Global ETD Search

1	Bifurcations in a model of Per1 neurons Alsaleh, Dana January 2017 (has links) Circadian rhythms refer to the physiological and biological processes that fluctuate over a 24-hour period. These rhythms are found in most living things such as animals, plants and fungi. In mammals, circadian rhythms are mainly generated and regulated by the suprachiasmatic nucleus (SCN).The period (Per1) gene in the SCN plays a key role in directing circadian rhythms. Per1 expression increases during the day and decreases at night. The neurons which express the Per1 gene show different behaviours to non-Per1 neurons during the day-night cycle. Per1 neurons are in a state of repetitive firing in the morning while in the late morning they display a bursting behaviour. In the afternoon, Per1 neurons divide into two groups: GA and GB, where GA is in a repetitive firing state and GB is silent. At night, these neurons are generally in a quiescent state but late at night they generate spikes. In this study, a standard Hodgkin-Huxley type model was used to study the behaviours of Per1 neurons over the day-night cycle using bifurcation analysis. In this model, the potassium and calcium currents carry the circadian rhythms which are modelled by their conductance. The currents had a significant impact on Per1 neuron behaviours. Furthermore, by changing some of the model parameters, different bistability mechanisms were examined. The study was extended to explore the effect of noise from other neurons on Per1 neuron behaviours. It was shown that noise plays a crucial role in inducing some of the Per1 neuron behaviours and that some Per1 neuron behaviours are fully induced by this noise, e.g. the late morning and late night behaviours. In contrast, the noise was found not to have any significant effect on other Per1 neuron behaviours other than the two behaviours that are observed in the afternoon. 510
2	Effets de l'agomélatine et de la mélatonine sur les oscillations de l'horloge circadienne : études physiologiques et moléculaires / Effects of agomelatine and melatonin on the oscillations of the circadian clock : physiological and molecular studies Castanho, Amelie 05 September 2013 (has links) La mélatonine est connue pour agir directement sur l’horloge circadienne. L’agomélatine est un antidépresseur présentant des propriétés agonistes MT1/MT2 et antagonistes 5-HT2C. Tout d’abord, nous avons évalué les effets de l’agomélatine, de la mélatonine et d’un antagoniste 5-HT2C sur deux sorties de l’horloge (rythme de la mélatonine endogène et de la température corporelle). Les résultats obtenus suggèrent une action centrale de l’agomélatine et de la mélatonine, directement sur l’horloge via les récepteurs MT1/MT2, en induisant une augmentation de l’amplitude et une avance de phase du rythme de mélatonine. Pour la température corporelle, l’ensemble des drogues augmente l’amplitude du rythme, suggérant une action des propriétés agonistes MT1/MT2 et/ou antagonistes 5-HT2C de l’agomélatine. Puis, l’étude sur l’expression du gène horloge Per1, a révélé un effet supérieur de l’agomélatine par rapport à la mélatonine, mais seulement le jour du traitement. L’agomélatine pourrait agir sur la machinerie moléculaire de l’horloge, ce qui reste à exploiter davantage. Ces nouvelles données contribuent à une meilleure compréhension des mécanismes d’action de l’agomélatine. / Melatonin is known to act directly on the circadian clock. Agomelatine is an antidepressant with MT1/MT2 agonist and antagonist 5-HT2C properties. First, we evaluated the effects of agomelatine, melatonin and 5-HT2C antagonist on two clock outputs (rhythm of endogenous melatonin and body temperature). The results suggest a central action of agomelatine and melatonin, directly on the circadian clock via MT1/MT2 receptors, inducing an increase on the amplitude and a phase advance of the rhythm of melatonin. For body temperature, all drugs increased the amplitude of the rhythm, this suggest an action of MT1/MT2 agonist and antagonist 5-HT2C properties of agomelatine. Secondly, the study on the expression of clock gene Per1 revealed a greater effect of agomelatine compared to melatonin, but only on the day of treatment. Agomelatine could act on the molecular machinery of the clock, but requires further investigations. These new data allow a better understand of the mechanisms action of agomelatine. Agomélatine Rythmes circadiens Mélatonine Température corporelle Microdialyse Gène Per1 Agomelatine Circadian rhythms Melatonin Body temperature Microdialysis Gene Per1 615.7 612.02
