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The cancer stem cell hypothesis is a cancer development model which elicited great interest in the last decades stating that cancer heterogeneity arises from a stem cell through asymmetrical division. The Cancer Stem Cell subset is described as the only population to be tumorigenic and having the potential to renew. Conventional therapy often fails to eradicate CSC resulting in tumor relapse. Consequently, it is of great inter-est to eliminate this subset of cells to provide the best patient outcome. In the last years several approaches to target CSC were developed, one of them being immunotherapeu-tic targeting with antibodies. Since markers associated with CSC are also expressed on normal stem cells or healthy adjacent tissue in colorectal cancer, dual targeting strate-gies are preferred over targeting only a single antigen. Subsequently, the idea of dual targeting two CSC markers in parallel by a newly developed split T cell-engaging anti-body format termed as Hemibodies emerged. In a preliminary single cell RNA sequenc-ing analysis of colorectal cancer cells CD133, CD24, CD166 and CEA were identified as suitable targets for the combinatorial targeting strategy. Therefore, this study focused on trispecific and trivalent Hemibodies comprising a split binding moiety against CD3 and a binding moiety against either CD133, CD24, CD166 or CEA to overcome the occurrence of resistance and to efficiently eradicate all tumor cells including the CSC compartment. The study showed that the Hemibody combinations CD133xCD24, CD133xCD166 and CD133xCEA are able to eliminate double positive CHO cells with high efficacy while having a high specificity indicated by no killing of single antigen positive cells. A thera-peutic window ranging between one to two log levels could be achieved for all combina-tions mentioned above. The combinations CD133xCD24 and CD133xCD166 further-more proved its efficacy and specificity on established colorectal cancer cell lines. Be-sides the evaluation of specificity and efficacy the already introduced 1st generation of Hemibodies could be improved into a 2nd generation Hemibody format with increased half-life, stability and production yield. In future experiments the applicability of above-mentioned Hemibodies will be proven on patient-derived micro tumors to also include variables like tumor microenvironment and infiltration.
Generation of early human neuroepithelial progenitors from primary cells for biomedical applications
(2018)
Patient-specific induced pluripotent stem cells (iPSCs) emerged as a promising cell source for disease modeling and drug screening as well as a virtually unlimited source for restorative therapy. The thesis deals with three major topics to help realizing biomedical applications with neural stem cells.
To enable the generation of transgene-free iPSCs, alternatives to retroviral reprogramming were developed. Hence, the adaptation and evaluation of reprogramming using excisable lentiviral constructs, Sendai virus (SeV) and synthetic mRNA-based methods was assessed in the first part of this thesis. hiPSCs exhibit the pluripotency markers OCT4, SSEA-4, TRA1-60 which were confirmed by immunofluorescence and flow cytometry. Besides, the potential to differentiate in cell types of all three germ layers was detected, confirming pluripotent identity of proliferating colonies resulting from various reprogramming strategies. However, major differences such as high efficiency with SeV in contrast to a relatively low efficiency with mRNA in regard to passage number and the phenotype of starting fibroblasts were observed. Furthermore, a prolonged clone- and passage-dependent residual presence of viral RNA genes was identified in SeV-iPSCs for up to 23 passages using RT-PCR underlining the importance of careful monitoring of clone selection. In contrast, viral-free reprogramming by synthetic mRNA represents a fully non-integrative approach but requires further refinement to be efficiently applicable to all fibroblasts.
The second part of this thesis deals with the establishment of a rapid monolayer approach to differentiate neural progenitor cells from iPSCs. To achieve this, a two-step protocol was developed allowing first the formation of a stable, primitive NPC line within 7 days which was expanded for 2-3 passages. In a second step, a subsequent adaptation to conditions yielding neural rosette-like NPCs followed. Both neural lines were demonstrated to be expandable, cryopreservable and negative for the pluripotency marker OCT4. Furthermore, a neural precursor identity including SOX1, SOX2, PAX6, Nestin was confirmed by immunofluorescence and quantitative RT-PCR. Moreover, the differentiation resulted in TUJ1-positive neurons and GFAP-positive astrocytes. Nonetheless, the outcome of glial differentiation from primitive NSCs remained low, whereas FGF/EGF-NPCs were efficiently differentiated into GFAP-positive astrocytes which were implicated in a cellular model of the blood brain barrier.
