Μελέτη των παραγόντων που οδηγούν στη μεταβολή του σωματικού βάρους ασθενών με εξωπυραμιδική συνδρομή, που υποβάλλονται σε χειρουργική θεραπεία με εμφύτευση ηλεκτροδίων στον εγκέφαλο και εν τω βάθει ηλεκτρικό ερεθισμό

Μαρκάκη, Έλλη

16 May 2014

Ο εν τω βάθει ηλεκτρικός εγκεφαλικός ερεθισμός (DBS) αποτελεί μία ευρέως αποδεκτή και πολύ αποτελεσματική θεραπευτική μέθοδο για ασθενείς με φαρμακοανθεκτική ν. Πάρκινσον. Διάφορες μελέτες έδειξαν ότι το DBS στον υποθαλάμιο πυρήνα (STN) οδηγεί σε αύξηση του σωματικού βάρους, ο μηχανισμός της οποίας παραμένει άγνωστος. Τα τελευταία χρόνια διατυπώθηκαν διάφορες θεωρίες για τον πιθανό μηχανισμό αυτής της αύξησης βάρους. Σύμφωνα με μία από τις πιο ενδιαφέρουσες θεωρίες, η αύξηση βάρους οφείλεται σε διαταραχή του μηχανισμού ρύθμισης της λήψης τροφής σε υποθαλαμικό επίπεδο. Είναι γνωστό ότι ο υποθάλαμος κατέχει κεντρικό ρόλο στη ρύθμιση της ομοιόστασης της ενέργειας: δέχεται, επεξεργάζεται και ερμηνεύει ορεξιογόνα και ανορεξιογόνα σήματα όπως η γκρελίνη, το ΝΡΥ και η λεπτίνη. Σκοπός της παρούσας μελέτης ήταν η διερεύνηση της πιθανής συμμετοχής του ηλεκτρικού ερεθισμού του υποθαλάμιου πυρήνα στη ρύθμιση της ομοιόστασης της ενέργειας, μέσω της διαταραχής των ορεξιογόνων και ανορεξιογόνων πεπτιδίων γκρελίνη, ΝΡΥ και λεπτίνη. Για το σκοπό αυτό μελετήθηκαν 23 από τους ασθενείς με ν.Πάρκινσον που υποβλήθηκαν σε STN DBS στην κλινική μας (15 άντρες-8 γυναίκες, ηλικία: 65,2 ± 8,9χρόνια, διάρκεια νόσου:12,7 ± 6χρόνια). Κάθε ασθενής εξετάστηκε σε 3 διαδοχικές χρονικές στιγμές: 3 μέρες πριν το χειρουργείο, 3 και 6 μήνες μετά το χειρουργείο και υπεβλήθη σε μέτρηση του σωματικού βάρους και του BMI, λιπομέτρηση και μέτρηση των επιπέδων γκρελίνης, λεπτίνης, NPY και κορτιζόλης ορού. Τρεις μέρες πριν και 6 μήνες μετά το χειρουργείο, πραγματοποιήθηκε κλινική εκτίμηση των ασθενών με τη χρήση των: Unified Parkinson’s Desease Rating Scale (UPDRS), Schwab and England Scale και Hoehn Yahr scale, καθώς και υπολογισμός της ημερήσιας δόσης ντοπαμίνης (LEDD). Τα αποτελέσματα της μελέτης μας συνοψίζονται ως εξής: 3 μήνες μετά τη χειρουργική επέμβαση διαπιστώθηκε σημαντική αύξηση βάρους των ασθενών μας: (3.09±5.00kg, P=0.007), χωρίς περαιτέρω αύξηση στους 6 μήνες. Τα επίπεδα του ΝΡΥ στο περιφερικό αίμα αυξήθηκαν σημαντικά 3 μήνες μετά το χειρουργείο (p=0.05), ενώ τα επίπεδα της γκρελίνης αυξήθηκαν σημαντικά στους 6 μήνες (p=0.001). Η αύξηση του σωματικού βάρους συσχετίστηκε σημαντικά με τη μεταβολή των επιπέδων της γκρελίνης και της λεπτίνης στους 3 και 6 μήνες αντίστοιχα. Συμπερασματικά μπορούμε να πούμε ότι το STN DBS φαίνεται να προκαλεί μία προσωρινή δυσλειτουργία της υποθαλάμιας έκκρισης ΝΡΥ και γκρελίνης. Η μεταβολή του σωματικού βάρους μπορεί να αποδοθεί στην αυξημένη έκκριση γκρελίνης και λεπτίνης. Περαιτέρω μελέτες με μεγαλύτερο αριθμό ασθενών απαιτούνται για να επιβεβαιωθεί ο ρόλος της πεπτιδιακής δυσλειτουργίας στην αύξηση βάρους μετά τη νευροδιέγερση και για να διερευνηθεί η πιθανή νευροπροστατευτική δράση που το DBS μπορεί να ασκήσει μέσω της αύξησης των επιπέδων της γκρελίνης. / Deep brain stimulation (DBS) is a widely accepted and highly effective treatment method for patients with medically refractory idiopathic Parkinson's desease. Various studies have shown that DBS of the subthalamic nucleus (STN) results in increased body weight, the mechanism of which is still unknown. In recent years there were various theories as to the possible mechanism of this weight gain. According to the most interesting theory, weight gain is due to a disruption of the central mechanism that regulates food intake. It is known that the hypothalamus plays a central role in the regulation of energy homeostasis: it receives, processes and interprets orexigenic and anorexigenic signals such as ghrelin, NPY and leptin. The aim of this study was to investigate the possible involvement of STN DBS in the regulation of energy homeostasis, through the disruption of orexigenic and anorexigenic peptides ghrelin, leptin and NPY. Twenty three patients with idiopathic Parkinson’s desease who underwent STN DBS in our clinic were included in our study (15 males - 8 females, age : 65,2 ± 8,9 years, disease duration : 12,7 ± 6chronia ). Each patient was examined at three consecutive time points: 3 days before surgery, 3 and 6 months after surgery. At each clinical appointment all patients underwent body composition measurements including body weight, body mass index (BMI) and fat mass, as well as blood sampling for the measurement of the circulating levels of ghrelin, leptin, NPY and cortisol. Three days before and 6 months after surgery patients were clinically evaluated with the use of the Unified Parkinson's Desease Rating Scale (UPDRS), Schwab and England Scale and Hoehn Yahr scale and the L-dopa daily dose (LEDD) was recorded. The results of our study are summarized as follows : 3 months after surgery there was a significant increase of body weight: (3.09 ± 5.00kg, P = 0.007), with no further increase at 6 months. NPY levels increased significantly 3 months after surgery (p = 0.05), while ghrelin levels increased significantly at 6 months (p = 0.001). Weight gain was significantly correlated with the change of ghrelin and leptin levels at 3 and 6 months respectively. In conclusion, STN DBS seems to temporarily dysregulate the hypothalamic secretion of NPY and ghrelin and weight gain can be attributed to the increased secretion of leptin and ghrelin. Further studies with a larger number of patients are required to confirm the role of peptide dysfunction on weight gain after neurostimulation and to investigate the possible neuroprotective role of DBS, exerted through the increase of ghrelin levels.