3	Efeito da Luz e Temperatura Sobre a Expressão de Genes do Relógio em Mamífero: Tecidos Periféricos como Modelo de Estudo / Effect of light and temperature on the mammalian clock genes expression: peripheral tissues as study model Mezzalira, Nathana Fernandes 10 December 2015 (has links) O surgimento e a evolução da vida na terra foram possíveis graças ao desenvolvimento de mecanismos temporais precisos capazes de ajustar os processos fisiológicos que ocorriam no interior do organismo com os ciclos ambientais, promovendo assim, ganhos na capacidade adaptativa e reprodutiva dos indivíduos. Neste contexto, luz e temperatura são as duas pistas temporais mais relevantes para resetar o relógio endógeno e, aparentemente, esses dois zeitgebers trabalham juntos para manter os ritmos circadianos. Uma ampla gama de fotorreceptores e fotopigmentos evoluiu no sentido de perceber com alta sensibilidade a informação fótica fornecida pelo ambiente e, recentemente, foi demonstrado que a detecção de temperatura também pode ser exercida pelos fotopigmentos rodopsina e melanopsina, sendo mediada por canais TRP (Shen et al., 2011). Consideramos as células B16-F10 Per1::Luc como um modelo promissor para o estudo de luz e temperatura em relógios periféricos, uma vez que essa linhagem expressa os dois fotopigmentos apontados com função de termorreceptores em Drosophila. Nossos estudos nos permitiram verificar que a luz não atua como um agente sincronizador nessas células, que se mantiveram em livre curso mesmo após um pulso de 10 min de luz azul (650 lux). Por outro lado, um pulso de temperatura de 2,5º C acima da temperatura de manutenção por 1h atuou ajustando a expressão do gene Per1, imprimindo um ritmo circadiano, diferentemente do observado no controle. Com base nessas informações, hipotetizamos que a informação de luz, percebida via melanopsina na retina de mamíferos, levaria a regulação da temperatura circadiana pelo NSQ, e a temperatura corporal, por sua vez, poderia atuar como uma pista interna para a sincronização dos tecidos periféricos, tendo os canais TRP como mediadores. Para responder esta questão, utilizamos camundongos WT e TrpV1 KO submetidos a diferentes protocolos de luz e avaliamos a expressão de genes do relógio Per1, Per2, Clock e Bmal1 e dos canais TrpV1 e TrpA1 em tecidos periféricos. Identificamos que a glândula suprarrenal, fígado e tecido adiposo marrom possuem uma maquinaria do relógio tipicamente ativa e acreditamos que a oscilação dos genes de relógio observada nesses tecidos é expressiva. Interessantemente, vimos também que o TrpV1, além de ser expresso nos tecidos analisados em animais WT, apresenta uma transcrição rítmica no fígado e tecido adiposo marrom de animais em LD, corroborando nossa hipótese de que canais TRP atuam como mediadores da informação de luz aos tecidos periféricos. Dadas as diferenças encontradas entre os animais WT e TrpV1 KO, sugerimos que a presença do canal TRPV1 pode ser essencial, embora seu grau de envolvimento varie de acordo com o tecido. No que diz respeito ao canal TRPA1, encontramos dois resultados que merecem ser destacados. Primeiramente, identificamos no fígado de camundongos TrpV1 KO mantidos em LD uma provável compensação da expressão de TrpA1 na ausência de TrpV1 e, curiosamente, que o tecido adiposo marrom não expressa o canal TrpA1. Considerando os resultados deste trabalho sobre o envolvimento dos canais TRP em resposta à luz e temperatura, acreditamos ter fortalecido nossa hipótese inicial, principalmente após demonstrarmos o papel do canal TRPV1 e que tecidos periféricos são sincronizados por alterações de temperatura. / The life emergence and evolution on Earth were made possible by the development of precise temporal mechanisms able to adjust the physiological processes within an organism with environmental cycles, thus promoting gains in the adaptive and reproductive capacity of the individuals. In this context, light and temperature are the two most relevant time cues to reset the endogenous clock; apparently these two zeitgebers work together to keep the circadian rhythms. A wide variety of photoreceptors and photopigments evolved in order to precisely perceive the photic information provided by the environment, and recently it has been shown that the temperature detection can also be exerted by the photopigments rhodopsin and melanopsin, being mediated by TRP channels (Shen et al., 2011). We have identified B16-F10 Per1::Luc cells as a promising model for the study of light and temperature effects on peripheral clocks, since this cell line expresses both photopigments pointed as thermoreceptors in Drosophila. Our studies allowed us to demonstrate that light does not act as a synchronizing agent on those cells, which remained in free running after a 10 min pulse of blue light (650 lux). On the other hand, a temperature pulse of 2.5º C above the maintenance temperature, for 1h, adjusted Per1 gene expression, imprinting a circadian rhythm, which was not observed in the control. Based on this information, we hypothesized that the light perceived via melanopsin by the mammalian retina would lead to the regulation of the circadian temperature by the SCN, and the body