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Multicellular organisms require that cells adhere to each other. This cell-cell adhesion is indispensable for the formation and the integrity of epithelial structures, tissues and organs. Mammals have developed four different cell-cell adhesion structures, the adhering junctions, which ensure the tight contact between cells but are also important platforms for communication and exchange in tissues. Two of these adhering junctions are cadherin based, the belt-like adherens junctions and the spot-like desmosomes. Both structures have in common that they are composed of single membrane spanning proteins, the cadherins, which accomplish adhesion in a calcium-dependent manner. The intracellular parts of classical as well as desmosomal cadherins bind to different adaptor proteins of the armadillo-protein family and others which build a protein plaque underneath the membrane and link the cadherins to the actin or intermediate filament cytoskeleton.
Desmosomes are of special importance for tissues that have to withstand mechanical stress. Although they are essential to stabilize tissues they have to be highly flexible and dynamic structures, as processes like wound healing or tissue remodeling require that adhesive interactions can be modulated. The molecular dynamics within desmosomes are not jet understood in detail, but it is assumed that two different membrane associated pools of desmosomal cadherins exist in cells. Cadherins that are incorporated in mature desmosomes are part of the junctional pool, whereas cadherins that are not associated with firm desmosomes and the intermediate filament cytoskeleton belong to the non-junctional pool. Lateral movements between the two pools results in a dynamic equilibrium and allows for example the exchange of old cadherins. Little is known about the breakdown of desmosomal cadherins. Several studies found that desmosome assembly or endocytosis are cholesterol dependent processes and claimed that membrane microdomains play a role in the regulation of desmosome dynamics. Moreover, membrane rafts may be involved in the pathomechanism of the desmosome associated disease pemphigus, were autoantibodies bind to the cadherin desmoglein-3 and trigger its internalization which results in a loss of adhesion in skin cells.
Membrane rafts are cholesterol dependent nanoscale structures of cellular membranes that are able to regulate the distribution of proteins within the plasma membrane and thus form platforms for cell signaling and membrane trafficking. Flotillins are proteins that are associated with membrane rafts and are reported to be involved in processes like endocytosis, endosomal sorting and a multitude of different signaling events. We could recently show that the membrane raft associated proteins flotillin-1 and flotillin-2 bind directly to the armadillo protein y-catenin which can be part of both, the adherens junction and the desmosome. The aim of this study was to eluciadate a possible role of flotillins in the regulation of desmosomes.
HaCaT keratinocytes were chosen as the main cell system for this study and at first the association of desmosomal components with flotillins was analyzed in detail. It was found that flotillins are clearly associated with desmosomal proteins. They colocalize with desmoglein-3 at cell borders and precipitate the other desmogleins. Further binding assays revealed that both flotillins bind to all desmogleins and the long isoforms of the second class of desmosomal cadherins, the desmocollins. The interaction is a direct one and was mapped to the ICS sequence within the cadherins. This close association rendered the question whether flotillins are functionally implicated in desmosome regulation. To address this issue, stable flotillin knockdown HaCaT cells were analyzed in detail. The molecular morphology of desmoglein-3, desmoglein-1 and two plaque proteins was clearly altered in the absence of flotillins. The membrane staining of all tested desmosomal proteins was derailed and disordered. Furthermoore, the loss of flotillins had an impact on the adhesive capacity of HaCaT keratinocytes. The cell-cell adhesion was weakened in the absence of flotillins, which was monitored by an increased fragmentation of knockdown cells in a cell dissociation assay.
In order to find out the mechanism by which flotillins influence the membrane morphology and the adhesiveness in keratinocytes, the association of desmosomal proteins with membrane microdomains was examined, at first. A predominant part of desmoglein-3 is associated with membrane rafts in HaCaT keratinocytes, whereas only a minor part of desmoglein-1 is found there. However, the raft-association of none of the examined proteins was altered in the absence of flotillins. Furthermore, flotillin depletion did not change the distribution of desmogleins with the two different cadherin pools. Less desmoglein-3 is found in the junctional pool of the flotillin depleted cells compared to the control cells, but this is due to an overall diminished desmoglein-3 protein level in these cells.
Flotillins are involved in endocytic processes but their exact role there is under debate. The endocytic uptake of desmosomal cadherins requires intact membrane rafts, but the precise mechanism is still unknown. A possible involvement of flotillins on the endocytosis of desmoglein-3 was addressed next. It is known that the internalization of desmoglein-2 is dependent on the GTPase dynamin, arguing for an involvement of dynamin in the endocytosis of desmoglein-3 as well. When dynamin and thus desmoglein-3 endocytosis was inhibited using chemical compounds, the mislocalization of desmoglein-3 that was observed in flotillin knockdown cells was restored. This suggest that inhibition of desmoglein-3 endocytosis enhances the amount and/or availability of desmoglein-3 at the plasma membrane, which then normalizes the morphological alterations caused by a knockdown of flotillins. Furthermore the morphological alterations in the flotillin knockdown HaCaT cells were found to be similar to the localization of desmoglein-3 that was observed upon treatment of keratinocytes with PV IgG These structures have been described before as linear arrays and are assumed to be sites of endocytic uptake. This strengthens the idea that enhanced desmoglein-3 internalization takes place in the absence of flotillins, which then results in a weakened adhesion.
Altogether this study revealed flotillins as novel players in desmosome mediated cell-cell adhesion processes. By binding to desmosomal cadherins and desmosomal plaque proteins, flotillins stabilize desmosomes at the plasma membrane and are required for a proper cell-cell adhesion.
