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Chromosomal translocations (CTs) are a genetic hallmark of cancer. They could be identified as recurrent genetic aberrations in hemato-malignancies and solid tumors. More than 40% of all "cancer genes" were identified in recurrent CTs. Most of these CTs result in the production of oncofusion proteins of which many have been studied over the past decades. They influence signaling pathways and/or alter gene expression. However, a precise mechanism for how these CTs arise and occur in a nearly identical fashion in individuals remains to be elucidated. Here, we performed experiments that explain the onset of CTs: proximity of genes able to produce prematurely terminated transcripts, which leads to the production of transspliced fusion RNAs, and finally, the induction of DNA double-strand breaks which are subsequently repaired via EJ repair pathways. Under these conditions, balanced chromosomal translocations could be specifically induced.
Chronic inflammation is considered to be a cause of the autoimmune diseases such as rheumatoid arthritis, Alzheimer’s disease, multiple sclerosis, etc. The search for effective compounds with anti-inflammatory properties to combat these diseases is still ongoing. Natural compound narciclasine, derived from plants of Narcissus species, demonstrated its anti-inflammatory activity in in vivo arthritis models. Further investigation of narciclasine’s anti-inflammatory activity together with its impact on the interaction between leukocytes and endothelial cells was the main focus of this PhD thesis.
Narciclasine reduced the infiltration of monocytes and neutrophils to the abdomen and the concentration of the pro-inflammatory cytokines TNF, IL-6 and IL-1β. Together with this, it reduced acute visceral pain caused by zymosan injection. Narciclasine interfered with leukocyte-endothelial cell interaction in both in vivo and in vitro models. In vivo microscopy revealed that the compound reduced rolling, adhesion and transmigration of leukocytes in the vessels of an injured murine cremaster muscle. This observation was confirmed in the in vitro models for adhesion and transmigration where narciclasine reduced the level of leukocyte’s interaction with HUVECs. Narciclasine demonstrated profound anti-inflammatory properties based on its interference with leukocyte-endothelium interaction by downregulation of endothelial cell adhesion molecules expression (ICAM-1, VCAM-1, E-selectin, CX3CL1) and shutdown of NF-κB pathway. All these effects were a result of the TNF receptor 1 protein translation blocking by narciclasine.
In this work the ability of the compound to reduce visceral pain, downregulate the expression of the endothelial cell adhesion molecules and to interfere with the interaction between leukocytes and endothelial cells was demonstrated for narciclasine for the first time. Obtained results open a promising insight into the understanding of narciclasine’s anti-inflammatory properties and justify further investigation of its potential for treatment of inflammatory diseases.
Chapter I of this work addressed the piggyBac (PB) transposon system, a non-viral genome engineering tool that is capable of efficiently performing stable integration of DNA sequences into a target cells genome and has already been used in clinical trials. However, the PB transposase has the problematic property of preferentially integrating transposons near transcriptional start sites (TSSs). This increases the likelihood of causing genotoxic effects, limiting its potential use as a tool in clinical applications. It has been shown in the past that the PB transposase shows physical interactions with BET proteins (e.g. BRD4) through Co-IP experiments. Representatives of these proteins are part of the transcriptional activation complex and are abundant at TSSs. Accordingly, it was previously proposed that this interaction is the underlying cause for the biased integration preference. For the first chapter of this thesis, the goal was to disrupt this interaction potentially modifying said integration preference. A secondary structure hypothesized to be mainly responsible for said interaction was extensively mutated resulting in several PB variants that were analyzed for their interaction capacity through a series of Co-IP experiments with BRD4. In total, seven substitutions were identified (E380F, V390K, T392Y, M394R, K407C, K407Q, and K407V) which exhibited reduced interaction capacity with BRD4. Each of the aforementioned mutants were used to generate integration libraries and, through NGS, it was determined if the integration preferences of the respective mutants had changed. In the immediate range 200 base pairs up- and downstream from known TSSs all mutants used exhibited a reduced integration bias. At a wider observation window 3 kbp up- and downstream from TSSs, further mutants with the substitutions M394R, T392Y and V390K showed a reduction in integration frequency of 17.3%, 1.5% and 5.4%, respectively, compared to the wildtype. Of particular note was the M394R mutant, which showed a reduction in all window sizes analyzed with a maximum of 65% less integration preference in the immediate vicinity of TSSs, theoretically generating a safety advantage over the wildtype transposase.
