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Introduction:
The evolutionary patterns of symbiotic organisms are inferred using cophylogenetic methods. Congruent phylogenies indicate cospeciation or host-switches to closely-related hosts, whereas incongruent topologies indicate independent speciation. Recent studies suggest that coordinated speciation is a rare event, and may not occur even in the highly specialized associations. The cospeciation hypothesis was mainly tested for free-living mutualistic associations, such as plant-pollinator interactions, and host-parasitic systems but was rarely tested on obligate, mutualistic associations involving intimate physiological interactions. Symbionts with lower partner selectivity may not experience coordinated speciation due to frequent switching of partners. On the other hand, symbionts with high partner selectivity may influence each other’s evolution owing to the highly interdependent lifestyles. Symbiont association patterns are also influenced by habitat and it has been proposed that symbiotic interactions are stronger in warm regions as compared to cooler regions (also referred as latitudinal gradient of biotic specialization). This hypothesis however, has recently been challenged and it has been suggested that a gradient of biotic specialization may not exist at all. Reliable species concepts are a prerequisite for understanding the association and evolutionary patterns of symbiotic organisms. The species concepts of many groups traditionally relied on the morphological species concept, which may not be adequate for distinguishing species due to the: i) homoplasious nature of morphological characters, an due to the inability to distinguish cryptic species. Thus phylogenetic species concept along with coalescent-based species delimitation approaches, which utilize molecular data for inferring species boundaries have been used widely for resolving taxonomic relationships. Lichens are obligatory symbiotic associations consisting of a fungal partner (mycobiont) and one or more photosynthetic partners, algae, and/or cyanobacteria (photobionts). I used the lichen forming fungal genus Protoparmelia as my study system, which consists of ~25-30 previously described species inhabiting different habitats, from the arctic to the tropics. This makes Protoparmelia an ideal system to explore the association and evolutionary patterns across different macrohabitats.
Objectives:
The objectives of this thesis were to 1. Elucidate the phylogenetic position of Protoparmelia within Lecanorales, and infer the monophyly of Protoparmelia; 2. Understand species diversity within Protoparmelia s.str. using coalescent-based species delimitation approaches; and 3. To identify the Trebouxia species associated with Protoparmelia using phylogenetic and species delimitation approaches and to infer the association and cophylogenetic patterns Protoparmelia and Trebouxia in different macrohabitats.
Results and discussion:
Chapter 1: Taxonomic position of Protoparmelia
In the first part of this study I explored the taxonomic position of Protoparmelia within the order Lecanorales. Overall this study included 54 taxa from four families, sequenced at five loci (178 sequences). I found Protoparmelia to be polyphyletic and sister to Parmeliaceae.
Chapter 2: Multilocus phylogeny and species delimitation of Protoparmelia spp.
In this part of the study, I identified and delimited the Protoparmelia species forming a monophyletic clade sister to Parmeliaceae i.e., Protoparmelia sensu stricto group, based on the multilocus phylogeny and coalescent-based species delimitation approaches. I included 18 previously described and three unidentified Protoparmelia species, which represents ~70% of the total described species, and 73 other taxa, sequenced at six loci. I found that the sensu stricto group comprised of 25 supported clades instead of 12 previously described Protoparmelia species. I tested the speciation probabilities of these 25 clades using species delimitation softwares BP&P and spedeSTEM. I found nine previously unrecognized lineages in Protoparmelia and I propose the presence of at least 23 species for Protoparmelia s.str., in contrast to the 12 described species included in the study.
Chapter 3: Association and cophylogenetic patterns of Protoparmelia and its symbiotic partner Trebouxia
...
In the dentate gyrus (DG) of the mammalian hippocampus, neurogenesis continues to take place throughout an organism’s life. Adult neurogenesis includes proliferation and differentiation of neural stem cells into dentate granule cells (GCs) that mature and integrate into the existing cellular network. This thesis work presents a novel approach that enables longitudinal examination of living postnatally generated GCs in their endogenous niche by using retroviral (RV) labeling in organotypic entorhino-hippocampal slice cultures (OTCs). Older GCs were fluorescence-labeled with an adeno-associated virus controlled by the synapsin 1 promoter (AAV-Syn). The combination of time-lapse imaging and 3-D reconstruction of newborn developing GCs and older, more mature GCs enabled comparative analyses of dendritic growth and cellular dynamics as well as investigations of spine formation and the establishment of synaptic contacts.
Postnatal neurogenesis was studied in the mouse and rat DG in vivo by analysis of the distribution of chemical neuronal maturation markers doublecortin (DCX) and calbindin in combination with the GC marker Prox1 between P7 and P42. The marker expression patterns at different time points indicated that the number of mature GCs increased gradually over time and that young, immature GCs were added to the inner layers of the granule cell layer (GCL), as is the case in the adult brain. The most substantial shift in GC maturation took place between P7 and P14, though GCs in the rat DG matured faster (i.e. by ~5 days) than GCs in the mouse. Immunocytochemical in vitro analysis in OTCs at DIV 7, 14, and 28 exhibited a distribution of marker expression over time that was comparable to in vivo, though the number of DCX-expressing GCs was low at DIV 28, indicating a considerable decrease in neurogenesis rate over time in the OTC. Nevertheless, RV-labeling of newborn GCs at DIV 0 yielded successful visualization and enabled time-lapse imaging of complete developing GCs up to 4 weeks after mitosis. During the second week of development, newborn GCs exhibited a high level of structural dynamics, including extension and retraction of dendritic segments. In the third week, newborn GCs displayed high dendritic complexity which was followed by pronounced dendritic pruning. Finally, a phase of structural stabilization and local refinement could be observed during the fourth week. Older AAV-Syn-labeled GCs did not exhibit such dynamic structural remodeling. Anterograde tracing of entorhinal projection fibers using the biotinylated dextran amine Mini Ruby showed innervation of the outer molecular layer (OML) by entorhinal axons at early time points, i.e. DIV 8 when newborn GCs started to extend dendrites into the ML, as well as at DIV 20 when RV-labeled GCs exhibited elaborate dendritic trees with processes in the OML intermingling with entorhinal fibers. This shows that newborn GCs in the OTC grow into an area of existing entorhinal axon terminals, which is highly similar to the situation in the adult brain. Hence, the results show that postnatal neurogenesis can be studied effectively in the OTC system as a model of adult neurogenesis. The first appearance of spine-like protrusions in newborn GCs was observed two weeks post RV injection. Ultrastructural electron-microscopic images revealed that spines established synaptic contacts with axonal boutons. These findings suggest that newborn GCs are successfully integrated into the existing cellular circuitry in the OTC system. The high level of structural flexibility found in this study might be a necessary requisite of new neurons for successful dendritic maturation and functional integration into a neuronal network. Thus, live imaging of postnatally born GCs in the OTC appears as a useful novel approach to elucidate the mechanisms that affect cellular dynamics of neurogenesis.
Embryonale Stammzellen (ESCs) sind ein wichtiges Werkzeug zur Untersuchung der frühen embryonalen Entwicklung. ESCs können mit Hilfe neuer Technologien zur Modifikation von Genen (z.B. mit dem CRISPR/Cas9 System) genetisch manipuliert werden. Daraus resultierende „knockout“ ES Zelllinien können helfen, die physiologische Rolle von Proteinen während der Differenzierung zu verstehen.
Transkriptionsfaktoren, die schnell und spezifisch Signalwege regulieren, spielen während der Embryonalentwicklung und während der Differenzierung von ESCs in vielen verschiedenen Zelltypen eine essentielle Rolle. Der Transkriptionsregulator „Far Upstream Binding Protein 1“ (FUBP1) ist ein Protein, welches eine ganz bestimmte einzelsträngige DNA Sequenz, das „Far Upstream Sequenz Element“, erkennt, bindet, und dadurch Gene wie z.B c-myc oder p21 reguliert. Mit der Entwicklung zweier Fubp1 Genfallen Mausstämme (Fubp1 GT) sollte die Frage nach der physiologischen Funktion von FUBP1 beantwortet werden. Die homozygoten FUBP1-defizienten GT Embryonen sterben im Mutterleib ungefähr am Tag E15.5 der Embryonalentwicklung. Sie sind kleiner als Wildtypembryonen und zeigen ein anämisches Aussehen. Daher wurden diese Mausmodelle hinsichtlich der Hämatopoese untersucht, die zu diesem Zeitpunkt vor allem in der Leber stattfindet. Es konnte eine signifikante Reduktion der hämatopoetischen Stammzellen (HSCs) festgestellt werden und zusätzlich war die langfristige Repopulation der FUBP1-/--Stammzellen im Knochenmark in Transplantationsexperimenten reduziert.
In der vorliegenden Arbeit wurde die Rolle von FUBP1 in einem weiteren Stammzellsystem analysiert und gleichzeitig seine Bedeutung in anderen Zelltypen der frühen Embryonalentwicklung untersucht.
Die Quantifizierung der FUBP1 Expression in den ESCs und während der Differenzierung zu sogenannten `embryoid bodies` (EBs) zeigten eine starke Expression auf mRNA- und auf Proteinebene. Nach der erfolgreichen Optimierung der Differenzierung von murinen ESCs wurden Fubp1 „knockout“ (KO) ESC Klone mit Hilfe der CRISPR/Cas9 Technologie etabliert. Die molekularbiologische Analyse der ESCs zeigte eine signifikante Erhöhung der Oct4 mRNA-Expression, während Nanog und die Differenzierungsmarker Brachyury, Nestin und Sox17 unverändert und in vergleichbarer Menge zu den Kontrollen vorhanden waren. Während der Differenzierung der Fubp1 KO Klone zu EBs zeigte sich eine signifikante Reduktion mesodermaler Marker wie Flk-1, SnaiI, Snai2, Bmp4 und FgfR2. Mit Hilfe durchflusszytometrischer Analysen bestätigte sich die verzögerte Bildung mesodermaler Zellen (Brachyury- und Flk-1-exprimierender Zellen) in den Fubp1 KO Klonen der EBs an den Tagen 3, 4 und 5 nach Beginn der Differenzierung.
Die Anwendung einer Ko-Kultivierung auf OP9 Zellen zur Differenzierung der ESCs in hämatopoetische Linien sollte zeigen, ob der Fubp1 KO ESCs ein Defekt in der frühen Entwicklung hämatopoetischer Stammzellen zu beobachten ist. Erneut konnte am Tag 5 der ESC-Differenzierung in der OP9 Ko-Kultur eine signifikante Reduktion der mesodermalen (Flk-1+) Zellen festgestellt werden. Die weitere Differenzierung zu hämatopoetischen CD45+ Zellen zeigte jedoch keinen Unterschied im prozentualen Anteil CD45+ Zellen am Tag 12 der Differenzierung. Auch die gezielte Differenzierung zu erythroiden Zellen durch Zugabe des Zytokins EPO zum Medium zeigte keinen signifikanten Unterschied im Differenzierungsgrad der erythroiden Zellen zwischen Kontroll- und Fubp1 KO Klonen.
In weiteren Experimenten habe ich in dieser Arbeit die Expression von FUBP1 in WT Embryos an den Tagen E9.5 und E13.5 der Embryonalentwicklung untersucht. Hierbei zeigte sich in beiden Entwicklungsstadien eine immunhistochemische Anfärbung von FUBP1 in den meisten Zellen des Embryos. Die Annahme, dass die Abwesenheit von FUBP1 in der Embryonalentwicklung zu verstärkten apoptotischen Vorgängen führen könnte und gleichzeitig die massive Expansion von Zellen gestört sein könnte wurde mit Hilfe immunhistochemischer Färbung von „cleaved Caspase 3“ (Apoptosemarker) und „Ki-67“ (Proliferationsmarker) in den homozygoten Fubp1 GT Embryos an den Tagen E9.5 und E13.5 nicht bestätigt.
Die Ergebnisse dieser Arbeit lassen darauf schließen, dass die Regulation von Apoptose und Proliferation durch FUBP1 während der Embryonalentwicklung nicht die Hauptrolle von FUBP1 darstellt. Es zeigte sich jedoch, dass FUBP1 als Transkriptionsregulator wichtig für die mesodermale Differenzierung von ESCs ist. Zu beobachten war, dass es in den FUBP1-defizienten ESCs zu einer Verzögerung der mesodermalen Differenzierung kommt. Es konnte bereits gezeigt werden, dass FUBP1 essenziell für die Selbsterneuerung von HSCs ist. Dies macht deutlich, dass FUBP1 neben der Proliferation und Apoptose ein breiteres Spektrum an Signalwegen reguliert, die für Stammzellen und deren Differenzierung von Bedeutung sind.
BACKGROUND: Acetogenic bacteria are able to use CO2 as terminal electron acceptor of an anaerobic respiration, thereby producing acetate with electrons coming from H2. Due to this feature, acetogens came into focus as platforms to produce biocommodities from waste gases such as H2+CO2 and/or CO. A prerequisite for metabolic engineering is a detailed understanding of the mechanisms of ATP synthesis and electron-transfer reactions to ensure redox homeostasis. Acetogenesis involves the reduction of CO2 to acetate via soluble enzymes and is coupled to energy conservation by a chemiosmotic mechanism. The membrane-bound module, acting as an ion pump, was of special interest for decades and recently, an Rnf complex was shown to couple electron flow from reduced ferredoxin to NAD+ with the export of Na+ in Acetobacterium woodii. However, not all acetogens have rnf genes in their genome. In order to gain further insights into energy conservation of non-Rnf-containing, thermophilic acetogens, we sequenced the genome of Thermoanaerobacter kivui.
RESULTS: The genome of Thermoanaerobacter kivui comprises 2.9 Mbp with a G+C content of 35% and 2,378 protein encoding orfs. Neither autotrophic growth nor acetate formation from H2+CO2 was dependent on Na+ and acetate formation was inhibited by a protonophore, indicating that H+ is used as coupling ion for primary bioenergetics. This is consistent with the finding that the c subunit of the F1FO ATP synthase does not have the conserved Na+ binding motif. A search for potential H+-translocating, membrane-bound protein complexes revealed genes potentially encoding two different proton-reducing, energy-conserving hydrogenases (Ech).
CONCLUSIONS: The thermophilic acetogen T. kivui does not use Na+ but H+ for chemiosmotic ATP synthesis. It does not contain cytochromes and the electrochemical proton gradient is most likely established by an energy-conserving hydrogenase (Ech). Its thermophilic nature and the efficient conversion of H2+CO2 make T. kivui an interesting acetogen to be used for the production of biocommodities in industrial micobiology. Furthermore, our experimental data as well as the increasing number of sequenced genomes of acetogenic bacteria supported the new classification of acetogens into two groups: Rnf- and Ech-containing acetogens.
Phenology is the study of periodic life cycle events of living organisms and how these are influenced by environmental factors. Late phenological phases such as the timing of seed release and subsequent seed dispersal considerably affect ecology and evolution in plants. Since plants are mostly sessile organisms, seed dispersal is a crucial life cycle event for the ecology and evolution of plants. In fact, long-distance seed dispersal (LDD) is a very complex process in plant biology and significantly shapes the spatial and temporal dynamics of plant populations. For example, wind dispersal in plants is influenced by a variety of factors such as plant traits, habitat type and environmental conditions (e.g. wind speed). Considering the variability of wind conditions throughout the year, the timing of seed release and dispersal is known to have considerable effects on LDD. Even though late phenologies such as ripening duration and timing of seed release and subsequent dispersal are vital in estimating ecologically highly relevant LDD, these phenologies are not appropriately addressed in ecological research. The aim of this thesis is to gain insights into the factors that shape late plant phenologies. In particular, we address the following questions: which ecologically or evolutionary parameters drive the ripening process of plant species? How does the seasonal variability of wind affect the seed release phenology of plant species? How do these factors interact for plant species in different habitat types?
