Strategische Stadtentwicklungsplanung Innsbruck 2015 : Quo vadis?

Im Rahmen des Grundkurses „Internationales Verwaltungsmanagement“ wurden im Wintersemester 2005/2006 von den Studentinnen und Studenten Seminararbeiten zur strategischen Stadtentwicklungsplanung für die Stadt Innsbruck verfasst. Unter dem Motto „Innsbruck 2015 – quo vadis“ bekamen die Studierenden die Aufgabe, eine SWOT-Analyse der Tiroler Landeshauptstadt durchzuführen, um, darauf aufbauend, einen strategischen Stadtentwicklungsplan für Innsbruck zu erarbeiten. Im ersten Teil dieser Arbeit befindet sich nun ein kurzer Überblick zu den theoretischen Hintergründen der strategischen Stadtentwicklungsplanung. Anschließend wird das Ergebnis der SWOT-Analyse vorgestellt, welches auf Interviews mit Stakeholdern und Vertretern aus den Bereichen Wirtschaft und Tourismus, Bildung und Jugend, Kultur und Sport, Soziales, Stadtplanung und Urbanistik, Umwelt und Verkehr, der Umlandgemeinden Hall und Völs sowie aus dem Bereich Arbeitnehmer basiert und durch statistische Daten der Stadt Innsbruck ergänzt wurde. Für detailliertere Informationen bezüglich der SWOT-Analyse soll auch noch auf das Kapitel 7 verwiesen werden, in dem alle Interviews nachgelesen werden können. Anhand zweier Beispiele, „Innsbruck, die Wissensstadt“ und „Kultur- und Sportstadt Innsbruck – Die Stadt meiner Träume“, wird im Hauptteil dieses Papers, ausgehend von der SWOT-Analyse, aufgezeigt, wie eine strategische Stadtentwicklungsplanung - im konkreten Fall für Innsbruck - aussehen könnte

Regulação da expressão gênica nas engrenagens do relógio circadiano de mamíferos

The expression of biological rhythms in most organisms is recognized since antiquity, but the basic principles responsible for their generation have only been unraveled from the last century on. In this context, a great mark was the discovery of a net of genes whose transcription and translation processes are regulated between each other and constitute the basic machinery of the endogenous oscillatory system. This review aim to describe how this machinery works in mammals, detailing its current components, and how it is propagated all over the organism.A manifestação de ritmos biológicos nos mais diversos organismos é reconhecida desde a antiguidade, mas os princípios básicos responsáveis por sua geração começaram a ser desvendados somente no século passado, e continuam até os dias atuais. Nesse contexto, um grande marco foi a descoberta de uma rede de genes cujos processos de transcrição e tradução são regulados entre si e que constituem a maquinaria básica do sistema oscilatório endógeno. Esta revisão visa descrever o funcionamento desta maquinaria em mamíferos, detalhando seus atuais componentes e como isso se propaga para todo o organismo

Molecular Basis for Defining the Pineal Gland and Pinealocytes as Targets for Tumor Necrosis Factor

The pineal gland, the gland that translates darkness into an endocrine signal by releasing melatonin at night, is now considered a key player in the mounting of an innate immune response. Tumor necrosis factor (TNF), the first pro-inflammatory cytokine to be released by an inflammatory response, suppresses the translation of the key enzyme of melatonin synthesis (arylalkylamine-N-acetyltransferase, Aanat). Here, we show that TNF receptors of the subtype 1 (TNF-R1) are expressed by astrocytes, microglia, and pinealocytes. We also show that the TNF signaling reduces the level of inhibitory nuclear factor kappa B protein subtype A (NFKBIA), leading to the nuclear translocation of two NFKB dimers, p50/p50, and p50/RelA. The lack of a transactivating domain in the p50/p50 dimer suggests that this dimer is responsible for the repression of Aanat transcription. Meanwhile, p50/RelA promotes the expression of inducible nitric oxide synthase (iNOS) and the production of nitric oxide, which inhibits adrenergically induced melatonin production. Together, these data provide a mechanistic basis for considering pinealocytes a target of TNF and reinforce the idea that the suppression of pineal melatonin is one of the mechanisms involved in mounting an innate immune response