Chapter II was dedicated to the overall safety improvement for transposon-based gene modification and addresses the time point after the transgene has already been integrated and serious side effects may not be preventable. With this in mind, the aim was to develop a novel suicide-switch that can be stably introduced into cells via transposition, and reliably leads to cell death of the modified cells once activated. A system based on CRISPR/Cas9 was developed, where single guide RNAs were used to guide the Cas9 nuclease to Alu elements. These are short, repetitive sequences, which are distributed over the human genome in more than one million copies. Inducing double strand breaks within these elements would lead to genomic fragmentation and cell death. To be inducible, a transcriptional as well as post- translational control mechanism was added. Transcription of the Cas9 nuclease was regulated using a tet-on system, making expression dependent on doxycycline (DOX) supplementation. Furthermore, a version of the Cas9 nuclease called arC9 was used that allows double strand break generation only in the presence of 4-Hydroxytamoxifen (4-HT). Together with an expression cassette for the Alu-specific guide RNA and an expression cassette for the reverse tetracycline controlled transactivator all components were arranged between transposase-specific recognition sequences on a plasmid to allow transposon-system based gene transfer. The system was tested in HeLa cells. First, conditional expression of the arC9 nuclease was confirmed by addition of 1 μg/ml DOX. Second, the suicide-switch was further induced by adding 200 nM 4-HT and protein extracts were assayed for the KAP1 phosphorylation. Only upon induction with DOX and 4-HT phosphorylated KAP1 was detected, indicating DNA damage. Further, extensive growth and survival experiments were conducted to determine the effect of suicide-switch induction on cell proliferation and survival. Between 24 and 48 hours after induction, a halt in cell division was detected, after which extensive cell death was observed. Within 5 days post induction, >99% of all cells were eliminated. In the absence of both inducers, no significant differences in survival were observed compared to control cells line lacking Alu-specific guide RNAs. Microscopic examinations of the <1% surviving cell fraction revealed a senescence-associated phenotype and showed no signs of resumption of the cell division process. Accordingly, the second chapter of this thesis also achieved its goal in developing a functional suicide-switch that can be inserted into human cells via transposition, is highly dependent on the necessary induction signals, and exhibits excellent elimination capabilities in the context tested.
KMT2A-rearrangements are causative for 70-80% all infant acute lymphoblastic leukemias (Pieters et al., 2019, 2007). Among these, the translocation t(4;11)(q21;23) generating the oncogenic fusion genes KMT2A::AFF1 and AFF1::KMT2A is the most frequent one, accounting for almost every second case of KMT2A-r infant ALL (Meyer et al., 2018). Despite passing a multimodal chemotherapy, 64% of patients achieve an event including relapse or death within four years from diagnosis, and overall survival three years from relapse remains poor with only 17% (Driessen et al., 2016; Pieters et al., 2019, 2007). Vari-ous studies have shown that relapse and therapy resistance were not mediated by chemotherapy-induced mutagenesis as there was no accumulation of secondary mutations in the dominant leukemic clone between diagnosis and relapse (Agraz-Doblas et al., 2019; Andersson et al., 2015; Bardini et al., 2011; Dobbins et al., 2013; Driessen et al., 2013; Mullighan et al., 2007).
