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My PhD work employed genetic and pharmacological manipulations, coupled with highresolution live imaging, to understand intercellular communications during zebrafish cardiovascular development. The heart is the first organ to form, and it is composed of several tissues, among which interactions are crucial. I identified two important interactions between muscular and non-muscular tissues in poorly characterized contexts, and the molecules required for the signalling. First, I discovered an important cellular and molecular crosstalk orchestrating the development of the cardiac outflow tract (i.e., the aortic root in mammals).
Endothelial-derived TGF-beta signalling controls the generation of the local extracellular matrix (ECM). The ECM in turn affects endothelial proliferation as well as smooth muscle cell organization (Boezio et al, 2020; Bensimon-Brito*, Boezio* et al, 2020). In my second project, I investigated the crosstalk between the epicardial layer and the myocardial wall. By generating epicardial-impairment models, I identified a novel role for the epicardium in regulating cardiomyocyte volume during heart development (Boezio et al, 2021). Ultimately, this research contributed to our understanding of how paracrine signalling controls the multicellular interactions integral to organogenesis.
The heart is the first functional organ that develops in the embryo. To become a functional organ, it undergoes several morphogenetic processes. These morphogenetic events involve different cell types, that interact with each other and respond to the surrounding extracellular matrix, as well as intrinsic and extrinsic mechanical forces, assuming different behaviors. Additionally, transcription factor networks, conserved among vertebrates, control the development.
To have a better understanding of cell behavior during development, it is necessary to find a model system that allows the investigation in vivo and at single-cell resolution. Thanks to the common evolutionary origin of the different cardiac structures, together with the conserved molecular pathways, the two-chambered zebrafish heart offers many advantages to study cell behavior during cardiac morphogenesis. Here, using the zebrafish heart as a model system, I uncovered the cell behavior behind two of the main cardiac morphogenetic events: cardiac wall maturation and cardiac valve formation.
In the first part of this study, I investigated how the cardiac wall is maintained at the molecular level. Using genetic, transcriptomic, and chimeric analyses in zebrafish, we find that Snai1b is required for myocardial wall integrity. Global loss of snai1b leads to the extrusion of CMs away from the cardiac lumen, a process we show is dependent on cardiac contractility. Examining CM junctions in snai1b mutants, we observed that N-cadherin localization was compromised, thereby likely weakening cell-cell adhesion. In addition, extruding CMs exhibit increased actomyosin contractility basally, as revealed by the specific enrichment of canonical markers of actomyosin tension - phosphorylated myosin light chain (active myosin) and the α-catenin epitope α-18. By comparing the transcriptome of wild-type and snai1b mutant hearts at the early stages of CM extrusion, we found the dysregulation of intermediate filament genes in mutants including the upregulation of desmin b. We tested the role of desmin b in myocardial wall integrity and found that CM-specific desmin b overexpression led to CM extrusion, recapitulating the snai1b mutant phenotype. Altogether, these results indicate that Snai1 is a critical regulator of intermediate filament gene expression in CMs and that it maintains the integrity of the myocardial epithelium during embryogenesis, at least in part by repressing desmin b expression.
In the second part of this study, I focused on the behavior of valve cells during cardiac development. Using the zebrafish atrioventricular valve, I focus on the valve interstitial cells which confer biomechanical strength to the cardiac valve leaflets. We find that initially AV endocardial cells migrate collectively into the cardiac jelly to form a bilayered structure; subsequently, the cells that led this migration invade the extracellular matrix (ECM) between the two EC monolayers, undergo an endothelial-to-mesenchymal transition as marked by loss of intercellular adhesion, and differentiate into VICs. These cells proliferate and are joined by a few neural crest-derived cells. VIC expansion and a switch from a pro-migratory to an elastic ECM drive valve leaflet elongation. Functional analysis of Nfatc1 reveals its requirement during VIC development. Zebrafish nfatc1 mutants form significantly fewer VICs due to reduced proliferation and impaired recruitment of endocardial and neural crest cells during the early stages of VIC development. Analysis of downstream effectors reveals that Nfatc1 promotes the expression of twist1b, a well-known regulator of epithelial-to-mesenchymal transition. This study shows for the first time that Nfatc1 regulates zebrafish VICs formation regulating valve EMT in part by regulating twist1b expression. Moreover, it proposes the zebrafish valve as an excellent model to study the cellular and molecular process that regulate VIC development and dysfunction.
In conclusion, my work: 1) identified an unsuspected role of Snai1 in maintaining the integrity of the myocardial epithelium, opening new avenues in its role in regulating cellular contractility; 2) uncovered the function of Nfatc1 in the establishment of the VIC, establishing a new model to study valve development and function.
Despite constant progress in basic and translational research, cancer is still one of the leading cause of death. In particular, tumors of the central nervous system (CNS) are usually associated with dismal prognosis. Although about 100 distinct subtypes of primary CNS tumors have been classified molecularly, metastases derived from primaries outside the CNS (= brain metastases, BrM) are more frequently observed across brain tumor patients. It is estimated that approximately 20 - 40 % of all cancer patients will develop BrM during their course of disease, and basically every tumor type is able to metastasize to the brain. Nevertheless, BrM are most frequently derived from primaries of the lung, breast, and skin (melanoma). Treatment options for patients with BrM are very limited, and standard of care therapies include surgery, ionizing radiation (e.g. whole brain radio-therapy, WBRT), and some systemic and immuno-therapeutic approaches.
The brain represents a unique organ, which in part is due to the presence of the blood-brain barrier, a unit of the neuro-vascular interface ensuring tightly regulated exchange of nutrients, molecules, and cells. Furthermore, apart from microglia the brain parenchyma does not harbor other immune cells. Those cells however can be found at the borders of the CNS residing in the meninges, for instance. Based on recent insight on the immune landscape in the CNS, a paradigm shift occurred after which the brain is no longer regarded as immune-privileged but rather immune distinct. The phenomenon of immune cell infiltration has been described before in the context of neurological disorders including Multiple Sclerosis, as well as in brain tumors.
Since the development of immune-therapeutic approaches for tumors outside the CNS that aim to evoke sustainable anti-tumor effects, it became increasingly interesting to understand and harness the immune landscape (= tumor microenvironment, TME) of brain tumors, as well. Interestingly, most of the knowledge about the TME is based on studies of primary brain tumors. However, it is known that BrM compared to primary brain tumors induce a different TME like e.g. the recruitment of much more lymphocytes, which is one of the reasons primary brain tumors are considered immunologically “cold” and poorly respond to immuno-therapies. Previous insight into the functional contribution of tumor-associated cells in BrM progression revealed for example that brain-resident cell types (e.g. astrocytes or microglia) promote BrM development and outgrowth. However, until recently a comprehensive view on the cellular composition and functional role of the brain metastases-associated TME was missing and little was known how it changes during tumor progression or standard therapy.
Hence, within this thesis it was sought to describe novel aspects of the TME of preclinical BrM models, which include two xenograft and one syngeneic mouse model. BrM was induced via intra-cardiac injection of tumor cells with a high brain tropism. Both xenograft models were based on immuno-compromised nude mice (Balb/c nude) and included the melanoma-to-brain (M2B) model H1_DL2, and the lung-to-brain (L2B) model H2030. In addition the breast-to-brain model 99LN-BrM was used in wild-type mice (BL6), and therefore represented an immuno-competent, syngeneic model. First BrMs could be detected in the xenograft models at 3 weeks after injection, whereas first 99LN BrMs were detected at 5 weeks. BrM development and progression were monitored by bioluminescence imaging once per week in the xenograft models. Tumor progression in the 99LN model was examined by magnetic resonance imaging. Based on the measurement methods, and for further histologic and cytometric experiments, mice were stratified into groups with small or large BrMs, respectively. Some initial immuno-stainings confirmed previous findings, showing that brain-resident cells like astrocytes and microglia become activated in the presence of tumor cells, whereas neurons for example rather give the impression of passive bystanders. Importantly, an accumulation of IBA1+ cells was observed during BrM progression. IBA1 is a pan-macrophage marker that stains all tumor-associated macrophages (TAMs). However previous work suggested that the TAM population consists of at least two main subpopulations in BrM as well: the resident-infiltrating microglia (MG, TAM-MG), as well as the peripheral and monocytic-derived macrophages (TAM-MDM). Since both cell types within the tumor share morphological traits, and due to the lack of markers to distinguish them, an exact discrimination of both cell types was complicated in the past. Recently, an integrative lineage-tracing-based study identified the integrin CD49d as MDM-specific in the context of brain tumor-associated myeloid cells, hence enabling a reliable dissection of both TAM populations in e.g. flow cytometric experiments.