temperature, in turn, could act as an inner cue for the synchronization of the peripheral tissues, having the TRP channels as mediators. To answer this question, we have used WT and TrpV1 KO mice under different light protocols and evaluated the expression of clock genes Per1, Per2, Clock and Bmal1 and TrpV1 and TrpA1 channels in peripheral tissues. We found that the adrenal gland, liver and brown adipose tissue have a typically active clock machinery, and the oscillation of clock genes observed in these tissues is significant. Interestingly, we observed that TrpV1 is expressed in those tissues, and presents a rhythmic transcription in the liver and brown adipose tissue of LD maintained animals, confirming our hypothesis that TRP channels act as mediators of light information to peripheral tissues. In face of the differences between WT and trpV1 KO animals, we suggest that the presence of the TRPV1 channel may be essential, although its degree of involvement may vary according to the tissue. In terms of TRPA1 channel, we found two results that deserve to be highlighted. Firstly, we identified in the liver of TrpV1 KO mice maintained in LD a presumable compensation of TrpA1 expression in the absence of TrpV1 and, interestingly, the brown adipose tissue does not express TrpA1 channel. Considering the findings of this study on the participation of TRP channels in responses to light and temperature, we believe we have strengthened our initial hypothesis, especially after we have demonstrated the role of TRPV1 channel, and that peripheral tissues may be synchronized by temperature changes. B16-F10 Per1::Luc B16-F10 Per1::Luc Canais TRP Clock genes Genes do relógio Light Luz Mus musculus Mus musculus Peripheral clocks Relógios periféricos Temperatura Temperature TRP channels
4	Efeito da Luz e Temperatura Sobre a Expressão de Genes do Relógio em Mamífero: Tecidos Periféricos como Modelo de Estudo / Effect of light and temperature on the mammalian clock genes expression: peripheral tissues as study model Nathana Fernandes Mezzalira 10 December 2015 (has links) O surgimento e a evolução da vida na terra foram possíveis graças ao desenvolvimento de mecanismos temporais precisos capazes de ajustar os processos fisiológicos que ocorriam no interior do organismo com os ciclos ambientais, promovendo assim, ganhos na capacidade adaptativa e reprodutiva dos indivíduos. Neste contexto, luz e temperatura são as duas pistas temporais mais relevantes para resetar o relógio endógeno e, aparentemente, esses dois zeitgebers trabalham juntos para manter os ritmos circadianos. Uma ampla gama de fotorreceptores e fotopigmentos evoluiu no sentido de perceber com alta sensibilidade a informação fótica fornecida pelo ambiente e, recentemente, foi demonstrado que a detecção de temperatura também pode ser exercida pelos fotopigmentos rodopsina e melanopsina, sendo mediada por canais TRP (Shen et al., 2011). Consideramos as células B16-F10 Per1::Luc como um modelo promissor para o estudo de luz e temperatura em relógios periféricos, uma vez que essa linhagem expressa os dois fotopigmentos apontados com função de termorreceptores em Drosophila. Nossos estudos nos permitiram verificar que a luz não atua como um agente sincronizador nessas células, que se mantiveram em livre curso mesmo após um pulso de 10 min de luz azul (650 lux). Por outro lado, um pulso de temperatura de 2,5º C acima da temperatura de manutenção por 1h atuou ajustando a expressão do gene Per1, imprimindo um ritmo circadiano, diferentemente do observado no controle. Com base nessas informações, hipotetizamos que a informação de luz, percebida via melanopsina na retina de mamíferos, levaria a regulação da temperatura circadiana pelo NSQ, e a temperatura corporal, por sua vez, poderia atuar como uma pista interna para a sincronização dos tecidos periféricos, tendo os canais TRP como mediadores. Para responder esta questão, utilizamos camundongos WT e TrpV1 KO submetidos a diferentes protocolos de luz e avaliamos a expressão de genes do relógio Per1, Per2, Clock e Bmal1 e dos canais TrpV1 e TrpA1 em tecidos periféricos. Identificamos que a glândula suprarrenal, fígado e tecido adiposo marrom possuem uma maquinaria do relógio tipicamente ativa e acreditamos que a oscilação dos genes de relógio observada nesses tecidos é expressiva. Interessantemente, vimos também que o TrpV1, além de ser expresso nos tecidos analisados em animais WT, apresenta uma transcrição rítmica no fígado e tecido adiposo marrom de animais em LD, corroborando nossa hipótese de que canais TRP atuam como mediadores da informação de luz aos tecidos periféricos. Dadas as diferenças encontradas entre os animais WT e TrpV1 KO, sugerimos que a presença do canal TRPV1 pode ser essencial, embora seu grau de envolvimento varie de acordo com o tecido. No que diz respeito ao canal TRPA1, encontramos dois resultados que merecem