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Cardiovascular disease is the leading cause of death worldwide. Aging is among the greatest risk factors for cardiovascular disease. Cardiovascular disease comprises several diseases, for example myocardial infarction, elevated blood pressure and stroke. Many processes are known to promote or worsen cardiovascular disease and in the present study, cellular senescence and inflammatory activation were of special interest, as they have a strong association to aging and can be seen as hallmarks of cellular aging.
Long noncoding RNAs (lncRNAs) are noncoding RNAs with a length of more than 200 nucleotides. In recent years, numerous regulatory functions were shown for these transcripts and lncRNAs were shown to directly interact with DNA, RNA and proteins. The long noncoding RNA H19 was among the first described noncoding RNAs and was initially shown to act as a tumor suppressor. More recently, several studies showed oncogenic roles for H19. In regards to the cardiovascular system, H19 was not analyzed before.
We show that H19 is the most profoundly downregulated lncRNA in endothelial cells of aged mice compared to young littermates. Microarray analysis of human primary endothelial cells upon pharmacological H19 depletion revealed an involvement of H19 in cell cycle regulation. Loss of H19 in human endothelial cells in vitro led to reduced proliferation and to increased senescence. H19 depletion was shown to counteract proliferation before, but none of the described mechanisms applied to endothelial cells. We show that the reduction in proliferative capacity and the pro-senescent function of H19 is most probably mediated by an upregulation of p16ink4A and p21 upon H19 depletion.
When we compared the angiogenic capacity of aortic endothelial cells from young and aged mice in an aortic ring assay, rings from aged mice showed a reduced cumulative sprout length. Interestingly, pharmacological inhibition of H19 in aortic rings of young animals, where H19 is highly expressed, was sufficient to reduce the cumulative sprout length to levels we observed from aged animals. Furthermore, overexpression of human H19 in aortic rings of aged mice, where H19 is poorly expressed, rescued the impaired angiogenic capacity of aged endothelial cells.
We generated inducible endothelial-specific H19 knockout mice (H19iEC-KO) and subjected these animals to hind limb ischemia surgery followed by perfusion analysis in the hind limbs by laser-doppler velocimetry and histological analysis. Perfusion in the operated hind limb was increased in H19iEC-KO compared to Ctrl littermates, which was in contrast to a reduction in capillary density in the operated hind limbs of H19iEC-KO animals compared to Ctrl littermates and to our previous results. Analysis of arteriogenesis revealed an increase in collateral growth upon EC-specific H19 depletion in the ischemic hind limbs, which explains the increase in perfusion despite the reduction in capillary density. Further characterization of the animals revealed an increase in leukocyte infiltration into the tissue in the ischemic hind limbs upon endothelial-specific H19 depletion, indicating a potential role of H19 in inflammatory tissue activation.
Reanalysis of the microarray data from human primary endothelial cells upon H19 depletion revealed an association of H19 with inflammatory signaling and more specifically with IL-6/JAK2/STAT3 signaling. Analysis of cell surface adhesion molecule expression revealed an upregulation of ICAM-1 and VCAM-1 on mRNA level and an increase of the abundance of the two proteins on the cell surface of human primary endothelial cells. Consequently, adhesion of isolated human monocytes to human primary endothelial cells was increased upon H19 depletion in vitro. Interestingly, TNF-α mediated inflammatory activation of primary human endothelial cells repressed H19 expression. H19 did not function via previously described mechanisms. We excluded a competitive endogenous RNA (ceRNA) function for H19 in endothelial cells and showed that miR-675, which is processed from H19, does not play a role in the endothelium. Furthermore, H19 did not regulate previously described genes or pathways.
Analysis of transcription factor activity upon H19 depletion and overexpression revealed a differential activity of STAT3. STAT3 phosphorylation at TYR705 and thus activation was increased upon H19 depletion. Inhibition of STAT3 activation using a small compound inhibitor abolished the effects of H19 depletion on mRNA expression of p21, ICAM-1 and VCAM-1 and on proliferation, indicating that the effects of H19 are at least partially mediated via STAT3. STAT3 was shown to have positive effects on the cardiovascular system before, most likely due to upregulation of VEGF in a STAT3-dependent manner. We were not able to confirm previously described mechanisms for STAT3 in the present study and propose a new mechanism of action for the H19-dependent regulation of STAT3. Taken together, these results identify the long noncoding RNA H19 as a pivotal regulator of endothelial cell function. Figure 38 summarizes the described functions of H19 in endothelial cells.
The composition of cellular membranes is extremely complex and the mechanisms underlying their homeostasis are poorly understood. Organelles within a eukaryotic cell require a non-random distribution of membrane lipids and a tight regulation of the membrane lipid composition is a prerequisite for the maintenance of specific organellar functions. Physical membrane properties such as bilayer thickness, lipid packing density and surface charge are governed by the lipid composition and change gradually from the early to the late secretory pathway. As the endoplasmic reticulum (ER) is situated at the beginning of the cells secretory pathway, it has to accept and accommodate a great variety and quantity of secretory and transmembrane proteins, which enter the ER on their way to their final cellular destination. Secretory proteins can be translocated into the lumen of the ER co- or posttanslationally and membrane proteins are being inserted and released into the ER membrane. In the oxidative milieu of the ER-lumen, supported by a variety of chaperones, proteins can fold into their native form.
