@phdthesis{Hart2004, author = {Hart, Stefan}, title = {Characterisation of the molecular mechanisms of EGFR signal transactivation in human cancer}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-10067}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2004}, abstract = {In a variety of established tumour cell lines, but also in primary mammary epithelial cells metalloprotease-dependent transactivation of the EGFR, and EGFR characteristic downstream signalling events were observed in response to stimulation with physiological concentrations of GPCR agonists such as the mitogens LPA and S1P as well as therapeutically relevant concentrations of cannabinoids. Moreover, this study reveals ADAM17 and HB-EGF as the main effectors of this mechanism in most of the cancer cell lines investigated. However, depending on the cellular context and GPCR agonist, various different members of the ADAM family are selectively recruited for specific ectodomain shedding of proAR and/or proHB-EGF and subsequent EGFR activation. Furthermore, biological responses induced by LPA or S1P such as migration in breast cancer and HNSCC cells, depend on ADAM17 and proHB-EGF/proAR function, respectively, suggesting that highly abundant GPCR ligands may play a role in tumour development and progression. Moreover, EGFR signal transactivation could be identified as the mechanistic link between cannabinoid receptors and the activation of mitogen activated protein kinases (MAPK) ERK1/2 as well as pro-survival Akt/PKB signalling. Depending on the cellular context, cannabinoid-induced signal cross-communication was mediated by shedding of proAmphiregulin and/or proHB-EGF by ADAM17. Most importantly, our data show that concentrations of THC comparable to those detected in the serum of patients after THC administration accelerate proliferation of cancer cells instead of apoptosis and thereby may contribute to cancer progression in patients.}, subject = {Epidermaler Wachstumsfaktor-Rezeptor}, language = {en} } @phdthesis{Robubi2007, author = {Robubi, Armin}, title = {RAF Kinases: Pathway, Modulation and Modeling}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-26953}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2007}, abstract = {The Ras/RAF/MEK/ERK cascade is a central cellular signal transduction pathway involved in cell proliferation, differentiation, and survival where RAF kinases are pivotal kinases implicated in cancer. The development of specific irreversible kinase inhibitors is a rewarding but difficult aim. CI-1033 was developed to irreversibly inhibit erbB receptor tyrosine kinases by reacting to the Cys113 residue (p38alpha MAP kinase numbering) of the kinase domain. In this study we tried a similar approach to target the RAF oncoproteins which posses a similar cysteine at position 108 in the hinge region between the small n-lobe and the large c-lobe of the kinase domain. A novel synthetic approach including a lyophilization step allowed us the synthesis of a diphenyl urea compound with an epoxide moiety (compound 1). Compound 1 possessed inhibitory activity in vitro. However our time kinetics experiments and mass spectroscopic studies clearly indicate that compound 1 does not react covalently with the cysteine residue in the hinge region. Moreover, in cell culture experiments, a strong activation of the RAF signaling pathway was observed, an effect which is known from several other RAF kinase inhibitors and is here reported for the first time for a diphenyl urea compound, to which the clinically used unspecific kinase inhibitor BAY 43-9006 (Sorafinib, Nexavar) belongs. Although activation was apparently independent on B- and C-RAF hetero-oligomerization in vitro, in vivo experiments support such a mechanism as the activation did not occur in starved knockout cells lacking either B-RAF or C-RAF. Furthermore, we developed a mathematical model of the Ras/RAF/MEK/ERK cascade demonstrating how stimuli induce different signal patterns and thereby different cellular responses, depending on cell type and the ratio between B-RAF and C-RAF. Based on biochemical data for activation and dephosphorylation, we set up