@phdthesis{Kober2015, author = {Kober, Christina}, title = {Characterization of Murine GL261 Glioma Models for Oncolytic Vaccinia Virus Therapy}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-118556}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2015}, abstract = {Glioblastoma multiforme (GBM) is one of the most frequent and malignant forms of brain cancer in adults. The prognosis is poor with a median survival time of 12-15 months. There is a broad range of alternative treatment options studied in preclinical and clinical trials for GBM. One alternative treatment option is oncolytic virotherapy, defined as the use of replication-competent viruses that selectively infect and destroy cancer cells while leaving, non-transformed cells unharmed. Vaccinia virus (VACV) is one favorable candidate. Although oncolytic viruses can kill tumor cells grown in vitro with high efficiency, they often exhibit reduced replication capacity in vivo suggesting that physiological aspects of the tumor microenvironment decrease the virus' therapeutic potential. The percentage and composition of immune cells varies between cancer types and patients and is investigated as a biomarker in several studies. Making oncolytic virotherapy successful for GBM, it is necessary to understand the individual tumor biology, the interaction with the microenvironment and immune system. It was demonstrated that the attenuated VACV wild-type (wt) isolate LIVP 1.1.1 replicate and lyse the murine GL261 glioma cell line in vitro. In the following, the replication efficacy was characterized in a comparative approach in vivo. Immunocompetent C57BL/6 (wt) mice and immunodeficient mouse strains of different genetic background C57BL/6 athymic and Balb/c athymic mice were used. In addition, subcutaneous and intracranial locations were compared. The results revealed viral replication exclusively in Balb/c athymic mice with subcutaneous tumors but in none of the other models. In the following, the tumor microenvironment of the subcutaneous tumor models at the time of infection was performed. The study showed that implantation of the same tumor cells in different mouse strains resulted in a different tumor microenvironment with a distinct composition of immune cells. Highest differences were detected between immunodeficient and immunocompetent mice. The study showed major differences in the expression of MHCII with strongest expression in C57BL/6 wt and weakest in Balb/c athymic tumors. In the following, the influence of the phenotypic change associated with the upregulation of MHCII on GL261 tumor cells on viral replication was analyzed. Comparison of C57BL/6 wt and C57BL/6 IFN-γ knockout mice revealed endogenous IFN-γ levels to upregulate MHCII on GL261 tumor cells and to reduce viral replication in C57BL/6 wt mice. Analysis of single cell suspensions of tumor homogenates of C57BL/6 and Balb/c athymic mice showed that the IFN-γ-mediated anti-tumor effect was a reversible effect. Furthermore, reasons for inhibition of virus replication in orthotopic glioma models were elucidated. By immunohistochemical analysis it was shown that intratumoral amounts of Iba1+ microglia and GFAP+ astrocytes in Gl261 gliomas was independent from intratumoral VACV injection. Based on these findings virus infection in glioma, microglia and astrocytes was compared and analyzed in cell culture. In contrast to the GL261 glioma cells, replication was barely detectable in BV-2 microglia and IMA2.1 astrocytic cells. Co-culture experiments revealed that microglia compete for virus uptake in cell culture. It was further shown that BV-2 cells showed apoptotic characteristics after VACV infection while GL261 cells showed signs of necrotic cell death. Additionally, in BV-2 cells with M1-phenotype a further reduction of viral replication and inhibition of cell lysis was detected. Infection of IMA 2.1 cells was independent of the M1/M2-phenotype. Application of BV-2 microglia with M1-phenotype onto organotypic slice cultures with implanted GL261 tumors resulted in reduced infection of BV-2 cells with LIVP 1.1.1, whereas GL261 cells were significantly infected. Taken together, the analyzed GL261 tumors were imprinted by the immunologic and genetic background in which they grow. The experimental approach applied in this thesis can be used as suitable model which reflects the principles of personalized medicine In an additional project, based on gene expression data and bioinformatic analyses, the biological role and function of the anti-apoptotic factor AVEN was analyzed with regard to oncolytic VACV therapy. Besides a comparison of the replication efficacy of GLV-1h68 and VACV-mediated cell killing of four human tumor cell lines, it was shown that AVEN was expressed in all analyzed cells. Further, shown for HT-29 and 1936-MEL, the knockdown of AVEN by siRNA in cell culture resulted in an increase of apoptotic characteristics and a decrease of VACV infection. These findings provide essential insights for future virus development.}, subject = {Krebs }, language = {en} } @phdthesis{MeirgebRother2015, author = {Meir [geb. Rother], Juliane}, title = {Influence of oncolytic vaccinia viruses on metastases of human and murine tumors}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-118530}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2015}, abstract = {Cancer is one of the leading causes of death. 