Hostname: page-component-78c5997874-g7gxr Total loading time: 0 Render date: 2024-11-17T17:25:36.134Z Has data issue: false hasContentIssue false

The receptive function of hypothalamic and brainstem centres to hormonal and nutrient signals affecting energy balance

Published online by Cambridge University Press:  29 August 2012

Thomas Riediger*
Affiliation:
Institute of Veterinary Physiology and Centre of Integrative Human Physiology, University of Zurich, 8057 Zurich, Switzerland
*
Corresponding author: Thomas Riediger, fax+41 44 635 8932, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The hypothalamic arcuate nucleus (ARC) and the area postrema (AP) represent targets for hormonal and metabolic signals involved in energy homoeostasis, e.g. glucose, amylin, insulin, leptin, peptide YY (PYY), glucagon-like peptide 1 (GLP-1) and ghrelin. Orexigenic neuropeptide Y expressing ARC neurons are activated by food deprivation and inhibited by feeding in a nutrient-dependent manner. PYY and leptin also reverse or prevent fasting-induced activation of the ARC. Interestingly, hypothalamic responses to fasting are blunted in different models of obesity (e.g. diet-induced obesity (DIO) or late-onset obesity). The AP also responds to feeding-related signals. The pancreatic hormone amylin acts via the AP to control energy intake. Amylin-sensitive AP neurons are also glucose-responsive. Furthermore, diet-derived protein attenuates amylin responsiveness suggesting a modulation of AP sensitivity by macronutrient supply. This review gives an overview of the receptive function of the ARC and the AP to hormonal and nutritional stimuli involved in the control of energy balance and the possible implications in the context of obesity. Collectively, there is consistency between the neurophysiological actions of these stimuli and their effects on energy homoeostasis under experimental conditions. However, surprisingly little progress has been made in the development of effective pharmacological approaches against obesity. A promising way to improve effectiveness involves combination treatments (e.g. amylin/leptin agonists). Hormonal alterations (e.g. GLP-1 and PYY) are also considered to mediate body weight loss observed in obese patients receiving bariatric surgery. The effects of hormonal and nutritional signals and their interactions might hold the potential to develop poly-mechanistic therapeutic strategies against obesity.

Type
70th Anniversary Conference on ‘Body weight regulation – food, gut and brain signalling’
Copyright
Copyright © The Author 2012

Abbreviations:
AMPK

adenosine monophosphate-activated protein kinase

AP

area postrema

APX

area postrema lesion

ARC

arcuate nucleus

CCK

cholecystokinin

DIO

diet-induced obesity

FAS

fatty acid synthase

GLP-1

glucagon-like peptide-1

GLP-1R

glucagon-like peptide-1 receptor

mTOR

mammalian target of rapamycin

NED

non-energy diet

NPY

neuropeptide Y

NTS

nucleus of the solitary tract

OXM

oxyntomodulin

POMC

pro-opiomelanocortin

PYY

peptide YY

STAT

signal transducer and activator of transcription

Driven by the search for therapeutic treatment strategies against obesity and associated metabolic disorders, considerable knowledge has accumulated about the control mechanisms involved in the maintenance of energy balance. The redundancy of control mechanisms, the capacity of these systems to compensate for pharmacological effects and the existence of obesity-related hormonal insensitivities make it difficult to achieve sufficient therapeutic efficiency for the reduction of body weight over longer periods of time. Evidently, at least under non-laboratory conditions, so-called non-homoeostatic factors (hedonic properties and availability of food, food preferences, social factors, eating habits, etc.) and central reward mechanisms override homoeostatic hormonal and metabolic signals that are considered to reflect and to control the body's energy status.

In contrast to the currently available pharmacological treatment options, bariatric surgery (e.g. Roux-en-Y gastric bypass) is very effective in reducing body weight and improving glucose homoeostasis in patients with type-2 diabetes mellitus( Reference Ferchak and Meneghini 1 , Reference Ahn, Pomp and Rubino 2 ). Apparently, bariatric surgery alters gastrointestinal physiology in a way that changes nutrient-induced gastrointestinal hormone responses, which presumably contribute to these therapeutic effects. Hence, the signalling mechanisms of the gut–brain axis and the interaction between its nutritional and hormonal feedback signals are not only essential for our understanding of the body's energy homoeostasis but also for the ultimate desire to develop pharmacological approaches against the obesity epidemic. Some of the hormones (e.g. glucagon-like peptide 1 (GLP-1) and peptide YY (PYY)) discussed in this review with regard to their central actions are presumed as mediators of weight loss after bariatric surgery. Although the exact mechanisms behind bariatric weight loss surgery and their potential to be targeted pharmacologically remain to be identified, there are other promising therapeutic approaches that are based on hormonal combination treatments. Both pre-clinical studies in obese rodents and clinical trials in human subjects have established a beneficial effect of combined treatment with the anorexigenic pancreatic hormone amylin with the fat-derived hormone leptin. Amylin treatment seems to reverse leptin insensitivity in obese subjects, in which amylin and leptin exert a synergistic action to reduce body weight( Reference Roth, Roland and Cole 3 , Reference Turek, Trevaskis and Levin 4 ).

Brain circuits involved in the control of energy balance also function as fuel sensors responding to diet-derived macronutrients. Nutrients not only alter neuronal activity in feeding regulatory brain areas, they also modulate neuronal responsiveness to hormonal stimuli. Two important brain sites that are targeted by hormonal and nutrient signals involved in the control of energy balance are the hypothalamic arcuate nucleus (ARC) and area postrema (AP) of the brainstem. The current review focuses on the receptive function of the ARC and the AP to feeding-related signals and alterations of neuronal responsiveness that are associated with obesity. It is beyond the scope of this review to describe similar hormone and nutrient-dependent signalling mechanisms in other brain areas that also contribute to the overall control of energy homoeostasis.