differential equations for a dynamical model of the Ras/RAF/MEK/ERK cascade. We find a different signaling pattern and response result for B-RAF (strong activation, sustained signal) and C-RAF (steep activation, transient signal). We further support the significance of such differential modulatory signaling by showing different RAF isoform expression in various cell lines and experimental testing of the predicted kinase activities in B-RAF, C-RAF as well as mutated versions. Additionally the effect of the tumor suppressor DiRas3 (also known as Noey2 or ARHI) on RAF signaling was studied. I could show that DiRas3 down-regulates the mitogenic pathway by inhibition of MEK, a basis for a refined model of the Ras/RAF/MEK/ERK cascade.}, subject = {Systembiologie}, language = {en} } @phdthesis{Laisney2010, author = {Laisney, Juliette Agn{\`e}s Genevi{\`e}ve Claire}, title = {Characterisation and regulation of the Egfr/Egfr ligand system in fish models for melanoma}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-51369}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2010}, abstract = {Fish of the genus Xiphophorus belong to the oldest animal models in cancer research. The oncogene responsible for the generation of spontaneous aggressive melanoma encodes for a mutated epidermal growth factor receptor (Egfr) and is called xmrk for Xiphophorus melanoma receptor kinase. Xmrk constitutive activation mechanisms and subsequent signaling pathways have already been investigated and charaterized but it is still unknown if Egfr ligands may also play a role in Xmrk-driven melanoma formation. To investigate the potential role of Egfr ligands in Xmrk-driven melanoma, I firstly analyzed the evolution of teleost and tetrapod Egfr/Egfr ligand systems. I especially focused on the analysis on the medaka fish, a closely related species to Xiphophorus, for which the whole genome has been sequenced. I could identify all seven Egfr ligands in medaka and could show that the two teleost-specific Egfr copies of medaka display dissimilar expression patterns in adult tissues together with differential expression of Egfr ligand subsets, arguing for subfunctionalization of receptor functions in this fish. Our phylogenetic and synteny analyses supported the hypothesis that only one gene in the chordate ancestor gave rise to the diversity of Egfr ligands found in vertebrate genomes today. I also could show that the Egfr extracellular subdomains implicated in ligand binding are not evolutionary conserved between tetrapods and teleosts, making the use of heterologous ligands in experiments with fish cells debatable. Despite its well understood and straight-forward process, Xmrk-driven melanomagenesis in Xiphophorus is problematic to further investigate in vivo. Our laboratory recently established a new melanoma animal model by generating transgenic mitf::xmrk medaka fishes, a Xiphophorus closely related species offering many more advantages. These fishes express xmrk under the control of the pigment-cell specific Mitf promoter. During my PhD thesis, I participated in the molecular analysis of the stably transgenic medaka and could show that the Xmrk-induced signaling pathways are similar when comparing Xiphophorus with transgenic mitf::xmrk medaka. These data together with additional RNA expression, protein, and histology analyses showed that Xmrk expression under the control of a pigment cell-specific promoter is sufficient to induce melanoma in the transgenic medaka, which develop very stereotyped tumors, including uveal and extracutaneous melanoma, with early onset during larval stages. To further investigate the potential role of Egfr ligands in Xmrk-driven melanoma, I made use of two model systems. One of them was the above mentioned mitf::xmrk medaka, the other was an in-vitro cell culture system, where the EGF-inducible Xmrk chimera HERmrk is stably expressed in murine melanocytes. Here I could show that HERmrk activation strongly induced expression of amphiregulin (Areg) and heparin-binding EGF-like growth factor (Hbegf) in melanocytes. This regulation was dependent on the MAPK and SRC signaling pathways. Moreover, upregulation