The Role Of Leptin Receptor Expressing Neurocircuitry In Energy Homeostasis

January 2015

1 / Yanyan Jiang

An investigation of the interaction between AMP-activated protein kinase subunits

Cheung, Peter Ching For

January 2000

No description available.

572

Molecular studies on the interaction of leptin with its receptor

Mistrik, Pavel

January 2000

No description available.

572

Developmental signaling pathways in adult energy homeostasis

Antonellis, Patrick

08 1900

Indiana University-Purdue University Indianapolis (IUPUI) / Many signaling pathways which are classically understood for their roles in early development are also known to be involved in tissue maintenance and adult energy homeostasis. Furthermore, dysfunction of these signaling pathways results in human diseases such as cancer. An in depth understanding of how developmentally important signaling pathways function in the adult will provide mechanistic insights into disease and potential new therapeutic targets. Here in Chapter 1, the Wnt, fibroblast growth factor (FGF), and Hedgehog (Hh) signaling pathways are discussed and examples of their relevance in development, adult homeostasis, and disease are provided. Wnt signaling provides an example of this concept as it has well described roles during both development and adult metabolism. Work included in Chapter 2, investigates the regulation of adult energy homeostasis by a member of the endocrine FGF family, FGF19. The three endocrine FGFs, FGF19 (FGF15 in mice), FGF21, and FGF23 have well described roles in the regulation of metabolic processes in adults. While FGF23 is primarily involved in the regulation of phosphate and vitamin D homeostasis, FGF19 and FGF21 have shown similar pharmacological effects on whole body metabolism. Here, the importance of adaptive thermogenesis for the pharmacological action of FGF19 is explored. Using UCP1KO animals we show that whole-body thermogenesis is dispensable for body weight loss following FGF19 treatment. Finally, the potential involvement of Hh signaling in mediating the hyperphagia driven obesity observed in certain ciliopathies is explored in Chapter 3. Emerging evidence suggests cilia play an important role in the regulation of feeding behavior. In mammals, the hedgehog pathway is dependent on the primary cilium as an organizing center and defects in hedgehog signaling share some clinical symptoms of ciliopathies. Here, we characterized the expression of core pathway components in the adult hypothalamus. We show that neurons within specific nuclei important for regulation of feeding behavior express Hh ligand and members of its signaling pathway. We also demonstrate that the Hh pathway is transcriptionally upregulated in response to an overnight fast. This work provides an important foundation for understanding the functional role of Hh signaling in regulation of energy homeostasis. In its entirety, this work highlights the emerging clinical relevance of developmentally critical pathways in diseases associated with dysfunction of adult tissue homeostasis, such as obesity.

Obesity

Hypothalamus

Cilia

Energy homeostasis

FGF19

ADIPONECTIN MODULATES EXCITABILITY OF SUBFORNICAL ORGAN NEURONS AT DIFFERENT ENERGY STATES

Alim, Ishraq

01 April 2009

Adiponectin (ADP) is an adipokine, which acts as an insulin sensitizing hormone. Recent studies have shown that adiponectin receptors (AdipoR1, AdipoR2) are present in the CNS; however, there is some debate as to whether or not ADP crosses the blood brain barrier (BBB). Circumventricular organs (CVO) are CNS sites outside the BBB, and thus represent sites at which circulating adiponectin may act to influence the CNS without having to cross the BBB. The subfornical organ (SFO) is a CVO that is responsive to a number of different circulating satiety signals including amylin, CCK, and ghrelin. We report here that the SFO also shows a high density of mRNA for both adiponectin receptors. These observations support the concept that the SFO may be a key player in sensing circulating ADP. To test the hypothesis that ADP influences the excitability of SFO neurons, we used current-clamp electrophysiology on dissociated SFO neurons to observe changes in membrane potential. ADP (10 nM) application effected the excitability of SFO neurons, where the cells either depolarized (8.9±0.9 mV, 21 of 97 cells) or hyperpolarized (-8.0±0.5 mV, 34 of 97 cells). Using single-cell RT-PCR we found that the majority of the responsive neurons expressed AdipoR1 or R2 and the non-responsive neurons expressed neither. In view of the recognized role of ADP in the regulation of energy balance, we next examined the effects of food deprivation for 48 hours on ADP signaling in the SFO. Our previous microarray analysis of SFO showed increases in AdipoR2 mRNA, with no significant change in AdipoR1 mRNA. We have also assessed the effects of such changes in receptor expression on ADP signaling in SFO neurons using calcium imaging and patch clamp techniques. In SFO neurons obtained from control animals, ADP induced increases in intracellular Ca2+ were observed in 25% of cells, while following food deprivation 0% of cells showed this response. Furthermore, 77% of neurons from starved animals showed clear depolarization, while no hyperpolarizing responses were observed. The results presented in this study suggest that adiponectin modulates the excitability of SFO neurons and that the response to ADP changes during starvation. / Thesis (Master, Neuroscience Studies) -- Queen's University, 2008-09-17 18:07:35.099