The hypothalamic arcuate nucleus

The ARC is considered as one of the most important hypothalamic target structures for blood-borne hormonal and metabolic factors involved in the regulation of food intake and energy homoeostasis. The best-characterised hormone supposed to act via the ARC is the lipostatic and anorectic hormone leptin, a 16 kDa protein that is secreted from white adipose tissue. Genetic deficiency of leptin or its receptor in rodents causes excessive food intake, body weight gain and an obese phenotype( Reference Zhang, Proenca and Maffei 5 , Reference Chua, Chung and Wu-Peng 6 ). Leptin acts via the ARC, which contains two functionally antagonistic populations of neurons with respect to the control of food intake. One population contains the orexigenic neuropeptide Y (NPY) and agouti gene-related peptide( Reference Broberger, Johansen and Johansson 7 ). The other distinct population synthesises the anorectic pro-opiomelanocortin (POMC) gene product α-melanocyte stimulating hormone( Reference Ellacott and Cone 8 ). Leptin up-regulates POMC neurons while it inhibits NPY/agouti gene-related peptide neurons in the ARC( Reference Cowley, Smart and Rubinstein 9 , Reference Spanswick, Smith and Groppi 10 ). Similar to leptin, insulin fulfils the criteria of an adiposity signal because circulating insulin levels increase in relation to body adiposity. Furthermore, insulin has access to the brain and it influences food intake and body weight in a similar way as leptin via the ARC( Reference Woods and Seeley 11 ).

Catalysed by the high importance of the ARC for body weight control and the failure of leptin therapy as an effective anti-obesity treatment because of leptin resistance( Reference Heymsfield, Greenberg and Fujioka 12 ), the scientific interest in other factors acting via the ARC and its downstream signalling pathways began to increase. The well-established concept that the ARC is targeted by the adiposity signals leptin and insulin has been extended by numerous studies demonstrating ARC-dependent actions of hormones, neuropeptides and metabolites that change dynamically according to the status of energy intake. Notably, leptin itself shows dynamic short-term changes as a function of food intake( Reference Boden, Chen and Mozzoli 13 , Reference Weigle, Duell and Connor 14 ).

Ghrelin

One of the hormones targeting the ARC is the orexigenic gastrointestinal hormone ghrelin( Reference Kojima, Hosoda and Date 15 ). Plasma levels of ghrelin are modulated by the nutritional state. During fasting and shortly before meals circulating ghrelin concentrations are elevated, while feeding or nutrient intake reduce blood-ghrelin levels( Reference Tschop, Smiley and Heiman 16 Reference Shiiya, Nakazato and Mizuta 18 ). Various electrophysiological and immunohistological studies characterised ghrelin's effects on neuronal activity of ARC neurons that have been suggested to represent target cells for ghrelin in the brain( Reference Traebert, Riediger and Whitebread 19 Reference Wang, Saint-Pierre and Tache 22 ). Ghrelin binds to the growth hormone secretagogue receptor that is highly abundant in the ARC( Reference Guan, Yu and Palyha 23 ). The growth hormone secretagogue receptor is predominantly expressed in NPY neurons (94% co-localisation), while it is found in only 8% of POMC neurons( Reference Willesen, Kristensen and Romer 24 ). Ghrelin exerts opposite effects to leptin on the activity of ARC neurons. Ghrelin or growth hormone secretagogue receptor agonists excite leptin-inhibited NPY neurons via a direct postsynaptic effect( Reference Traebert, Riediger and Whitebread 19 , Reference Hewson, Viltart and McKenzie 25 Reference Tung, Hewson and Dickson 27 ). In addition to this action, ghrelin indirectly inhibits neurons of the lateral ARC, where POMC neurons are located( Reference Riediger, Traebert and Schmid 20 , Reference Cowley, Smith and Diano 28 ). The excitatory effect of ghrelin on ARC neurons and the NPYergic phenotype of these cells have been confirmed in vivo by immunohistochemical studies using c-Fos as a marker for neuronal activation( Reference Wang, Saint-Pierre and Tache 22 , Reference Dickson and Luckman 29 ).

Whether ghrelin can be considered a physiological signal in the control of energy homoeostasis has not yet been confirmed based on the general criteria that have been suggested to define a physiological relevance( Reference Geary 30 ). Owing to the weak consequences of ghrelin antagonism for feeding behaviour or body weight phenotype and because of the ineffectiveness of physiological ghrelin doses to produce feeding or body weight effects, the physiological relevance of ghrelin has not yet been fully established( Reference Kirchner, Heppner and Tschop 31 ). Based on the leptin counter-regulatory action of ghrelin, antagonism of ghrelin signalling has been proposed as a therapeutic approach against obesity. However, the role of ghrelin in the pathogenesis of obesity is not clear. Ghrelin levels in obese human subjects are lower than under normal weight conditions( Reference Cummings, Weigle and Frayo 32 ) limiting the usefulness and success of ghrelin antagonism as an anti-obesity strategy( Reference Kirchner, Heppner and Tschop 31 ). Interestingly, weight loss in obese subjects seems to be associated with an increase in ghrelin levels suggesting that a blockade of ghrelin action might facilitate the body weight reducing effect of other therapeutic interventions( Reference Cummings, Weigle and Frayo 32 ). Notably, there is cumulating evidence for a role of ghrelin in reward mechanisms that involve extra-hypothalamic pathways originating in the ventral tegmental area( Reference Dickson, Egecioglu and Landgren 33 ). The potential of pharmacological ghrelin-dependent approaches with respect to this mechanism has not yet been sufficiently explored in clinical studies.

Peptide YY/glucagon-like peptide 1

The two gut hormones PYY and GLP-1 act on ARC neurons. They have received special attention in the context of energy homoeostasis and as potential targets for the treatment of overweight. Both hormones might contribute to weight loss after gastric bypass surgery because Roux-en-Y gastric bypass patients have increased GLP-1 and PYY levels and blockade of gastrointestinal hormone release (including GLP-1 and PYY) by the somatostatin analogue octreotide led to increased appetite( Reference Borg, le Roux and Ghatei 34 Reference le Roux, Welbourn and Werling 36 ). A specific role for PYY is suggested by the absence of weight loss in PYY knockout mice subjected to gastrointestinal bypass surgery( Reference Chandarana, Gelegen and Karra 37 ).