Der Gyrus dentatus ist eine anatomische Region im Hippocampus und besitzt die einzigartige Fähigkeit auch im adulten Gehirn lebenslang neue Nervenzellen zu generieren. Dieser Prozess wird als adulte Neurogenese bezeichnet, stellt eine besondere Form struktureller Plastizität dar und es wurde gezeigt, dass adult neugebildete Körnerzellen im Gyrus dentatus essentiell am Prozess des hippocampalen Lernens und der Gedächtnisausbildung beteiligt sind. Es wird vermutet, dass neue Körnerzellen aufgrund ihrer charakteristischen Eigenschaften verstärkt auf neue Informationsmuster reagieren können und darauf spezialisiert sind Muster, die eine hohe Ähnlichkeit zueinander haben zu separieren und diese Unterschiede zu kodieren. Obwohl bereits eine Vielzahl von wissenschaftlichen Studien zum Verständnis der Entwicklung und Funktion adult neugebildeter Körnerzellen beitragen konnte, bestehen immer noch Unklarheiten darin, wie sich diese neuen Nervenzellen strukturell entwickeln, wann es zu einer funktionellen Integration kommt und wie diese beiden Prozesse miteinander zusammenhängen. In den vorliegenden Arbeiten wurde die strukturelle Entwicklung und synaptische Integration adult neugebildeter Körnerzellen in das bestehende hippocampale Netzwerk der Ratte und Maus unter in vivo Bedingungen untersucht. Zur Beantwortung dieser Fragen wurden Methoden aus der Anatomie, Histologie und in vivo Elektrophysiologie kombiniert. Der Nachweis neuer Körnerzellen erfolgte entweder durch immunhistologische Färbungen gegen spezifische Marker für unreife und reife Körnerzellen, Markierungen mit Bromdesoxyuridin oder retro- bzw. adenovirale intrazerebrale Injektionen und Expression von GFP. Es wurde eine in vivo Stimulation des Tractus perforans in der anästhesierten Ratte zur Langzeitpotenzierung der Körnerzellsynapsen und anschließend eine immunhistologische Analyse der Expression von synaptischen Aktivitäts- und Plastizitätsmarkern in neugebildeten und reifen Körnerzellen nach der Stimulation durchgeführt. Zusätzlich wurden detaillierte drei-dimensionale Rekonstruktion dendritischer Bäume erstellt und dendritische Dornenfortsätze an retroviral markierten Zellen analysiert.
Die vorliegenden Daten belegen den generellen Verlauf der Entwicklung neugeborener Körnerzellen in zwei unterschiedliche Phasen: eine frühe dendritische Reifung und eine späte funktionelle und synaptische Integration. Neugeborene Körnerzellen zeigten ein rasches dendritisches Auswachsen, dass innerhalb der ersten drei bis vier Wochen abgeschlossen war. Während dieses Wachstumsprozesses passieren Dendriten nacheinander die Körnerzellschicht und anschließend die innere, mittlere und äußere Molekularschicht. Dadurch sind sie innerhalb ihrer morphologischen Entwicklungsphasen anatomisch auf spezifische präsynaptische Partner limitiert. In der wissenschaftlichen Literatur wird eine transiente kritische Phase beschrieben, in der neugeborene Körnerzellen eine starke Plastizität und sensitivere synaptische Erregbarkeit aufweisen. Obwohl die vorliegenden Resultate keine direkten Hinweise auf eine stärkere bzw. sensitivere Plastizität neugeborener Körnerzellen liefern, konnte eine Phase zwischen vier und fünf Wochen identifiziert werden, in der neue Körnerzellen einen sprunghaften Anstieg in ihrer Fähigkeit zur Expression synaptischer Aktivitätsmarker (z.B. Arc und c-fos) und Ausbildung struktureller Plastizität (Dendriten und Dornenfortsätze) zeigten. Die präsentierten Resultate machen deutlich, dass Dornenfortsätze neuer Körnerzellen nach elf Wochen eine vergleichbare Dichte, Größenverteilung und Plastizität aufzeigen, die vergleichbar mit denen vorhandener Körnerzellen sind. Die Fähigkeit zur dendritischen Plastizität nach synaptischer Aktivierung zeigten jedoch nur neugeborene Körnerzellen zwischen der vierten und fünften Woche. Diese Ergebnisse implizieren, dass die Integration neugebildeter Körnerzellen kontinuierlich verläuft und obwohl die vorliegenden Daten die Existenz einer dendritischen Plastizität und einen sprunghaften Anstieg synaptischer Plastizität in der vierten und fünften Woche belegen, wurden keine weiteren Hinweise auf eine transiente kritische Phase gefunden. Des Weiteren zeigten dendritische Bäume von gereiften adult neugeborenen und reifen Körnerzellen Unterschiede, die daraufhin deuten, dass neue Körnerzellen eine eigene Subpopulation darstellen.
Colorectal cancer (CRC) has the third highest incidence and the fourth highest mortality rate worldwide and represents a substantial health care burden and affects the life of millions of people. CRC is a genetic disease caused by the stepwise accumulation of genetic alterations. The initiating event in colorectal carcinogenesis is the aberrant activation of the WNT pathway, but other pathways are also commonly deregulated, including the PI3K/AKT pathway. A number of previous studies using genetically engineered mouse models aimed at dissecting the exact role of PI3K/AKT pathway in CRC, but have yielded in rather conflicting results. Despite the inconsistent results, these studies already put forward the idea that PI3K/AKT signaling in combination with other genetic events might substantially contribute to tumor progression. Since the PI3K/AKT pathway is frequently activated in CRC, it represents an ideal candidate for therapeutic intervention. Although extensive efforts had led to the development of numerous inhibitors targeting the PI3K/AKT pathway, the diversity of genetic alterations can challenge the identification of the most effective therapeutic targets. Therefore, the discovery of shared tumor-promoting mechanisms downstream of these genetic alterations might unravel new biomarkers and druggable targets. The aim of this study was to elucidate the precise role of PI3K/AKT pathway during the course of colorectal carcinogenesis and to decipher novel protumorigenic molecular mechanisms downstream of PI3K/AKT activation that can be used for therapeutic intervention.