In order to address these questions, we applied different methodological approaches, ranging from fieldwork and monitoring phenology to computational simulation studies and statistical modeling. To study the ripening process of species, we monitored the flowering, ripening and seed release phenology of more than 100 Central European plant species. We conducted computational simulation studies for estimating LDD by wind to study the phenology of seed release and the parameters determining LDD by wind. In conjunction with phenological data from literature, we used the obtained simulation results to investigate evidence for the existence of phenological adaptations towards LDD in 165 plant species. Further, we used the results from simulation studies of LDD by wind to disentangle the effects of species, habitat types and meteorological conditions and their interactions on the spatial spread of plant species.
The results of the relationship between plant traits, phylogeny, the ripening process and climatic factors provide insights into the basic understanding of the ripening process of plants. We identified ecological factors that shape species’ ripening phenology and seed release timing. In particular, we suggest that the species’ seed weight, life form and phylogeny shapes ripening and seed release phenology. With the statistical models on species’ temperature demands for reproduction, we introduce data that that are well suitable for parametrization and further development of plant dispersal models. The results from the simulation study based on a seasonal perspective showed that heavier seeded tree species with medium wind dispersal potential (including genera Abies, Acer, Fraxinus and Larix) have a clear synchronisation of seed abscission with periods favouring LDD. These species, which are both ecologically and economically important, showed significant synchronisation of the highest rate of seed release with high wind-speed that promoted LDD by wind in wintertime. For the tree species mentioned, we suggest strong seasonal synchronisation as evidence for phenological adaptations in order to match favourable conditions during seed release. With a closer look at the wind conditions that promote LDD by wind, our results showed considerable differences in how specific wind conditions affect LDD in different species and habitat types. We suggest that LDD by wind in species from open habitats with high wind dispersal potential is likely to be driven by thermal updrafts that are mainly driven by the sun providing energy to the ground. By contrast, LDD of heavier-seeded species from open and forested habitats is more likely to be driven by storms that produce shear-driven turbulence. The results from this thesis contribute to an increased understanding of the complete dispersal process of plants and to making more realistic projections of (future) plant distribution.
The results obtained on factors driving ripening and release phenology provide valuable insights into their ecological and phylogenetic factor constraints. The implementation of more realistic assumptions in assessing species’ dispersal potential throughout the year could help considerably in improving landscape management (e.g. timing of mowing) and in the conservation of plant populations. The evidence found for phenological adaptations towards LDD in plants is an important step in understanding the evolutionary basis of LDD in these species.
Ischemic injuries of the cardiovascular system are still the leading cause of death worldwide. They are often accompanied by loss of cardiomyocytes (CM) and their replacement by non-functional heart tissue. Cardiac fibroblasts (CF) play a major role in the recovery after ischemic injury and in the scar formation. In the last few years researchers were able to reprogram fibroblasts into CM in vitro and in murine models of myocardial infarction using various protocols including a cocktail of microRNAs (miRs). These miRs can target hundreds of messenger RNAs and inhibit their translation into proteins, potentially regulating multiple cellular signaling pathways. Because of this, there has been a rising interest in the use of miRs for therapeutic purposes. However, as different miRs have different effects in different cells, there is the danger of causing serious side effects. These could be alleviated by enacting a cell-specific transport of miRs, for example by using aptamers. Aptamers are usually short strands of DNA or RNA, which can fold into a specific three-dimensional confirmation which allows them to bind specifically to target molecules. Aptamers are commonly selected from a large library for their ability to bind to target molecules using a procedure called SELEX. Aptamers have already been used to transport miRs into cancer cells.
In this thesis, we first established the transport of miRs into cells of the cardiovascular system using aptamers. MiR-126 is an important part of the signaling in endothelial cells (EC), protects from atherosclerosis and supports angiogenesis, which is why we chose it as a candidate to transport into the vasculature. We first tested two aptamers for their ability to internalize into EC and fibroblasts. Both the aptamer for the ubiquitously expressed transferrin receptor (TRA) and a general internalizing RNA motif, but not a control construct, could internalize efficiently into all cell types tested. We then designed three chimeras (Ch) using different strategies to connect TRA to miR-126. While all chimeras could internalize efficiently, only Ch3, which connects TRA to Pre-miR-126 using a sticky bridge structure, had functional effects in EC. Ch3 reduced the protein expression of VCAM-1 in EC and increased the VEGF induced sprouting of EC in a spheroid-sprouting assay. Treatment of breast cancer cells with Ch3 emulated the effects of treatment with classical miR-126-3p and miR-126-5p mimics. In the SK-BR3 cell line Ch3 and miR-126-3p reduce the viability of the cells while they reduce recruitment of EC by the MCF7 cell line. miR-126-5p had no apparent effect in the SK-BR3 line, but increased viability of MCF7 cells, as did Ch3. This implies that Ch3 can be processed to both functional miR-126-3p and miR-126-5p in treated cells.
We were unable to achieve a reprogramming of adult murine cardiac fibroblasts into cells resembling CM using the cocktail of 4 miRs. This indicates that the miR-mediated transdifferentiation is only possible in neonatal fibroblasts. The effects in mice after an AMI might possibly be caused by an enhanced plasticity of fibroblasts in and close to the infarcted area.
We also screened to find aptamers specifically binding to cells of the cardiovascular system. We used two oligonucleotide libraries in a cell-SELEX to select candidates which bind to CF, but not EC. We observed that only the library which contains two randomized regions of 26 bases showed an enrichment of species binding to fibroblasts. We then sequenced rounds 5-7 of the SELEX and analyzed the data bioinfomatically to select 10 candidate aptamers. All candidates showed a strong binding not only to CF, but also EC. This indicates that the selection pressure against species binding to EC was not high enough and would have to be increased to find true CF-aptamers. Four promising candidates were also analyzed for their potential to be internalized and we surprisingly found that all of them were internalized by EC and CF more efficiently than TRA. The similar behavior of the candidates implies that they possibly share a ligand, which is expressed both by EC and CF, but more prominently by the latter.
This work demonstrates the possibility of using aptamers to transport miRs into cells of the cardiovascular system. It also shows that it is possible to select aptamers for non-cancerous mammalian cells, which has not been done before. It is reasonable to assume that a refinement of the cell-SELEX will allow selection of cell-specific aptamers. Due to the failure of reprogramming of adult fibroblasts into induced cardiomyocytes we were unable to test whether a miR-mediated reprogramming might be inducible using aptamer transported-miRs. Ultimately, aptamer mediated transport of miRs is a feasible and promising therapeutic option for the treatment of cardiovascular diseases and other disorders like cancer.
Reading is an essential ability to master everyday life in our society. The ability to read is based on specific connections between brain regions involved in the reading process – so-called cortical networks for reading. These cortical networks for reading allow us to learn the correct identification of visual words. The use of visual words is based on knowledge about the orthography (lexical) and the meaning of words (semantic). This knowledge must be acquired by beginning readers (first grader), i.e. beginning readers learn in a first step to link letters to a whole word and in a second step associate this whole word with meaning. To retrieve this knowledge during visual word recognition (VWR) a cortical network for lexical-semantic process must be activated. However, it is currently unclear whether beginning readers and reading experts activate the same neuronal network during VWR. Therefore, the aim of this thesis was to investigate the question whether beginning readers (first grader, children) and reading experts (adults) use different cortical networks for the lexical-semantic processing in VWR.
To address this question we recorded electroencephalographic (EEG) activity during VWR in children and adults. Children and adults were instructed to read a visualizable word to compare this word with a following picture stimulus. The first part of this thesis is concerned with the analysis of ERPs for visual word recognition in children and adults at sensor level. For both groups we observed the typical ERP components P100 and N170 for visual word recognition. These components differed in amplitude and time course between both groups. The second part of this thesis investigated the neuronal generators (brain areas) of ERPs during VWR and possible differences between children and adults at source level. We observed a high overlap in brain areas involved during VWR in children and adults. However, the brain areas differed in activation and time course between children and adults. Finally, the third and most important part of the thesis investigated the question whether children and adults use different cortical networks for the lexical-semantic processing in VWR over time. To address this question Dynamic Causal Modeling (DCM) and Bayesian model comparison were used. We compared nine biologically plausible cortical network models underlying the ventral lexical-semantic path in VWR. In addition, increasing time intervals were used to consider possible changes of network structure during VWR. The network models included eight brain regions (four bilateral pairs) involved in the lexical-semantic processing in VWR: occipital cortex (OC), temporo-occipital part of inferior temporal gyrus (ITG), temporal pole (TP), and inferior frontal gyrus (IFG). In almost all time intervals we found evidence that children and adults use the same cortical networks for the lexical-semantic processing in VWR. However, we found differences between adults and children in the connection strengths of the favoured model. Interestingly, we found a stronger direct connection from OC to IFG in adults compared to children.
In conclusion, our results suggest that children and adults activate largely the same lexical-semantic networks during VWR over time. This supports the notion that children and adults use the same biological fiber connections for VWR. However in contrast to children, adults showed increased use of the shortcut pathway from OC to IFG. The increased use of the shortcut pathway from OC to IFG in adults can be interpreted as consequence of learning. Learning causes in accordance with the Hebbian learning rule (“neurons that fire together, wire together” (Hebb, 1949)) synaptic change. Consequently the frequent coactivation of the input and output stage of OC and IFG during the lexical-semantic process facilitates the stronger direct connection between both brain areas. The stronger direct connection from OC to IFG most likely allows adult reading experts to speed up the lexical-semantic process during VWR. Accordingly, we conclude that the stronger direct connections from OC to IFG in adults compared to children underlay the different reading capabilities in both groups.
Termites are important ecosystem engineers of the savanna biome, with the large mounds of fungus-cultivating termites being sources of habitat heterogeneity and structural complexity in African savanna landscapes. Studies from different localities throughout Africa have shown that termite mounds have a strong influence of diversity and composition of plant communities. However, most research has been conducted only at the local scale, and integrating knowledge across Africa is hampered by different methodology of studies and differing environmental context. Little is known about the variation in vegetation composition on termite mounds compared to the surrounding savanna at the regional scale and at the landscape scale, and the main determinants of plant communities on mounds are yet to be ascertained.
This thesis aimes at better understanding the influence of termite mounds on vegetation compared to the surrounding savanna across spatial scales. Three research projects analyse vegetation data and soil data from paired mound and savanna plots in West Africa. The first project examines the influence of termite-induced heterogeneity on plant diversity and vegetation composition at a regional scale, following a bioclimatic gradient from the Sahel of Burkina Faso to the Sudanian vegetation zone in North Benin. The second Project analysed variation of vegetation on and off mounds at the landscape scale in Pendjari National Park, North Benin. The third is a monitoring study over the course of two years, exploring dynamics of juvenile woody plant communities on mounds and in the surrounding savanna at a local scale. The thesis thus provides the first comparative quantitative analysis across scales of mound and savanna vegetation and the drivers of the mound–savanna difference in vegetation.
Synthesizing across scales, its results confirm that termite mounds strongly contribute to savanna plant diversity, even though mounds are not generally more species rich than the surrounding savanna. Variation in mound vegetation is much higher along climatic and soil gradients than previously acknowledged. Mound vegetation differs from the surrounding savanna in the whole study area and in each sampled savanna type, with the strongest differences occurring at the most humid study sites. A large proportion of the differences between mound and savanna vegetation is explained by clay enrichment and related soil factors, such as cation concentrations. Plants on mounds thus benefit from favourable soil conditions, including higher fertility and higher water availability, which is also mirrored by the higher abundance and basal area of juvenile woody plants found on mounds. The variation in mound vegetation between study sites across scales results in part from local differences in soil composition and from climatic differences that influence the regional distribution of species. Different sets of characteristic mound species are identified in each project. Specific plant families and traits like succulency, lianescence, and adaptations to zoochory are found to be overrepresented in mound communities.
In addition to the findings in this thesis, remaining parts of the variation in mound vegetation between study sites could likely be explained by investigating further factors. Specifically, mound vegetation depends on habitat context, which includes available species pools, spatial distribution of mounds, biotic interactions with dispersers and herbivores, fire, and also anthropogenic influence. The high proportion of species with adaptations to zoochory found on mounds, for example, indicates that animal dispersers should be of particular importance for vegetation on termite mounds. Herbivory and fire regime, which are known to contribute to the diversity and community composition of the mound–savanna system, also show strong local variation, not least because of anthropogenic influence.
In conclusion, termite mounds play a crucial role in maintaining heterogeneity and plant diversity in the savanna across scales. Ecosystem services provided by termites, especially considering long-term effects on soil fertility and ecosystem resilience, are most likely undervalued. Mounds should be considered in management plans from local to regional, transnational scales as a matter of course, accompanied by further research on the role of termite mounds in savanna ecology on a longer temporal scale. The research presented here thus provides a basis for future studies on termite mound vegetation that should specifically consider the biotic and abiotic context of the mound–savanna system.
Vascular tumors associated with chronic B. henselae infections are unique examples of infection-associated pathological angiogenesis. The chaotic vascular architecture and prominent myeloid infiltrate of B. henselae induced vascular lesions show many similarities with malignant tumors.
In human cancers infiltrating myeloid cells play a decisive role in tumor progression and vascularization. In particular, tumor associated macrophages (TAMs) transform the tumor microenvironment, drive tumor invasion and vascularization through secretion of pro-angiogenic and immune modulatory cytokines and participation in matrix remodeling processes.
Myeloid angiogenic cells (MACs) are a subset of circulating myeloid progenitors with important roles in regenerative and pathological angiogenesis and a critical involvement in tumor vascularization. The phenotypic plasticity and importance of MACs in pathological angiogenic processes, position these cells as key potential players in B. henselae associated vascular tumor formation.
To investigate the possible role of MACs in B henselae induced pathological angiogenesis, the objective of this study was to examine the interaction of B. henselae with MACs and determine how this may affect their angiogenic capacity.
Building on previous work by Mӓndle (2005) this study has demonstrated that MACs are susceptible to infection with B. henselae and reside in intracellular vacuoles. As in endothelial cells, infection of MACs with B. henselae was associated with inhibition of apoptosis and activation of endogenous angiogenic programs including activation of the angiogenic transcription factor HIF-1.
In addition to angiogenic re-programming on a molecular level B. henselae infection increases MAC functional angiogenic capacity. B. henselae infected MACs were found to integrate into growing endothelium and increase the rate of angiogenic sprouting in a paracrine manner.
When cultured in a Matrigel capillary formation assay, infected MACs were also found to form networks of capillary-like structures that were stable over long periods of time. The B. henselae pathogenicity factor BadA was essential for the induction of this vascular mimicry phenotype as well as the activation of HIF-1 in infected MACs indicating that this factor may play an important role in MAC angiogenic re-programming.
Examination of infected MACs via FACS analysis, cytospin immunohistochemistry and qRT-PCR revealed that endothelial differentiation does not play a role in the B. henselae induced pro-angiogenic phenotype. Instead, MACs were shown to be myeloid in phenotype displaying typical macrophage markers which were upregulated upon B. henselae infection and maintained over long-term culture.
The increased angiogenic activity of B. henselae infected MACs was found to be associated with a broad phenotypic reprogramming in infected cells. In particular, gene expression programs related to angiogenesis, structural organization, apoptosis, sterol metabolism and immune regulation, were upregulated. Further examination of microarray gene expression profiles revealed that B. henselae infected MACs display a predominantly M2 anti-inflammatory macrophage activation status.
Finally, examination of the paracrine microenvironment created by B. henselae infected MACs revealed a diverse cytokine secretion profile dominated by inflammatory-angiogenic cytokines and matrix remodeling elements and lacking expression of some of the most important cytokines involved in the expansion of the inflammatory response. This B. henselae induced activation status was demonstrated to be distinct from the general inflammatory response induced by E. coli LPS treatment.