PYY and PYY(3–36) are two biologically active peptides arising from endocrine L-cells of the ileum and colon in response to food intake( Reference Grandt, Schimiczek and Beglinger 38 ). Although PYY binds to several subtypes of Y receptors, PYY(3–36) exhibits relative specificity for the Y2 receptor( Reference Dumont, Fournier and St-Pierre 39 ). Both PYY isoforms inhibit food intake after peripheral administration; but PYY(3–36) appears to be more potent possibly due to its specificity to the Y2 receptor that is decisive for the anorexigenic response( Reference Degen, Oesch and Casanova 40 , Reference Sloth, Holst and Flint 41 ). However, the minimal doses that were required to suppress food intake in these studies were supraphysiological when compared with meal-induced changes of total PYY blood levels. Therefore, the question whether PYY(3–36) acts as a physiological satiating signal is controversial. Direct site-specific injections of PYY(3–36) identified the ARC as possible central target structure( Reference Batterham, Cowley and Small 42 ). With respect to the electrophysiological effects of PYY(3–36) in the ARC, conflicting data exist in the literature. In mice, PYY(3–36) has been demonstrated to indirectly (presynaptically) excite phenotypically identified POMC neurons( Reference Batterham, Cowley and Small 42 ), while another electrophysiological study demonstrated direct postsynaptic inhibitions in POMC neurons of mice( Reference Ghamari-Langroudi, Colmers and Cone 43 ). Among others, the reasons for these seemingly contradictory findings have not yet been identified, but might be related to experimental and technical differences concerning the slice preparation and selection of cells( Reference Ghamari-Langroudi, Colmers and Cone 43 ). In rats, full-length PYY exerts direct inhibitory effects on ghrelin-exited ARC neurons (Fig. 1) suggesting that the NPYergic system is also affected by PYY signalling( Reference Riediger, Bothe and Becskei 44 ). This is consistent with the demonstration that PYY(3–36) inhibits NPY release from ARC explants in addition to stimulating a α-melanocyte stimulating hormone response( Reference Batterham, Cowley and Small 42 ).

Fig. 1. Continuous rate meter recording of a spontaneously active neuron from the medial arcuate nucleus of the rat. Consecutive superfusions of ghrelin and the anorectic hormone peptide YY (PYY) at the indicated times caused opposite effects on neuronal activity. While ghrelin induced a strong excitatory response, PYY effectively decreased the discharge rate. Reproduced with permission (published in Riediger et al. ( Reference Riediger, Bothe and Becskei 44 )).

Basal and postprandial PYY(3–36) levels are decreased in obese human subjects and rodents( Reference Batterham, Cohen and Ellis 45 ). The absence of PYY(3–36) resistance in obese subjects is in favour of using PYY agonists as anti-obesity drugs. Chronic peripheral administration of PYY(3–36) decreases body weight in different species including rhesus macaques( Reference Batterham, Cowley and Small 42 , Reference Adams, Lei and Jodka 46 , Reference Koegler, Enriori and Billes 47 ). Whether PYY agonists can be therapeutically used in human subjects to reduce body weight awaits further evaluation. Interestingly, PYY seems to synergise with other hormones or hormone agonists affecting the control of energy balance and glucose homoeostasis, including the GLP-1 agonist exendin-4 and the pancreatic hormone amylin( Reference Talsania, Anini and Siu 48 , Reference Roth, Coffey and Jodka 49 ). The neuronal correlates of these synergies are unknown.

Similar to PYY, GLP-1 is released in response to food intake from gastrointestinal L-cells( Reference Orskov, Wettergren and Holst 50 , Reference Kreymann, Williams and Ghatei 51 ). GLP-1 plays an important role in glucose homoeostasis (incretin) and gastrointestinal function( Reference Holst 52 ). In addition to its peripheral expression, GLP-1 is a neuropeptide expressed in a discrete population of enteroceptive neurons located in the brainstem( Reference Larsen, Tang-Christensen and Holst 53 ). It binds to the GLP-1 receptor (GLP-1R) that is also activated by the agonist exendin-4, a peptide that has been isolated from the saliva of the lizard Heloderma suspectum. The truncated form of exendin (9–39) (also termed exendin-9) acts as a competitive antagonist at the GLP-1R. The ARC, and other hypothalamic and brainstem structures, including the paraventricular nucleus and the AP, show high GLP-1R expression( Reference Merchenthaler, Lane and Shughrue 54 , Reference Alvarez, Roncero and Chowen 55 ). Central and peripheral injection GLP-1R agonists decrease food intake in rodents( Reference Turton, O'Shea and Gunn 56 Reference Reidelberger, Haver and Apenteng 59 ). Furthermore, numerous studies have demonstrated a GLP-1-mediated reduction in energy intake in human subjects( Reference Verdich, Flint and Gutzwiller 60 ). Similar to ghrelin and PYY, it has not yet been confirmed that endogenous GLP-1 physiologically controls food intake.

The neuronal mechanisms mediating the action of GLP-1 on food intake have not yet been clearly identified, which might be due to the fact that different pathways seem to be activated depending on the experimental conditions, particularly the route of administration and the potency of the stimulus. While subdiaphragmatic deafferentation blocked the anorexigenic effect of hepatic portal vein GLP-1 infusion, subdiaphragmatic deafferentation did not blunt the feeding suppressive effect of GLP-1 infused into the vena cava( Reference Ruttimann, Arnold and Hillebrand 61 ). In contrast, the effect of the long-acting GLP-1 agonist exendin-4 was not blocked in rats with subdiaphragmatic deafferentation( Reference Punjabi, Arnold and Geary 62 ). There is some evidence that the ARC represents a target site not only for GLP-1 but also for the structurally related hormone oxyntomodulin (OXM), which is co-secreted with GLP-1 and exerts an anorexigenic effect via the GLP-1R after central injection( Reference Le Quellec, Kervran and Blache 63 , Reference Baggio, Huang and Brown 64 ). GLP-1R activation by intra-arcuate injection of OXM decreased food intake and the OXM-mediated suppression of intraperitoneal OXM administration was blocked by injection of the GLP-1R antagonist exendin(9–39)( Reference Dakin, Small and Batterham 58 ). Another study did not observe a feeding suppressive effect after intra-arcuate GLP-1 injection, but hepatic glucose production was reduced under these conditions( Reference Sandoval, Bagnol and Woods 65 ). However, GLP-1 consistently reduced feeding after site-specific injection into the paraventricular nucleus( Reference Sandoval, Bagnol and Woods 65 , Reference Dakin, Gunn and Small 66 ).