Nocturnal Activation of Melatonin Receptor Type 1 Signaling Modulates Diurnal Insulin Sensitivity via Regulation of Pi3k Activity

Recent genetic studies have highlighted the potential involvement of melatonin receptor 1 (MT1) and melatonin receptor 2 (MT2) in the pathogenesis of type 2 diabetes. Here, we report that mice lacking MT1 (MT1 KO) tend to accumulate more fat mass than WT mice and exhibit marked systemic insulin resistance. Additional experiments revealed that the main insulin signaling pathway affected by the loss of MT1 was the activation of phosphatidylinositol-3-kinase (PI3K). Transcripts of both catalytic and regulatory subunits of PI3K were strongly downregulated within MT1 KO mice. Moreover, the suppression of nocturnal melatonin levels within WT mice, by exposing mice to constant light, resulted in impaired PI3K activity and insulin resistance during the day, similar to what was observed in MT1 KO mice. Inversely, administration of melatonin to WT mice exposed to constant light was sufficient and necessary to restore insulin-mediated PI3K activity and insulin sensitivity. Hence, our data demonstrate that the activation of MT1 signaling at night modulates insulin sensitivity during the day via the regulation of the PI3K transcription and activity. Lastly, we provide evidence that decreased expression of MTNR1A (MT1) in the liver of diabetic individuals is associated with poorly controlled diabetes

NFKB transcription factor in rat pineal glands

A glândula pineal é um órgão neuroendócrino que tranduz a informação fótica ambiental em sinal humoral pela produção noturna do hormônio melatonina. Recentemente, trabalhos de nosso grupo apontam para a existência de um eixo imunepineal, que considera não só a influência que a melatonina exerce sobre células imunocompetentes, mas também o efeito de mediadores da inflamação sobre a atividade biossintética da glândula. Foi demonstrado que a síntese de melatonina pode ser inibida por agentes pró-inflamatórios e potenciada por substâncias antiinflamatórias. Ambos os efeitos são dependentes da via do fator de transcrição NFKB, sendo que seu conteúdo nuclear nos pinealócitos está inversamente relacionado à produção de melatonina. Esta via de sinalização do NFKB foi inicialmente relacionada somente aos processos de resposta imunológica. Entretanto, seu envolvimento em processos fisiológicos tem sido cada vez relatado. A detecção desta via em glândulas pineais e da sua potencialidade em modular a síntese de melatonina induziu à pesquisa do possível papel fisiológico de NFKB neste órgão, objetivo da presente dissertação. Glândulas pineais obtidas de animais hígidos apresentam a via NFKB constitutivamente ativada, sendo que o conteúdo nuclear deste fator apresenta-se de forma rítmica ao longo do dia. Na fase de claro ambiental há um acúmulo nuclear gradativo, mas assim que inicia a fase de escuro os níveis nucleares de NFKB são bruscamente reduzidos e mantidos baixos durante toda a fase de escuro. Essa dependência do ritmo de NFKB com relação à informação fótica ambiental é, na verdade, consequência do efeito de ritmos hormonais atuantes sobre a essa via. A corticosterona induz a queda abrupta nos níveis nucleares deste fator no início do escuro, enquanto que a própria melatonina produzida pela pineal mantém essa inibição sobre a translocação nuclear de NFKB durante o restante da noite. Assim, postula-se que a regulação deste fator garanta a funcionalidade fisiológica da glândula, uma vez em que alterações no seu conteúdo nuclear resultam em alterações na produção de melatonina. Além disso, tais dados abrem novas perspectivas quanto aos mecanismos regulatórios da atividade da pineal por agentes que atuam via NFKBThe pineal gland is a neuroendocrine organ that transduces the environmental photic information into humoral signals through the nocturnal production of melatonin. Recently, our group have showed the existence of a Immune-pineal axis, that consider not only the melatonin effects on immunocompetent cells, but also the effect of inflammatory mediators on the biosynthetic activity of the pineal gland. It was shown that the melatonin production can be inhibited by pro-inflammatory agents and potenciated by the anti-inflammatory ones. Both effects rely on the NFKB nuclear factor pathway, since its nuclear content in pinealocytes is inversely related to melatonin production. The NFKB pathway was firstly related only to the immune response processes. However, its role in several physiological functions is well documented nowadays. The detection of this pathway in pineal glands and the detection of its modulatory effects on melatonin production lead to the investigation of the putative physiologic role of NFKB in the gland, which was the aim of this project. Pineal glands from healthy animals show NFKB pathway constitutively activated and its nuclear contents show a rhythm through out the 24h of the day. During the light phase, the amount of NFKB increases continuously and a sharp drop occurrs when lights are turned off and there is low level of nuclear NFKB all night long. Actually, the relation between the NFKB rhythm and the light/dark cycle is dependent on endogenous hormonal rhythms. Corticosterone induces the abrupt drop in nuclear NFKB at the beginning of the dark phase, while the pineal melatonin keeps this inhibitory effect through the night. Therefore, it is suggested that the control of NFKB nuclear translocation is required to the physiological function of pineal gland, since any alteration on its nuclear content results in alteration on melatonin production. In addition, these data opens new perspectives on the regulatory mechanisms of the pineal biosynthetic activity by agents that act through the NFKB pathwa