ser destacados. Primeiramente, identificamos no fígado de camundongos TrpV1 KO mantidos em LD uma provável compensação da expressão de TrpA1 na ausência de TrpV1 e, curiosamente, que o tecido adiposo marrom não expressa o canal TrpA1. Considerando os resultados deste trabalho sobre o envolvimento dos canais TRP em resposta à luz e temperatura, acreditamos ter fortalecido nossa hipótese inicial, principalmente após demonstrarmos o papel do canal TRPV1 e que tecidos periféricos são sincronizados por alterações de temperatura. / The life emergence and evolution on Earth were made possible by the development of precise temporal mechanisms able to adjust the physiological processes within an organism with environmental cycles, thus promoting gains in the adaptive and reproductive capacity of the individuals. In this context, light and temperature are the two most relevant time cues to reset the endogenous clock; apparently these two zeitgebers work together to keep the circadian rhythms. A wide variety of photoreceptors and photopigments evolved in order to precisely perceive the photic information provided by the environment, and recently it has been shown that the temperature detection can also be exerted by the photopigments rhodopsin and melanopsin, being mediated by TRP channels (Shen et al., 2011). We have identified B16-F10 Per1::Luc cells as a promising model for the study of light and temperature effects on peripheral clocks, since this cell line expresses both photopigments pointed as thermoreceptors in Drosophila. Our studies allowed us to demonstrate that light does not act as a synchronizing agent on those cells, which remained in free running after a 10 min pulse of blue light (650 lux). On the other hand, a temperature pulse of 2.5º C above the maintenance temperature, for 1h, adjusted Per1 gene expression, imprinting a circadian rhythm, which was not observed in the control. Based on this information, we hypothesized that the light perceived via melanopsin by the mammalian retina would lead to the regulation of the circadian temperature by the SCN, and the body temperature, in turn, could act as an inner cue for the synchronization of the peripheral tissues, having the TRP channels as mediators. To answer this question, we have used WT and TrpV1 KO mice under different light protocols and evaluated the expression of clock genes Per1, Per2, Clock and Bmal1 and TrpV1 and TrpA1 channels in peripheral tissues. We found that the adrenal gland, liver and brown adipose tissue have a typically active clock machinery, and the oscillation of clock genes observed in these tissues is significant. Interestingly, we observed that TrpV1 is expressed in those tissues, and presents a rhythmic transcription in the liver and brown adipose tissue of LD maintained animals, confirming our hypothesis that TRP channels act as mediators of light information to peripheral tissues. In face of the differences between WT and trpV1 KO animals, we suggest that the presence of the TRPV1 channel may be essential, although its degree of involvement may vary according to the tissue. In terms of TRPA1 channel, we found two results that deserve to be highlighted. Firstly, we identified in the liver of TrpV1 KO mice maintained in LD a presumable compensation of TrpA1 expression in the absence of TrpV1 and, interestingly, the brown adipose tissue does not express TrpA1 channel. Considering the findings of this study on the participation of TRP channels in responses to light and temperature, we believe we have strengthened our initial hypothesis, especially after we have demonstrated the role of TRPV1 channel, and that peripheral tissues may be synchronized by temperature changes. B16-F10 Per1::Luc Canais TRP Genes do relógio Luz Mus musculus Relógios periféricos Temperatura B16-F10 Per1::Luc Clock genes Light Mus musculus Peripheral clocks Temperature TRP channels
5	Timing Matters: The Role of Circadian Clock Genes In Development and Toxin Responses Qu, Xiaoyu 15 May 2009 (has links) Most members of the PAS (PER-ARNT-SIM) protein family are transcription factors, mediating development and adaptive responses to the environment, such as circadian rhythms and toxin responses. Because the PAS domain mediates protein-protein interactions and functional cross-talk between distinct biological processes, we hypothesized that PAS genes in the circadian clockworks, namely Per1 and Per2, may be involved in development and toxin responses, which are modulated by other PAS members. To explore the possible role of clock genes in development, we examined mammary epithelial cells in vitro and the mouse mammary gland in vivo for evidences of changes in clock gene expression during different stages of development and differentiation. Our results showed that Per1 and Bmal1 expression were up-regulated in differentiated HC-11 cells, whereas Per2 mRNA levels were