@phdthesis{Geissinger2010, author = {Geissinger, Ulrike}, title = {Vaccinia Virus-mediated MR Imaging of Tumors in Mice: Overexpression of Iron-binding Proteins in Colonized Xenografts}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-48099}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2010}, abstract = {Vaccinia virus plays an important role in human medicine and molecular biology ever since the 18th century after E. Jenner discovered its value as a vaccination virus against smallpox. After the successful eradication of smallpox, vaccinia virus, apart from its use as a vaccine carrier, is today mainly used as a viral vector in molecular biology and increasingly in cancer therapy. The capability to specifically target and destroy cancer cells makes it a perfect agent for oncolytic virotherapy. Furthermore, the virus can easily be modified by inserting genes encoding therapeutic or diagnostic proteins to be expressed within the tumor. The emphasis in this study was the diagnosis of tumors using different vaccinia virus strains. Viruses with metal-accumulating capabilities for tumor detection via MRI technology were generated and tested for their usefulness in cell culture and in vivo. The virus strains GLV-1h131, GLV-1h132, and GLV-1h133 carry the gene encoding the two subunits of the iron storage protein ferritin under the control of three different promoters. GLV-1h110, GLV-1h111, and GLV-1h112 encode the bacterial iron storage protein bacterioferritin, whereas GLV-1h113 encodes the codon-optimized version of bacterioferritin for more efficient expression in human cells. GLV-1h22 contains the transferrin receptor gene, which plays an important role in iron uptake, and GLV-1h114 and GLV-1h115 contain the murine transferrin receptor gene. For possibly better iron uptake the virus strains GLV-1h154, GLV-1h155, GLV-1h156, and GLV-1h157 were generated, each with a version of a ferritin gene and a transferrin receptor gene. GLV-1h154 carries the genes that encode bacterioferritin and human transferrin receptor, GLV-1h155 the human ferritin H-chain gene and the human transferrin receptor gene. GLV-1h156 and GLV-1h157 infected cells both express the mouse transferrin receptor and bacterioferritin or human ferritin H-chain, respectively. The virus strains GLV-1h186 and GLV-1h187 were generated to contain a mutated form of the ferritin light chain, which was shown to result in iron overload and the wildtype light chain gene, respectively. The gene encoding the Divalent Metal Transporter 1, which is a major protein in the uptake of iron, was inserted in the virus strain GLV-1h102. The virus strain GLV-1h184 contains the magA gene of the magnetotactic bacterium Magnetospirillum magnetotacticum, which produces magnetic nanoparticles for orientation in the earth's magnetic field. Initially the infection and replication capability of all the virus strains were analyzed and compared to that of the parental virus strain GLV-1h68, revealing that all the viruses were able to infect cells of the human cancer cell lines A549 and GI-101A. All constructs exhibited a course of infection comparable to that of GLV-1h68. Next, to investigate the expression of the foreign proteins in GI-101A and A549 cells with protein analytical methods, SDS-gelelectrophoresis, Western blots and ELISAs were performed. The proteins, which were expressed under the control of the strong promoters, could be detected using these methods. To be able to successfully detect the protein expression of MagA and DMT1, which were expressed under the control of the weak promoter, the more sensitive method RT-PCR was used to at least confirm the transcription of the inserted genes. The determination of the iron content in infected GI-101A and A549 cells showed that infection with all used virus strains led to iron accumulation in comparison to uninfected cells, even infection with the parental virus strain GLV-1h68. The synthetic