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Several lines of evidence implicate a dysregulation of tryptophan hydroxylase (TPH)-dependent serotonin (5-HT) synthesis in emotions and stress and point to their potential relevance to the etiology and pathogenesis of various neuropsychiatric disorders. However, the differential expression pattern of the two isoforms TPH1 and TPH2 which encode two forms of the rate-limiting enzyme of 5-HT synthesis is controversial. Here, a comprehensive spatio-temporal analysis clarifies TPH1 and TPH2 expression during pre- and postnatal development of the mouse brain and in adult human brain as well as in peripheral organs including the pineal gland. Four different methods (real time PCR, in situ hybridization, immunohistochemistry and Western blot analysis) were performed to systematically control for tissue-, species- and isoform-specific expression on both the pre- and posttranslational level. TPH2 expression was consistently detected in the raphe nuclei, as well as in fibres in the deep pineal gland and in the gastrointestinal tract. Although TPH1 expression was found in these peripheral tissues, no significant TPH1 expression was detected in the brain, neither during murine development, nor in mouse and human adult brain. Also under conditions like stress and clearing the tissue from blood cells, no changes in expression levels were detectable. Furthermore, the reuptake of 5-HT into the presynaptic neuron by the serotonin transporter (SERT) is the major mechanism terminating the neurotransmitter signal. Thus, mice with a deletion in the Sert gene (Sert KO mice) provide an adequate model for human affective disorders to study lifelong modified 5-HT homeostasis in interaction with stressful life events. To further explore the role of TPH isoforms, Tph1 and Tph2 expression was studied in the raphe nuclei of Sert deficient mice under normal conditions as well as following exposure to acute immobilization stress. Interestingly, no statistically significant changes in expression were detected. Moreover, in comparison to Tph2, no relevant Tph1 expression was detected in the brain independent from genotype, gender and treatment confirming expression in data from native animals. Raphe neurons of a brain-specific Tph2 conditional knockout (cKO) model were completely devoid of Tph2-positive neurons and consequently 5-HT in the brain, with no compensatory activation of Tph1 expression. In addition, a time-specific Tph2 inducible (i) KO mouse provides a brain-specific knockdown model during adult life, resulting in a highly reduced number of Tph2-positive cells and 5-HT in the brain. Intriguingly, expression studies detected no obvious alteration in expression of 5-HT system-associated genes in these brain-specific Tph2 knockout and knockdown models. The findings on the one hand confirm the specificity of Tph2 in brain 5-HT synthesis across the lifespan and on the other hand indicate that neither developmental nor adult Tph2-dependent 5-HT synthesis is required for normal formation of the serotonergic system, although Tph1 does not compensate for the lack of 5-HT in the brain of Tph2 KO models. A further aim of this thesis was to investigate the expression of the neuropeptide oxytocin, which is primarily produced in the hypothalamus and released for instance in response to stimulation of 5-HT and selective serotonin reuptake inhibitors (SSRIs). Oxytocin acts as a neuromodulator within the central nervous system (CNS) and is critically involved in mediating pain modulation, anxiolytic-like effects and decrease of stress response, thereby reducing the risk for emotional disorders. In this study, the expression levels of oxytocin in different brain regions of interest (cortex, hippocampus, amygdala, hypothalamus and raphe nuclei) from female and male wildtype (WT) and Sert KO mice with or without exposure to acute immobilization stress were investigated. Results showed significantly higher expression levels of oxytocin in brain regions which are involved in the regulation of emotional stimuli (amygdala and hippocampus) of stressed male WT mice, whereas male Sert KO as well as female WT and Sert KO mice lack these stress-induced changes. These findings are in accordance with the hypothesis of oxytocin being necessary for protection against stress, depressive mood and anxiety but suggest gender-dependent differences. The lack of altered oxytocin expression in Sert KO mice also indicates a modulation of the oxytocin response by the serotonergic system and provides novel research perspectives with respect to altered response of Sert KO mice to stress and anxiety inducing stimuli.
Persönlichkeit im Allgemeinen wird, neben Umwelteinflüssen, durch genetische Komponenten beeinflusst. Bisher konnten jedoch nur wenige funktionelle Genvarianten mit Verhaltenszügen assoziiert werden. Aggressives Verhalten als spezifisches Verhaltensmuster wird durch eine Reihe von Genvariationen beeinflusst, die in serotonerge, dopaminerge und nitrinerge Regelkreise eingreifen. Neben der genetischen Komponente prädisponieren aber hier ganz erheblich auch äußere Faktoren in der Umwelt, wie z.B. das soziale Umfeld, in dem Kinder und Jugendliche aufwachsen, für die Entwicklung von gewalttätigem Verhalten. Ziel der vorliegenden Arbeit war es, einen möglichen Einfluss von vier verschiedenen funktionellen Gen-Polymorphismen (MAOA-uVNTR, DAT-uVNTR, NOS1 Ex1f-uVNTR und NOS1 Ex1c-SNP) auf Gewalttätigkeit bzw. Aggressivität zu untersuchen. Außerdem wurden Gen x Umweltinteraktionen im Bezug auf ungünstige soziale Bedingungen in der Kindheit untersucht. Eine aus 184 Männern bestehende Stichprobe von Straffälligen wurde in eine Gruppe von gewalttätigen und eine Gruppe von nicht-gewalttätigen Straftätern unterteilt. Durch die logistische Regressionsanalyse konnte ermittelt werden, dass der MAO-A Genotyp, wie auch ungünstige soziale Bedingungen in der Kindheit, unabhängig voneinander für gewalttätiges Verhalten prädispositionieren. 45% der Gewalttätigen, aber nur 30% der nicht-gewalttätigen Studienteilnehmer sind Träger des niedrig-aktiven kurzen MAO-A Allels. Die neuronale Isoform der Stickstoffmonoxid-Synthase (NOS-I) wurde, ebenso wie MAO-A, in Tierversuchen mit aggressiven Verhaltensweisen assoziiert. In der vorliegenden Arbeit konnte gezeigt werden, dass es auch einen Zusammenhang zwischen einem funktionellen Promotorpolymorphismus von NOS1 und menschlicher Aggressivität gibt. Im Gegensatz zu MAOA und NOS1 beeinflusst ein funktioneller Polymorphismus im DAT1-Gen Gewalttätigkeit nicht. Diese Ergebnisse legen komplexe Interaktionen zwischen genetischer Variation und Umweltfaktoren nahe und zeigen gleichzeitig, dass aggressives Verhalten nicht durch einfache Vererbungsmodi zu erklären ist.