Comparison of B. henselae infected MACs to TAMs revealed many parallels in functional and phenotypic characteristics. Both TAMs and B. henselae infected MACs demonstrate increased angiogenic capacity, invasive, and immune modulatory phenotypes and the ability to participate in the formation of vascular mimicry phenotypes under angiogenic pressure. Furthermore, the pro-angiogenic paracrine microenvironment created by B. henselae infected MACs shows many similarities to the TAM-created tumor-microenvironment.
In conclusion, these investigations have demonstrated that the infection of MACs with B. henselae results in the phenotypic re-programming towards TAM-like cells with increased pro-angiogenic, invasive and immune-modulatory qualities. The results of this study elucidate new aspects of B. henselae pathogenicity in myeloid cells and highlight the role of these cells as paracrine mediators of B. henselae induced vascular tumor formation. In addition, these findings demonstrate that manipulation of myeloid cells by pathogenic bacteria can contribute to microenvironmental regulation of pathological tissue growth and suggest parallels underlying bacterial infections and cancer.
The brain vascular system is composed of specialized endothelial cells, which regulate the movement of ions, molecules and cells from the blood lumen to the central nervous system (CNS). Endothelial cells in the brain form the blood-brain barrier (BBB) that is essential to maintain the brain homeostasis and protect the CNS from pathogens and toxins for a proper neurological function. Endothelium together with other cellular components such as pericytes, astrocytes and the basement membrane, forms the neurovascular unit (NVU), the structural unit of the BBB. Breakdown of the BBB occurs in various neurological disorders, leading to edema and neuronal damage. Therapeutic strategies focusing on factors that regulate the permeability of the BBB may help to improve neurological disorders and facilitate drug delivery to the brain.
Angiopoietins (Ang) are potential candidates for therapeutic targeting the BBB due to their role in regulating the vascular permeability in periphery. They are key growth factors that control angiogenesis and vessel maturation. Ang-1 and Ang-2 possess similar binding affinities to the Tie2 receptor tyrosine kinase, which is almost exclusively expressed on endothelial cells. Ang-1 is expressed in smooth muscle cells and pericytes, and binds in a paracrine manner to Tie2. This results in phosphorylation of the receptor and induction of downstream signaling pathways leading to vessel maturation via pericyte recruitment and blood vessel stabilization. Ang-2, on the other hand, is stored in Weibel Palade bodies in endothelial cells and is released upon inflammatory or angiogenic stimuli. Therefore, in mature, stabilized blood vessels, Ang-2 expression is low. Increased level of Ang-2 is only observed during development or in pathology such as ischemia, cancer and inflammation. When Ang-2 is released, it acts in an autocrine manner and interferes with Tie2 phosphorylation in a context-dependent way. Antagonizing the receptor results in de-stabilization of the vessels, often accompanied by reduced numbers of pericytes leading to myeloid cell infiltration. In conjunction with the vascular endothelial growth factor (VEGF), Ang-2 contributes to blood vessel sprouting, whereupon in absence of VEGF it promotes vessel regression. ...
Cyanobacteria belong to the most widely distributed microorganisms in the biosphere and contribute significantly to global primary production. Their metabolism is based on oxygenic photosynthesis and some cyanobacteria can fix elemental nitrogen. Obligate photosynthetic diazotrophs have a particularly high iron demand in comparison to heterotrophic bacteria. Nevertheless the understanding of iron acquisition in cyanobacteria is just beginning to emerge. Iron acquisition in bacteria comprises highly specific transport of siderophore-iron complexes over the outer membrane by TonB-dependent transporter (TBDT). The transport itself is active and energized by a multi-complex localized to the inner membrane termed the TonB-system (TonB-ExbB-ExbD). The siderophore-iron complexes are further transported into the cytosol by a binding protein dependent ABC-transporter. Cyanobacterial iron acquisition response has most extensively been studied in unicellular, non-siderophore synthesizing cyanobacteria in the genus Synechococcus and Synechocystis. Anabaena sp. PCC 7120, however, is a different model organism as it is a freshwater living, siderophore synthesizing and, truly multicellular microorganism. It can be assumed that siderophore synthesis and siderophore-dependent iron uptake are tightly coordinated processes, therefore Anabaena represents a different model organism as compared to non-siderophore producing cyanobacteria. Moreover the surprisingly abundant protein family of 22 putative TBDTs in Anabaena indicates a high complexity of TonB-dependent uptake systems. Sequence similarity analysis revealed 4 putative tonB encoding genes (alr0248, all3585, all5036, alr5329), 2 putative exbB-exbD encoding gene cluster (alr0643-alr0644, all5047-all5046), one single standing putative exbB encoding gene (alr4587) and several hypothetical binding-protein-dependent ATP binding cassette (ABC)-type transporter encoding genes (fhu-, fec- and fut-type transporter).
In this study the respond of the predeicted systems to iron-limiting conditions was analysed by qRT-PCR. The expression analysis revealed on the one hand an enhanced transcription of all5036 (tonB3), all5047-all5046 (exbB3-exbD3) and the fhu-like encoding genes (all0387-all0389) under iron-limitation and at the same time down-regulation of expression under enhanced iron concentrations. Summerizing the transcription profile of the tonB3- and the fhu-system showed an expression regulated by iron-availability. To further characterize the role of TonB3-, ExbB3- and the Fhu-system, mutants thereof were generated. None of the generated mutants, except for the exbB3 mutant, could be fully segregated, suggesting an essential character of the genes. Characterization of the mutants revealed enhanced expression of iron-starvatrion indicator genes (isiA, fhuA) and altered growth of the tonB3 mutant under iron-limiting conditions. The iron starvation phenotype was further strengthened by enhanced siderophore secretion in the tonB3, exbB3 and fhuC mutants. Taken as a whole the results strongly indicate involvement of the tonB3- and the fhu-system in siderophore-dependnet iron uptake in Anabaena.
Investigation of the tonB2 (all3585) mutant under iron and citric acid limitation resultated in altered growth of the mutant. However, growth could be restored by addition of iron chlorid. Therefore a connection of the TonB2 protein to iron uptake is implied and further supported by ressitance to toxic iron concentrations. Lastly, mutation of tonB1 (alr0248) reuslted in insensibility to toxic manganese and copper concentrations and macrolid antibiotics. The altered permeability of the outer membrane may be a result of decreased expression of seven putative porin encoding genes in the mutant. A possible role in transcriptional regulation of porin expression is discussed.
Snake bite envenoming often results in disability or death of breadwinners of poor families in the rural tropics and the subtropics of Nepal. Identification of the medically relevant snake species, circumstances of venomous snake bites, prehospital care of their bites and human responses to snakes and snake bite is, therefore, crucial to enable victims or first aider to select the appropriate first aid measures, physicians to anticipate complications and to use appropriate treatment protocols as well as the local community to implement prevention strategies. Inadequate educational gaps exist in Nepal and hinder identification of snakes involved in bites. To fill this gap, I aim to provide an evidence-based list of medically relevant snake species. Snake specimens brought by patients bitten or their attendants from the tropical and subtropical regions in southeastern, southcentral, and southwestern Nepal to snake bite treatment centres over a period from 2010 through 2014, were taxonomically identified and medical records of envenoming were evaluated.
In Nepal, the epidemiology of snake bite is poorly known. Here I describe the ecological circumstances of proven krait (Bungarus spp.) and Russell´s Viper (Daboia russelii) bites to elucidate and examine, whether environmental circumstances or human behaviour contributed to envenoming. In a cross-sectional study, data about prehospital care, environmental circumstances of 46 krait and 10 Russell´s Viper bites were evaluated. Patients were interviewed using structured interview forms. Snake bite prone communities were surveyed to test people´s knowledge on snakes and their attitude towards venomous snakes in general.
Of 349 snakes involved in bites, 199 (57%) specimens were found to be medically relevant venomous snakes that included 11 species belonging to six genera and two families. Among them, Naja naja (n = 76, 22%), Bungarus caeruleus (n = 65, 19%) and Trimeresusurs albolabris (n = 10, 3%) were the most widely distributed snakes. Daboia russelii (n = 10, 3%) was found to be restricted to the southwestern part of Nepal. For B. walli, a previously poorly known species, 13 voucher specimens represent the first country records of this species as well as the first documented cases of involvement in snake bite envenoming by this species in Nepal.
Numerous snake bites (33%) occurred at night, during the rainy season, and are mainly due to Bungarus species, particularly B. caeruleus. Bites of cobras and Russell’s Vipers are a risk at daytime. Evaluation of data regarding the place where the bite happened, indicates that the snake bite risks appear to be as high in residential areas, in and around houses, as in rural areas. In cases of kraits (n = 46), 61% of the bites occurred while the victim was sleeping indoors, those of Russell´s Vipers mainly during agricultural activities in the fields. Analysis of socio-demographic data revealed that both krait and viper bites predominantly affected farmers or their family members. However, snake bites involved also people of higher socio-economic status, which suggests that it is not a health problem of poor people only living in the rural areas of Nepal.
A small number of snake bite victims (n = 7) sought help from traditional healers, but most patients went to hospitals for medical treatment using motorbikes (65%) or were transferred by ambulance cars (22%). As a first aid measure, most patients (78%) had used a tourniquet, which is of doubtful value and has often severe sequelae, instead of applying the WHO recommended pressure immobilisation bandage or local compression pad. The overall case fatality rate was calculated to be 10%, but up to 17% in cases of Bungarus spp. bites.
Rural community people were found to be extremely afraid of snakes, a major reason for indiscriminate killing of even harmless snakes, e.g., Lycodon aulicus, which were wrongly considered to be venomous. This is mainly due to the poor knowledge on snakes in general and on their role in providing ecological services, which may eventually lead to a decline in snake populations and even the extinction of rare species.
The results of the present study strongly emphasize that snake bite is an important public health issue in Nepal. There is an urgent need to improve the knowledge of people on snakes and to try changing their attitudes towards these reptiles, in addition to documenting the biodiversity and distribution of medically relevant snakes, the epidemiology and circumstances of their bites. Avoiding high-risk behaviour (e.g., killing of snakes), using screened doors and windows are some of the suggested measures preventing snake bite. Early and accurate identification of the snakes involved should help physicians to apply timely treatment, eventually referring the patient to the appropriate hospital. This also has important implications in developing public health and conservation strategies, to the benefit of the people of Nepal.
Die Parkinson Erkrankung ist die zweithäufigste neurodegenerative Erkrankung in industrialisierten Ländern. Die charakteristischen Symptome sind schwere Beeinträchtigungen des Bewegungsablaufes welche auf den Verlust dopaminerger Neurone der Substantia nigra und der damit einhergehenden Reduktion des striatalen Dopamin Gehaltes zurückzuführen sind. Alpha-Synuklein (SNCA) ist ein Protein welches zum einen mit sporadischen aber auch mit idiopathischen Erkrankungen assoziiert ist. Mutationen welche einen Funktionsgewinn von SNCA zur Folge haben konnten mit autosomal dominanten Varianten der Parkinson Erkrankung assoziiert werden und genetische Veränderungen an beiden Genenden agieren als Risikofaktor für sporadische Formen der Erkrankung. Des Weiteren wird SNCA als Hauptbestandteil der Lewy Körperchen gefunden, einem pathologischen Kennzeichen der parkinsonschen Erkrankung. Die charakteristischen Bewegungsstörungen können mittels L-DOPA, einer metabolischen Vorstufe von Dopamin, behandelt werden. Neben dem enorm positiven Effekt auf die Bewegungsstörungen, geht die Behandlung mit L-DOPA jedoch auch mit ernsten Nebenwirkungen einher, welche als Levodopa induzierte Dyskinesien (LID) beschrieben werden.
Ziel der Arbeit war die Analyse von Effekten eines SNCA Funktionsgewinns sowie des Pink1 Funktionsverlustes auf molekulare Signalwege der synaptischen Plastizität unter Verwendung dreier PD Mausmodelle (A53T-SNCA überexprimierendes Modell (PrPmtA), Pink1KO Modell sowie A53T-SNCA + Pink1KO Doppelmutante (DM)). Es wurden Kandidatengene welche eine Rolle für synaptische Plastizität spielen in 6 Monate alten Mäusen aller drei PD Mauslinien untersucht. Die Analyse von PrPmtA zeigte erhöhte mRNA Spiegel von Glutamatrezeptor-Untereinheiten und von Kandidatengenen welche eine Rolle bei der synaptischen Signalweiterleitung spielen, sowie reduzierte mRNA Spiegel von IEGs und Transkriptionsfaktoren. Die Analyse der DM zeigte nur geringe Expressionsänderungen der Glutamatrezeptor-Untereinheiten und die Analyse von IEGs und Transkriptionsfaktoren zeigte erneut reduziert mRNA Spiege. In Pink1KO Tieren konnten nur minimale Expressionsveränderungen der Kandidatengene gefunden werden, was den Schluss zulässt, dass die zuvor beschriebenen Expressionsveränderungen in PrPmtA und DM Mäusen eindeutig auf den SNCA Funktionsgewinn zurückzuführen sind. Um frühe Effekte des SNCA Funktionsgewinns zu studieren wurde die Analyse auf 3 Monate alte PrPmtA Mäuse ausgeweitet. Diese ergab, Expressionsveränderungen für Homer1, cFos, NOR1, Nurr1 und Nur77.
In einem weiteren Versuchsansatz wurde die Auswirkung des SNCA Funktionsgewinns auf das Verhalten sowie auf molekulare Parameter nach Apomorphin Behandlung analysiert. Die Analyse ergab ein erhöhtes Niveau an unwillkürlichen Bewegungsmustern mit stereotypen und dystonischen Eigenschaften in PrPmtA im Vergleich zu Wildtypen (wt). Die molekulare Analyse von striatalem Gewebe wurde zu zwei Zeitpunkten durchgeführt, 30 min nach Apomorphin Injektion und 100 min nach Injektion. Die Analyse von striatalem Gewebe welches zum Zeitpunkt 30 min nach Injektion entnommen wurde ergab eine erhöhte Apomorphin abhängige Phosphorylierung von ERK1/2, sowie eine erhöhte Apomorphin abhängige Expression von Dusp1, Dusp6 und cFos in transgenen und wt Tieren. Genotyp abhängige Unterschiede ergaben sich für cFos, welches signifikant höher in PrPmtA induziert wurde. 100 min nach Apomorphin Injektion ergab die gleiche Analyse eine erhöhte Apomorphin abhängige Phosphorylierung von ERK1 und eine erhöhte Apomorphin abhängige Expression von Dusp1, Dusp6, cFos und Nur77 in PrPmtA im Vergleich zu wt. Die Daten unterstreichen die fundamentale Rolle von SNCA auf die Neurotransmission und synaptische Plastizität und zeigen auf, dass PrPmtA ein zuverlässiges Modell für die Analyse von präsynaptischer Dysfunktion in Frühstadien der Parkinson Erkrankung darstellt.
Der letzte Versuchsansatz stellt die Charakterisierung des DM-Mausmodells welches sich durch einen starken Phänotyp auszeichnet, sowie die Analyse des Pink1 Effektes auf die SNCA induzierte Neurotoxizität dar. DM-Tiere zeigen deutlich reduzierte Spontanmotorik im Alter von 3 Monaten sowie einer progressiven Lähmung der Hinterläufe, was Anlass zu einer immunhistologischen Charakterisierung mittels Schnitten des Gehirns und Rückenmarks gab. Die histologische Analyse zeigte pSer129-SNCA, p62/SQSTM1 und Ubiquitin positive Aggregate innerhalb der grauen Substanz des Rückenmarks sowie innerhalb einer neuronalen Zellpopulation welche dorsal der Substantia nigra angeordnet ist. Das histologische Erscheinungsbild wurde spezifisch in gelähmten DM-Tieren gefunden und nicht in Einzelmutanten oder DM-Tieren ohne Lähmung. Dieses Modell stellt ein wertvolles Instrument für die Identifizierung von pathologischen Mechanismen und Signalkaskaden welche beiden Parkinson relevanten Genen gemeinsam sind, dar.