One of the main aims of this thesis was to dissect the myeloid TME in the three different BrM models during tumor progression. Using a 5-marker flow cytometry (FCM) (CD45/CD11b/Ly6C/Ly6G/CD49d) approach, the following cell populations were examined in more detail: granulocytes, inflammatory monocytes, MDM, and MG.
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Ischemic heart disease caused by occlusion of coronary vessels leads to the death of downstream tissues, resulting in a fibrotic scar that cannot be resolved. In contrast to the adult mammalian heart, the adult zebrafish heart can regenerate following injury, enabling the study of the underlying cellular and molecular mechanisms. One of the earliest responses that take place after cardiac injury in adult zebrafish is coronary revascularization. Previous transcriptomic data from our lab show that vegfc, a well-known regulator of lymphatic development, is upregulated early after injury and peaks at 96 hours post cryoinjury, coinciding with the peak of coronary endothelial cell proliferation. To test the hypothesis that vegfc is involved in coronary revascularization, I examined its expression pattern and found that it is expressed by coronary endothelial cells after cardiac damage. Using a loss-of-function approach to block Vegfc signaling, I found that it is required for coronary revascularization during cardiac regeneration. Notably, blocking Vegfc signaling resulted in a significant reduction in cardiomyocyte regeneration. Using transcriptomic analysis, I identified the extracellular matrix component gene emilin2a and the chemokine gene cxcl8a as effectors of Vegfc signaling. During cardiac regeneration, cxcl8a is expressed in epicardium-derived cells, while the gene encoding its receptor cxcr1 is expressed on coronary endothelial cells. I found that overexpressing emilin2a increases coronary revascularization, and induces cxcl8a expression. Using loss-of-function approaches, I observed that both cxcl8a and cxcr1 are required for coronary revascularization after cardiac injury.
Altogether, my findings indicate that Vegfc acts as an angiocrine factor that plays an important role in regulating cardiac regeneration in zebrafish. Mechanistically, Vegfc promotes the expression of emilin2a, which promotes coronary proliferation, at least in part by enhancing Cxcl8a-Cxcr1 signaling. This study helps in understanding the mechanisms underlying coronary revascularization during cardiac regeneration, with promising therapeutic applications for human heart regeneration.
Subject of this thesis was the investigation of the actin-interacting and glucocorticoid-sensitive Protein DRR1 (or Fam107a) and its role in promoting stress resilience in the murine hippocampus.
We proposed the hypothesis that DRR1 through its actin-binding properties specifically modulates neuronal actin dynamics and promotes resilience through synaptic plasticity leading to subsequently improvement of cognitive performance and social behavior. The accompanied AMPA-receptor transport could create an efficient way regulating neural function and complex behavior during stress episodes.
By utilizing fluorescent immunohistochemistry, we showed basal expression of DRR1 primarily in the murine cerebellum and hippocampal CA3 and CA1 area. Co-staining with different cell marker proteins showed DRR1 expression in neurons, microglia and especially in astrocytic end-feet, which create contact to the brain vasculature.
To test whether DRR1 and AMPA receptor function correlate to modulate stress-associated consequences, primary hippocampal neuron cultures were transduced with adeno-associated virus (AAV) for overexpression or suppression of the protein. Western Blot analysis showed a positive correlation between the AMPA-receptor subunit GluR2 and DRR1 amounts. Further the application of the proximity ligation assay (PLA) in untreated neural cultures indicated interaction between DRR1 and the AMPA receptor subunit GluR2. To address whether DRR1 even affects AMPAR trafficking we performed the “newly inserted assay” after AAV-treatment of primary hippocampal neuron cultures. Suppression of DRR1 revealed less newly inserted GluR2 subunits as compared to controls. Inconclusive were the results upon DRR1 overexpression, however they point to no changes.
In the second part we correlated behavioral phenotypes originating from in vivo overexpression and suppression of DRR1 in the murine hippocampus with potential alterations in neuronal morphology. Therefore, in vitro analysis was performed utilizing AAV transduced primary hippocampal cultures overexpressing or suppressing DRR1. Synchronously the viral vector included a green fluorescent protein (GFP) being expressed throughout the complete neural cell. GFP staining was used to verify successful transfection and for reconstruction of dendritic arbors and dendritic stretches for spine classification. DRR1 suppression showed reduced total spine numbers especially evoked by reduced numbers of immature spine classes – namely long thin spines and filopodia. Whereas mature mushroom spines and stubby spines were unaffected. By overexpressing DRR1, tendencies inclined against higher total dendritic lengths, branch points and increased dendritic arbors in comparison to controls. In regard of spines, total numbers were unaffected. However, mature mushroom spines were significantly declined in numbers, but compensated by increased numbers of immature long thin spines and filopodia.
Chronic social defeat stress (CSDS) is widely used in mouse models to study the effects of stress and resilience. We exposed C57Bl/6J mice expressing GFP under the Thy1 promoter CSDS and categorized them into resilient (R+/-), susceptible (R-/-) and non-learning (R+/+) mice following a modified social interaction test (MSIT). We found alterations in CA1 spine compositions with resilient animals resembling the untreated phenotype. Stress susceptible and non-learning animals displayed reduced numbers in stubby spines with simultaneous increases in mature mushroom spines. In addition, we could detect a tendency towards more immature spines in susceptible animals and non-learners, mirroring our in vitro results.
Finally, we present a different investigative approach in this thesis. Sequenced acute stress was previously found to compromise cognition including spine loss.
We aimed to investigate the implication of acute stress on DRR1 levels and its occurrence in diverse cell types of the brain. We subjected one group of C57Bl/6J mice to acute stress and injected another group with the artificial glucocorticoid DEX. Six hours post stress, animals were perfused and brains were subsequently immunobiologically analyzed. We found DRR1 protein levels elevated in the hippocampus of stressed and DEX-treated animals compared to controls. Interestingly, DRR1 seemed was especially elevated in endothelial cells. This coincides with our investigations finding DRR1 present in astrocytic end-feet under basal conditions and might claim a participation of DRR1 in the blood-brain-barrier integrity.
Our results show DRR1 as actin-interacting and glucocorticoid-sensitive gene affecting structural plasticity of hippocampal spines. Moreover, DRR1 directly interacts with AMPA glutamate receptors and presumably is involved in AMPA trafficking to the postsynaptic membrane. In addition, this study could demonstrate that DRR1 is expressed by other cell types of the brain. Of special interest is DRR1’s occurrence in astrocytic end-feet and endothelial cells suggesting a role as integrator of cell-cell communication and to this end also acting as modifier of stress-induced consequences at the neurovascular unit.
In vivo data of chronically stressed mice displayed no phenotypic differences in hippocampal pyramidal neurons of resilient animals as compared to unstressed mice. Morphological alterations of spine structures were particularly visible in stress susceptible and non-learning animals. Integrating our findings with existing behavioral data, we can conclude that DRR1 plays a role in stress resilience whereby it needs to be expressed in a tightly managed homeostatic equilibrium.
