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Humans and other primates are highly visual animals. Our daily visual activities such as recognizing familiar faces, interacting with objects, or reading, are supported by an extensive system of interacting brain areas. The interactions between the many individual nerve cells both within and between brain areas need to be coordinated. One possible solution to achieve flexible coordination between cells in the network is rhythmic activity, or oscillations. The focus of the thesis will be activity in the largest visual area, V1, in non-human primates. In V1, high-frequency activity, so-called gamma-band activity (“gamma”, ca. 30-90 Hz) can be frequently observed and has been suggested to play a role in coordinating activity in the visual system. In Chapter 1, the coordination problem, the primate visual system and gamma-band oscillations are introduced in detail. The following chapters explore the dependence of gamma on contextual influences. Does V1 use contextual information to optimize co-ordination? In the first part, the short-term consequences of repeated encounters with visual stimuli on V1 responses are explored (Chapters 2 and 3). Inspired by results from colored, naturalistic images in the first part, the second part tests the dependence of gamma on spatial and chromatic stimulus aspects (Chapters 4 and 5).
Stimulus repetition is a simple yet powerful way to tap into our brains’ ability to learn and adapt to our environment. Repeated presentation of a visual stimulus tends to decrease responses to this stimulus. Is this accompanied by changes in the coordination of brain activity? In Chapter 2, the stimulus-specificity of repetition effects on gamma was tested using naturalistic stimuli. V1 is most typically studied using black-and-white, artificial stimuli that are very familiar to the animals. Here, colored natural images were repeatedly presented that were initially novel to the animals, to provide a wider and more naturalistic range of stimulation. Both multi-unit spiking activity (MUA) and gamma showed stimulus-specific repetition effects. MUA responses de-creased most strongly for initial repetitions and less for later repetitions. In contrast, gamma could increase or decrease for initial repetitions, but tended to increase for later repetitions. This points to the operation of multiple plasticity mechanisms. One process may rapidly decrease MUA and gamma and be related to initial novelty or adaptation. The other increases gamma, is active for more repetitions, and could constitute a form of refinement of coordination over time. Moreover, based on the spacing of stimulus repetitions, stimulus memory in V1 persisted for tens of seconds.
In the following Chapter 3, the stimulus location specificity and persistence of the repetition effects for longer timescales were tested. To this end, the observation that the increase in gamma with repetition was strongest for the first tens of repetitions was used to test for location specificity and memory. Using simple artificial stimuli that were repeated many times at two alternating locations, both location specificity and memory on the order of minutes was observed. Due to the structure of the primate visual system, location specificity suggests that the repetition effects involve early to mid-level visual areas such as V1. Memory for previous stimulus presentations on the order of minutes has not been previously reported for V1 gamma. Taken together, these experiments demonstrate short-term plasticity of gamma that is stimulus- and location specific and persists on the timescale of minutes.
In Chapter 2, the average gamma-band response to the large, naturalistic stimuli was highly stimulus dependent. Relative increases in gamma-band activity scaled between tens and thousands of percent change depending on the stimulus. Particularly the color of the stimuli appeared to play a strong role, although the stimulus set was too limited and uncontrolled to draw strong conclusions. In Chapters 4 and 5, underlying mechanisms for the stimulus specificity of gamma were explored using more well-controlled, artificial stimuli that varied in color and spatial structure.
Much of vision relies on the analysis of spatial structure. Each nerve cell in V1 only responds to visual stimuli in a particular, small part of the visual field, its so-called “receptive field” (RF). Compared to isolated RF stimulation, nearby cells that are stimulated by a similar structure from different parts of visual space can show response decreases, commonly known as “surround suppression”, and may show coordinated activity in the gamma band. In Chapter 3, responses to large, uniformly colored disks are contrasted with responses to black or white (achromatic) disks. A first experiment showed that gamma-band responses were stronger for colored than achromatic stimuli, whereas MUA responses could decrease below baseline for colored stimuli. To test whether these phenomena were related to surround suppression, stimulus size was manipulated in a second experiment. When stimuli were of sufficient size to induce surround suppression, clear gamma-band responses emerged. Surround suppression and gamma were stronger for chromatic stimuli. However, the change of stimulus size could have changed not only surround suppression but also stimulus saliency. Therefore, in a third experiment, the overall size of the stimulus was kept constant, and the spatial structure of the stimulus was manipulated. In comparison to uniform, predictable stimulus structure, mismatches between the center of the stimulus and the surrounding visual space led to strong increases in MUA responses and strong de-creases in gamma-band activity. These effects were restricted to the recording sites with RFs at the mismatch location. These experiments underpin the strong role of both spatial structure and color for gamma in V1.
In Chapter 4, responses to different color hues are studied in more detail. Gamma response strength depended on hue, being strongest for red compared to blue and green stimuli when measured with a gray background. To better understand the underlying mechanisms of the differential responses, the spatio-temporal context in the form of the background color was manipulated. Background color had a strong influence on gamma strength. Using differently colored backgrounds, different parts of the color signaling pathways could be adapted. Response differences to different color hues could be explained well with a model that incorporates differences in adaptation between pathways involving long- compared to medium-wavelength cone signals.
Taken together, these experiments indicate a strong role of both spatial context (stimulus size and structure) and temporal context and drive (repetition, adaptation) for the generation of gamma-band activity in V1. Functional implications of these dependencies are considered in the final Chapter 6, and a role for gamma-band syn-chronization in a coding regime for visual inputs that generate strong drive and high predictability is suggested.
Antagonistic and mutualistic species interactions provide important ecosystem functions affecting plant population dynamics and distribution. Many of these functions are important for the regeneration of plants, either by limiting or facilitating successful transition between life stages. Interactions can occur across the whole geographical range of a species and thereby encompass different environmental gradients, such as changes in temperature or water availability. Understanding the joint effects of species interactions and environmental factors on the regeneration of plants is key for understanding plant population dynamics under global change and could provide important recommendations for managing and conservation efforts.
My thesis aimed at advancing the knowledge of how species interactions depend on environmental conditions and jointly affect plant recruitment along the elevational distribution of plants. This thesis includes three chapters in which I studied the effects of animal seed deposition, seed predation, mycorrhizal and pathogenic fungi occurrences as well as abiotic and biotic environmental factors on the recruitment of Swiss stone pine (Pinus cembra). I conducted fieldwork in the Swiss Alps across the entire elevational distribution of the pine (1850 – 2250 m a.s.l). Over a period of three years, I recorded animal seed deposition by spotted nutcrackers (Nucifraga caryocatactes) and conducted seed translocation experiments. Further, I assessed fungal communities using DNA metabarcoding. I measured abiotic environmental factors such as temperature, water and light availability, pH, as well as biotic environmental factors such as distance to conspecific adults and ground vegetation cover. In my thesis, I used a broad range of community ecology approaches, from seed dispersal ecology to experimental plant ecology and microbial ecology.
First, I investigated the effects of environmental factors on four recruitment processes (i.e. seed deposition, seed predation, seed germination, seedling survival) of Swiss stone pine. Further, I aimed at identifying the most important recruitment processes potentially limiting pine regeneration across its elevational range. To investigate pine recruitment, I firstly tested how seed deposition, seed predation, seed germination and seedling survival were affected by the microhabitat characteristics ultimately determining where a seed arrives in the environment (i.e. canopy cover & ground vegetation cover). Secondly, I applied a sensitivity analysis to investigate which of the four recruitment processes poses limitation to the pines’ regeneration across its range. My results reveal that the importance of particular recruitment processes varies along the pines’ elevational range. I found that at the lower range margin and the distribution centre seed germination and seedling survival were the main limiting factors, whereas animal-mediated seed dispersal became especially important at the upper range margin. My study contributes to the field with a new approach for disentangling the relative importance of recruitment processes across environmental gradients and thereby could help to project how plant recruitment might respond to future changes in environmental conditions.
The second aim of my study was to investigate how abiotic and biotic environmental factors affect the occurrence of Swiss stone pine-associated pathogenic and mutualistic fungi by combining field measurements of environmental factors with a DNA metabarcoding approach. I identified potentially important fungal interaction partners of the pine and determined drivers shaping their occurrences. My results reveal that generalist fungi were not affected by abiotic and biotic environmental factors. However, specialist pathogens showed patterns according to the Janzen-Connell framework (i.e. accumulation of pathogen close to adult plants). Interestingly, I found evidence for an “inverse” Janzen-Connell effect, i.e. high abundance of a specialist mutualist close to adult plants, potentially mitigating effects of soil pathogens close to parent trees. Further, I found that pine-associated fungi are distributed widely within and beyond the range of their host plant, adding knowledge on how mutualisms and antagonisms might be affected when plants move their distributional range upwards.
Finally, I investigated how known and unknown plant-associated fungi affect the regeneration of Swiss stone pine in an environmental context. My results suggest that seedling establishment was most strongly affected by abiotic environmental factors, such as light availability and maximum summer temperature. Further, the results indicate that seedling survival was affected by biotic environmental factors, i.e. fungal agents, with high abundances of a known fungal pathogen co-occurring with low seedling survival rates. My results also reveal that known mycorrhizal partners as well as a large number of unknown fungal operational taxonomic units (OTUs) were associated with the survival of seedlings. My findings highlight the importance of plant-fungal interactions for plant recruitment and offer a feasible approach for the identification of hidden plant-fungal associations in highly complex DNA metabarcoding datasets. This approach offers a valuable tool for investigating plant-microbe interactions, ultimately helping to understand plant population dynamics.
My dissertation adds to a deeper understanding on the linkage between plant regeneration and species interactions, especially on how plant-animal and plant-fungal interactions in concert with environmental factors shape plant recruitment. My study reveals the importance of animal-mediated seed dispersal and fungal pathogens in plant recruitment with consequences for potential range shifts of plant species. My thesis has important implications for conservation and management efforts by informing on key species interactions under environmental change.