Γκρελίνη

Λεπτίνη

Νευροπεπτίδιο Υ

Υποθάλαμος

Νόσος Πάρκινσον

Σωματικό βάρος

Νευροπροστασία

617.481 01

Ghrelin

Leptin

NPY

Hypothalamus

Parkinson's disease

Deep brain stimulation

Body weght

Neuroprotection

Serotonergic Responsiveness in Hypothalamic Neurons

Tung, Stephanie S. Y.

04 December 2012

Serotonin (5-HT) has been implicated in energy homeostasis. There is growing evidence that 5-HT, acting through the 5-HT1BR in the paraventricular nucleus of the hypothalamus (PVN), is important to this regulation. To investigate the cellular events underlying 5-HT1BR action, a PVN neuronal cell model was established. The mHypoA-2/30 cell line expresses a complement of markers and neuropeptides specifically localized to the PVN. 5-HT induces neuronal activation in a dose-dependent manner as determined by an elevation in cFos mRNA levels. As 5-HT exerted limited transcriptional control, the integrity of 5-HT signaling machinery was assessed. 5-HT signals through cAMP and calcium secondary messenger systems by suppressing cAMP and elevating intracellular calcium, effects that are mimicked by activating the 5-HT1BR and that are attenuated in the presence of inhibitors. These findings support the use of this novel PVN cell model for delineating components involved in direct 5-HT action in PVN neurons.

physiology

cellular biology

molecular biology

hypothalamus

neuroendocrinology

feeding behaviour

serotonin

neuropeptide expression

transcriptional regulation

obesity

immortalized cell lines

signal transduction

paraventricular nucleus

neuroscience

real-time PCR

calcium signaling

neuronal activation

secretion

0379

0307

0317

0719

0570

Serotonergic Responsiveness in Hypothalamic Neurons

Tung, Stephanie S. Y.