If the folding capacity of the ER-lumen is exceeded, an accumulation of mis- or unfolded proteins in the lumen of the ER occurs, consequently triggering the unfolded protein response (UPR). This highly conserved program activates a wide-spread transcriptional response to restore protein folding homeostasis. In fact, 7 – 8% of all genes in the yeast Saccharomyces cerevisiae (S. cerevisiae) are regulated by the UPR. The mechanism underlying the activation of the UPR by protein folding stress has been investigated thoroughly in the last decades and many of its mechanistic details have been elucidated. Recently, it became evident that aberrant lipid compositions of the ER membrane, collectively referred to as lipid bilayer stress, are equally potent in activating the UPR. The underlying molecular mechanism of this membrane-activated UPR, however, remained unclear.
This study focuses on the UPR in S. cerevisiae and characterizes the inositol requiring enzyme 1 (Ire1) as the sole UPR sensor in S. cerevisiae. Active Ire1 forms oligomers and, collaboratively with the tRNA ligase Rlg1, splices immature mRNA of the transcription factor HAC1, which results in the synthesis of mature HAC1 mRNA and the production of the active Hac1 protein, which binds to UPR-elements in the nucleus and activates the expression of UPR target genes. Here, the combination of in vivo and in vitro experiments is being used, which is supplemented by molecular dynamics (MD) simulations performed by Roberto Covino and Gerhard Hummer (MPI for Biophysics, Frankfurt), aiming to identify the molecular mechanism of Ire1 activation by lipid bilayer stress. This study focuses on the analysis of the juxta- and transmembrane region of Ire1. Bioinformatic analyses revealed a putative ER-lumenal amphipathic helix (AH) N-terminally of and partially overlapping with the transmembrane helix (TMH). This predicted AH contains a large hydrophobic face, which inserts into the ER membrane, forcing the TMH into a tilted orientation within the membrane. The resulting unusual architecture of Ire1’s AH and TMH constitutes a unique structural element required for the activation of Ire1 by lipid bilayer stress.
To investigate the function of the AH in the physiological context, different variants of Ire1 were produced under the control of their endogenous promoter and from their endogenous locus. The functional role of the AH was tested, by disrupting its amphipathic character by the introduction of charged residues into the hydrophobic face of the AH. The role of a conserved negative residue between the TMH and the AH (E540 in S. cerevisiae) was tested by substituting it by a unipolar, polar, or positively charged residue. These variants were intensively characterized using a series of assays:
This thesis provides evidence that the AH is crucial for the function of Ire1: Mutant variants with a disrupted (F531R, V535R) or otherwise modified AH (E540A) exhibited a lower degree of oligomerization and failed to catalyze the splicing of the HAC1 mRNA as the Wildtype control. Likewise, the induction of PDI1, a target gene of the UPR, was greatly reduced in mutants with a disrupted or defective AH. These data revealed an important functional role of the AH for normal Ire1 function.
An in vitro system was established to analyze the membrane-mediated oligomerization of Ire1. This system enabled the isolated functional analysis of the AH and TMH during Ire1 activation by lipid bilayer stress. A fusion construct, coding for the maltose binding protein (MBP) from Escherichia coli (E. coli), N-terminally to the AH and TMH of Ire1 was produced. The heterologous production in E. coli, the purification and reconstitution of this minimal sensor of Ire1 in liposomes was established as part of this study. To analyze the oligomeric status of the minimal sensor in different lipid environments, continuous wave electron paramagnetic resonance (cwEPR) spectroscopic experiments were performed. These experiments revealed that the molecular packing density of the lipids had a significant influence of the oligomerization of the spin-labeled membrane sensor: increasing packing densities resulted in sensor oligomerization. The AH-disruptive F531R mutant, in which the amphipathic character of the AH was destroyed, showed no membrane-sensitive changes in its oligomerization status.
Thus, the activation of Ire1 by lipid bilayer stress is achieved by a membrane-based mechanism. According to the current model, the AH induces a local membrane compression by inserting its large hydrophobic face into the membrane. As membrane thickness and acyl chain order are interconnected, this compression simultaneously results in an increased local disordering of lipid acyl chains. Supporting MD simulations performed by Roberto Covino and Gerhard Hummer revealed that the bilayer compression is significantly more pronounced in a densely packed lipid environment, than in a lipid environment of lower lipid packing density. Hence, the energetic cost of the local compression increases with the packing density of the membrane, but is compensated for by the oligomerization of Ire1. This minimization of energetic cost induced by the membrane deformation of Ire1 forms the basis for the activation of Ire1 by lipid bilayer stress.
The cardiovascular system (CVS) consists of heart and blood vessels, forming a close circulatory loop. All tissues depend on the nutrients and molecular oxygen (O2) delivered by the blood. Therefore, it is not surprising that the CVS is one of the first working systems and the heart is the first functional organ in the forming embryo (Baldwin 1996). The building blocks of blood vessels are endothelial cells (ECs), which form the endothelium, a specialized epithelium that defines the luminal surface of the vessels (Pugsley and Tabrizchi 2000). The process of blood vessel development comprises several steps. The first events occurring are the formation of new vessels de novo to constitute the primary vascular loop known as vasculogenesis. During vasculogenesis the vascular precursors, known as angioblasts, migrate and coalesce to form the axial vessels. Subsequently, the main vessels undergo a specification step where they acquire either arterial or venous identity. As the embryo increases in size, the main vascular loop needs to increase in complexity. In order to reach all the different parts of the developing organs, new blood vessels are formed from pre-existing ones, a phenomenon known as angiogenesis (Gore et al. 2012).
