands would advance a strategic design at an early stage of therapeutic development. rn rn This work is centered around a systematic evaluation of polyplexes, such carriers that are able to complex siRNA due to electrostatic interactions. Six structurally and chemically diverse candidates, poly-L-lysine brushes, block copolymers, cationic peptides, cationic lipids, nanohydrogels, and manganese oxide particles, were tested in a simultaneous fashion. The assays, mostly based on fluorescently labeled siRNA, ranged from the evaluation of polyplex formation and stability to in vitro parameters like cellular uptake and knockdown capability. The analysis from several perspectives offered insight into the interplay between the specifications of one polyplex. Assessing the different carriers under exactly the same experimental conditions also allowed conclusions about favourable traits and starting points for further optimization. This comparative approach also revealed weaknesses of some of the conventional protocols, which were therefore contrasted with alternative methods. In addition, in vitro knockdown assays were optimized and the impact of fluorescently labeled siRNA on knockdown efficiency was assessed. rn rn rn A second class of carriers, which share the ability to entrap siRNA inside their matrix, are briefly addressed. Nanocapsules, dextran particles and liposomes were assessed for basic features like siRNA encapsulation and knockdown capability. rn rn rn rn In an approach towards targeted delivery of RNA, liposomes were endowed with mitochondriotropic tags. Despite successful functionalization, no colocalization between the liposomal cargo and mitochondria was so far observed, which makes further optimization necessary.

Optimization of RNA-based transgene expression by targeting Protein Kinase R

The aim of this thesis was to establish a method for repeated transfection of in vitro transcribed RNA (IVT-RNA) leading to a sustained protein expression lasting for days or even weeks. Once transfected cells recognize IVT-RNA as "non-self" and initiate defense pathways leading to an upregulated interferon (IFN) response and stalled translation. In this work Protein Kinase R (PKR) was identified as the main effector molecule mediating this cellular response. We assessed four strategies to inhibit PKR and the IFN response: A small molecule PKR inhibitor enhanced protein expression and hampered the induction of IFN-transcripts, but had to be excluded due to cytotoxicity. A siRNA mediated PKR knockdown and the overexpression of a kinase inactive PKR mutant elevated the protein expression, but the down-regulation of the IFN response was insufficient. The co-transfer of the viral inhibitors of PKR and the IFN response was most successful. The use of E3, K3 and B18R co-transfection enabled repeated IVT-RNA-based transfection of human fibroblasts. Thus, the developed protocol allows a continuous IVT-RNA encoded protein expression of proteins, which could be the basis for the generation of induced pluripotent stem cells (iPS) for several therapeutic applications in regenerative medicine or drug research.