Ubiquitin and the ubiquitin-like protein ATG8 are covalently attached to their respective targets via a coordinated cascade involving E1 activating, E2 conjugating and E3 ligating enzymes. Whereas ubiquitin is conferred to proteins as mono- and/or polymer(s) to alter their stability, localization and/or activity, the ubiquitin-like modifier (UBL) ATG8 is conjugated to the phospholipid phosphatidylethanolamine (PE). The best understood function of ATG8 is during autophagy where ATG8-PE conjugates are incorporated into both layers of incipient autophagosomes and serve as multipurpose docking sites for autophagosomal cargo receptors as well as regulatory factors (termed adaptors) that drive formation and maturation of autophagosomes. Mammalian cells harbor six ATG8 family members that can be subclassified into the LC3- and GABARAP-family and that can all be lipidated. However, it is currently unclear to what extent these proteins are functionally redundant or fulfil unique roles.
Cullin-RING ligase complexes (CRLs) are modular E3 ubiquitin ligases that comprise a RING-finger protein that associates with the ubiquitin-charged E2 enzyme, a substrate recruiting module as well as a cullin scaffold as a linker between RING protein and substrate adaptor. Whereas SCF (SKP1-CUL1-F-box protein) complexes, the most studied CRLs, harbor cullin-1 (CUL1) as scaffold and F-box proteins as substrate binding modules, CUL3-containing CRL complexes employ cullin-3 (CUL3), RING-box protein 1 (RBX1) and BTB proteins as substrate adaptors. Here, the BTB domain serves as binding interface for CUL3 and is usually complemented by an additional protein-protein interaction domain such as MATH or Kelch that mediates binding to the substrate of the E3 ligase complex.
Besides ubiquitylation, guanine nucleotide binding is another common way to regulate protein activity and signaling in cells. Here, small Rho GTPases cycle between active and inactive states by binding of the guanine nucleotides GTP or GDP with the help of regulatory proteins. Whereas GTPase-activating proteins (GAP) render RAC1 inactive by facilitating GTP hydrolysis, guanine exchange factors (GEF) such as T-lymphoma invasion and metastasis-inducing protein 1 (TIAM1) activate RAC1 by stimulating the exchange of GDP to GTP. Local control of RAC1 activity is essential to allow a specific cellular response to stimuli such as growth factors or migratory impulses.
This study reports an unexpected link between the GABARAP subfamily of mammalian ATG8 proteins, the ubiquitin proteasome system and RAC1 through the ubiquitylation of the RAC1 GEF TIAM1. The Kelch repeat and BTB domain-containing proteins 6 (KBTBD6) and 7 (KBTBD7) were established as heterodimeric substrate adaptors for CUL3. Interestingly, a thorough proteomic analysis revealed a number of putative substrates but, out of 11 substrate candidates tested, only the RAC1 GEF TIAM1 appeared to be influenced by depletion of CUL3KBTBD6/KBTBD7. Binding studies showed that KBTBD7 binds TIAM1 via the Kelch repeats and that this binding was markedly enhanced when CUL3 activation was abolished upon treatment with the neddylation inhibitor MLN4924. Also, total TIAM1 abundance was increased upon CUL3KBTBD6/KBTBD7 depletion and accumulation of TIAM1 upon proteasome inhibition suggested that TIAM1 is degraded via the proteasome. In vivo ubiquitylation assays and denaturing immunoprecipitations as well as mass spectrometrical analysis confirmed that CUL3KBTBD6/KBTBD7 ubiquitylates TIAM1 at two distinct lysines (K1404 and K1420) close to its C-terminus.
Previously, KBTBD6 and KBTBD7 were found as interactors of several members of the human ATG8 family of proteins in a proteomic study analyzing the human autophagy network. This association was confirmed in the present work. Furthermore, peptide array technology and mutational analysis revealed that KBTBD6 and KBTBD7 employ a classical ATG8-family interacting motif (AIM; also referred to as LC3-interacting region or LIR) as binding interface. The AIMs of KBTBD6 (W-V-R-V) and KBTBD7 (W-V-Q-V) fulfil the consensus AIM sequence motif (F/W/Y1-X2-X3-I/L/V4) and are preceded by several acidic residues and serines. A series of structural and cell biological experiments revealed a binding preference for the GABARAP subfamily of human ATG8 proteins and most importantly, a requirement of the GABARAP-KBTBD6 and -KBTBD7 interaction for TIAM1 ubiquitylation. The finding that TIAM1 binding to KBTBD6 and KBTBD7 AIM mutants was diminished raised the possibility that GABARAP binding mediates the recruitment of CUL3KBTBD6/KBTBD7 to membranes where TIAM1 is localized. Interestingly, colocalization of KBTBD6, GABARAPL1 and TIAM1 in punctuate structures could be observed. Since only a very small fraction of GABARAPL1 colocalized with LC3B, and colocalization between KBTBD6 and LC3B was not observed, these vesicular structures are most likely distinct from autophagosomes. Furthermore, TIAM1 ubiquitylation was reduced when GABARAP, but not LC3B, was depleted or when lipidation of GABARAP was prevented.
Stabilization of TIAM1 upon KBTBD6 and/or KBTBD7 depletion led to elevated TIAM1-dependent RAC1 activity, altered actin morphology with increased cortical actin and loss of vinculin foci. Re-introduction of wild-type KBTBD6 or KBTBD7 but not AIM mutants reverted all these phenotypes. Moreover, depletion of KBTBD6 or KBTBD7 in human breast cancer cells massively increased their invasiveness, whereas TIAM1 knockdown had the opposite outcome. All physiological effects of KBTBD6 and KBTBD7 depletion were inhibited by additional depletion of TIAM1 or RAC1 confirming that the phenotypes observed are indeed mediated by the CUL3KBTBD6/KBTBD7-TIAM1-RAC1 signaling pathway. Intriguingly, KBTBD6 and KBTBD7 were not subject to autophagosomal degradation, thereby establishing a new function for GABARAP proteins beyond autophagosomal degradation in providing a signaling platform for recruitment of the E3 ligase CUL3KBTBD6/KBTBD7 in close proximity to its substrate TIAM1, enabling localized ubiquitylation.
Local restricted control of RAC1 activity by ubiquitylation has been described for TIAM1-RAC1 signaling previously. Examples are HECT, UBA and WWE domain-containing protein 1 (HUWE1)-mediated TIAM1 ubiquitylation that occurs predominantly at cell-cell-junctions in response to hepatocyte growth factor stimulation in MDCKII cells or inhibition of RAC1 activity by the RAC1 GAP protein BCR (breakpoint cluster region) at the leading edge of astrocytes through binding to the TIAM1-Par (polarity) complex. SCFBTRC mediates ubiquitylation of TIAM1 in response to mitogens or DNA damage, though it has not been explored whether this regulation is spatially restricted. Thus, this study adds a novel layer of complexity to the spatial regulation of RAC1 signaling by implicating membrane-bound human ATG8 proteins in this process.
Also, this study is the first report specifically implicating the GABARAP proteins in cellular signaling events. It will be interesting to explore whether the concept of localized signaling mediated by GABARAPs applies to other substrates of CUL3KBTBD6/KBTBD7 and membranerelated signaling processes in which GABARAP proteins are involved. Controlling RAC1 activity at GABARAP-decorated membranes might also be important for trafficking events or autophagy since it was described that RAC1 has an inhibitory function on autophagy. Therefore, spatial restricted ubiquitylation of TIAM1 resulting in specific deactivation of RAC1 could promote the autophagic process when locally needed. Although the catalytic mTOR inhibitor Torin1 and the lysosomal H+ ATPase inhibitor BafilomycinA1 promoted TIAM1 ubiquitylation by increasing the pool of membrane-conjugated GABARAP, but other signals that stimulate GABARAP-KBTBD6/KBTBD7 association and subsequent TIAM1 ubiquitylation are to be identified. Besides, determining the KBTBD6/KBTBD7 binding site in TIAM1 or uncovering a deubiquitylating enzyme (DUB) that locally counteracts the ubiquitylation of TIAM1 will enable a better comprehension of the complete localized signaling cascade.
Eine qualitative und quantitative Studie zum Einsatz der virtuellen Mikroskopie in der Schule
(2019)
Das Mikroskop stellt in der Alltagswelt ein Sinnbild für naturwissenschaftliches Arbeiten dar (Coleman 2009, Paulsen 2010). Im Bereich der Lehre eröffnet dieses Laborgerät das Eintauchen in die mikroskopische Dimension und besitzt eine wesentliche Rolle bei der damit verbundenen Erkenntnisgewinnung, insbesondere von funktionsmorphologischen Konzepten (Gropengießer & Kattmann 2008, Kremer 2002). Jedoch wird die Durchführung der klassischen Mikroskopie und damit die aktive Auseinandersetzung mit mikroskopischen Präparaten im schulischen (Biologie-)Unterricht durch verschiedene Faktoren erschwert. Zu den Limitierungen gehören beispielsweise die Verfügbarkeit geeigneter Mikroskope und Dauerpräparate, die aufwendige Vor- und Nachbereitungszeit sowie der zeitliche Aufwand bei der Herstellung hochwertiger mikroskopischer Frischpräparate. Die virtuelle Mikroskopie könnte diese Schwierigkeiten umgehen. Das virtuelle Mikroskop kann als eine Simulation verstanden werden, bei der die bildanalytischen Vorgehensweisen bei mikroskopischen Präparaten analog zur klassischen Mikroskopie nachvollzogen werden können (Gu & Oglivie 2005, Hentschel 2009). Hierbei umfasst das virtuelle Mikroskop ein Akquisitionssystem zum Einscannen und Digitalisieren mikroskopischer Präparate, einen Server zum Speichern und Bereitstellen der entstandenen virtuellen hochauflösenden Aufnahmen (WSI) sowie eine Bildbetrachtungssoftware auf einem Anwendungsrechner (Kalinski et al. 2006). Basierend auf einer Nutzerbefragung wurde eine Betrachtungssoftware programmiert, die hinsicht¬lich ihrer Benutzerfreundlichkeit und ihren Eigenschaften auf den schulischen Einsatz angepasst wurde. Um die Relevanz in diesem Anwendungsfeld zu testen, wurden die Untersuchungen der vorliegenden Arbeit sowohl im Schülerlabor Goethe BioLab als auch in der universitären Lehre der Abteilung für Didaktik der Biowissen¬schaften der Goethe–Universität Frankfurt am Main durchgeführt. Der Schülerlabortag „Blut und das virtuelle Mikroskop“ wurde entwickelt, um die computerbasierte virtuelle Mikroskopie mit Schülern ergänzend zur klassischen Mikroskopie in einem fachlichen Kontext anzuwenden und zu erforschen.
