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Heat stress transcription factors (Hsfs) have an essential role in heat stress response (HSR) and thermotolerance by controlling the expression of hundreds of genes including heat shock proteins (Hsps) with molecular chaperone functions. Hsf family in plants shows a striking multiplicity, with more than 20 members in many species. In Solanum lycopersicum HsfA1a was reported to act as the master regulator of the onset of HSR and therefore is essential for basal thermotolerance. Evidence for this was provided by the analysis of HsfA1a co-suppression (A1CS) transgenic plants, which exhibited hypersensitivity upon exposure to heat stress (HS) due to the inability of the plants to induce the expression of many HS-genes including HsfA2, HsfB1 and several Hsps. Completion of tomato genome sequencing allowed the completion of the Hsf inventory, which is consisted of 27 members, including another three HsfA1 genes, namely HsfA1b, HsfA1c and HsfA1e.
Consequently, the suppression effect of the short interference RNA in A1CS lin e was re-evaluated for all HsfA1 genes. We found that expression of all HsfA1 proteins was suppressed in A1CS protoplasts. This result suggested that the model of single master regulator needs to be re-examined.
Expression analysis revealed that HsfA1a is constitutively expressed in different tissues and in response to HS, while HsfA1c and HsfA1e are minimally expressed in general, and show an induction during fruit ripening and a weak upregulation in late HSR. Instead HsfA1b shows preferential expression in specific tissues and is strongly and rapidly induced in response to HS. At the protein level HsfA1b and HsfA1e are rapidly degraded while HsfA1a and HsfA1c show a higher stability. In addition, HsfA1a and HsfA1c show a nucleocytosolic distribution, while HsfA1b and HsfA1e a strong nuclear retention.
A major property of a master regulator in HSR is thought to be its ability to cause a strong transactivation of a wide range of genes required for the initial activation of protective mechanisms. GUS reporter assays as well as analysis of transcript levels of several endogenous transcripts in protoplasts transiently expressing HsfA1 proteins revealed that HsfA1a can stimulate the transcription of many genes, while the other Hsfs have weaker activity and only on limited set of target genes. The low activity of HsfA1c and HsfA1e can be attributed to the lower DNA capacity of the two factors as judged by a GUS reporter repressor assay.
HsfA1a has been shown to have synergistic activity with the stress induced HsfA2 and HsfB1. The formation of such complexes is considered as important for stimulation of transcription and long term stress adaptation. All HsfA1 members show synergistic activity with HsfA2, while only HsfA1a act as co-activator of HsfB1 and HsfA7. Interestingly, HsfA1b shows an exceptional synergistic activity with HsfA3, suggesting that different Hsf complexes might regulate different HS-related gene networks. Altogether these results suggest that HsfA1a has unique characteristics within HsfA1 subfamily. This result is interesting considering the very high sequencing similarity among HsfA1s, and particularly among HsfA1a and HsfA1c.
To understand the molecular basis of this discrepancy, a series of domain swapping mutants between HsfA1a and HsfA1c were generated. Oligomerization domain and C-terminal swaps did not affect the basal activity or co-activity of the proteins. Remarkably, an HsfA1a mutant harbouring the N-terminus of HsfA1c shows reduced activity and co-activity, while the reciprocal HsfA1c with the N-terminus of HsfA1a cause a gain of activity and enhanced DNA binding capacity.
Sequence analysis of the DBD of HsfA1 proteins revealed a divergence in the highly conserved C-terminus of the turn of β3-β4 sheet. As the vast majority of HsfA1 proteins, HsfA1a at this position comprises an Arg residue (R107), while HsfA1c a Leu and HsfA1e a Cys. An HsfA1a-R107L mutant has reduced DNA binding capacity and consequently activity. Therefore, the results presented here point to the essential function of this amino acid residue for DNA binding function. Interestingly, the mutation did not affect the activity of the protein on Hsp70-1, suggesting that the functionality of the DBD and consequently the transcription factor on different promoters with variable heat stress element number and architecture is dependent on structural peculiarities of the DBD.
In conclusion, the unique properties including expression pattern, transcriptional activities, stability, DBD-peculiarities are likely responsible for the dominant function of HsfA1a as a master regulator of HSR in tomato. Instead, other HsfA1-members are only participating in HSR or developmental regulations by regulating a specific set of genes. Furthermore, HsfA1b and HsfA1e are likely function as stress primers in specific tissues while HsfA1c as a co-regulator in mild HSR. Thereby, tomato subclass A1 presents another example of function diversity not only within the Hsf family but also within the Hsf-subfamily of closely related members. The diversification based on DBD peculiarities is likely to occur in potato as well. Therefore this might have eliminated the functional redundancy observed in other species such as Arabidopsis thaliana but has probably allowed the more refined regulation of Hsf networks possibly under different stress regimes, tissues and cell types.
Smut fungi (Ustilaginomycotina) were previously defined as plant parasites that produced blackish or brownish masses of teliospores in or on various organs of plants. Each teliospore germinates to form a single basidium with usually four basidiospores that subsequently grow as a saprobic, yeast-like, haploid stage. The Ustilaginomycotina are a highly diverse group with about 1,700 species in 115 different genera. All of the species were united in a single order, the Ustilaginales, in late 19th century. These teliospore producing fungi are now considered the classic smut fungi. Towards the end of the 20th century, new ideas were brought into this classification system. Most notable was the comparative work regarding the ultrastructure of septal pores and the anatomy of the interaction zones between host and parasite. This work changed the whole concept of smut fungi and their evolutionary relationships. These results were subsequently supported by molecular phylogenetic studies. Both lines of investigation led to the classification of the smut fungi into four different classes, Ustilaginomycetes, Exobasidiomycetes, Malasseziomycetes and Moniliellomycetes (see chapter 1.3).