04 December 2012

Serotonin (5-HT) has been implicated in energy homeostasis. There is growing evidence that 5-HT, acting through the 5-HT1BR in the paraventricular nucleus of the hypothalamus (PVN), is important to this regulation. To investigate the cellular events underlying 5-HT1BR action, a PVN neuronal cell model was established. The mHypoA-2/30 cell line expresses a complement of markers and neuropeptides specifically localized to the PVN. 5-HT induces neuronal activation in a dose-dependent manner as determined by an elevation in cFos mRNA levels. As 5-HT exerted limited transcriptional control, the integrity of 5-HT signaling machinery was assessed. 5-HT signals through cAMP and calcium secondary messenger systems by suppressing cAMP and elevating intracellular calcium, effects that are mimicked by activating the 5-HT1BR and that are attenuated in the presence of inhibitors. These findings support the use of this novel PVN cell model for delineating components involved in direct 5-HT action in PVN neurons.

physiology

cellular biology

molecular biology

hypothalamus

neuroendocrinology

feeding behaviour

serotonin

neuropeptide expression

transcriptional regulation

obesity

immortalized cell lines

signal transduction

paraventricular nucleus

neuroscience

real-time PCR

calcium signaling

neuronal activation

secretion

0379

0307

0317

0719

0570

Dissection du programme développemental du noyau paraventriculaire de l'hypothalamus.

Caqueret, Aurore

03 1900

Une cascade de facteurs de transcription composée de SIM1, ARNT2, OTP, BRN2 et SIM2 est requise pour la différenciation des cinq types cellulaires qui peuplent le noyau paraventriculaire (PVN) de l’hypothalamus, un régulateur critique de plusieurs processus physiologiques essentiels à la survie. De plus, l’haploinsuffisance de Sim1 est aussi une cause d’hyperphagie isolée chez la souris et chez l’homme. Nous désirons disséquer le programme développemental du PVN, via une approche intégrative, afin d’identifier de nouveaux gènes qui ont le potentiel de réguler l’homéostasie chez l’individu adulte. Premièrement, nous avons utilisé une approche incluant l’analyse du transcriptome du PVN à différents stades du développement de la souris pour identifier de tels gènes. Nous avons comparé les transcriptomes de l’hypothalamus antérieur chez des embryons de souris Sim1+/+ et Sim1-/- à E12.5 issus de la même portée. De cette manière, nous avons identifié 56 gènes agissant en aval de Sim1 dont 5 facteurs de transcription - Irx3, Sax1, Rxrg, Ror et Neurod6. Nous avons également proposé un modèle de développement à deux couches de l’hypothalamus antérieur. Selon ce modèle, les gènes qui occupent un domaine médial dans la zone du manteau caractérisent des cellules qui peupleront le PVN alors que les gènes qui ont une expression latérale identifient des cellules qui donneront plus tard naissance aux structures ventrolatérales de l’hypothalamus. Nous avons aussi démontré que Sim1 est impliqué à la fois dans la différenciation, la migration et la prolifération des neurones qui peuplent le PVN tout comme Otp. Nous avons également isolé par microdissection au laser le PVN et l’hypothalamus médiobasal chez des souris de type sauvage à E14.5 pour en comparer les transcriptomes. Ceci nous a permis d’identifier 34 facteurs de transcription spécifiques au PVN et 76 facteurs spécifiques à l’hypothalamus médiobasal. Ces gènes représentent des régulateurs potentiels du développement hypothalamique. Deuxièmement, nous avons identifié 3 blocs de séquences au sein de la région 5’ d’Otp qui sont conservés chez l’homme, la souris et le poisson. Nous avons construit un transgène qui est composé d’un fragment de 7 kb contenant ces blocs de séquences et d’un gène rapporteur. L’analyse de 4 lignées de souris a montré que ce transgène est uniquement exprimé dans le PVN en développement. Nous avons généré un deuxième transgène dans lequel le fragment de 7 kb est inséré en amont de l’ADNc de Brn2 ou Sim1 et de Gfp. Nous avons obtenu quatre lignées de souris dans lesquels le profil d’expression de Brn2 et de Gfp reproduit celui d’Otp. Nous étudierons le développement du PVN et la prise alimentaire chez ces souris. En parallèle, nous croisons ces lignées avec les souris déficientes en Sim1 pour déterminer si l’expression de Brn2 permet le développement des cellules du PVN en absence de Sim1. En résumé, nous avons généré le premier transgène qui est exprimé spécifiquement dans le PVN. Ce transgène