Beruhend auf der Vergleichbarkeit beider Mikroskopiemethoden (Paulsen et al. 2010) lagen die Forschungsschwerpunkte neben der Nutzung der Software durch Schülerinnen und Schülern auf einer gegenüberstellenden Beurteilung beider mikroskopischer Verfahren von Schülern und Lehramtsstudierenden. Es wurden in diesem Zusammenhang drei zentrale Forschungsfragen formuliert.
Die erste Forschungsfrage untersucht das Nutzerverhalten der Schüler (n = 123) bei der virtuellen Mikroskopie mittels automatisch generierter Datensätze während der Anwendung der Bildbetrachtungssoftware. Die Analyse der Anwendungsdaten zeigt, dass das mikroskopische Sehen, insbesondere das Fokussieren auf relevante Bildbereiche, im virtuellen Humanblutausstrich angewandt wurde.
Die zweite Forschungsfrage untersuchte das aktuelle Interesses bei Schülern (n = 293) im direkten Vergleich zwischen virtueller und klassischer Mikroskopie. Dabei wurde das aktuelle Interesse aufgrund des engen Zusammenhangs zum Lernen (vgl. Krapp 1992a) als Indikator der Lernwirksamkeit gewählt. Die Erhebung erfolgte mittels eines Fragebogens. Die Ergebnisse dieser Untersuchung zeigen, dass der Einsatz beider mikroskopischer Verfahren das aktuelle Interesse fördert, das emotionale und das wertbezogene Merkmal sich jedoch zugunsten der klassischen Mikroskopie signifikant unterscheiden.
Im Rahmen der dritten Forschungsfrage erfolgte eine Beurteilung der Vorteile virtueller Mikroskopie gegenüber der klassischen Mikroskopie von Schülern (n = 504) sowie Lehramtsstudierenden (n = 247). Hierbei diente ebenfalls ein Fragebogen als Grundlage der Erhebung. Die Auswertung zeigt, dass sowohl die Schüler als auch die Studierenden die Vorteile der virtuellen Mikroskopie klar erkennen. Es liegen jedoch signifikante Unterschiede zwischen den Versuchsgruppen vor. Die Schüler bewerten die Vorteile betreffend der Förderung von Lernprozessen, des Erkennens von Strukturen und des mikroskopischen Zeichnens höher.
Zusammenfassend bestärken die Ergebnisse dieser Studie die Ansicht, dass das virtuelle Mikroskop nicht als Ersatz, sondern als sinnvolle Ergänzung zu der klassischen Lichtmikroskopie angesehen werden sollte (Bloodgood et al. 2006, Berg et al. 2016, Braun & Kearns 2008, Hufnagl et al. 2012, Mione et al. 2013, Santiago 2018, Scoville & Buskirk 2007). Dabei sollte die vorliegende Arbeit als Einstieg verstanden werden, um bestehende Forschungslücken zu verkleinern, damit ein Transfer der virtuellen Mikroskopie in den schulischen Kontext möglichst lernwirksam erfolgen kann.
Die Neurowissenschaften sind in Forschungsarbeiten für Schüler und Studierende immer wieder als eines der schwierigsten Teilgebiete der Biologie angeführt. Die Inhalte werden überwiegend nicht verstanden. Als mögliche Ursache gelten die seltenen praktischen Zugänge für die Lernenden aufgrund limitierter Ressourcen. Diese Ursache konnte in der vorliegenden Arbeit durch eine Befragung der Lehrkräfte zu ihren Praxisumsetzungen bestätigt werden. 70 % der Lehrkräfte gaben an, dass sie keine Experimente in der Schule zum Thema Nervenzellen anbieten. Experimente zur Verhaltensbiologie führen 65 % der Lehrkräfte nicht durch.
Um Schülern die Möglichkeit zu geben, sich experimentell mit den Themenfeldern der Neuro- und Verhaltensbiologie auseinanderzusetzen, wurden im Rahmen der vorliegenden Arbeit Schülerlabortage auf dem Feld der Neurowissenschaften konzipiert. Die Konzepte wurden schülerorientiert umgesetzt und neurowissenschaftliche Forschung durch den eigenen Umgang mit modernen Forschungsapparaturen erfahrbar gemacht. Die drei Labortage für die Sekundarstufe II wurden wissenschaftlich begleitet: 1) Verhaltensbiologie, 2) systemische Ebene der Elektrophysiologie, 3) elektrophysiologische Forschungsmethoden. Um die Qualität und Wirksamkeit der Labortage beurteilen zu können, wurden sie mit Feedbackerhebungen begleitet. Die drei Labortage wurden sowohl von den Lehrkräften als auch von den Schülern bezüglich ihrer Qualität positiv bewertet. Für die Schüler konnte gezeigt werden, dass die Beurteilung weitgehend unabhängig von einem zugrunde liegenden Interesse an Biologie und Forschung ausfällt. Anhand einer retrospektiven Erhebung wird außerdem gezeigt, dass alle drei Labortage eine höchst signifikante, selbsteingeschätzte Steigerung des „Wissens“, der „Anwendungszuversicht“ und des „Interesses“ bewirken. Schüler mit niedrigen Ausgangswerten zeigen einen besonders hohen Anstieg. Für das Interesse kann weiter gezeigt werden, dass auch Schüler mit hohem Ausgangswert eine große Interessenssteigerung durch den Labortag aufweisen. Das Interesse für den verhaltensbiologischen Labortag liegt etwas niedriger – die Labortage mit elektrophysiologischen Inhalten zeigen dagegen für die Anwendungszuversicht etwas niedrigere Werte.
Der Fokus der fachdidaktischen Forschung lag auf der Betrachtung des experimentellen Zugangs zur Elektrophysiologie über ein entwickeltes „EPhys-Setup“. Dabei handelt es sich um einen quasi-realen Messaufbau. Die Umsetzung kombiniert dazu Komponenten eines realen Elektrophysiologie-Setups (Hands-on Komponenten) mit einer speziell entwickelten schülerfreundlichen Software (Neurosimulation) und einem virtuellen Nervensystem in Form einer Platine. Als Modellnervensystem werden für diese Umsetzung Ganglien von Hirudo medicinalis verwendet – der Neurosimulation liegen originale elektrophysiologische Messspuren des Ganglions zugrunde. Experimentelle Vermittlungsansätze für die Elektrophysiologie finden sich kaum für den Schulbereich. Dem Bedarf einer entsprechenden Beforschung wurde mit verschiedenen Testinstrumenten nachgegangen, um den Vermittlungsansatz mit dem EPhys-Setup bewerten zu können. Dafür fand eine Wirksamkeitsanalyse über die Erhebung der Motivation der Schüler statt (Lab Motivation Scale; Dohn et al. 2016). Von Bedeutung war auch, inwiefern gegenüber der Umsetzung eine Technologieakzeptanz vorliegt (Technology Acceptance Model; Davis 1989), die im Schulkontext ausgehend von der steigenden Einbindung von Technologien einen entsprechenden Forschungsbedarf aufweist. Weiter wurde untersucht, ob sich die Bewertung des EPhys-Setups von der Bewertung einer Kontrollgruppe unterscheidet. Für die Kontrollgruppe wurde die Neurosimulation von den Hands-on Komponenten gelöst und die Schüler arbeiteten ausschließlich PC-basiert. Die Ergebnisse zeigen, dass beide Umsetzungen die Motivation förderten und eine Technologieakzeptanz bei den Schülern aufwiesen. Der Unterschied der Untersuchungsgruppen fällt gering aus. Die Abhängigkeiten, die für die verwendete Simulationsumsetzung gefunden wurden, beziehen sich ausschließlich auf Komponenten der „Freude“. Somit wird der intrinsische Bereich von den Schülern die am EPhys-Setup gearbeitet haben höher bewertet. Zur weiteren Analyse der Testinstrumente wurde auch eine Abhängigkeit der Bewertung vom zugrunde liegenden Biologieinteresse sowie von den Computerfähigkeiten vergleichend betrachtet. Der Einfluss auf die Bewertungen der drei Testskalen ist in vielen Fällen höher als der Einfluss der verwendeten Simulation. Vom individuellen Biologieinteresse der Schüler zeigen alle untersuchten Komponenten eine Abhängigkeit. Die größeren Effekte beziehen sich auf die Komponenten der „Lernwirksamkeit“ oder der „Freude“. Von den individuellen Computerfähigkeiten der Schüler zeigen Komponenten zur „Zuversicht bezüglich der Methoden und der Inhalte“ eine Abhängigkeit.