A reliable taxonomy that reflects phylogenies needed in order to estimate the diversity and the relationships between the diverse groups of smut fungi. In the last 20 years, molecular investigations based mostly on rDNA loci, e.g. ITS (internal transcribed spacer) or LSU (large subunit), have revealed the evolutionary relationships between many taxa of smut fungi. However, there are few phylogenetic studies available for smut fungi (see chapter 1.5.1), and much work is needed to develop backbone phylogenetic trees and to resolve species complexes of many smut fungi.
This thesis reports the results of six different studies that aimed to develop new and improved tools for the phylogenetic analyses of smut fungi, and then apply these methods to selected groups of smut fungi. The first study (Kruse et al. 2017a, Chapter 3) developed a method to improve the amplification of ITS sequences of some smut fungi. Due to its high discrimination value, the ITS gene region is widely used as a barcoding locus for species delimitation of fungi. For this purpose, the general ITS primers ITS1 and ITS4 or more specific modifications, e.g. ITS1F for Ascomycota, ITS4B for Basidiomycota or M-ITS1 for smut fungi, were used. As these primer combinations often yielded unsatisfactory results, due to coamplification of other (contaminant) fungi or the host plant DNA, improvement of the amplification of the ITS region was needed. In order to design new smut specific primers for the ITS region, a representative set of several sequences of the flanking regions of the ITS region (LSU and SSU) of smut fungi, plants and other fungi were downloaded from GenBank. A set of primers was designed on this dataset. These primers were tested on a representative set of about 70 different smut genera under different PCR conditions. Finally, three different primers, one forward primer, smITS-F, and two reverse primers, smITS-R1 and -R2, were selected as the best ones. The following tests with different combinations of these primers, and also under inclusion of the M-ITS1 primer, showed only slight differences in the number of different genera that successfully amplified. But there were some differences regarding the genera that amplified. A broader test on 205 samples in 39 genera showed that the PCR efficiency of the newly designed primers was much better than the primer set ITS4/M-ITS1. With the primers designed in this study almost no non-target ITS was amplified, giving new opportunities especially for amplifying ancient DNA or DNA from older herbarium samples. However, many species groups remain unresolved by only one gene region.
The second study (Kruse et al. 2017c, Chapter 4) found new loci and suitable primers that better resolved multi-locus trees. To date, the most frequently used loci for making multi-locus trees are SSU (small subunit), LSU (large subunit) and ITS (internal transcribed spacer). While the LSU is not always sufficient to distinguish between closely related species, it is highly discriminative above the species level. In an effort to increase the phylogenetic resolution of smut phylogenies, some protein-coding genes were used, including rpb1, rpb2, and atp6 with varying success (see Chapter 2.1.2). As most of these loci are seldom used or sometimes only work on pure cultures because of their low specifity, new protein-coding loci were identified that produced reliable phylogenetic trees. Based on five available genomes, potential gene loci were filtered for possible primers. Initially, 40 different primer combinations for 14 gene loci were tested on a set of twelve different genera of smut fungi. The best candidates were selected and optimized during further tests. Finally, 22 different forward primers and 17 different reverse primers for nine different gene regions were developed, with each differentiating at least one genus of smut fungi (preferably for Ustilaginomycetes). The different primers showed varying discriminative power for different smut genera. They worked best for the Ustilaginaceae, based on the primer designed from Ustilaginomycetes genomes. These new primer sets and loci have the potential to resolve different species groups within the smut fungi and furthermore to produce reliable phylogenetic trees with high resolution. To prove their applicability, three species complexes were investigated in-depth, two from the Ustilaginomycetes and one from the Exobasidiomycetes.
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The objectives of this thesis were to understand how distinct classes of cell types interact to shape oscillatory activity in cortical circuits of the turtle. We chose the turtle cortex as a model system for cortical computations for two reasons. One is that the phylogenetic position of turtles makes their cortex functionally and anatomically particularly interesting. The second is that reptilian brains present several unique experimental advantages. Turtles have a three-layered cortex that forms the dorsalmost part of their pallium and receives direct input from visual thalamus. Thus turtle cortex, while sharing several features with mammalian cortices, constitutes a simpler system for studying cortical computations and dynamics. Freshwater turtles are semiaquatic species, that dive for hours and hibernate for months without breathing. Their brains are adapted to these behaviors so that they can operate under severe anoxia. This property allows for ex vivo wholebrain and whole-cortex (”cortical slab”) preparations in vitro, enabling the use of many sophisticated techniques for monitoring activity in parallel.
I thus set out to utilize the advantages of our model system, by using optogenetic methods to reliably evoke oscillations in an ex vivo whole-cortex preparation while observing activity in parallel with planar multi-electrode arrays (MEA), linear silicon depth-electrodes and patch-clamp recording techniques. This required several technical aspects to be solved. Prior work in turtle cortex (Prechtl, 1994; Prechtl et al., 1997; Senseman and Robbins, 2002) indicated that visual stimuli evoke complex activity patterns (e. g. wave patterns) in dorsal cortex. The goal was to examine these dynamics in detail and to provide mechanistic explanations for them whenever possible. The recent advent of optogenetics, the development of microelectrode arrays, and the possibility to combine these techniques with classical electrophysiological approaches on a resistant, accessible and stable preparation led me to explore a number of technical avenues.