of Adam10 and Adam17, the two major sheddases of Egfr ligands, was observed. I also could demonstrate the functionality of the growth factors by invitro analyses. Using the mitf::xmrk medaka model I could also show the upregulation of a subset of ligand genes, namely egf, areg, betacellulin (btc) and epigen (epgn) as well as upregulation of medaka egfrb in tumors from fish with metastatic melanoma. All these results converge to support an Xmrk-induced autocrine Egfr ligand loop. Interestingly, my in-vitro experiments with conditioned supernatant from medaka Egf- and Hbegf-producing cells revealed that not only Xiphophorus Egfrb, but also the pre-activated Xmrk could be further stimulated by the ligands. Altogether, I could show with in-vitro and in-vivo experiments that Xmrk is capable of inducing a functional autocrine Egfr ligand loop. These data confirm the importance of autocrine loops in receptor tyrosine kinase (RTK)-dependent cancer development and show the possibility for a constitutively active RTK to strengthen its oncogenic signaling by ligand binding.}, subject = {Schwertk{\"a}rpfling}, language = {en} } @phdthesis{Polzien2011, author = {Polzien, Lisa}, title = {BAD Phosphorylation: A Novel Link between Apoptosis and Cancer}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-56919}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2011}, abstract = {BAD (Bcl-2 antagonist of cell death, Bcl-2 associated death promoter) is a pro-apoptotic member of the Bcl-2 protein family that is regulated by phosphorylation in response to survival factors. Although much attention has been devoted to the identification of phosphorylation sites in murine BAD (mBAD), little data are available with respect to phosphorylation of human BAD (hBAD) protein. In this work, we investigated the quantitative contribution of BAD targeting kinases in phosphorylating serines 75, 99 and 118 of hBAD (Chapter 3.1). Our results indicate that RAF kinases phosphorylate hBAD in vivo at these established serine residues. RAF-induced phosphorylation of hBAD was not prevented by MEK inhibitors but could be reduced to control levels by use of the RAF inhibitor Sorafenib (BAY 43-9006). Consistently, expression of active RAF suppressed apoptosis induced by hBAD and the inhibition of colony formation caused by hBAD could be prevented by RAF. In addition, using surface plasmon resonance technique we analyzed the direct consequences of hBAD phosphorylation by RAF with respect to complex formation of BAD with 14-3-3 proteins and Bcl-XL. Phosphorylation of hBAD by active RAF promotes 14-3-3 protein association, whereby the phosphoserine 99 represents the major binding site. Furthermore, we demonstrate in this work that hBAD forms channels in planar bilayer membranes in vitro. This pore-forming capacity is dependent on phosphorylation status and interaction with 14-3-3 proteins. Additionally, we show that hBAD pores possess a funnel-shaped geometry that can be entered by ions and non-charged molecules up to 200 Da (Chapter 3.2). Since both lipid binding domains of hBAD (LBD1 and LBD2) are located within the C-terminal region, we investigated this part of the protein with respect to its structural properties (Chapter 3.3). Our results demonstrate that the C-terminus of hBAD possesses an ordered β-sheet structure in aqueous solution that adopts helical disposition upon interaction with lipid membranes. Additionally, we show that the interaction of the C-terminal segment of hBAD with the BH3 domain results in the formation of permanently open pores, whereby the phosphorylation of serine 118 proved to be necessary for effective pore-formation. In contrast, phosphorylation of serine 99 in combination with 14-3-3 association suppresses formation of channels. These results indicate that the C-terminal part of hBAD controls hBAD function by structural transitions, lipid binding and phosphorylation. Using mass spectrometry we identified in this work, besides the established in vivo phosphorylation sites at serines 75, 99 and 118, several novel hBAD phosphorylation sites (serines 25, 32/34, 97, 124 and 134, Chapter 3.1). To further