The melatonergic system as a target of amyloid-β peptide

A doença de Alzheimer (AD) é a doença neurodegenerativa relacionada ao envelhecimento mais frequente no mundo. Uma das características moleculares de AD é a produção exacerbada de peptídeos beta-amiloide (Aβ), principalmente dos fragmentos de 40 e 42 aminoácidos (Aβ1-40 e Aβ1-42). Aβ induz respostas neuroinflamatórias e alterações moleculares relacionadas à perda sináptica e morte neuronal. Diversos relatos mostram que pacientes de AD apresentam redução na concentração plasmática de melatonina, hormônio produzido pela glândula pineal e também alteração na expressão dos receptores de melatonina, mas os mecanismos envolvidos ainda não são conhecidos. De acordo com o conceito do eixo imunepineal, agentes inflamatórios são capazes de atuar diretamente sobre a glândula pineal e inibir a síntese de melatonina. No presente estudo investigamos, portanto, se o peptídeo Aβ atua diretamente sobre o sistema melatonérgico, modulando a síntese de melatonina ou a função de seus receptores. Pineais em cultura tratadas com Aβ 1-40 ou Aβ 1-42 apresentaram redução na produção de melatonina. Aβ 1-40 ativou a via do fator de transcrição NF-κB na pineal, resultando em aumento da transcrição de diversos genes inflamatórios, como interleucinas e quimiocinas, e inibição da expressão da enzima arilalquilamina N-acetiltransferase, essencial à síntese de melatonina. Em células HEK293 expressando estavelmente receptores MT1 ou MT2 recombinantes, a ativação da via ERK1/2 pela melatonina foi inibida tanto por Aβ 1-40 quanto por Aβ 1-42. O mesmo efeito inibitório foi observado em células endoteliais primárias que expressam MT1 e MT2 constitutivamente. O presente trabalho mostra que a síntese de melatonina pela pineal e a função dos receptores de melatonina são diretamente regulados por Aβ, o que amplia nossos conhecimentos a respeito dos efeitos prejudiciais de Aβ. Considerando que a melatonina tem propriedades neuroprotetora e antioxidante, a disfunção do sistema melatonérgico pode contribuir para os processos neurodegenerativos que ocorrem na patologia de ADAlzheimer\'s disease (AD) is the most common age-related neurodegenerative disorder worldwide. Excess of amyloid beta peptides (Aβ), composed mainly by 40 and 42 aminoacids-long fragments (Aβ 1-40 e Aβ 1-42) is a molecular hallmark in AD. Aβ-induced neuroinflammatory responses and molecular changes are related to synapse impairment and neuronal loss. It is well documented that AD patients show impaired melatonin synthesis, the pineal gland-derived hormone, and altered expression of melatonin receptors, but the underlying mechanisms remain unclear. According to the immune-pineal axis concept, inflammatory mediators act on the pineal gland, leading to inhibition of melatonin synthesis. Therefore, in the present study we sought to investigate whether Aβ? directly targets the melatonergic system, modulating melatonin synthesis and/or melatonin receptors function. Pineal glands cultured in the presence of Aβ 1-40 or Aβ 1-42 showed reduced melatonin production. Aβ 1-40 activated the nuclear factor kappa B (NF-κ B) pathway in the pineal gland, leading to up-regulation of several inflammatory genes, as interleukins and chemokines, and inhibition of the arylalkylamine N-acetyltransferase enzyme expression, the key enzyme in melatonin synthesis. In HEK293 cells stably expressing recombinant melatonin MT1 or MT2 receptors melatonin-induced ERK1/2 activation was markedly impaired by Aβ 1-40 and Aβ 1-42. Similar results were obtained in primary culture of endothelial cells expressing melatonin receptors endogenously. The present study shows that melatonin synthesis and melatonin receptors function are directly impaired by Aβ, thus extending our understanding on the detrimental effects of Aβ. Because melatonin shows neuroprotective and antioxidant properties, impairment of the melatonergic system may contribute to the neurodegenerative processes that take place in AD. 1-42) is a molecular hallmark in AD. Aβ-induced neuroinflammatory responses and molecular changes are related to synapse impairment and neuronal loss. It is well documented that AD patients show impaired melatonin synthesis, the pineal gland-derived hormone, and altered expression of melatonin receptors, but the underlying mechanisms remain unclear. According to the immune-pineal axis concept, inflammatory mediators act on the pineal gland, leading to inhibition of melatonin synthesis. Therefore, in the present study we sought to investigate whether Aβ?directly targets the melatonergic system, modulating melatonin synthesis and/or melatonin receptors function. Pineal glands cultured in the presence of Aβ 1-40 or Aβ 1-42 showed reduced melatonin production. Aβ 1-40 activated the nuclear factor kappa B (NF-&kappa B) pathway in the pineal gland, leading to up-regulation of several inflammatory genes, as interleukins and chemokines, and inhibition of the arylalkylamine N-acetyltransferase enzyme expression, the key enzyme in melatonin synthesis. In HEK293 cells stably expressing recombinant melatonin MT1 or MT2 receptors melatonin-induced ERK1/2 activation was markedly impaired by Aβ 1-40 and Aβ 1-42. Similar results were obtained in primary culture of endothelial cells expressing melatonin receptors endogenously. The present study shows that melatonin synthesis and melatonin receptors function are directly impaired by Aβ, thus extending our understanding on the detrimental effects of Aβ. Because melatonin shows neuroprotective and antioxidant properties, impairment of the melatonergic system may contribute to the neurodegenerative processes that take place in A