To obtain a better insight into the role of the PI3K/AKT pathway during colorectal carcinogenesis, mice expressing an oncogenic variant of AKT1 (AktE17K) specifically in the intestinal epithelial cells (IEC) were used. At the age of 6 months untreated AktE17K mice showed clearly perturbed intestinal homeostasis, but no tumor formation. To induce colonic tumorigenesis, AktE17K mice were subjected to treatment with the colonic carcinogen azoxymethane (AOM). In response to AOM, AktE17K mice developed invasive but non-metastatic tumors, which showed strong nuclear accumulation of TP53. To investigate the role of PI3K/AKT signaling specifically in CRC progression, AktE17K mice were crossed to TP53-deficient mice (Tp53ΔIEC). Unlike AktE17K mice, untreated Tp53ΔIEC; AktE17K, developed highly invasive small
intestinal tumors by the age of 6 months. To investigate the role of AKT hyperactivation in colonic tumor progression, Tp53ΔIEC; AktE17K mice were subjected to AOM treatment. AKT hyperactivation significantly enhanced tumor progression and induced metastatic dissemination.
To get a better insight how AKT signaling can promote tumor progression, whole tumor tissues from AOM-treated Tp53ΔIEC and Tp53ΔIEC; AktE17K mice were subjected to next generation mRNA sequencing and phospho-proteomic analysis by mass spectrometry. Both analyses indicated that AKT hyperactivation expands the inflammatory tumor microenvironment and upregulates pathways associated with invasion and metastasis. Importantly, Gene Set Enrichment Analysis revealed that AOM-induced colon tumors of Tp53ΔIEC; AktE17K animals, are highly similar in their gene expression profile to the CMS4 subtype of human CRC, which is associated with worse overall- and relapse-free survival. Gene expression analysis also suggested elevated NOTCH signaling in the Tp53ΔIEC; AktE17K tumors. Interestingly, while the expression of Notch3 mRNA was increased in the tumors of Tp53ΔIEC; AktE17K mice, the expression of the other NOTCH receptors was unaffected by AKT hyperactivation. In vitro experiments using TP53-deficient mouse tumor organoids with hyperactive AKT signaling confirmed the direct, tumor cell-intrinsic link between AKT activation and increased Notch3 expression. Moreover, inhibition of EZH2 mimicked the effect of AKT hyperactivation on Notch3 expression, suggesting that AKT regulates Notch3 via an epigenetic mechanism.
Knock-down of Notch3 in TP53-deficient mouse tumor organoids with hyperactive AKT signaling resulted in differential regulation of several pathways with potential role in invasion and metastasis and in cell death and survival. Subsequent in vivo experiments confirmed the role of NOTCH3 signaling in CRC progression. Treatment of AOM-induced Tp53ΔIEC; AktE17K mice with a NOTCH3 antagonistic antibody or the γ-secretase inhibitor DAPT significantly reduced invasion and metastasis. Importantly, NOTCH3 expression was also found to be associated with human CRC progression, suggesting that NOTCH3 represent a valid target for the treatment of CRC. This work, using genetically engineered mouse models and advanced in vitro techniques, has demonstrated a strong tumor promoting role for PI3K/AKT signaling in CRC progression and has identified NOTCH3 signaling as a potential therapeutic target downstream of the PI3K/AKT pathway.
Colorectal cancer (CRC) has the third highest incidence and the fourth highest mortality rate worldwide and represents a substantial health care burden and affects the life of millions of people. CRC is a genetic disease caused by the stepwise accumulation of genetic alterations. The initiating event in colorectal carcinogenesis is the aberrant activation of the WNT pathway, but other pathways are also commonly deregulated, including the PI3K/AKT pathway. A number of previous studies using genetically engineered mouse models aimed at dissecting the exact role of PI3K/AKT pathway in CRC, but have yielded in rather conflicting results. Despite the inconsistent results, these studies already put forward the idea that PI3K/AKT signaling in combination with other genetic events might substantially contribute to tumor progression.
Since the PI3K/AKT pathway is frequently activated in CRC, it represents an ideal candidate for therapeutic intervention. Although extensive efforts had led to the development of numerous inhibitors targeting the PI3K/AKT pathway, the diversity of genetic alterations can challenge the identification of the most effective therapeutic targets. Therefore, the discovery of shared tumor-promoting mechanisms downstream of these genetic alterations might unravel new biomarkers and druggable targets. The aim of this study was to elucidate the precise role of PI3K/AKT pathway during the course of colorectal carcinogenesis and to decipher novel pro-tumorigenic molecular mechanisms downstream of PI3K/AKT activation that can be used for therapeutic intervention.
To obtain a better insight into the role of the PI3K/AKT pathway during colorectal carcinogenesis, mice expressing an oncogenic variant of AKT1 (AktE17K) specifically in the intestinal epithelial cells (IEC) were used. At the age of 6 months untreated AktE17K mice showed clearly perturbed intestinal homeostasis, but no tumor formation. To induce colonic tumorigenesis, AktE17K mice were subjected to treatment with the colonic carcinogen azoxymethane (AOM). In response to AOM, AktE17K mice developed invasive but nonmetastatic tumors, which showed strong nuclear accumulation of TP53. To investigate the role of PI3K/AKT signaling specifically in CRC progression, AktE17K mice were crossed to TP53- deficient mice (Tp53ΔIEC). Unlike AktE17K mice, untreated Tp53ΔIECAktE17K, developed highly invasive small intestinal tumors by the age of 6 months. To investigate the role of AKT hyperactivation in colonic tumor progression, Tp53ΔIECAktE17K mice were subjected to AOM treatment. AKT hyperactivation significantly enhanced tumor progression and induced metastatic dissemination.
To get a better insight how AKT signaling can promote tumor progression, whole tumor tissues from AOM-treated Tp53ΔIEC and Tp53ΔIECAktE17K mice were subjected to next generation mRNA sequencing and phospho-proteomic analysis by mass spectrometry. Both analyses indicated that AKT hyperactivation expands the inflammatory tumor microenvironment and upregulates pathways associated with invasion and metastasis. Importantly, Gene Set Enrichment Analysis revealed that AOM-induced colon tumors of Tp53ΔIECAktE17K animals, are highly similar in their gene expression profile to the CMS4 subtype of human CRC, which is associated with worse overall- and relapse-free survival7 . Gene expression analysis also suggested elevated NOTCH signaling in the Tp53ΔIECAktE17K tumors. Interestingly, while the expression of Notch3 mRNA was increased in the tumors of Tp53ΔIECAktE17K mice, the expression of the other NOTCH receptors was unaffected by AKT hyperactivation. In vitro experiments using TP53-deficient mouse tumor organoids with hyperactive AKT signaling confirmed the direct, tumor cell-intrinsic link between AKT activation and increased Notch3 expression. Moreover, inhibition of EZH2 mimicked the effect of AKT hyperactivation on Notch3 expression, suggesting that AKT regulates Notch3 via an epigenetic mechanism.