Mature blood cells have a short lifespan. Therefore, hematopoietic stem cells (HSCs) are required throughout lifetime to constantly form new blood cells in a process called hematopoiesis. Interestingly, endothelial and immune cells development have been shown to converge at different points during their development, one of which is developmental hematopoiesis. During embryogenesis, definitive hematopoiesis occurs in a tissue called hemogenic endothelium (HE), a specialized subset of ECs at the ventral wall of the dorsal aorta (DA). HE acquires hematopoietic potentials and gives rise to HSCs, through a process known as endothelial-to-hematopoietic transition (EHT). During EHT, these specialized ECs extrude from DA and colonize the so-called aorta-gonadmesonephros (AGM) region, forming the native HSCs (Paik and Zon 2010).
As vascular development requires different steps, the molecular pathways involved are many. The Notch signaling pathway has been demonstrated to be one of the main players in vascular development. Among other functions, Notch signaling has been shown to be important during EHT. In the murine model, Runx1, a master regulator of HSC formation, has been shown to be transcriptionally regulated by NOTCH1 through GATA2 activation. This observation was later corroborated by knockdown studies for notch1a and notch1b in zebrafish (Butko, Pouget, and Traver 2016). Another essential pathway for vascular development is the HIF pathway. Hif-1α, Hif-1β and Hif-2α mouse mutants show severe vascular defects that result in early embryonic lethality (Simon and Keith 2008), which hinders a deep analysis of the phenotypes incurring in the mutant embryos. In addition, deletion of Hif-1α specifically in myeloid cells showed abnormalities in the motility, invasiveness, and adhesion of macrophages (Cramer et al. 2003). Intriguingly, Hif-1α deletion in vascular endothelial cadherin-expressing cells led to a significant but partial reduction of HSC number, suggesting that other players may be involved in this pathway (Imanirad et al. 2014).
Zebrafish embryos have been shown to be tolerant to hypoxia at very early stages of development (Padilla and Roth 2001). Also, zebrafish embryos develop externally and this allows to finely manipulate the environment where they grow (Lieschke and Currie 2007). These features make zebrafish an ideal model to investigate how hypoxia and Hif transcription factors affect vertebrate vascular development. In this study, I will examine the impact of hypoxia on zebrafish vascular development. Specifically, I will dissect the role of hif-1α in macrophage-EC interactions during vascular development and repair. Moreover, I show redundant functions for hif-1α and hif-2α in HSC development upstream of Notch signaling.
Deciphering the ecological functions of fungal root endophytes based on their natural occurrence
(2017)
Plants are colonized by a large diversity of fungi, some residing on the surface and others penetrating the plant tissues, the latter referred to as fungal endophytes (endon Gr., within; phyton, plant; de Bary 1879). Despite the saprotrophic potential of fungal endophytes, they are not found to cause visible disease symptoms to the host. Plants are colonized simultaneously by various fungal species, which form rich and diverse endophytic assemblages. Although it is hypothesized that fungal endophytes contribute to the fitness of their hosts and to the functioning of ecosystems, the ecological function of fungal endophytic assemblages remains cryptic. The aims of this doctoral thesis are to gain insight to the ecological functions of root fungal endophytes, by deciphering their roles in ecosystems based on their natural occurrence and the structure of their assemblages. The thesis focuses on studying the diversity and structure of the endophytic mycobiome within roots of two annual and widespread plant hosts Microthlapsi perfoliatum and M. erraticum (Brassicaceae) in several locations across northern Mediterranean and central Europe. The thesis is composed by six Chapters, with a primary focus on Chapter 1, 2 and 3.
Chapter 1 (Glynou et al., 2016) aimed at characterizing the diversity of fungal endophytes in roots at a continental scale and at assessing the factors affecting the structure of endophytic assemblages with the use of cultivation-based methods. For that, root samples were collected from 52 plant populations, along with a collection of soil, bioclimatic, geographic and host data. Cultivation of surface-sterilized root samples on culture media and isolation of fungal colonies in pure culture generated 1,998 fungal colonies. Grouping of sequences into Operational Taxonomic Units (OTUs), based on the 97% similarity of the isolates’ rDNA Internal Transcribed Spacer (ITS) sequence, generated in total 296 OTUs, representing taxa mostly within the phylum Ascomycota with a minor representation of Basidiomycota. Endophytic assemblages were mostly correlated with variation in bioclimatic conditions. Interestingly, despite the large diversity revealed, the assemblages were dominated by only six OTUs related to the orders Hypocreales, Pleosporales and Helotiales, which had a widespread distribution across populations but with some following patterns of ecological preferences.
Chapter 2 aimed at characterizing the uncultivable fraction of the root fungal endophytic diversity, which was not possible to capture in Chapter 1. High-throughput sequencing via the
Illumina Miseq platform was implemented in 43 of the 52 original populations and mostly in the same root samples. In comparison with the cultivation-based approach, the HTS managed to cover the overall diversity within samples. It revealed a large non-cultivated endophytic diversity but the same cultivable fungi dominated assemblages. Moreover, the endophytic diversity was grouped mostly within fungal orders with demonstrated ability to grow in culture and taxonomically related groups were found to have divergent ecological preferences.