Die vorliegende Dissertation mit dem Titel: Ecophysiological monitoring of Oaks in Central Europe, introduced in the framework of proactive climate change mitigation beschäftigt sich mit der Anwendung zerstörungsfreier, radiometrischer Methoden zur Bestimmung von Pigment- und Stickstoffkonzentrationen und der photosynthetischen Funktionalität in Blättern von heimischen und gebietsfremden Eichen und ihre Beeinflussung durch Trocken-, Hitze- und Kältestress.
Die Eichenarten Quercus robur L. (Stieleiche), Q. pubescens Willd. (Flaumeiche), Q. frainetto Ten. (Ungarische Eiche), Q. ilex L. (immergrüne Steineiche) und Q. rubra L. (amerikanische Roteiche) wurden im Frühjahr 2011 auf einer Versuchsfläche im Frankfurter Stadtwald gepflanzt, um ihre Nutzung als potentielle Waldbäume in einem sich ändernden Klima zu untersuchen. Über eine Dauer von zwei Jahren wurden diese Arten mit einem hohen Maß an blattspezifischer Merkmalsvariabilität beobachtet und beprobt. Ziel war es, die interspezifischen Unterschiede und die jahreszeitliche Dynamik von morphologischen und chemischen Blattmerkmalen sowie die Beeinflussung der radiometrischen Bestimmung des Chlorophyllgehaltes (und damit assoziierten Komponenten wie z.B. Blattstickstoffgehalt und Karotinoiden) und der photosynthetischen Funktionalität durch klimatische Umweltbelastungen in Eichen zu untersuchen. Die Analyse der Blattproben zielte neben der Bestimmung der Beziehung zwischen absoluten und optisch ermittelten Pigmentgehalten auf die Ermittlung des Einflusses der Blattstruktur auf die Lichttransmission im roten und infrarotem Bereich des Elektromagnetischen Spektrums ab, sowie auf die artspezifische Korrelation von Blattstickstoff zu Blattchlorophyll zu dessen indirekte Quantifizierung. Des Weiteren wurden Versuche zur Trocken- und Hitzestressanpassung durchgeführt, um eine potentiell artspezifische Stressantwort, sowie eine mögliche Beeinflussung der aufgenommenen radiometrischen Messwerte zu ermitteln. Ein zusätzliches Monitoringprogramm im Winter 2012/2013 mit einer Dauer von sechs Monaten ermöglichte die Überprüfung der Anpassungsfähigkeit der immergrünen Steineiche (Q. ilex) an mitteleuropäische Winterbedingungen und die Veränderung der photosynthetischen Funktionalität unter Kältestress. Messungen im Zusammenhang mit der praktischen Anwendbarkeit der zerstörungsfreien, optischen Methode und zur Bereitstellung von Referenzdaten für zukünftige Evaluierungen komplementieren die Untersuchungen.
Signifikante, artspezifische Unterschiede wurden in den blattmorphologischen Schlüsselmerkmalen in den Quercus-Arten ermittelt. Die artspezifischen Unterschiede in den morphologischen Blattmerkmalen beeinflussten auf signifikante Weise die Beziehung zwischen absoluten, massebasierten Pigment- und Stickstoffgehalten und deren radiometrischen Bestimmung. Wurden die Pigmentgehalte hingegen auf die Blattfläche bezogen und die Stickstoffgehalte mittels des Verhältnisses von Blattfläche zu Trockenmasse korrigiert, zeichnete sich eine Beziehung zwischen absoluten und optisch ermittelten Werten ab, der jegliche jahreszeitliche oder artspezifisch morphologische Variabilität fehlte und die somit für alle Quercus-taxa anwendbar ist. Koeffizienten für die Berechnung von flächenbezogenen Gehalten von Gesamtchlorophyll, Chl a, Chl b und Carotinoiden für die jeweiligen Quercus-taxa, wie auch für ein artübergreifendes Modell wurden ermittelt, um die Bestimmung dieser Gehalte während aller Entwicklungsstufen zu ermöglich. Aus der jahreszeitlichen Entwicklung der Pigmentgehalte konnten drei deutliche Phasen abgeleitet werden: Die Phase der Blattentwicklung im Frühling, einer Plateauphase mit geringen Veränderungen (“core vegetation time”) und die Phase des Pigmentabbaus während der Herbstlaubfärbung. Die Übergänge zwischen diesen Phasen variierten zum Teil erheblich zwischen einzelnen Individuen einer Art sowie zwischen den Arten, was Unterschiede in der potentiellen, jährlichen Kohlenstoffaufnahme nach sich zieht. Stressbedingungen, wie Hitze- Kälte- oder Trockenstress, können zu Veränderung von Fluoreszenzparametern ohne gleichzeitige Änderung des Pigmentgehaltes führen, wie auch die indirekte Bestimmung von mit Chl assoziierten Komponenten (Carotinoide, Chl a, Chl b) mittels optischer Bestimmung (durch die Veränderungen von Pigmentverhältnissen) beeinflussen.
Im Rahmen des Forschungsprojektes konnten, Modelle zur Berechnung von Blattpigmenten und Blattstickstoff aus optischem Messdaten, Veränderungen der photosynthetischen Funktionalität, sowie Referenzdaten für die zukünftig nutzbaren Eichenarten hinsichtlich artspezifischer und jahreszeitlicher Variabilität unter mitteleuropäischen Umweltbedingungen ermittelt werden, die eine Nutzung und Einordnung von zerstörungsfreien, optischen Messwerten zur Ermittlung von Vitalitätsunterschieden in Eichen ermöglichen.
Die Spinozerebelläre Ataxie Typ 2 (SCA2) ist eine autosomal dominant vererbte neurodegenerative Krankheit, welche durch die Expansion des Trinukleotids Cytosin-Adenin-Guanin von ~22/23 auf >32 im Ataxin-2 Gen (ATXN2) verursacht wird. Dieses Trinukleotid codiert für die Aminosäure Glutamin weshalb SCA2 auch zu den Polyglutaminerkrankungen zählt. Zu dieser Gruppe zählen außerdem fünf weitere SCA-Subtypen sowie drei weitere neurodegenerative Erkrankungen, darunter die Huntington-Krankheit.
SCA2 wurde 1971 zum ersten Mal von Wadia und Swami beschrieben und unterscheidet sich von den anderen SCAs aufgrund der typischen Störung der sakkadischen Augenbewegungen. Weitere klinische Symptome von SCA2 sind Ataxie, Tremor, Dysmetrie, Dysarthrie, Hyporeflexie und Dysdiadochokinese. Die Symptome gehen auf einen neuronalen Verlust insbesondere im Cerebellum, aber auch in anderen Hirnregionen wie zum Beispiel dem Hirnstamm zurück.
Atxn2 wird in weiten Teilen des Zentralnervensystems aber auch in vielen nicht-neuronalen Geweben exprimiert. Es handelt sich um ein überwiegend cytoplasmatisch lokalisiertes Protein, welches im Gegensatz zu vielen anderen SCA-Proteinen cytoplasmatische und nur selten nukleäre Aggregate bildet. Die exakte Funktion von Atxn2 ist bisher unklar, es wurde allerdings mehrfach gezeigt, dass es in die mRNA Translation involviert ist aufgrund seiner Interaktion mit dem PolyA-bindenden Protein PABPC1.
Eine Expansion des Trinukleotids in Ataxin-2 kann nicht nur zu SCA2 führen, sondern stellt bei Wiederholungen zwischen 27 und 32 CAGs auch ein erhöhtes Risiko für eine Erkrankung an Amyotropher Lateralsklerose (ALS) und anderen neurodegenerativen Krankheiten dar. Eine Interaktion zwischen ATXN2 und dem ALS-verursachenden TDP43 (Tardbp) wurde bereits zahlreich beforscht, da Aggregate von ATXN2 in Motoneuronen des Rückenmarks von ALS-Patienten und aggregiertes TDP43 in SCA2-Neuronen beobachtet wurden.
Generell sind die Mechanismen, die zur Pathologie von SCA2 und ALS führen, noch weitgehend unklar. Ziel dieser Arbeit war es daher auf der einen Seite einen Einblick in den Pathomechanismus von SCA2 zu erhalten, indem mögliche oder bereits bekannte Interaktoren in etablierten Atxn2-Mausmodellen untersucht wurden. Auf der anderen Seite wurden zwei neue Mausmodelle charakterisiert, um ihre Eignung für die Erforschung von ALS und SCA2 zu prüfen.
Für den ersten Teil der Arbeit dienten Daten aus mehreren Transkriptomstudien von Atxn2-Knock-Out (KO) und Atxn2-CAG42-Knock-In (KIN) Mäusen als Grundlage. Konnten die Daten mit einer unabhängigen Methode bestätigt werden, folgten weitere Untersuchungen auf mRNA und Proteinebene sowie unter zusätzlicher Verwendung von Zellkultur und Patientenmaterial. Dadurch konnten neue Interaktionspartner von ATXN2 identifiziert und bereits bekannte in diesen Mausmodellen bestätigt werden.
So wurde zum Beispiel eine Interaktion von ATXN2 mit der E3-Ubiquitin-Protein-Ligasekomponente FBXW8 gezeigt und deren Beteiligung am Abbau von expandiertem ATXN2. Außerdem wurde eine Interaktion von FBXW8 mit dem bereits bekannten ATXN2-degradierenden Protein PARK2 gezeigt. Eine Hochregulierung des Fbxw8 Transkripts wurde sowohl im Atxn2-CAG42-KIN-Mausmodell als auch in SCA2-Patientenfibroblasten gefunden, während Park2 in keinem der Modelle signifikant veränderte Transkriptspiegel aufwies. Diese Daten belegen die Relevanz von Fbxw8 für den Abbau von moderat-expandiertem Atxn2 und begründen weitere Studien zur genauen Funktion dieses Proteins im Pathomechanismus von Atxn2.
Des Weiteren wurden diverse Kalziumhomöostasefaktoren untersucht, welche eine konsistente Herunterregulierung der Transkripte in beiden Mausmodellen aufwiesen. Auf Proteinebene zeigten sich jedoch Unterschiede zwischen den Modellen. Diese Daten belegen, dass zwar ähnliche Transkriptveränderungen im KIN- und KO-Modell auftreten, diesen aber vermutlich verschiedene Mechanismen zugrunde liegen. Welche Mechanismen dies genau sind bleibt zu klären, es ist jedoch wahrscheinlich, dass im KIN-Modell die Aggregatbildung sowie in beiden Modellen die Beteiligung von ATXN2 an der Translationregulation eine Rolle spielen. Die Ergebnisse dieser Studie unterstreichen die Relevanz des Ca2+ Signalwegs für die Entwicklung von SCA2.
Der zweite Teil der Arbeit beinhaltet die Charakterisierung einer ATXN2/TDP43 Doppelmutante auf Verhaltensebene sowie die gründliche Evaluierung des Phänotyps einer vollkommen neuen SCA2 Mausmutante. Während in der Doppelmutante trotz doppelter Genmutation nur ein sehr schwacher Phänotyp auf Verhaltensebene festgestellt werden konnte und bis zu einem Alter von 12 Monaten keine Potenzierung der Mutationen zu beobachten war, zeigte die Atxn2-CAG100-KIN Maus signifikante und früh auftretende Pathologie. Neben einer verminderten Überlebensrate, einem Gewichtsverlust und diversen motorischen Störungen, konnten auch Aggregate des mutierten Proteins in diversen Hirnregionen identifiziert werden. Der Atxn2-CAG100-KIN Phänotyp spiegelt die humanen Symptome daher recht gut wider, weshalb diese Mausmutante ein wertvolles Modell für die weitere SCA2-Forschung darstellt.
Zusammengefasst zeigt diese Arbeit die Bedeutung des ATXN2-Interaktors FBXW8 im SCA2-Mausmodell als auch im Patientenmaterial. Sie betont die Relevanz des Atxn2-KO-Modells in Bezug auf Störungen der Kalziumhomöostase und dokumentiert die Alters- und Gewebespezifität dieser Veränderungen. Außerdem beinhaltet sie die vorläufige Beschreibung eines kombinierten Atxn2/TDP43-Mausmodells und schließlich die ausführliche Charakterisierung eines vollkommen neuen und äußerst wertvollen SCA2-Mausmodells.
Amphibians have existed on the planet for over 300 million years and are today one of the most diverse vertebrate classes in the world with over 7000 known species and still many more to be discovered. However, several studies assume that approximately one third of the world´s known living amphibians are directly threatened with extinction, making it the most endangered vertebrate class. In relation to the relatively small land mass that is occupied by the state of Panama, it supports one of the most diverse amphibian faunas. However, in many cases the ecological role of single species in a wider context and their habitat preferences are still poorly understood and subject to ongoing research. Modern taxonomic approaches in other tropical regions have shown that former assumptions of amphibian diversity were distinct underestimations of the actual species diversity; a situation that is probably also true for Panama. Concurrently, the collection of amphibian diversity data and the description of new species is a race against time. The amphibian fauna of the world and that of Panama in particular, has suffered from an unprecedented loss of diversity over the last 30 years. The reasons are manifold and include destruction, alteration, and fragmentation of their natural habitats as the main causes, but also the deadly amphibian disease chytridiomycosis caused by the fungal pathogen Batrachochytrium dendrobatidis (Bd). In Panama and Costa Rica, this Emerging Infectious Disease (EID) spread in a wave-like manner from west to east causing mass die-offs and reduced amphibian diversity even in well-preserved habitats. The disease has primarily affected stream-associated highland species. The last large-scale evaluation of the conservation status of Panama´s amphibians through the IUCN Red List of Threatened Species in 2004 concluded that approximately 30% of the known species are acutely threatened with extinction. Furthermore, around 17% of the amphibian species that have been known back then lacked adequate data to be assessed. In view of Panama´s already overwhelming amphibian diversity, as well as the variety of habitats and the large number of sites that have not been examined with regard to amphibians before, I started this study with the conviction that the inventory of Panama´s amphibian diversity is far from being completed. Furthermore, when I started this study, it was uncertain if there would be any surviving amphibian species in areas where chytridiomycosis had emerged. The loss of whole amphibian communities in upland western Panama following Bd arrival led to a shift of amphibian research to lowland sites in central and eastern Panama aiming primarily on pathogen arrival and the documentation of epizootic outbreak and subsequent population decline. The situation of amphibian communities in areas post-decline was therefore largely unknown. Accordingly, the main goals of my study were to add to the taxonomic inventory of amphibians in Panama and to assess the situation of amphibian populations in habitats where chytrid-driven declines have been observed. To address these tasks I conducted fieldwork in western Panama with a focus on mountainous elevations between 1000 and 3475 m asl. Additionally, I visited different lowland sites between sea level and 1000 m asl to collect comparative material. In the period between 2008 and 2013, I conducted five collection trips to Panama that add up to a total of approximately 13 months in the field. I have sampled nine regions in western Panama and collected 767 specimens together with student collaborators, 531 of which were collected under my personal field number. Additional data obtained from those specimens include 68 male anuran call recordings, 102 standardized color descriptions of specimens in life, and 259 tissue samples that to date yielded 185 16S mtDNA sequences. This comprises the most comprehensive data set for amphibians of Panama and the first large-scale DNA barcoding approach for western Panama to date. After a preliminary DNA barcoding and subsequent comparative examination of morphological und bioacoustic data of all specimens collected, the number of taxonomic problems that needed to be addressed was higher than I previously anticipated. For most genetic lineages deeper taxonomic analyses were required to reach conclusive results. A selection had to be made with which lineages to proceed in the analyses, in view of the substantial financial and time expenditure that would be needed for a complete taxonomic revision. Therefore, I chose to run deeper analyses on one genus from each of the three amphibian orders in Panama. The genera selection depended largely on the availability of sufficient material and the scientific relevance of the respective genus.