NFKB transcription factor in rat pineal glands

A glândula pineal é um órgão neuroendócrino que tranduz a informação fótica ambiental em sinal humoral pela produção noturna do hormônio melatonina. Recentemente, trabalhos de nosso grupo apontam para a existência de um eixo imunepineal, que considera não só a influência que a melatonina exerce sobre células imunocompetentes, mas também o efeito de mediadores da inflamação sobre a atividade biossintética da glândula. Foi demonstrado que a síntese de melatonina pode ser inibida por agentes pró-inflamatórios e potenciada por substâncias antiinflamatórias. Ambos os efeitos são dependentes da via do fator de transcrição NFKB, sendo que seu conteúdo nuclear nos pinealócitos está inversamente relacionado à produção de melatonina. Esta via de sinalização do NFKB foi inicialmente relacionada somente aos processos de resposta imunológica. Entretanto, seu envolvimento em processos fisiológicos tem sido cada vez relatado. A detecção desta via em glândulas pineais e da sua potencialidade em modular a síntese de melatonina induziu à pesquisa do possível papel fisiológico de NFKB neste órgão, objetivo da presente dissertação. Glândulas pineais obtidas de animais hígidos apresentam a via NFKB constitutivamente ativada, sendo que o conteúdo nuclear deste fator apresenta-se de forma rítmica ao longo do dia. Na fase de claro ambiental há um acúmulo nuclear gradativo, mas assim que inicia a fase de escuro os níveis nucleares de NFKB são bruscamente reduzidos e mantidos baixos durante toda a fase de escuro. Essa dependência do ritmo de NFKB com relação à informação fótica ambiental é, na verdade, consequência do efeito de ritmos hormonais atuantes sobre a essa via. A corticosterona induz a queda abrupta nos níveis nucleares deste fator no início do escuro, enquanto que a própria melatonina produzida pela pineal mantém essa inibição sobre a translocação nuclear de NFKB durante o restante da noite. Assim, postula-se que a regulação deste fator garanta a funcionalidade fisiológica da glândula, uma vez em que alterações no seu conteúdo nuclear resultam em alterações na produção de melatonina. Além disso, tais dados abrem novas perspectivas quanto aos mecanismos regulatórios da atividade da pineal por agentes que atuam via NFKBThe pineal gland is a neuroendocrine organ that transduces the environmental photic information into humoral signals through the nocturnal production of melatonin. Recently, our group have showed the existence of a Immune-pineal axis, that consider not only the melatonin effects on immunocompetent cells, but also the effect of inflammatory mediators on the biosynthetic activity of the pineal gland. It was shown that the melatonin production can be inhibited by pro-inflammatory agents and potenciated by the anti-inflammatory ones. Both effects rely on the NFKB nuclear factor pathway, since its nuclear content in pinealocytes is inversely related to melatonin production. The NFKB pathway was firstly related only to the immune response processes. However, its role in several physiological functions is well documented nowadays. The detection of this pathway in pineal glands and the detection of its modulatory effects on melatonin production lead to the investigation of the putative physiologic role of NFKB in the gland, which was the aim of this project. Pineal glands from healthy animals show NFKB pathway constitutively