Heart development is a dynamic process modulated by various extracellular and intracellular cues. Cardiac progenitors in vertebrates such as the zebrafish, migrate over to the midline after differentiation from the epiblast (Bakkers, 2011; Rosenthal & Harvey, 2010; Stainier et al., 1996; Trinh & Stainier, 2004). These progenitors form a cardiac disc at the midline which elongates into the linear heart tube. The differentiation and migration of cardiac precursors is modulated by signaling interactions between cardiac precursor cells and their extracellular environment known as the Extracellular Matrix (ECM). Studies have shown that Cell-ECM interactions play a crucial role in sculpting the heart during early morphogenic events (Davis CL, 1924; Männer & Yelbuz, 2019; Rosenthal & Harvey, 2010). One key factor to these processes is the presence of a specialized ECM known as the Basement Membrane (BM). Extracellular basement membrane proteins such as Fibronectin have been shown to modulate these very early migration processes of the cardiomyocyte progenitors (Trinh & Stainier, 2004). As the heart develops further, the linear heart tube is composed of myocardial cells with an inner endothelial cell lining separated by a layer of thick jelly like substance called the cardiac jelly (Barry A, 1948; Davis CL, 1924; Little et al., 1989). The cardiac jelly also called the cardiac basement membrane, has been shown to regulate distinct developmental events during cardiogenesis. This early CJ contains components of the basal lamina such as laminins, fibronectin, hyaluronan as well as non-fibrillar collagens such as Collagen IV (Little et al., 1989). In this study, I aimed to identify ECM molecules of the Basement Membrane in the heart and identify their role in the modulation of cardiac development and regeneration using the zebrafish as my model organism.
I identified genes belonging to the Zebrafish Matrisome expressed during cardiac developmental and regeneration and performed CRISPR/Cas9 sgRNA mediated mutagenesis. I also developed overexpression tools for these genes.
Agrinp168 mutants exhibited no obvious gross morphology defects during cardiac development and were adult viable. Adult mutants exhibited reduced cardiomyocyte proliferation, but no significant difference in cardiomyocyte dedifferentiation post cardiac cryoinjury.
Decorin overexpression through mRNA injections led to increased myocardial wall thickness and DN dcn overexpression through mRNA injections led to loss of cardiac looping during early development.
Mutants for Small Leucine Rich Proteoglycan (SLRP) prelp generated using CRISPR/Cas9 mutagenesis exhibited cardiovascular defects. Close observation of prelp mutant hearts revealed a reduced heart rate and impaired fractional shortening of the ventricle. prelp mutants exhibited an enlarged atrium at 48 hpf and 72 hpf as well as a reduced ventricle size at 72 hpf. Chamber size in the mutant hearts were enlarged irrespective of contractility of the heart. Mutants showed an increased number of Atrial cardiomyocytes, but no change in cell size. On the molecular level, extracellular Laminin localization was disrupted in prelp mutants along with an increase in thickness and volume of the cardiac HA in the CJ suggesting a potential compensatory role, or retention of immaturity of the cardiac jelly in the prelp mutants. Transcriptomics analysis on the prelp mutant hearts revealed downregulation of ECM organization and ECM-Receptor interaction processes in the mutants. Gene Ontology analysis on prelp mutants hearts transcriptome revealed increased MAPK signaling. Interestingly, genes related to degradation of cardiac HA and maturation of cardiac jelly were downregulated, and genes related to epithelial identity of cardiomyocytes were upregulated. Analysis of the mutant hearts at single cell resolution revealed increased number of mutants exhibiting rounded up cardiomyocytes and loss of apical Podocalyxin. Truncated forms of prelp were generated to identify domain specific roles for Prelp, and reintroduction of N-terminal truncated Prelp into the mutants rescued the basal lamina localization and cardiac jelly volume phenotypes. Myocardium specific re-establishment of prelp expression revealed a marked rescue of the mutant cardiovascular phenotype suggesting that tissue specific expression of prelp is not required so long as Prelp is secreted into the CJ. With these data, I’ve elucidated the role of ECM SLRPs in modulation of cardiac chamber morphogenesis process and regeneration of the heart.
Fuer die schlechte Prognose von Glioblastompatienten mit einer ueberlebenszeit von 9-15 Monaten (Norden and Wen, 2006) ist vor allem die hohe Invasivitaet dieser Tumore verantwortlich. Nach operativer Entfernung des Haupttumors entstehen aus den verbleibenden invadierten Zellen sekundaere Tumore, die sich mitunter ueber weite Bereiche des Hirns verteilen. Des Weitern sind die hochinvasiven Tumorzellen oft resistent gegen Chemo- und Strahlentherapie (Drappatz et al., 2009; Lefranc et al., 2005). In Maustumormodellen und Pateinten konnte zudem gezeigt werden, dass die neuartige antiangiogenetische Therapie zwar das Tumorwachstum verringert, jedoch die Invasivitaet stark erhoeht. (Norden et al., 2008; Ebos et al., 2009; Paez-Ribes et al., 2009). Ueber die Mechanismen die diese hohen Invasivitaet induzieren, ist bislang nur sehr wenig bekannt. Die durch Reduktion von Blutgefaessen steigende Hypoxie des Tumors foerdert die Expression von Matrix-Metalloproteinasen (MMPs). Dies fuehrt zum Abbau der extrazelluaeren Matrix des umgebenden gesunden Gewebes und beguenstigt dadurch die Tumorzellinvasion (Indelicato et al., 2010; Miyazaki et al., 2008; Shyu et al., 2007). Die Umformung des Aktinzytoskeletts und damit die Mobilitaet von Zellen wird vorwiegend durch ein akkurates Zusammenspeil der Rho GTPasen Rac, Rho und Cdc42, kontrolliert (Ridley et al., 2003). Fuer die Organisation von Axonen im Nervensystem und fuer die Blut- und Lymphgefaessbildung wurde gezeigt, dass die Interaktion der Eph-Rezeptortyrosinkinasen und Ihrer Ephrin-Liganden Signalwege induziert, die in die Regulation dieses Zusammenspiels involviert sind (Egea and Klein, 2007; Makinen et al., 2005; Palmer et al., 2002; Sawamiphak et al., 2010). Des Weiteren zeigt die Analyse der Genloci von Eph-Rezeptoren und Ephrinen in verschieden Hirntumoren eine gehaeufte Deletionen des Ephrin-B2-Gens. Die Quantifizierung von Ephrin-B2 mRNA in diesen Tumoren hat ausserdem ergeben, dass mit zunehmender Malignitaet die Expression von Ephrin-B2 sinkt. Aus diesen Gruenden wurden die Untersuchungen in dieser Arbeit auf die Rolle von Ephrin-B2 anhaengigen Signalwegen in der Glioblastomzellinvasion konzentriert. In einem modifiziertem Boyden-Chamber-Assay konnte gezeigt werden, dass das Ephrin-B2 induzierte EphB4 forward signaling und EphB4 induzierte Ephrin-B2 reverse signaling die Invasivitaet der human Glioblastomzelllinien LN-229, G55 und SNB-19 reduziert. In einem Maustumormodel konnte weiterhin gezeigt werden, dass Ephrin-B2 Knock-Out (KO) Astrozytomzellen, im Vergleich zu Wild-Typ (WT) Zellen, Tumore mit einem groesseren Volumen und einer erhoehten Invasivitaet bilden. Da die Expressionslevel fuer die Ephrin-B2 bindenden Rezeptoren EphA4, EphB1 EphB3 und EphB6 auch im adulten Hirn hoch sind (Hafner et al., 2004), weisen diese in vitro und in vivo Ergebnisse auf eine Tumorsupressorfunktion von Ephrin-B2 hin, die durch repulsive Effekte des Ephrin-B2 reverse signaling vermittelte werden koennten. Dies geht mit Erkenntnissen ueber kolorektale Tumore einher (Batlle et al., 2005). Die in einem Sphaeroid-Invasionsassay mit einer EphB-Rezeptoren freien Umgebung beobachtete verminderte Invasion von Ephrin-B2 WT deutet auf eine zusaetzliche invasionsblockierende Rolle der Ephrin-B2-Eph-Rezeptor Interaktion zwischen benachbarten Tumorzellen hin, wie sie auch in Brusttumoren gefunden wurde (Noren et al., 2006). Es scheint als sei Tumorprogression und Invasion erst moeglich, nachdem die Expression von Ephrin-B2 vermindert wurde. Es konnte weiterhin gezeigt werden, dass in hypoxischen Glioblastomzellen die Ephrin-B2 Expression durch die direkte Bindung des den Transkriptionsfaktors ZEB2 an den Ephrin-B2 Promoter reprimiert wird. In einem Weiteren Maustumormodel konnte gezeigt werden, dass die Blockierung der ZEB2 Expression mittels shRNA und die damit einhergehenden Inhibition der hypoxie induzierten Ephrin-B2 Repression das Wachstum und die Invasivitaet von Glioblastomen verringert. Zusaetzlich wurde gezeigt, dass der Verlust von ZEB2 ausreicht, die durch antiangiogenetische Therapie induzierte stark erhoehte Invasivitaet zu vermeiden. Die in dieser Arbeit gewonnen Erkenntnisse fuehren zu folgendem Modelmechanismus. In kleinen normoxischen Tumoren koennen repulsive Effekte des Ephrin-B2 reverse signalings und EphB forward signalings zwischen Tumorzellen und Zellen des umgebenden Gewebes die Ausbreitung und Invasion des Tumors unterdruecken. Zusaetzlich koennte das Ephrin-B2 induzierte EphB forward signaling zwischen benachbarten Tumorzellen die Mobilitaet der Tumorzellen wie in Brusttumoren inhibieren. Beim Erreichen einer bestimmten Tumorgroesse tritt Hypoxie auf, wodurch HIF-1alpha stabilisiert wird. Dies fuehrt dann zur ZEB2 Expression und leitet die Repression von Ephrin-B2 ein, was wiederum zur erhoehten Tumorzellemobilitaet und im Zusammenspiel mit MMPs zu Invasion fuehren kann. Gleichzeitig werden durch den HIF-induzierten VEGF-Gradienten neue Blutgefaesse rekrutiert. Damit wird der hypoxie-induzierten Invasivitaet entgegengewirkt. Wird mittels antiangiogenetischer Behandlung versucht Tumorprogression entgegenzuwirken, resultiert daraus eine erneut gesteigerte Hypoxie, die dann durch die ZEB2 vermittelte Repression von Ephrin-B2 wieder eine erhoehte Invasivitaet induzieren kann. Das Blockieren der ZEB2 Expression kann dieser durch antiangiogenetischen Behandlung induzierten Invasivitaet entgegenwirken.