I selected the genus Diasporus from the order Anura. These small frogs are omnipresent in many habitats and thus relatively easy to find. In addition, the genus is underrepresented in taxonomic studies. This is the first taxonomic study on the genus Diasporus to include a molecular phylogeny and the first comparison of advertisement calls between several populations from western Panama. In total, I collected 67 Diasporus specimens throughout western Panama and compared them morphologically with 49 additional specimens from Central America in collections, including the primary types of D. diasporus and D. hylaeformis. Additional comparative data were taken from literature. The DNA barcoding analysis of a fragment of the 16S rRNA gene included 43 own sequences that were complemented with 15 relevant GenBank sequences. In addition, I compared the advertisement calls of 26 male individuals among each other and with call descriptions from the literature. The DNA barcoding approach revealed several unnamed genetic lineages, but in some cases also resulted in the lumping of morphologically and bioacoustically distinct specimens. Generally, the morphological examination of the collected material revealed almost no specific characters that could be used to distinguish between genetic lineages. However, it was possible to identify species using a combination of several morphological characteristics. Which ones are relevant in the individual case depends on the respective species. My extensive collection of call recordings made it possible to test for the first time the intraspecific call variation of D. hylaeformis in dependency of various parameters. This analysis showed that the dominant frequency depends significantly on the body size of the calling male; the smaller the calling male, the higher the frequency of the call. A similar relationship was observed between the call rate and temperature: the lower the temperature during calling, the lower the call rate. I suppose that these general patterns, which have already been observed in other anuran genera, are also true in other Diasporus species that could not be tested in this study. Taking into account the intraspecific variation of Diasporus advertisement calls, I consider comparative call analyses to be the best way to distinguish between species. This is especially true in syntopic species. Integration of the three lines of evidence (i.e., morphology, DNA barcoding, and bioacoustics) led to the identification of four new species, two of which (i.e., D. citrinobapheus and D. igneus) colleagues and I have already formally described.
I conducted an integrative taxonomic analysis of the western Panamanian representatives of the genus Bolitoglossa from the order Caudata, the larger of the two Panamanian salamander genera. Bolitoglossa is very species-rich with a centre of diversification in the high mountains of Costa Rica and western Panama. I collected 53 Bolitoglossa specimens and compared them to twelve specimens in collection, including the holotype and one paratype of B. gomezi. The dataset was complemented with information from the literature. Among the sampled specimens were two species considered to be endangered that have not been collected or observed for several decades; B. magnifica has not been seen for 34 years and B. anthracina has not been seen for 22 years. Further, I collected salamanders at several new locations. To date, my 16S mtDNA barcoding analysis represents the densest taxon sampling for Panamanian Bolitoglossa composed of 21 own sequences that were combined in the final alignment with 47 GenBank sequences. Even though the molecular phylogeny is based only on a single marker, the received trees largely coincide with previous studies and the nodes received high statistical support. In these trees, I retrieve all previously defined subgenera and species groups. On the basis of this molecular phylogeny, I placed B. anthracina, here sequenced for the first time, in the B. subpalmata species group. Due to the fact that B. anthracina is a large and dark colored species it had previously been placed by implication in the B. schizodactyla species group along with other large black salamanders of the B. nigrescens species complex. Moreover, I found deep divergent genetic lineages among geographically separated populations of B. minutula. However, until now there were no additional morphological characteristics detectable to distinguish between these lineages. Additionally, my colleagues and I described a new deep divergent lineage in the B. robinsoni species group as B. jugivagans, a species new to science. In contrast, I found only minor genetic differences between specimens of B. sombra and B. nigrescens. After combining morphometric data and tooth counts from literature of both species with additional data from specimens of B. sombra that I collected near the type locality, the distinguishing features blurred. In particular, including much larger specimens of B. sombra, not yet known at the time of its description, showed that the tooth count difference is dependent on the size and age of the specimen examined. Larger specimens have more maxillary and vomerine teeth. Based on this evidence I regard B. sombra as a junior synonym of B. nigrescens. Further, I revised the Panamanian distribution of the two relatively common lowland salamanders, B. colonnea and B. lignicolor. Besides filling the gaps in the fragmentary known distributions of these species, I assessed the molecular and morphological variation of both species among populations in Panama. While there was little variation in B. lignicolor, I found divergent genetic lineages among geographically distinct populations of B. colonnea that require further taxonomic examination.
Caecilians (order Gymnophiona) are among the least investigated terrestrial vertebrates. After I received a first specimen of the predominantly South American genus Oscaecilia (family Caeciliidae) in western Panama, I started to work more extensively on the taxonomy of Caeciliidae in Central America. The specimens from western Panama were not readily assignable to a single described species, but shared characters with O. elongata and O. osae. While O. osae was only known from the holotype, the type material of O. elongata was destroyed during World War II. On the basis of the original description, the unique feature in O. elongata within Oscaecilia is the absence of subdermal scales in the posterior part of the body. In a referred specimen of O. elongata mentioned in the original description from eastern Panama, this characteristic cannot be examined as it consists of head and neck only. Therefore, I used non-destructive high-resolution, synchrotron-based X-ray micro CT imaging (HRμCT) to examine cranial characters in the specimens in question and took normal radiographs to count vertebrae and to make subdermal scales visible. I found that the fragmented specimen from eastern Panama likely belongs to the well-sampled species O. ochrocephala and has not much in common with O. osae or the specimens from western Panama. Contrarily, O. osae and the specimens from western Panama share many morphological characters, but also show some differences. Genetic barcoding revealed that both species are close relatives, but the genetic distance could not be finally resolved, because 16S sequences obtained from blood samples of living O. osae were of poor quality. Thus, I compare the Oscaecilia from western Panama to O. osae in this study, but postpone a taxonomic decision until further material becomes available. Further, I designate O. elongata a nomen dubium, because the type material is lost, the type locality is not defined in more detail than “Panama”, and the original description does not allow for a definite assignment. Since previous molecular studies only considered O. ochrocephala, the monophyly of Oscaecilia was never tested before. So far, the genus Oscaecilia is based largely on a single cranial character, the eyes covered with bone. Here, I combined two 16S mtDNA sequences of O. osae from Costa Rica and two sequences from O. sp. from western Panama with two sequences of O. ochrocephala and ten sequences of four species of the genus Caecilia, the sister genus of Oscaecilia. The resulted phylogeny contains two well-supported clades, one clade containing two species of Caecilia, one from Panama and one from western Ecuador and all species of Oscaecilia tested. The other clade consists of two species of Caecilia from the Amazon basin. I therefore assume that the split in both clades is due to the rise of the Andes, what led to today’s cis-trans-Andean distribution of the two clades. For now, to restore monophyly, I suggest to place Oscaecilia within the synonymy of Caecilia until more taxa have been tested. When assessing the conservation status of the amphibian species in mountainous western Panama, I first compiled a list of known species that I potentially could have found during my fieldwork. Using the IUCN categories, I analyzed how many of the endangered species I actually found and how these are distributed over families and species groups. Surprisingly, my rediscoveries of lost species were not equally distributed among the four families that comprise most endangered amphibian species (i.e., Bufonidae, Craugastoridae, Hylidae, and Plethodontidae). While I discovered ten of eleven endangered hylids and six of nine endangered plethodontids, I found only one of four endangered bufonids and none of the nine endangered craugastorids. I assume that the secretive living plethodontids, for which no Bd related declines have been documented, were just overlooked in the past decades. In contrast, I propose that hylids, in which Bd related population decline is well documented, developed distinct evolutionary solutions permitting coexistence with the pathogen. The situation is obviously different in bufonids and craugastorids, where I found no signs of population recoveries at present. So far, the only surviving populations of species from these families exist in climatic or physiographic niches that have probably shielded them from Bd. My data confirm the current view that the risk for naïve amphibian populations to decline during Bd epizootics is predicted by ecological traits (e.g., aquatic index, vertical distribution) and not dependent on taxonomic affiliation. However, I propose that only certain amphibian families (e.g., hylids and centrolenids) have the ability to acquire immunity solutions to coexist with the pathogen during enzootic stages. This is a very new perspective on the worst infectious disease in amphibians worldwide, allowing for new research approaches to understand the host-pathogen dynamics. Moreover, I examined where the share of surviving endangered amphibian species is particularly high in mountainous western Panama. As was to be expected, most of the endangered species are found within the boundaries of protected areas. One exception is the unprotected Cerro Colorado region in the Comarca Ngöbe-Buglé that provides habitat for a wide variety of endangered and undiscovered amphibian species. Nonetheless, planned open pit mining would destroy the forests in a large part of the area. This demonstrates once again that human activities are the biggest threat to amphibians in Panama and elsewhere.
In the interest of understanding the development of a multicellular organism, subcellular events must be seen in the context of the entire three-dimensional tissue. In addition, events that occur within a short period of time can be of great importance for the relatively long developmental process of the organ. Thus, it is required to capture subcellular events in a larger spatio-temporal scale context, which has been up to now a technical challenge. In developmental biology, light microscopy has always been an important tool. The dilemma of light microscopy, in particular fluorescence microscopy, is that molecules receive high light intensities that might change the conformation of molecules, which can have signaling or toxic effects. In Light Sheet-based Fluorescence Microscopy (LSFM), the energy required for a single recording is reduced by several orders of magnitude compared to other fluorescence microscopy techniques. During the last ten years, LSFM has emerged as a preferred tool to capture all cells during embryogenesis of the zebrafish Danio rerio, the fruit fly Drosophila melanogaster or recently the red flour beetle Tribolium castaneum for a period of several days. The motivation of this work was to gain new insights in developmental related processes of plant organs. The aim of this work was to establish a protocol for imaging plant growth over a long period of time using LSFM and perform comprehensive analyses at the cellular level. Plants have to cope with a variety of environmental conditions, therefore the conditions inside the microscope chamber had to be brought under control. The sample preparation methods and the standardized conditions at a physiological level allowed the study of gravity response, day-night rhythms, organ shape development as well as the intracellular dynamic events of the cytoskeleton and endosomal compartments in an unprecedented manner. Several of these projects were successfully published in collaborations with Prof. Jozef Šamaj (Palacký University Olomouc, Czech Republic), Prof. Niko Geldner (University of Lausanne, Switzerland), Prof. Malcom Bennett (University of Nottingham, UK) and Dr. Jürgen Kleine-Vehn (University of Natural Resources and Life Sciences, Austria). The main part of my work focused on the formation of lateral roots in Arabidopsis thaliana and was conducted in close collaboration with Dr. Alexis Maizel (University of Heidelberg, Germany). Previously, most experiments that describe lateral root formation have been performed on a small number of cells and for short periods of time. Capturing the complete process of lateral roots is an ambitious goal, because first, the primordium of a lateral root is located deep inside the primary root and imaging quality is impaired due to scattering of the overlaying tissue. Second, the process takes about 48 h, i.e. the plant has to be kept healthy for the whole period. Third, the amount of excitation light required for the spatio-temporal might have phototoxic effects that lead to a stop of growth at least in conventional microscopic techniques. In Arabidopsis embryogenesis, the sequence of cell divisions is relatively invariant. However, whether lateral root organogenesis follows particular cell division patterns has been unknown. The complete process of lateral root formation was captured from the first cell division until after the emergence from the main root. Images of a nuclei marker and a plasmamembrane marker were recorded every 5 min for a time period of up to 64 h. The positions and cell divisions of all cells were tracked manually. In collaboration with Alexander Schmitz (Goethe University Frankfurt am Main, Germany) and Dr. Jens Fangerau (University of Heidelberg, Germany), comprehensive analyses of the data were performed. A lateral root forms from initially 8-15 founder cells, arranged in a patch of 5-8 parallel files. The occurrence of new cell layers by periclinal divisions, as well as the sequence of layer generation was conserved and resembles the sequence suggested by Malamy and Benfey in 1997. Besides this stereotyped occurrence of periclinal divisions, radial divisions were found to appear stochastically, following no particular pattern. A large variability was also found in the contribution of founder cells and cell files to the final lateral root. In summary, the results suggest that a stereotyped pattern of cell divisions at particular developmental stages and a dynamically adapted control of cell divisions exist in parallel. Both properties allow a controlled but flexible development of the organ according to variations in cell topology and mechanical properties of the surrounding tissue. This work shows that LSFM, the sample preparation methods and controlled environmental conditions allow to capture and analyse the development of plants over several days at high resolution in an unprecedented manner.
By far not all genetic information is expressed by mRNA coding regions of the DNA. 98% of the human genome is not encoding for proteins. Therefore, these non-coding regions have been considered as “junk DNA” for a long time [1, 2]. The last years, new high throughput sequencing techniques have allowed the elucidation of the heterogeneous population of non-coding RNAs (ncRNAs, Table 1). RNAs longer than 200 nucleotides (nt) belong to the family of long non-coding RNAs (lncRNAs). They can exhibit numerous functions: The biggest family of RNAs is represented by the ribosomal RNAs (rRNAs). Together with the transfer RNAs (tRNAs) they are essential for the translation of mRNA into an amino acid sequence.
Myxobacteria are on order of Gram-negative, soil dwelling bacteria that feature an impressive number of properties: they can glide on solid surfaces by using two different motility motors, subsist by preying on other microorganisms, are often producers of multiple natural products, and upon adverse environmental conditions, they are able to form multicellular structures called “fruiting bodies”. The process, in which these macroscopically visible structures arise from independent single cells, has been the predominant subject of myxobacterial research for many decades. More precisely, researchers have strived for the discovery of genes, proteins and small molecules that act as signals, receivers or modulators of this complex process. In this regard, the species Myxococcus xanthus has evolved into the model organism due to its relatively simple and reliable handling in a laboratory environment. The research underlying this thesis focused on the identification and biosynthesis of lipids that may act as intercellular signaling molecules during the course of fruiting body formation of the myxobacterium Myxococcus xanthus as part of the “E-signal” system. In general, lipids containing branched-chain fatty acids with an uneven number of carbon atoms were found to be important players in this particular process. Nevertheless, their exact roles remain largely unknown as of this day. The first publication that is part of this thesis deals with an aspect that even strengthened the importance of role of iso-branched compounds in myxobacteria: myxobacterial metabolism is able to transform precursors of iso-lipids to isoprenoids. It addresses the question whether isoprenoids in general are important for fruiting body formation. Phenotypic analysis of mutants impaired in the biosynthesis of the central isoprenoid precursor 3-hydroxymethylglutaryl-Coenzyme A (3-HMG-CoA) from acetate and/or branched chain keto acids and their genetic and metabolic complementation clearly showed that isoprenoids are essential for fruiting body formation and confirmed that leucine derived isovalerate is an important source for isoprenoid precursors in myxobacteria. The second, and by far and away most tedious and sophisticated study, addressed the question as to how myxobacteria form fatty acid derived iso-branched ether lipids and to what extent they are important for fruiting body formation and sporulation. In a previous study, those unusual lipids were identified as specific biomarkers for myxobacterial development. No biochemical pathways to ether lipids specific for prokaryotes were known by then. In this study, a putative candidate gene that may be in involved in ether lipid biosynthesis was investigated. A combination of gene disruption and complementation experiments, phenotypic analysis and monitoring of ether lipid formation by means of GC-MS demonstrated its involvement in myxobacterial ether lipid biosynthesis and the importance of these lipids for the developmental process. Heterologous expression and biochemical testing of this gene together with in-silico sequence analysis and docking experiments confirmed the functions of its predicted domains. The discussion section provides an additional suggestion on how the ether bond formation is performed. Furthermore and most importantly, iso-branched ether lipids were found to be essential for sporulation but not for fruiting body formation. In summary, one or several molecules derived from an iso-branched alkylglycerol seem to play a role during sporulation in M. xanthus and a multidomain enzyme unique for myxobacteria is involved in their biosynthesis. The last manuscript addresses the complexity of lipid metabolism in myxobacteria. Prior to this work, there was limited knowledge about the exact composition of the myxobacterial lipidome and no method was available to monitor putative changes in the myxobacterial lipidome down to the single molecular species for studying lipid biosynthesis or regulation. An ultra-performance liquid chromatography coupled with mass spectrometry based method with electrospray ionization (UPLC-ESI-MS) utilizing standard equipment and a water/acetonitrile/isopropanol based eluent system proved to be geared for the construction of lipid profiles for wild type and mutant cells of M. xanthus and to show their differences. Fragmentation spectra based structure elucidation of lipid molecular species resulted in the identification of 99 molecular species comprising glycerophosphoethanolamines, glycerophosphoglycerols, glycerolipids, ceramides and ceramide phosphoinositols. The latter have never been described for any prokaryotes before. Three dimensional plots were created from the relative intensity differences of the single molecular ion species between the different samples to provide an efficient and versatile visualization of the data and enable the researcher to quickly detect differences.