The effects of GLP-1 and OXM on neuronal activity in the ARC are similar. In rats, both hormones induced excitatory responses in ghrelin-inhibited cells( Reference Riediger, Eisele and Scheel 67 ) (see example in Fig. 2) suggesting a stimulation of POMC signalling, which is consistent with the high expression of the GLP-1R in POMC neurons( Reference Sandoval, Bagnol and Woods 65 ). GLP-1 and OXM induced heterogeneous excitatory and inhibitory effects in ghrelin-excited ARC neurons, but the functional and neurochemical phenotype of these cells have not yet been identified. The absence of GLP-1R expression in NPY neurons seems to exclude the NPY system as a primary target for GLP-1 in the ARC. Despite the existing in vivo and in vitro evidence for a potential role of ARC-dependent GLP-1 signalling in energy and glucose homoeostasis further support for a physiological role of endogenous GLP-1R ligands acting via hypothalamic circuits needs to be established. Although beneficial effects on body weight have been reported for anti-diabetic GLP-1 agonists( Reference Klonoff, Buse and Nielsen 68 Reference Vilsboll, Christensen and Junker 70 ), moderate effectiveness and undesired side effects limit the potential of these drugs at least as a mono-therapy against obesity.

Fig. 2. Representative recording showing the excitatory effect of glucagon-like peptide-1 (GLP-1) on a ghrelin-inhibited neuron of the arcuate nucleus. Reproduced with permission (published in Riediger et al.( Reference Riediger, Eisele and Scheel 67 ).

Feeding and nutrient-related effects on neuronal function

Numerous studies have confirmed the reciprocal regulation of NPY and POMC gene expression in response to alterations in energy intake( Reference Schwartz, Woods and Porte 71 ). Fasting not only leads to alterations in neuropeptide expression but also to alterations in neuronal activity. Food deprivation for 24 h elicits an activation of ARC neurons in mice as reflected by an increase in c-Fos expression( Reference Wang, Martinez and Barrachina 72 Reference Mistry, Helferich and Romsos 74 ). Refeeding of 12 h food-deprived mice completely reverses the fasting-induced ARC activation (Fig. 3) indicating that feeding-related signals exert a strong inhibitory effect on ARC neurons that are activated under negative energy balance( Reference Riediger, Bothe and Becskei 44 , Reference Becskei, Lutz and Riediger 75 ). Hence, ARC neurons appear to respond to negative and positive changes in energy intake. As demonstrated by phenotyping studies, fasting-induced ARC activation specifically occurs in NPY neurons, but not in POMC neurons under these conditions( Reference Becskei, Lutz and Riediger 75 , Reference Coppola, Liu and Andrews 76 ). While this observation suggests increased hypothalamic NPY signalling as a result of fasting, it does not exclude a parallel inhibition of POMC neurons in the ARC. The induction of a fasting-induced ARC activation has also been demonstrated in rats, although considerably longer periods of food deprivation (3 d) are typically required for an immunohistochemically detectable response in this species, at least when c-Fos is used as a marker. Interestingly, there seems to be a shift of neuronal activation from the NPY system in the fasted state to the melanocortin system following refeeding( Reference Sanchez, Singru and Acharya 77 , Reference Singru, Sanchez and Fekete 78 ). This response is consistent with the function of the NPY system to promote energy intake under negative energy balance and with the counter-regulatory function of the POMC system to limit energy intake.

Fig. 3. Refeeding with chow completely reversed the fasting-induced c-Fos expression in the arcuate nucleus (ARC). Representative ARC sections immunostained for c-Fos of 14-h fasted (A), chow-refed (B) and ad libitum chow-fed (C) mice. Bar charts show the quantitative results of c-Fos expression (D). a,b Different letters indicate significant differences between groups (P < 0·05). 3 V: 3rd ventricle. Scale bar: 100 μm. Reproduced with permission (published in Becskei et al.) ( Reference Becskei, Lutz and Riediger 75 ).

Feeding of palatable non-energy diet (NED; vanilla-flavoured cellulose) with or without selective nutrient supplementation has proven to be a useful approach to explore the role of diet-derived nutrients in feeding-related modulation of neuronal ARC activity. Mice receiving NED for 12 h instead of standard chow exhibit a strong c-Fos expression in the ARC that is only slightly lower than in 12 h fasted animals( Reference Becskei, Lutz and Riediger 75 ). The same is true for fasted mice that were refed with NED. Therefore, nutrient-independent stimuli associated with feeding activity (e.g. gustatory, oropharyngeal cues and gastric distension) appear to exert a minor, but significant influence on the ARC because they only weakly counteract the stimulation of ARC activation triggered by short-term energy deprivation. When refeeding with NED that was selectively supplemented with each of the different macronutrients (carbohydrates, protein or fat), a stronger reversal of fasting-induced ARC activation was observed than that following refeeding with non-supplemented NED( Reference Becskei, Lutz and Riediger 75 ). When the intake of each nutrient was matched to specific nutrient intake of chow-fed animals, the carbohydrates were more effective than protein and fat. However, increasing the protein content in the diet or refeeding with pure fat (lard) resulted in a similar reversal of fasting-induced c-Fos expression as observed for refeeding with carbohydrate. Therefore, the relative contribution of each macronutrient to the inhibition of ARC activity in this experimental setting appeared to depend on the amount of intake. Whether isoenergetic intakes of the different macronutrients are equipotent to reverse fasting-induced ARC activation has not yet been investigated.