Adiponectin

Subfornical Organ

circumventricular organ

patch clamp

Energy homeostasis

THE PHYSIOLOGICAL ACTIONS OF ADIPONECTIN IN CENTRAL AUTONOMIC NUCLEI: IMPLICATIONS FOR THE INTEGRATIVE CONTROL OF ENERGY HOMEOSTASIS

HOYDA, TED

13 April 2010

Adiponectin regulates feeding behavior, energy expenditure and autonomic function through the activation of two receptors present in nuclei throughout the central nervous system, however much remains unknown about the mechanisms mediating these effects. Here I investigate the actions of adiponectin in autonomic centers of the hypothalamus (the paraventricular nucleus) and brainstem (the nucleus of the solitary tract) through examining molecular, electrical, hormonal and physiological consequences of peptidergic signalling. RT-PCR and in situ hybridization experiments demonstrate the presence of AdipoR1 and AdipoR2 mRNA in the paraventricular nucleus. Investigation of the electrical consequences following receptor activation in the paraventricular nucleus indicates that magnocellular-oxytocin cells are homogeneously inhibited while magnocellular-vasopressin neurons display mixed responses. Single cell RT-PCR analysis shows oxytocin neurons express both receptors while vasopressin neurons express either both receptors or one receptor. Co-expressing oxytocin and vasopressin neurons express neither receptor and are not affected by adiponectin. Median eminence projecting corticotropin releasing hormone neurons, brainstem projecting oxytocin neurons, and thyrotropin releasing hormone neurons are all depolarized by adiponectin. Plasma adrenocorticotropin hormone concentration is increased following intracerebroventricular injections of adiponectin. I demonstrate that the nucleus of the solitary tract, the primary cardiovascular regulation site of the medulla, expresses mRNA for AdipoR1 and AdipoR2 and mediates adiponectin induced hypotension. Adiponectin has electrical effects on a majority of medial solitary tract neurons and depolarizes those expressing mRNA for the hypotensive neuropeptide Y, revealing a central mechanism to modulate blood pressure. Finally, I show that adiponectin controls paraventricular nucleus neuron excitability by either inhibiting a tetraethyl ammonium-sensitive potassium current thereby depolarizing neurons or activating a glibenclamide-sensitive voltage independent potassium current hyperpolarizing neurons. Therefore, adiponectin differentially modulates potassium current to confer its central effects. These results are the first to show the physiological and electrical actions of adiponectin on individual neurons in blood brain barrier protected central autonomic nuclei. This thesis provides a framework for how adiponectin acts centrally to coordinate whole body energy homeostasis and feeding behavior in the rat. / Thesis (Ph.D, Physiology) -- Queen's University, 2009-09-15 16:50:13.933

adiponectin

paraventricular nucleus

nucleus of the solitary tract

energy homeostasis

autonomic function

Insulin modulates the electrical activity of dissociated and cultured Subfornical Organ (SFO) neurons in male Sprague Dawley Rats