RNA modifications are present in all three kingdoms of life and detected in all classes of cellular RNAs. RNA modifications are diverse, with more than 100 types of chemical modifications identified to date. These chemical modifications expand the topological repertoire of RNAs and are expected to fine-tune their functions. Ribosomal RNA (rRNA) contains two types of covalent modifications, either methylation on the sugar (Nm) or bases (mN), or base isomerization (conversion of uridine into pseudouridines, "). Pseudouridylations and ribose methylations are catalyzed by site-specific H/ACA and C/D box snoRNPs, respectively. The RNA component (snoRNA) of both types of snoRNPs is responsible for the site selection by base pairing with the rRNA substrate, whereas the protein component catalyzes the modification reaction: Nop1 in C/D box and Cbf5 in H/ACA box snoRNPs. Contrastingly, base methylations are performed by snoRNA independent, ‘protein-only’, methyltransferases (MTases). rRNA modifications occur at highly conserved positions, all clustering around functional ribosomal sites. Mutations in factors involved in rRNA modification have been linked to severe human diseases (e.g. X-linked Dyskeratosis congenita). Emerging evidences indicate that heterogeneity in RNA modification prevails, i.e. not all positions are modified at all time, and the concept of ‘specialized ribosomes’ has been coined. rRNA modification heterogeneity has been correlated with disease etiology (cancer), and shown to play a role in cell differentiation(hematopoiesis). Remarkably, alteration in rRNA modification patterns profoundly affects the preference of ribosomes for cap- versus IRESdependent translation initiation, with major consequences on cell physiology.
Fungal organisms, including the most common human pathogens Candida spp., are commensal organisms that are widely present as part of the human flora. Fungal infections are, most frequently, local infections that do not compromise the life of patients. However, mycotic diseases can be life-threatening if they become systemic infections. Systemic fungal infections have risen over the last three decades in parallel to the increased immune-compromised population as a consequence of diseases (e.g. HIV/AIDS) or therapeutic interventions that affect the immune system (e.g. chemotherapy for cancer treatment and immunosuppressors used for patients with organ transplants). This has resulted in the demand of new antifungal drugs that can eradicate the new infections caused by these opportunistic fungal pathogens. However, most of the current compounds have poor pharmaceutical properties such as narrow spectrum of activity, susceptibility to be extruded by efflux pumps or lack of specificity, which make them not suitable for human clinical applications. The treatment of fungal and parasitic infections has been traditionally difficult because the infective organisms are eukaryotic cells that share most of the pathways and enzymes with human cells. To avoid side effects and to develop a targeted therapy, the research has traditionally been centered on the very few enzymes and pathways existing in the infectious organism but absent in humans. Until now, antifungal therapeutic options are limited and are almost dominated by azole class of sterol biosynthesis inhibitors affecting the synthesis of ergosterol, a major constituent of the fungal cell membrane. Because human cells do not have a cell wall, the development of effective and safe antifungal agents has also been directed to enzymes required for the synthesis of the cell wall. Alternatively, it is theoretically possible to target enzymes that are present in fungal organisms and in humans, when: 1) sufficient selectivity can be achieved, and 2) inhibition of the fungal enzyme is lethal to the fungus but does not produce major side effects to humans. In this line, it would be ideal to evaluate the development of selective inhibitors of enzymes which are already known to be drug targets, like protein kinases.
Cancer is a disease characterized by uncontrolled cell growth and the capacity to disseminate to distant organs. The properties of cancers are caused by genetic and epigenetic alterations when compared to their normal counterparts. Genetic mutations occur in oncogenes and tumor suppressor genes and are the initial drivers of cellular transformation (Lengauer et al., 1998; Vogelstein and Kinzler, 2004). In addition, epigenetic alterations, which influence the expression of oncogenes and tumor suppressor genes independently from sequence alterations, are also involved in the transformation process (Esteller and Herman, 2001; Sharma et al., 2010). Genetic alterations and epigenetic regulatory signals cooperate in tumor etiology. Glioblastoma multiforme (GBM) is a frequent and aggressive malignant brain tumor in humans. The median survival of GBM patients is about 15 months after diagnosis. Like in other cancers, genetic and epigenetic alterations can be detected in GBM. Genetic alterations in GBM affect cell growth, apoptosis, angiogenesis, and invasion; however, epigenetic alterations in GBM also affect the expression of oncogenes or tumor suppresser genes that increase tumor malignancy (Nagarajan and Costello, 2009).
Reprogramming is a cellular process in which somatic cells can be induced to assume the properties of less differentiated stem cells. This process can be mediated through epigenetic modifications of the genome of somatic cells by the action of four defined transcription factors (Oct4, Sox2, Klf4 and Myc) or by the action of the miR 302/367 cluster (Anokye-Danso et al., 2011; Takahashi and Yamanaka, 2006; Takahashi et al., 2007) and result in the generation of induced pluripotent stem cells (iPS cells). Reprogramming of somatic cells by the miR 302/367 cluster can generate nontumorigenic iPS cells through the inhibition of the epithelial to mesenchymal transition (EMT), cell cycle regulatory genes and epigenetic modifiers (Lin and Ying, 2013).
Alzheimer’s disease (AD) is a common, age associated neurodegenerative disease that manifests as progressive dementia and is characterized by accumulation of the amyloid beta (Aβ) peptide which is a processing product of a transmembrane protein termed Alzheimer Amyloid Precursor Protein (APP). The Aβ peptide is generated by a sequential proteolytic processing of APP by two distinct proteases that are termed β- and γ-secretase. The β-secretase, also called BACE-1 or memapsin 2, belongs to the family of aspartyl proteases. BACE-1 evidently cleaves APP in an acidic endosomal compartment after endocytosis of APP, thereby facilitating Aβ peptide generation.
Sorting of transmembrane proteins is generally controlled by sorting signals in the cytoplasmic domains of the cargo proteins. The short cytoplasmic tail of BACE-1 with 23 amino acids contains a sorting signal of the acidic cluster, di-leucine (ACDL) type. The two Leu residues in this determinant are important for the clathrin mediated endocytosis of BACE-1, whereas the acidic residues together with the Leu are required for the endosomal sorting and recycling of BACE-1 back to the plasma membrane. The ACDL motif binds to the members of the GGA (Golgi-localized γ ear-containg ARF- binding proteins) family (GGA1-GGA3) that are involved in the sorting of BACE-1.
One of the major aims of this study was to address the role of flotillins in the intracellular sorting of BACE-1. This study shows that flotillin-1 directly binds to the di-leucine motif in the cytoplasmic tail of BACE-1, whereas flotillin-2 only shows an association mediated by flotillin-1. Flotillin-1 competes with GGA2 for the binding to BACE-1 tail, and thus influences the endosomal sorting of BACE-1. Importantly, depletion of flotillins results in an altered localization of the wildtype BACE-1, whereas the plasma membrane resident Leu to Ala (LLAA) mutant is not affected. Flotillin knockdown results in an accumulation of BACE-1, implicating reduced degradation and enhanced stability of this protease. Thus, flotillins appear to be important for the cellular targeting of BACE-1 and also influence the amyloidogenic processing of APP, as demonstrated by an increase in the amyloidogenic C-99 processing fragments.
When flotillin depleted cells were subjected to apoptotic stresses including Aβ25-35 synthetic peptide (inducer of the extrinsic apoptosis pathway) or several chemotherapeutic agents (staurosporine, brefeldin A, doxorubicin, carboplatin and paclitaxel: intrinsic apoptosis pathway) and cytotoxicity was determined, various apoptotic markers were activated in flotillin depleted cells. Caspase-3 and GGA3 are well accepted apoptosis markers and an enhanced caspase-3 cleavage was detected upon STS induced apoptosis in SH-SY5Y, HeLa, and HaCaT cell lines and increased GGA3 cleavage was observed in MCF7 cell line.
One of the major reasons for the apoptotic sensitivity in the absence of flotillins was a PI3K/Akt signaling defect. Neuroblastoma cells depleted of flotillins showed diminished levels of total Akt, phospho-Akt and phospho-ERK upon STS induced apoptosis. Since PI3K/Akt was the primary survival pathway affected upon STS induced apoptosis, ectopic expression of Akt in neuroblastoma cell line reduced caspase-3 cleavage and retarded apoptosis.
The direct downstream target of Akt is FOXO3a, whose localization was investigated in flotillin depleted cells. A major proportion of FOXO3a was localized in the nucleus of flotillin knockdown cells, implicating that FOXOs are active in these cells and subsequently trigger the transcription of death genes. Strikingly, an essential anti-apoptotic molecule and a major cancer target, Mcl-1, was inherently downregulated in flotillin knockdown cells. Mcl-1 is a chief member of the Bcl-2 family as it plays a pivotal role in cell survival and it is a critical protein in cancer therapeutics as suppression of Mcl-1 protein can curtail the survival and growth of tumorous cells.
Neuroblastoma cells were rescued from undergoing permanent damage due to STS induced apoptosis by overexpression of anti-apoptotic Bcl-2. Phorbol esters are well known PKC activators, and pre-treatment of neuroblastoma cells with phorbol esters along with staurosporine reduced caspase-3 cleavage.
These results demonstrate that absence of flotillins can sensitize cellular systems to apoptosis induction. The two main characteristics of cancer cells include resistance to apoptosis and unresponsiveness to chemotherapeutic agents. It is a well established fact that impaired apoptosis is central to tumour development. This study implicates that the downregulation of flotillin function can trigger cellular susceptibility and enhances apoptosis in response to conventional chemotherapeutic agents. Therefore, flotillins can serve as vital regulators in providing a more rational approach in molecular-targeted therapies for receding cancer growth and survival.
Angiogenesis, the formation of new blood vessels from existing ones, is a fundamental biological process required for embryonic development; it also plays an important role during postnatal organ development and various physiological and pathological remodeling processes in the adult organism. Vascular endothelial growth factor (VEGF) and its main receptor, VEGF receptor-2 (VEGFR-2), play a central role in angiogenesis. VEGFR-2 expression is strongly upregulated in angiogenic vessels, but the mechanisms regulating VEGFR-2 expression are not well understood. We found in this study that the G-protein α subunit Gα13 plays an important role in the regulation of VEGFR-2 expression. In vitro, we found that knockdown of Gα13 reduced VEGFR-2 expression in human umbilical vein endothelial cells and impaired responsiveness to VEGF-A. This phenotype was rescued by adenoviral normalization of VEGFR-2 expression. Gα13-dependent VEGFR-2 expression involved activation of the small GTPase RhoA and transcription factor NF-κB; it was abrogated by deletion of the NF-κB binding site at position -84 of the VEGFR-2 promoter. In vivo, endothelial cell-specific loss of Gα13 resulted in reduced VEGFR-2 expression, impaired responsiveness towards VEGF-A in Matrigel assays, and reduced retinal angiogenesis. Importantly, also tumor vascularization was diminished in the absence of endothelial Gα13, resulting in reduced tumor growth. Taken together, we identified Gα13-dependent NF-κB activation as a new pathway underlying the transcriptional regulation of VEGFR-2 during retinal and tumor angiogenesis.
The spider genus Eusparassus Simon, 1903 (Araneae: Sparassidae: Eusparassinae; stone huntsman spider) is revised worldwide to include 30 valid species distributed exclusively in Africa and Eurasia. The type species E. dufouri Simon, 1932 is redescribed and a neotype is designated from Portugal. An extended diagnosis for the genus is presented. Eight new species are described: Eusparassus arabicus Moradmand, 2013 (male, female) from Arabian Peninsula, E. educatus Moradmand, 2013 (male, female) from Namibia, E. reverentia Moradmand, 2013 (male, female) from Burkina Faso and Nigeria, E. jaegeri Moradmand, 2013 (male, female) from South Africa and Botswana, E. jocquei Moradmand, 2013 (male, female) from Zimbabwe, E. borakalalo Moradmand, 2013 (female) from South Africa, E. schoemanae Moradmand, 2013 (male, female) from South Africa and Namibia and E. mesopotamicus Moradmand and Jäger, 2012 (male and female) from Iraq, Iran and Turkey. 22 species are re-described six of them are transferred from the genus Olios Walckenaer, 1837. Six species-groups are proposed: the dufouri-group [8 species: E. dufouri, E. levantinus Urones, 2006, E. barbarus (Lucas, 1846), E. atlanticus Simon, 1909, E. syrticus Simon, 1909, E. oraniensis (Lucas, 1846), E. letourneuxi (Simon, 1874), E. fritschi (Koch, 1873); Iberian Peninsula to parts of north-western Africa], walckenaeri-group [3 species: E. walckenaeri (Audouin, 1826), E. laevatus (Simon, 1897), E. arabicus; eastern Mediterranean to Arabia and parts of north-eastern Africa], doriae-group [7 species: E. doriae (Simon, 1874), E. kronebergi Denis, 1958, E. maynardi (Pocock, 1901), E. potanini (Simon, 1895), E. fuscimanus Denis, 1958, E. oculatus (Kroneberg, 1846) and E. mesopotamicus; Middle East to Central and South Asia], vestigator-group (3 species: E. vestigator (Simon, 1897), E. reverentia, E. pearsoni (Pocock, 1901); central to eastern Africa and an isolated area in NW India], jaegeri-group [4 species: E. jaegeri, E. jocquei, E. borakalalo, E. schoemanae; southern and south-eastern Africa], tuckeri-group [2 species: E. tuckeri (Lawrence, 1927), E. educatus; south-western Africa). Two species, E. pontii Caporiacco, 1935 and E. xerxes (Pocock, 1901) cannot be placed in any of the above groups. Two species are transferred from Eusparassus to Olios: O. flavovittatus (Caporiacco, 1935) and O. quesitio Moradmand, 2013. 14 species are recognized as misplaced in Eusparassus, thus nearly half of the described species prior to this revision were placed mistakenly in this genus. Neotypes are designated for E. walckenaeri from Egypt, E. barbarus, E. oraniensis and E. letourneuxi (all three from Algeria) to establish their identity. The male and female of Cercetius perezi Simon, 1902, which was known only from the immature holotype, are described for the first time. It is recognized that the monotypic and little used generic name Cercetius Simon, 1902 — a species, which had been known only from the immature holotype — as a synonym of the widely used name Eusparassus. The case proposal 3596 (conservation of name Eusparassus) is under consideration by ICZN.