The mechanism underlying the fasting and feeding-related effects on neuronal activity in the ARC are likely to involve not only direct effects of metabolites but also indirect actions mediated by gastrointestinal hormones. ARC neurons have been shown to respond to glucose in excitatory and inhibitory ways( Reference Wang, Liu and Hentges 79 ). Phenotypically identified NPY neurons of mice and rats decrease their firing rate with increasing glucose concentrations (glucose-inhibited cells)( Reference Fioramonti, Contie and Song 80 , Reference Muroya, Yada and Shioda 81 ). Conversely, POMC neurons have been demonstrated to be glucose-excited because they decrease their discharge rate when the extracellular glucose concentration is decreased( Reference Claret, Smith and Batterham 82 , Reference Parton, Ye and Coppari 83 ). The intracellular mechanisms transducing changes in the glucose concentration into altered neuronal activity are well understood for glucose-excited neurons, while the molecular correlates of inhibitory glucose signalling are less clear. Glucose sensitivity in glucose-excited neurons has obvious parallels to glucose responsiveness of pancreatic β-cells, in which glucose metabolism leads to increased ATP:ADP ratios. As a consequence ATP induces a closure of the Kir6.2 pore-forming subunit of the ATP-sensitive K+ channel, leading to a depolarisation of the cell. Genetic manipulations that cause a loss of function of Kir6.2 subunit are associated with a loss of glucose responsiveness in hypothalamic neurons, including POMC neurons of the ARC( Reference Parton, Ye and Coppari 83 , Reference Miki, Liss and Minami 84 ). Although the ATP-sensitive K+ channel is required for the glucose sensitivity of glucose-excited neurons, it is also expressed in glucose-insensitive cells suggesting that other molecular transducers are decisive for neuronal glucose responsiveness. One of these transducers is the enzyme glucokinase, the rate-limiting enzyme for glucose metabolism in glucose sensitive neurons( Reference Levin, Routh and Kang 85 ). Another enzyme that seems to function as a master switch for intracellular metabolic pathways including glucose metabolism is the enzyme adenosine monophosphate-activated protein kinase (AMPK). AMPK responds to changes in the ADP:ATP ratio and induces counter-regulatory metabolic responses through a variety of downstream targets( Reference Kahn, Alquier and Carling 86 ). Hypothalamic AMPK activity in the ARC and other hypothalamic structures is inhibited not only by leptin and insulin but also by refeeding in fasted mice and by intraperitoneal and intracerebroventricular glucose administration( Reference Minokoshi, Alquier and Furukawa 87 ). Genetic manipulation that results in constitutive hypothalamic AMPK activity was associated with increased body weight, while reduced AMPK activity resulted in reduced body weight. These effects were partly attributed to changes in food intake( Reference Minokoshi, Alquier and Furukawa 87 ). Genetic disruption of AMPK in POMC and NPY neurons was paralleled by a loss of glucose responsiveness of these cells in the ARC supporting of a role of AMPK in glucose sensing( Reference Claret, Smith and Batterham 82 ). In line with the well-established glucose sensitivity of ARC neurons, an increase in circulating glucose after intraperitoneal glucose administration reversed the fasting-induced ARC activation to a similar degree as refeeding( Reference Becskei, Lutz and Riediger 88 ). These studies do not exclude indirect hormonal or vagal afferent signalling mechanisms that might be engaged in parallel to a direct action of glucose on ARC neurons.

Not only glucose but also hypothalamic fatty acid signalling contributes to the control of energy balance and glucose homoeostasis because intracerebroventricular infusion of oleic acid inhibits food intake and hepatic glucose production( Reference Morgan, Obici and Rossetti 89 , Reference Obici, Feng and Morgan 90 ). Besides other hypothalamic structures, the ARC has been identified as a fatty acid responsive area( Reference Wang, Cruciani-Guglielmacci and Migrenne 91 ). Lipid sensitivity has been demonstrated for POMC neurons that were inhibited by oleic acid( Reference Jo, Su and Gutierrez-Juarez 92 ). In analogy to the importance of intracellular glucose metabolism, intracellular lipid metabolism has been linked to altered neuronal function and to changes in food intake and body weight. Pharmacological blockade fatty acid synthase (FAS) pathway by central or peripheral injection of the FAS inhibitor C75 inhibited feeding and reduced body weight in mice( Reference Loftus, Jaworsky and Frehywot 93 ). Among other hypothalamic sites, FAS is expressed in NPY neurons of the ARC( Reference Kim, Miller and Landree 94 ). Peripherally applied C75 prevented the fasting induced c-Fos expression in the medial ARC and in hypothalamic downstream targets of the ARC supporting a role of lipid signalling in fasting-induced ARC activation( Reference Miller, Ronnett and Moran 95 ). Different intracellular mechanisms have been proposed to mediate the effects of FAS inhibition on energy homoeostasis. These mechanisms include an increase in the FAS substrate malonyl CoA, which represents an intracellular metabolic signal inhibiting food intake and body weight. This view is consistent with the development of obesity and increased food intake when malonyl CoA degradation in the mediobasal hypothalamus is enhanced by overexpression of the enzyme malonyl CoA decarboxylase( Reference He, Lam and Obici 96 ). A regulatory function for cellular lipid sensing has also been postulated for the enzyme carnitine palmitoyltransferase-1 that controls long-chain fatty acid transport into the mitochondria. Pharmacological or genetic inhibition of hypothamalic carnitine palmitoyltransferase-1 reduced food intake and glucose production( Reference Obici, Feng and Arduini 97 ). Despite the cumulating evidence for a role of hypothalamic lipid sensing further confirmation is required for the physiological relevance of these processes in the context of feeding-related or metabolically induced changes in circulating mediators involved in lipid signalling.

Similar to lipid signalling a role of hypothalamic amino acid signalling in the control of food intake and body weight has emerged. The serine-threonine kinase mammalian target of rapamycin (mTOR) functions as nutrient sensor implicated in cell growth and proliferation( Reference Jacinto and Hall 98 ). Particularly branched amino acids such as leucine activate the mTOR pathway. Components of the mTOR pathway have been detected in 90 and 45% of ARC NPY and POMC neurons, respectively( Reference Cota, Proulx and Smith 99 ). In analogy to the changes of neuronal activity in the ARC as a result of fasting and refeeding, activity of the mTOR pathway in the ARC is down-regulated in the fasted state, while it increases in response to refeeding. Both intracerebroventricular and site-specific injection of leucine into the mediobasal hypothalamus inhibited food intake( Reference Cota, Proulx and Smith 99 , Reference Blouet, Jo and Li 100 ). POMC neurons of the ARC increase their electrical activity in response to stimulation with leucine, which is consistent with in vivo studies demonstrating a melanocortin receptor involvement in the anorexigenic effect of mediobasal hypothalamic leucin injection( Reference Blouet, Jo and Li 100 ).