constitue un outil critique pour la dissection du programme développemental de l’hypothalamus. Troisièmement, nous avons caractérisé le développement de l’hypothalamus antérieur chez l’embryon de poulet qui représente un modèle intéressant pour réaliser des études de perte et de gain de fonction au cours du développement de cette structure. Il faut souligner que le modèle de développement à deux couches de l’hypothalamus antérieur semble être conservé chez l’embryon de poulet où il est aussi possible de classer les gènes selon leur profil d’expression médio-latéral et le devenir des régions qu’ils définissent. Finalement, nous croyons que cette approche intégrative nous permettra d’identifier et de caractériser des régulateurs du développement du PVN qui pourront potentiellement être associés à des pathologies chez l’adulte telles que l’obésité ou l’hypertension. / A cascade of transcription factors composed of SIM1, ARNT2, OTP, BRN2 and SIM2 is required for the differentiation of the five major cell types populating the paraventricular nucleus (PVN) of the hypothalamus, a critical integrator of several homeostatic processes that are required for the survival of vertebrates. Haploinsufficency of Sim1 also causes isolated hyperphagia in mice and humans. The goal of our study is to dissect the developmental program of the PVN using an integrative approach in order to identify new genes that could potentially be implicated in the regulation of homeostasis in adults. First, we used a comparative approach to analyse the PVN transcriptome at different developmental stages in mice embryos in order to identity new genes implicated in PVN development. We compared gene expression in the anterior hypothalamus of E12.5 Sim1-/- and Sim1+/+ littermate embryos using a microarray approach. We identified 56 genes acting downstream of Sim1 including 5 transcription factors - Irx3, Sax1, Rxrg, Ror and Neurod6. We proposed a model for the development of the anterior hypothalamus. In this model, the genes expressed in the medial domain of the mantle layer characterise cells that will form the PVN and genes expressed in the lateral domain identify cells that will give rise to ventrolateral areas of the hypothalamus. We also showed that Sim1, like Otp, is implicated in the differentiation, migration and proliferation of the neurons populating the PVN. Furthermore, we have isolated by laser captured microdissection the PVN and ARC nucleus in wild type mice at E14.5 and compared their transcriptomes. This technique allowed us to identity 34 transcription factors specific to the PVN and 76 factors specific to the ARC. These genes represent potential regulators of hypothalamic development. Second, we identified 3 blocks of sequence in the 5’ region of Otp that are conserved between human, mouse and fish. We constructed a transgene which included a 7 Kb fragment encompassing these sequences followed by a reporter gene. The analysis of 4 mice strains showed that this transgene is specifically expressed in the prospective PVN. We have generated a second transgene in which the 7 Kb fragment is located upstream of the cDNA encoding Brn2 or Sim1 and Gfp. We obtained 4 mice strains in which the Brn2 and Gfp expression pattern is similar to the Otp expression pattern. These mice will be used to study PVN development and food intake. Also, to determine if Brn2 expression only – without Sim1 gene expression - allows the development of PVN cells, we are presently crossing these mice with Sim1 deficient mice. In conclusion, we have generated the first transgene that is specifically expressed in the PVN. This transgene constitutes a critical tool for dissecting the developmental program of the hypothalamus. Third, we have characterised the development of the anterior hypothalamus of chick embryos which represent an interesting model for loss and gain of function experiments during the development of this brain region. Interestingly, our proposed model for the development of the anterior hypothalamus seems to be conserved in chick embryos. As a matter of fact, it is possible to classify genes according to their medio-lateral expression patterns and the outcome of the regions that they are defining. Finally, we believe that this integrative approach will allow us to identify and characterize factors implicated in PVN development. From a clinical point of view, these factors could potentially be associated with pathologies such as obesity or arterial hypertension.