phytochelatin EC20 was also shown to enhance the accumulation of different heavy metals in bacterial cultures. In vivo experiments with A549 tumor-bearing athymic nude mice revealed that 24 days post infection virus particles were found mainly in the tumor. The virus-mediated expression of recombinant proteins in the tumors was detected successfully by Western blot. Iron accumulation in tumor lysates was investigated by using the ferrozine assay and led to the result that GLV-1h68-infected tumors had the highest iron content. Histological stainings confirmed the finding that iron accumulation was not a direct result of the insertion of genes encoding iron-accumulating proteins in the virus genome. Furthermore virus-injected tumorous mice were analyzed using MRI technology. Two different measurements were performed, the first scan being done with a seven Tesla small animal scanner seven days post infection whereas the second scan was performed using a three Tesla human scanner 21 days after virus injection. Tumors of mice injected with the virus strains GLV-1h113 and GLV-1h184 were shown to exhibit shortened T2 and T2* relaxation times, which indicates enhanced iron accumulation. In conclusion, the experiments in this study suggest that the bacterioferritin-encoding virus strain GLV-1h113 and the magA-encoding virus strain GLV-1h184 are promising candidates to be used for cancer imaging after further analyzation and optimization.}, subject = {Vaccinia-Virus}, language = {en} } @phdthesis{Worschech2010, author = {Worschech, Andrea}, title = {Oncolytic Therapy with Vaccinia Virus GLV-1h68 - Comparative Microarray Analysis of Infected Xenografts and Human Tumor Cell Lines -}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-45338}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2010}, abstract = {Aim of this thesis was to study the contribution of the hosts immune system during tumor regression. A wild-type rejection model was studied in which tumor regression is mediated through an adaptive, T cell host response (Research article 1). Additionally, the relationship between VACV infection and cancer rejection was assessed by applying organism-specific microarray platforms to infected and non-infected xenografts. It could be shown that tumor rejection in this nude mouse model was orchestrated solely by the hosts innate immune system without help of the adaptive immunity. In a third study the inflammatory baseline status of 75 human cancer cell lines was tested in vitro which was correlated with the susceptibility to VACV and Adenovirus 5 (Ad5) replication of the respective cell line (Manuscript for Research article 3). Although xenografts by themselves lack the ability to signal danger and do not provide sufficient proinflammatory signals to induce acute inflammation, the presence of viral replication in the oncolytic xenograft model provides the "tissue-specific trigger" that activates the immune response and in concordance with the hypothesis, the ICR is activated when chronic inflammation is switched into an acute one. Thus, in conditions in which a switch from a chronic to an acute inflammatory process can be induced by other factors like the immune-stimulation induced by the presence of a virus in the target tissue, adaptive immune responses may not be necessary and immune-mediated rejection can occur without the assistance of T or B cells. However, in the regression study using neu expressing MMC in absence of a stimulus such as a virus and infected cancer cells thereafter, adaptive immunity is needed to provoke the switch into an acute inflammation and initiate tissue rejection. Taken together, this work is supportive of the hypothesis that the mechanisms prompting TSD differ among immune pathologies but the effect phase converges and central molecules can be detected over and over every time TSD occurs. It could be shown that in presence of a trigger such as infection with VACV and functional danger signaling pathways of the infected tumor cells, innate immunity is sufficient to orchestrate rejection of manifested tumors.