90\% of all deaths are caused by the effects of metastases. It is of major importance to successfully treat the primary tumor and metastases. Tumors and metastases often differ in their properties and therefore, treatment is not always successful. In contrast, those therapeutic agents can even promote formation and growth of metastases. Hence, it is indispensable to find treatment options for metastatic disease. One promising candidate represents the oncolytic virus therapy with vaccinia viruses. The aim of this work was to analyze two cell lines regarding their metastatic abilities and to investigate whether oncolytic vaccinia viruses are useful therapy options. The cell lines used were the human cervical cancer cell line C33A implanted into immune-compromised mice and the murine melanoma cell line B16F10, implanted into immune-competent mice. The initial point of the investigations was the observation of enlarged lumbar und renal lymph nodes in C33A tumor-bearing mice 35 days post implantation of C33A cells subcutaneously into immune-compromised nude mice. Subsequently, the presence of human cells in enlarged lymph nodes was demonstrated by RT-PCR. To facilitate the monitoring of cancer cell spreading, the gene encoding for RFP was inserted into the genome of C33A cells. In cell culture experiments, it was possible to demonstrate that this insertion did not negatively affect the susceptibility of the cells to virus infection, replication and virus-mediated cell lysis. The analysis of the metastatic process in a xenografted mouse model revealed the continuous progression of lumbar (LN) and renal (RN) lymph node metastasis after C33A-RFP tumor cell implantation. The lymph node volume and the amount of RFP-positive LNs and RNs was increasing from week to week in accordance with the gain of the primary tumor volume. Moreover, the metastatic spread of cancer cells in lymph vessels between lumbar and renal lymph nodes was visualized. Additionally, the haematogenous way of cancer cell migration was demonstrated by RFP positive cancer cells in blood vessels. The haematogenous route of spreading was confirmed by detecting micrometastases in lungs of tumor bearing mice. The next step was to investigate whether the recombinant oncolytic vaccinia virus GLV-1h68 is a suitable candidate to cure the primary tumor and metastases. Therefore, GLV-1h68 was systemically injected into C33A-RFP tumor bearing mice 21 days after tumor cell implantation. It was demonstrated that the volume of the primary tumor was drastically reduced, and the volume and the amount of RFP positive lumbar and renal lymph nodes were significantly decreasing compared to the untreated control group. Subsequently, this process was analyzed further by investigating the colonization pattern in the C33A-RFP model. It was shown that first the primary tumor was colonized with highest detectable virus levels, followed by LN and RN lymph nodes. Histological analyses revealed the proliferative status of tumor cells in the tumor and lymph nodes, the amount of different immune cell populations and the vascular permeability in primary tumors and lymph nodes having an influence on the colonization pattern of the virus. Whereby, the vascular permeability seems to have a crucial impact on the preferential colonization of tumors compared to lymph node metastases in this tumor model. C33A turned out to be a useful model to study the formation and therapy of metastases. However, a metastatic model in which the influence of the immune system on tumors and especially on tumor therapy can be analyzed would be preferable. Therefore, the aim of the second part was to establish a syngeneic metastatic mouse model. Accordingly, the murine melanoma cell line B16F10 was analyzed in immunocompetent mice. First, the highly attenuated GLV 1h68 virus was compared to its parental strain LIVP 1.1.1 concerning infection, replication and cell lysis efficacy in cell culture. LIVP 1.1.1 was more efficient than GLV-1h68 and was subsequently used for following mouse studies. Comparative studies were performed, comparing two different implantation sites of the tumor cells, subcutaneously and footpad, and two different mouse strains, FoxN1 nude and C57BL/6 mice. Implantation into the footpad led to a higher metastatic burden in lymph nodes compared to the subcutaneous implantation site. Finally, the model of choice was the implantation of B16F10 into the footpad of immune-competent C57BL/6 mice. Furthermore, it was inevitable to deliver the virus as efficient as possible to the tumor and metastases. Comparison of two different injection routes, intravenously and intratumorally, revealed, that the optimal injection route was intratumorally. In summary, the murine B16F10 model is a promising model to study the effects of the immune system on vaccinia virus mediated therapy of primary tumors and metastases.}, subject = {Krebs }, language = {en} } @phdthesis{Gnamlin2015, author = {Gnamlin, Prisca}, title = {Use of Tumor Vasculature for Successful Treatment of Carcinomas by Oncolytic Vaccinia Virus}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-119019}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2015}, abstract = {Tumor-induced angiogenesis is of major interest for oncology research. Vascular endothelial growth factor (VEGF) is the most potent angiogenic factor characterized so far. VEGF blockade was shown to be sufficient for angiogenesis inhibition and subsequent tumor regression in several preclinical tumor models. Bevacizumab was the first treatment targeting specifically tumor-induced angiogenesis through VEGF blockade to be approved by the Food and Drugs Administration (FDA) for cancer treatment. However, after very promising results in preclinical evaluations, VEGF blockade did not show the expected success in patients. Some tumors became resistant to VEGF blockade. Several factors have been accounted responsible, the over-expression of other angiogenic factors, the noxious influence of VEFG blockade on normal tissues, the selection of hypoxia resistant neoplastic cells, the recruitment of hematopoietic progenitor cells and finally the transient nature of angiogenesis inhibition by VEGF blockade. The development of blocking agents against other angiogenic factors like placental growth factor (PlGF) and Angiopoietin-2 (Ang-2) allows the development of an anti-angiogenesis strategy adapted to the profile of the tumor. Oncolytic virotherapy uses the natural propensity of viruses to colonize tumors to treat cancer. The recombinant vaccinia virus GLV-1h68 was shown to infect, colonize and lyse several tumor types. Its descendant GLV-1h108, expressing an anti-VEGF antibody, was proved in previous studies to inhibit efficiently tumor induced angiogenesis. Additional VACVs expressing single chain antibodies (scAb) antibodies against PlGF and Ang-2 alone or in combination with anti VEGF scAb were designed. In this study, VACV-mediated anti-angiogenesis treatments have been evaluated in several preclinical tumor models. The efficiency of PlGF blockade, alone or in combination with VEGF, mediated by VACV has been established and confirmed. PlGF inhibition alone or with VEGF reduced tumor burden 5- and 2-folds more efficiently than the control virus, respectively. Ang-2 blockade efficiency for cancer treatment gave controversial results when tested in different laboratories. Here we demonstrated that unlike VEGF, the success of Ang-2 blockade is not only correlated to the strength of the blockade. A particular balance between Ang-2, VEGF and Ang-1 needs to be induced by the treatment to see a regression of the tumor and an improved survival. We saw that Ang-2 inhibition delayed tumor growth up to 3-folds compared to the control virus. These same viruses induced statistically significant tumor growth delays. This study unveiled the need to establish an angiogenic profile of the tumor to be treated as well as the necessity to better understand the synergic effects of VEGF and Ang-2. In addition angiogenesis inhibition by VACV-mediated PlGF and Ang-2 blockade was able to reduce the number of metastases and migrating tumor cells (even more efficiently than VEGF blockade). VACV colonization of tumor cells, in vitro, was limited by VEGF, when the use of the anti-VEGF VACV GLV-1h108 drastically improved the colonization efficiency up to 2-fold, 72 hours post-infection. These in vitro data were confirmed by in vivo analysis of tumors. Fourteen days post-treatment, the anti-VEGF virus GLV-1h108 was colonizing 78.8\% of the tumors when GLV-1h68 colonization rate was 49.6\%. These data confirmed the synergistic effect of VEGF blockade and VACV replication for tumor regression. Three of the tumor cell lines used to assess VACV-mediated angiogenesis inhibition were found, in certain conditions, to mimic either endothelial cell or pericyte functions, and participate directly to the vascular structure. The expression by these tumor cells of e-selectin, p-selectin, ICAM-1 and VCAM-1, normally expressed on activated endothelial cells, corroborates our findings. These proteins play an important role in immune cell recruitment, and there amount vary in presence of VEGF, PlGF and Ang-2, confirming the involvement of angiogenic factors in the immuno-modulatory abilities of tumors. In this study VACV-mediated angiogenesis blockade proved its potential as a therapeutic agent able to treat different tumor types and prevent resistance observed during bevacizumab treatment by acting on different factors. First, the expression of several antibodies by VACV would prevent another angiogenic factor to take over VEGF and stimulate angiogenesis. Then, the ability of VACV to infect tumor cells would prevent them to form blood vessel-like structures to sustain tumor growth, and the localized delivery of the antibody would decrease the risk of adverse effects. Next, the blockade of angiogenic factors would improve VACV replication and decrease the immune-modulatory effect of tumors. Finally the fact that angiogenesis blockade lasts until total regression of the tumor would prevent the recovery of the tumor-associated vasculature and the relapse of patients.}, subject = {Vaccinia-Virus}, language = {en} } @phdthesis{Huang2013, author = {Huang, Ting}, title = {Vaccinia Virus-mediated Therapy of Solid Tumor Xenografts: Intra-tumoral Delivery of Therapeutic Antibodies}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-91327}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2013}, abstract = {Over the past 30 years, much effort and financial support have been invested in the fight against cancer, yet cancer still represents the leading cause of death in the world. Conventional therapies for treatment of cancer are predominantly directed against tumor cells. Recently however, new treatments options have paid more attention to exploiting the advantage of targeting the tumor stroma instead. Vaccinia virus (VACV) has played an important role in human medicine since the 18th century as a vaccination against smallpox. In our laboratory, the recombinant, replication-competent vaccinia virus, GLV-1h68, was shown to enter, colonize and destroy cancer cells both in cell culture, and in vivo, in xenograft models (Zhang, Yu et al. 2007). In addition, combined therapy of GLV-1h68 and anti-VEGF immunotherapy significantly enhanced antitumor therapy in vivo (Frentzen, Yu et al. 2009). In this study, we constructed several new recombinant VACVs carrying genes encoding different antibodies against fibroblast activation protein (FAP) in stroma (GLV-1h282), nanobody against the extracellular domain of epidermal growth factor receptor (EGFR, GLV-1h442) or antibodies targeting both vascular endothelial growth factor (VEGF) and EGFR (GLV-1h444) or targeting both VEGF and FAP (GLV-1h446). The expression of the recombinant proteins was first verified using protein analytical methods, SDS-gel electrophoresis, Western blot analysis, immunoprecipitation (IP) assays and ELISA assays. The proteins were detected after infection of the cells with the different VACVs and the recombinant proteins purified by affinity adsorption. The purified antibodies were shown to specifically