Sim1

Otp

Brn2

Facteurs de transcription

Noyau paraventriculaire

PVN

Hypothalamus

Promoteur

Transgenèse

Embryon de poulet

Développement

Transcription factor

Paraventricular nucleus

Promoter

Transgenesis

Chick embryo

Development

Dissection du programme développemental du noyau paraventriculaire de l'hypothalamus

Caqueret, Aurore

03 1900

No description available.

Sim1

Otp

Brn2

Facteurs de transcription

Noyau paraventriculaire

PVN

Hypothalamus

Promoteur

Transgenèse

Embryon de poulet

Développement

Transcription factor

Paraventricular nucleus

Promoter

Transgenesis

Chick embryo

Development

Associação do POMC, NPY e IRS2 hipotalâmicos com padrões de comportamento alimentar em ratos wistar normais e sobrepeso / Association of hypotalamic POMC, NPY and IRS2 with feeding behavior in norma and overweight Wistar rats

Mario José dos Santos Pereira

25 May 2009

O comportamento alimentar de uma espécie é determinado por um conjunto de características filogenéticas, ontogenéticas, e epigenéticas, e regulado por fatores internos e externos ao organismo. Os fenômenos naturais que regem a vida no nosso planeta são periódicos em sua maioria, e a oferta de alimentos não é exceção. Cada safra é seguida de uma entressafra, e este ritmo sincroniza diversos outros ritmos, exógenos e endógenos, capazes de determinar a sobrevivência de espécies. Uma das estratégias adaptativas mais primitivas e bem sucedidas na dinâmica oscilatória da natureza é o acúmulo de reservas. Nossa espécie, nos últimos 50 anos, vive uma situação de grande oferta de alimentos, período este extremamente pequeno, se visto sob a ordem de grandeza da evolução humana. Este fenômeno tem sido determinante na prevalência do depósito de energia e em decorrência, do surgimento da obesidade e suas consequentes patologias. O hipotálamo está intimamente associado à homeostase energética e ao comportamento alimentar. No núcleo arqueado hipotalâmico encontram-se populações neuronais orexigênicas e anorexigênicas, dentre as quais, as que expressam os neuroreceptores POMC, NPY e o substrato de receptor de insulina IRS2. A modificação da expressão destas proteínas tem sido associada à alterações do comportamento alimentar, bem como à impressão e programação metabólica, capazes de induzir obesidade em ratos adultos. A correlação desta circuitaria neuronal com o comportamento alimentar, porém, ainda não está suficientemente compreendida. A detecção do estado de fome-saciedade nos ratos, fundamental no estudo da neurofisiologia relacionada ao comportamento alimentar, vem sendo obtida via de regra, por meio de procedimentos complexos de observação comportamental. O presente estudo contribui para o conhecimento de padrões de alimentação determinados por condições nutricionais, e sua relação com a expressão neurofisiológica hipotalâmica dos neurônios POMC, NPY e IRS2. Utilizando o modelo de programação metabólica de Plagemann (1999) obtivemos animais com 25% de sobrepeso em relação aos animais controle, hiperfágicos, e com padrões de tamanho e ritmo circadiano de refeição, distintos. Apesar dos níveis hormonais elevados de leptina (>100%, p<0,001) e insulina (>90%, p<0,05) em relação ao grupo controle, estes animais apresentaram baixa expressão no estado de fome, e alta expressão, na saciedade, de NPY hipotalâmico, sugerindo que o POMC estaria mais comprometido, a longo prazo, com a regulação do ritmo alimentar. A hiperinsulinemia e hiperleptinemia plasmática associada à reduzida expressão de POMC e IRS2 no ARC, corroboraram esta conclusão. Demonstramos também padrões de alimentação distintos. O método de registro da alimentação, baseado no som da roída foi validado como excelente, pelos registros obtidos nos vídeos, e mostrou-se eficiente. Quando os estados de fome-saciedade foram discriminados nos grupos controle e sobrepeso, os resultados da expressão hipotalâmica dos neuroreceptores estudados se mostraram associados aos particulares padrões de alimentação. / The feeding behavior of a specie is determined by a group of phylogenetic, ontogenetic, and epigenetic features, and regulated by internal and external factors to the organism. The natural phenomena that govern life in our planet are mainly periodic, and the food stocks is not an exception. Each harvest is followed by a time between harvests, and this rhythm synchronizes other several exogenous and endogenous rhythms, capable of determining the survival of species. One of the most primitive strategies of adaptative evolution of species, and what usually happens regarding the oscillatory dynamics of nature, is the reserve accumulation. Our species, in the last 50 years, has been living a situation of great food offer, such period is extremely small if analysed under the greatness order of the human evolution. This phenomenon has been decisive in the prevalence of the energy deposit and, in consequence, determining the appearance of obesity and its consequent pathologies. The hypothalamus is intimately associated to the energy homeostasis and the feeding behavior. In the arcuate nucleous are orexigenic and anorexigenic neuronal populations, that express the neuroreceptors POMC, NPY and insulin receptor substratum IRS2. The modification of these proteins expression, has been associated to alterations of the feeding behavior, as well as to the metabolic imprinting and programming, capable to induce obesity in adult rats. The correlation of this neuronal circuits with the alimentary behavior, however, it is not yet sufficiently understood. The detection of the hunger-satiation state in the rat, crucial in the neurophysiology studies related to the alimentary behavior, has been obtained through complex procedures of behavioral observation. The present study contributed to the knowledge of certain feeding patterns for nutritional conditions, and its relationship with the neurophysiological expression of POMC, NPY and IRS2 neurons. Using the metabolic programming model of Plagemann (1999) animals with 25% of overweight in relation to the control animals were obtained, hyperphagics, and with different size patterns and meal circadian rhythm. In spite of the high hormonal levels of leptin (>100%, p < 0,001) and insulin (>90%, p < 0,05) in relation to the control groups, these animals presented low expression in the hunger state, and high expression in the satiation of hypothalamic NPY, suggesting that POMC would be more committed, in the long term, with the regulation of the feeding rhythm. The hyperinsulinemia and plasmatic hyperleptinemia associated to the reduced POMC and IRS2 expression in the ARC, corroborated this conclusion. We also demonstrated different feeding patterns. The feeding registration method, based on the gnaw sound was validated as excellent, when comparedto a gold pattern, the registrations obtained in the videos, and it were considered efficient. When the hunger-satiation states were discriminated in the control and overweight groups, the results of the hypothalamic neuroreceptors expression studied showed association to the feeding patterns.