Die neuronalen Mechanismen, welche den meisten kognitiven Prozessen zu Grunde liegen, bestehen aus dem Zusammenspiel verschiedener Neuronen-Typen und deren spezifischen Funktionsmechanismen, sowohl in lokalen, als auch in globalen neuronalen Netzwerken. Eine funktionelle Interaktion mit diesen Netzwerken ist unumgänglich um das „kognitive“ Gehirn zu studieren, da neuronale Gruppen in einer hierarchischen, nicht linearen Weise miteinander interagieren, und dabei charakteristische raum-zeitliche Muster aufweisen. In dieser Arbeit untersuchten wir die Struktur und Funktion eines wichtigen Merkmals kortikaler Prozesse: Die neuronale gamma-Band Oszillation.
Cardiovascular disease is the leading cause of death worldwide. Aging is among the greatest risk factors for cardiovascular disease. Cardiovascular disease comprises several diseases, for example myocardial infarction, elevated blood pressure and stroke. Many processes are known to promote or worsen cardiovascular disease and in the present study, cellular senescence and inflammatory activation were of special interest, as they have a strong association to aging and can be seen as hallmarks of cellular aging.
Long noncoding RNAs (lncRNAs) are noncoding RNAs with a length of more than 200 nucleotides. In recent years, numerous regulatory functions were shown for these transcripts and lncRNAs were shown to directly interact with DNA, RNA and proteins. The long noncoding RNA H19 was among the first described noncoding RNAs and was initially shown to act as a tumor suppressor. More recently, several studies showed oncogenic roles for H19. In regards to the cardiovascular system, H19 was not analyzed before.
We show that H19 is the most profoundly downregulated lncRNA in endothelial cells of aged mice compared to young littermates. Microarray analysis of human primary endothelial cells upon pharmacological H19 depletion revealed an involvement of H19 in cell cycle regulation. Loss of H19 in human endothelial cells in vitro led to reduced proliferation and to increased senescence. H19 depletion was shown to counteract proliferation before, but none of the described mechanisms applied to endothelial cells. We show that the reduction in proliferative capacity and the pro-senescent function of H19 is most probably mediated by an upregulation of p16ink4A and p21 upon H19 depletion.
When we compared the angiogenic capacity of aortic endothelial cells from young and aged mice in an aortic ring assay, rings from aged mice showed a reduced cumulative sprout length. Interestingly, pharmacological inhibition of H19 in aortic rings of young animals, where H19 is highly expressed, was sufficient to reduce the cumulative sprout length to levels we observed from aged animals. Furthermore, overexpression of human H19 in aortic rings of aged mice, where H19 is poorly expressed, rescued the impaired angiogenic capacity of aged endothelial cells.
We generated inducible endothelial-specific H19 knockout mice (H19iEC-KO) and subjected these animals to hind limb ischemia surgery followed by perfusion analysis in the hind limbs by laser-doppler velocimetry and histological analysis. Perfusion in the operated hind limb was increased in H19iEC-KO compared to Ctrl littermates, which was in contrast to a reduction in capillary density in the operated hind limbs of H19iEC-KO animals compared to Ctrl littermates and to our previous results. Analysis of arteriogenesis revealed an increase in collateral growth upon EC-specific H19 depletion in the ischemic hind limbs, which explains the increase in perfusion despite the reduction in capillary density. Further characterization of the animals revealed an increase in leukocyte infiltration into the tissue in the ischemic hind limbs upon endothelial-specific H19 depletion, indicating a potential role of H19 in inflammatory tissue activation.
Reanalysis of the microarray data from human primary endothelial cells upon H19 depletion revealed an association of H19 with inflammatory signaling and more specifically with IL-6/JAK2/STAT3 signaling. Analysis of cell surface adhesion molecule expression revealed an upregulation of ICAM-1 and VCAM-1 on mRNA level and an increase of the abundance of the two proteins on the cell surface of human primary endothelial cells. Consequently, adhesion of isolated human monocytes to human primary endothelial cells was increased upon H19 depletion in vitro. Interestingly, TNF-α mediated inflammatory activation of primary human endothelial cells repressed H19 expression. H19 did not function via previously described mechanisms. We excluded a competitive endogenous RNA (ceRNA) function for H19 in endothelial cells and showed that miR-675, which is processed from H19, does not play a role in the endothelium. Furthermore, H19 did not regulate previously described genes or pathways.
Analysis of transcription factor activity upon H19 depletion and overexpression revealed a differential activity of STAT3. STAT3 phosphorylation at TYR705 and thus activation was increased upon H19 depletion. Inhibition of STAT3 activation using a small compound inhibitor abolished the effects of H19 depletion on mRNA expression of p21, ICAM-1 and VCAM-1 and on proliferation, indicating that the effects of H19 are at least partially mediated via STAT3. STAT3 was shown to have positive effects on the cardiovascular system before, most likely due to upregulation of VEGF in a STAT3-dependent manner. We were not able to confirm previously described mechanisms for STAT3 in the present study and propose a new mechanism of action for the H19-dependent regulation of STAT3. Taken together, these results identify the long noncoding RNA H19 as a pivotal regulator of endothelial cell function. Figure 38 summarizes the described functions of H19 in endothelial cells.