Knock-down of Notch3 in TP53-deficient mouse tumor organoids with hyperactive AKT signaling resulted in differential regulation of several pathways with potential role in invasion and metastasis and in cell death and survival. Subsequent in vivo experiments confirmed the role of NOTCH3 signaling in CRC progression. Treatment of AOM-induced Tp53ΔIECAkt E17K mice with a NOTCH3 antagonistic antibody or the γ-secretase inhibitor DAPT significantly reduced invasion and metastasis. Importantly, NOTCH3 expression was also found to be associated with human CRC progression, suggesting that NOTCH3 represent a valid target for the treatment of CRC. This work, using genetically engineered mouse models and advanced in vitro techniques, has demonstrated a strong tumor promoting role for PI3K/AKT signaling in CRC progression and has identified NOTCH3 signaling as a potential therapeutic target downstream of the PI3K/AKT pathway.
Glucose homeostasis is tightly regulated by insulin production from ß-cells and glucagon production from α-cells. Changes in the balance of these hormones lead to Diabetes Mellitus (DM), which is foreseen to be the 7th leading cause of death by 2030, warranting a high demand to identify new therapeutics. DM is characterized by a reduction in ß-cell mass and reduced insulin production from ß-cells. α-cell development and fate mainly depend on the activity of the homeodomain-containing transcription factor Aristaless related homeobox (Arx). Conditional loss- of- function of Arx in α-cells leads to their conversion into functional insulin-producing ß-cells and thus an expansion of ß-cell mass. Therefore, inhibition of Arx is an interesting target for the expansion of ß-cells. The zebrafish model provides a fast, cost-effective and reliable translational platform for drug discovery in an in vivo setting. Here, we screened ~6217 small molecules on a transgenic zebrafish line (TgBAC(arxa:Luc2)) in which the arx promoter drives the expression of the luciferase gene which allows a sensitive and quantitative readout of promoter activity. Small molecule screening allowed us to identify 36 candidate repressors of arxa promoter activity. Furthermore, we started to validate these candidates in other assays. Preliminary results showed that DMAT (a potent CK2 inhibitor) and CNS-1102 (NMDA receptor inhibitor) increase functional ß-cell regeneration. By lineage tracing α-cells during ß-cell regeneration, we could show that both DMAT and CNS-1102 promote α- to ß-cell transdifferentiation. Here, we propose that Casein kinase II and NMDA receptor as potential molecular targets that could be exploited for the treatment of diabetes by generating functional beta-cells from the non-beta-cell progenitor, particularly alpha-cells in situ.
Inhibition of midbrain dopamine (DA) neurons codes for negative reward prediction errors, and causally affects conditioning learning. DA neurons located in the ventral tegmental area (VTA) display two-fold longer rebound delays from hyperpolarizing inhibition in comparison to those in the substantia nigra (SN). This difference has been linked to the slow inactivation of Kv4.3-mediated A-type currents (IA). One known suppressor of Kv4.3 inactivation is a splice variant of potassium channel interacting protein 4 (KChIP4), KChIP4a, which has a unique potassium channel inactivation suppressor domain (KISD) that is coded within exon 3 of the KChIP4 gene. Previous ex vivo experiments from our lab showed that the constitutive knockout of KChIP4 (KChIP4 KO) removes the slow inactivation of IA in VTA DA neurons, with marginal effects on SN DA neurons. KChIP4 KO also increased firing pauses in response to phasic hyperpolarization in these neurons. Here I show, using extracellular recordings combined with juxtacellular labeling in anesthetized mice, that KChIP4 KO also selectively changes the number and duration spontaneous firing pauses by VTA DA neurons in vivo. Pauses were quantified with two different statistical methods, including one developed in house. No other firing parameter was affected, including mean frequency and bursting, and the activity of SN DA neurons was untouched, suggesting that KChIP4 gene products have a highly specific effect on VTA DA neuron responses to inhibitory input.
Following up on this result, I developed a new mouse line (KChIP4 Ex3d) where the KISD-coding exon 3 of KChIP4 is selectively excised by cre-recombinase expressed under the dopamine transporter (DAT) promoter, therefore disrupting the expression of KChIP4a only in midbrain DA neurons. I show that these mice have a highly selective behavioral phenotype, displaying a drastic acceleration in extinction learning, but no changes in acquisition learning, in comparison to control littermates. Computational fitting of the behavioral data with a modified Rescorla-Wagner model confirmed that this phenotype is congruent with a selective increase in learning from negative prediction errors. KChIP4 Ex3d also had normal open field exploration, novel object preference, hole board exploration and spontaneous alternation in a plus maze, indicating that exploratory drive, responses to novelty, anxiety, locomotion and working memory were not affected by the genetic manipulation. Furthermore semi-quantitative IHC revealed that KChIP4 Ex3d mice have increased Kv4.3 expression in TH+ neurons, suggesting that the absence of KChIP4a increases the binding of other KChIP variants, which known to increase surface expression of Kv4 channels.
Furthermore, in the course of my experimental study I identified that the most used mouse line where cre-recombinase is expressed under the DAT promoter (DAT-cre KI) has a different behavioral phenotype during conditioning in relation to WT littermate controls. These animals displayed increased responding during the initial trials of acquisition and delayed response latency extinction, consistent with an increase in motivation, which is in line with a decrease in DAT function.