Comportamento alimentar

Ritmo circadiano

Pró-ópiomelanocortina

Receptor de insulina substrato 2

Neuropeptídeo Y

Hiperfagia

Obesidade

Hipotálamo

Programação metabólica

Feeding behavior

pro-ópiomelanocortin

Insulin-receptor substratum 2

Neuropeptide Y

Hyperphagia

Obesity

Hypothalamus

Metabolic programming

Circadian rhythm

NEUROFISIOLOGIA

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

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

Natriorexigênese paradoxal: núcleo parabraquial lateral e mecanismos centrais, sistêmicos e comportamentais

David, Richard Boarato

22 March 2013

Made available in DSpace on 2016-06-02T19:22:09Z (GMT). No. of bitstreams: 1 5394.pdf: 2154328 bytes, checksum: 49114074adb778dc78d219f32b8ee5b4 (MD5) Previous issue date: 2013-03-22 / Sodium intake is induced by facilitatory signals, like angiotensin II and aldosterone Cell dehydration, a classical inhibitory signal for sodium intake, may also induce paradoxical sodium intake if the sodium intake inhibition by the ocitocinergic hypothalamic mechanism or by the lateral parabraquial nucleus (LPBN) is absent. Thus, the LPBN deactivation could modify the activity of hypothalamic oxytocinergic pathways or the gastric emptying control system, another inhibitory system, as well as facilitatory areas and the reward system. The aim of this study was to investigate the effect of LPBN injections of methysergide (4 &#956;g/0.2 &#956;l, serotonergic antagonist) in cell dehydrated animals on: activity of brain areas involved in ingestive behavior by measuring c-Fos protein immunoreactivity and tissue levels of dopamine, serotonin and metabolites or plasma hormone levels; pre-systemic satiety involving gastric emptying; selectivity of paradoxical sodium intake. The effect of disinhibition of the natriorexigenesis on the reward system was tested by repeated deactivations of the LPBN with muscimol (2 nmol/0.2 &#956;l; GABAA agonist) and its effect on ingestive behavior sensitization and water deprivation with partial rehydration followed by sodium access (WD-PR protocol) on the lateral hypothalamus self-stimulation (LHSS). Holtzman or Sprague-Dawley rats (280-320 g), intacts or operated (femoral vein cannulation and/or guide cannulas implanted in direction to the LPBN or bipolar electrode implanted in the hypothalamus), were used in the experiments. Animals treated with methysergide and hyperosmotic by gavage of 2 M NaCl (2 ml) compared to the control treatment (vehicle) showed: (a) increase in ir-Fos in the area postrema and intermediate nucleus of the solitary tract, subfornical organ and non-oxytocinergic neurons of the ventral portion of the paraventricular nucleus of the hypothalamus; (b) increase in tissue levels of dopamine in the amygdala, but not in the accumbens; (c) unchanged activity of oxytocinergic system (ir-Fos in oxytocinergic neurons and oxytocin plasma levels similar to control group). Hyperosmotic rats (iv infusion of 2 ml of 2 M NaCl) treated with methysergide and a gavage of 0.3 M NaCl (3 ml) showed a hypertonic gastric and intestinal content similar to the control group (vehicle) after gavage. In hydrated animals with a history of two previous treatments of muscimol into the LPBN, the hypertonic NaCl intake induced by muscimol was higher than the control animals pretreated with vehicle. The LHSS was not altered at any stage of WD-PR protocol, as well as in cell dehydrated animals in comparison with hydrated control group. The results demonstrate that the deactivation of the LPBN enhances specifically the intake of solutions containing sodium and suggest the involvement of the brain stem and the amygdala during the appetitive phase of