Fasting and the ingestion of each of the single macronutrients lead to hormonal responses adjusting energy homoeostasis and gastrointestinal function to the metabolic and digestive requirements of the body. Some attempts have been made to explore the involvement of hormones in the feeding-related changes in ARC activity. Based on the increase in ghrelin levels under fasting conditions, ghrelin might contribute to the fasting-induced ARC activation in mice. In rats, neutralisation of ghrelin by a site-specific injection of anti-ghrelin Ig into the ARC attenuated food intake in fasted animals during refeeding( Reference Bagnasco, Tulipano and Melis 101 ). An alternative approach to neutralise ghrelin is the use of an L-RNA-based hormone antagonist, a so-called Spiegelmer, that specifically binds and inactivates the bioactive form of ghrelin( Reference Helmling, Maasch and Eulberg 102 , Reference Kobelt, Helmling and Stengel 103 ). Owing to its long-lasting action a single intravenous infusion of the anti-ghrelin Spiegelmer NOX-B11-3 blocked the c-Fos response in the ARC of ad libitum fed mice induced by exogenous ghrelin injected peripherally 12 h after administration of the antagonist( Reference Becskei, Bilik and Klussmann 21 ). In the same study, ghrelin antagonism did not significantly attenuate the fasting-induced c-Fos response in the ARC suggesting that endogenous ghrelin is not necessary for the activation of the ARC under these experimental conditions.

Among the feeding-related hormones that are likely to act via the ARC, ghrelin is the only hormone that increases during fasting. Not only increases but also decreases in hormone levels are likely to reflect alterations in energy homoeostasis and metabolism. One experimental approach to investigate this consists in the compensation of decreased hormone levels by exogenous administration of the respective hormone. Superimposed to the well-described differences in leptin levels related to body adiposity, leptin plasma levels decrease considerably (5-fold) in fasted v. ad libitum fed lean mice( Reference Becskei, Lutz and Riediger 75 ). Preventing the fasting-induced decrease in leptin by repeated low-dose leptin injections during the fasting period markedly attenuated the c-Fos expression of in the ARC of food-deprived mice (Fig. 4)( Reference Becskei, Lutz and Riediger 104 ). Despite the limitation of this approach to precisely mimic physiological leptin levels by exogenous leptin administration, this finding supports the contribution of decreased leptin signalling to fasting-induced ARC activation. Studies in leptin deficient ob/ob mice seem to complement these findings because fasting-induced ARC activation is exaggerated in ob/ob mice compared with wild-type littermates( Reference Becskei, Lutz and Riediger 104 ). Together these studies underscore that leptin signalling has an important impact on the ARC in the context of feeding-related modulation of ARC neurons.

Fig. 4. Effect of exogenous leptin-induced hyperleptinaemia during fasting on arcuate nucleus (ARC) activation in lean mice. Representative ARC sections immunostained for c-Fos of young lean mice treated with saline or leptin every 3 h during a 14-h food-deprivation period. Leptin treatment significantly increased the leptin plasma concentration and attenuated the fasting-induced c-Fos expression in the ARC (**P < 0·01 for both effects). 3 V: 3rd ventricle. Scale bar: 100 μm. Reproduced with permission (published in Becskei et al.)( Reference Becskei, Lutz and Riediger 104 ).

Using the fasting/refeeding paradigm the possible involvement of other hormones in feeding-related changes of ARC activity has been studied. Similar to the ineffectiveness of an acute leptin treatment to reverse fasting-induced ARC activation, insulin did not attenuate c-Fos expression in fasted animals regardless of whether a glucose-lowering dose of insulin was used or a dose that did not produce a reduction in blood glucose( Reference Becskei, Lutz and Riediger 75 ). Besides insulin the anorexigenic hormones PYY, amylin and cholecystokinin (CCK) were tested for their ability to reverse fasting-induced c-Fos expression in the ARC. Only PPY, but not amylin or CCK attenuated the stimulation of ARC neurons in food-deprived mice( Reference Becskei, Lutz and Riediger 75 , Reference Riediger, Michel and Becskei 105 ). The lack of effectiveness was probably not due to ineffective doses, because in the same animals both amylin and CCK elicited c-Fos expression in the AP and the nucleus of the solitary tract (NTS), respectively. As amylin and CCK primarily act via the brainstem (see later) and because the ARC is considered as a target site for PYY, these findings are consistent with the presumed central signalling mechanisms for these hormones. Despite the failure of CCK and amylin to reverse fasting-induced ARC activation, at least CCK partially prevented ghrelin-induced c-Fos expression in the ARC in ad libitum fed mice( Reference Becskei, Lutz and Riediger 75 ) indicating some CCK-dependent inhibitory input to the ARC. Collectively, these findings suggest diverse roles for the investigated hormones in feeding-related changes of neuronal function in the ARC. However, the use of knockout models or specific hormone antagonists is required to confirm the relevance of endogenous hormone actions.

Altered neuronal arcuate nucleus responses in obese rodent models

Obesity is associated with hormonal and metabolic perturbations, including hyperleptinaemia, hyperinsulinaemia, leptin and insulin resistance, dyslipidaemia and hyperglycaemia and others( Reference Heymsfield, Greenberg and Fujioka 12 , Reference Halaas, Boozer and Blair-West 106 , Reference Bjorntorp 107 ). In rodent models of diet-induced obesity (DIO) neuronal to responsiveness of ARC neurons to leptin is disrupted. DIO mice show a reduced phosphorylation of the signal transducer and activator of transcription 3 (STAT3), a marker for leptin receptor activation( Reference Munzberg, Flier and Bjorbaek 108 , Reference Gamber, Huo and Ha 109 ). Furthermore, the leptin-dependent release of NPY and α-melanocyte stimulating hormone( Reference Enriori, Evans and Sinnayah 110 ) is decreased. As recently demonstrated, obesity also seems to be associated with ghrelin resistance in the ARC because peripheral or central ghrelin injection did not induce food intake and ARC activation in DIO mice( Reference Briggs, Enriori and Lemus 111 ). Moreover, ghrelin failed to induce the release of NPY and agouti gene-related peptide in hypothalamic explants from DIO mice in this study. Not only hormonal resistance but also impaired responsiveness of the ARC to metabolic stimuli has been described( Reference Levin, Govek and Dunn-Meynell 112 ).