Brain development is a complex and highly organized process that relies on the coordinated interaction between neurons and vessels. These cell systems form a neurovascular link that involves the exchange of oxygen, ions, and other physiological components necessary for proper neuronal and vascular function. This physiologically coupled process is executed through analogous structural and molecular signaling mechanisms shared by both cell types. At the neurovascular interface, the cellular crosstalk via these shared signaling mechanisms allows for the synchronized expansion and integration of neurons and vessels into complex cellular networks. This study investigated the role of VEGFR2, a receptor for vascular endothelial growth factor (VEGF), during postnatal neuronal development in the mouse hippocampus. Prior studies have revealed physiological roles of VEGF, a pro-angiogenic morphogen, in nervous system development. However, it was unclear if VEGF signaling had a direct effect on neuronal physiology and function through neuronal-expressing receptors. In this investigative work, we identified a previously unknown function of VEGFR2, whereby VEGF-induced signaling coordinates the development and circuitry integration of CA3 pyramidal neurons in the early postnatal mouse hippocampus. Mechanistically, we found that VEGFR2 signaling requires receptor endocytosis, a process mediated by ephrinB2. We also found that VEGF-induced cooperative signaling between VEGFR2 and ephrinB2 is functionally required for the dendritic arborization and spine maturation of developing CA3 neurons during the first few postnatal weeks. Moreover, in a collaborative effort with the research group of Carmen Ruiz de Almodovar, formerly at the University of Heidelberg, we simultaneously studied VEGF-induced VEGFR2 signaling in CA3 axonal development. Together, we aimed to gain a comprehensive understanding of the complex interplay between VEGF and VEGFR2 signaling during the early postnatal development of CA3 neurons. Ruiz de Almodovar’s research group found that, unlike the branch and spine development of CA3 dendrites, VEGF-VEGFR2 signaling promotes axonal development through mechanisms that are independent of ephrinB2 function. Our findings on CA3 dendritic development are reported in the published manuscript, Harde et al. (2019), and the complementary work on CA3 axonal development from Ruiz de Almodovar's group is presented in the co-published manuscript, Luck et al. (2019). Although the totality of Ruiz de Almodovar's group's work on CA3 axons is not fully discussed here, it is referenced where noted to provide biological context for our findings on CA3 dendritic development.
VEGFR2 signaling within neurovascular niches is known to play a role in the neurogenesis of neural progenitor cells during embryonic development and within the adult brain. However, the precise localization of neuronal VEGFR2 expression and functional role within the nervous system during postnatal brain development was unknown. To investigate this, we used immunohistochemistry to identify the spatial expression of VEGFR2 within the mouse hippocampus during the first few weeks after birth. Our results showed that VEGFR2 was predominantly expressed within the hippocampal vasculature, consistent with prior studies. However, we also observed localized VEGFR2 expression in pyramidal cell neurons of the hippocampal CA3 region by postnatal day 10 (P10). This spatially restricted postnatal expression of VEGFR2 in CA3 neurons suggested a potential role in the development of these neurons during this developmental stage.
The first two weeks after birth in the mouse hippocampus is a critical period for the development of neuronal circuits, as neurons undergo extensive dendritic arborization and spine formation. To explore the role of VEGFR2 in the postnatal nervous system, we used a Nes-cre VEGFR2lox/- mouse line to target the deletion of VEGFR2 expression within the nervous system while preserving normal receptor expression in all other cell types. We also generated corresponding control mice that were negative for Nes-cre. By breeding these mice with Thy1-GFP reporter mice, we could analyze the functional consequences of VEGFR2 by assessing the morphologies of CA3 dendritic trees and spine density and maturation at P10 and P15, respectively. Our analysis showed that CA3 neurons in Nes-cre VEGFR2lox/- mice had less complex dendritic arbors compared to control mice. There were significant reductions in total length and branch points, particularly in areas located 100-250 μm from the cell soma within the stratum radiatum layer. Additionally, Nes-cre VEGFR2lox/- mice exhibited a significant decrease in spine density accompanied by an increased proportion of immature spines. These findings suggest that VEGFR2 plays a crucial role in the proper development of CA3 dendrites and spines during the early postnatal weeks.
Bei Autismus-Spektrum-Störungen (ASS) handelt es sich um genetisch komplexe Störungen mit hoher Erblichkeit. Als zugrundeliegender Pathomechanismus von ASS werden unter anderem Veränderungen der neuronalen Entwicklung diskutiert. Der Phänotyp von ASS ist definiert durch Einschränkungen in der sozialen Interaktion und Kommunikation sowie repetitives und stereotypes Verhalten. Genkopiepolymorphismen (englisch „copy number variations“/CNVs), also Deletionen oder Duplikationen einer chromosomalen Region, wurden wiederholt in Probanden mit ASS identifiziert. Hierbei ist in ASS die Region 16p11.2 mit am häufigsten von CNVs betroffen. Einige Gene aus diesem chromosomalen Abschnitt wurden bereits funktionell charakterisiert. Dennoch können die Befunde der bisherigen Einzelgenstudien nicht alle Aspekte erklären, die durch 16p11.2 CNVs hervorgerufen werden. Ziel dieser Studie war es daher, ein weiteres neuronal assoziiertes Kandidatengen dieser Region zu identifizieren und im Anschluss funktionell im Kontext der neuronalen Differenzierung zu charakterisieren.
Das SH-SY5Y Neuroblastom-Zellmodell wurde auf Transkriptom- und morphologischer Ebene auf seine Eignung als Modell für neuronale Differenzierung untersucht und bestätigt. Eine Analyse der Expressionen aller Gene der 16p11.2-Region zeigte, dass das Gen Quinolinat-Phosphoribosyltransferase (QPRT) eine vergleichsweise hohe Expression mit der stärksten und robustesten Regulierung über die Zeit aufwies. Eine de novo Deletion der 16p11.2-Region wurde in einem Patienten im Vergleich zu seinen Eltern validiert. In Patienten-spezifischen lymphoblastoiden Zelllinien derselben Familie konnten wir eine Gendosis-abhängige Expression von QPRT auf RNA-Ebene bestätigen. In SH-SY5Y-Zellen korrelierte die Expression von QPRT signifikant mit der Entwicklung von Neuriten während der Differenzierung. Um QPRT funktionell zu charakterisieren, benutzten wir drei verschiedene Methoden zur Reduktion der QPRT-Gendosis: (i) knock down (KD) durch siRNA, (ii) chemische Inhibition durch Phthalsäure und (iii) knock out (KO) über CRISPR/Cas9-Geneditierung. Eine Reduktion von QPRT durch siRNA führte zu einer schwachen Veränderung der neuronalen Morphologie differenzierter SH-SY5Y-Zellen. Die chemische Inhibition sowie der genetische KO von QPRT waren letal für differenzierende aber nicht für proliferierende Zellen. Eine Metabolitenanalyse zeigte keine Veränderungen des QPRT-assoziierten Tryptophanstoffwechsels. Gene, welche auf Transkriptomebene im Vergleich zwischen KO- und Kontrollzellen differenziell reguliert vorlagen, waren häufig an Prozessen der neuronalen Entwicklung sowie an der Bildung, Stabilität und Funktion synaptischer Strukturen beteiligt. Die Liste differenziell regulierter Gene enthielt außerdem überdurchschnittlich viele ASS-Risikogene und ko-regulierte Gengruppen waren assoziiert mit der Entwicklung des dorsolateralen präfrontalen Cortex, des Hippocampus sowie der Amygdala.
In dieser Studie zeigten wir einen kausalen Zusammenhang zwischen QPRT und der neuronalen Differenzierung in vitro sowie einen Einfluss von QPRT auf die Regulation von ASS-assoziierten Genen und Gen-Netzwerken. Funktionell standen diese Gene im Kontext mit synaptischen Vorgängen, welche durch Veränderungen zu einem Exzitations-Inhibitions-Ungleichgewicht und letztendlich zum Zelltod von Neuronen führen können. Unsere Ergebnisse heben in Summe die wichtige Rolle von QPRT in der Krankheitsentstehung von ASS, insbesondere in Trägern einer 16p11.2 Deletion, hervor.
With 5-10 newly diagnosed patients per 100,000 people every year, glioblastoma is the most common malignant primary brain tumor. Despite extensive research activity in the last decades, clinical effectiveness of the currently available therapy standard of surgery, radiochemotherapy and tumor-treating fields is still limited and mean survival rates in unselected collectives are only about one year. Accordingly, there is an urgent need to explore new therapeutic options. The current standard of care includes surgery followed by radiation therapy in combination with the alkylating chemotherapeutic agent Temozolomide. Even with successful initial therapy, tumor recurrence is still inevitable. Currently, there are no defined recommendations for clinical management of the disease in the event of tumor recurrence. Only 20-30% of patients qualify for a second surgical resection, while other options include retreatment with Temozolomide, CCNU (Lomustine) or Regorafenib and enrollment in a clinical trial.
The development of immunotherapies for glioblastoma, in particular, has been the focus of intense preclinical and clinical efforts. However, low numbers of mutations and a highly immunosuppressive tumor microenvironment result in glioblastoma being considered an immunologically “cold” tumor. Strategies successfully established in mutagen-induced tumors with antibodies directed against the PD-1, PD-L1 or CTLA-A4 immune checkpoints have therefore failed in glioblastoma.