the paradoxical sodium intake, while the deactivation of other inhibitory mechanisms (oxytocin and gastric retention) seems not to be essential. Furthermore, the repetition of LPBN deactivation sensitizes hydrated animals for sodium intake. Removing the inhibition of sodium appetite by partial rehydration in WD-PR does not change the LHSS reward. / A ingestão de sódio é induzida por sinais facilitadores, como a angiotensina II e a aldosterona. Apesar de classicamente considerada antinatriorexigênica, a desidratação celular também se mostra facilitadora da ingestão paradoxal de sódio quando a inibição da ingestão de sódio pelo mecanismo ocitocinérgico do hipotálamo ou pelo núcleo parabraquial lateral (NPBL) está desativada. A desativação do NPBL poderia, então, atuar sobre o mecanismo ocitocinérgico ou de controle do esvaziamento gástrico, ambos inibidores, ou ainda modificar a atividade de áreas facilitadoras ou envolvidas na recompensa. O objetivo deste estudo foi investigar o efeito da injeção de metisergida (4 &#956;g/0,2 &#956;l, antagonista serotonérgico) no NPBL em animais com desidratação celular sobre a: atividade de áreas encefálicas envolvidas no comportamento ingestivo, medindo-se imunorreatividade para proteína c-Fos e dosagem tecidual de dopamina, serotonina e metabólitos em áreas de interesse ou dosagem hormonal; saciedade pré-sistêmica envolvendo esvaziamento gástrico; seletividade da ingestão paradoxal de sódio. Também foi avaliado o possível efeito da desinibição da natriorexigênese sobre o sistema de recompensa através da sensibilização por desativações repetidas do NPBL pelo muscimol (2 nmol/0,2 &#956;l; agonista GABAA) e na privação hídrica com reidratação parcial e posterior acesso ao sódio (modelo PH-RP) sobre a autoestimulação elétrica do hipotálamo lateral (AEHL). Ratos (280-320 g) Holtzman ou Sprague-Dawley, intactos ou operados (canulação da veia femoral e/ou cânulas-guia direcionadas ao NPBL ou eletrodo bipolar no hipotálamo), foram utilizados nos experimentos. Animais tratados com metisergida e hiperosmóticos por gavagem de NaCl 2 M (2 ml) apresentaram, em relação ao tratamento controle (veículo): (a) aumento da ir-Fos na área postrema e núcleo do trato solitário intermediário, no órgão subfornical e em neurônios não ocitocinérgicos da porção ventral do núcleo paraventricular do hipotálamo; (b) aumento da concentração tecidual de dopamina na amígdala, mas não no accumbens; (c) atividade do sistema ocitocinérgico inalterada (ir-Fos em neurônios ocitocinérgicos e ocitocina plasmática semelhantes ao controle). Ratos tratados com metisergida e hiperosmóticos por infusão iv de NaCl 2 M (1,5 ml), que receberam uma gavagem de NaCl 0,3 M (3 ml) apresentaram conteúdo gástrico e intestinal hipertônico semelhantes ao controle (veículo) após a gavagem. Em animais hidratados com histórico de dois tratamentos prévios de muscimol no NPBL, a ingestão de NaCl hipertônico induzida por muscimol foi superior aos animais controle tratados previamente com veículo. A AEHL não foi alterada em nenhuma fase do protocolo PH-RP, assim como em animais com desidratação celular, em relação aos controles hidratados. Os resultados demonstram que a desativação do NPBL potencializa especificamente a ingestão de solução contendo sódio e sugerem a participação do tronco encefálico e da amígdala na fase apetitiva da ingestão paradoxal de sódio, enquanto a desativação de outros mecanismos inibidores (ocitocina e retenção gástrica) parece não ser essencial. Ainda, a repetição da desativação do NPBL sensibiliza a ingestão de sódio em animais hidratados. A remoção da inibição ao apetite ao sódio pela reidratação parcial na PHRP não altera a recompensa na AEHL.