The third and major objective of this study was to generate human early neural progenitor cells from fetal brain tissue with a wide neural differentiation capacity. Therefore, a defined medium composition including small molecules and growth factors capable of modulation of crucial signaling pathways orchestrating early human development such as SHH and FGF was assessed. Indeed, specific culture conditions containing TGFβ inhibitor SB431542, SHH agonist Purmorphamine, GSK3β inhibitor CHIR99021 and basic FGF, but no EGF enabled robust formation of early neuroepithelial progenitor (eNEP) colonies displaying a homogeneous morphology and a high proliferation rate. Moreover, primary eNEPs exhibit a relatively high clonogenicity of more than 23 % and can be monoclonally expanded for more than 45 passages carrying a normal karyotype. Characterization by immunofluorescence, flow cytometry and quantitative RT-PCR revealed a distinct NPC profile including SOX1, PAX6, Nestin and SOX2 and Prominin. Furthermore, primary eNEPs show NOTCH and HES5 activation in combination with non-polarized morphology, indicative of an early neuroepithelial identity. Microarray analysis unraveled SOX11, BRN2 and other HES-genes as characteristic upregulated genes. Interestingly, eNEPs were detected to display ventral midbrain/hindbrain regional identity. The validation of yielded cell types upon differentiation indicates a strong neurogenic potential with more than 90 % of TUJ1-positive neurons. Moreover, astrocytes marked by GFAP and putative myelin structures indicating oligodendrocytes were identified. Electrophysiological recordings revealed functionally active neurons and immunofluorescence indicate GABAergic, glutamatergic, dopaminergic and serotonergic subtypes. Additionally, putative physiological synapse formation was observed by the presence of Synapsin and PSD-95 as well as by ultrastructural examination. Notably, rare neurons stained positive for the peripheral neuronal marker Peripherin suggesting the potential of eNEPS to give rise to cells of neural tube and neural crest origin. By the application of specific differentiation protocols an increase of TH-positive neurons or neural crest-derivatives such as putative A- and C-sensory neurons and mesenchymal cells was identified. Taken together, primary eNEPs might help to elucidate mechanisms of early human neurodevelopment and will serve as a novel source for cell replacement and further biomedical applications.
The DREAM complex plays an important role in regulation of gene expression during the cell cycle. It was previously shown that the DREAM subunits LIN9 and B-MYB are required for early embryonic development and for the maintenance of the inner cell mass in vitro. In this work the effect of LIN9 or B-MYB depletion on embryonic stem cells (ESC) was examined. It demonstrates that LIN9 and B-MYB knock down changes the cell cycle distribution of ESCs and results in an accumulation of cells in G2 and M and in an increase of polyploid cells. By using genome-wide expression studies it was revealed that the depletion of LIN9 leads to downregulation of mitotic genes and to upregulation of differentiation-specific genes. ChIP-on chip experiments determined that mitotic genes are direct targets of LIN9 while lineage specific markers are regulated indirectly. Importantly, depletion of LIN9 does not alter the expression of the pluripotency markers Sox2 and Oct4 and LIN9 depleted ESCs retain alkaline phosphatase activity. I conclude that LIN9 is essential for proliferation and genome stability of ESCs by activating genes with important functions in mitosis and cytokinesis. The exact molecular mechanisms behind this gene activation are still unclear as no DREAM subunit features a catalytically active domain. It is assumed that DREAM interacts with other proteins or co-factors for transcriptional activation. This study discovered potential binding proteins by combining in vivo isotope labeling of proteins with mass spectrometry
(MS) and further analysed the identified interaction of the tight junction protein ZO-2 with DREAM which is cell cycle dependent and strongest in S-phase. ZO-2 depletion results in reduced cell proliferation and decreased G1 gene expression. As no G2/M genes, typical DREAM targets, are affected upon ZO-2 knock down, it is unlikely that ZO-2 binding is needed for a functional DREAM complex. However, this work demonstrates that with (MS)-based quantitative proteomics, DREAM interacting proteins can be identified which might help to elucidate the mechanisms underlying DREAM mediated gene activation.