bind to their respective antigens. Secondly, the infection and replication capability of all the virus strains was analyzed in cell culture using several human tumor cell lines (A549, FaDu or DU145), revealing that all the new recombinant VACVs were able to infect cancer cells with comparable efficiency to the parental viruses from which they were derived. Thirdly, the antitumor efficacy of the new recombinant VACVs was evaluated in vivo using several human cancer xenograft models in mice. In A549 and DU145 xenografts, the new recombinant VACVs exhibited an enhanced therapeutic efficacy compared to GLV-1h68 with no change in toxicity in mice. In the FaDu xenograft, treatment with GLV-1h282 (anti-FAP) significantly slowed down the speed of tumor growth compared to GLV-1h68. Additionally, treatment with the recombinant VACVs expressed the various antibodies achieved comparable or superior therapeutic effects compared to treatment with a combination of GLV-1h68 and the commercial therapeutic antibodies, Avastin, Erbitux or both. Next, the virus distribution in tumors and organs of treated mice was evaluated. For most of the viruses, the virus titer in tumors was not signficantly diffferent than GLV-1h68. However, for animals treated with GLV-1h282, the virus titer in tumors was significantly higher than with GLV-1h68. This may be the reason for enhanced antitumor efficacy of GLV-1h282 in vivo. Lastly, the underlying mechanisms of therapeutic antibody-enhanced antitumor effects were investigated by immunohistochemistry. Blood vessels density and cell proliferation in tumors were suppressed after treatment with the antibody-encoded VACVs. The results indicated that the suppression of angiogenesis or cell proliferation in tumors may cause the observed therapeutic effect. In conclusion, the results of the studies presented here support the hypothesis that the treatment of solid tumors with a combination of oncolytic virotherapy and immunotherapy has an additive effect over each treatment alone. Moreover, expression of the immunotherapeutic antibody by the oncolytic VACV locally in the tumor enhances the antitumor effect over systemic treatment with the same antibody. Combined, these results indicate that therapy with oncolytic VACVs expressing-therapeutic antibodies may be a promising approach for the treatment of cancer.}, subject = {Vaccinia-Virus}, language = {en} } @phdthesis{Hess2013, author = {Heß, Michael}, title = {Vaccinia virus-encoded bacterial beta-glucuronidase as a diagnostic biomarker for oncolytic virotherapy}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-86789}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2013}, abstract = {Oncolytic virotherapy represents a promising approach to revolutionize cancer therapy. Several preclinical and clinical trials display the safety of oncolytic viruses as wells as their efficiency against solid tumors. The development of complementary diagnosis and monitoring concepts as well as the optimization of anti-tumor activity are key points of current virotherapy research. Within the framework of this thesis, the diagnostic and therapeutic prospects of beta-glucuronidase expressed by the oncolytic vaccinia virus strain GLV-1h68 were evaluated. In this regard, a beta-glucuronidase-based, therapy-accompanying biomarker test was established which is currently under clinical validation. By using fluorescent substrates, the activity of virally expressed beta-glucuronidase could be detected and quantified. Thereby conclusions about the replication kinetics of oncolytic viruses in animal models and virus-induced cancer cell lysis could be drawn. These findings finally led to the elaboration and establishment of a versatile biomarker assay which allows statements regarding the replication of oncolytic viruses in mice based on serum samples. Besides the analysis of retrospective conditions, this test is able to serve as therapy-accompanying monitoring tool for virotherapy approaches with beta-glucuronidase-expressing viruses. The newly developed assay also served as complement to routinely used plaque assays as well as reference for virally expressed anti-angiogenic antibodies in additional preclinical studies. Further validation of this biomarker test is currently taking place in the context of clinical trials with GL-ONC1 (clinical grade GLV-1h68) and has already shown promising preliminary results. It was furthermore demonstrated that fluorogenic substrates in combination with beta-glucuronidase expressed by oncolytic viruses facilitated the optical detection of solid tumors in preclinical models. In addition to diagnostic purposes, virus-encoded enzymes could also be combined with prodrugs resulting in an improved therapeutic outcome of oncolytic virotherapy. In further studies, the visualization of virus-induced immune reactions as well as the establishment of innovative concepts to improve the therapeutic outcome of oncolytic virotherapy could be accomplished. In conclusion, the results of this thesis provide crucial findings about the influence of virally expressed beta-glucuronidase on various diagnostic concepts in the context of oncolytic virotherapy. In addition, innovative monitoring and therapeutic strategies could be established. Our preclinical findings have important clinical influence, particularly by the development of a therapy-associated biomarker assay which is currently used in different clinical trials.