In this thesis, we have studied the potential of the zebrafish larval model in studying the ECS, as a complementary model to the existing rodent models. More specifically, we have looked at the... Show moreIn this thesis, we have studied the potential of the zebrafish larval model in studying the ECS, as a complementary model to the existing rodent models. More specifically, we have looked at the role of the ECS in regulating locomotion and anxiety, and its interaction with the hypothalamic-pituitary-interrenal (HPI) axis, or stress axis. This study has provided us with an interesting animal model which allows for pharmacological screening of Cnr1 agonists, and their involvement in the CNS, as shown by a change in locomotion, anxiety-like behavior and HPI axis activity. The zebrafish larval model can be used as a complementary model to the existing rodent animal models, to study the ECS. The zebrafish larval model brings several interesting features, such as optical transparency and possibilities for high-throughput screening. Furthermore, a complete ECS is present, there is lack of endogenous activity, allowing for exogenous compound screening, and zebrafish data is generally in line with rodent literature. Since the ECS is involved in many diseases, more research of this system may result in the discovery of novel drugs and drug targets. Show less
Bacteria are highly complex and diverse organisms that have adapted to survive in ecological niches ranging from the most extreme to the most heterogeneous environments. Actinobacteria, with their... Show moreBacteria are highly complex and diverse organisms that have adapted to survive in ecological niches ranging from the most extreme to the most heterogeneous environments. Actinobacteria, with their beautiful morphologies and complex multicellular life cycle, are a striking example. These filamentous bacteria produce many enzymes and natural products, including two-thirds of all known antibiotics, which makes them highly relevant for medical, biotechnological and industrial applications. In Streptomyces, complex and intertwining regulatory networks, consisting of pathway-specific and global regulators, control development and antibiotic production in response to environmental stimuli and stresses. This thesis explores how the model organism Streptomyces coelicolor senses environmental signals, related to oxygen stress and the availability of aminosugars, and how the bacterium translates these into appropriate responses. Show less
The project described in this thesis was designed to test if genetic variation in the mineralocorticoid receptor (MR) gene is a risk factor for developing major depression. First the MR-gene was... Show moreThe project described in this thesis was designed to test if genetic variation in the mineralocorticoid receptor (MR) gene is a risk factor for developing major depression. First the MR-gene was screened for genetic variation. Two selected single nucleotide polymorphisms (SNPs) were tested for in vitro functionality at different levels including: protein and mRNA expression, transactivational capacity and ligand binding. Functionality in vitro was confirmed leading us to test their influence on electrolyte regulation, stress responsiveness and personality. First, in three different cohorts one SNP influenced blood pressure and salt regulation, as could be expected for the MR. Second, the SNPs were associated with the cortisol awaking response (CAR) after dexamethasone administration and with the cortisol and autonomic response following psychosocial stress. This indicates an important role for the MR in the regulation of the stress-response. Third in a relatively small cohort (n=150) the SNPs were not associated with mood and/or anxiety disorders but in the patient group there was an association with the personality trait neuroticism. We hypothesize that genetic variants in the MR-gene are determinants of vulnerability for psychiatric disorders. Show less
Pronounced ultradian and circadian rhythms in the hormones of the hypothalamic-pituitary-adrenal (HPA) axis (i.e. glucocorticoids), one of the body__s major neuroendocrine axes, were already... Show morePronounced ultradian and circadian rhythms in the hormones of the hypothalamic-pituitary-adrenal (HPA) axis (i.e. glucocorticoids), one of the body__s major neuroendocrine axes, were already demonstrated several decades ago. Until now, the clinical relevance of the pulsatile nature of glucocorticoids was poorly understood or sometimes even regarded as not important. Its evolutionary conservation across many species however implies biological significance. Indeed, glucocorticoids have been proven to be crucial for a plethora of bodily functions, e.g. emotion, cognition and the central mechanism underlying the adaptation to stress. Furthermore, disturbances in the characteristic temporal pattern of glucocorticoid exposure have often been described in stress-related pathology. However, the significance of glucocorticoids secretory patterns for physiology, stress responsiveness and nuclear receptor signalling is still largely unexplored and is accordingly addressed in this thesis. A new concept in the endocrinology of glucocorticoids has evolved from the data presented here showing that pulsatile release of glucocorticoids is a major determinant in __resilience__ of glucocorticoid signalling in neuronal cells and stress responsiveness. Moreover, we show that particularly the glucocorticoid receptor is affected after disrupting glucocorticoid pulsatility and could thus provide an excellent target for therapy to normalise the downstream effects of disturbances in glucocorticoid rhythms in stress-related disease. Show less
Currently, the raising awareness of the role of glucocorticoids in the onset of numerous (neuro)-pathologies constitutes the increasing necessity of understanding the mechanisms of action of... Show moreCurrently, the raising awareness of the role of glucocorticoids in the onset of numerous (neuro)-pathologies constitutes the increasing necessity of understanding the mechanisms of action of glucocorticoids in bodily processes and brain functioning. Glucocorticoids mediate their effects by binding to intracellular receptors which act as transcription factors. A remarkable and yet unexplained phenomenon described more than two decades ago, is the cell-specific effects glucocorticoids bring about on gene expression in brain. For example, while glucocorticoids suppress corticotrophin-releasing hormone (CRH) synthesis in the hypothalamus, production of CRH in the central nucleus of the amygdala (CeA) is stimulated by increased hormone levels. Inasmuch as the neuroanatomical distribution of the corticosteroid receptors does not satisfactorily explain these effects, it is of interest to decipher the role of recently discovered coregu lator proteins that modulate the direction and the magnitude of steroid receptor-driven transcription. Therefore, in the current thesis the expression and function of central coregulators was studied: the coactivators SRC1a and SRC1e along with the corepressors N-CoR and SMRT were found to be expressed in brain and involved in regulation of CRH gene expression. Finally, a method that allows detection of coregulator recruitment by steroid receptors in brain tissue was developed. Show less
A general overview of regulation of secondary metabolism in Pseudomonas species is given in Chapter 1. Several approaches were combined to identify novel genes involved in the regulation of PCN... Show moreA general overview of regulation of secondary metabolism in Pseudomonas species is given in Chapter 1. Several approaches were combined to identify novel genes involved in the regulation of PCN synthesis and to study their interactions with other regulators. Site-directed mutagenesis was used to test the hypothesis that rpoS is a regulatory gene of PCN synthesis (Chapter 2). To discover additional genes in the regulatory cascade, which already contains psrA and rpoS, a random DNA-fragment microarray of the PCL1391 genome was constructed and used for transcriptomics of the psrA and rpoS mutants (Chapter 3). A random mutagenesis approach resulted in the identification of pip, a novel gene that stimulates PCN production in PCL1391 (Chapter 4). Analyses on the role of Pip as a switch of PCN production depending on environmental conditions are described in Chapter 5. The results described in this thesis are summarized in Chapter 6, where in addition the regulatory network of PCN synthesis in P. chlororaphis PCL1391 is compared to regulatory networks of secondary metabolism in other Pseudomonas species. Show less