The genetic identity of the most abundant OTUs was further investigated in Chapter 3 (Glynou et al., 2017), aiming to unravel genotypic variability, which was possibly overlooked due to the use of lTS, as a universal genetic marker, and could explain their high abundance and widespread distribution. Multi-locus gene sequencing and AFLP profiling for the five most abundant OTUs suggested a low within-OTU genetic variability and show that these fungi have ubiquitous distribution and are not limited by environmental conditions within the ecological ranges of the study. A selection of endophytes frequently isolated in Chapter 1 was functionally characterized in Chapter 4 (Kia et al., 2017) based on the isolates’ traits and interactions with plants. In Chapter 5 (Cheikh-Ali et al., 2015) fungal cultures of Exophiala sp. with differential colony structure where investigated for their production of secondary metabolites. Moreover, Chapter 6 (Maciá-Vicente et al., 2016) comprises the description of the new species Exophiala radicis based on morphological and molecular characteristics.
Compilation of all results shows that the fungal endophytic diversity in roots of Microthlaspi spp. is high but few widespread OTUs dominate the assemblages, and have unlimited dispersal ability. These fungi seem also to have a wide niche breadth and are not affected by environmental filtering. The findings indicate that the local environment but also processes of competitive exclusion determine the structure of endophytic assemblages. In addition, the fungal endophytes associated with Microthlapsi spp. likely have saprotrophic activity however the interactions with plants are likely context-dependent. Further research is needed to assess the biotic interactions among endophytes and their effect on the structure of fungal endophytic assemblages. Ultimately, the findings of this thesis are useful to shed light on the processes underlying the structure of endophytic assemblages. They also upraise the need to describe diversity by combining genetic, metabolic and physiological data, in order to disentangle the elusive ecological roles of the endophytic mycobiome.
Tissue integrity is defined by the composition and connection of cells as a structural and functional unit. It is modulated by a magnitude of processes including differentiation, survival, controlled death and adhesion of cells. Besides, external factors such as physical forces are also involved. A suitable model system to study all modalities of tissue integrity is the mammary gland. Postnatally and within the reproductive phase, the mammary gland undergoes morphological and functional modifications that periodically loosen or strengthen tissue integrity. An important point in the development of the mammary gland is the regression during weaning, also termed involution. The transition from lactation to involution is important for a controlled loss of tissue integrity. In this transition, collective cell death is initiated but not yet prominent enabling the mammary gland to fully recover lactation.
In this thesis, modalities of tissue integrity were investigated using three-dimensional cell cultures (i.e. spheroids) and the mammary gland as model systems. In the context of this thesis, I established (1) an immunofluorescence staining protocol and its detailed evaluation. Furthermore, I studied (2) the role of cell survival during mammary gland development, (3) the effect of physical forces that modulate tissue integrity and (4) the contribution of proteins to cell adhesion and growth.
Since a homogeneous fluorescence stain of the specimen is necessary for quantitative analysis, an immunofluorescence staining protocol was established to stain large spheroids in toto. The evaluation contributes qualitative and quantitative criteria that judge the specificity, intensity and homogeneity of the stain. Based on this approach, it was possible to demonstrate the morphological and functional characteristics that spheroids share with the mammary gland in vivo. These characteristics included the synthesis of extracellular matrix, the development of polarized acinar structures and lactogenic differentiation.
The role of cell survival during mammary gland development was analyzed by means of the expression profile of the pro-survival protein BAG3. The expression of BAG3 differed in the progress of mammary gland development. While the expression was low during pregnancy, it rose in the lactation phase and peaked within the first days of involution, indicating that BAG3 is associated with early involution in the mammary gland. In vitro experiments related the expression of BAG3 to cell survival in mammary epithelial cells.
Physical forces naturally occur during developmental processes influence tissue integrity during the initiation of mammary gland involution. The influence of physical force applied as compression on mammary epithelial spheroids was investigated. A morphological analysis showed that following a lag, the cell nuclei volume changed upon compression. A short-term compression induced the activation of caspases. A prolonged compression reduced the activity of caspases. This suggests the induction of a process that allows cells the adaption to changing environmental conditions. BAG3 is known to be involved in mechanical stress-induced autophagy, also known as chaperone assisted selective autophagy (CASA). Compression of spheroids did not induce CASA. The experimentally applied strain was not comparable to the strain found in the alveolar cells during involution in vivo. Thus, whether or not CASA is activated during mammary gland involution remains elusive. Nevertheless, the methodical approach to apply compression on spheroids in vitro is a model to study the influence of physical forces on cell aggregates.
Apart from cell survival and physical forces, growth and adhesion of cells affect tissue integrity. A spheroid formation assay and subsequent data analysis and computational modeling enabled the investigation of these processes in a non-adhesive environment. The analysis suggested that spheroid formation follows a reaction-controlled process, in which cells do not necessarily form a connection when they collide. The loss of function of either E-cadherin or actin strongly inhibited the formation of a spheroid. The analysis further revealed that neither E-cadherin nor actin influence the chance of the cells to form a connection when they collide. Both molecules are more important in stabilizing established connections. Depolymerization of microtubules still allowed spheroids to form, but the formation was decelerated and growth of the final spheroids was inhibited. The results from computational modeling suggested that microtubules act on cell adhesion through different mechanisms, which also vary among different cell types. The inhibition of FAK phosphorylation at Y397, a downstream target of integrin signaling, and the analysis of FAK protein levels in spheroids showed that integrin-mediated signaling is not prominent in three-dimensional spheroids formed from non-invasive cells. A deletion of BAG3 gene expression increased the number of dead cells in forming spheroids suggesting that BAG3 predominantly affects cell survival.