}, subject = {Vaccinia-Virus}, language = {en} } @phdthesis{Reinboth2012, author = {Reinboth, Jennifer}, title = {Cellular Factors Contributing to Host Cell Permissiveness in Support of Oncolytic Vaccinia Virus Replication}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-85392}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2012}, abstract = {In initial experiments, the well characterized VACV strain GLV-1h68 and three wild-type LIVP isolates were utilized to analyze gene expression in a pair of autologous human melanoma cell lines (888-MEL and 1936 MEL) after infection. Microarray analyses, followed by sequential statistical approaches, characterized human genes whose transcription is affected specifically by VACV infection. In accordance with the literature, those genes were involved in broad cellular functions, such as cell death, protein synthesis and folding, as well as DNA replication, recombination, and repair. In parallel to host gene expression, viral gene expression was evaluated with help of customized VACV array platforms to get better insight over the interplay between VACV and its host. Our main focus was to compare host and viral early events, since virus genome replication occurs early after infection. We observed that viral transcripts segregated in a characteristic time-specific pattern, consistent with the three temporal expression classes of VACV genes, including a group of genes which could be classified as early-stage genes. In this work, comparison of VACV early replication and respective early gene transcription led to the identification of seven viral genes whose expression correlated strictly with replication. We considered the early expression of those seven genes to be representative for VACV replication and we therefore referred to them as viral replication indicators (VRIs). To explore the relationship between host cell transcription and viral replication, we correlated viral (VRI) and human early gene expression. Correlation analysis revealed a subset of 114 human transcripts whose early expression tightly correlated with early VRI expression and thus early viral replication. These 114 human molecules represented an involvement in broad cellular functions. We found at least six out of 114 correlates to be involved in protein ubiquitination or proteasomal function. Another molecule of interest was the serine-threonine protein kinase WNK lysine-deficient protein kinase 1 (WNK1). We discovered that WNK1 features differences on several molecular biological levels associated with permissiveness to VACV infection. In addition to that, a set of human genes was identified with possible predictive value for viral replication in an independent dataset. A further objective of this work was to explore baseline molecular biological variances associated with permissiveness which could help identifying cellular components that contribute to the formation of a permissive phenotype. Therefore, in a subsequent approach, we screened a set of 15 melanoma cell lines (15-MEL) regarding their permissiveness to GLV-1h68, evaluated by GFP expression levels, and classified the top four and lowest four cell lines into high and low permissive group, respectively. Baseline gene transcriptional data, comparing low and highly permissive group, suggest that differences between the two groups are at least in part due to variances in global cellular functions, such as cell cycle, cell growth and proliferation, as well as cell death and survival. We also observed differences in the ubiquitination pathway, which is consistent with our previous results and underlines the importance of this pathway in VACV replication and permissiveness. Moreover, baseline microRNA (miRNA) expression between low and highly permissive group was considered to provide valuable information regarding virus-host co-existence. In our data set, we identified six miRNAs that featured varying baseline expression between low and highly permissive group. Finally, copy number variations (CNVs) between low and highly permissive group were evaluated. In this study, when investigating differences in the chromosomal aberration patterns between low and highly permissive group, we observed frequent segmental amplifications within the low permissive group, whereas the same regions were mostly unchanged in the high group. Taken together, our results highlight a probable correlation between viral replication, early gene expression, and the respective host response and thus a possible involvement of human host factors in viral early replication. Furthermore, we revealed the importance of cellular baseline composition for permissiveness to VACV infection on different molecular biological levels, including mRNA expression, miRNA expression, as well as copy number variations. The characterization of human target genes that influence viral replication could help answering the question of host cell response to oncolytic virotherapy and provide important information for the development of novel recombinant vaccinia viruses with improved features to enhance replication rate and hence trigger therapeutic outcome.}, subject = {Vaccinia-Virus}, language = {en} } @phdthesis{Buckel2012, author = {Buckel, Lisa}, title = {Evaluating the combination of oncolytic vaccinia virus and ionizing radiation in therapy of preclinical glioma models}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-85309}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2012}, abstract = {Glioblastoma multiforme (GBM) represents the most aggressive form of malignant brain tumors and remains a therapeutically challenge. Intense research in the field has lead to the testing of oncolytic viruses to improve tumor control. Currently, a variety of different oncolytic viruses are being evaluated for their ability to be used in anti-cancer therapy and a few have entered clinical trials. Vaccinia virus, is one of the viruses being studied. GLV-1h68, an oncolytic vaccinia virus engineered by Genelux Corporation, was constructed by insertion of three gene cassettes, RUC-GFP fusion, β-galactosidase and β- glucuronidase into the genome of the LIVP strain. Since focal tumor radiotherapy is a mainstay for cancer treatment, including glioma therapy, it is of clinical relevance to assess how