analyze the regulation of hBAD function, we investigated the role of these newly identified phosphorylation sites on BAD-mediated apoptosis. We found that in contrast to the N-terminal phosphorylation sites, the C-terminal serines 124 and 134 act in an anti-apoptotic manner (Chapter 3.4). Our results further indicate that RAF kinases and PAK1 effectively phosphorylate BAD at serine 134. Notably, in the presence of wild type hBAD, co-expression of survival kinases, such as RAF and PAK1, leads to a strongly increased proliferation, whereas substitution of serine 134 by alanine abolishes this process. Furthermore, we identified hBAD serine 134 to be strongly involved in survival signaling in B-RAF-V600E containing tumor cells and found phosphorylation of this residue to be crucial for efficient proliferation in these cells. Collectively, our findings provide new insights into the regulation of hBAD function by phosphorylation and its role in cancer signaling.}, subject = {Krebs }, 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{Siegl2014, author = {Siegl, Christine}, title = {Degradation of Tumour Suppressor p53 during Chlamydia trachomatis Infections}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-108679}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2014}, abstract = {The intracellular pathogen Chlamydia is the causative agent of millions of new infections per year transmitting diseases like trachoma, pelvic inflammatory disease or lymphogranuloma venereum. Undetected or recurrent infections caused by chlamydial persistence are especially likely to provoke severe pathologies. To ensure host cell survival and to facilitate long term infections Chlamydia induces anti-apoptotic pathways, mainly at the level of mitochondria, and restrains activity of pro-apoptotic proteins. Additionally, the pathogen seizes host energy, carbohydrates, amino acids, lipids and nucleotides to facilitate propagation of bacterial progeny and growth of the chlamydial inclusion. At the beginning of this study, Chlamydia-mediated apoptosis resistance to DNA damage induced by the topoisomerase inhibitor etoposide was investigated. In the course of this, a central cellular protein crucial for etoposide-mediated apoptosis, the tumour suppressor p53, was found to be downregulated during Chlamydia infections. Subsequently, different chlamydial strains and serovars were examined and p53 downregulation was ascertained to be a general feature during Chlamydia infections of human cells. Reduction of p53 protein level was established to be mediated by the PI3K-Akt signalling pathway, activation of the E3-ubiquitin ligase HDM2 and final degradation by the proteasome. Additionally, an intriguing discrepancy between infections of human and mouse cells was detected. Both activation of the PI3K-Akt pathway as well as degradation of p53 could not be observed in Chlamydia-infected mouse cells. Recently, production of reactive oxygen species (ROS) and damage to host cell DNA was reported to occur during Chlamydia infection. Thus, degradation of p53 strongly contributes to the anti-apoptotic environment crucial for chlamydial infection. To verify the importance of p53 degradation for chlamydial growth and development, p53 was stabilised and activated by the HDM2-inhibiting drug nutlin-3 and the DNA damage-inducing compound etoposide. Unexpectedly, chlamydial development was severely impaired and inclusion formation was defective. Completion of the chlamydial developmental cycle was prevented resulting in loss of infectivity. Intriguingly, removal of the p53 activating stimulus allowed formation of the bacterial inclusion and recovery of infectivity. A similar observation of growth recovery was made in infected cell lines deficient for p53. As bacterial growth and inclusion formation was strongly delayed in the presence of activated p53, p53-mediated inhibitory regulation of cellular metabolism was suspected to contribute to chlamydial growth defects. To verify this, glycolytic and pentose phosphate pathways were analysed revealing the importance of a functioning PPP for chlamydial growth. In addition, increased expression of