higher in undifferentiated cells. A similar differentiation-dependent profile of clock gene expression was observed in mouse mammary glands; Per1 and Bmal1 mRNA levels were elevated in late pregnant and lactating mammary tissues, whereas Per2 expression was higher in proliferating virgin and early pregnant glands. These data suggest that circadian clock genes may play a role in mouse mammary gland development. To examine clock gene function in toxin responses, we evaluated whether disruption or inhibition of Per1 and/or Per2 alters toxin-induced activity of the AhR signaling pathway in the mouse mammary gland and liver. We assessed the activation of the AhR signaling pathway in response to 2,3,7,8-Tetrachlorodibenzo-p-dioxin (TCDD), a prototypical AhR agonist, by analyzing the mRNA abundance of its two target genes, cytochrome P450, subfamily I, polypeptide 1 (Cyp1A1) and Cyp1B1. Our results showed that the targeted disruption of Per1, but not Per2, significantly increases the TCDD-induced p450 expression in the mammary gland and liver in vivo. Similar changes in TCDD-mediated p450 expression were observed in vitro using mammary primary cultures of mammary cells derived from from Per1ldc, Per2ldc and Per1ldc/Per2ldc mutant mice and Hepa1c1c7 cells subjected to siRNA-mediated inhibition of Per1 or Per2. These discoveries suggest that the clock gene Per1 may modulate toxin responses perhaps by functioning as a negative regulator for TCDD-mediated activation of the AhR signaling pathway. Circadian rhythm Development AhR signaling pathway Per1 Cyp1A1 Mammary gland Liver RNA TCDD
6	Timing Matters: The Role of Circadian Clock Genes In Development and Toxin Responses Qu, Xiaoyu 15 May 2009 (has links) Most members of the PAS (PER-ARNT-SIM) protein family are transcription factors, mediating development and adaptive responses to the environment, such as circadian rhythms and toxin responses. Because the PAS domain mediates protein-protein interactions and functional cross-talk between distinct biological processes, we hypothesized that PAS genes in the circadian clockworks, namely Per1 and Per2, may be involved in development and toxin responses, which are modulated by other PAS members. To explore the possible role of clock genes in development, we examined mammary epithelial cells in vitro and the mouse mammary gland in vivo for evidences of changes in clock gene expression during different stages of development and differentiation. Our results showed that Per1 and Bmal1 expression were up-regulated in differentiated HC-11 cells, whereas Per2 mRNA levels were higher in undifferentiated cells. A similar differentiation-dependent profile of clock gene expression was observed in mouse mammary glands; Per1 and Bmal1 mRNA levels were elevated in late pregnant and lactating mammary tissues, whereas Per2 expression was higher in proliferating virgin and early pregnant glands. These data suggest that circadian clock genes may play a role in mouse mammary gland development. To examine clock gene function in toxin responses, we evaluated whether disruption or inhibition of Per1 and/or Per2 alters toxin-induced activity of the AhR signaling pathway in the mouse mammary gland and liver. We assessed the activation of the AhR signaling pathway in response to 2,3,7,8-Tetrachlorodibenzo-p-dioxin (TCDD), a prototypical AhR agonist, by analyzing the mRNA abundance of its two target genes, cytochrome P450, subfamily I, polypeptide 1 (Cyp1A1) and Cyp1B1. Our results showed that the targeted disruption of Per1, but not Per2, significantly increases the TCDD-induced p450 expression in the mammary gland and liver in vivo. Similar changes in TCDD-mediated p450 expression were observed in vitro using mammary primary cultures of mammary cells derived from from Per1ldc, Per2ldc and Per1ldc/Per2ldc mutant mice and Hepa1c1c7 cells subjected to siRNA-mediated inhibition of Per1 or Per2. These discoveries suggest that the clock gene Per1 may modulate toxin responses perhaps by functioning as a negative regulator for TCDD-mediated activation of the AhR signaling pathway. Circadian rhythm Development AhR signaling pathway Per1 Cyp1A1 Mammary gland Liver RNA TCDD