Die Differenzierung zwischen Teilpopulationen hin zu unterschiedlichen Arten kann nur erfolgen, wenn zwischen diesen Teilpopulationen reproduktive Isolation besteht. Wie die unterschiedlichen Arten von reproduktiver Isolation zusammenwirken und welche Voraussetzungen bestehen müssen, um neue Arten zu bilden, muss in jedem Studiensystem untersucht werden. Ein idealer Ansatzpunkt sind Arten, die sich mehrfach an anspruchsvolle Habitate angepasst haben, deren Artbildung also von ökologischen Habitatparametern bestimmt wird. Dieser Vorgang wird als Ökologische Artbildung bezeichnet. Im Artkomplex Poecilia spec., der im Süden Mexikos mehrere schwefelangepasste Ökotypen ausgebildet hat, wurden erste Hinweise auf eine Korrelation zwischen der Selektionsstärke von natürlicher und sexueller Selektion gefunden, deren Einfluss zusammen die bestehenden reproduktiven Barrieren zwischen Klarwasser- und Schwefelökotyp formen. Wie diese Reproduktionsbarrieren beschaffen sind und wie die Umweltvariable Schwefel auf die Morphologie und das Verhalten der Poeciliiden Einfluss nimmt, wurde in der vorliegenden Arbeit anhand von fünf Fragestellungen untersucht. (1) Die Körperfärbung kann ein aussagekräftiges Signal für die Qualität des potentiellen Partners bei der Fortpflanzung sein. Wie beeinflusst die extreme Umweltvariable Schwefel die Ausbildung von Färbung? (2) Sind die gefundenen Anpassungen der Färbung erblich oder werden sie plastisch entsprechend des Nahrungsangebots ausgebildet? (3) In einem der untersuchten Flusssysteme konnte unvollständige reproduktive Isolation zwischen der Klarwasser- und Schwefelpopulation nachgewiesen werden. Sind in den Mischzonen zwischen diesen beiden Habitaten Hybriden genetisch nachweisbar und bilden diese die Färbungsanpassungen der Klarwasser-, der Schwefelpopulation oder eine intermediäre Form aus? (4) Die Gelbfärbung der Flossen bei Männchen scheint ein geeignetes Merkmal für die Anzeige der Qualität zu sein, da es möglicherweise unabhängig vom Nahrungsangebot ausgebildet wird. Besteht eine weibliche Präferenz für dieses Merkmal? (5) Auch die weibliche Partnerwahlpräferenz wird vom Habitat und dem eigenen Zustand beeinflusst. Wie verändert sich die Präferenz für Männchen mit gutem Ernährungszustand bei Weibchen, die hungrig sind?
Um diese Fragen zu beantworten, wurden in mehreren Jahren Männchen und Weibchen der Arten Poecilia mexicana und Poecilia sulphuraria aus sieben Populationen im Studiengebiet in Südmexiko gefangen und auf ihre Färbung untersucht sowie Laborpopulationen getestet. Es konnten generelle Anpassungen der Färbung an die Umweltvariable Schwefel nachgewiesen werden. Dazu gehören die Aufhellung der Körperregionen, die durch Tarnung (konkret: countershading und background matching) vor Entdeckung durch Prädatoren schützen, und die Reduktion von Gelb- und Rottönen. Diese Anpassung ist vermutlich auf das geringe Angebot an Karotinoiden in den schwefelbelasteten Extremhabitaten zurückzuführen. Außerdem konnten zahlreiche flusssystem¬spezifische Anpassungen beschrieben werden, deren Ursachen in den Unterschieden zwischen den Schwefelhabitaten untereinander begründet sind. Das Flusssystem des Río Tacotalpa stellt hier eine Besonderheit dar, da Männchen eine besonders starke Gelbfärbung der Flossen aufweisen. Wildgefangene und laborgeborene Männchen dieses Flusssystems wurden verglichen, um einen Hinweis auf den Einfluss des Nahrungsangebots auf dieses Merkmal zu untersuchen. Tatsächlich ist die Ausprägung dieses Merkmals, die Gelbfärbung der Flossen, unabhängig vom Angebot an Karotinoiden. Während die hier verwendeten genetischen Analysen nicht geeignet waren, Hybriden aus den Mischzonen zwischen Schwefel- und Klarwasserhabitat nachzuweisen, ergaben die Untersuchungen von Individuen aus den Mischzonen keine eindeutigen Ergebnisse über eine etwaige intermediäre Ausbildung der Färbung. Die Präsentation von Männchen, deren Gelbintensität an den Flossenspitzen künstlich verändert wurde, konnte bei Weibchen keine eindeutige Präferenz für stärker gefärbte Männchen aufzeigen. Vielmehr weist dieses Ergebnis auf eine starke Korrelation zwischen mehreren Merkmalen (z. B. weitere morphologische Merkmale, Verhalten) hin, die für die Beurteilung der männlichen Qualität herangezogen werden. Die weibliche Präferenz für konditionsabhängige Merkmale wird bei schwefelangepassten Weibchen leicht verstärkt, wenn diese hungrig sind. Eine solche flexible Präferenz sollte gerade in Habitaten mit starken Fluktuationen im Nährstoffangebot existieren. Dabei waren Weibchen, denen Videoaufnahmen präsentiert wurden, eher in der Lage, das qualitativ hochwertigere Männchen zu identifizieren, als Weibchen, denen animierte Bilder präsentiert wurden. Auch hier wird davon ausgegangen, dass die Reduktion auf eines oder wenige Merkmale, die für die Partnerwahl zur Verfügung stehen, keine ausreichend starke Reaktion auslösen können. Vielmehr ist der Zugriff auf alle Aspekte der männlichen Erscheinung wichtig, um die Qualität des potentiellen Partners zu beurteilen.
Färbung ist also generell geeignet, den Ökotyp eines Individuums zu bestimmen und ein solches Merkmal kann der Artbestimmung im ersten Schritt der Partnerwahl dienen. Dasjenige männliche Färbungsmerkmal, das über mehrere Generationen gleichbleibend ausgeprägt wurde – die Gelbfärbung der Flossen – reicht jedoch nicht aus, um bei der weiblichen Partnerwahl eine Reaktion auszulösen. Vielmehr deuten die Ergebnisse auf eine enge Korrelation der Färbung mit weiteren Merkmalen in Morphologie und Verhalten eines Individuums hin, die vom wählenden Weibchen stets gemeinsam entsprechend der Multiple-message-Theorie betrachtet werden. Auch der Vergleich zwischen Videoaufnahmen und animierten Fotografien als Stimuli bei der Partnerwahl ergab, dass der Aspekt Verhalten (nur verfügbar mit Videoaufnahmen) für eine Partnerwahlentscheidung von Bedeutung ist.
Meine Arbeit konnte den bestehenden Wissensschatz um die bestehenden reproduktiven Barrieren im Studiensystem um den Aspekt der Färbung erweitern. Meine Ergebnisse zeigen weitere spannende Fragestellungen auf. Je größer das Verständnis der vorliegenden Selektionskräfte und Mechanismen reproduktiver Isolation ist, desto besser kann die Wissenschaft verstehen, welche Umgebungsvariablen welchen Einfluss auf den Prozess der Artbildung haben.
Cardiovascular diseases are a leading cause of morbidity and mortality worldwide. Aging inflicts structural and molecular changes on the heart that oftentimes involve ischemic events, cardiomyocyte apoptosis and cardiac stiffening, which makes it a major risk factor for cardiovascular disease. After being disregarded as transcriptional noise for a long time, long non-coding RNAs have lately emerged as key regulators of many cellular processes in physiology and disease of virtually all tissues and organs, with some of them being differentially regulated during aging.
This study identified a long non-coding transcript antisense to the OXCT1 gene locus, Sarrah, to be downregulated in the heart during aging, after acute myocardial infarction and upon heart failure with preserved ejection fraction. Sarrah is expressed in several cardiac cell types with highest levels in cardiomyocytes, where it is predominantly localized in the nucleus. In mouse and human cardiomyocytes, Sarrah levels are reduced upon exposure to hypoxia or treatment with hypoxiamimetic agents in vitro.
Sarrah exerts an anti-apoptotic function in mouse and human cardiomyocytes as assessed from caspase activity and annexin V staining. Histological stainings of Sarrah-depleted human engineered heart tissue organoids and Sarrah overexpressing infarcted mouse hearts confirmed its anti-apoptotic function. Sarrah also plays a role in cardiomyocyte contractility, which is substantially impaired upon Sarrah silencing in human engineered heart tissue and neonatal rat cardiomyocytes. Additionally, cardiomyocytal Sarrah stimulates endothelial cell proliferation via paracrine effects as observed after Sarrah overexpression in mouse hearts as well as in co-culture settings with human endothelial cells and Sarrah-depleted or Sarrah overexpressing human cardiomyocytes. A microarray analysis revealed that silencing Sarrah in human cardiomyocytes induced apoptosisrelated gene expression. Mechanistically, Sarrah was predicted to form triplexes in human and mouse with promoters of genes downregulated, but not upregulated after Sarrah knockdown, suggesting that Sarrah interacts with target genes to activate their transcription. This interaction was confirmed in vitro using nucleic acid oligonucleotides containing the sequences of the Sarrah triplex motif and the Sarrah binding site of the exemplary target gene GPC6 of both human and mouse. RNA immunoprecipitation experiments in human cells demonstrated that Sarrah is associated with open chromatin, transcription factor CRIP2, transcriptional co-activator p300 and DNA-RNA hybrid structures that also occur in Sarrah target gene promoters, which indicated that Sarrah activates gene expression by triplex formation and recruitment of protein interaction partners. Deleting the triplex motif of endogenous Sarrah in mouse cardiomyocytes augmented apoptosis, showing that triplex formation is of functional relevance for Sarrah action.