glucose-6-phosphate dehydrogenase rescued chlamydial growth inhibition induced by activated p53. The rescuing effect was even more pronounced in p53-deficient cells treated with etoposide or nutlin-3 revealing additional p53-independent aspects of Chlamydia inhibition. Removal of ROS by anti-oxidant compounds was not sufficient to rescue chlamydial infectivity. Apparently, not only the anti-oxidant capacities of the PPP but also provision of precursors for nucleotide synthesis as well as contribution to DNA repair are important for successful chlamydial growth. Modulation of host cell signalling was previously reported for a number of pathogens. As formation of ROS and DNA damage are likely to occur during infections of intracellular bacteria, several strategies to manipulate the host and to inhibit induction of apoptosis were invented. Downregulation of the tumour suppressor p53 is a crucial point during development of Chlamydia, ensuring both host cell survival and metabolic support conducive to chlamydial growth.}, subject = {Chlamydia-trachomatis-Infektion}, language = {en} } @phdthesis{Wolter2015, author = {Wolter, Patrick}, title = {Characterization of the mitotic localization and function of the novel DREAM target GAS2L3 and Mitotic kinesins are regulated by the DREAM complex, often up-regulated in cancer cells, and are potential targets for anti-cancer therapy}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-122531}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2015}, abstract = {The recently discovered human DREAM complex (for DP, RB-like, E2F and MuvB complex) is a chromatin-associated pocket protein complex involved in cell cycle- dependent gene expression. DREAM consists of five core subunits and forms a complex either with the pocket protein p130 and the transcription factor E2F4 to repress gene expression or with the transcription factors B-MYB and FOXM1 to promote gene expression. Gas2l3 was recently identified by our group as a novel DREAM target gene. Subsequent characterization in human cell lines revealed that GAS2L3 is a microtubule and F-actin cross-linking protein, expressed in G2/M, plays a role in cytokinesis, and is important for chromosomal stability. The aim of the first part of the study was to analyze how expression of GAS2L3 is regulated by DREAM and to provide a better understanding of the function of GAS2L3 in mitosis and cytokinesis. ChIP assays revealed that the repressive and the activating form of DREAM bind to the GAS2L3 promoter. RNA interference (RNAi) mediated GAS2L3 depletion demonstrated the requirement of GAS2L3 for proper cleavage furrow ingression in cytokinesis. Immunofluorescence-based localization studies showed a localization of GAS2L3 at the mitotic spindle in mitosis and at the midbody in cytokinesis. Additional experiments demonstrated that the GAS2L3 GAR domain, a putative microtubule- binding domain, is responsible for GAS2L3 localization to the constriction zones in cytokinesis suggesting a function for GAS2L3 in the abscission process. DREAM is known to promote G2/M gene expression. DREAM target genes include several mitotic kinesins and mitotic microtubule-associated proteins (mitotic MAPs). However, it is not clear to what extent DREAM regulates mitotic kinesins and MAPs, so far. Furthermore, a comprehensive study of mitotic kinesin expression in cancer cell lines is still missing. Therefore, the second major aim of the thesis was to characterize the regulation of mitotic kinesins and MAPs by DREAM, to investigate the expression of mitotic kinesins in cancer cell line panels and to evaluate them as possible anti-cancer targets. ChIP assays together with RNAi mediated DREAM subunit depletion experiments demonstrated that DREAM is a master regulator of mitotic kinesins. Furthermore, expression analyses in a panel of breast and lung cancer cell lines revealed that mitotic kinesins are up-regulated in the majority of cancer cell lines in contrast to non-transformed controls. Finally, an inducible lentiviral-based shRNA system was developed to effectively deplete mitotic kinesins. Depletion of selected mitotic kinesins resulted in cytokinesis failures and strong anti-proliferative effects in several human cancer cell lines. Thus, this system will provide a robust tool for future investigation of mitotic kinesin function in cancer cells.