First I had to establish gene delivery methods in reptiles. I settled on recombinant viruses, and show results from several serotypes of adeno-associated virus (AAV), i lentivirus and rabies virus. I report successful gene expression of genes of interest with several subtypes of AAV, including the commonly used AAV2/1 and AAV2/5 serotypes. Second I had to find promoters enabling global and cell-type specific gene expression in reptiles. Ubiquitous high-yield promoters such as CAG/CB7 or CMV drive high levels of expression in turtles; cell-type specific promoters such as hSyn (expression limited to neurons) and CaMKIIa (expression limited exclusively o mostly to excitatory neurons) appear similarly biased in turtles. Other cell-type specific promoters reported in the literature (fNPY, fPV, fSST) failed to express in turtles.
A second major aspect of my work focused on electrophysiological recordings using microelectrode arrays and the interpretation of extracellular signals recorded from cortex in ex vivo preparations. We observed that spike signals produced by pyramidal and inhibitory neurons were very often followed by a slower potential. We identified these slower potentials as reflections of synaptic currents, and thus of the axonal projections of the neurons, at least within the deep layers of cortex. This also resulted in a means to classify neurons as excitatory or inhibitory with much higher reliability than classical methods (e. g. spike width). The final aspect of my work concerns the use of optogenetics to dissect the mechanisms of cortical oscillations and wave propagation. I show that oscillations can be induced by light in turtle cortex after transfection with AAV2/1 carrying the gene for channelrhodopsin 2 (ChR2). By using the CaMKIIa promoter, ChR2 induced currents are limited to LII/III excitatory cells; we can therefore control excitatory drive to cortical networks. If this drive is strong enough, layer III inhibitory interneurons are recruited and fire in a concerted fashion, silencing the excitatory population. The visually evoked 20 Hz oscillations observed in chronically recorded animals (Schneider, 2015) or in anaesthetized animals (Fournier et al., in press) thus appear to result from a feedback loop between E and I cells within layers II & III. Details of these interactions are being investigated but - layer I interneurons, by contrast, do not seem to be involved. By pulsing light I could control the frequency of the oscillations within a range of several Hz around the natural oscillation frequency. Above this range, cortex could only follow the stimulus at a fraction (1/2, 1/3,...) of the light pulse frequency. Using a digital micromirror device, I limited activation of the cortical networks spatially, enabling the study of wave propagation in this system.
Reptilian cortex offers a relatively simple model system for a reductionist and comparative strategy on understanding cortical computations and dynamics. Turtle dorsal cortex could thus give fundamental insights to the primordial organization tional, computational and functional principles of cortical networks. These insights are relevant to our understanding of mammalian brains and may prove valuable to decipher fundamental questions of modern neuroscience.
To date, chemicals are used ubiquitous in everyday life and an increasing consumption of pharmaceuticals and personal care products and industrial chemicals results in an increased water pollution. Conventional wastewater treatment plants are not able to completely remove the variety of (polar) organic compounds from today’s wastewater and thus serve as constant key point sources for the unintentional release of (micro-)pollutants into the aquatic environment. Anthropogenic micropollutants are detectable in very low concentrations in almost every aquatic compartment and may cause adverse effects on aquatic organisms. Considering the current situation of water pollution and to enhance water quality with regard to environmental and human health, the implementation of advanced wastewater treatment technologies, such as ozonation and activated carbon filtration was extensively discussed and investigated in recent years. Yet, besides their advantages regarding the efficient removal of a variety of recalcitrant, organic compounds as well as pathogens from the wastewater, it is known that especially the treatment with ozone may lead to the formation of largely unknown ozonation by-products with often unknown toxicity and unknown threats to human and the environment. To address these topics the joint research project TransRisk aimed at the “characterization, communication and minimization of risks originating from emerging contaminants and pathogens in the water cycle”. Within this research project the present thesis focuses on the ecotoxicological investigation of emerging waterborne contaminants, including their potential transformation products (TPs). Additionally, focus was laid on the investigation of combined effects of anthropogenic contaminants and pathogens with effects especially on aquatic invertebrate organisms.
The potential ecotoxicological effects of the antiviral drug acyclovir and two of its structurally identified TPs, were investigated on three aquatic organisms (Raphidocelis subcapitata, Daphnia magna and embryos of Danio rerio). While the parent compound acyclovir caused no acute toxicity up to a tested concentration of 100 mg/l on any of the investigated organisms, both TPs were shown to exhibit an increased aquatic toxicity. Carboxy-acyclovir, the biodegradation product of acyclovir, significantly reduced reproduction of D. magna by 40% at 102 mg/l, and the ozonation product COFA significantly inhibited growth of green algae R. subcapitata (EC10 = 14.1 mg/l). In the present case, advanced wastewater treatment was shown to lead to the formation of TPs, that reveal a higher toxicity towards investigated organisms, than the parent compound. Results highlight the necessity of further research related to the topic of identification and characterization of TPs, formed during advanced wastewater treatment processes.
To investigate the potential reduction or enhancement of toxic effects of nine differently treated wastewater effluents, selected bioassays with Daphnia magna, Lumbriculus variegatus and Lemna minor were conducted in flow-through test systems on a pilot treatment plant. The different treatment processes included ozonation of conventional biological treatment, with subsequent filtration processes as well as membrane bioreactor treatment in combination with ozonation. While exposure to the conventionally treated wastewater did not result in significant impairing effects on D. magna and L. minor, a reduced abundance of L. variegatus (by up to 46%) was observed compared to the medium control. Subsequent ozonation and additional filtration of the wastewater enhanced water quality, visible in an improved performance of L. variegatus. In general, direct evidence for the formation of toxic TPs due to the advanced wastewater treatments was not found, at least not in concentrations high enough to cause measurable effects in the investigated test systems. Additionally, no evidence for immunotoxic effects of the investigated wastewater effluents were observed. Yet, study-site- and species-specific effects hindered the definite interpretation of results. That underline the importance of a suitable test battery consisting of representatives of different taxonomic groups and trophic levels, to ensure a comprehensive evaluation of the complex matrix of wastewater and to avoid false-negative or false-positive results.