Finally, overexpressing Sarrah in an acute myocardial infarction mouse model improved recovery of cardiac contractile function as assessed from ejection fraction, stroke volume, wall motion and wall thickness measured by echocardiography and magnetic resonance imaging. Infarct size was substantially reduced in Sarrah overexpressing mice compared with controls. This in vivo study implies that restoring Sarrah levels in the aged or infarcted heart bears significant therapeutic potential, which can be attributed to the combination of three Sarrah effects: increased cardiomyocytes survival, enhanced contractility of individual cardiomyocytes and paracrine stimulation of endothelial cell proliferation likely contributing to increased angiogenesis and tissue perfusion.
In summary, cardiac lncRNA Sarrah is evolutionary conserved with regard to its genomic locus, function and molecular mechanism. Via triplex formation with gene promoters, it is capable to activate a set of target genes that together mediate the anti-apoptotic and pro-contractile function of Sarrah in cardiomyocytes and that confer angiogenic effects to endothelial cells. A therapeutic utilization of Sarrah in the context of myocardial ischemia is conceivable in the future if Sarrah upregulation proves to be beneficial in further studies.
The overarching aim of this doctoral research was to examine and quantify the spatiotemporal variability in the movements of nomadic ungulates to better understand the possible drivers and characteristics of such movements as well as to examine the particular conservation challenges associated with nomadic movements.
Cerebellar ataxias are a group of neurodegenerative disorders primarily affecting the cerebellum. Although causative mutations in several genes have been identified there is currently no cure for ataxias.
The first part of this dissertation is focused on Spinocerebellar ataxia type 2 (SCA2). SCA2 is a dominant ataxia caused by repeat expansion mutations in the ATXN2 gene, which encodes the protein Ataxin2 (ATXN2). A polyglutamine (polyQ) tract consisting of CAG repeats interrupted by CAA was identified at exon 1 of ATXN2. Healthy individuals have between 22 and 23 glutamines, while expansions longer than 33 CAG repeats cause SCA2. The most noticeable symptom that SCA2 patients show is ataxic gait; however, they also show cerebellar dysarthria, dysdiadochokinesia, and ocular dysmetria caused by the progressive cerebellar degeneration.
To model the SCA2 disease, we generated a new mouse model where 100 CAG repeats were introduced in the mouse Atxn2 gene via homologous recombination. The characterization of this mouse model, Atxn2-CAG100-KIN, demonstrated that it reproduces the symptomatology observed in SCA2 patients. These animals showed significant loss of weight over time, brain atrophy, and motor deficits.
In addition, ATXN2 intermediate expansions have been linked to the pathology of Amyotrophic lateral sclerosis (ALS) as a risk factor. ALS is a fatal neurodegenerative disease where the motor neurons in the brain and spinal cord degenerate. A hallmark of ALS is the presence of TDP43-positive inclusions in neurons and glia. Further studies of post mortem spinal cord samples from SCA2 patients showed severe and widespread neurodegeneration of the central somatosensory system. Therefore, it was of interest to further investigate the pathology affection of this tissue in the Atxn2-CAG100-KIN line and the relationship between ATXN2 and TDP43. The characterization of the spinal cord pathology via protein quantification, transcript quantification, and immunohistochemistry showed a preferential affection of RNA binding proteins (RBP) in the spinal cord rather than the cerebellum. The ALS-linked factors TDP43 and TIA1 showed time-dependent co-aggregation with ATXN2 in spinal cord sections together with an increase of CASP3 levels. Therefore, this mouse model can help develop new therapies and evaluate their effect in differently affected areas.
A transcriptome data set from Atxn2-CAG100-KIN spinal cord samples at the final disease stage of this mouse model showed a strong up-regulation of RNA toxicity-, immune- and lysosome-implicated factors. These data pointed to a pathological reactivation of the synaptic pruning and phagocytosis in microglia. ATXN2-positive aggregates were found in microglia from spinal cord sections of 14-month-old Atxn2-CAG100-KIN via immunohistochemistry. The characterization of microglial response and the potentially deleterious effects of the expanded ATXN2 in this cell type could lead to therapies to improve patients’ living standards or delay the symptoms’ onset.
The second part of this thesis was focused on an autosomal recessive form of cerebellar ataxia, Ataxia Telangiectasia (A-T), with childhood onset. A-T patients show severe cerebellar atrophy manifesting as ataxia when the child starts to walk. The genetic cause of A-T is loss-of-function-mutations in the Ataxia Telangiectasia Mutated gene (ATM). ATM is a kinase involved in DNA damage response, oxidative stress, insulin resistance, autophagy via mTOR signaling, and synaptic function.
Working with proteome data from cerebrospinal fluid of 12 A-T patients and 12 healthy controls, we aimed to define novel biomarkers that would allow following the neurodegeneration in extracellular fluid. Additional validation efforts with ~2-month-old Atm-knock-out (Atm-/-) cerebellar samples helped us to define a scenario were the deficit of vesicle-associated ATM alters the secretion of ApoB, reelin, and glutamate. As extracellular factors, apolipoproteins and their cargo such as vitamin E may be useful for neuroprotective interventions.
ADAM15, which belongs to the family of the disintegrin and metalloproteinases, is a multi-domain transmembrane protein. A strongly upregulated expression of ADAM15 is found in inflamed synovial membranes from articular joints affected by osteoarthritis and especially rheumatoid arthritis (RA). During the chronic inflammatory process in RA the synovial membrane gets hyperplastic, resulting eventually in the formation of a pannus tissue, which can invade into the adjacent cartilage and bone thereby destroying their integrity. Previously, the expression of ADAM15 in fibroblasts of the RA synovial membrane was found to confer a significant anti-apoptotic response upon triggering of the Fas receptor, which resulted in the activation of two survival kinases, focal adhesion kinase (FAK) and Src. The Fas receptor, also named CD95, belongs to the death receptor family of the tumor necrosis factor receptors and stimulation of Fas/CD95 by its ligand FasL results in the execution of apoptotic cell death in synovial membranes of RA patients. However, the occurrence of apoptotic cell death in vivo in RA synovial tissues is considerably low despite the presence of FasL at high concentrations in the chronically inflamed joint. Accordingly, a general apoptosis resistance is a characteristic of RA-synovial fibroblasts that contributes considerably to the formation the hyperplastic aggressive pannus tissue. The objective of this study was to investigate the mechanisms underlying the capability of ADAM15 to transform FasL-mediated death- inducing signals into pro-survival activation of Src and FAK in rheumatoid arthritis fibroblasts (RASFs).
In the present study, the down-regulation of ADAM15 by RNA interference resulted in a significant increase of caspase 3/7 activity upon stimulation of the Fas receptor in RASFs. Likewise, chondrocytes expressing a deletion mutant of ADAM15 (ΔC), lacking the cytoplasmic domain, revealed increased caspase activities upon Fas ligation in comparison to cells transfected with full-length ADAM15, clearly demonstrating the importance of the cytoplasmic domain for an increased apoptosis resistance. Furthermore, activation of the Fas receptor triggered the phosphorylation of Src at Y416, which results in the active conformation of Src, as well as the phosphorylation of FAK at Y576/577 and Y861 – the target tyrosines phosphorylated by Src - in full-length ADAM15-transfected chondrocytes. However, cells transfected with ADAM15 mutant (ΔC) or with vector control did not exhibit any activation of Src and FAK upon Fas ligation. This suggested the presence of an as yet unknown protein interaction mediating the Fas triggered activation of the two kinases.
In order to identify this mechanism, the application of signal transduction inhibitors interfering with Calcium signaling either by inhibiting calmodulin with trifluoperazine (TFP) or the Calcium release-activated channel (CRAC/Orai1) with BTP-2 efficiently inhibited the phosphorylation of FAK and Src, revealing a role of calmodulin, the major Ca2+ sensor in cells, in ADAM15-dependent and Fas-elicited activation of the two survival kinases. Also, a direct Ca2+ -dependent binding of calmodulin to ADAM15 could be demonstrated by pull-down assays using calmodulin-conjugated sepharose and by protein binding assays using the recombinant cytoplasmic domain of ADAM15 and calmodulin.
Furthermore, it could be demonstrated in living synovial fibroblasts by double immunofluorescence stainings that triggering the Fas receptor by its ligand FasL or a Fas-activating antibody resulted in the recruitment of calmodulin to ADAM15 as well as to the Fas receptor in patch-like structures at the cell membrane. Simultaneously, Src associated with calmodulin was shown to become engaged in an ADAM15 complex, also containing cytoplasmic-bound FAK, by co-immunoprecipitations.
Additional studies were performed to analyze the efficacy of TFP and BTP-2 on apoptosis induction in synovial fibroblasts from 10 RA patients. Using caspase 3/7 and annexin V stainings for determining apoptosis, it could be shown that both inhibitors did not possess any apoptosis inducing capacity. However, when co-incubated with FasL both compounds synergistically enhanced apoptosis rates in the RASFs. Moreover, an additional silencing of ADAM15 revealed a further significant rise in apoptosis rates upon incubation with FasL/TFP or FasL/BTP-2, providing unequivocal evidence for an involvement of ADAM15 in facilitating apoptosis resistance in RASFs.
Taken together, these results demonstrate that ADAM15 provides a scaffold for the formation of calmodulin-dependent pro-survival signaling complexes upon CRAC/Orai1 coactivation by Fas ligation, which provides a new potential therapeutic target to break the apoptosis resistance in RASFs that critically contributes to joint destruction in RA.