It has been demonstrated in different obesity models that obese mice show blunted neuronal responses of the ARC to alterations in energy intake. Age-related obese (late-onset obesity) and DIO mice show completely absent or a strongly attenuated fasting-induced activation of NPY neurons in the ARC depending on the duration of food deprivation (12 h or 24 h, respectively). The blunted responses in these animals were not due to age per se or due to high-fat diet feeding because age-matched controls and diet-resistant lean controls showed intense fasting-induced c-Fos responses in the ARC( Reference Becskei, Lutz and Riediger 104 , Reference Becskei, Lutz and Riediger 113 ). The absence of fasting-induced ARC activation was associated with the absence of refeeding hyperphagia that only occurred in lean mice after fasting but not in late-onset obesity mice. The blunted ARC activation in these hyperleptinaemic obesity models contrasts with the exaggerated fasting response in the ARC of obese leptin-deficient ob/ob mice( Reference Becskei, Lutz and Riediger 113 ). Measurements of metabolic (blood glucose and lipids) and hormonal parameters (insulin, ghrelin and leptin) were conducted in fasted and ad libitum fed obese mice and in respective lean controls( Reference Becskei, Lutz and Riediger 104 , Reference Becskei, Lutz and Riediger 113 ). Among these parameters, the only factor that consistently predicted the altered neuronal responses across the different obesity models was leptin because neuronal ARC activation is enhanced under leptin deficiency, prevented by exogenous leptin and blunted under hyperleptinaemia. However, the idea that obesity-related hyperleptinaemia prevents the response of the ARC to fasting is challenged by well-described leptin resistance in hyperleptinaemic obesity. Factors that limit central effectiveness of circulating leptin involve reduced transport across the blood–brain barrier, increased intracellular inhibition of leptin-signalling and reduced leptin receptor expression. Each of these factors are affected by feeding in a way that promotes leptin responsiveness under fasting conditions. Fasting increases the rate of leptin transport into the brain( Reference Banks and Farrell 114 , Reference Banks, Coon and Robinson 115 ), reduces intracellular leptin-antagonistic signalling( Reference Baskin, Breininger and Schwartz 116 , Reference Morrison, White and Wang 117 ) and increases leptin receptor expression( Reference Baskin, Seeley and Kuijper 118 ) and leptin binding to the receptor( Reference Baskin, Breininger and Bonigut 119 ). Hence, leptin responsiveness is dynamic and linked to the feeding status. In line with this assumption, fasting not only increases the leptin-induced STAT3 phosphorylation in lean mice but also in late-onset obesity mice that did not show a significant STAT3 response in the ad libitum fed state( Reference Becskei, Lutz and Riediger 104 ). Consequently, the combination of increased leptin levels and increased leptin responsiveness might prevent the activation of ARC neurons under negative energy balance. Together, these findings suggest that dynamic changes in leptin sensitivity under hyperleptinaemia might interfere with the receptive function of the ARC for stimuli reflecting short-term excursions in energy intake.

The area postrema

The AP is a sensory circumventricular organ located in the dorsal vagal complex of the brainstem. Owing to the lack of a functional blood–brain barrier AP neurons can be reached by humoral factors including peptide hormones that do not passively cross the blood–brain barrier in other areas of the brain. The AP is neuronally interconnected with structures of the visceral enteroceptive neuroaxis including the NTS and the lateral parabrachial nucleus ( Reference van der Kooy and Koda 120 ). Among other neuronal efferents the AP also projects to the dorsal motor nucleus of the vagus that controls visceral motor functions. The AP plays an important protective role as a so-called chemoreceptor trigger zone that mediates aversive and emetic responses induced by noxious or toxic stimuli. This function is for example reflected by the absence of lithium chloride induced taste aversion after ablation of the AP-lesioned (APX) in rats( Reference Ritter, McGlone and Kelley 121 ).

Observations from APX studies suggested an AP involvement in the control of food intake and body weight. APX rats are hypophagic and show lower body weight compared with sham-lesions animals, although they over-consume highly palatable food( Reference Hyde and Miselis 122 , Reference Miselis, Hyde and Shapiro 123 ). Furthermore, APX leads to loss of hypoglycaemic or glucoprivic feeding responses induced by insulin, 2-deoxy-glucose or 5-thio-glucose( Reference Hyde and Miselis 122 , Reference Bird, Cardone and Contreras 124 ), suggesting a role of the AP in central nervous glucose sensing.

Area postrema-mediated effects of amylin on food intake

The AP has been identified as a target structure for the anorexigenic hormone amylin, which is widely accepted to contribute to the physiological control of food intake. Amylin is co-secreted with insulin from pancreatic β-cells in response to meal-related stimuli( Reference Young 125 ). Amylin reduces food intake at near physiological doses via a reduction of meal size( Reference Lutz, Del Prete and Scharrer 126 Reference Arnelo, Reidelberger and Adrian 128 ). Amylin antagonism not only blocks the anorexigenic effect of exogenous amylin but also increases food intake, supporting a physiological role of endogenous amylin in energy intake( Reference Reidelberger, Haver and Arnelo 129 ). Numerous studies provided evidence that the AP mediates amylin's suppressive effect on food intake. While vagal afferents are not required for amylin's anorexigenic action( Reference Lutz, Del Prete and Scharrer 130 ), APX blocks feeding inhibitory action of amylin( Reference Lutz, Mollet and Rushing 131 Reference Mack, Soares and Wilson 133 ).

The effects of amylin on neuronal function in the AP and the transmission of amylin signalling to other brain structures involved in the control of energy homoeostasis are well established. The amylin receptor consists of a functional complex of the calcitonin receptor and so-called receptor activity modifying proteins (receptor activity modifying protein 1 and receptor activity modifying protein 3)( Reference Christopoulos, Perry and Morfis 134 ). The calcitonin receptor is densely expressed in the AP( Reference Becskei, Riediger and Zund 135 ), where receptor activity modifying protein 3 gene expression has also been described( Reference Barth, Riediger and Lutz 136 ). In electrophysiological studies, amylin exerted strong excitatory effects in 44% of the recorded spontaneously active AP neurons( Reference Riediger, Schmid and Lutz 137 ). These effects were blocked by the amylin receptor antagonist AC187 and appeared to be mediated by the intracellular second messenger cyclic GMP. The excitatory action of amylin on AP neurons is in line with studies demonstrating an amylin-induced c-Fos expression in the AP( Reference Riediger, Schmid and Lutz 137 , Reference Rowland, Crews and Gentry 138 ). Not only exogenous but also feeding-related endogenous amylin activates AP neurons because refeeding of fasted rats triggered a c-Fos response in the AP that was attenuated by amylin antagonism( Reference Riediger, Zuend and Becskei 139 ). About 50% of neurons showing amylin-induced c-Fos are noradrenergic and specific neurotoxic lesion of these cells blunted amylin's feeding inhibitory action( Reference Potes, Turek and Cole 140 ).