7	La peau, un modèle d'horloge périphérique / The skin as a peripheral clock model Liu, Taole 03 March 2014 (has links) Ce travail avait pour objet d’étudier les propriétés d’horloge et de synchronisation de la peau, un modèle potentiel d’horloge périphérique. L’activité rythmique a été analysée par bioluminescence en temps réel, sur des explants de peau abdominale et des fibroblastes dermiques primaires, isolés à partir de rats transgéniques Per1-luciférase. Nous avons montré que des explants de peau présentent une activité rythmique soutenue en culture, indiquant une importante synchronisation interne dans le tissu. Cette synchronisation se manifeste au cours du développement post-natal à partir de 1 mois et augmente jusqu’à 6 mois, avant de décroître, laissant place à des rythmes altérés à l’âge de 2 ans. Nous avons aussi établi que les fibroblastes dermiques présentent la propriété de compensation thermique commune à toutes les horloges circadiennes, et qu’ils sont potentiellement synchronisables par la mélatonine puisque celle-ci augmente leur amplitude en culture. Nous avons aussi préparé un vecteur lentiviral exprimant le gène rapporteur luciférase sous le contrôle du promoteur du gène horloge Bmal1, un nouvel outil pour compléter l’étude des rythmes dans les cellules de la peau. / This work aimed to investigate the skin as a potential model of peripheral clock by characterizing its rhythmic and synchronization properties. Circadian activity was examined in abdominal skin explants and fibroblasts derived from Per1-Luciferase transgenic rats by real-time recording of bioluminescence. First, the skin clock was characterized from early postnatal to old age. Low amplitude oscillations appeared at 1 month only and their robustness increased until 6 months. In 1-2 year-old rats, skin circadian rhythms showed decreasing amplitude and abnormal cycles. Primary fibroblasts derived from the skin at the same ages demonstrated similar pattern of clock activity. Temperature compensation, an intrinsic clock feature, was shown the first time in skin and primary fibroblasts. Secondly, we demonstrated a phase-dependent effect of melatonin to increase the amplitude of oscillations in skin primary fibroblasts, indicating it displays a synchronising role in the circadiansystem. Finally, to facilitate our studies on the multioscillatory skin tissue, we constructed a lentivirus carrying a Bmal1-luciferase reporter, to measure clock genes activities in human skin cells. Per1 Bmal1 Horloge périphérique Rythmes circadiens Synchronisation Peau Fibroblastes Bioluminescence Développement postnatal Vieillissement Compensation thermique Mélatonine Lentivirus Per1 Bmal1 Peripheral clock Circadian rhythms Synchronization Skin Fibroblasts Bioluminescence Postnatal development Ageing Temperature compensation Melatonin Lentivirus 571.8 612.02
8	Relógios biológicos e padrões de alimentação em camundongos normais e com sobrepeso / Biological clocks and feeding patterns in normal mice and overweight Priscila Queiroz Pires de Souza 28 June 2011 (has links) Fundação Carlos Chagas Filho de Amparo a Pesquisa do Estado do Rio de Janeiro / A saudável interação entre o indivíduo e o meio depende do alinhamento entre a dinâmica fisiológica do primeiro e os periódicos movimentos da natureza. A interação entre tais ritmos por sua vez constitui-se em base e derivação do processo de evolução. O comprometimento de tal alinhamento representa um risco para a sobrevivência das espécies. Neste contexto, os organismos alinham seus ritmos fisiológicos a diferentes ciclos externos. Desta forma, ciclos endógenos são coordenados por relógios biológicos que determinam em nosso organismo, específicos ritmos em fase com a natureza, tais como ritmos circadianos (RC), cujo período aproxima-se de 24 horas. O peso corporal, a ingestão de alimentos e o consumo de energia são processos caracterizados pelo RC e a obesidade está associada a uma dessincronização deste processo. A modulação do RC é resultado da expressão dos clock gens CLOCK e BMAL1 que formam um heterodímero responsável pela transcrição gênica de Per1, Per2, Per3, Cry1 e Cry2. As proteínas codificadas por estes genes, uma vez sintetizadas, formam dímeros (PER-CRY) no citoplasma que, a partir de determinada concentração, retornam ao núcleo, bloqueando a ação do heterodímero CLOCK/BMAL1 na transcrição dos próprios genes, formando assim uma alça de retroalimentação negativa de transcrição e tradução. Estes genes asseguram a periodicidade e são significativamente expressos no núcleo supraquiasmático (SCN) do hipotálamo. Para estudar esse processo em camundongos normais e hiperalimentados, saciados e em estado de fome, foi utilizado um método de registro do comportamento alimentar baseado no som produzido pela alimentação dos animais, e a correlação destes estados metabólicos com a expressão de CLOCK, BMAL1, Per1, Per2, Per3, bem como das proteínas Cry1 e Cry2 no SCN, por análise de imagens obtidas em microscopia confocal. Camundongos suíços controle em estado de fome (CF) e saciados (CS) foram comparados com animais hiperalimentados com fome (HF) e saciados (HS). Nenhum grupo demonstrou diferença nos conteúdos CLOCK e BMAL1, indicando capacidade potencial para modular os ritmos biológicos. No entanto, as proteínas Per1, Per2, Per3 e Cry1 apresentaram menor expressão no grupo CS, mostrando uma diferença significativa quando comparados com o grupo CF (P<0,05), diferença esta não encontrada na comparação entre os grupos HF e HS. A quantidade de proteína Cry2 não foi diferente na mesma comparação. Os resultados do