Intriguingly, exclusively infant t(4;11) ALL patients were reported to subdivide in two groups depending on the level of HOXA gene cluster expression (Trentin et al., 2009). The HOXAlo group displayed a high expression of IRX1 and the HOXAhi group a low expression of IRX1 (Symeonidou and Ottersbach, 2021; Trentin et al., 2009). Importantly, the HOXAlo/IRX1hi group was characterized to possess a strongly ele-vated relapse incidence compared to the HOXAhi/IRX1lo group (Kang et al., 2012; Stam et al., 2010). IRX1 was identified to upregulate the Early growth response genes EGR1, EGR2 and EGR3 (Kühn et al., 2016).
The doctoral project “EGR-mediated relapse mechanisms in infant t(4;11) acute lymphoblastic leuke-mia” aimed to investigate a potential correlation between the HOXAlo-IRX1-EGR axis and relapse development in infant t(4;11) ALL. The primary objective was to clarify through which molecular mechanism(s) relapse development despite continuous chemotherapy could be achieved. In this context, the role of the EGR genes has been investigated. In addition, this project aimed to disclose molecular targets which could offer novel therapeutic interventions to interfere with therapy resistance and relapse formation.
The generation of O2- by NADPH oxidaes was mainly attributed to immune cells that kill invading bacteria or cancer cells. But importantly, in the past several years, several homologs of the catalytic subunit gp91phox (Nox2) of the phagocytic NADPH oxidase have been identified in non-immune cells and tissues. Superoxide production derived from NADPH oxidaes has been shown to play a role not only in host defense but also in defined signaling cascades mediating growth and apoptosis. The aim of this work was to study the expression and the regulation of the”new” Nox isoforms in rat renal mesangial cells (MC). In particular the following results were achieved. 1) mRNA’s for both Nox1 and Nox4 were detected by RT-PCR. 2) Nox1 mRNA levels were increased upon exposure to basic fibroblast growth factor (bFGF), platelet-derived growth factor (PDGF) and fetal calf serum (FCS) in a time- and dose-dependent manner. Exposure of MC to bFGF and FCS increased also basal production of reactive oxygen species (ROS) by MC. By contrast, Nox4 mRNA levels were not significantly affected by bFGF treatment, but were markedly down-regulated by PDGF and FCS. 3) To study the regulation of Nox1 on the protein level, an anti-Nox1 antibody was generated and characterized using affinity chromatography. Up-regulation of Nox1 expression by growth factors was confirmed also on the protein level. 4) Based on the already known cDNA sequence for Nox1, the transcriptional start site was determined by the “gene RACE” technique. 2547 bp of the genomic sequence of the 5´-flanking region of the Nox1 gene were cloned and sequenced using the „Genome-Walking“ method. To study the regulation of Nox1 transcription functional Nox1 promoter/luciferase fusions were be established. MC were transiently transfected with different promoter/luciferase constructs and stimulated with growth factors. By measuring luciferase activity it was determined that growth factors induced the Nox1 transcription and that the Nox1 core promoter is sufficient for the activation. 5) By measurement of superoxide radicals and analysis of Nox1 mRNA expression by quantitative RT-PCR (TaqMan) as well as protein level by Western blotting it could be shown that treatment of MC with NO donors inhibited the expression of Nox1 in a time- and dose-dependent manner. Moreover, using activators and inhibitors of the soluble guanylyl cyclase (sGC) it could be shown, that the activation of sGC mediates the effect of NO on Nox1 expression. However, NO had no inhibitory effect on Nox1 promoter activity. Experiments with the inhibitor of transcription, actinomycin D, suggest that NO-mediated regulation of Nox1 is triggered probably via post-transcriptional mechanisms. Nox4 is regulated on the mRNA levels in a similar manner as Nox1. 6) To analyze the sub-cellular localization of the Nox isoforms, coding sequences for Nox1 and Nox4 were fused together with green fluorescent protein into the pEGFP-N1 demonstrated that both isoforms are localized predominantly in the plasma membrane, but also in the perinuclear region and cytoplasm. However, the localization of Nox1 in the plasma membrane was more pronounced. 7) In addition to Nox1 and Nox4, mRNA of the newly identified NOXA1 that is a homolog of the p67phox subunit of NADPH oxidase was detected in MC by RT-PCR.