Lakhi, Suman

06 January 2012

The brain is protected by the blood brain barrier (BBB); areas lacking the BBB are termed circumventricular organs (CVOs). The SFO, a CVO is capable of detecting and responding to satiety signals that regulate energy balance. Insulin, a satiety signal, plays a role in energy balance and its actions at the SFO are unknown. The goal was to determine if cultured SFO neurons are electrophysiologically sensitive to insulin. Of 27 neurons tested 33% neurons hyperpolarized (-8.7 ± 1.7 mV), 37% neurons depolarized (10.5 ±2.8 mV) and 30% neurons (8 out of 27) showed no change in membrane potential. Input resistance changes indicated the modulation of two ion channels. Pharmacological data suggests hyperpolarization arises from the opening of KATP channels and depolarization results from the opening of non-selective cationic channels. Thus insulin modulates the electrical activity of SFO neurons and supports that the SFO is a sensor for maintaining energy homeostasis.

neuroscience

electrophysiology

insulin

subfornical organ

obesity

energy homeostasis

Insulin modulates the electrical activity of dissociated and cultured Subfornical Organ (SFO) neurons in male Sprague Dawley Rats

Lakhi, Suman

06 January 2012

The brain is protected by the blood brain barrier (BBB); areas lacking the BBB are termed circumventricular organs (CVOs). The SFO, a CVO is capable of detecting and responding to satiety signals that regulate energy balance. Insulin, a satiety signal, plays a role in energy balance and its actions at the SFO are unknown. The goal was to determine if cultured SFO neurons are electrophysiologically sensitive to insulin. Of 27 neurons tested 33% neurons hyperpolarized (-8.7 ± 1.7 mV), 37% neurons depolarized (10.5 ±2.8 mV) and 30% neurons (8 out of 27) showed no change in membrane potential. Input resistance changes indicated the modulation of two ion channels. Pharmacological data suggests hyperpolarization arises from the opening of KATP channels and depolarization results from the opening of non-selective cationic channels. Thus insulin modulates the electrical activity of SFO neurons and supports that the SFO is a sensor for maintaining energy homeostasis.