Cellular immunotherapies based on chimeric antigen receptor (CAR)-technology have emerged as an alternative powerful option to tackle immunologically “cold” tumors. Several CAR-T cell products targeting glioma antigens have been developed and some evidence of clinical activity has been demonstrated. Natural killer (NK) cells as carriers of CAR constructs have several advantages over T cells, including a much lower risk of neurotoxicity and better interaction with immune cells in the microenvironment. Based on the human NK cell line NK-92, a clinical-grade product, suitable as an off-the-shelf therapeutic, has been developed. The NK-92/5.28.z clone (CAR-NK) expresses a CAR based on the HER2-specific antibody FRP5 in addition to signal-enhancing CD28 and CD3ζ domains. Similar to several other tumor entities, overexpression of the growth factor receptor HER2 is often found in glioblastoma patients. Because of its substantial role in the regulation of cell proliferation, survival, differentiation, angiogenesis and invasion, this receptor is classified as an oncogene. HER2 overexpression plays a major role in the malignant transformation of cells and its oncogenic potential has been studied in detail in breast cancer. However, HER2 expression was also found in up to 80% of glioblastomas, which correlates with an impaired probability of survival. Under physiological conditions, HER2 is not expressed in the adult central nervous system, making it a promising target antigen for glioblastoma immunotherapy.
In previous projects, it has already been shown that these CAR-NK cells exhibit a high and specific lytic activity towards HER2+ glioblastoma cells. While repetitive intratumoral injections of CAR-NK cells already significantly extended symptom-free survival in murine orthotopic xenograft models, CAR-NK cell therapy in immunocompetent mice promotes an endogenous anti-tumor immune response which improves tumor control and provides persisting anti-tumor immunity after therapy of early-stage tumors. However, in more advanced tumor models, efficacy is limited and induction of the checkpoint-molecule PD-L1 in response to CAR-NK-cell therapy was identified as a key mechanism of therapy resistance.
Immunotherapy employing the intravenous administration of checkpoint inhibitors has already revolutionized the treatment of various malignant diseases such as melanoma or lung cancer. In particular, the approach of cancer immunotherapy has focused on the systemic administration of antibodies directed against immune checkpoints such as PD-1, PD-L1 and CTLA-4. In glioblastoma, both tumor cells and microglia, the brain-resident macrophages, express PD-L1, which hinders the activation of CD8+ and CD4+ T cells. Therefore, immunotherapy directed against the PD-1/PD-L1 axis represents a promising approach for the treatment of glioblastoma. One problem, however, is the severe toxicity caused by the systemic effects of checkpoint inhibitors, since the immune response is stimulated not only in tumor tissue but also in healthy organs. Serious side effects such as colitis, hepatitis, pancreatitis or hypophysitis, including numerous deaths, have been reported.
This study aimed to improve the efficacy of CAR-NK cell therapy by combining it with adeno-associated virus (AAV)-mediated transfer of anti-PD-1 antibodies as a strategy to enable local combination therapy to control intracranial tumors.
AAVs carrying a payload coding for an anti-PD-1 immunoadhesin (aPD-1) retargeted to HER2-expressing cells by fusion of so-called Designed Ankyrin Repeat Proteins (DARPins) with a viral capsid protein were employed for this to focus checkpoint inhibitor therapy to the tumor area, resulting in high intratumoral and low systemic drug concentrations. ...
In the dentate gyrus (DG) of the mammalian hippocampus, neurogenesis continues to take place throughout an organism’s life. Adult neurogenesis includes proliferation and differentiation of neural stem cells into dentate granule cells (GCs) that mature and integrate into the existing cellular network. This thesis work presents a novel approach that enables longitudinal examination of living postnatally generated GCs in their endogenous niche by using retroviral (RV) labeling in organotypic entorhino-hippocampal slice cultures (OTCs). Older GCs were fluorescence-labeled with an adeno-associated virus controlled by the synapsin 1 promoter (AAV-Syn). The combination of time-lapse imaging and 3-D reconstruction of newborn developing GCs and older, more mature GCs enabled comparative analyses of dendritic growth and cellular dynamics as well as investigations of spine formation and the establishment of synaptic contacts.
Postnatal neurogenesis was studied in the mouse and rat DG in vivo by analysis of the distribution of chemical neuronal maturation markers doublecortin (DCX) and calbindin in combination with the GC marker Prox1 between P7 and P42. The marker expression patterns at different time points indicated that the number of mature GCs increased gradually over time and that young, immature GCs were added to the inner layers of the granule cell layer (GCL), as is the case in the adult brain. The most substantial shift in GC maturation took place between P7 and P14, though GCs in the rat DG matured faster (i.e. by ~5 days) than GCs in the mouse. Immunocytochemical in vitro analysis in OTCs at DIV 7, 14, and 28 exhibited a distribution of marker expression over time that was comparable to in vivo, though the number of DCX-expressing GCs was low at DIV 28, indicating a considerable decrease in neurogenesis rate over time in the OTC. Nevertheless, RV-labeling of newborn GCs at DIV 0 yielded successful visualization and enabled time-lapse imaging of complete developing GCs up to 4 weeks after mitosis. During the second week of development, newborn GCs exhibited a high level of structural dynamics, including extension and retraction of dendritic segments. In the third week, newborn GCs displayed high dendritic complexity which was followed by pronounced dendritic pruning. Finally, a phase of structural stabilization and local refinement could be observed during the fourth week. Older AAV-Syn-labeled GCs did not exhibit such dynamic structural remodeling. Anterograde tracing of entorhinal projection fibers using the biotinylated dextran amine Mini Ruby showed innervation of the outer molecular layer (OML) by entorhinal axons at early time points, i.e. DIV 8 when newborn GCs started to extend dendrites into the ML, as well as at DIV 20 when RV-labeled GCs exhibited elaborate dendritic trees with processes in the OML intermingling with entorhinal fibers. This shows that newborn GCs in the OTC grow into an area of existing entorhinal axon terminals, which is highly similar to the situation in the adult brain. Hence, the results show that postnatal neurogenesis can be studied effectively in the OTC system as a model of adult neurogenesis. The first appearance of spine-like protrusions in newborn GCs was observed two weeks post RV injection. Ultrastructural electron-microscopic images revealed that spines established synaptic contacts with axonal boutons. These findings suggest that newborn GCs are successfully integrated into the existing cellular circuitry in the OTC system. The high level of structural flexibility found in this study might be a necessary requisite of new neurons for successful dendritic maturation and functional integration into a neuronal network. Thus, live imaging of postnatally born GCs in the OTC appears as a useful novel approach to elucidate the mechanisms that affect cellular dynamics of neurogenesis.
Angiogenesis, the formation of new blood vessels from existing ones, is a fundamental biological process required for embryonic development; it also plays an important role during postnatal organ development and various physiological and pathological remodeling processes in the adult organism. Vascular endothelial growth factor (VEGF) and its main receptor, VEGF receptor-2 (VEGFR-2), play a central role in angiogenesis. VEGFR-2 expression is strongly upregulated in angiogenic vessels, but the mechanisms regulating VEGFR-2 expression are not well understood. We found in this study that the G-protein α subunit Gα13 plays an important role in the regulation of VEGFR-2 expression. In vitro, we found that knockdown of Gα13 reduced VEGFR-2 expression in human umbilical vein endothelial cells and impaired responsiveness to VEGF-A. This phenotype was rescued by adenoviral normalization of VEGFR-2 expression. Gα13-dependent VEGFR-2 expression involved activation of the small GTPase RhoA and transcription factor NF-κB; it was abrogated by deletion of the NF-κB binding site at position -84 of the VEGFR-2 promoter. In vivo, endothelial cell-specific loss of Gα13 resulted in reduced VEGFR-2 expression, impaired responsiveness towards VEGF-A in Matrigel assays, and reduced retinal angiogenesis. Importantly, also tumor vascularization was diminished in the absence of endothelial Gα13, resulting in reduced tumor growth. Taken together, we identified Gα13-dependent NF-κB activation as a new pathway underlying the transcriptional regulation of VEGFR-2 during retinal and tumor angiogenesis.