estudo indicaram que as alterações dos ritmos endógenos e exógenos, refletido pelo comportamento hiperfágico observado em camundongos hiperalimentados, pode ser devido a um defeito no mecanismo de feedback negativo associado ao dímero Cry-Per, que não bloqueia a transcrição de Per1 Per2, Per3 e Cry1 pelo heterodímero CLOCK-BMAL1. / The healthy interaction between the subject and the environment depends on the alignment between the physiological dynamics of the first one and the periodical movements of nature. The interaction between these rhythms in turn is based on the derivation and evolution process. The involvement of such an alignment is a risk to the survival of species. In this context the bodies line up their physiological rhythms to different external cycles. Thus, endogenous cycles are coordinated by biological clocks which determine in our organism specific rhythms in phase with the nature, such as Circadian Rhythms (CR) whose period is close to 24 hours. The body weight, the food intake and the energy consumption are processes characterized by the CR and the obesity is associated with a different timing of this process. The CR modulation is a result of the formulation of clock-gens CLOCK and BMAL1 who form an heterodimer responsible for the gene transcription of Per1, Per2, Per3, Cry1 e Cry2. The proteins encoded by these genes, once synthesized, form dimers (PER-CRY) in the cytoplasm that, depending on a given concentration, return to the core blocking the action of the CLOCK/BMAL1 heterodimer in the transcription of its own genes, thus forming a negative feedback loop of transcription and translation. These genes secure the periodicity and are significantly expressed in the hypothalamus suprachiasmatic nucleus. In order to study this process in regular, hyper-fed, hungry and satiated mice, we used a registration method of feeding behavior based on the sound produced by animal feeding and the relation between the metabolic states with the expression CLOCK, BMAL1, Per1, Per2, Per3, as well as the Cry1 and Cry2 proteins in the SCN, by analysis of images obtained in confocal microscopy. Control Swiss mice in state of hunger/ satiated were compared to hyper-fed animals in the same conditions. None of them showed difference in the CLOCK and BMAL1 contents, showing a potential capacity to modulate the biological rhythms. However, the Per1, Per2, Per3 and Cry1 proteins showed a minor expression in the CS group and a significant difference when compared to the CF group (P<0,05). This difference cant be found in the HF and HS groups. The results of the studies indicated that the endogenous and exogenous changes, reflected by the hyperphagic behavior observed in hyper-fed mice, may be due to a defect in the mechanism of negative feedback associated to the Cry-Per dimer, which has abolished the blocking mechanism of Per1 Per2, Per3 and Cry1 by the CLOCK-BMAL1 heterodimer. Ritmo circadiano Programação metabólica Hipotálamo Obesidade Hiperfagia Comportamento alimentar CLOCK BMAL1 Per1 Per2 Per3 Cry1 Cry2 Nutrição - Teses Circadian rhythm Metabolic programming Hypothalamus Obesity Hyperphagia Feeding behavior CLOCK BMAL1 Per1 Per2 Per3 Cry1 Cry2 Nutrition - Theses FISIOLOGIA DE ORGAOS E SISTEMAS
9	Relógios biológicos e padrões de alimentação em camundongos normais e com sobrepeso / Biological clocks and feeding patterns in normal mice and overweight Priscila Queiroz Pires de Souza 28 June 2011 (has links) Fundação Carlos Chagas Filho de Amparo a Pesquisa do Estado do Rio de Janeiro / A saudável interação entre o indivíduo e o meio depende do alinhamento entre a dinâmica fisiológica do primeiro e os periódicos movimentos da natureza. A interação entre tais ritmos por sua vez constitui-se em base e derivação do processo de evolução. O comprometimento de tal alinhamento representa um risco para a sobrevivência das espécies. Neste contexto, os organismos alinham seus ritmos fisiológicos a diferentes ciclos externos. Desta forma, ciclos endógenos são coordenados por relógios biológicos que determinam em nosso organismo, específicos ritmos em fase com a natureza, tais como ritmos circadianos (RC), cujo período aproxima-se de 24 horas. O peso corporal, a ingestão de alimentos e o consumo de energia são processos caracterizados pelo RC e a obesidade está associada a uma dessincronização deste processo. A modulação do RC é resultado da expressão dos clock gens CLOCK e BMAL1 que formam um heterodímero responsável pela transcrição gênica de Per1, Per2, Per3, Cry1 e Cry2. As proteínas codificadas por estes genes, uma vez sintetizadas, formam dímeros (PER-CRY) no citoplasma que, a partir de determinada concentração, retornam ao núcleo, bloqueando a ação do heterodímero CLOCK/BMAL1 na transcrição dos próprios genes, formando assim uma alça de retroalimentação negativa de transcrição e tradução. Estes genes asseguram a periodicidade e