neuroscience

electrophysiology

insulin

subfornical organ

obesity

energy homeostasis

Elucidating the Metabolic Function of RORalpha and gamma in Skeletal Muscle

Surya Prakash

Unknown Date

Nuclear Hormone Receptors (NRs) are hormone dependent DNA binding proteins that translate physiological signals into gene expression. Gene products have been identified that belong to the NR superfamily on the basis of homology. However, the endogenous and /or synthetic ligands that regulate their activity remain unknown, consequently, this subgroup of proteins are designated as orphans). Retinoic acid receptor related orphan receptors alpha and gamma(RORα and γ) are orphan NRs, and are preferentially expressed in skeletal muscle a major metabolic tissue and other tissues including pancreas, thymus, prostate, liver, adipose and testis. Surprisingly, the specific roles of ROR α and γ in skeletal muscle, a peripheral tissue, have not been examined. Muscle is one of the most energy demanding tissues which accounts for ~40% of the total body mass and energy expenditure, ~75% of glucose disposal and relies heavily on β-oxidation of fatty acids. We hypothesize that ROR α and γ regulates metabolism in this major mass lean tissue. Initially, this hypothesis was examined by “gain and loss” of function studies in an in-vitro mouse skeletal muscle cell culture model. Previous in vitro studies analyzed the role of RORα in the regulation of lipid homeostasis in skeletal muscle cells. We similarly conducted in vitro RORγ gain and loss of function studies in skeletal muscle cells to understand the role of this isoform in metabolism. We utilized stable ectopic over-expression of VP16-RORγ (gain of function), native RORγ and RORγΔH12 (loss of function) vectors to modulate RORγ mRNA expression and function. Candidate driven expression profiling of lines that ectopically express the native and variant forms of RORγ suggested that this orphan NR has a function in regulating the expression of genes that control lipid homeostasis (fatty acid-binding protein 4), CD36 (fatty acid translocase), lipoprotein lipase and uncoupling protein 3), carbohydrate metabolism (GLUT5 (fructose transporter), adiponectin receptor 2 and interleukin 15 (IL-15)) and muscle mass (including myostatin and IL-15). Interestingly, our study revealed a function for RORγ in the pathway that regulates production of reactive oxygen species which was also correlated with increased expression of UCP3 mRNA. Subsequently, we conducted in vivo studies with mouse models displaying global and muscle specific perturbation in RORα expression and function to elucidate the physiological role of this orphan NR in the context of metabolism.Along these lines, we characterized homozygous staggerer mice (sg/sg) in the context of lipid, carbohydrate and energy homeostasis. Staggerer mice were characterized by decreased and dysfunctional retinoic acid receptor-related orphan receptor alpha (RORα) expression. We observed decreases in serum (and liver) triglycerides and total and high density lipoprotein serum cholesterol in staggerer mice. Moreover, the staggerer mice were associated with reduced adiposity, decreased fat pad mass and adipocyte size. Candidate-based expression profiling demonstrated that the dyslipidemia in staggerer mice was associated with decreased hepatic expression of SREBP-1c, and the reverse cholesterol transporters, ABCA1 and ABCG1. This was consistent with the reduced serum lipids. Furthermore, the lean phenotype in staggerer mice was also characterized by significantly increased expression of PGC-1α, PGC-1β, and lipin1mRNAin liver and white and brown adipose tissue from staggerer mice. In addition, we observed a significant 4-fold increase in β2-adrenergic receptor mRNA in brown adipose tissue. Finally, dysfunctional RORα expression protects against diet-induced obesity. Following a 10-week high fat diet, wild-type (but not sg/sg) mice exhibited a ~20% weight gain, increased hepatic triglycerides, and notable white and brown adipose tissue accumulation. In summary, these changes in gene expression (that modulate lipid homeostasis) in metabolic tissues were involved in decreased adiposity and resistance to diet induced obesity in the sg/sg mice, despite hyperphagia. Finally, we specifically modulated RORα signaling in skeletal muscle by the targeted over-expression of truncated RORαΔDE (lacking the ligand binding domain) driven by a myogenic specific promoter, to investigate the contribution of this peripheral tissue to the RORα phenotype. Interestingly, transgenic heterozygous animals exhibit increased fasting blood glucose levels and mild glucose intolerance. Expression profiling (and western analysis) identified perturbations in the insulin signaling cascade. For example, we observed attenuation of p85alpha (PI3K) and Akt2 (mRNA and protein) expression; and insulin dependent induction of phospho-Akt2. In concordance, significantly increased levels of active phospho-AMPK were detected in the muscle of transgenic mice (relative to wt littermates). The increase in phospho-AMPK correlated with: (i) the suppression of lipogenic gene expression; and (ii) increased phospho-ACC and activation of genes involved in fatty acid oxidation in the skeletal muscle of transgenic animals. In conclusion, we suggest these orphan nuclear receptors (RORα and γ) are key modulators of fat and carbohydrate homeostasis in skeletal muscle tissue. Specifically, we propose that, RORα plays vital role in fat accumulation in adipose tissue and insulin mediated glucose homeostasis in skeletal muscle. Therefore we suggest that selective muscle specific RORα modulators may have utility in the treatment of type2 diabetes and obesity.

L'hydrolyse des lipoprotéines dans le Système Nerveux Central : un nouvel acteur dans la régulation de l'homéostasie énergétique / The hydrolysis of lipoproteins in the Central Nervous System : a new actor in the regulation of energy balance.