The results of this thesis identified and characterized adhesion- and survival-associated proteins that are important for tissue integrity. This thesis suggests that a BAG3-dependent cell survival mechanism is prominent at the beginning of mammary gland involution. Future studies will have to identify the related factors and inducers of tissue integrity loss in the mammary gland. This will shed light on the physiology of the organ and could explain the disorders that destroy its integrity. In addition, this thesis contributes to a better understanding of spontaneous cell aggregation, the aggregate organization and implies a role of cell migration in these processes. Future studies that focus on three-dimensional cell migration could explain, how cell migration is promoted and to which extent it supports tissue integrity.
Savannas provide essential ecosystem services for human well-being in West Africa. Thus, ecosystem change not only directly affects biodiversity but also human livelihoods. Human land use considerably shaped these savanna ecosystems for millennia, particularly agriculture, livestock grazing, logging and the collection of non-timber forest products (NTFPs). NTFPs are wild plant products and comprise all organic matter from herbaceous plants, shrubs, and trees (excluding timber). Current increasing land use pressure through fast demographic changes is widely esteemed as a severe threat for savanna biodiversity and the socio-economy of rural communities. In consideration of the pivotal role of NTFP species for biodiversity and livelihoods, it is important to evaluate the effect of increasing land use change on savanna vegetation and on its provisioning service for human well-being. Thus, the major aim of this thesis is to investigate the impacts of land use intensification on vegetation composition, diversity and function and its consequences for provisioning ecosystem services (NTFPs) and human well-being in a West African savanna.
The research for this study was conducted in the North Sudanian vegetation zone of south-eastern Burkina Faso, where population growth exceeds the nationwide trend. Generally, Burkina Faso belongs to the worldwide poorest countries, where nearly one quarter of the population suffers from malnutrition (FAO 2014). The integration of NTFPs and particularly wild food species into rural household economies is, thus, an important measure in the national combat against poverty and food insecurity (FAO 2014). Against this background, I focus on vegetation changes, the economic importance of NTFPs as well as the decrease and substitution of wild food species in this study.
Vegetation resurveys of different vegetation types since the early 1990s showed that land use change led to more pronounced changes in the herbaceous than in the woody vegetation layer. Most woody vegetation types stayed stable in species composition and richness, even though some highly useful tree species (Vitellaria paradoxa, Parkia biglobosa) declined in some woody vegetation types. In contrast, in most herbaceous vegetation types species richness increased and species composition considerably changed. This change might be explained by a general ruderalisation process through a pronounced increase of wide-ranging herbaceous species. However, in spite of a general species increase in the herbaceous layer, a decrease of preferred herbaceous fodder species was found. Thus, the decline of useful species in both layers is alarming. Herbaceous vegetation types also showed more pronounced changes in plant functional trait characteristics in comparison to woody vegetation types. However, an increase of smaller plant species and species with a high diaspore terminal velocity (VTerm) was found in both vegetation layers. Since these two trait responses are generally related to grazing and browsing, the strong increase of livestock herds is likely to be responsible for the detected vegetation changes.
In addition to the vegetation study, interviews showed that all useful food species were widely considered to decline. The two economically most important tree species, the shea tree (Vitellaria paradoxa) and the locust bean tree (Parkia biglobosa) that contribute with 70% to wild food income, were considered among the most declining species of all cited wild food species. On this matter, local perceptions of species decline and results from field observations are in accordance. However, a wide range of cited substitutes indicated a great knowledge on alternative plant species in the area. Most wild food species are, however, substituted by other highly valued wild food species. Although our results suggest that rural communities are able to cope with the decrease or absence of wild food species, growing decline of one species would concurrently increase the pressure on other native food species. Therefore, the need to counteract the decrease of highly useful wild food species should be of high priority in management measures. In general, I showed that NTFPs are an essential component in rural households, since it contributed with 45 % to total household income. Significant differences in NTFP dependency between the two investigated villages and across the three main ethnic groups were detected, reflecting different traditional uses and harvesting practices. In general, it was shown that poorer households depend more on NTFP income than wealthier households. Against the background of this study, management strategies for agroforestry systems and poverty alleviation should consider local differences, and ethnicity-dependent NTFP-use patterns.
Overall, the combination of field studies on temporal and functional vegetation change with socio-economic and ethno-botanic interviews increases the knowledge on qualitative and quantitative vegetation changes and on the consequences for rural populations. This thesis gives a thorough insight into decreasing trends of economically valued plant species and thus gives evidence on the consequences of vegetation changes for ecosystem services of West African savanna ecosystems. Further, different NTFP-dependencies and use preferences according to socio-economic and cultural variables, such as ethnicity, present a valuable basis for specific decision-making and should be considered in management plans.
Die Paarverteilungsfunktion (PDF) beschreibt die Wahrscheinlichkeit, zwei Atome eines Materials in einem Abstand r voneinander zu finden. Diese Methode bewährt sich seit längerer Zeit zur Untersuchung von Gläsern, Flüssigkeiten, amorphen, stark fehlgeordneten und nanokristallinen anorganischen Substanzen. Die Anwendung für organische Substanzen ist jedoch relativ neu, mit etwa 20 Veröffentlichungen und Patenten insgesamt.