Flow hemodynamics regulates endothelial cell (EC) responses and laminar shear stress induces an atheroprotective and quiescent phenotype. The flow-responsive transcription factor KLF2 is a pivotal mediator of endothelial quiescence, but the precise mechanism is unclear. In this doctoral study, we assessed the hypothesis that laminar shear stress and KLF2 regulate endothelial quiescence by controlling endothelial metabolism.
Laminar flow exposure and KLF2 over expression in HUVECs reduced glucose uptake. Endothelial specific deletion of KLF2 (EC-KO) in mice and subsequent infusion of labeled glucose in Langendorff perfused hearts induced glucose uptake in ECs lacking KLF2. Bioenergetic measurements revealed that KLF2 reduces and glycolytic acidification in vitro.
Mechanistically, RNA sequencing analysis of shear stimulated ECs showed reduced expression of key glycolytic enzymes Hexokinase 2, PFKFB3 and PFK-1. KLF2 also reduced expression of these enzymes at protein level. KLF2 knockdown in shear stimulated ECs reversed the reduction in expression of PFKFB3 and PFK-1, indicating KLF2-dependency. Promoter analysis revealed KLF binding sites in the promoter of PFKFB3 and KLF2 over expression markedly reduced PFKFB3 promoter activity which was abolished on mutation of the KLF binding site. In addition, PFKFB3 knockdown reduced glycolysis while over expression increased glycolysis. Over expression of PFKFB3 along with KLF2 partially reversed the KLF2-mediated reduction in glycolysis. Importantly, PFKFB3 over expression reversed KLF2-mediated reduction in angiogenic sprouting and network formation in vitro. Ex-vivo aortic ring assays revealed an increase in endothelial sprouting from aortas from KLF2 EC-KO mice, which was partially reversed upon PFKFB3 inhibition by 3-PO.
In conclusion, work performed during this doctoral thesis demonstrates that laminar shear stress and KLF2 mediated repression of endothelial metabolism via regulation of PFKFB3 contributes to the anti-angiogenic and quiescent properties of the endothelium.
This thesis reports on the results obtained by expression photoactivatable adenylyl cyclase from Beggiatoa spp. (bPAC) in cholinergic neurons from Caenorhabditis elegans (C. elegans) and the characterization of the role of a single neuron, RIS, during locomotion in the adult animal.
Pharmacological activation of adenylyl cyclases through Forskolin is known to induce increased neuronal output in diverse model organisms through a protein kinase A (PKA) dependent mechanism. Nevertheless, pharmacological assays are not spatially restricted, do not allow for precise and acute activation nor to cessation of the signal. Thus, an optogenetic approach for was selected trough the expression of photoactivatable adenylyl cyclase from Beggiatoa spp. (bPAC) in cholinergic neurons of Caenorhabditis elegans (C. elegans). This model organism was chosen due to its transparency, ease of maintenance, fast generation cycles as well as for being an eutelic animal. Further, its genome has been fully sequenced and the connectome of the neuronal network is known, thus allowing for precise analysis of neuronal function. Furthermore, the molecular mechanisms governing neuronal functions are well conserved up to primates. Mainly two optogenetical tools were applied, bPAC and the light gated cation channel channelrhodopsin 2 (ChR2).
Behavioral assays of bPAC photostimulation in cholinergic neurons recapitulated previous work performed with the photoactivatable adenylyl cyclase from Euglena gracilis (EuPACa), in which swimming frequency and speed on solid substrate were increased. Electrophysiological recordings of body wall muscle (BWM) cells by Dr. Jana F. Liewald showed that bPAC photoactivation led to an increase in miniature postsynaptic current (mPSC) rate and, in contrast to ChR2 invoked depolarization, also amplitude. Analysis of mutants deficient in neuropeptidergic signaling (UNC- 31) via electrophysiology performed by Dr. Jana F. Liewald showed that the increase in mPSC amplitude due to bPAC photoactivation requires neuropeptide release. This was confirmed by co-expression of bPAC with the neuropeptide marker NLP-21::Venus and subsequent fluorescence analysis of release, exploiting the fact that released neuropeptides are ultimately degraded by scavenger cells (coelomocytes). These were enriched with NLP-21::Venus after bPAC photostimulation, but no fluorescence could be observed in the UNC-31 mutants.
Additional analysis of the electrophysiological data performed by myself showed no modulation of mPSC kinetics dues to neuropeptidergic release induced by bPAC. Hence, neuropeptide release and action sites were in the cholinergic neurons, the latter including cholinergic motoneurons.
Dr. Szi-chieh Yu provided electron microscopy images of high pressure frozen, bPAC or ChR2 expressing animals. These were tagged by myself for automatic analysis of ultrastructural properties of the cholinergic presynapse, also during photoactivation of both optogenetic tools. Photoactivation of both induced a reduction of synaptic vesicles, with ChR2 showing a more severe effect. In contrast to ChR2, though, bPAC also reduced the amount of dense core vesicles (DCV), the neuropeptide transporters. Additionally, long bPAC photoactivation as well as ChR2 photoactivation led to the appearance of large vesicles (LV), presumably in response to the increased SV fusion rate. bPAC photostimulation also induced an increase in SV size, not observed after ChR2 photostimulation. In UNC-31 mutants, bPAC photostimulation could not lead to the SV size increase, a further argument for the presynaptic effect of the released neuropeptide. Additional analysis of electrophysiology paired with pharmacology, performed by Dr. Jana F. Liewald, showed that mPSC amplitude increase requires the function of the vesicular acetylcholine transporter.
A further effect observed in the ultrastructure of bPAC photostimulated cholinergic presynapses was a shift in the distribution of SV regarding the dense projection. An analysis of cAMP pathway mutants showed that synapsin is required for bPAC induced behavior effects. Synapsin is known to mediate SV tethering to the cytoskeleton. Here, I show evidence for a new role of synapsin in controlling the availability of DCVs for fusion and thus, in neuropeptidergic signaling.
In the second part of my thesis I characterized the function of the GABAergic interneuron RIS in the neuronal network of C. elegans. RIS was shown to induce lethargus, a sleep-like state, during all larval molts, but its function in the adult animal was not yet described. Specific RIS expression of ChR2 achieved by a recombinase based system allowed to acutely depolarize the neuron during locomotion, which led to an acute behavioral stop. Diverse signal transduction pathway mutants were analyzed showing that the phenotype was induced by neuropeptidergic signaling. Through mutagenesis followed by whole genome sequencing data analysis as well as analysis of RIS specific RNA sequencing data further narrowed the signal transduction pathway to mediate the locomotion stop behavior. Since the neuropeptide and, to some extent, the neuron are conserved across nematodes, an argument is outlined in favor of the conservation of this sleep-like state.
In addition, since ChR2 could induce neuropeptidergic signaling from RIS, secretion of vesicles is regulated by variable pathways depending on the neuronal identity. Nevertheless, expression of bPAC in RIS allowed to optogenetically increase the probability of short stops, as observed by expression of a calcium sensor (GCaMP) in RIS and analysis of its intrinsic activity in the adult animal.
In recent years, several neuronal differentiation protocols were published that circumvent the requirement of embryoid body (EB) formation under serum-deprivation and simplified medium conditions. But a neuronal default model to establish an approach that works efficiently for all pluripotent cells and neuronal precursors is still lacking. Whether such a default neural mechanism exist and how this is implemented across a broad spectrum of cell source, is addressed in several studies and still controversially discussed. It was proposed that the default neuronal fate is initiated in the absence of extrinsic signals and is achieved by eliminating extracellular inhibitors of neuroectodermal fate and suppressing cell-cell signalling through limited cell density. Previous studies reported that ESC and ECC grown at low density and in absence of exogenous factors or feeder layers die within 24 h but acquire a neural identity as indicated by expression of the neural marker Nestin. Thus, this application is not suitable for generating neural cultures. Furthermore, it was reported that P19 cells survive and express neuroectodermal marker genes in serum-free DMEM/F12 medium containing transferrin, insulin, and selenite, although no neurites were identified.