systemically administered oncolytic vaccinia virus could be combined with targeted ionizing radiation for therapeutic gain. In this work we show how focal ionizing radiation (IR) can be combined with multiple systemically delivered oncolytic vaccinia virus strains in murine models of human U-87 glioma. After initial experiments which confirmed that ionizing radiation does not damage viral DNA or alter viral tropism, animal studies were carried out to analyze the interaction of vaccinia virus and ionizing radiation in the in vivo setting. We found that irradiation of the tumor target, prior to systemic administration of oncolytic vaccinia virus GLV-1h68, increased viral replication within the U-87 xenografts as measured by viral reporter gene expression and viral titers. Importantly, while GLV-1h68 alone had minimal effect on U-87 tumor growth delay, IR enhanced GLV-1h68 replication, which translated to increased tumor growth delay and mouse survival in subcutaneous and orthotopic U-87 glioma murine models compared to monotherapy with IR or GLV-1h68. The ability of IR to enhance vaccinia replication was not restricted to the multi-mutated GLV-1h68, but was also seen with the less attenuated oncolytic vaccinia, LIVP 1.1.1. We have demonstrated that in animals treated with combination of ionizing radiation and LIVP 1.1.1 a strong pro-inflammatory tissue response was induced. When IR was given in a more clinically relevant fractionated scheme, we found oncolytic vaccinia virus replication also increased. This indicates that vaccinia virus could be incorporated into either larger hypo-fraction or more conventionally fractionated radiotherapy schemes. The ability of focal IR to mediate selective replication of systemically injected oncolytic vaccinia was demonstrated in a bilateral glioma model. In mice with bilateral U-87 tumors in both hindlimbs, systemically administered oncolytic vaccinia replicated preferentially in the focally irradiated tumor compared to the shielded non- irradiated tumor in the same mouse We demonstrated that tumor control could be further improved when fractionated focal ionizing radiation was combined with a vaccinia virus caring an anti-angiogenic payload targeting vascular endothelial growth factor (VEGF). Our studies showed that following ionizing radiation expression of VEGF is upregulated in U-87 glioma cells in culture. We further showed a concentration dependent increase in radioresistance of human endothelial cells in presence of VEGF. Interestingly, we found effects of vascular endothelial growth factor on endothelial cells were reversible by adding purified GLAF-1 to the cells. GLAF-1 is a single- chain antibody targeting human and murine VEGF and is expressed by oncolytic vaccinia virus GLV-109. In U-87 glioma xenograft murine models the combination of fractionated ionizing radiation with GLV-1h164, a vaccinia virus also targeting VEGF, resulted in the best volumetric tumor response and a drastic decrease in vascular endothelial growth factor. Histological analysis of embedded tumor sections 14 days after viral administration confirmed that blocking VEGF translated into a decrease in vessel number to 30\% of vessel number found in control tumors in animals treated with GLV-164 and fractionated IR which was lower than for all other treatment groups. Our experiments with GLV-1h164 and fractionated radiotherapy have shown that in addition to ionizing radiation and viral induced tumor cell destruction we were able to effectively target the tumor vasculature. This was achieved by enhanced viral replication translating in increased levels of GLAF-2 disrupting tumor vessels as well as the radiosensitization of tumor vasculature to IR by blocking VEGF. Our preclinical results have important clinical implications of how focal radiotherapy can be combined with systemic oncolytic viral administration for highly aggressive, locally advanced tumors with the potential, by using a vaccinia virus targeting human vascular endothelial growth factor, to further increase tumor radiation sensitivity by engaging the vascular component in addition to cancer cells.}, subject = {Gliom}, language = {en} } @phdthesis{Donat2011, author = {Donat, Ulrike}, title = {Detektion und Therapie von Metastasen des humanen Prostatakarzinoms durch das onkolytische Vaccinia-Virus GLV-1h68}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-56421}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2011}, abstract = {Zurzeit sterben j{\"a}hrlich ca. 11.000 M{\"a}nner in Deutschland am Prostatakarzinom. Damit stellt dies die zweith{\"a}ufigste Krebstodesursache von M{\"a}nnern dar. Da das Prostatakarzinom h{\"a}ufig asymptomatisch verl{\"a}uft, wird die Erkrankung oftmals erst so sp{\"a}t erkannt, dass zum Zeitpunkt der Diagnose bereits eine Metastasierung stattgefunden hat. Durch metastasierende Prostatakarzinomzellen werden Lymphknoten, Knochen und Lungen befallen. Es sind zwei unterschiedliche Verbreitungsarten von metastasierenden Tumorzellen beschrieben. Zum einen kann eine Migration {\"u}ber Lymphgef{\"a}ße erfolgen, ein Prozess der als lymphatische Metastasierung bezeichnet wird. Zum anderen k{\"o}nnen Tumorzellen {\"u}ber das Blutsystem im K{\"o}rper zirkulieren: die h{\"a}matogene Metastasierung. In dieser Arbeit wurde die lymphatische Metastasierung der humanen Prostatakarzinomzellline PC-3 im Detail analysiert und Teilaspekte der h{\"a}matogenen Verteilung untersucht. Ausgangspunkt der Untersuchungen bildete die Vergr{\"o}ßerung lumbaler und renaler Lymphknoten in PC-3-Tumor-tragenden M{\"a}usen 60 Tage nach der Implantation von PC-3-Zellen. Es wurde daraufhin der zeitliche Verlauf der Vergr{\"o}ßerung untersucht und festgestellt, dass sowohl das Volumen als auch die Anzahl vergr{\"o}ßerter Lymphknoten von Woche zu Woche nach Implantation der PC-3-Tumore zunehmen. Anschließend wurden