Im Rahmen dieser Dissertation wurden zwei Methoden zur Strukturverfeinerung und Strukturlösung organischer Substanzen anhand von PDF-Daten erfolgreich entwickelt und an diversen Beispielen validiert. Als erster Schritt hierzu wurde eine Methodenverbesserung vorgenommen. Hierbei handelte es sich um eine Verbesserung der Simulation der PDF-Kurven organischer Verbindungen anhand eines gegebenen Strukturmodells. Mit Hilfe der bisherigen Methoden können die PDF-Kurven anorganischer Substanzen erfolgreich simuliert werden. Für organische Substanzen werden bei Anwendung der bisherigen Methode die Signalbreiten der intramolekularen und intermolekularen Beiträge zu der PDF-Kurve falsch wiedergegeben, dies führt zu einer schlechten Anpassung der simulierten PDF-Daten and die experimentellen PDF-Daten. Deshalb wurde ein neuer Ansatz entwickelt, in welchem für die Berechnung der intramolekularen Beiträge zum PDF-Signal ein anderer isotroper Auslenkungsparameter verwendet wurde, als bei der Berechnung der intermolekularen Beiträge zum PDF-Signal. Mit diesem Ansatz konnte eine sehr gute Simulation der PDF-Kurve für alle Testbeispiele erzielt werden. Zur Strukturverfeinerung organischer Substanzen anhand von PDF-Daten wurden zwei Ansätze entwickelt: der Rigid-Body-Ansatz zur Behandlung starrer organischer Moleküle und der Restraint-Ansatz zur Behandlung flexibler organischer Moleküle.
Neben methodischen Entwicklungen wurden in dieser Arbeit zwei weitere Untersuchungen organischer Verbindungen mittels PDF-Analyse durchgeführt.
Es wurden drei, auf unterschiedliche Weise hergestellte, amorphe Proben des Wirkstoffes Telmisartan untersucht. Des Weiteren wurde mittels PDF-Analyse eine pharmazeutische Nanosuspension untersucht.
Im Rahmen der vorliegenden Arbeit wurden Inhibitoren der bakteriellen Resistenzproteine New Delhi Metallo-β-Lactamase 1 (NDM-1), die beiden Mutanten der Verona-Integron Encoded Metallo-β-Lactamase 1 und 2 (VIM-1, bzw. -2), sowie die Imipenemase 7 (IMP-7) entwickelt.
Auf Grund natürlicher Selektion, aber vor allem auch bedingt durch den unüberlegten und verschwenderischen Einsatz von β-Lactam-Antibiotika, ist eine weltweite Zunahme an multiresistenten Erregern zu beobachten. Einer der Hauptgründe dieser Resistenzen sind die Metallo- β-Lactamsen (MBL), welche vor allem in Gramnegativen Bakterien vertreten sind und für die Hydrolyse und damit der Desaktivierung der β-Lactam-Wirkstoffe verantwortlich sind. Neben der Suche nach anderweitig wirkenden Antibiotika, ist die Entwicklung von Inhibitoren der MBLs von vordringlicher Bedeutung.
Basierend auf der Grundstruktur des ACE-Hemmers Captopril, wurden trotz synthetischer Herausforderungen erfolgreich mehrere Strukturen mit inhibitorischer Aktivität gegenüber den MBLs synthetisiert. Der Prolinring von Captopril wurde in einer neuen Variante der Captopril-Synthese durch verschiedene Ring- und nicht cyclische Teilstrukturen ersetzt. Durch die Entwicklung einer Schutzgruppenstrategie, konnte die Ringstruktur durch einen Piperazin-Rest ersetzt werden. Dies erlaubt es, die Molekülstruktur auf dieser Seite zu erweitern. Des Weiteren wurde eine neue Syntheseroute etabliert, welche es auf elegante Weise ermöglicht, weitere Derivatisierungen an der Methylgruppe des Captoprils durchzuführen.
In einem proteinbasierten Testsystem wurden die synthetisierten Substanzen auf ihr inhibitorisches Potential hin untersucht. Dabei wurden IC50-Werte im niedrig einstelligen mikromolaren, für drei Verbindungen sogar im sub-mikromolaren Bereich ermittelt. Die erhaltenen Ergebnisse wurden für die drei aktivsten Inhibitoren durch eine Erhöhung des Schmelzpunktes in einem TSA-Testsystem erfolgreich verifiziert. Mittels ITC-Untersuchungen konnte die unterschiedlichen Gewichtungen der entropischen und enthalpischen Beiträge zur Bindung der Inhibitoren an die untersuchten MBLs aufgezeigt werden. Hierdurch konnten die scheinbar widersprüchlichen Ergebnisse der ermittelten IC50-Werte und Schmelzpunktverschiebungen für die Verbindung DBDK48 bezüglich der NDM-1 aufgeklärt werden.
Die Strukturen DB320 konnte erfolgreich mit VIM-2 co-kristallisiert werden. Dies ermöglicht eine genauere Untersuchung und qualifizierte Aussagen über die Bindungsverhältnisse zwischen Protein und Ligand.