With aim to improve knowledge regarding immunotoxicity in invertebrates, the potential immunotoxic effects of the immunosuppressive pharmaceutical cyclosporine A (CsA) were investigated by applying the host-parasite model system Daphnia magna – Pasteuria ramosa in an adapted host resistance assay. Co-exposure to CsA and Pasteuria synergistically affected long-term survival of D. magna. Additionally, the enhanced virulence of the pathogen upon chemical co-exposure was expressed in synergistically increased infection rates and an increased speed of Pasteuria-induced host sterilization. In conclusion, results provide evidence for a suppressed disease resistance in a chemically stressed invertebrate host, highlighting the importance of investigating the conjunction of environmental pollutants and pathogens in the environmental risk assessment of anthropogenic pollutants.
Die Analyse früher Entwicklungsstadien von Säugetierembryonen und daraus gewonnener Stammzelllinien kann entscheidende Erkenntnisse im Bereich der Reproduktionsbiologie und der regenerativen Medizin hervorbringen. Dabei spielt die Maus, als geeignetes Modellsystem für die Übertragbarkeit auf den Menschen eine wichtige Rolle, in erster Linie weil die Blastozysten der Maus verglichen mit menschliche Blastozysten eine morphologische Ähnlichkeit aufweisen. Humane embryonale Stammzelllinien haben großes Potential für die Anwendung in der regenerativen Medizin und vergleichend dazu wurde Gen-Targeting in embryonalen Stammzellen verwendet, um tausende neuer Mausstämme zu generieren. Die Gewinnung embryonaler Stammzellen erfolgt im Blastozystenstadium, diese können dann nach Injektion in eine andere Blastozyste zur Entwicklung aller Gewebearten, einschließlich der Keimbahngewebe, beitragen (Martin, 1981; Evans and Kaufman 1981).
Ursache einer Fehlgeburt können vor allem Defekte in der Entwicklung des Trophoblasten und des primitive Entoderms (PrE) sein, dabei sind ca. 5 % der Paare betroffen die versuchen ein Kind zu bekommen (Stephenson and Kutteh, 2007). Eine Untersuchung dieser Zelllinien im Mausmodell könnte weitere Erkenntnisse für die Gründe einer Fehlentwicklung liefern. Trophoblasten Stammzelllinien können aus den Blastozysten der Maus und dem extraembryonalen Ektoderm von bereits implantieren Embryonen gewonnen werden (Tanaka et al., 1998). Diese Zelllinien geben Aufschluss über die Entwicklung des Trophoblasten, fördern die Entwicklung der Plazenta und sind gleichzeitig ein gutes Modellsystem um die Implantation des Embryos im Uterus näher zu untersuchen. Zellen des primitive Entoderms (PrE) beeinflussen das im Dottersack vorhandene extraembryonale Entoderm, welches dort als “frühe Plazenta” fungiert und für die Versorgung des Embryos mit Nährstoffen zuständig ist (Cross et al., 1994). Des Weiteren besitzt das Entoderm einen induktiven Einfluss auf die Bildung von anterioren Strukturen und die Bildung von Endothelzellen sowie Blutinseln (Byrd et al., 2002).
Extraembryonale Endodermstammzellen (XEN Zellen) können aus Blastozysten gewonnen und in embryonale Stammzellen (ES-Zellen) umgewandelt werden (Fujikura et al., 2002; Kunath et al., 2005). Es war jedoch nicht bekannt, ob XEN-Zellen auch aus Postimplantations-Embryonen gewonnen werden können. XEN-Zellen tragen in vivo zur Entwicklung des Darmendoderms bei (Kwon et al., 2008; Viotti et al., 2014) und könnten als alternative, selbsterneuernde Quelle für extraembryonale Endoderm-abgeleitete Zellen dienen, die zur Herstellung von Geweben für die regenerative Medizin verwendet werden könnten (Niakan et al., 2013).
In der Embryogenese der Maus zeigt sich an Tag E3.0 eine kompakte Morula die sich allmählich in das Trophektoderm (TE) differenziert, welches wiederum den Embryonalknoten (“innere Zellmasse”) umschließt (Johnson and Ziomek, 1981). Ein wichtiger Schritt im Rahmen der Entwicklung findet an Tag E3.5 statt, in diesem Zeitraum gehen aus dem Embryonalknoten der pluripotente Epiblast und das primitive Entoderm hervor. Im späten Blastozystenstadium an Tag E4.5 liegt das PrE als Zellschicht entlang der Oberfläche der Blastocoel-Höhle. Aus dem Epiblast entwickeln sich im weiteren Verlauf der Embryo, das Amnion und das extraembryonale Mesoderm des Dottersacks. Die Zellen des Trophektoderm führen zur Entwicklung der Plazenta. Das PrE differenziert sich im Zuge der Weiterentwicklung in das viszerale Entoderm (VE) und das parietale Entoderm (PE) des Dottersacks (Chazaud et al., 2006; Gardner and Rossant, 1979; Plusa et al., 2008). VE umgibt den Epiblast und extraembryonisches Ektoderm (ExE). PE-Zellen wandern entlang der inneren Oberfläche von TE und sezernieren zusammen mit Trophoblasten-Riesenzellen Basalmembranproteine, um die Reichert-Membran zu bilden (Hogan et al., 1980). Die Reichert-Membran besteht aus Basalmembranproteinen, einschließlich Kollagenen und Lamininen, die zwischen den parietalen Endoderm- und Trophoblastzellen liegen. Diese Membran wirkt als ein Filter, der dem Embryo den Zugang zu Nährstoffen ermöglicht, während er eine Barriere zu den Zellen der Mutter bildet (Gardner, 1983).