}, subject = {Zellzyklus}, 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{Tsoneva2017, author = {Tsoneva, Desislava}, title = {Humanized mouse model: a system to study the interactions of human immune system with vaccinia virus-infected human tumors in mice}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-118983}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2017}, abstract = {Ein vielversprechender neuer Ansatz zur Behandlung von Krebs beim Menschen ist die Verwendung von onkolytischen Viren, die einen Tumor-spezifischen Tropismus aufweisen. Einer der Top-Kandidaten in diesem Bereich ist das onkolytische Vaccinia Virus (VACV), das bereits vielversprechende Ergebnisse in Tierversuchen und in klinischen Studien gezeigt hat. Aber die von den in vivo in tierischen Modellen erhaltenen Resultate k{\"o}nnten ungenaue Informationen wegen der anatomischen und physiologischen Unterschiede zwischen den Spezies liefern. Andererseits sind Studien in Menschen aufgrund ethischer Erw{\"a}gungen und potenzieller Toxizit{\"a}t nur limitiert m{\"o}glich. Die zahlreichen Einschr{\"a}nkungen und Risiken, die mit den Humanstudien verbunden sind, k{\"o}nnten mit der Verwendung eines humanisierten Mausmodells vermieden werden. Die LIVP-1.1.1, GLV-2b372, GLV-1h68, GLV-1h375, GLV-1h376 and GLV-1h377 VACV St{\"a}mmen wurden von der Genelux Corporation zur Verf{\"u}gung gestellt. GLV-2b372 wurde durch Einf{\"u}gen der TurboFP635 Expressionskassette in den J2R Genlocus des parentalen LIVP-1.1.1-Stammes konstruiert. GLV-1h375, -1h376 and -1h377 kodiert das Gen f{\"u}r den menschlichen CTLA4-blockierenden Einzelketten-Antik{\"o}rper (CTLA4 scAb). Befunde aus Replikations- and Zytotoxizit{\"a}tsstudien zeigten, dass alle sechs Viren Tumorzellen infizieren, sich in ihnen replizieren und sie in Zellkultur schließlich ebenso dosis- und zeitabh{\"a}ngig effizient abt{\"o}ten konnten. CTLA4 scAb und β-Glucuronidase (GusA) Expression sowie Virus Titer in GLV-1h376-infizierten A549-Zellen wurde anhand von ELISA-, β-Glucuronidase- and Standard Plaque-Assays bestimmt. Hierbei zeigte sich eine ausgezeichnete Korrelation mit Korrelationskoeffizienten R2>0.9806. Der durch das GLV-1h376 kodierte CTLA4 scAb wurde erfolgreich aus {\"U}berst{\"a}nden von infizierten CV-1-Zellen gereinigt. CTLA4 scAb hat eine hohe in-vitro-Affinit{\"a}t zu seinem menschlichen CTLA4-Zielmolek{\"u}l sowie abwesende Kreuzreaktivit{\"a}t gegen{\"u}ber murine CTLA4 gezeigt. CTLA4 scAb Funktionalit{\"a}t wurde in Jurkat-Zellen best{\"a}tigt. LIVP-1.1.1, GLV-2b372, GLV-1h68 und GLV-1h376 wurden auch in nicht-tumor{\"o}sen und/oder tumortragenden humanisierten M{\"a}usen getestet. Zun{\"a}chst wurde gezeigt, dass die Injektion von menschlichen CD34+ Stammzellen in die Leber von vorkonditionierten neugeborenen NSG M{\"a}usen zu einer erfolgreichen systemische Rekonstitution mit menschlichen Immunzellen gef{\"u}hrt hat. CD19+-B-Zellen, CD4+- und CD8+-CD3+-T-Zellen, NKp46+CD56- und NKp46+CD56+-NK-Zellen sowie CD33+-myeloischen Zellen wurden detektiert. Die Mehrheit der nachgewisenen humanen h{\"a}matopoetischen Zellen im M{\"a}useblut in den ersten Wochen nach der Humanisierung waren CD19+-B-Zellen, und nur ein kleiner Teil waren CD3+-T-Zellen. Mit der Zeit wurde eine signifikante Ver{\"a}nderung in CD19+/CD3+-Verh{\"a}ltnis beobachtet, die parallel zur Abnahme der B-Zellen und einem Anstieg der T-Zellen kam. Die Implantation von A549-Zellen unter die Haut dieser M{\"a}use f{\"u}hrte zu einem progressiven Tumorwachstum. Bildgebende Verfahren zur Detektion von Virus-vermittelter TurboFP635- und GFP-Expression, Standard Plaque Assays sowie immunohistochemische Analysen best{\"a}tigten die erfolgreiche Invasion der Viren in die subkutanen Tumoren. Die humane CD45+-Zellpopulation in Tumoren wurde haupts{\"a}chlich durch NKp46+CD56bright-NK-Zellen und einen hohen Anteil von aktivierten CD4+- und zytotoxische CD8+-T-Zellen dargestellt. Es wurden jedoch