Für zwei der synthetisierten Inhibitoren sollte untersucht werden, ob deren Aktivität in vitro auch in Bakterien erhalten bleibt. Dazu wurden pathogene klinische Isolate und Laborstämme, welche mit dem Resistenzplasmid transfiziert wurden, und gegen Imipenem resistent sind, herangezogen. Durch die Zugabe der Inhibitoren konnte die Wirksamkeit von Imipenem wiederhergestellt werden.
Es konnte eine HPLC-Methode etabliert werden, welche eine Abschätzung der Polaritäten in Abhängigkeit der Retentionszeiten erlaubt. Dadurch konnte ein direkter Zusammenhang zwischen der Polarität der Verbindungen und dem Grad der Wirksamkeit im MIC-Testsystem aufgezeigt werden.
Durch die Untersuchung der Inhibitoren auf die Proteine ACE und LTA4H, konnten zwei Ziel-Proteine der Captopril-Grundstruktur als unerwünschte Nebenziele ausgeschlossen werden. Des Weiteren führte die Behandlung von U937-Zellen, selbst bei einer hohen Konzentration von 100 µM, weder zu Auffälligkeiten in einem WST-1 Assay, noch zu einer erhöhten Freisetzung von LDH. Daher kann davon ausgegangen werden, dass die Verbindungen über keine zytotoxischen Eigenschaften verfügen.
Surface water can contain a complex mixture of organic micropollutants (i.e. residues of pharmaceuticals or biocides). Conventional wastewater treatment plants (WWTPs) do not completely remove a broad range of anthropogenic chemicals and therefore represent a leading point source. To upgrade WWTPs, technical solutions based on oxidative and sorptive processes have been developed and successfully implemented. Acknowledging these substantial advances, this thesis focuses on another key topic and aims to investigate whether improved biological treatment processes likewise effectively remove anthropogenic micropollutants from wastewater. The work conducted on this topic was part of two European research projects (ATHENE, ENDETECH).
The ATHENE project aimed to go beyond the state-of-the-art by developing biological wastewater treatment processes that exploit the full potential of biodegradation. With the objective to explore the potential of complementary strictly anaerobic conditions within the biological wastewater treatment, combinations of aerobic and anaerobic treatments on site of a WWTP were implemented. Based on pre-experiments, two promising treatment combinations were selected for a more comprehensive evaluation. An aerobic treatment was paired with an anaerobic pre-treatment under iron-reducing conditions, and an activated sludge treatment was combined with an anaerobic post-treatment under substrate-limiting conditions. For the evaluation of these processes, an effect-based assessment was applied and combined with chemical data of 31 selected target organic micropollutants as well as ten metabolites. To assess the removal of endocrine disrupting chemicals (EDCs), yeast based reporter gene assays covering seven receptor-mediated mechanisms of action including (anti-)estrogenicity, (anti-) androgenicity, retinoid-like, and dioxin-like activity were conducted. Furthermore, the removal of unspecific toxicity (Microtox assay) and oxidative stress response as a marker for reactive toxicity (AREc32 assay) were analyzed to cover micropollutants acting via a non-specific mechanism of action. Moreover, to assess toxicity of the whole effluent in vivo, standardized in vivo bioassays with four aquatic model species (Desmodesmus subspicatus, Daphnia magna, Lumbriculus variegatus, Potamopyrgus antipodarum) were performed.
The combination of aerobic and anaerobic treatments resulted in a low additional removal of the selected target organic micropollutants (by 14-17%). In contrast, the removal of endocrine and dioxin-like activities (by 17-75%) and non-specific in vitro toxicities (by 27-60%) was significantly enhanced. Compared to technical solutions (i.e. ozonation), the combination with an anaerobic pre-treatment under iron-reducing conditions was likewise effective in removing the estrogenic activity as well as the unspecific toxicity, whereas anti-androgenic activity and dioxin-like activity were less effectively removed. Exposure to effluents of the conventional activated sludge treatment did not induce adverse in vivo effects in the investigated aquatic model species. Accordingly, no further improvement in water quality could be observed. In conclusion, the combination of aerobic and anaerobic treatment processes significantly enhanced the removal of specific and non-specific in vitro toxicities. Thus, an optimization of the biological wastewater treatment can lead to a substantially improved detoxification. These capacities of a treatment technology can only be uncovered by complementary effect-based measurements.
The global objective of the ENDETECH project was to develop a biotechnological solution to eliminate recalcitrant pharmaceuticals in wastewater direct from sites, where high loads are expected (i.e. hospitals). For this purpose, laccase, an enzyme mainly found in wood decaying fungi, was immobilized on ceramic membranes for application in bioreactors. In a proof of principle experiment, the performance of immobilized laccase in removing a mixture of 38 antibiotics without and in combination with a natural mediator (syringaldehyde; SYR) was investigated. For the evaluation of the enzymatic membrane bioreactors, chemical data on the elimination of the selected target antibiotics was combined with the outcomes of two in vitro bioassays. Growth inhibition tests with an antibiotic sensitive Bacillus subtilis strain were conducted to assess the residual antibiotic activity of the effluents, and Microtox assays were performed to detect a potential formation of toxic by-products.