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Angesichts heutiger Umweltprobleme ist die Stärkung positiver Mensch-Natur-Beziehungen wichtiger denn je. Zeitgenössische Umweltbildung zielt darauf ab, Motivation und Einstellungen zu fördern sowie eine grundlegende Wissensbasis zu schaffen (IUCN, UNEP, & WWF, 1991; Potter, 2010), um einen selbstbestimmten, verantwortungsvollen Umgang mit der Natur zu ermöglichen. Positiver Naturbezug und Umwelteinstellungen gelten als Basis für aktiven Umweltschutz. Direkte Naturerfahrungen gelten dabei als didaktische Möglichkeit, die Motivation für Umweltschutz zu festigen (Kaiser, Roczen, & Bogner, 2008). Einstellungen verändern sich im Laufe des Lebens und so kann das Alter eine wichtige Rolle bezüglich der Effektivität von Umweltbildungsprogrammen spielen (Ernst & Theimer, 2011). Auch Umweltwissen gilt als Grundlage von Umwelthandeln. Denn sinnliche Erfahrungen allein führen nicht zum Verständnis ökologischer Zusammenhänge (Frick, Kaiser, & Wilson, 2004; Liefländer, Bogner, Kibbe, & Kaiser, 2015). Die biologiedidaktische Forschung sieht Fakten-, Handlungs- und Effektivitäts-wissen als zentral für die Genese von Umwelthandeln (Frick, Kaiser, & Wilson, 2004). Isoliertes Fachwissen wiederum führt nach aktueller Erkenntnis auch nicht zur Entwicklung von Haltungen und Wertvorstellungen, welche unser Handeln beeinflussen (Barr, 2003; Finger, 2010; Leiserowitz, Kates, & Parris, 2005).
Bis heute sind altersbasierte Unterschiede bei Schülerinnen und Schülern bezüglich ihrer Naturverbundenheit und Umwelteinstellungen nicht hinreichend untersucht. Auch ist die nötige Dauer der Naturerfahrungen noch nicht nachgewiesen. Es gibt bislang keine Studie, die Umwelteinstellungen, -wissen und –handeln von Kindern verschiedener Regionen der Erde untersucht und Daten auf internationaler Ebene erhoben und ausgewertet hat. Die gezielte Integration der drei Umweltwissensarten in ein solch globales Umweltbildungsprojekt stellt eine zusätzliche bislang nicht angegangene Aufgabe dar. Die vorliegende Arbeit schließt diese Forschungslücken, indem sie auf internationaler Ebene jene Variablen mit einbezieht, die einen nahezu vollständigen Eindruck der Effektivität von Umweltbildung in verschiedenen Regionen, Sozialisationen und Altersklassen zulässt. So wird der Einfluss eines umfassenden Umweltbildungsprogramms auf Naturverbundenheit, Umwelteinstellungen und -wissen der verschiedenen Typen untersucht und ein Bezug zur eventuellen Veränderung des Umwelthandelns hergestellt. Dabei stehen sowohl traditionelle als noch unerforschte mögliche Einflussfaktoren im Fokus. Die Studie umfasst insgesamt 1454 Schülerinnen und Schüler aus Bangladesch, Malaysia, Deutschland und Singapur, die alle an dem Umweltbildungsprojekt „Global denken, lokal handeln – wir schützen unsere Umwelt!“ bzw. “Think global, act local – we protect our environment!“ teilgenommen haben.
Zur Messung der Naturverbundenheit diente Schulz’ INS-Skala (Inclusion of Nature in Self) (2002). Umwelteinstellungen wurden mit dem 2-MEV-Modell (Two Major Environmental Values) gemessen (Johnson & Manoli, 2011). Eine Skala zur Erhebung von Umweltwissen wurde eigens erstellt und hinsichtlich der drei Wissenstypen nochmals modelliert. Eine Skala zur Ermittlung von Umwelthandeln wurde auf Grundlage von Bögeholz (1999) erstellt. Alle Skalen waren Teil eines Fragebogens, welcher in Form eines Pre-, Post- und Follow-up-Test eingesetzt wurde. Kinder aus Parallelklassen, die nicht am Projekt teilnahmen, aber Klassenunterricht zu den jeweiligen Themen erhielten, dienten als Kontrollgruppen.
Die Ergebnisse bestätigen einen positiven Effekt außerschulischer Umweltbildung bezüglich der Entwicklung der untersuchten Variablen. So wurde nach der Teilnahme am eintägigen und auch nach dem fünftägigen Umweltbildungsprogramm eine signifikante Verstärkung des Naturbezugs gemessen, wohingegen die Kontrollgruppen keine messbare Veränderung zeigten. Jedoch nur die fünftägige Intervention führte auch zu nachhaltigen Veränderungen. Hierbei am stärksten beeinflusst wurden Kinder zwischen sieben und neun Jahren.