são significativamente expressos no núcleo supraquiasmático (SCN) do hipotálamo. Para estudar esse processo em camundongos normais e hiperalimentados, saciados e em estado de fome, foi utilizado um método de registro do comportamento alimentar baseado no som produzido pela alimentação dos animais, e a correlação destes estados metabólicos com a expressão de CLOCK, BMAL1, Per1, Per2, Per3, bem como das proteínas Cry1 e Cry2 no SCN, por análise de imagens obtidas em microscopia confocal. Camundongos suíços controle em estado de fome (CF) e saciados (CS) foram comparados com animais hiperalimentados com fome (HF) e saciados (HS). Nenhum grupo demonstrou diferença nos conteúdos CLOCK e BMAL1, indicando capacidade potencial para modular os ritmos biológicos. No entanto, as proteínas Per1, Per2, Per3 e Cry1 apresentaram menor expressão no grupo CS, mostrando uma diferença significativa quando comparados com o grupo CF (P<0,05), diferença esta não encontrada na comparação entre os grupos HF e HS. A quantidade de proteína Cry2 não foi diferente na mesma comparação. Os resultados do estudo indicaram que as alterações dos ritmos endógenos e exógenos, refletido pelo comportamento hiperfágico observado em camundongos hiperalimentados, pode ser devido a um defeito no mecanismo de feedback negativo associado ao dímero Cry-Per, que não bloqueia a transcrição de Per1 Per2, Per3 e Cry1 pelo heterodímero CLOCK-BMAL1. / The healthy interaction between the subject and the environment depends on the alignment between the physiological dynamics of the first one and the periodical movements of nature. The interaction between these rhythms in turn is based on the derivation and evolution process. The involvement of such an alignment is a risk to the survival of species. In this context the bodies line up their physiological rhythms to different external cycles. Thus, endogenous cycles are coordinated by biological clocks which determine in our organism specific rhythms in phase with the nature, such as Circadian Rhythms (CR) whose period is close to 24 hours. The body weight, the food intake and the energy consumption are processes characterized by the CR and the obesity is associated with a different timing of this process. The CR modulation is a result of the formulation of clock-gens CLOCK and BMAL1 who form an heterodimer responsible for the gene transcription of Per1, Per2, Per3, Cry1 e Cry2. The proteins encoded by these genes, once synthesized, form dimers (PER-CRY) in the cytoplasm that, depending on a given concentration, return to the core blocking the action of the CLOCK/BMAL1 heterodimer in the transcription of its own genes, thus forming a negative feedback loop of transcription and translation. These genes secure the periodicity and are significantly expressed in the hypothalamus suprachiasmatic nucleus. In order to study this process in regular, hyper-fed, hungry and satiated mice, we used a registration method of feeding behavior based on the sound produced by animal feeding and the relation between the metabolic states with the expression CLOCK, BMAL1, Per1, Per2, Per3, as well as the Cry1 and Cry2 proteins in the SCN, by analysis of images obtained in confocal microscopy. Control Swiss mice in state of hunger/ satiated were compared to hyper-fed animals in the same conditions. None of them showed difference in the CLOCK and BMAL1 contents, showing a potential capacity to modulate the biological rhythms. However, the Per1, Per2, Per3 and Cry1 proteins showed a minor expression in the CS group and a significant difference when compared to the CF group (P<0,05). This difference cant be found in the HF and HS groups. The results of the studies indicated that the endogenous and exogenous changes, reflected by the hyperphagic behavior observed in hyper-fed mice, may be due to a defect in the mechanism of negative feedback associated to the Cry-Per dimer, which has abolished the blocking mechanism of Per1 Per2, Per3 and Cry1 by the CLOCK-BMAL1 heterodimer. Ritmo circadiano Programação metabólica Hipotálamo Obesidade Hiperfagia Comportamento alimentar CLOCK BMAL1 Per1 Per2 Per3 Cry1 Cry2 Nutrição - Teses Circadian rhythm Metabolic programming Hypothalamus Obesity Hyperphagia Feeding behavior CLOCK BMAL1 Per1 Per2 Per3 Cry1 Cry2 Nutrition - Theses FISIOLOGIA DE ORGAOS E SISTEMAS
10	Genetic interaction of Per- and Dec-genes in the mammalian circadian clock / Genetische Interaktion der Per und Dec Gene in der zirkadianen Uhr der Säugetiere Bode, Brid 31 May 2011 (has links) No description available. 570 Biowissenschaften Biologie zirkadiane Rhythmik Uhr gentische Interaktion Dec1 Dec2 Per1 Per2 Entrainment Freilauf SCN Maus circadian rhythm clock genetic interaction Dec1 Dec2 Per1 Per2 Entrainment Free-run SCN mice 42.17 42.63 WE 000: Biologische Rhythmen Chronobiologie {Biologie}

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