alle vergr{\"o}ßerten Lymphknoten bez{\"u}glich des Vorhandenseins von metastasierenden humanen PC-3-Zellen in den M{\"a}usen untersucht. Dies geschah mit Hilfe einer RT-PCR unter Verwendung von Primern f{\"u}r humanes β-Aktin. Sechs Wochen nach Implantation konnten in 90 \% der vergr{\"o}ßerten Lymphknoten PC-3-Zellen nachgewiesen werden. Weiterhin wurde durch lentivirale Transduktion das Gen f{\"u}r das rot fluoreszierende Protein (RFP) in die PC-3-Zellen inseriert, wodurch eine Visualisierung dieser Zellen in der Maus erm{\"o}glicht wurde. Es konnten metastasierende PC-3-RFP-Zellen in lumbalen und renalen Lymphknoten PC-3-RFP-Tumor-tragender M{\"a}use nachgewiesen werden. Ebenso konnte mittels RFP gezeigt werden, dass die Lymphknotenmetastasierung in Abh{\"a}ngigkeit von der Lokalisation des PC-3-RFP-Tumors erfolgt. Es kam zur Metastasierung jener Lymphknoten, in deren Einzugsgebiet sich der PC-3-Tumor befand. Es wurde eine PC-3-RFP-Zellmigration zwischen lumbalen und renalen Lymphknotenmetastasen nachgewiesen und bei immunhistologischen Untersuchungen stellte sich heraus, dass PC-3-RFP-Zellen tats{\"a}chlich in lymphatischen Bahnen zwischen lumbalen und renalen Lymphknotenmetastasen migrieren. Außerdem wurde gezeigt, dass es von Woche zu Woche nach Implantation von PC-3-Zellen zu einer Zunahme der Anzahl von Lymphgef{\"a}ßen in PC-3-Tumoren kommt. Die Zunahme der Lymphgef{\"a}ßdichte korrelierte hierbei positiv mit der Bildung von Lymphknotenmetastasen. Es konnten weiterhin neben Lymphknotenmetastasen h{\"a}matogene Mikrometastasen in den Lungen PC-3-RFP-Tumor-tragender M{\"a}use beobachtet werden. Da die Haupttodesursache von Prostatakarzinompatienten in der Bildung von Metastasen liegt, ist es von herausragender Bedeutung eine effektive Therapie gegen lymphatische und h{\"a}matogene Metastasen zu entwickeln. Aus diesem Grund erlangt die onkolytische Virustherapie große Bedeutung. Deshalb wurde als zweiter Aspekt in dieser Arbeit der Einfluss des onkolytischen Vaccinia-Virus GLV-1h68 auf den Prozess der PC-3-Zellmetastasierung untersucht. Dabei konnte zun{\"a}chst gezeigt werden, dass GLV-1h68 in der Lage ist, erfolgreich sowohl migrierende PC-3-Zellen als auch metastasierende PC-3-Zellen in Lymphknoten zu kolonisieren. In der Folge wurde deshalb ein m{\"o}glicher Metastasen-inhibierender Effekt von GLV-1h68 untersucht. Hierbei stellte sich heraus, dass GLV-1h68 drei Wochen nach intraven{\"o}ser Injektion eine signifikante Reduktion der Anzahl der f{\"u}r PC-3-Zellen positiven Lymphknoten bewirkt. Des Weiteren konnte ein inhibierender Effekt von GLV-1h68 auf die im Blut zirkulierenden PC-3-Zellen und auf h{\"a}matogene Metastasen in den Lungen beobachtet werden. Durch intraven{\"o}se Injektion von GLV-1h68 in PC-3-RFP-Tumor-tragenden M{\"a}usen konnte gezeigt werden, dass es zu einer pr{\"a}ferentiellen Virus-Kolonisierung der Lymphknotenmetastasen im Vergleich zu den Tumoren kommt. Auch nach intraperitonealer und intratumoraler Injektion von GLV-1h68 konnte eine pr{\"a}ferentielle Virus-Kolonisierung der Lymphknotenmetastasen gezeigt werden. Dar{\"u}ber hinaus wurden die Lymph- und Blutgef{\"a}ße von PC-3-Tumoren und Lymphknotenmetastasen analysiert. Hierbei wurde gezeigt, dass es sieben Tage nach intraven{\"o}ser Injektion von GLV-1h68 zu einer signifikanten Abnahme von beiden Gef{\"a}ßarten kam. Es wurde in dieser Arbeit somit gezeigt, dass GLV-1h68 in der Lage ist, sowohl lymphatische als auch h{\"a}matogene Metastasen der Prostatakarzinomzelllinie PC-3 erfolgreich zu eliminieren. Folglich d{\"u}rften onkolytische Vaccinia-Viren ein vielversprechendes Therapeutikum f{\"u}r die Behandlung des fortgeschrittenen Prostatakarzinoms darstellen.}, subject = {Prostatakrebs}, language = {de} } @phdthesis{Cook2012, author = {Cook, Vanessa Janine}, title = {Protection of healthy tissues from infection with systemically administered vaccinia virus strains}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-69654}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2012}, abstract = {Oncolytic virotherapy using recombinant vaccinia virus strains is a promising approach for the treatment of cancer. To further improve the safety of oncolytic vaccinia viruses, the cellular microRNA machinery can be applied as the host's own security mechanism to avoid unwanted viral replication in healthy tissues. MicroRNAs are a class of small single-stranded RNAs which due to their ability to mediate post-transcriptional gene-silencing, play a crucial role in almost every regulatory process in cellular metabolism. Different cancers display unique microRNA expression patterns, showing significant up- or downregulation of endogenously expressed microRNAs. Furthermore, the behavior of cancer cells can be altered by either adding microRNAs known to inhibit cancer cell spread and proliferation or suppressing cancer promoting microRNAs (oncomirs) making microRNAs promising targets for cancer gene therapy. The cell's own RNAi machinery can also be utilized to control viral replication due to the virus dependence on the host cell replication machinery, a process controlled by microRNAs. GLV-1h68 is a replication-competent recombinant oncolytic vaccinia virus constructed and generated by Genelux Corp., San Diego, CA, USA which carries insertions of three reporter gene cassettes for detection and attenuation purposes and is currently being evaluated for cancer treatment in clinical trials. Though there are hardly any side effects found in GLV-1h68 mediated oncolytic therapy an increased tropism for replication exclusively in cancer cells is desirable. Therefore it was investigated whether or not further cancer cell specificity of a recombinant vaccinia virus strain could be obtained without compromising its oncolytic activity using microRNA interference. Let-7a is a well characterized microRNA known to be expressed