activated and its nuclear contents show a rhythm through out the 24h of the day. During the light phase, the amount of NFKB increases continuously and a sharp drop occurrs when lights are turned off and there is low level of nuclear NFKB all night long. Actually, the relation between the NFKB rhythm and the light/dark cycle is dependent on endogenous hormonal rhythms. Corticosterone induces the abrupt drop in nuclear NFKB at the beginning of the dark phase, while the pineal melatonin keeps this inhibitory effect through the night. Therefore, it is suggested that the control of NFKB nuclear translocation is required to the physiological function of pineal gland, since any alteration on its nuclear content results in alteration on melatonin production. In addition, these data opens new perspectives on the regulatory mechanisms of the pineal biosynthetic activity by agents that act through the NFKB pathwa

Molecular Characterization and Pharmacology of Melatonin Receptors in Animals

Melatonin, the hormone of darkness, is secreted in minute amounts during the night and is virtually undetectable during the day. Melatonin mainly acts on high-affinity G protein-coupled receptors. The present review will trace the path of the discovery of melatonin receptors from their cloning, expression and purification to the development of recent radioactive and fluorescent tracers. We will then report on the state-of-the-art of melatonin receptor functional properties, including ligand bias and system bias due to receptor-associated proteins and receptor heteromers. Currently available antibodies raised against melatonin receptors will be critically reviewed here for the first time. The review will close with future perspectives in terms of the discovery of allosteric ligands and the in vivo validation of a range of melatonin receptor-associated signaling complexes to improve future drug development

Immune-Pineal Axis: Nuclear Factor κB (NF-kB) Mediates the Shift in the Melatonin Source from Pinealocytes to Immune Competent Cells

Pineal gland melatonin is the darkness hormone, while extra-pineal melatonin produced by the gonads, gut, retina, and immune competent cells acts as a paracrine or autocrine mediator. The well-known immunomodulatory effect of melatonin is observed either as an endocrine, a paracrine or an autocrine response. In mammals, nuclear translocation of nuclear factor κ-light-chain-enhancer of activated B cells (NF-κB) blocks noradrenaline-induced melatonin synthesis in pinealocytes, which induces melatonin synthesis in macrophages. In addition, melatonin reduces NF-κB activation in pinealocytes and immune competent cells. Therefore, pathogen- or danger-associated molecular patterns transiently switch the synthesis of melatonin from pinealocytes to immune competent cells, and as the response progresses melatonin inhibition of NF-κB activity leads these cells to a more quiescent state. The opposite effect of NF-κB in pinealocytes and immune competent cells is due to different NF-κB dimers recruited in each phase of the defense response. This coordinated shift of the source of melatonin driven by NF-κB is called the immune-pineal axis. Finally, we discuss how this concept might be relevant to a better understanding of pathological conditions with impaired melatonin rhythms and hope it opens new horizons for the research of side effects of melatonin-based therapies