Laperrousaz, Elise

03 October 2016

Le Système Nerveux Central (SNC) est un acteur majeur de la régulation de l’homéostasie énergétique, intégrant différents signaux nerveux, hormonaux ou nutritionnels. Le métabolisme lipidique joue un rôle essentiel notamment dans la détection des signaux lipidiques, et les enzymes y participant sont donc fortement impliquées dans la régulation de ces signaux et leur expression est cruciale au bon équilibre énergétique. La Lipoprotéine Lipase (LPL), enzyme clé de l'hydrolyse des triglycérides, nous est apparue comme une cible de choix dans la mesure où elle est exprimée dans différentes structures cérébrales comme l'hippocampe ou l'hypothalamus. L'hypothalamus a été identifié depuis de nombreuses années comme un centre de régulation de la prise alimentaire et donc de l'équilibre entre entrées et dépenses d'énergie. Ainsi, il est apparu comme légitime que de s'intéresser plus précisément au rôle de la LPL hypothalamique et son implication dans la régulation de l'homéostasie énergétique.L'objet de cette thèse a donc été d'étudier, dans un premier temps, les effets d'une délétion de LPL dans le VMH, réalisée grâce à une injection d'un AAV2/9 exprimant la Cre recombinase chez des souris LPL lox/lox âgées de 8 semaines. La diminution de l'activité LPL dans le VMH conduit au développement d'une obésité au bout de 3 semaines post-injection, ainsi qu'au développement d'une intolérance au glucose, d'une résistance à l'insuline ainsi qu'une diminution de l'activité locomotrice.Ce phénotype est dû à une diminution transitoire de la quantité de céramides synthétisées par l’enzyme CerS1 au sein de l'hypothalamus durant les semaines qui suivent l'injection et qui perturbent la signalisation homéostatique. Il apparait également que le système endocannabinoïde pourrait être impliqué dans la mise en place de ce phénotype. Les caractéristiques de ce phénotype rappelant celles d'un état de torpeur, nous avons cherché dans la deuxième partie de ce travail de thèse, à reproduire celui-ci pour pouvoir étudier plus précisément les liens et les conséquences entre torpeur et lipases cérébrales. Nous avons donc exposés les animaux à 4°C pendant 4 heures et étudié les répercussions de ce stress thermique sur les gènes des lipases centrales ainsi que ceux du rythme circadien : nous avons pu mettre en évidence une modification du rythme circadien. Nous avons également exposé des animaux délétés en LPL hypothalamique et pu établir que cette délétion centrale en LPL modifie la thermogenèse du tissu adipeux brun ainsi et favorise le développement du tissu adipeux beige. Ce travail de thèse a donc permis de mettre en lumière pour la première fois l'implication de la LPL hypothalamique dans la régulation de l'homéostasie énergétique ainsi que son rôle dans la réponse adaptative à une exposition aiguë au froid. / The Central Nervous System (CNS) is a major actor in the energy balance regulation, integrating different nervous, hormonal or nutritional signals. The lipid metabolism plays an essential role especially in the detection of lipid signals. So, the enzymes taking part in it are involved in the regulation of these signals and their expression is crucial to the energy balance. The Lipoprotein Lipase (LPL), the key enzyme in triglycerides hydrolysis appeared to us as a target of choice as it is expressed in different brain structures like the hypothalamus or the hippocampus.The hypothalamus has long been known as a regulation center of food intake and so of the balance between entrance and expenditure of energy. It seemed interesting to focus more precisely on the role of hypothalamic LPL and its implication in the regulation of energy homeostasis.This dissertation’s main objective was to identify the effects of LPL deletion in the VMH, achieved by injection of an AAV2/9 expressing the Cre-recombinase in LPL lox/lox mice aged of 8 weeks. The decrease of LPL activity in the VMH leads to obesity development around 3 weeks post-injection and to the development of glucose intolerance, resistance to insulin and a decrease in locomotor activity.This phenotype is probably due to a transient decrease of ceramides synthesized by the CerS1 enzyme in the hypothalamus during the weeks post-injection and which disrupts the homeostatic signalling. The endocannabinoid system also seems to be involved in the onset of this phenotype.As the characteristics of this phenotype were reminiscent of a torpor state, we tried in a second part of work to reproduce it to study more precisely the links between torpor and brain lipases. We exposed animals to 4°C for 4 hours and studied the repercussions of this thermic stress on the central lipases genes and on circadian rhythm genes: we were able to highlight a modulation of the circadian rhythm. We also exposed to the cold VMH-LPL-depleted mice and established that this depletion in VMH-LPL modifies the thermogenesis of brown adipose tissue and so promotes the development of beige adipocytes.This work highlights for the first time the implication of hypothalamic LPL in the regulation of energy homeostasis and its role in adaptive response to cold exposure.

Homéostasie énergétique

Système endocannabinoïde

Energy homeostasis

Endocannabinoid system