Durch RNAinterferenz (RNAi) läßt sich die Expression eines beliebigen Gens spezifisch unterdrücken. Dafür müssen in das Zytoplasma kurze, doppelsträngige RNA Moleküle (siRNA bzw. shRNA) eingebracht werden, die teilweise komplementäre Sequenzen zu dem Zielgen aufweisen. Um siRNAs mit einer hohen Effizienz und Kopienzahl in die Zielzelle einzubringen, wurden Transfersysteme unterschiedlicher Art entwickelt. Nicht-virale Transfersysteme können nur einen transienten Effekt auslösen - ein Umstand, der für Langzeitstudien eine mehrfache Transfektion bedingt. Zur Lösung dieses Problems wurden retrovirale Vektorsysteme entwickelt, die durch Integration der shRNA-Expressionskassette in das zelluläre Genom eine stabile Unterdrückung eines Zielgens erreichen können. Insbesondere für präklinische Studien in vivo ist jedoch ein System mit erhöhter Transferrate wünschenswert, um in möglichst vielen Zielzellen einen RNAi-Effekt zu bewirken. Sliva et al. konnten zeigen, dass das Murine Leukämie Virus (MLV) theoretisch diese Anforderung erfüllt. Dafür wurde eine shRNA-Expressionskassette in das Virusgenom eingefügt und in vitro ein RNAi-Effekt nachgewiesen. In der vorliegenden Arbeit wurde dieses System nun durch die Verwendung von microRNA-adaptierten shRNAs (shRNAmir) verbessert. In mehreren Publikationen wurde bestätigt, dass shRNAs, die endogenen microRNAs nachempfunden sind, eine höhere Effizienz und niedrigere Toxizität aufweisen. Zunächst wurde die für die genetische Stabilität optimale Orientierung der shRNAmir-Expressionskassette bestimmt. Das Konstrukt in reverser Orientierung wies eine Deletion in der shRNAmir Promotersequenz auf, die wahrscheinlich durch Interferenz mit dem 5’LTR Promoter entstanden ist. Mit dem genetisch stabilen Viruskonstrukt wurden Experimente zur Reduktion der Expression von Markergenen durchgeführt, um die Effizienz der RNAi-Aktivität leicht zu quantifizieren. Dafür wurden humane Fibrosarkom (HT1080) Zellen infiziert, die eGFP oder Luziferase stabil exprimieren.
Mit eGFP- und Luziferase-spezifischen shRNAmir-Expressionskassetten konnte nach Infektion eine Herunterregulation von eGFP auf etwa 20 % und für Luziferase auf unter 10% beobachtet werden. Das Kontrollvirus, das eine unspezifische shRNAmir kodiert, hatte keinen Einfluss auf die Expression beider Markerproteine. Die Kinetik mit der die Markerproteine herrunterreguliert wurden, war abhängig von der Virusdosis. Die Virusdosis hatte aber keinen Einfluß auf die Stärke des RNAi-Effekts, der nach Infektion aller Zellen festgestellt werden konnte. Dieses Ergebnis entspricht der Erwartung an ein replikatives Transfersystems, das je nach applizierter Virusdosis unterschiedlich schnell RNAi in der Zellkultur ausbreitet und induziert. Die Anwendbarkeit dieses RNAi-Transfersystems auch für endogene Gene wurde mit MMP14-spezifischen shRNAmirs gezeigt. Nach Infektion von HT1080 Zellen mit den entsprechenden Viren in HT1080 Zellen konnte eine verringerte Menge an MMP14 mRNA und Protein nachgewiesen werden. Dies konnte funktionell durch eine verringerte Menge an intermediärem MMP2 und durch eine reduzierte Invasivität bestätigt werden. Zudem war die Fähigkeit dieser Zellen subkutane Tumore zu bilden stark eingeschränkt.