Effects of stem cell transcription factor-expressing vaccinia viruses in oncolytic virotherapy
(2012)
Cancer remains the second leading cause of death in the industrialized. The data from many different studies investigating the nature of cancer-initiating cells coined the description ‘cancer stem cells’ and has major implications on conventional cancer therapy. Thus, to improve the outcome of cancer treatment and to lower negative side effects, the development of novel therapeutic regimens is indispensable. It has been demonstrated in many preclinical studies that oncolytic virotherapy using vaccinia virus may provide a powerful and well-tolerable new tool in cancer therapy which is currently investigated in several clinical trials (Phase I & II) as stand-alone treatment or in combination with conventional cancer therapy. Cancer-initiating cells and stem cells share a variety of characteristics like the ability to self-renew, differentiation potential, quiescence, drug and radiation resistance, activation and inhibition of similar signaling pathways as well as expression of cell surface markers and stem cell-related genes. In this work, two new recombinant vaccinia viruses expressing the transcription factors Nanog (GLV-1h205) and Oct4 (GLV-1h208) were engineered to provide deeper insight of these stem cell master regulators in their significance of cancer-initiation and their impact on oncolytic virotherapy. Both viruses were analyzed for their replication potential in A549 and PC-3 human cancer cells. Marker gene expression was assessed by RT-PCR, SDS-PAGE and Western blotting, ELISA or immunocytochemistry.Furthermore, the effect of GLV-1h205 infection on the cell cycle in A549 cells was analyzed. Next, the effects of virus-mediated expression of stem cell transcription factors on therapeutic efficacy and survival rates in A549 xenograft mouse models was analyzed. A non-functional Nanog mutant-expressing virus strain (GLV-1h321) was engineered to analyze whether the observed therapeutic benefits were promoter- or payload-driven. Furthermore, this study analyzed the potential of GLV-1h68 to infect, replicate in, and lyse colorectal cancer cell lines to study whether oncolytic vaccinia viruses can be potential new and less invasive treatment regimens for late stage colorectal cancer. Marker gene expression was assessed by fluorescence microscopy and FACS. The transcription factor Klf4 is highly expressed in quiescent, terminally differentiated cells in the colonic epithelium whereas it is dramatically downregulated in colon cancers. Klf4 expression leads to cell growth arrest and inhibits Wnt signaling by binding to beta-catenin. To further improve the treatment of colorectal cancers, new recombinant vaccinia viruses (GLV-1h290-292) mediating the expression of differing amounts of the tumor suppressor Klf4 by using different promoter strengths were engineered. Initial characterization of recombinant vaccinia viruses expressing Klf4 by replication assay, cell viability assay, SDS-PAGE and Western blotting, immuncytochemistry and analysis of protein functionality by qPCR and ELISA analysis for cellular beta-catenin expression, demonstrated promoter strength-dependent expression of and impact of Klf4. To further boost the effects of tumor suppressor Klf4, a vaccinia virus strain expressing Klf4 with a C-terminal fusion of the TAT transduction domain (GLV-1h391) was engineered. Treatment of HT-29 non-responder tumors in vivo with GLV-1h291 and GLV-1h391 led to significant tumor growth inhibition and improved overall survival compared to GLV-1h68. This makes the Klf4-TAT expressing GLV-1h391 a promising candidate for the treatment of colorectal cancer in man.