keine signifikanten Unterschiede zwischen den Kontroll- und LIVP-1.1.1-infizierten Tumoren beobachtet, was darauf hindeutete, dass die Rekrutierung von NK- und aktivierten T-Zellen, mehr Tumorgewebe-spezifisch als Virus-abh{\"a}ngig waren. Die GLV-1h376-vermittelten CTLA4 scAb-Expression in den infizierten Tumoren war ebenfalls nicht in der Lage, die Aktivierung von Tumor-infiltrierenden T-Zellen im Vergleich zur Kontrolle und GLV-1h68-behandelten M{\"a}usen, signifikant zu erh{\"o}hen. ELISA-, β-Glucuronidase- and Standard Plaque-Assays zeigten eine eindeutige Korrelation mit den Korrelationskoeffizienten R2>0,9454 zwischen CTLA4 scAb- und GusA-Konzentrationen und Virus Titer in Tumorproben von GLV-1h376-behandelten M{\"a}usen. T-Zellen, die aus der Milz dieser Tumor-tragenden M{\"a}use isoliert wurden, waren funktionell und konnten erfolgreich mit Beads aktiviert werden. Mehr CD25+ und IFN-ɣ+ T-Zellen wurden in der GLV-1h376-Gruppe gefunden, wahrscheinlich aufgrund der CTLA4-Blockade durch die Virus-vermittelte CTLA4 scAb-Expression in den M{\"a}usen. Außerdem wurde eine h{\"o}here Konzentration von IL-2 in dem Kultur{\"u}berstand von diesen Splenozyten im Vergleich zu Kontrollproben nachgewiesen. Im Gegensatz zu der Aktivierung mit Beads konnten T-Zellen von allen drei Maus-Gruppen nicht durch A549 Tumorzellen ex vivo aktiviert werden. Unser Mausmodell hat den besonderen Vorteil, dass sich Tumoren unter der Haut der humanisierten M{\"a}use entwickeln, was eine genaue {\"U}berwachung des Tumorwachstums und Auswertung der onkolytischen Virotherapie erm{\"o}glicht.}, subject = {Vaccinia virus}, language = {en} } @phdthesis{Dejure2018, author = {Dejure, Francesca Romana}, title = {Investigation of the role of MYC as a stress responsive protein}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-158587}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2018}, abstract = {The transcription factor MYC is deregulated in over 70\% of all human tumors and, in its oncogenic form, plays a major role in the cancer metabolic reprogramming, promoting the uptake of nutrients in order to sustain the biosynthetic needs of cancer cells. The research presented in this work aimed to understand if MYC itself is regulated by nutrient availability, focusing on the two major fuels of cancer cells: glucose and glutamine. Initial observations showed that endogenous MYC protein levels strongly depend on the availability of glutamine, but not of glucose. Subsequent analysis highlighted that the mechanism which accounts for the glutamine-mediated regulation of MYC is dependent on the 3´-untranslated region (3´-UTR) of MYC. Enhanced glutamine utilization by tumors has been shown to be directly linked to MYC oncogenic activity and MYC-dependent apoptosis has been observed under glutamine starvation. Such effect has been described in experimental systems which are mainly based on the use of MYC transgenes that do not contain the 3´-UTR. It was observed in the present study that cells are able to survive under glutamine starvation, which leads to cell cycle arrest and not apoptosis, as previously reported. However, enforced expression of a MYC transgene, which lacks the 3´-UTR, strongly increases the percentage of apoptotic cells upon starvation. Evaluation of glutamine-derived metabolites allowed to identify adenosine nucleotides as the specific stimulus responsible for the glutamine-mediated regulation of MYC, in a 3´-UTR-dependent way. Finally, glutamine-dependent MYC-mediated effects on RNA Polymerase II (RNAPII) function were evaluated, since MYC is involved in different steps of global transcriptional regulation. A global loss of RNAPII recruitment at the transcriptional start site results upon glutamine withdrawal. Such effect is overcome by enforced MYC expression under the same condition. This study shows that the 3´UTR of MYC acts as metabolic sensor and that MYC globally regulates the RNAPII function according to the availability of glutamine. The observations presented in this work underline the importance of considering stress-induced mechanisms impinging on the 3´UTR of MYC.}, subject = {Myc}, language = {en} }