The first comprehensive molecular phylogeny of the family Sparassidae with focus on the genus Eusparassus is investigated using four molecular markers (mitochondrial COI and 16S; nuclear H3 and 28S). The monophyly of Eusparassus and the dufouri, walckenaeri and doriae species-groups are recovered with the latter two groups more closely related. The monophyly of the tuckeri-group is not supported and the position of E. jaegeri as the only available member of the jaegeri-group is not resolved within the Eusparassus clade. DNA samples of the vestigator-group were not accessible for this study. The origination of the genus Eusparassus around 70 million years ago (MA) is estimated according to molecular clock analyses. Using this recent result in combination with some biogeographic and geological data, the Namib Desert is proposed as the place of ancestral origin for Eusparassus and putative Eusparassinae genera.
Further analyses are done on the phylogenetic relationships of Sparassidae and its subfamilies. The Eusparassinae are not confirmed as monophyletic, with the two original genera Eusparassus and Pseudomicrommata in separate clades and only the latter clusters with most other assumed Eusparassinae, here termed the "African clade". Monophyly of the subfamilies Sparianthinae, Heteropodinae sensu stricto, Palystinae and Deleninae is recovered. The Sparianthinae are supported as the most basal clade, diverging considerably early (143 MA) from all other Sparassidae. The Sparassinae and genus Olios are found to be polyphyletic. The Sparassidae are confirmed as monophyletic and as most basal group within the RTA-clade. The divergence time of Sparassidae from the RTA-clade is estimated with 186 MA in the Jurassic. No affiliation of Sparassidae to other members of the "Laterigradae" (Philodromidae, Selenopidae and Thomisidae) is observed, thus the crab-like posture of this group was proposed a result of convergent evolution. Only the families Philodromidae and Selenopidae are found members of a supported clade. Including a considerable amount of RTA-clade representatives, the higher-level clade Dionycha is not but monophyly of the RTA-clade itself is supported.
Climate and subsequent environmental changes are regarded as one driver of species evolution. Against this background the present study investigates the evolutionary history of the mammalian family Bovidae (Cetartiodactyla, Mammalia), today the most species-rich family of large herbivores on the African continent. Temporal and spatial patterns in that group’s evolution are the focus of the present study and were investigated using methods and data deriving from multiple disciplines (palaeontology, genetics, climatology, conservation biology). The results serve as a validation of macroevolutionary hypotheses of species evolution.
A major proportion of African mammalian fossils can be assigned to that family. Due to their morphological adaptations, bovid species are highly indicative of their habitats. Hence, bovids are of great importance for paleontology. However, a strong taphonomic bias is present in the fossil record of bovids, favoring large and arid- adapted species. Molecular phylogenies of extant species and species distribution modelling combined with climate reconstructions can help to overcome these limitations.
A molecular phylogeny, based on the cytochrome b gene of 136 bovid species served as basis for analysis of temporal patterns. Divergence events were dated using the relaxed molecular clock approach. The tree was time calibrated at 30 nodes using information inferred from the fossil record. Lineage-Through-Time plots and the respective statistical analyses reveal detailed temporal patterns in the evolutionary history of tribes and groups combining arid- and humid-adapted tribes. The resulting pattern shows three distinct phases. Phase 1 (P1) is dominated by speciation events within the humid group, while the second phase (P2) is marked by a dominance of speciation within the arid group. The switch in diversification rates (BDS) from P1 to P2 is dated to 2.8 million years ago. The third phase (P3) shows low diversification rates for all groups, starting around 1.4 million year ago and culminates in a significantly reduced diversification rate for the complete family at 0.8 million years ago. Both transitions are contemporaneous with global climate changes and turnover events in fossil faunal communities.
To investigate the impact of climate changes onto the habitat availability within the last 3 million years and its putative influence on diversification rates, the species distribution modeling method was applied. For 85 African species and subspecies the climate niches were established and grouped into 5 climate-groups based on their climate preferences. For each group the available habitat for the period before and after the BDS was calculated on continental scale using reconstructed climate scenarios. To evaluate the modeled habitat distributions, regional analyses were performed in test areas surrounding well studied fossil sites (Laetoli, Olduvai, Chiwondo Beds, Lothagam, Koobi Fora, West Turkana, Swartkrans, Sterkfontain und Toros-Menalla). Habitat profiles (HP) permitted the comparison of the model based habitat reconstruction with the interpretations of classic paleontological reconstruction. The validity of the habitat modeling has been shown in particular for East African test areas. The reconstructions for the northern and southern fossil sites does not support the modeled habitats in these areas. Yet, the method of habitat- profiling may serve as suitable tool for environmental reconstruction of areas lacking sufficient paleontological material. A comparison of habitat availability before and after the BDS on continental scale identified a significant loss of habitat for humid adapted groups (7-22%) and habitat gain for arid adapted groups (19-173%). The climatically intermediate group experiences a tremendous gain of habitat (3366%). The greatest environmental change was modeled for East Africa, initiated by a progressive regional aridification.
In addition to the distribution modeling for past climate conditions, the geographical distribution was modeled for the future, i.e. for climate scenarios representing the years 2050 and 2080 under a putative climate change scenario (global surface warming). It was shown that in particular the arid groups have to expect a remarkable loss of habitat (41-76%), while a gain of available habitat can be expected for the humid adapted groups (114-577%). The climatically intermediate group suffers the strongest habitat loss (85%). Regions with locally stable climate conditions were detected and may serve as potential refugia and are already today known as Africa’s hot spots of biodiversity.
The results show a positive correlation of high diversification rates and increasing habitat availability. None of the tested speciation hypotheses taken alone explains the observations (e.g., Turnover-pulse Hypothesis, Relay Model). A major element in these hypotheses is the passive fragmentation of populations induced by unfavorable climate changes. In contrast, the Periodic Model (Grubb 1999) considers natural, periodically recurring climate changes and moreover, the active dispersal of individuals and resulting founder events. I added the effect of a superimposed directed climate trend – like the progressive aridification since the late Pliocene in Africa – which leads to a bias in the proportion and probability towards leading edge effects. This Directed Periodic Model explains the patterns found in the evolution of Bovidae.
The combination of a molecular phylogeny and species distribution modeling, together with information inferred from the fossil record, reveals remarkable temporal and spatial patterns in the evolution of bovids, and helps overcome the limitations of the fossil record. The present study highlights the importance of active dispersal and founder populations in speciation processes. A point widely unattended in speciation hypotheses. The fully dated molecular phylogeny is the most densely sampled tree for the family Bovidae to date and may serve as a framework for a connection of present and future population studies, permitting the connection of medium-scale with long- term effects induced by climate and environmental changes.
The environmental impact of climate change is meanwhile not only discussed in the scientific community but also in the general public. However, little is known about the interaction between climate change and pollutants like pesticides. A combination of multiple stressors (e.g. temperature, pollutants, predators) may lead to severe alterations for organisms such as changes in time of reproduction, reproductive success and growth performance, mortality and geographic distribution. The questions if aquatic organisms tend to react more sensitive towards incidents under climate change conditions remains. Therefore, within the present thesis the aquatic ecotoxicological profile of the fungicide pyrimethanil, as an exemplarily anthropogenic used contaminant, was examined.
A large test battery of ecotoxicological standard tests and supplement bioassays with non-model species was conducted to investigate if species-specific or life stage-specific differences occur or if temperature alteration may change the impact of the fungicide. Two of the most sensitive species (Chironomus riparius and Daphnia magna) were used to investigate the acute and chronic thermal dependence of pyrimethanil effects. The results clearly depict that the ecotoxicity of pyrimethanil at optimal thermal conditions did not depend on the trophic level, but was species-specific. With regard to EC10 values the acute pyrimethanil toxicity on C. riparius increased with higher temperature (6.78 mg L-1 at 14°C and 3.06 mg L-1 at 26°C). The chronic response of D. magna to the NOEC (no observed effect concentration) of the fungicide (0.5 mg L-1) was examined in an experiment which lasted for several generations under three simulated near-natural temperature regimes (‘cold year, today’ (11 to 22.7°C), ‘warm year, today’ (14 to 25.2°C) and ‘warm year, 2080’ (16.5 to 28.1°C)). A pyrimethanil-induced mortality increase was buffered by the strongly related increase of the general reproductive capacity, while population growth was stronger influenced by temperature than by the fungicide. At a further pyrimethanil concentration (LOEC – lowest observed effect concentration: 1 mg L-1), a second generation could not be established by D. magna under all thermal regimes.
Besides daphnids, the midge C. riparius was used for a second multigeneration study. In a bifactorial test design it was tested if climate change conditions alter or affect the impact of a low fungicide concentration on life history and genetic diversity. The NOAEC/2 (half of the no observed adverse effect concentration derived from a standard toxicity test) was used as a low pyrimethanil concentration to which laboratory populations of the midges were chronically exposed under the mentioned temperature scenarios. During the 140-day-multigeneration study, survival, emergence, reproduction, population growth, and genetic diversity of C. riparius were analyzed. The results reveal that high temperatures and pyrimethanil act synergistically on life history parameters of C. riparius. In simulated present-day scenarios, a NOAEC/2 of pyrimethanil provoked only slight to moderate beneficial or adverse effects. In contrast, an exposure to a NOAEC/2 concentration of pyrimethanil at a thermal situation likely for a summer under the future expactations uncovered adverse effects on mortality and population growth rate. In addition, genetic diversity was considerably reduced by pyrimethanil in the ‘warm year, 2080’ scenario, but only slightly under current climatic conditions. The multigeneration studies under near-natural thermal conditions indicate that not only the impact of climate change, but also low concentrations of pesticides may pose a reasonable risk for aquatic invertebrates in the future. This clearly shows that thermal and multigenerational effects should be considered when appraising the ecotoxicity of pesticides and assessing their future risk for the environment.
In addition to temperature further multiple abiotic and biotic stressors alterate pollutant effects. Moreover, to better discriminate and understand the intrinsic and environmental correlates of changing aquatic ecosystems, it was experimentally unraveled how the effects of a low-dose of pyrimethanil on daphnids becomes modified by different temperatures (15°C, 20°C, 25°C) and in the presence/ absence of predator kairomones of Chaoborus flavicans larvae. The usage of a fractional multifactorial test design provided the possibility to investigate the individual growth, reproduction and population growth rate of Daphnia pulex via different exposure routes to the fungicide pyrimethanil at an environmentally relevant concentration (0.05 mg L-1) - either directly (via the water phase), indirectly (via algae food), dually (via water and food) or for multiple generations (fungicide treated source population).
The number of neonates increased with increasing temperatures. At a temperature of 25°C no significant differences between the individual treatment groups were observed although the growth was overall inhibited due to pyrimethanil. Besides, at 15 and 20°C it is obvious that daphnids which were fed with contaminated algae had the lowest reproduction and growth rate. The obtained results clearly demonstrate that multiple stress factors can modify the response of daphnids to pollutants. The exposure routes of the contaminant are of minor importance, while temperature and the presence of a predator are the dominant factors impacting the reproduction of D. pulex. It can be concluded that low concentrations of pyrimethanil may disturb the zooplankton community at suboptimal temperature conditions, but the effects will become masked if chaoborid larvae are present. Therefore it seems necessary to observe prospectively if the combination of several stress factors like pesticide exposure and suboptimal temperature may influence the life history and sensitivity of several aquatic invertebrates differently.
Besides standard test organisms it is inevitable to conduct test with aquatic invertebrate which are not yet considered regularly in ecotoxicological experiments. For example molluscs represent one of the largest phyla of macroinvertebrates with more than 100.000 species, being ecologically and economically important. Therefore, within the present study embryo, juvenile, half- and full-life cycle toxicity tests with the snail Physella acuta were performed to investigate the impact of pollutants on various life stages. Different concentrations of pyrimethanil (0.06-0.5 or 1.0 mg L-1) assessed at three temperatures (15°C, 20°C, 25°C) revealed that pyrimethanil caused concentration-dependent effects independent of temperature. Interestingly, the ecotoxicity of pyrimethanil was higher at lower temperature for the embryo hatching and F1 reproduction, but its ecotoxicity for the growth of juveniles and the F0 reproduction increased with increasing temperature. More specifically, it could have been observed that especially during the reproduction test high mortality rates occurred at the highest concentration of 1 mg L-1 at all temperatures. Due to high mortality rates no snails were available for the F1 at the highest concentrations (0.5 and 1.0 mg L-1). Compared to the F0, overall more egg masses were produced in the F1, being all fertile and no mortality occurred. For the F1-generation the strongest pyrimethanil effects were detected at 15°C. A comparison of effect concentrations between both generations showed that the F1 is more sensitive than the F0.
These results indicate that an exposure over more than one generation may give a better overview of the impact of xenobiotics. With the establishment of an embryo and reproduction test under different temperatures and various concentrations of pyrimethanil with P. acuta we could successfully show that molluscs can respond more sensitive than model organisms and that both, chemical and thermal stressor strongly influence the behaviour of the pulmonates. It can be concluded that the high susceptibility for the fungicide observed in gastropods clearly demonstrates the complexity of pesticide-temperature interactions and the challenge to draw conclusions for the ecotoxicological risk assessment of pesticides under the impact of global climate change.
European pea crabs - taxonomy, morphology, and host-ecology (Crustacea: Brachyura: Pinnotheridae)
(2010)
Pinnotherids are small crabs symbiotic to a variety of invertebrates. The European species infest bivalves and sea squirts. Their way of life is parasitic and poses a threat to commercially exploited bivalves. While juveniles of both sexes still look very similar - being agile swimmers and partially free living - a metamorphosis takes place in the female after mating and results in a conspicuous sexual dimorphism. Thereafter, the female settles in its host definitely and is morphologically strongly adapted to the parasitic life phase. A very high reproductive output was demonstrated among several pea crab species infesting bivalves. Despite from that, hardly any information is present in the literature on the pinnotherids’ reproductive biology and the underlying morphology.
Due to their cryptic way of life, the sexual dimorphism, and the different morphotypes of the female, the taxonomy of the Pinnotheridae is a serious challenge. Two widely accepted species are recognized on European coasts: Pinnotheres pisum and Nepinnotheres pinnotheres. Pinnotheres pectunculi was so far only known from the bivalve Glycymeris glycymeris in its type locality Roscoff (France), while Pinnotheres ascidicola and Pinnotheres marioni were described as living exclusively in ascidians without careful comparison with the previously described species. In order to produce standardized comparative descriptions, pea crabs were collected and studied from different hosts and localities in the Northeast Atlantic and in the Mediterranean. Nepinnotheres pinnotheres and Pinnotheres pisum were redescribed with consideration to characters of female and male. According to our morphological analysis, Pinnotheres ascidicola and Pinnotheres marioni are junior synonyms of Nepinnotheres pinnotheres, whereas the status of Pinnotheres pectunculi as a valid species was ascertained. Important characters are the mouthparts, the male gonopods, and especially chelipeds that showed consistent characteristics among different crab stages of both sexes.
Based on our sampling, we estimated the host-range of the European species. Nepinnotheres pinnotheres lives in ascidians and in the pen shell Pinna nobilis. Pinnotheres pisum infests numerous bivalve species - Pinna nobilis included. For Pinnotheres pectunculi novel host records are presented, all from the bivalve family Veneridae. Furthermore, feeding of the Pinnotheres-species was observed. They use a setae comb ventrally on the claw to brush mucus (and the accumulated food particles) from the bivalve gills. Feeding strategies and host-ecology will be thoroughly discussed in consideration to other Pinnotheridae.
We investigated the reproductive systems of European pinnotherids by histological methods, scanning and transmission electron microscopy, and confocal laser scanning microscopy.