I propose a working model where the disruption of KChIP4a expression in DA neurons leads to an increase in binding of other KChIP variants to Kv4.3 subunits, promoting their increased surface expression and increasing IA current density; this then increases firing pauses in response to synaptic inhibition, which in behaving animals translates to an increase in negative prediction error-based learning.
The adult mammalian heart is unable to regenerate lost myocardial tissue after injury. In contrast, some lower vertebrates including zebrafish are able to undergo complete epimorphic regeneration following multiple types of cardiac injury. During the process of regeneration, spared zebrafish cardiomyocytes in the vicinity of the injured area undergo dedifferentiation and proliferation, thereby giving rise to new cardiomyocytes which replace the injured muscle. Insights into the molecular networks controlling these regenerative processes might help to develop novel therapeutic strategies to restore cardiac performance in humans.
While TGF-β signaling has been implicated in zebrafish cardiac regeneration, the role of individual TGF-β ligands remains to be determined. Here, I report the opposing expression response of two TGF-β ligand genes, mstnb and inhbaa, during zebrafish heart regeneration. Using gain- and loss-of-function approaches, I show that these ligands exert opposite effects on cardiac regeneration and specifically on cardiomyocyte proliferation. Notably, I show that overexpression of mstnb and loss of inhbaa negatively regulate cardiomyocyte proliferation and therefore disturb cardiac regeneration. In contrast, loss of mstnb and activation of inhbaa not only promote physiological cardiomyocyte proliferation but also enhance cardiac regeneration. I also identify Inhbaa as a mitogen which promotes cardiomyocyte proliferation independent of the well-established Nrg-ErbB signaling. Mechanistically, I unraveled that Mstnb and Inhbaa function through alternate Activin type 2 receptor complexes to control the activities of the signal transducers, Smad2 and Smad3, thereby regulating cardiomyocyte proliferation.
Altogether, I reveal novel and unidentified opposite functions of two TGF-β ligands during cardiac development and regeneration, resulting in a pro-mitogenic as well as an anti-mitogenic effect on cardiomyocytes. This study should therefore stimulate further research on targeting specific TGF-β family members to generate novel regenerative therapeutic strategies.
The cardiovascular system (CVS) consists of heart and blood vessels, forming a close circulatory loop. All tissues depend on the nutrients and molecular oxygen (O2) delivered by the blood. Therefore, it is not surprising that the CVS is one of the first working systems and the heart is the first functional organ in the forming embryo (Baldwin 1996). The building blocks of blood vessels are endothelial cells (ECs), which form the endothelium, a specialized epithelium that defines the luminal surface of the vessels (Pugsley and Tabrizchi 2000). The process of blood vessel development comprises several steps. The first events occurring are the formation of new vessels de novo to constitute the primary vascular loop known as vasculogenesis. During vasculogenesis the vascular precursors, known as angioblasts, migrate and coalesce to form the axial vessels. Subsequently, the main vessels undergo a specification step where they acquire either arterial or venous identity. As the embryo increases in size, the main vascular loop needs to increase in complexity. In order to reach all the different parts of the developing organs, new blood vessels are formed from pre-existing ones, a phenomenon known as angiogenesis (Gore et al. 2012).
Mature blood cells have a short lifespan. Therefore, hematopoietic stem cells (HSCs) are required throughout lifetime to constantly form new blood cells in a process called hematopoiesis. Interestingly, endothelial and immune cells development have been shown to converge at different points during their development, one of which is developmental hematopoiesis. During embryogenesis, definitive hematopoiesis occurs in a tissue called hemogenic endothelium (HE), a specialized subset of ECs at the ventral wall of the dorsal aorta (DA). HE acquires hematopoietic potentials and gives rise to HSCs, through a process known as endothelial-to-hematopoietic transition (EHT). During EHT, these specialized ECs extrude from DA and colonize the so-called aorta-gonadmesonephros (AGM) region, forming the native HSCs (Paik and Zon 2010).
As vascular development requires different steps, the molecular pathways involved are many. The Notch signaling pathway has been demonstrated to be one of the main players in vascular development. Among other functions, Notch signaling has been shown to be important during EHT. In the murine model, Runx1, a master regulator of HSC formation, has been shown to be transcriptionally regulated by NOTCH1 through GATA2 activation. This observation was later corroborated by knockdown studies for notch1a and notch1b in zebrafish (Butko, Pouget, and Traver 2016). Another essential pathway for vascular development is the HIF pathway. Hif-1α, Hif-1β and Hif-2α mouse mutants show severe vascular defects that result in early embryonic lethality (Simon and Keith 2008), which hinders a deep analysis of the phenotypes incurring in the mutant embryos. In addition, deletion of Hif-1α specifically in myeloid cells showed abnormalities in the motility, invasiveness, and adhesion of macrophages (Cramer et al. 2003). Intriguingly, Hif-1α deletion in vascular endothelial cadherin-expressing cells led to a significant but partial reduction of HSC number, suggesting that other players may be involved in this pathway (Imanirad et al. 2014).
Zebrafish embryos have been shown to be tolerant to hypoxia at very early stages of development (Padilla and Roth 2001). Also, zebrafish embryos develop externally and this allows to finely manipulate the environment where they grow (Lieschke and Currie 2007). These features make zebrafish an ideal model to investigate how hypoxia and Hif transcription factors affect vertebrate vascular development. In this study, I will examine the impact of hypoxia on zebrafish vascular development. Specifically, I will dissect the role of hif-1α in macrophage-EC interactions during vascular development and repair. Moreover, I show redundant functions for hif-1α and hif-2α in HSC development upstream of Notch signaling.
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.
Taxonomy, phylogeny and zoogeography of the hexaploid Torini of the Middle East and North Africa
(2017)
Fishes of the tribe Torini Karaman, 1971 (Teleostei: Cyprinidae) are a diverse group of primary freshwater fishes, distributed in Africa, the Middle East, and Indomalaya. They are an important component of the native freshwater-fish fauna of the Middle East and North Africa, and occur in most large river systems of the Levant, Arabia, Mesopotamia, southern Iran, and Morocco. They belong to the subfamily Cyprininae, are characterised by being tetraploid or hexaploid, having large scales, and a smooth and ossified last unbranched ray in the dorsal fin. As primary freshwater fishes they are not able to tolerate marine conditions and depend on direct freshwater connections for their dispersal. This makes them an ideal model for zoogeographic studies.