Understanding global biodiversity patterns is one of the main objectives of ecology. Spatial variation in species richness can be explained by several environmental factors. The relationships between species richness and environmental factors have been associated with latitudinal, longitudinal and elevational gradients. The number of species is determined by birth, death and migration rates of species in a given area. These rates are affected by abiotic and biotic factors acting at local and regional scales. Climatic seasonal variation may also influence biodiversity, directly through physiological limitations and indirectly through biotic interactions, vegetation structure and food availability. Climate and land use change are the main factors for landscape simplification and biotic homogenization. Thus, the study of community patterns across environmental gradients may help to predict the effect of projected environmental change.
I investigated how abiotic and biotic factors influence different facets of bird diversity across an elevational gradient. My study was conducted along an elevational gradient spanning 2000 m within and around Podocarpus National Park and San Francisco reserve on the southeastern slope of the Andes in Ecuador. The climate is humid tropical montane with a bimodal rain regime. The region is characterized by evergreen premontane forest at low elevations, evergreen lower montane forest at mid elevations and upper montane forest at high elevations. The elevational gradient has natural continuous forests within the protected reserves and fragmented forests surrounding the reserves in a matrix of cattle pastures. To monitor bird diversity, I placed nine 20-m radius point counts within 18 one-hectare plots, in continuous and fragmented forest at 1000, 2000 and 3000 m a.s.l. I recorded and identified all birds for 10 minutes within each point count. Bird communities were sampled eight times per plot, in the most humid season and in the least humid season of 2014 and 2015. To estimate flower and fruit availability, I recorded all plants with open flowers and ripe fruits within each point count. To obtain the relative invertebrate availability, I assessed understory invertebrate fresh biomass using a standardized sweep-netting design along 100-metre borders of each plot. Vertical vegetation heterogeneity was estimated at eight layers above the ground within each point count. Temperature for each plot was obtained using an air temperature regionalization tool and precipitation through remote sensing techniques and meteorological data.
In the first chapter of this thesis, I explored the effects of elevation, climate and vegetation structure on overall bird communities as well as on frugivorous and insectivorous birds. I found that elevation was mostly indirectly associated with bird diversity, jointly mediated via temperature, precipitation and vegetation structure. Additionally, elevation was directly and positively associated with both the overall bird community and with insectivores, but not with frugivores. My findings indicate a reduction of bird diversity due to climatic factors and vegetation structure with increasing elevation. However, the direct, positive effect of elevation suggests that bird diversity was higher than expected towards high elevations, probably due to spatial, biotic and evolutionary settings.
In the second chapter, I analysed the influence of climate and resource availability on temporal variation of bird communities. I found a higher bird diversity in the least humid season than in the most humid season. The seasonality of the bird communities was mainly driven by temperature and precipitation. While temperature had a significant positive effect at high elevations, precipitation had a significant negative effect at low elevations. Resource availability had no significant effect. My findings suggest that the temporal fluctuations in bird communities likely occur due to climate
constraints rather than due to resource limitations.
In the third chapter, I studied the effect of forest fragmentation on taxonomic and functional bird diversity. I found that taxonomic diversity was higher in fragmented compared to continuous forests, while functional diversity was negatively affected by fragmentation, but only at low elevations. The increase of taxonomic diversity in disturbed habitats suggests an increase of habitat generalists, which may compensate the loss of forest specialists. My findings suggest that taxonomic diversity can be uncoupled from functional diversity in diverse communities at low elevations.
My results show the effects of environmental factors on the spatio-temporal patterns of bird communities and the potentially uncoupled responses of taxonomic and functional diversity to forest fragmentation. My findings highlight that bird communities respond differently to abiotic and biotic factors across elevational gradients. Overall, my study helps to better understand the mechanisms that drive species communities in response to complex environmental conditions, which could be an essential contribution for the conservation of bird communities in the tropical Andes.
Investigating the influence of truffle´s microbiome and genotype on the aroma of truffle fungi
(2019)
Truffles (Tuber spp.) are belowground forming fungi that develop in association with roots of various host trees and shrubs. Their fruiting bodies are renowned for their enticing aromas which vary considerably, even within truffles of the same species. This aroma variability might be attributed to factors such as geographical origin, degree of fruiting body maturation, truffle genotype and microbiome (microbial communities that colonise truffle fruiting bodies) which often co-vary. Although the influence of specific factors is highlighted by several studies, discerning the contribution of each factor remains a challenge since it requires an appropriate experimental design. The primary purpose of this thesis was to gain insight into the influence of truffle’s genotype and microbiome on truffle aroma.
This doctoral thesis is comprised of four chapters. Chapter1 (Vahdatzadeh et al., 2018) aimed to exclusively elucidate the influence of truffle genotype on truffle aroma by investigating the aroma of nine mycelial strains of the white truffle Tuber borchii. We also assessed whether strain selection could be employed to improve the human- perceived truffle aroma. Quantitative differences in aroma profiles among strains could be observed upon feeding of amino acids. Considerable aroma variabilities among strains were attributed to important truffle volatiles, many of which might be derived from amino acid catabolism through the Ehrlich pathway. 13 C-labelling experiments confirmed the existence of the Ehrlich pathway in truffles for leucine, isoleucine, methionine, and phenylalanine. Sensory analyses further demonstrated that the human nose can differentiate among strains. Our results illustrated the influence of truffle genotype on truffle aroma and showed how strain selection could be used to improve the human-perceived truffle aroma.
In chapter 2 the existing knowledge on the composition of bacterial community of four truffle species was compiled using meta-analysis approach (Vahdatzadeh et al., 2015). We highlighted the endemic microbiome of truffle as well as similarities and differences in the composition of microbial community within species at various phases of their life cycle. Furthermore, the potential contribution of truffle microbiome in the formation of truffle odorants was studied. Our findings showed that truffle fruiting bodies harbour complex microbial community composed of bacteria, yeasts, filamentous fungi, and viruses with bacteria being the dominant group. Regardless of truffle species, the composition of endemic microbiome of fruiting bodies appeared very similar and was dominated by α-Proteobacteria class. However, striking differences were observed in the bacterial community composition at various stages of the life cycle of truffle.Our analyses further suggested that odorants common to many truffle species might be produced by both truffle fungi and microbes, whereas specific truffle odorants might be derived from microbes only. Nevertheless, disentangling the origin of truffle odorants is very challenging, since acquiring microbe-free fruiting bodies are currently not possible.
Chapter 3 (Splivallo et al., 2019) further characterises truffle-associated bacterial communities of fruiting bodies of the black truffle T. aestivum from two different orchards. It aimed at defining the native microbiome in this truffle species, evaluating the variability of their microbiome across orchards, and assessing factors that shape assemblages of the bacterial communities. The dominant bacterial communities in T. aestivum revealed to be similar in both orchards: although a large portion of fruiting bodies were dominated by the α-Proteobacteria class (Bradyrhizobium genus) similar to other so far-assessed truffle species, in few cases β-Proteobacteria (Polaromonas genus), or Sphingobacteria (Pedobacter genus) were found to be predominant classes. Moreover, factors shaping bacterial communities influenced the two orchards differently, with spatial location within the orchard being the main driver in Swiss orchard and collection season in the French one. Surprisingly, in contrast to other fungi, truffle genotype and the degree of fruiting body maturity seemed not to contribute in shaping the assembly of truffle microbiome. Altogether, our data highlighted the existence of heterogeneous bacterial communities in T. aestivum fruiting bodies which are dominated by either of the three bacterial classes and mainly by the α-Proteobacteria class, irrespective of geographical origin. They further illustrated that determinants driving the assembly of various bacterial communities within truffle fruiting bodies are site-specific. Truffles are highly perishable delicacies with a short shelf life (1-2 weeks), and their aroma changes profoundly upon storage. Since truffle aroma might be at least partially produced by the truffle microbiome, chapter 4 (Vahdatzadeh et al., 2019) focuses on assessing the influence of the truffle microbiome on aroma deterioration of T.aestivum during post harvest storage. Specifically, volatile profile and bacterial communities of fruiting bodies collected from four different regions (three in France and one in Switzerland) were studied over nine days of storage. Our findings demonstrated the gradual replacement of dominant bacterial classes in fresh truffles (α-Proteobacteria, β-Proteobacteria, and Sphingobacteria) by food spoilage bacteria (members of γ- Proteobacteria and Bacilli classes), regardless of the initial diversity of the bacterial classes. This shift in the bacterial community also correlated with changes in volatile profiles, and markers for truffle freshness and spoilage could be identified. Ultimately, network analysis illustrated possible links among those volatile markers and specific bacterial classes. Our data showed that storage deeply influenced the composition of bacterial community as well as aroma of truffle fruiting bodies. They also illustrated the correlation between the shift in truffle microbiome, from commensal to detrimental, and the change of aroma profile, possibly leading to the loss of fresh truffle aroma. Overall, the work undertaken in this thesis demonstrated that truffle genotype and microbiome had a stronger influence on truffle aroma than previously believed.
Role of npas4l and Hif pathway in endothelial cell specification and specialization in vertebrates
(2018)
Cardiovascular development requires two main steps, vasculogenesis and angiogenesis. During vasculogenesis, angioblasts, the precursors of endothelial cells (ECs), specify from the mesoderm and coalesce to form the axial vessels of the vertebrate embryo. Many questions regarding the transcriptional waves initiating and sustaining angioblast specification are still unanswered. The identity of cloche, a gene essential for EC differentiation in zebrafish, was only recently discovered by our group, and very little is known about its upstream regulators or its molecular mechanism of action. I described the molecular players involved in orchestrating npas4l expression, upstream of angioblast specification. By using genetic models and chemical treatments, I identified FGF-Erk axis and BMP signaling to be involved in npas4l regulation. I also showed that eomesa is a potent inducer of npas4l expression. In addition, in vitro experiments indicated that murine Eomes promotes EC specification, acting upstream of Etv2 and Tal1. Using a combination of gain-of-function and loss-of-function models for npas4l, I identified primary and secondary downstream effectors of npas4l. I showed that Npas4l binding sites are present in the promoter of genes involved in hematoendothelial specification, such as tal1, lmo2 and etv2. Importantly, I reported that npas4l is sufficient and necessary to promote the EC specification program. By performing a combined analysis of the developed datasets, I recovered putative genes with a potential role in EC specification. One of the most promising candidates was tspan18b. I generated a mutant allele for tspan18b and observed angiogenic defects in tspan18b-/- embryos, confirming a role for this gene in zebrafish cardiovascular development. I showed that Npas4l binds etv2 promoter in zebrafish. In mammalian embryonic stem cells, however, Etv2 promoter is bound by HIF-1α, a transcription factor homolog to Npas4l. Interestingly, Eomes knockdown in vitro lead to a significant reduction of Hif-1α expression. To test the function of Hif-1α in vivo, I took advantage of a murine loss-of-function model.