Bei der Untersuchung demographischer Einflussfaktoren auf Umwelteinstellung, -wissen und –handeln stellten sich das Wohnsitzland sowie die städtische bzw. ländliche Prägung der Wohngegend als entscheidend heraus. So waren dies die einflussreichsten Determinanten zur Vorhersage des Grundvorhandenseins sowie Veränderungen der untersuchten Variablen in Folge der Bildungsmaßnahme. Einzig bei der Entwicklung des Umwelthandelns schien die direkte Naturerfahrung unwesentlich, zeigten die Kontrollgruppen ähnlichen Wandel in ihrem aktiven Einsatz für die Umwelt. Im internationalen Vergleich scheint die komplexe Verkettung diverser einflussnehmender Faktoren, wie der Wohlstand des jeweiligen Staates, das generelle politische System sowie spezifische bildungspolitische Begebenheiten, den Erfolg von Umweltbildungsprogrammen mit zu bestimmen.
Die Daten zeigen, dass Faktenwissen Grundlage für Handlungs- und Effektivitätswissen ist. Alle Dimensionen wurden durch die Intervention signifikant gesteigert. Effektivitätswissen wuchs am stärksten. Auch das Umweltverhalten wurde positiv verstärkt. Jedoch ließen sich nur schwache Korrelationen zwischen den einzelnen Wissenstypen und Handeln feststellen. Zusammenfassend war das durchgeführte Bildungsprojekt erfolgreich in der Förderung von Naturverbundenheit sowie Umwelteinstellungen, -wissen und- handeln. Die Ergebnisse werden im Rahmen dieser Arbeit im Hinblick auf ihre Bedeutung für die schulische Umweltbildung sowie die didaktische Forschung erörtert.
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.
Microsporidia are a group of parasites that infect a wide range of species, many of which play important roles in agriculture and human disease. At least 14 microsporidian species have been confirmed to cause potentially lifethreatening infectious diseases in both immunocompromised and immunocompetent humans. Approximately 1,400 species of microsporidia have been described. Depending on their host and habitat they are classified into three groups, the aquasporidia, the terresporidia and the marinosporidia.
Microsporidia were originally classified as fungi by Naegeli (1857). However, their lack of typical eukaryotic components – such as mitochondria, Golgi bodies or peroxisomes – suggested to place the microsporidia together with other amitochondriate protists within the Archezoa kingdom. This "microsporidia-early" hypothesis was further supported by molecular phylogenies inferred from individual genes. Despite this evidence, the placement of microsporidia as an early branching eukaryote remained a topic for debate. The phylogeny of microsporidia is prone to suffer from biases in their reconstruction. The high evolutionary rate of microsporidian proteins tends to place these proteins together with other fast evolving lineages, a phenomenon known as long-branch attraction. In 1996, the first molecular phylogenetic studies placed the microsporidia inside the fungi.
Subsequently, several further studies located the microsporidia at different positions inside the fungal clade. Since then, microsporidia have been considered as members of the Ascomycota, Zygomycota, Cryptomycota, or as a sister group to the Ascomycota and Basidiomycota, or even as the sister group of all fungi.
The difficulties in determining the evolutionary origin of microsporidia are not only caused by their lack of several cellular components but also by their reduced genomes and metabolism. Being obligate intracellular parasites, microsporidia successfully reduced their genome sizes, down to the range of bacteria. As the smallest eukaryotic genome described so far, the genome of Encephalitozoon intestinalis is just 2.3 Mbp, about half the size of the one of Escherichia coli. Due to their low number of protein coding genes (less than 4,000), microsporidia are thought to retain only genes essential for their survival and development. Furthermore, several key metabolic pathways are missing in the microsporidia, such as the citric acid cycle, oxidative phosphorylation, or the de novo biosynthesis of nucleotides. As a result they are in an obligatory dependence on many primary metabolites from the hosts. However, the presence of hsp70 protein suggests a more complex genome of the microsporidian ancestor. Consequently, the small microsporidian genomes and the reduced metabolism would be consequences of a secondary loss process that molded the contemporary microsporidia from a functionally more complex ancestral species. However, it remains unclear whether the last common ancestor (LCA) of the microsporidia was already reduced, or whether the genome compaction was lineage-specific and started from a more complex LCA.
We investigated the evolutionary history of the contemporary microsporidia through the reconstruction and analysis of their LCA. As a first step in our analysis, we have developed and implemented a software facilitating an intuitive data analysis of the large presence absence-patterns resulting from the tracing of microsporidian proteins in gene sets of many different species. These so called phylogenetic profiles can now be dynamically visualized and explored with PhyloProfile. The software allows the integration of other additional information layers into the phylogenetic profile, such as the similarity of feature architecture (FAS) between the protein under study and its orthologs. The FAS score can be displayed along the presence-absence pattern, which can help to identify orthologs that have likely diverged in function. PhyloProfile closes the methodological gap that existed between tools to generate large phylogenetic profiles to delineate the evolutionary history and the contemporary distribution of large – and ultimately complete – gene sets, and the more function-oriented analysis of individual protein. In the next step we tackled the problem of how to transfer functional annotation from one protein to another. We have developed HamFAS that integrates a targeted ortholog search based on the HaMStR algorithm with a weighted assessment of feature architecture similarities (FAS) between orthologs. In brief, for a seed protein we identify orthologs in reference species in which proteins have been functionally annotated based on manually curated assignments to KEGG Ortholog (KO) groups. The FAS scores between the orthologs and seed proteins are calculated. Subsequently, we compute pairwise FAS scores for all reference proteins within a KO group. A group's mean FAS score serves then as cutoff that must be exceeded to warrant transfer of its KO identifier to the seed. A benchmark using a manually curated yeast protein set showed that HamFAS yields the best precision (98.5%) when compared with two state-of-the-art annotation tools, KAAS and BlastKOALA. Furthermore, HamFAS achieves a higher sensitivity. On average HamFAS annotates almost 50% more proteins than KAAS or BlastKOALA.