Prior to this study, the diversity of the Torini species in the Middle East and North Africa was not well understood. The validity of several genera and species was unclear, and the generic assignment of several species changed frequently.
In this PhD project the taxonomy, phylogeny, and zoogeography of the Torini of the Middle East and North Africa were investigated with morphological, as well as molecular methods. More than 1550 fish specimens were examined morphologically. Some of the specimens, including the types of most nominal species, were already available from museum collections. The remaining specimens were collected during expeditions to Ethiopia, Iran, Jordan, Morocco and Syria. Tissue samples were collected for molecular genetic analyses. The mitochondrial genes for cytochrome b, NADH dehydrogenase subunit 4 and the tRNAs for serine and histidine were sequenced from more than 120 specimens, representing 20 species of Torini and two small, diploid African barbs (Cyprinidae, tribe Smiliogastrini). Molecular data were analysed with Bayesian inference and other methods.
The analyses confirmed that the hexaploid Torini of Africa and the Middle East form a monophyletic group. In the Middle East and North Africa the Torini are represented by the genera Arabibarbus, Carasobarbus, Mesopotamichthys, and Pterocapoeta. These genera are each morphologically diagnosable, monophyletic, and genetically distinct. The species 'Labeobarbus' reinii cannot be assigned to any of these genera, because it is morphologically dissimilar and genetically clearly separated from each of them. A generic name for this species is presently not available and until the description of a new genus it is preliminarily assigned to the genus 'Labeobarbus'.
Out of the 28 species-group taxa described from the Middle East and North Africa until now, 15 are valid: Arabibarbus arabicus, A. grypus, A. hadhrami, Carasobarbus apoensis, C. canis, C. chantrei, C. exulatus, C. fritschii, C. harterti, C. kosswigi, C. luteus, C. sublimus, Mesopotamichthys sharpeyi, Pterocapoeta maroccana, and 'Labeobarbus' reinii.
The phylogenetic relationships between the Middle Eastern and North African Torini are well resolved, based on the analysis of mitochondrial DNA sequences from nearly all relevant species.
The interspecific and intraspecific morphological and genetic diversity is shaped by the zoogeographic history. Conclusions can be drawn about the events that shaped the evolution of this group. The Torini originated in the Indomalayan biogeographical realm and colonised the Middle East and Africa during the Miocene via the Gomphotherium landbridge. The Indomalayan Torini are tetraploid, whereas those of the Middle East and Africa are hexaploid. Molecular phylogenetic analyses showed that the hexaploid Torini cluster within the tetraploid Torini. This makes the tetraploid Torini a paraphyletic group with respect to the hexaploid Torini. Morocco was colonised in two independent waves. The first came from sub-Saharan Africa and is represented by Pterocapoeta maroccana. The second originated in the Middle East and gave rise to C. fritschii, C. harterti, and probably 'L.' reinii. The Tigris-Euphrates system is the largest freshwater system in the Middle East. Its central position between the Orontes River and Jordan River in the West, the Iranian tributaries to the Persian Gulf in the East, and the Arabian Peninsula in the South made it an important crossroad for the colonisation of the Middle East by Torini and other freshwater biota. During the Miocene the predecessors of the Jordan and Orontes rivers were connected to the Tigris-Euphrates system. The Jordan River was separated from the Euphrates before the Orontes. Arabia was colonised in two waves. The first (A. arabicus, A. hadhrami, C. exulatus) dates to the Pliocene, whereas the second (C. apoensis) ended as recently as the late Pleistocene or early Holocene.
Tissue integrity is defined by the composition and connection of cells as a structural and functional unit. It is modulated by a magnitude of processes including differentiation, survival, controlled death and adhesion of cells. Besides, external factors such as physical forces are also involved. A suitable model system to study all modalities of tissue integrity is the mammary gland. Postnatally and within the reproductive phase, the mammary gland undergoes morphological and functional modifications that periodically loosen or strengthen tissue integrity. An important point in the development of the mammary gland is the regression during weaning, also termed involution. The transition from lactation to involution is important for a controlled loss of tissue integrity. In this transition, collective cell death is initiated but not yet prominent enabling the mammary gland to fully recover lactation.
In this thesis, modalities of tissue integrity were investigated using three-dimensional cell cultures (i.e. spheroids) and the mammary gland as model systems. In the context of this thesis, I established (1) an immunofluorescence staining protocol and its detailed evaluation. Furthermore, I studied (2) the role of cell survival during mammary gland development, (3) the effect of physical forces that modulate tissue integrity and (4) the contribution of proteins to cell adhesion and growth.
Since a homogeneous fluorescence stain of the specimen is necessary for quantitative analysis, an immunofluorescence staining protocol was established to stain large spheroids in toto. The evaluation contributes qualitative and quantitative criteria that judge the specificity, intensity and homogeneity of the stain. Based on this approach, it was possible to demonstrate the morphological and functional characteristics that spheroids share with the mammary gland in vivo. These characteristics included the synthesis of extracellular matrix, the development of polarized acinar structures and lactogenic differentiation.
The role of cell survival during mammary gland development was analyzed by means of the expression profile of the pro-survival protein BAG3. The expression of BAG3 differed in the progress of mammary gland development. While the expression was low during pregnancy, it rose in the lactation phase and peaked within the first days of involution, indicating that BAG3 is associated with early involution in the mammary gland. In vitro experiments related the expression of BAG3 to cell survival in mammary epithelial cells.