Hif-1α mouse mutant embryos exhibit a significant decrease in Etv2 expression, when compared with WT siblings. These data suggest a model where mammals lost npas4l during evolution and HIF-1α acquired a new function, replacing npas4l role in EC specification. I compared the phenotype of Hif-1α mouse mutant with zebrafish hif-1α loss-of- function models. Importantly, zebrafish hif-1α mutant did not show defects in vasculogenesis or EC specification, but in EC specialization, during HSC development. I showed that hypoxia is a potent inducer of HSC formation, and hif-1α as well as hif-2α act upstream of notch1, vegfaa and evi1 in hemogenic endothelial specification.
Conclusions
In this work, I explored the molecular mechanisms underlying EC specification in vertebrates, analyzing the role of bHLH-PAS transcription factors in this biological process. I identified the upstream regulators and the downstream effectors of npas4l, describing a novel role for tspan18b in zebrafish cardiovascular development. Npas4l is a transcription factor necessary and sufficient for angioblast differentiation in zebrafish, but the gene was lost in the mammalian lineage. hif-1α and hif-2α, paralogous genes of npas4l, are involved in the establishment of EC heterogeneity and specifically in the specification of hemogenic endothelium in zebrafish. Murine Hif-1α, however, is responsible for Etv2 regulation, indicating a role for hypoxia inducible factor in initiating the EC specification program in mouse, similarly to npas4l function in zebrafish.
Biodiversity is threatened worldwide because of ongoing habitat loss and fragmentation, overexploitation, pollution, biological invasions and a changing global climate. Due to the major importance of biological diversity for modern human living, efficient conservation and management strategies are required to protect endangered habitats and species. For this purpose, ambitious multilateral agreements on regional and global scale were declared to prevent biodiversity loss.
Efficient biomonitoring methods are required to adequately implement these biodiversity conventions. Species monitoring as a core activity in biodiversity research is an effective tool to assess the status of species and trends within habitats. Data collection can be obtained with visual, electronic or genetic surveys. Still, these monitoring programs can be expensive, laborious and inefficient for accurate species assessments. New techniques based on environmental DNA (eDNA) allows for the detection of DNA traces in environmental samples (soil, sediment, water and air samples) and open up new possibilities for species monitoring. The eDNA methodology enables detection of single species in a qualitative (presence/absence) or (semi-) quantitative way. eDNA metabarcoding approaches can be an effective community structure assessment method.
This thesis, located at the interface between experimental and applied research, illustrates the suitability of the eDNA methodology in applied biomonitoring using the example of the water-borne crayfish plague pathogen Aphanomyces astaci (Schikora 1906). The obtained results provide new insights into A. astaci sporulation dynamics in natural water courses. A. astaci sporulation is influenced by seasonal variation of water temperatures and life history traits (molting, activity, mating) of infected crayfish. The results also imply a high transmission risk of A. astaci spores during the complete year. This thesis compares two eDNA methods, which are successfully and consistently detecting A. astaci spores. Each approach is suitable for different biomonitoring tasks due to the method-specific requirements. The obtained results also reveal spatial variation in A. astaci occurance in the tested water bodies. A. astaci spore estimates are positively correlated with population density and pathogen loads of captured A. astaci- positive crayfish. eDNA results show a downstream zoospore transport of up to three kilometres distance from a distribution hot spot area of A. astaci-infected crayfish. The eDNA methodology is helpful in gaining reliable information on A. astaci occurrence in large water bodies. This information is urgently needed to initiate efficient management decisions for the conservation of European crayfish species.
eDNA-based methods such as for A. astaci detection are a useful complement for conventional monitoring and should have a strong impact on conservation policy. eDNA methodology will be helpful for the practical implementation of the main aims of key conservation agreements and thus will make important contributions to biodiversity protection.
Cardiac trabeculation is one of the essential processes required for the formation of a competent ventricular wall, whereby clusters of ventricular cardiomyocytes (CMs) from a single layer delaminate and expand into the cardiac jelly to form sheet-like projections in the developing heart (Samsa et al., 2013). Several congenital heart diseases are associated with defects in the formation of these trabeculae and lead to embryonic lethality (Jenni et al., 1999; Zhang et al., 2013, Jenni et al., 2001; Towbin 2010). It has been experimentally shown that lack of Nrg1/ErbB2/ErbB4, Angipoetin1/Tie2, EphrinB2/B4, BMP10, or any component of the Notch signaling pathway can cause defective trabeculation. Moreover, changes in blood flow and/or contractility can also affect trabeculation (Samsa et al., 2013). Together, these observations demonstrate that cardiac trabeculation is a highly dynamic and regulated process.
Trabeculation is a morphogenetic process that requires control over cell shape changes and rearrangements, similar to those observed during EMT. Epithelial cells within an epithelium are polarized and establish cell-cell junctions with the neighboring cells (Ikenouchi et al., 2003; Ferrer-vaquer et al., 2010), thus epithelial cell polarity is an important feature to maintain cell shape and tissue structure. During developmental processes such as cell migration and cell division or in disease states epithelial polarity might be disrupted. As a consequence of this alteration, cells lose their tight cell-cell adhesions, undergo cytoskeletal rearrangements, change their shape and gain migratory properties becoming mesenchymal cells (Micalizzi et al., 2010). In epithelial cells, apicobasal polarity is regulated by a conserved set of core complexes, including the PAR, Scribble and Crumbs complexes (Kemphues et al., 1988; Bilder and Perrimon, 2000; Teppas et al., 1984). The polarity proteins composing these complexes interact in a well organized and coordinated-manner creating molecular asymmetry along the apicobasal axis of the cell. In turn, this crosstalk regulates the maturation and stabilization of the junctions between cells and cytoskeleton in order to strengthen cell polarization (Roignot et al., 2013). Amongst the different polarity complex, Crumbs has been shown to be a key regulator of apicobasal polarity during development in both vertebrates and invertebrates (Tepass et al., 1990; Fan et al., 2004).
Here, taking advantage of zebrafish as a model organism, I study in vivo at single cell resolution changes in CM apicobasal polarity during cardiac trabeculation. Moreover, I show which factors regulate CM apicobasal polarity during this process. In addition, I dissect the role of the polarity complex Crumbs in regulating CM junctional rearrangements and the formation of the trabecular network.
In the 'Golden Age of Antibiotics', between 1940 and 1970, the global pharmaceutical companies discovered many antibiotics, such as cephalosporins, tetracyclines, aminoglycosides, glycopeptides, etc., as well as antifungal and antiparisitic agents. Due to several reasons, e.g. the steady re-discovery of already known NPs and the associated high costs, many pharmaceutical companies have significantly scaled back or totally abandoned their NP discovery programs since the late 20th century. Instead those companies started to focus on drug discovery based on combinatorial synthesis and thereby on the creation of enormous synthetic libraries containing small molecules. Unfortunately, this synthetic approach dealing with the optimization of existing NP or antibiotic has its limitations. As a result, leading pharmaceutical companies are re-conducting NPs research to discover new antimicrobials for the upcoming antimicrobial resistance threat. The Natural Product Center of Excellence, a collaboration between Sanofi-Aventis and Fraunhofer IME, is advancing in this context the discovery and development of novel antimicrobial agents for the treatment of infectious diseases through the testing of Sanofi's microbial extract library and strain collection. The aim of the present PhD thesis was the discovery and isolation of novel antimicrobial compounds with improved activities and/or novel MOAs as potential lead compound for a further drug discovery.
Transposable elements (TEs) are replicating genetic elementst hat comprise up to 50% of mammalian genomes. A specific class of TEs are retrotransposons that proliferate by transcription into a RNA intermediate, followed by genomic reintegration into another locus (so called “copy & paste” mechanism). Due to the lack of removal mechanisms and very rare parallel insertions, the presence of TE insertions at ortholgous genomic loci in multiple taxa provides a virtually homoplasy free phylogenetic marker. So far, developing phylogenetically informative markers from TE insertions has been a tedious work of testing hundreds of putative candidate loci in a trial-and error approach with low success rate. Hence, phylogenetic studies using TE insertions were often limited to a few dozen markers.
Recently, genome sequencing of multiple species using reference-mapping allowed the identification of genome-scale datasets of TE insertions. and made the ad-hoc development of phylogenetic informative markers possible. However, genome scale TE detection methods have rarely been applied to non model organisms in which data availability and quality is comparably limited. In this thesis, I developed the TeddyPi pipeline (TE detection and discovery for phylogenetic inference), a software tool that made it possible to obtain reliable genome-scale TE insertion data from low-coverage genomes. This was achieved by integrating the data from multiple TE and structural variation callers as well as applying a stringent filtering pipeline to exclude low-quality insertion calls. Whole-genome sequencing datasets of bears (Ursidae) and baleen whales (Mysticeti) were used to apply TE based phylogenetic inference and evaluate the method in comparison to sequence-based phylogenomic analyses.