in high levels in healthy tissues and strongly downregulated in most cancers. To control vaccinia virus replication rates, four copies of the mature human microRNA let-7a target sequence were cloned behind the stop codon in the 3'end of the vaccinia virus D4R gene, using a GLV-1h68 derivative, GLV-1h190, as parental strain yielding the new recombinant virus strain GLV-1h250. The D4R gene belongs to the group of early transcribed vaccinia genes and encodes an essential enzyme, uracil DNA glycosylase, which catalyzes the removal of uracil residues from double-stranded DNA. A defect in D4R prevents vaccinia virus from entering into the intermediate and late phase of replication, leading to an aborted virus replication. After expression of the microRNA target sequence from the vaccinia virus genome, the endogenously expressed microRNA-let-7a should recognize its target structure within the viral mRNA transcript, thereby binding and degrading the viral mRNA which should lead to a strong inhibition of the virus replication in healthy cells. GLV-1h250 replication rates in cancerous A549 lung adenocarcinoma cells, which show a strong down-regulation of microRNA let-7a, was comparable to the replication rates of its parental strain GLV-1h190 and the control strain GLV-1h68. In contrast, GLV-1h250 displayed a 10-fold decrease in viral replication in non-cancerous ERC cells when compared to GLV-1h190 and GLV-1h68. In A549 tumor bearing nude mice GLV-1h250 replicated exclusively in the tumorous tissue and resulted in efficient tumor regression without adverse effects leading to the conclusion that GLV-1h250 replicates preferentially in cancerous cells and tissues, which display low endogenous let-7a expression levels.}, subject = {Vaccinia-Virus}, language = {en} } @phdthesis{Krueger2012, author = {Kr{\"u}ger, Beate}, title = {Integration und Kombination bioinformatischer Methoden in Biotechnologie, synthetischer Biologie und Pharmaindustrie}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-70702}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2012}, abstract = {Die Bioinformatik ist eine interdisziplin{\"a}re Wissenschaft, welche Probleme aus allen Lebenswissenschaften mit Hilfe computergest{\"u}tzter Methoden bearbeitet. Ihr Ziel ist es, die Verarbeitung und Interpretation großer Datenmengen zu erm{\"o}glichen. Zudem unterst{\"u}tzt sie den Designprozess von Experimenten in der Synthetischen Biologie. Die synthetische Biologie besch{\"a}ftigt sich mit der Generierung neuer Komponenten und deren Eigenschaften, welche durch die Behandlung und Manipulation lebender Organismen oder Teilen daraus entstehen. Ein besonders interessantes Themengebiet hierbei sind Zweikomponenten-Systeme (Two-Component System, TCS). TCS sind wichtige Signalkaskaden in Bakterien, welche in der Lage sind Informationen aus der Umgebung in eine Zelle zu {\"u}bertragen und darauf zu reagieren. Die vorliegende Dissertation besch{\"a}ftigt sich mit der Beurteilung, Nutzung und Weiterentwicklung von bioinformatischen Methoden zur Untersuchung von Proteininteraktionen und biologischen Systemen. Der wissenschaftliche Beitrag der vorliegenden Arbeit kann in drei Aspekte unterteilt werden: - Untersuchung und Beurteilung von bioinformatischen Methoden und Weiterf{\"u}hrung der Ergebnisse aus der vorhergehenden Diplomarbeit zum Thema Protein-Protein-Interaktionsvorhersagen. - Analyse genereller evolution{\"a}rer Modifikationsm{\"o}glichkeiten von TCS sowie deren Design und spezifische Unterschiede. - Abstraktion bzw. Transfer der gewonnenen Erkenntnisse auf technische und biologische Zusammenh{\"a}nge. Mit dem Ziel das Design neuer Experimente in der synthetischen Biologie zu vereinfachen und die Vergleichbarkeit von technischen und biologischen Prozessen sowie zwischen Organismen zu erm{\"o}glichen. Das Ergebnis der durchgef{\"u}hrten Studie zeigte, dass Zweikomponenten-Systeme in ihrem Aufbau sehr konserviert sind. Nichtsdestotrotz konnten viele spezifische Eigenschaften und drei generelle Modifikationsm{\"o}glichkeiten entdeckt werden. Die Untersuchungen erm{\"o}glichten die Identifikation neuer Promotorstellen, erlaubten aber auch die Beschreibung der Beschaffenheit unterschiedlicher Signalbindestellen. Zudem konnten bisher fehlende Komponenten aus TCS entdeckt werden, ebenso wie neue divergierte TCS-Dom{\"a}nen im Organismus Mycoplasma. Eine Kombination aus technischen Ans{\"a}tzen und synthetischer Biologie vereinfachte die gezielte Manipulation von TCS oder anderen modularen Systemen. Die Etablierung der vorgestellten zweistufigen Modul-Klassifikation erm{\"o}glichte eine effizientere Analyse modular aufgebauter Prozesse und erlaubte somit das molekulare Design synthetischer, biologischer Anwendungen. Zur einfachen Nutzung dieses Ansatzes wurde eine frei zug{\"a}ngliche Software GoSynthetic entwickelt. Konkrete Beispiele demonstrierten die praktische Anwendbarkeit dieser Analysesoftware. Die vorgestellte Klassifikation der synthetisch-biologischen und technischen Einheiten soll die Planung zuk{\"u}nftiger Designexperimente vereinfachen und neue Wege f{\"u}r sinnverwandte Bereiche aufzeigen. Es ist nicht die Hauptaufgabe der Bioinformatik, Experimente zu ersetzen, sondern resultierende große Datenmengen sinnvoll und effizient auszuwerten. Daraus sollen neue Ideen f{\"u}r weitere Analysen und alternative Anwendungen gewonnen werden, um fehlerhafte oder falsche Ans{\"a}tze fr{\"u}hzeitig zu erkennen. Die Bioinformatik bietet moderne, technische Verfahren, um vertraute, aber oft m{\"u}hsame experimentelle Wege durch neue, vielversprechende Ans{\"a}tze zur Datenstrukturierung und Auswertung großer Datenmengen zu erg{\"a}nzen. Neue Sichtweisen werden durch die Erleichterung des Testprozederes gef{\"o}rdert. Die resultierende Zeitersparnis f{\"u}hrt zudem zu einer Kostenreduktion.}, subject = {Biotechnologie}, language = {de} }