The treatment by laccase without SYR did not reduce the load of antibiotics significantly. In contrast, in combination with a SYR concentration of 10 µmol L-1, 26 out of 38 antibiotics were removed by >50% after 24 h treatment. Moreover, increasing the SYR concentration to 1000 µmol L-1 resulted in a further improvement of the antibiotic removal. 32 out of 38 antibiotics were removed by over 50%, whereby 17 were almost completely eliminated (>90%). However, the treatment with laccase in combination with SYR resulted in a time-dependent increase of unspecific toxicity. While SYR alone did not affect B. subtilis, the combination of laccase with SYR led to a strong time-dependent growth inhibition up to 100%. Similar to that, a time-dependent increase of unspecific toxicity in the Microtox assay was observed. In conclusion, the laccase-mediator process successfully degrades a broad spectrum of antibiotics and thus represents a promising technology to treat wastewater from sites, where high loads are expected. However, further research is required to reduce the formation of unspecific toxicity before an implementation of this technology can be considered.
The focus of this research was to understand the molecular mechanism that lies behind the insertion of tail-anchored membrane proteins into the ER membrane of yeast cells. State-of-art instruments such as LILBID, and Cryo-EM, combined with the introduction of direct electron detectors, were used to analyze the proteins that capture tail-anchored proteins near the ER membrane and help their releases from a chaperone, an ATPase named Get3. Get3 escorts TA proteins to the ER membrane, where both Get3 and the TA proteins interact sequentially to Get3 membrane bound receptors Get1 and Get2. Get1 and Get2 are homologs of mammalian WRB and CAML.
The native host was used to separately produce Get1, Get2, and the Get2/Get1 single chain constructs. The studies showed that when Get1 is expressed alone, Get1 does not seems to be located in the ER membrane but rather in microbodies like shape organelles (or peroxisome). Interestingly, Get1 seems to be located in the ER membrane when it is linked to Get2 as single chain construct.
The localization study of Get2/Get1 fused to GFP shows from the fluorescence intensity that Get2/Get1.GFP has a tube-like morphology or membrane-enclosed sacs (cisterna), implying that Get2/Get1 is actually targeted to the ER membrane and is likely functional. In other words, Get1 and Get2 stabilize each other in the ER membrane.
The expression of Get2/Get1 was found to be already optimum when expressed as single chain construct because the fluorescence counts did not improve when additives such as DMSO or histidine were added. However, when Get1 and Get2 are expressed separately, additives improve their protein production yield. In 1 liter culture, Get1 yield is increased by about 3 mg and Get2 by 1.8 mg. This can be explained by the space that Get1 and Get2 should occupy within the ER membrane as they must coexist with other membrane components to maintain the homeostasis of the cell. Hence, if there were no gain for single chain construct expression, it meant that Get2/Get1 was already well expressed on its own in ER membrane and has reached its optimum expression without the help of additives. The Get2/Get1 overexpression is more stable, tolerated and less toxic for the cells to express it at a high level.
DDM has proved to be the best detergent from the detergents tested to solubilize Get1, Get2, and Get2/Get1.
Thereafter, Get1, Get2 (data not shown), and Get2/Get1 were successfully purified in DDM micelles.
Furthermore, for the first time using LILBID, the actual study has shown that Get1 and Get2 are predominantly a heterotetramer (2xGet1 and 2xGet2) but higher oligomerization may exist as well.
Get3 binds to Get1 in a biphasic way with a specific strong binding of an affinity of 57 nM and the second of 740 nM nonspecific indicative of heterogeneity within the interaction between Get1 and Get3. This heterogeneity is caused by the presence of different conformation of either protein. However, in order to characterize a high-resolution structure model of a specific target one needs highly homogenous and identical molecules of the target protein or complex in solution. The homogeneity increases the chances of growing crystals during crystallography as the good homogeneity will likely generate a perfect packing of unit cells stack (also known as crystal lattice) in the three-dimensional spaces. The same truth goes for the single particles analysis Cryo-EM, especially for smaller complexes where having less or no conformation alterations of specific targets will enable the researcher to classify the particles in 2D and 3D, therefore improving the signal-to-noise-ratio that will ultimately lead to high-resolution structure determination.
Get1, Get2/Get1 and chimeric variants (tGet2/Get1, T4l.Get2/Get1, T4l.Get2.apocyte.Get1) were crystallized but none of the crystals could diffract due to heterogeneity.
This heterogeneity was not only occurring upon the binding of Get3 to its membrane receptors, but seems to be already present within the receptors themselves through possibly different conformation.
In this Ph.D. thesis, the heterogeneity of purified Get2 and Get1 as complex or individually in detergent is then, so far, the limiting factor for obtaining a high-resolution structure model of Get1 and Get2. As mentioned above, the heterogeneity observed was not due to the quality of the sample preparation but rather to the effect of different conformations that could have been native, or just because of the micelle used, as it was proven by the 3-D heterogeneity classification by Cryo-EM.
In general, crosslinking is one way to keep the integrity of protein complexes, however it appeared not to improve the sample quality when it was analyzed in micelles. Often the integrity of some membrane proteins is affected when they are solubilized and purified in detergents.
Finally, in this study, the structural map of Get2 and Get1 complex linked with chimeric protein T4 lysozyme and apocytochrome C b562RIL gene was obtained at 10 Å. However, this single chain construct has a density map corresponding to heterodimer species (one Get1 and Get2). Therefore, based on those data the tertiary structure of Get2/Get1 in micelle is poorly defined. It could be that the membrane extraction in DDM and the purification destabilizes the structure of the complex.