Physical forces naturally occur during developmental processes influence tissue integrity during the initiation of mammary gland involution. The influence of physical force applied as compression on mammary epithelial spheroids was investigated. A morphological analysis showed that following a lag, the cell nuclei volume changed upon compression. A short-term compression induced the activation of caspases. A prolonged compression reduced the activity of caspases. This suggests the induction of a process that allows cells the adaption to changing environmental conditions. BAG3 is known to be involved in mechanical stress-induced autophagy, also known as chaperone assisted selective autophagy (CASA). Compression of spheroids did not induce CASA. The experimentally applied strain was not comparable to the strain found in the alveolar cells during involution in vivo. Thus, whether or not CASA is activated during mammary gland involution remains elusive. Nevertheless, the methodical approach to apply compression on spheroids in vitro is a model to study the influence of physical forces on cell aggregates.
Apart from cell survival and physical forces, growth and adhesion of cells affect tissue integrity. A spheroid formation assay and subsequent data analysis and computational modeling enabled the investigation of these processes in a non-adhesive environment. The analysis suggested that spheroid formation follows a reaction-controlled process, in which cells do not necessarily form a connection when they collide. The loss of function of either E-cadherin or actin strongly inhibited the formation of a spheroid. The analysis further revealed that neither E-cadherin nor actin influence the chance of the cells to form a connection when they collide. Both molecules are more important in stabilizing established connections. Depolymerization of microtubules still allowed spheroids to form, but the formation was decelerated and growth of the final spheroids was inhibited. The results from computational modeling suggested that microtubules act on cell adhesion through different mechanisms, which also vary among different cell types. The inhibition of FAK phosphorylation at Y397, a downstream target of integrin signaling, and the analysis of FAK protein levels in spheroids showed that integrin-mediated signaling is not prominent in three-dimensional spheroids formed from non-invasive cells. A deletion of BAG3 gene expression increased the number of dead cells in forming spheroids suggesting that BAG3 predominantly affects cell survival.
The results of this thesis identified and characterized adhesion- and survival-associated proteins that are important for tissue integrity. This thesis suggests that a BAG3-dependent cell survival mechanism is prominent at the beginning of mammary gland involution. Future studies will have to identify the related factors and inducers of tissue integrity loss in the mammary gland. This will shed light on the physiology of the organ and could explain the disorders that destroy its integrity. In addition, this thesis contributes to a better understanding of spontaneous cell aggregation, the aggregate organization and implies a role of cell migration in these processes. Future studies that focus on three-dimensional cell migration could explain, how cell migration is promoted and to which extent it supports tissue integrity.
Tissue size regulation is critical for the normal functioning of the organ as well as to prevent unwanted pathogenesis such as cancer. The Hippo signaling pathway is well known for its robust regulation of tissue growth by the negative regulation of its nuclear effectors YAP1 and WWTR1. In this study, I have described the role of Yap1/Wwtr1 in zebrafish development, with a primary emphasis on the cardiovascular system.
I have generated zebrafish yap1 and wwtr1 mutants by CRISPR/CAS9. The mutant alleles are likely to be nonfunctional due to a premature stop codon and they show evidence of nonsense-mediated decay. Given that Yap1 and Wwtr1 are closely related proteins and have overlapping functions, I am given the opportunity to perform combinatorial analysis of the mutations on zebrafish development. Together with molecular probing tools, high-throughput sequencing and high-resolution imaging, I showed that
1. Double yap1;wwtr1 mutants exhibit severe posterior elongation phenotype, but somitogenesis appears to proceed as usual.
2. Yap1 and Wwtr1 may play an important role in PCV development and secondary angiogenic sprouting. However, key experiments will be needed to elucidate the direct role of Yap1 and Wwtr1 on these processes.
3. wwtr1-/- larvae hearts have a reduction in trabeculation, but in mosaic WT hearts, mutant cardiomyocytes prefer to populate the trabecular layer. My studies revealed that the mutant compact wall could not support trabeculation, which explains the hypotrabeculation phenotype of wwtr1-/- hearts. Additionally, Wwtr1 is required for myocardial Notch activity and can inhibit compact wall cardiomyocytes from entering the trabecular layer.
In summary, the Hippo signaling pathway, through Yap1/Wwtr1 has important regulatory functions in growth control. My work has revealed a surprising role for Yap1/Wwtr1 in tissue morphogenesis such as posterior tail morphogenesis and specific developmental processes of the cardiovascular system. It will be of interest to elucidate the regulation of Yap1/Wwtr1 in individual cells that translates into the complex cellular behaviors that drives morphogenesis.
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.
The human brain is one of the most complex biological systems. More than 100 billion neurons build networks that control basic body functions and highly coordinated movements, enable us to express emotions, feelings and thoughts and to store memories over years and even throughout life time. Ultimately, “We are who we are because of what we learn and what we remember” (Kandel 2006). Under pathological conditions, the brain function is challenged. Most if not all neurological diseases have in common that they are either triggered and/or accompanied by inflammatory processes of brain tissue, referred to as neuroinflammation. Such inflammatory processes directly affect an elementary neural mechanism relevant for learning and memory: synaptic plasticity. Indeed, neurons are highly dynamic structures and able to respond to specific stimuli with morphological, functional and molecular adaptations that modify the strength and number of neuronal contact sides (synapses). Hence, the main motivation of this thesis was to identify the neural targets through which inflammation affects brain function and synaptic plasticity in particular. The principles of synaptic plasticity have been studied intensively in the hippocampus, an anatomical structure localized within the temporal lobes that is essential for the consolidation of memories and spatial navigation. Synaptic plasticity is coordinated by complex interactions of thousands of molecules and proteins. Among those proteins, synaptopodin (SP) is localized at a strategic position within excitatory synapses and has been shown to be fundamentally involved in the regulation of synaptic plasticity.
To induce neuroinflammation and to study its effects on SP as well as synaptic plasticity, the classic model of lipopolysaccharide (LPS) was applied. This thesis discloses that inflammatory processes impair the ability of neurons to express hippocampal synaptic plasticity in vivo, which is accompanied by a downregulation of SP-mRNA and protein level in the mouse hippocampus, indicating that SP is one of the cellular targets through which inflammatory signaling pathways affect synaptic plasticity and hence neural function. To learn more about the cellular and molecular mechanisms, an in vitro LPS model was established using entorhino-hippocampal organotypic slice cultures (OTCs).