The Eubrachyura have internal fertilization: paired vaginas enlarge into storage structures, the spermathecae, which are connected to the ovaries by oviducts. Sperm is stored until the oocytes are mature and transported into the spermathecae, where fertilization takes place. In the investigated pinnotherids, the vagina is of the ‘concave pattern’. Musculature is attached alongside flexible parts of the vagina-wall to control the dimension of its lumen. The genital opening is closed by a muscular mobile operculum.
The spermatheca can be divided into two distinct regions by function and morphology. The ventral part includes the connection with vagina and oviduct and is regarded as the zone where fertilization takes place. It is lined with cuticle except where the oviduct enters the spermatheca by the ‘holocrine transfer tissue’. At ovulation, the oocytes have to pass through this multi-layered glandular epithelium, which has a holocrine mode secretion. The dorsal part of the spermatheca is lined by a highly secretory apocrine glandular epithelium, which was to date only found in fiddler crabs of the genus Uca.
The male internal reproductive system consists of paired testes and corresponding vasa deferentia. The sperm morphology of pinnotherids conforms to other thoracotremes, with slight differences between Nepinnotheres pinnotheres and Pinnotheres pisum. Spermatozoa become enveloped into spermatophores in the secretory proximal vas deferens. The medial vas deferens is strongly enlarged and stores spermatophores embedded in seminal plasma. The distal vas deferens holds tubular appendices, which extend into the ventral cephalothorax and slightly into the pleon. These appendices produce and store vast quantities of seminal plasma. The copulatory system of the Brachyura is formed by paired penes and two pairs of gonopods, which function in sperm transfer. In pinnotherids, the long first gonopods transfers the sperm mass to the female. It holds the ejaculatory canal inside, which opens proximally and distally. The second gonopod is solid, short and conical. During copulation, the penis and the second gonopod are inserted into the base of the tubular first gonopod. The second gonopod functions in the transport of the sperm mass inside the ejaculatory canal towards its distal opening. The specific shape of the second gonopod is strongly adapted for a sealing of the tubular first gonopod with longitudinal cuticle foldings that interlock inside the first gonopod. The presented results are discussed concerning their function in reproduction and in respect of the systematic account.
The role of secretion in sperm transfer, storage and fertilization among the Brachyura is still under debate. It is notable that structure and function of secretion are more complex in pinnotherids and probably more efficient than in other brachyuran crabs, which will be discussed, in view of the parasitic way of life and the high fecundity of pinnotherids.
For millennia, rural West African communities living in or adjacent of savanna ecosystems have been collecting components of local plant species (e.g. fruits, leaves, bark) in order to fulfil essential household subsistence needs (alimentation, medical care, energy demand etc.), to generate cash income and to overcome times of (financial) crisis. Thus, these non-timber forest products (NTFPs) make a considerable contribution to the well-being of local households. However, climate and land use change severely impact West African savanna ecosystems and, consequently, the safe-guarding of dependent rural livelihoods. The conversion of savanna area into cultivated land for subsistence farming owing to the ongoing population growth, as well as the progressive promotion of cash crops (e.g. cotton) is ever-increasing. As a consequence, present land-use management in West Africa has to cope with serious trade-offs. Within this decision-making NTFPs have been constantly understated due to a lack of appropriate economic figures to use within common cost-benefit analysis, and, thus, have been frequently outcompeted by seemingly more profitable land-use options. Therefore, it is crucial to provide appropriate economic data for NTFPs in order to create positive incentives for both decision-makers and NTFP beneficiaries to conserve NTFP-providing trees. The key finding of this analysis is that income from NTFPs accounts for 39 % on average of an annual total household income in Northern Benin, representing the second largest income share next to crop income and proving the respective households to be economically heavily dependent on NTFPs. Thereby, socio-economic characteristics of NTFP users tremendously shape their preferences for woody species. Particularly ethnicity has a major impact on the species used and the economic return obtained by them. Moreover, the study investigated the impacts of climate and land use change on the economic benefits derived from the three economically most important tree species in the region Vitellaria paradoxa, Parkia biglobosa and Adansonia digitata in 2050: Environmental changes will have primarily negative effects on the economic returns from all the three species. At large, the study underpins the economic relevance of NTFPs for rural communities in West African savannas and, consequently, the necessity to appropriately sustain them in order to safe-guard local livelihoods. Providing key figures on the current and future economic benefits obtained from NTFPs can augment common cost-benefit analysis, and, delivering detailed information about peoples’ use preferences for local species, this study clearly contributes to improve the basis of decision-making with reference to local land-use policies.
Diatoms contribute largely to the total primary production of the ecosphere and are key players in global biogeochemical cycles. Their chloroplasts are surrounded by four membranes owing to their secondary endosymbiotic origin. Their thylakoids are arranged into three parallel bands and differentiation of thylakoid membranes into grana or stroma is not observed. The fucoxanthin chlorophyll a/c binding proteins act as the light harvesting proteins and play a role in photoprotection during excess light as well. The diatom genome encodes three different families of antenna proteins. Family I are the classical light harvesting proteins called "Lhcf". Family II are the red algae related Lhca-R1/2 proteins called "Lhcr" and family III are the photoprotective LI818 related proteins called "Lhcx".
All known Fcps have a molecular weight in the range of 17-23 kDa. They are membrane proteins and have shorter loops and termini compared to LHCs of higher plants and are therefore extremely hydrophobic. This makes the isolation of single specific Fcps using routine protein purification techniques difficult.
The purification of a specific Fcp containing complex has not been achieved so far and until this is done several questions concerning light harvesting antenna systems of diatoms cannot be answered. For e.g. Which proteins interact specifically? Are various Fcps differently pigmented? Which pigments interact with each other and how? Which proteins contribute to photosystem specific antenna systems? Can pure Fcps be reconstituted into crystals like LHCII proteins? In order to answer these questions specific Fcp containing complexes have to be purified. ...
The canonical Wnt/β-catenin and the Shh pathway as well as the Notch signaling cascade
are key regulators in stem cell biology and are independently associated with the development
of cancer. Despite the knowledge of a balanced signaling for cellular maintenance, the
fundamental biochemical mechanisms of crosstalk are still poorly understood. This study
demonstrates that the outcome of interaction between Wnt and Shh is cell type specific. A
combined inhibitory mechanism of the Shh and Notch2/Jagged2 pathways on dominant
active β-catenin signaling in the adult tongue epithelium keeps Wnt/β-catenin signaling
restricted to physiological tolerable levels. In the opposite crosstalk the activation of
Wnt/β-catenin signaling in medulloblastoma (MB) of the Shh subtype, in turn inhibits the Hh
pathway.
The inhibitory mechanism of Shh and Notch2/Jagged2 on Wnt/β-catenin signaling is
independent of the degradation complex of β-catenin and takes place inside the nucleus.
Furthermore, the negative feedback on Wnt/β-catenin signaling by the Shh pathway relies
on transcriptional activity of Gli1/2A. Inhibition of Gli1/2A with the specific inhibitor GANT61
abrogated the negative impact of Shh on β-catenin signaling in vitro. Although the negative
feedback loop of Shh is still functional in human SCC25 cells, the inhibitory effect of
Notch2/Jagged2 is lost and contributes to the cancerogenic phenotype of these cells. In the
inverse situation, the activation of β−catenin signaling has a negative feedback on
constantly active Shh signaling and significantly inhibits the Hh pathway. This was shown in
Ptch+/- and Math1-Cre:SmoM2Fl/+ MB tumor spheres in vitro, in which inhibition of sphere
formation and growth was observed and Hh target gene transcription was down-regulated.
This demonstrates for the first time that the activation of canonical Wnt/β-catenin signaling
in primary MB cells with a Hh pathway over-activation has a negative effect on the growth of
these cells in vitro.
In summary the results show that crosstalk of Wnt/β-catenin and Shh signaling has context
specific outcome on pathway activity. Elucidation of the molecular interactions will improve
our understanding of Wnt and Hh associated tumors and contribute to the development of
new therapeutic strategies.
It has been estimated that about 1% of live births carry severe congenital heart defects and 20-30% among them have valve malformations. Despite its medical importance the underlying cause of many valvular diseases remains undiscovered. Thus, it is important to identify genes that play a crucial role in cardiac valve formation and maturation.
A temporal RNA expression analysis of heart development suggested that the extracellular matrix protein Nephronectin might be a novel regulator of valve development and/or trabeculation. Nephronectin is transiently expressed during rat heart development at the time of heart valve morphogenesis and trabeculation. Moreover, the extracellular matrix is known to be crucial for organogenesis. It is a complex, dynamic and critical component that regulates cell behavior by modulating the activity, bioavailability, or presentation of growth factors to cell surface receptors.
In order to verify the hypothesis that Nephronectin is a novel regulator of valve formation and/or trabeculation the zebrafish was chosen as model system. Females are able to spawn at intervals of 5 days laying hundreds of eggs in each clutch. Development progresses rapidly with precursors to all major organs appearing within 36 hours post fertilization. Zebrafish embryos develop externally, are translucent and continue to grow for several days despite developing severely malformed, non functional hearts. In addition, gene expression can be easily modulated. During the present study it has been shown that Nephronectin expression is correlated to valve development and trabeculation. Morpholinomediated knockdown of Nephronectin in zebrafish caused failure of valve formation and trabeculation resulting in > 85% lethality at 7 days post fertilization.
Cardiac valve formation is initiated at the junction of atrium and ventricle and is characterized by extracellular matrix deposition and endocardial cell differentiation. In accordance with the above-described phenotype the earliest observed abnormality in Nephronectin morphants was an extended tube like structure at the atrio-ventricular boundary. In addition, the expression of myocardial genes involved in cardiac valve formation (cspg2, fibulin1, tbx2b, bmp4) was expanded and endocardial cells along the extended tube like structure exhibited characteristics of atrio-ventricular cells (has2, notch1b and Alcam expression, cuboidal cell shape). Inhibition of has2 in Nephronectin morphants rescued the endocardial but not the myocardial expansion. In contrast, diminishment of BMP signaling in npnt morphants resulted in reduced ectopic expression of myocardial and endocardial atrio-ventricular markers. Taken together, these results identify Nephronectin as a novel upstream regulator of BMP4-HAS2 signaling playing a crucial role in atrio-ventricular canal differentiation.
Savannas are the most important timber and non-timber forest products (NTFPs) providing ecosystems in West Africa. They have been shaped by traditional human land-use (i.e. agriculture, grazing, and harvesting) for thousands of years. In the last decades, land-use has drastically changed due to the rapid population growth and the growing production of cash-crop in West Africa and this process is still continuing. The percentage of land intensively used for agriculture has increased, while the length of fallow periods has decreased. Such changes have enormous ecological, economic, and social consequences. In the context of land-use changes, there is an urgent need to better understand and evaluate the impact of land-use on savannas. Such an understanding provides insights on appropriate management activities that ensure the maintenance of savannas and guarantee the availability of savanna products for subsistence and commercial use of rural West African people.
The major objective of the present thesis was to study the impact of land-use on savanna vegetation and diversity as well as on populations of two important NTFP-providing tree species in a semi-arid area in West Africa. The study area was located in the south-eastern part of Burkina Faso and comprised the protected W National Park and its adjacent communal area.
In the first study (chapter 2), I investigated in cooperation with a colleague from Burkina Faso (Blandine Nacoulma) the impact of land-use on the savanna vegetation. We analyzed which environmental factors determine the occurrence of the vegetation types and investigated the effect of land-use on vegetation structure and the occurrence of life forms and highly valued tree species. Furthermore, we tested whether land-use has an impact on plant diversity pattern and if this impact differed between the vegetation types and layers (woody and herb layer). Vegetation relevés were performed and the vegetation and plant diversity of the protected W National Park were compared with those of its surrounding communal area. Our results reveal five vegetation types occurring in both areas. Elevation and physical soil characteristics and thus soil water availability for plants played the most important role for the occurrence of the vegetation types. The influence of land-use on plant diversity differed between the five vegetation types and the two layers. The impact was highest on the vegetation types with the most favorable soil conditions for cultivation and lowest on rocky habitats with poor soils. While the diversity of the woody layer was increased under human land-use, the diversity of the herb layer was diminished. Overall, as land-use effects were not only negative, our findings suggest that land-use does not automatically lead to a loss of plant species and to a degradation of savanna habitats. We conclude that both protected and communal areas are of great importance for the conservation of savanna vegetation and diversity. Our study highlights furthermore the importance of different management strategies for each vegetation type.
In the following two studies (chapter 3 and 4), the impact of land-use - and in particular of harvesting - on populations of Adansonia digitata L., the baobab tree, and Anogeissus leiocarpa (DC.) Guill. & Perr. was examined. These two tree species were chosen as they provide several NTFPs for the local population and as they show different levels of human protection and opposed life histories. Thus, they may react differently to land-use. Stands of the protected W National Park were compared with those of its surrounding communal area (in fallows, croplands, and villages). I applied dendrometric methods to study the population structures and combined it with rates and patterns of NTFP-harvesting (debarking and chopping/pruning). Furthermore, the impact of land-use and harvesting on the fruit production of A. digitata and on the sprouting ability of A. leiocarpa were studied. The inverse J-shaped size class distribution curve indicates that the stands of A. digitata were in a healthy state in the park, while the low number of smaller size classes in fallows, croplands, and villages may give evidence of an ageing population. However, a high number of seedlings were recorded in villages. The stands of A. leiocarpa were also in healthy states in the park and likewise in fallows. In contrast, the absence of saplings gives evidence of a declining population in croplands. Both species were strongly harvested by local people and harvesting was tree size-specific. Pruning in interaction with tree-size had a significant impact on fruit production of A. digitata. While smaller trees were more vulnerable to pruning, bigger trees benefited from slight-pruning. A. leiocarpa had a great ability to respond to chopping by sprouting. The sprouting ability increased even with higher chopping intensity. Results suggest that despite the intense harvesting and the land-use impact, populations of both species are still well preserved. While A. digitata can withstand the harvesting and land-use pressure by its longevity, extremely low adult mortality rates, and particularly due to positive human influences, A. leiocarpa is able to withstand the use pressure by its fast growing, high recruitment, and high sprouting ability. I conclude that a none protected tree species (A. leiocarpa) might not necessarily be at higher risk to the harvesting and land-use impact than a protected tree species (A. digitata) as the adverse impact of harvesting and land-use can be compensated by its specific life history.
Important additional information to such ecological findings can be provided by local people. Learning from traditional knowledge and management systems of local people will help to produce culturally and ecologically reasonable conservation and management strategies. Thus, I investigated local uses and management strategies of A. digitata and A. leiocarpa in the last two studies (chapter 5 and 6). Quantitative ethnobotanical surveys among the Gulimanceba people were conducted in the communal area in order to document uses of the different plant parts, harvesting modes, perceptions about the population status, and conservation status of both species. Hereby, differences in knowledge between gender, generations, and people from different villages were tested. Interviews reveal that both species are harvested for multipurpose and emphasize the high importance of both species for local people. Especially the leaves and fruits of A. digitata add valuable minerals and vitamins to the otherwise micronutrient-“poor” staple crops of the Gulimanceba people. In comparison with other studies in West Africa, it has turned out that people in this area could benefit even more from A. leiocarpa, e.g. for dyeing of clothes, for treatment of malaria and skin problems. Local knowledge did not differ between genders and generations, while it slightly differed between people from different villages. The lack of age differences suggests that the traditional knowledge about these two species is passed on from one generation to another. Differences between people from different villages might be explained by influences from the neighboring countries Niger and Benin. Current local harvesting modes and management strategies of both species resulted in sustainable use. However, ongoing land-use intensifications require adapted harvesting and management techniques to guarantee the persistence of these economically important species. These results provide, in combination with the ecological findings (chapter 3 and 4), appropriate management recommendations for A. digitata and A. leiocarpa that are reliable under currently practiced management strategies.