In the bear genomes, TeddyPi identified 150,513 high-quality transposable element (TE) insertions, which allowed me to reconstruct the evolutionary history of bears despite extensive phylogenetic conflict (Lammers et al., 2017). The large number of detected TE insertions made also detailed network analyses possible that visualize the phylogenetic conflict. Experimental polymerase chain reaction (PCR) assays validated up to 93 % of the computationally identified TE loci and demonstrated the high accuracy of the dataset underlying the phylogenetic analyses.
Second, I present the initial genome sequencing of six baleen whales and a detailed investigation of their evolutionary history using TE insertions and established sequence-based phylogenomic methods. The taxon sampling of baleen whales included iconic species like the blue whale (Balaneoptera musculus) or the humpback whale (Megaptera novaengliae) (Árnason et al., 2018). A sequence-based reconstruction of the baleen whale species tree solved the long-debated phylogenetic position of the gray whale (Echrichtius robustus) within rorquals (Balaneopteridae) for the first time with high statistical support. Furthermore, the genome data made it possible to identify large extent of phylogenetic conflict for divergences during the radiation of rorquals that occurred 7-10 million years ago (Ma).
The phylogenomic analyses of 91,589 TE insertions in the whale genomes confirmed the sequence-based topology (Lammers et al., 2019). The quantification of phylogenetic signals obtained from the TE insertions revealed a high degree of discordance for the divergence of the gray whale and rorquals. Despite the large genome-scale dataset, statistical tests showed only marginal support for a bifurcating divergence of gray whales and the rorqual species. The limited statistical support for a strictly bifurcating tree obtained from genome-scale datasets of thousands of markers demonstrates the importance for including phylogenetic networks for displaying evolutionary divergences.
In conclusion, this thesis shows that identification of TE insertions from whole-genome resequencing provides plentiful and accurate phylogenomic markers. For the application in non model organisms, I provide a easy-to-use software to integrate multiple datasets from TE and structural variation callers in order to obtain reliable and ascertainment-bias free datasets. Detecting genome-scale datasets of TE insertions in two case studies demonstrates the applicability of this marker system for phylogenetic reconstruction and inferring phylogenetic conflict.
Der DNA-Translokator von T. thermophilus HB27, ebenso wie Typ-IV-Pili (T4P), sind Multiproteinkomplexe, die die Membranen und das Periplasma durchspannen. Sie sind ähnlich aufgebaut und enthalten identische Proteine. Der DNA-Translokator vermittelt Transport von DNA in das Zellinnere während der natürlichen Transformation. T4P sind filamentöse Zellorganellen, die an der inneren Membran assembliert werden und bis zu mehrere Mikrometer aus der Zelle hinausragen. Sie dienen der Anhaftung und Fortbewegung der Zellen auf Oberflächen.
Das Ziel dieser Arbeit war es, die Funktionen einzelner Komponenten der Komplexe und ihrer Proteindomänen bei der natürlichen Transformation, der T4P-Assemblierung und den durch T4P vermittelten Funktionen Adhäsion und „twitching motility“ aufzuklären.
Es sind neun Proteine bekannt, die eine duale Rolle als Komponenten des DNA-Translokators und des T4P spielen. Eines dieser Proteine ist die Assemblierungs-ATPase PilF, die Hexamere bildet. Diese cytoplasmatischen ATPase-Komplexe stellen die Energie für die Assemblierung der T4P bereit, ebenso wie für die Aufnahme freier DNA. Es ist jedoch bisher nicht geklärt, wie die durch PilF bereitgestellte Energie auf die anderen Komponenten des DNA-Translokators/T4P übertragen wird.
In dieser Arbeit konnte gezeigt werden, dass PilF an das cytoplasmatische Protein PilM des T4P und DNA-Translokators bindet. Zudem konnten Proteinkomplexe bestehend aus den Proteinen PilM, PilN und PilO heterolog produziert und aus Zellmembranen koisoliert werden. PilF interagierte mit diesen PilMNO-Komplexen via PilM. Diese Interaktionen führt zur Stimulierung der ATPase-Aktivität von PilF. Dies deutet an, dass PilM ein Kupplungsprotein ist, welches die Assemblierungs-ATPase PilF physisch und funktionell mit dem T4P/DNA-Translokator über den PilMNO-Komplex verbindet.
Neben PilF standen Präpiline von T. thermophilus im Fokus dieser Arbeit. Präpiline sind Vorläuferproteine, die zu Pilinen prozessiert werden und als solche dann die Untereinheiten der Pilus-Strukturen bilden.
Zusammenfassend konnten die Rollen einzelner Präpilin-ähnlicher Proteine bei T4P-assoziierten Funktionen geklärt werden und es konnten erste Analysen zur Charakterisierung des weitestgehend unbekannten Proteins ComZ durchgeführt werden. Desweiteren liefert diese Arbeit Hinweise darauf, dass die membranassoziierten Proteine PilM, PilN und PilO Kupplungsproteine sind, die PilF mit den periplasmatischen Komponenten des T4P/DNA-Translokators verbinden und dadurch die ATPase-Aktivität von PilF stimulieren. Die Rollen einzelner Proteindomänen von PilF und PilM bei der Protein-Protein-Interaktion und der Bindung von Liganden wurden aufgeklärt, sowie ihre Funktionen bei den T4P-vermittelten Funktionen und der natürlichen Transformation.
Autophagy, meaning “self-eating”, is an important cellular waste disposal mechanism. Thereby, damaged proteins, lipids and organelles are enclosed by autophagosomes and subsequently transported to the lysosomes for degradation into basic, cellular building blocks. Under basal conditions autophagy prevents the accumulation of defective and harmful material and generally promotes cell survival. However, several studies reported that hyperactivated autophagy, e.g. during developmental processes in lower eukaryotes, or during chemotherapeutic treatment of cancer cells, can also trigger cell death.
In recent years, autophagic cell death (ACD) has been considered as an alternative cell death pathway for tumor therapy, especially for solid tumors with high apoptosis resistance such as glioblastoma. Glioblastoma (GBM) is a very aggressive, malignant primary brain tumor with a median survival of ~ 15 months despite surgery and chemoradiotherapy. Accordingly, there is a great interest in improving GBM therapy through alternative cell death mechanisms. Interestingly, it has been shown that various substances, e.g. AT 101, cannabinoids and the combination of imipramine and ticlopidine (IM+TIC), induce ACD in GBM cells.
The aim of this project was to identify the underlying mechanisms of stress- and drug-induced ACD and its therapeutic potential for glioblastoma treatment. For detailed investigation of ACD, a CRISPR/Cas9-based approach was used to generate ATG5 and ATG7 knockouts as genetic models of autophagy deficiency. In a previous study of our lab it was demonstrated that administration of AT 101 triggers ACD in glioblastoma cells, which was associated with early mitochondrial fragmentation but no signs of apoptosis. Since mitochondrial fragmentation often precedes mitophagy, the first part of this thesis explored the potential role of mitophagy in AT 101-induced cell death.
ATG5-depleted cells confirmed that AT 101 induces ACD. In addition, treatment with AT 101 resulted in a pronounced mitochondrial depolarization, which was at least partly caused by the opening of the mitochondrial permeability pore. Global proteome analysis of AT 101-treated GBM cells revealed a robust decrease in mitochondrial protein clusters as well as a strong increase in the enzyme heme oxygenase-1 (HMOX1). Subsequent experiments for detailed investigation of mitophagy following AT 101 treatment (western blot, flow cytometric MTG and mt-mKeima, qRT-PCR of mitochondrial vs nuclear DNA) consistently indicated strong mitophagy induction by AT 101, which could be reduced by genetic or pharmacological inhibition of autophagy. Furthermore, siRNA-mediated knockdown experiments revealed that the selective mitophagy receptors BNIP3 and BNIP3L and the HMOX1 enzyme play an essential role in AT 101-induced mitophagy and subsequent cell death. Taken together, these data demonstrate that AT 101-induced mitochondrial dysfunction and HMOX1 induction synergize to promote excessive mitophagy with a lethal outcome in glioma cells.
The second part of this thesis focused on the identification of new substances that cause ACD and the investigation of the underlying cell death pathways. Using a cell death screen of the ENZO Screen-Well™ autophagy library in MZ-54 wild-type vs ATG5 and ATG7-depleted cells, loperamide, pimozide, and STF-62247 were identified as ACD-inducing agents. The increase of the autophagic flux and the induction of ACD by these substances was confirmed by using different ATG5 and ATG7 knockout cell lines and the already established positive control IM+TIC.
In contrast to AT 101, IM+TIC, STF-62247, loperamide and pimozide produced neither mitochondrial dysfunction nor mitophagy. Interestingly, it has been described that imipramine, loperamide and pimozide inhibit the lysosomal enzyme acid sphingomyelinase, which is associated with impaired lipid transport. Global proteome analysis and cholesterol staining confirmed that all four substances, but especially loperamide and pimozide, inhibit cellular lipid transport, leading to massive lipid accumulation in the lysosomes. In the further course of the experiments, the connection between defective lipid transport and autophagy was investigated in more detail. On the one hand, the defective lipid transport contributed to the induction of autophagy, on the other hand the massive accumulation of lipids led to lysosomal membrane damage, inhibition of lysosomal degradation at later time points and finally to a lysosomal cell death. Remarkably, it has been shown that hyperactivated autophagy by IM+TIC, loperamide and pimozide massively promotes lysosomal membrane damage. This result highlights the difficulties of a clear distinction between autophagic and lysosomal cell death.
In summary, two new signaling pathways that induce autophagic cell death in GBM cells and may be relevant for glioblastoma therapy were investigated in this study.