With this extended bioinformatics toolbox at hand, we aimed at reconstructing the evolutionary history of the microsporidia. We generated a robust phylogeny of microsporidia using a phylogenomics approach. As a data basis, we identified a set of microsporidian proteins encoded by 80 core genes with one-to-one orthologs. A maximum likelihood analysis of this data
with 48 fungi and additionally in 13 species from more distantly related such as animals and plants combined in a supermatrix strongly supported the hypothesis that microsporidia form the sister group of the fungi. We confirmed that the data explains this microsporidia-fungi relationship significantly better than any other of the previously proposed phylogenetic hypotheses.
On the basis of this phylogeny, and of the phylogenetic profiles of microsporidian proteins, we then focused on reconstructing the dynamics microsporidian genome evolution. Between 2% of the proteins in the compact microsporidia Encephalitozoon intestinalis and up to 49% of the proteins of Edhazardia aedis are private for individual microsporidian species. A comparison of the sequence characteristics of these proteins to that of proteins with orthologs in other microsporidian species revealed individual differences. Yet, without further evidences it remains unclear whether these private genes are indeed lineage-specific innovations contributing to the adaptation of each microsporidium to its host, or whether these are artifacts introduced in the process of gene annotation. A total of 14,410 microsporidian proteins could then be grouped into 1605 orthologous groups that can be traced back to the last common ancestor of the microsporidia (LCA set). We found that 94% of the microsporidian LCA proteins could be tracked back to the last eukaryotic common ancestor. The high evolutionary age of these proteins, together with the resistance against gene loss in the microsporidia suggests that the corresponding functions are essential for eukaryotic life. Further 3% of the LCA proteins could be dated to the common ancestor microsporidia share with the fungi. Only 3% of the LCA proteins appear as microsporidia specific inventions. These proteins are potentially of importance for the evolutionary of the obligate parasitic lifestyle nowadays shared by all microsporidia.
The functional annotation and metabolic pathway analysis of the microsporidian LCA protein set gave us more insight into the adaptation of the microsporidia to their parasitic lifestyle and the origin of the microsporidian genome reduction. The presence of E1 and E3 components of the pyruvate dehydrogenase complex and the mitochondrial hsp70 protein support an ancestral presence of mitochondria in the ancestral microsporidia. In addition, several ancient proteins that complement gapped metabolic pathways were found in the microsporidian LCA. They suggested a more complex genome and metabolism in the LCA. However, our reconstruction of the metabolic network of the microsporidian LCA still lacks many main pathways. For example, the TCA cycle for effective energy production, and key enzymes that are required for in vivo synthesis of critical metabolites like purines and pyrimidines appear absent. We therefore find that the parasitic lifestyle and the genome reduction already occurred in the microsporidian LCA. This ancestral state was followed by further losses and gains during the evolution of each individual microsporidian lineage.
In conclusion, I described for the first time the in vivo functions of PAK2 during cardiac development and its requirement for heart contractility
AIM1 – Characterization of Pak2a and Pak2b functions during cardiovascular system development: description of the phenotype triggered by the loss of expression of pak2b in the pak2a mutant Firstly, in addition to the confirmation of the published data regarding the pak2a mutant and morphant phenotype, I showed that pak2bbns159 mutant does not exhibit morphological defects, neither in the ISV formation nor in the brain vascular patterning. More importantly, I analyzed in more details the phenotypic consequences of pak2a and pak2b loss of expression in the trunk and brain vasculatures. Indeed, the lack of blood flow in the embryos, was associated with central arteries migration defects and reduced lumen in these central arteries and the ISVs. Moreover, pak2a and pak2b loss of expression resulted in cardiac failure.
AIM2 – Role of Pak2 on cardiac contractility From 40 -46 hpf, I found a weaker heart contractility in the pak2ami149/mi149;pak2bbns159/bns159. Although, the PAK proteins have been shown to impact the actin cytoskeleton organization, the heart morphological defects associated with the altered contractility, were not associated with acto-myosin filament reorganization. However, by analyzing in more details the structure of the sarcomeres, I was able to demonstrate that the proteins constituting the sarcomeres were strongly affected and showed an altered spatial organization. Then, I also described the effects of the loss of expression of both paralogs on the junctional protein localization. I demonstrated the loss of Pak2 function resulted in junction protein rearrangement in the cardiomyocytes in the pak2ami149/mi149;pak2bbns159/bns159 mutants at 40 and 46 hpf.
Thus, I was able for the first time to demonstrate in vivo PAK2 functions during cardiac development and its requirement for proper cardiac contractility activity.
AIM3 – Decipher mechanism of Pak2 signaling cascade involved during cardiac development Both pak2a and pak2b WT mRNAs were able to rescue the pak2ami149/mi149;pak2bbns159/bns159 mutant heart defects and the results indicated that these paralogs share overlapping function during cardiac development. Moreover, although I was not able to examine the control transgenic lines, myocardial and endothelial specific pak2a overexpression did not ameliorate the mutant cardiac deficiency. Thus,the absence of rescue by reactivating pak2a in cardiomyocytes indicates a non-cell autonomous function of Pak2a on cardiomyocytes.