While confirming the major effect of LPS on SP, this thesis furthermore shows that neuroinflammation crucially involves the cytokine TNFα to transduce its effects on SP, and that microglial cells are the main source of TNFα production under inflammatory conditions. In an attempt to learn more about the mechanisms that are affected under conditions of neuroinflammation effects of retinoic acid (RA), a vitamin A derivate were tested. This is mainly because SP as well as RA have been shown to modulate synaptic plasticity through the accumulation of glutamate receptors at the postsynaptic site: SP via the association with the actincytoskeleton as well as intracellular calcium stores, and RA directly via the modulation of local protein synthesis within dendrites. Indeed, in slice cultures exposed to RA, hippocampal SP cluster size is upregulated, both in vitro and in vivo. Intriguingly, a lack of SP prevents RA-induced synaptic strengthening of hippocampal dentate granule cells in OTCs. This suggests a direct contribution of SP in RA-dependent synaptic plasticity. Interestingly, co-immunoprecipitation of SP-mRNA together with the RA-receptor alpha (RARα) further implies that RA directly controls synaptic plasticity via regulation of SP-protein expression. It is therefore interesting to speculate that RA may increase SP expression or prevent its reduction and thus alterations in synaptic plasticity under conditions of neuroinflammation. Taken together, this thesis identifies SP as an important neuronal target of TNFα-mediated alterations in synaptic plasticity. Moreover, the work on RA indicates that SP affects the ability of neurons to express synaptic plasticity by modulating/mediating local protein synthesis. Since neuroinflammatory processes are an elementary concomitant feature and/or cause of neurological diseases, I am confident that future work on the effects of inflammatory processes on brain function may provide the perspective in devising new therapeutic strategies for the treatment of neuropathologies such as Alzheimer’s disease, multiple sclerosis, epilepsy or stroke, by targeting SP expression and SP-mediated synaptic plasticity.
Savannas provide essential ecosystem services for human well-being in West Africa. Thus, ecosystem change not only directly affects biodiversity but also human livelihoods. Human land use considerably shaped these savanna ecosystems for millennia, particularly agriculture, livestock grazing, logging and the collection of non-timber forest products (NTFPs). NTFPs are wild plant products and comprise all organic matter from herbaceous plants, shrubs, and trees (excluding timber). Current increasing land use pressure through fast demographic changes is widely esteemed as a severe threat for savanna biodiversity and the socio-economy of rural communities. In consideration of the pivotal role of NTFP species for biodiversity and livelihoods, it is important to evaluate the effect of increasing land use change on savanna vegetation and on its provisioning service for human well-being. Thus, the major aim of this thesis is to investigate the impacts of land use intensification on vegetation composition, diversity and function and its consequences for provisioning ecosystem services (NTFPs) and human well-being in a West African savanna.
The research for this study was conducted in the North Sudanian vegetation zone of south-eastern Burkina Faso, where population growth exceeds the nationwide trend. Generally, Burkina Faso belongs to the worldwide poorest countries, where nearly one quarter of the population suffers from malnutrition (FAO 2014). The integration of NTFPs and particularly wild food species into rural household economies is, thus, an important measure in the national combat against poverty and food insecurity (FAO 2014). Against this background, I focus on vegetation changes, the economic importance of NTFPs as well as the decrease and substitution of wild food species in this study.
Vegetation resurveys of different vegetation types since the early 1990s showed that land use change led to more pronounced changes in the herbaceous than in the woody vegetation layer. Most woody vegetation types stayed stable in species composition and richness, even though some highly useful tree species (Vitellaria paradoxa, Parkia biglobosa) declined in some woody vegetation types. In contrast, in most herbaceous vegetation types species richness increased and species composition considerably changed. This change might be explained by a general ruderalisation process through a pronounced increase of wide-ranging herbaceous species. However, in spite of a general species increase in the herbaceous layer, a decrease of preferred herbaceous fodder species was found. Thus, the decline of useful species in both layers is alarming. Herbaceous vegetation types also showed more pronounced changes in plant functional trait characteristics in comparison to woody vegetation types. However, an increase of smaller plant species and species with a high diaspore terminal velocity (VTerm) was found in both vegetation layers. Since these two trait responses are generally related to grazing and browsing, the strong increase of livestock herds is likely to be responsible for the detected vegetation changes.
In addition to the vegetation study, interviews showed that all useful food species were widely considered to decline. The two economically most important tree species, the shea tree (Vitellaria paradoxa) and the locust bean tree (Parkia biglobosa) that contribute with 70% to wild food income, were considered among the most declining species of all cited wild food species. On this matter, local perceptions of species decline and results from field observations are in accordance. However, a wide range of cited substitutes indicated a great knowledge on alternative plant species in the area. Most wild food species are, however, substituted by other highly valued wild food species. Although our results suggest that rural communities are able to cope with the decrease or absence of wild food species, growing decline of one species would concurrently increase the pressure on other native food species. Therefore, the need to counteract the decrease of highly useful wild food species should be of high priority in management measures. In general, I showed that NTFPs are an essential component in rural households, since it contributed with 45 % to total household income. Significant differences in NTFP dependency between the two investigated villages and across the three main ethnic groups were detected, reflecting different traditional uses and harvesting practices. In general, it was shown that poorer households depend more on NTFP income than wealthier households. Against the background of this study, management strategies for agroforestry systems and poverty alleviation should consider local differences, and ethnicity-dependent NTFP-use patterns.
Overall, the combination of field studies on temporal and functional vegetation change with socio-economic and ethno-botanic interviews increases the knowledge on qualitative and quantitative vegetation changes and on the consequences for rural populations. This thesis gives a thorough insight into decreasing trends of economically valued plant species and thus gives evidence on the consequences of vegetation changes for ecosystem services of West African savanna ecosystems. Further, different NTFP-dependencies and use preferences according to socio-economic and cultural variables, such as ethnicity, present a valuable basis for specific decision-making and should be considered in management plans.