Based on this background, in this study, a novel approach to induce neuronal differentiation in vitro was developed that implements a nutrient-poor environment, which, in contrast to previous studies, ensures the survival of neuronally differentiated cells over a long period of time and allows normal formation of neurites. Neither the formation of free-floating aggregates nor supplementation of growth factors or known inducers was required to establish a reliable neuronal differentiation protocol. A simple medium, consisting of DMEM/F12+N2 that was highly diluted in salt solution, was sufficient to drive a fast neuronal differentiation in monolayer cultures. Serum deprivation and strong dilution of DMEM/F12+N2 medium cause a nutrient-poor environment in which the influence of growth factors and inducers is minimized. This medium creates a metabolically defined environment that is presumably free of extrinsic signals that prevent the decision of neuronal fate. Analysis of the medium components discovered no actual inducer. Hence, it was suggested that the metabolic composition of the medium exclusively covers specific cell requirements of neurons, therefore ensures their survival, and drives the switch from pluripotent cells to neurons. The self-developed method was established by usage of the murine embryonal carcinoma cell line P19 and could be transferred to murine ESC. Consequently, the method could provide a feasible protocol for a generally valid neuronal default model.
The established protocol provides several advantages such as the possibility to generate stable pure neuronal cultures by a fast, simple, and highly reproducible one-step induction under defined medium conditions with a minimum of exogen effectors. The method is characterised by clear and steady medium conditions that makes the investigation of specific cell requirements during differentiation accessible. It is therefore expected to be a useful tool to investigate the molecular basis of neuronal differentiation as well as for high throughput screenings. The phenotype of mature postmitotic neurons was arising within one week and cultures were shown to stay stable at least for three weeks. The neuronal identity was confirmed by expression of neuronal markers through immunofluorescence staining and mass spectrometry analysis. Furthermore, increased levels of axon markers were detected in early neuronal differentiation and functionality of the synapses of the P19-derived neurons was ascertained by detection of calcium activity. Axonal laser ablation, immediately followed by fast regrowth of connections in the neuronal network, revealed a strong regeneration potential under the given conditions. Furthermore, the generated neurons showed a morphologically distinct phenotype and the formation of neural rosettes. Immunofluorescence staining demonstrated the generation of pure and homogeneous neuronal cultures, free of glial cells.
Retinoic acid (RA) plays an essential role in cell signalling during embryogenesis and efficiently induces neuronal differentiation in vitro in a concentration dependent manner. Neither retinol nor retinoic acid was included in any of the components of the self-prepared medium in this work. However, I observed, dependence on RARβ- and/or RARγ-regulated RA signalling in serum-free monolayer cultures. Nevertheless, neuronal differentiation in serum-free monolayer cultures was assumed to be RARα-independent because (i) RARα was slightly downregulated after neuronal induction, (ii) the truncated RARα of the RAC65 mutant had no effect on induction efficiency, and (iii) a pan-RAR inhibitor suppressed neuronal differentiation. In contrast to serum-free monolayer cultures, the truncated RARα prevented neuronal differentiation by application of the conventional protocol where cells are grown in free floating cell aggregates in serum-containing medium. Proteome analysis of P19 cells, treated by the self-developed differentiation protocol over five days showed increased levels of cellular RA binding proteins that mediate the cellular RA transport and are involved in canonical as well as non-canonical RA signalling.
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Synaptic plasticity is the basis for information storage, learning and memory and is achieved by modulation of the synaptic transmission. The amount of active AMPA (α-amino-3-hydroxy-5-methyl-4-isoxazol-propionic acid) receptors at the synapse determines the transmission properties, therefore the regulation of AMPA receptor trafficking affects the synaptic strength. The protein GRIP (glutamate receptor interacting protein) binds to AMPA receptors and is one of the important regulators of AMPA receptor stability at the synapse (Dong et al., 1997; Osten et al., 2000). Previous studies have shown that the ablation of ephrinB2 or ephrinB3 in the nervous system leads to severe defects in hippocampal LTP (long term potentiation) and LTD (long term depression) (Grunwald et al., 2004). We found that ephrinB2 ligands play an important role in the stabilization of AMPA receptors at the cellular membrane (Essmann et al., 2008). Treating cultured hippocampal neurons with AMPA resulted in a robust AMPA receptor internalization, which could be inhibited by simultaneous ephrinB2 activation with soluble EphB4-Fc fusion proteins. Conditional hippocampal ephrinB2 knock-out (KO) neurons showed enhanced constitutive internalization of AMPA receptors. Interaction and interference experiments revealed that ephrinB ligands and AMPA receptors are bridged by GRIP. This interaction is regulated by phosphorylation of a single serine residue in close proximity to the C-terminal PDZ protein target site in ephrinB ligands (Essmann et al., 2008). To investigate the in vivo relevance of this previously undescribed feature of ephrinB reverse signaling, we generated ephrinB2 S-9>A knock-in mice, where the serine at position -9 was replaced by an alanine to prevent phosphorylation. The mutated ephrinB2 of this mouse line was expressed and able to form clusters following stimulation with the preclustered receptor EphB4-Fc. Surface ephrinB2 cluster size and cluster number was slightly smaller in comparison to wild type (WT) mice. Analyzing AMPA receptor internalization, we oserved an increased basal GluR2 endocytosis in cultured hippocampal neurons of ephrinB2 S-9>A mice. Dendrite and spine morphology was similar in pyramidal CA1 neurons of brain slices from adult ephrinB2 S-9>A and WT mice, suggesting a redundancy between the different ephrinB familily members.
Apart from regulating AMPA receptor stability at the synapse, GRIP1 also has an important role in the secretory pathway to deliver cargo proteins along microtubules to dendrites and synapses (Setou et al., 2002). Proteins involved in synaptic transmission and plasticity, as well as lipids required for the outgrowth and remodeling of dendrites and axons have to be transported. We showed in our laboratory with a directed proteomic analysis using the tandem affinity purification-mass spectrometry methodology (Angrand et al., 2006) and with immunoprecipitation assays with brain lysates that the small regulatory protein 14-3-3 interacts with GRIP1. Further immunoprecipitation assays with lysates from HeLa cells transfected with various parts and sequence mutants of GRIP1 revealed that threonine 956 in the linker region L2 between PDZ6 and PDZ7 of GRIP1 is necessary for the interaction with 14-3-3. GRIP1 has been postulated to influence dendritic arborization and maintenance in hippocampal neurons in culture due to defective kinesin-dependent transport along microtubules (Hoogenraad et al 2005). In order to address the role of the association of GRIP1 and 14-3-3 in dendritogenesis, we transfected rat hippocampal neurons with GRIP1-WT and GRIP1 mutants and performed Sholl analysis to evaluate dendritic arborization defects. We could observe striking increased formation and growth of dendrites in developing neurons as well as in mature neurons overexpressing GRIP1-WT. However, overexpression of GRIP1-T956A, where the threonine 956 was replaced by an alanine to prevent phosphorylation, did not show enhanced dendritogenesis, indicating a role for threonine 956 phosphorylation in dendrite branching. To investigate the importance of the interaction between GRIP1 and 14-3-3 in vivo, we generated transgenic mouse lines with a GRIP1-T956A transgene or a GRIP1-WT transgene as control. These mice were crossed with heterozygous GRIP1 mice and by further breedings we obtained some surviver mice carrying either the wild type or the mutated GRIP1 transgene in the usually embryonic lethal GRIP1-KO background (Bladt et al., 2002; Takamiya et al., 2004). In embryonic day (E) 14.5 cultured hippocampal GRIP1-KO neurons we could observe reduced dendritic growth. We also showed reduced GluR2 staining on the dendritic surface in cultured hippocampal neurons from GRIP1-KO and GRIP1-KO neurons containing the GRIP1-T956A transgene. GRIP1-KO neurons containing the GRIP1-WT transgene showed a similar surface GluR2 signal intensity as WT neurons. Reduced surface GluR2 staining in GRIP1-KO neurons and GRIP1-KO neurons with the GRIP1-T956A transgene might be a consequence of defective kinesin-dependent transport of GluR2 to dendrites, indicating an important role of threonine 956 phosphorylation of GRIP1 for GluR2 trafficking.