For the first time, this study allowed to follow PAK2 in vivo functions during cardiovascular development. More importantly, its role on heart contractility regulation would enable further investigations to generate new tools for the treatment of cardiomyopathies.
Polyploidie in Prokaryoten
(2018)
Diese Arbeit teilt sich in drei Teile auf, die sich mit der Regulation der Polyploidie sowie mit der Genkonversion als evolutionären Vorteil von Polyploidie in Haloferax volcanii beschäftigen.
Im ersten Teil dieser Arbeit, wurde der Einfluss der DNA-Replikationsinitiatorproteine Orc1/Cdc6 auf das Ploidielevel untersucht. Hierbei konnte anhand von Deletionsmutanten zunächst gezeigt werden, dass lediglich drei der 16 Orc1/Cdc6-Proteine in H. volcanii essentiell sind. Bestimmung des Ploidielevels mittels qPCR-Analyse ergab, dass jedes der 12 untersuchten Orc1/Cdc6-Proteine das Ploidielevel mindestens eines Replikons beeinflusst und dementsprechend sowohl die mit einem Replikationsursprung assoziierten als auch die „verwaisten“ Orc1/Cdc6-Proteine eine Funktion haben. Die mit einem Replikationsursprung assoziierten Orc1/Cdc6-Proteine hatten hierbei keinen größeren Einfluss auf das Ploidielevel als die „verwaisten“. Zusätzlich konnte durch Wachstumsanalysen in Mikrotiterplatten gezeigt werden, dass die meisten Deletionsmutanten unter allen getesteten Bedingungen ein mit dem Wildtyp vergleichbares oder besseres Wachstum zeigen. Eine Deletionsmutante eines Orc1/Cdc6-Proteins hingegen zeigte nur verbessertes Wachstum bei Glukose als Kohlenstoffquelle, was ein Hinweis auf die Verwendung verschiedener Orc1/Cdc6-Proteine unter verschiedenen Bedingungen sein könnte. Zusätzlich wurden zwei mit dem Replikationsursprung assoziierte Orc1/Cdc6-Proteine überexprimiert und via ihres N-terminalen His-Tag im Western-Blot nachgewiesen, sodass diese nun für Co-Affinitätsaufreinigungen zur weiteren Charakterisierung des komplexen Zusammenspiels der Orc1/Cdc6-Proteine zur Verfügung stehen.
Im Rahme des zweiten Teils der Arbeit wurde der Einfluss der in der 5‘-Region der der Replikationsursprünge ori1 und ori2 kodierten Proteine auf Wachstum und die Kopienzahl des Hauptchromosoms bestimmt. Zunächst wurde die Expression der drei in Haloarchaea hoch-konservierten oap-Gene upstream von ori1 mittels Nothern-Blot untersucht und es konnte gezeigt werden, dass das oap-Operon tatsächlich als Operon abgelesen wird. Um alle Gene in den 5‘-Regionen von ori1 und ori2 genauer zu charakterisieren, wurden induzierbare Überexpressionsmutanten im Wildtyp-Hintergrund angefertigt. Es konnte mittels Wachstumsversuchen in Mikrotiterplatten gezeigt werden, dass bei Induktion von Beginn an die Überexpression der Hef-Helikase und des oapB-Proteins zu einem starken Wachstumsdefekt führen, die von oapC und HVO_1724 zu einem moderaten Wachstumsdefekt, wohingegen für die Überexpressionsmutante von oapA vergleichbares Wachstum zum Wildtyp und für die Überexpression der Rad25d-Helikase verbessertes Wachstum beobachtet werden konnte. Es konnte darüber hinaus gezeigt werden, dass sowohl die Deletion als auch die Überexpression der Helikasen keinen Einfluss auf das Ploidielevel hat; die Deletion von oapC führt jedoch zu einer Reduktion der Genomkopienzahl in exponentieller und stationärer Phase, was ein erster Hinweis darauf ist, dass das oap-Operon eine Rolle bei der Regulation des Ploidielevels spielen könnte.
Im dritten Teil der Arbeit wurde eine Methode entwickelt, um Genkonversion farblich sichtbar zu machen. Hierbei wurde sich H. volcaniis Carotinoidbiosynthese zu Nutze gemacht. Es wurden zwei verschiedene, auxotrophe Elternstämme mittels Protoplastenfusion verschmolzen, um eine heterozygote Tochterzelle zu erzeugen. Ein Genkonversionsereignis wurde durch einen roten Keil angezeigt, der aus einer weißen Kolonie wuchs und durch die erfolgreiche Reparatur des Carotinoidbiosynthesegens entstand. Es wurden insgesamt 8525 Klone ausgestrichen und 0,14 % der Kolonien zeigten eine entsprechende rote Färbung. Das Proof-of-Principle dieser Methode ist in damit in dieser Arbeit gelungen. Um die Genkonversion in den weißen Kolonien auf genetischer Ebene genauer zu untersuchen, wurde PCR verwendet. Es konnte gezeigt werden, dass in den Zellen aller 135 untersuchten Kolonien Genkonversion stattgefunden hatte und zwar so effizient, dass nur in seltenen Fällen Heterozygotie vorlag. Unter Selektionsdruck stehende Loci hatten in beiden untersuchten Fällen eine starke Präferenz in Richtung Homozygotie und Erhalt der Prototrophie. Für nicht unter Selektionsdruck stehende Loci konnte gezeigt werden, dass die Hälfte der untersuchten Kolonien dem Elternstamm 1 glich, während die andere Hälfte dem Elternstamm 2 glich. Auch hier waren die Zellen nur in seltenen Fällen homozygot.