Fisiologia humana

Núcleo parabraquial lateral

Desidratação celular

Ocitocina

Esvaziamento gástrico

Natriorexigênese

Esvaziamento gástrico

Saciedade

Recompensa

Autoestimulação do hipotálamo lateral

Lateral parabrachial nucleus

Cell dehydration

Natriorexigenesis

Oxytocin

Gastric emptying

Satiety

Reward

Lateral hypothalamus self-stimulation

CIENCIAS BIOLOGICAS::FISIOLOGIA

Associação do POMC, NPY e IRS2 hipotalâmicos com padrões de comportamento alimentar em ratos wistar normais e sobrepeso / Association of hypotalamic POMC, NPY and IRS2 with feeding behavior in norma and overweight Wistar rats

Mario José dos Santos Pereira

25 May 2009

O comportamento alimentar de uma espécie é determinado por um conjunto de características filogenéticas, ontogenéticas, e epigenéticas, e regulado por fatores internos e externos ao organismo. Os fenômenos naturais que regem a vida no nosso planeta são periódicos em sua maioria, e a oferta de alimentos não é exceção. Cada safra é seguida de uma entressafra, e este ritmo sincroniza diversos outros ritmos, exógenos e endógenos, capazes de determinar a sobrevivência de espécies. Uma das estratégias adaptativas mais primitivas e bem sucedidas na dinâmica oscilatória da natureza é o acúmulo de reservas. Nossa espécie, nos últimos 50 anos, vive uma situação de grande oferta de alimentos, período este extremamente pequeno, se visto sob a ordem de grandeza da evolução humana. Este fenômeno tem sido determinante na prevalência do depósito de energia e em decorrência, do surgimento da obesidade e suas consequentes patologias. O hipotálamo está intimamente associado à homeostase energética e ao comportamento alimentar. No núcleo arqueado hipotalâmico encontram-se populações neuronais orexigênicas e anorexigênicas, dentre as quais, as que expressam os neuroreceptores POMC, NPY e o substrato de receptor de insulina IRS2. A modificação da expressão destas proteínas tem sido associada à alterações do comportamento alimentar, bem como à impressão e programação metabólica, capazes de induzir obesidade em ratos adultos. A correlação desta circuitaria neuronal com o comportamento alimentar, porém, ainda não está suficientemente compreendida. A detecção do estado de fome-saciedade nos ratos, fundamental no estudo da neurofisiologia relacionada ao comportamento alimentar, vem sendo obtida via de regra, por meio de procedimentos complexos de observação comportamental. O presente estudo contribui para o conhecimento de padrões de alimentação determinados por condições nutricionais, e sua relação com a expressão neurofisiológica hipotalâmica dos neurônios POMC, NPY e IRS2. Utilizando o modelo de programação metabólica de Plagemann (1999) obtivemos animais com 25% de sobrepeso em relação aos animais controle, hiperfágicos, e com padrões de tamanho e ritmo circadiano de refeição, distintos. Apesar dos níveis hormonais elevados de leptina (>100%, p<0,001) e insulina (>90%, p<0,05) em relação ao grupo controle, estes animais apresentaram baixa expressão no estado de fome, e alta expressão, na saciedade, de NPY hipotalâmico, sugerindo que o POMC estaria mais comprometido, a longo prazo, com a regulação do ritmo alimentar. A hiperinsulinemia e hiperleptinemia plasmática associada à reduzida expressão de POMC e IRS2 no ARC, corroboraram esta conclusão. Demonstramos também padrões de alimentação distintos. O método de registro da alimentação, baseado no som da roída foi validado como excelente, pelos registros obtidos nos vídeos, e mostrou-se eficiente. Quando os estados de fome-saciedade foram discriminados nos grupos controle e sobrepeso, os resultados da expressão hipotalâmica dos neuroreceptores estudados se mostraram associados aos particulares padrões de alimentação. / The feeding behavior of a specie is determined by a group of phylogenetic, ontogenetic, and epigenetic features, and regulated by internal and external factors to the organism. The natural phenomena that govern life in our planet are mainly periodic, and the food stocks is not an exception. Each harvest is followed by a time between harvests, and this rhythm synchronizes other several exogenous and endogenous rhythms, capable of determining the survival of species. One of the most primitive strategies of adaptative evolution of species, and what usually happens regarding the oscillatory dynamics of nature, is the reserve accumulation. Our species, in the last 50 years, has been living a situation of great food offer, such period is extremely small if analysed under the greatness order of the human evolution. This phenomenon has been decisive in the prevalence of the energy deposit and, in consequence, determining the appearance of obesity and its consequent pathologies. The hypothalamus is intimately associated to the energy homeostasis and the feeding behavior. In the arcuate nucleous are orexigenic and anorexigenic neuronal populations, that express the neuroreceptors POMC, NPY and insulin receptor substratum IRS2. The modification of these proteins expression, has been associated to alterations of the feeding behavior, as well as to the metabolic imprinting and programming, capable to induce obesity in adult rats. The correlation of this neuronal circuits with the alimentary behavior, however, it is not yet sufficiently understood. The detection of the hunger-satiation state in the rat, crucial in the neurophysiology studies related to the alimentary behavior, has been obtained through complex procedures of behavioral observation. The present study contributed to the knowledge of certain feeding patterns for nutritional conditions, and its relationship with the neurophysiological expression of POMC, NPY and IRS2 neurons. Using the metabolic programming model of Plagemann (1999) animals with 25% of overweight in relation to the control animals were obtained, hyperphagics, and with different size patterns and meal circadian rhythm. In spite of the high hormonal levels of leptin (>100%, p < 0,001) and insulin (>90%, p < 0,05) in relation to the control groups, these animals presented low expression in the hunger state, and high expression in the satiation of hypothalamic NPY, suggesting that POMC would be more committed, in the long term, with the regulation of the feeding rhythm. The hyperinsulinemia and plasmatic hyperleptinemia associated to the reduced POMC and IRS2 expression in the ARC, corroborated this conclusion. We also demonstrated different feeding patterns. The feeding registration method, based on the gnaw sound was validated as excellent, when comparedto a gold pattern, the registrations obtained in the videos, and it were considered efficient. When the hunger-satiation states were discriminated in the control and overweight groups, the results of the hypothalamic neuroreceptors expression studied showed association to the feeding patterns.

Comportamento alimentar

Ritmo circadiano

Pró-ópiomelanocortina

Receptor de insulina substrato 2

Neuropeptídeo Y

Hiperfagia

Obesidade

Hipotálamo

Programação metabólica

Feeding behavior

pro-ópiomelanocortin

Insulin-receptor substratum 2

Neuropeptide Y

Hyperphagia

Obesity

Hypothalamus

Metabolic programming

Circadian rhythm

NEUROFISIOLOGIA

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

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