}, subject = {Tumorimmunologie}, language = {en} } @phdthesis{Reiss2010, author = {Reiß, Cora}, title = {Einfluss von Defekten des Mismatch Reparatur Proteins MLH1 (Mut L Homolog 1) auf Fertilit{\"a}t und Tumorgenese im Mausmodell}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-53626}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2010}, abstract = {Mutationen im humanen DNA Mismatch-Reparatur (MMR) Gens Mlh1 sind mit dem erblichen, nicht-polyp{\"o}sen Kolonkarzinom (Lynch Syndrom, HNPCC) und einem signifikanten Anteil sporadischer kolorektaler Tumore assoziiert. Zudem konnten MMR Defekte in sporadischen und erblichen Lymphom Erkrankungen beschrieben werden. In Zellen resultiert die Inaktivierung des Mlh1 Gens in der Akkumulation von somatischen Mutationen im Genom und einer erh{\"o}hten Resistenz gegen{\"u}ber den genotoxischen Effekten einer Vielzahl von DNA sch{\"a}digenden Agenzien. M{\"a}use, die ein Null Allel f{\"u}r das MMR Gen Mlh1 tragen zeigen einen starken Tumorpr{\"a}dispositions Ph{\"a}notyp. Sie entwickeln vorrangig B- und T-Zell Lymphome und mit geringerer Haufigkeit gastrointestinale Tumore. Zus{\"a}tzlich sind Mlh1-/- M{\"a}use durch einen meiotischen Ph{\"a}notyp charakterisiert, der zu Sterilit{\"a}ten in beiden Geschlechtern f{\"u}hrt. Um die Effekte von Mlh1 missense Mutationen auf die Tumoranf{\"a}lligkeit zu untersuchen, erzeugten wir eine Mauslinie, die die h{\"a}ufig in HNPCC Patienten beschriebene MLH1G67R Mutation tragen, die in einer der ATP Bindungs-Dom{\"a}nen von MLH1 lokalisiert ist. Auch wenn die MLH1G67R Mutation in homozygot mutanten M{\"a}usen in einer DNA Reparatur Defizienz resultierte hatte sie keinen Effekt auf die MMR vermittelte zellul{\"a}re Antwort auf DNA Sch{\"a}den. Hierzu geh{\"o}rte die apoptotische Antwort von Epithelzellen der intestinalen Mucosa auf Cisplatin, die in Mlh1-/- M{\"a}usen defektiv jedoch in Mlh1G67R/G67R M{\"a}usen normal ausfiel. Mlh1G67R/G67R mutante M{\"a}use zeigten wie Mlh1-/- Tiere einen starken Tumorpr{\"a}dispositions Ph{\"a}notyp. Sie entwickelten jedoch im Vergleich zu Mlh1-/- Tieren signifikant weniger gastrointestinale Tumore, was darauf hinweist, dass Mlh1 missense Mutationen die Tumor supprimierende MMR Funktion in einer Gewebs-spezifischen Weise beeinflussen k{\"o}nnen. Dar{\"u}ber hinaus sind Mlh1G67R/G67R M{\"a}use, aufgrund der fehlenden Bindungsf{\"a}higkeit des MLH1G67R Proteins an die meiotischen Chromosomen im Pachyt{\"a}n Stadium, steril. Dies zeigt, dass die ATPase Aktivit{\"a}t von MLH1 f{\"u}r die Fertilit{\"a}t in S{\"a}ugern essentiell ist. Diese Untersuchungen belegen, dass die Mlh1G67R Mutation die biologischen MLH1 Funktionen differentiell mit einem eindeutigen Ph{\"a}notyp beeinflusst. Um die Rolle von MLH1 f{\"u}r die Lymphomagenese detaillierter untersuchen zu k{\"o}nnen, generierten wir ein neues Mausmodell mit einem konditionellen Mlh1 Allel (Mlh1flox/flox). Das Einkreuzen von transgenen EIIa-Cre Mausen in die Mlh1flox/flox Mauslinie f{\"u}hrte zur konstitutiven Inaktivierung von MLH1. Die resultierende Mlh1Δex4/Δex4 Mauslinie zeichnete sich durch MMR Defizienz und einen zu Mlh1-/- Tieren vergleichbaren Tumorpr{\"a}dispositions Ph{\"a}notyp aus. Zur T-Zell spezifischen MMR Inaktivierung kombinierten wir das Mlh1flox/flox Allel mit dem Lck-Cre Transgen. In den resultierenden Mlh1TΔex4/TΔex4 M{\"a}usen ist die MLH1 Inaktivierung auf doppelt positive und einzel positive Thymozyten und na{\"i}ve periphere TZellen beschr{\"a}nkt. Die Entwicklung von T-Zell Lymphomen in Mlh1TΔex4/TΔex4 M{\"a}usen ist im Vergleich zu Mlh1-/- M{\"a}usen signifikant reduziert, was eine wichtige, Lymphom supprimierende MMR Funktion in fr{\"u}hen Stadien der T-Zell Entwicklung oder in lymphoiden Vorl{\"a}uferzellen impliziert.}, subject = {Colonkrebs}, language = {de} }