Um die Anwendbarkeit dieses Systems für in vivo Applikationen zu zeigen, wurde in Mäuse, die Luziferase-exprimierenden Tumoren trugen, MLV-shLuc oder das Kontrollvirus systemisch appliziert. 21 Tage nach Virusgabe konnte in den Tumoren von MLV-shLuc infizierten Mäusen eine Abnahme der Luziferaseaktivität auf 15 % nachgewiesen werden. Auch in Mäusen, die systemisch applizierte Tumorzellen erhielten, konnte eine Tendenz von RNAi-vermittelter Luziferase-Reduktion beobachtet werden.
Damit wurde in dieser Arbeit ein neuartiges RNAi-Transfersystem geschaffen, das in der Lage ist, auch in vivo einen starken und lang andauernden RNAi-Effekt auszulösen. Die Einzigartigkeit besteht in der Kombination von shRNAmir und Replikations-kompetenten Retroviren. Dadurch konnte eine erweiterte Transferrate von shRNAmir in Tumorzellen erreicht werden, so dass nun Genfunktionsstudien mit sehr hoher Aussagekraft möglich sind.
"Protein Associated with Myc" (PAM) hat aufgrund seiner enormen Größe von 510 kD und der Vielzahl an Proteinbindungsstellen das Potential viele regulatorische und physiologische Prozesse zu regulieren. Mit der Funktion als E3-Ubiquitinligase und davon unabhängigen Proteininteraktionen reguliert es beispielsweise Prozesse der Synaptogenese und der spinalen Schmerzverarbeitung, wie auch die Regulation des Pteridin Stoffwechsels und des cAMP-Signalweges. Im Gegensatz zur spinalen Schmerzverarbeitung war eine Beteiligung von PAM an der peripheren Nozizeption bisher unbekannt und sollte im Rahmen dieser Arbeit untersucht werden. Dazu wurden konditionale PAM-Knockout Mäuse generiert und charakterisiert. Zum einen wurde PAM in Vorläuferzellen von Neuronen und Gliazellen und zum anderen in allen nozizeptiven und thermorezeptiven Neuronen der Dorsalganglia und der Ganglia trigeminale deletiert. Der Knockout in Neuronen und Gliazellen führte zu einer pränatalen Letalität und unterstreicht so die Bedeutung von PAM während der Neuronenentwicklung. Mit Hilfe des spezifischen Knockouts in nozizeptiven Neuronen konnte eine Rolle von PAM bei der Regulation der thermischen Hyperalgesie gezeigt werden. Keinen Einfluss hatte die Deletion von PAM auf basale thermische und mechanische Schmerzschwellen, sowie auf Formalin-induzierte akute Schmerzen. Als potentieller Mechanismus wurde der mTOR- und der p38 MAPK-Signalweg untersucht. Dabei konnte eine Vermittlung der S1P-induzierten mTOR-Aktivierung durch PAM nachgewiesen werden und Rheb als eine Komponente dieser Aktivierung ermittelt werden. Der p38 MAPK Signalweg war in Abwesenheit von PAM konstitutiv aktiviert und einige Proteine des Rezeptortraffickings waren verstärkt exprimiert. Als ursächlich für die beobachtete verlängerte Hyperalgesie in PAM-defizienten Mäusen konnte die Unterbindung der Internalisierung des TRPV1-Rezeptors nachgewiesen werden. Dieser Effekt ist spezifisch für TRPV1, da der verwandte Ionenkanal TRPA1 durch die PAM-Deletion nicht beeinträchtigt wurde. In der vorliegenden Arbeit konnte so zum ersten Mal gezeigt werden, dass PAM in peripheren nozizeptiven Neuronen über die p38 MAPK-vermittelte Internalisierung von TRPV1 die Dauer der thermischen Hyperalgesie reguliert.