Interaction of amylin and nutrient signalling

Glucose

In support of the afore-mentioned evidence for a role of the AP as central glucose sensor, electrophysiological studies identified glucose-responsive neurons in the AP( Reference Funahashi and Adachi 141 ). These studies were extended by the demonstration that amylin-sensitive neurons in the AP are specifically excited by glucose (Fig. 5), whereas amylin-insensitive neurons are unresponsive to changes in the ambient glucose concentration( Reference Riediger, Schmid and Lutz 142 ). Based on the importance of amylin-sensitive AP neurons for the physiological control of feeding behaviour, these findings further support a role of the AP in the metabolic control of food intake. The AP is not the only glucose sensitive structure in the brainstem, but it is located in a brainstem area where local injection of 5-thio-glucose induced the strongest glucoprivic feeding responses( Reference Ritter, Dinh and Zhang 143 ).

Fig. 5. Co-sensitivity of an area postrema (AP) neuron to glucose and amylin. Decreasing the glucose concentration in the superfusion solution from the standard concentration of 10 mM to 2, 4 and 6 mM during the indicated time caused concentration-dependent decreases of the spontaneous discharge rate. Superfusion of amylin elicited a strong excitatory effect. Reproduced with permission (published in Riediger et al.( Reference Riediger, Schmid and Lutz 142 )).

The glucose sensitivity of the AP has also been postulated as a protective mechanism against excursions in blood glucose values. Hypoglycaemia induces a counter-regulatory increase in the rate of gastric emptying( Reference Schvarcz, Palmer and Aman 144 ) that compensates the decreased blood glucose via increased gastrointestinal nutrient absorption. This mechanism interferes with hormonal and pharmacological effects that delay gastric emptying because glucose appears to be a permissive factor. Amylin potently inhibits gastric emptying via an AP-dependent action, which is overridden by hypoglycaemia( Reference Gedulin and Young 145 ). Our group recently demonstrated a similar permissive effect of glucose for amylin's feeding suppressive effect because amylin failed to significantly inhibit feeding under hypoglycemic conditions (C Neuner-Boyle, unpublished results). The inhibitory effect of the amylin agonist pramlintide on gastric emptying is an important therapeutic mechanism to lower postprandial glucose levels in diabetic patients. As treatment-induced hypoglycaemia is a severe risk in diabetic patients, the permissive effect of glucose on gastric emptying is considered as a fail-safe mechanism that overrides the anti-diabetic action of amylin agonism under hypoglycaemic conditions (see( Reference Young 146 , Reference Young 147 ) for review).

Protein

Amylin's satiating and effect and amylin-induced AP activation are modulated by diet-derived macronutrients, in particular by protein. An influence of diet-derived nutrients on amylin signalling was inferred from the observation that amylin-induced activation of the AP is stronger in fasted v. ad libitum fed rats and also in rats that received nutrient-deficient NED( Reference Michel, Becskei and Erguven 148 ). Selective supplementation of NED with protein but not with glucose or fat strongly attenuated the amylin-induced AP activation suggesting that protein counteracts anorexigenic amylin signalling. In light of the well-established satiating action of protein this assumption appeared unexpected, but it was confirmed by feeding studies in which amylin failed to inhibit protein supplemented NED (Fig. 6)( Reference Michel, Becskei and Erguven 148 ). The inhibitory effect of diet-derived protein on amylin action has been corroborated by immunohistological and feeding studies using isoenergetic diets of different protein content. Amylin more potently decreased intake of 1 and 8% protein chow than standard chow containing 18% protein. Similarly, amylin-induced c-Fos expression was higher in rats receiving less protein( Reference Züger, Forster and Lutz 149 ). These effects were not secondary to altered energy intake that was similar across the experimental groups. While blood glucose levels were also similar, blood amino acid levels decreased in rats fed low-protein diet suggesting that circulating amino acids might contribute the protein-dependent attenuation of amylin-induced AP activation. Pre-treatment of rats with an intraperitoneal administration of a mixed amino acid solution also attenuated amylin's c-Fos response in the AP, which supports this hypothesis( Reference Züger, Forster and Lutz 149 ). However, the exact neuronal mechanism underlying the protein-dependent modulation of amylin signalling remains to be identified. The relationship between reduced amylin-responsiveness and protein intake might bear both physiological and therapeutic implications. Amylin's function in the control of nutrient and energy intake might be adapted to the nutrient composition of the diet. At least under undisturbed energy homoeostasis protein is metabolically less important than carbohydrate or fat, which might suggest that amylin's contribution to the overall control of energy intake is stronger when the intake of protein relative to glucose or fat is low. Another mutually not exclusive implication might consist of an AP-sensitising effect produced by short-term reduction of food intake or food availability in a protein-dependent manner, pre-adapting AP responsiveness to a higher level in the pre-prandial state before meal onset. In addition to the possible physiological relevance, the effectiveness of pharmacological approaches based on amylin agonism might be influenced in a nutrient-dependent way.

Fig. 6. Effect of amylin (5 μg/kg s.c.) on food intake in rats kept on different test diets (NED, non-energy diet, vanilla-flavoured cellulose) for 24 h prior to injection. Bars represent group means and sem (n12). *P < 0·05 and ***P < 0·001, significantly different from respective control (saline) group (paired Student t test). Modified and reproduced with permission (published in Michel et al.( Reference Michel, Becskei and Erguven 148 )).

Fat

There is not much experimental evidence for a role of the AP in lipid sensing. Although lipoprivic feeding induced by the fatty acid oxidation inhibitor mercaptoacetate is blunted in rats after AP/NTS lesion, this effect has been attributed to the destruction of vagal terminal fields in the NTS( Reference Ritter and Taylor 150 ). Accordingly, lipoprivic feeding is also blocked in vagotomised rats, confirming a mediation of vagal afferent signals( Reference Ritter and Taylor 150 ). Similarly, c-Fos expression in the AP/NTS region after intraduodenal lipid infusion is attenuated by capsaicin-induced destruction of vagal afferents and by CCK receptor antagonism. The latter finding indicates an indirect effect of intestinal lipid sensing via CCK-mediated activation the vagal afferents signalling( Reference Monnikes, Lauer and Bauer 151 ). It is reasonable to assume that amylin signalling and vagally transmitted lipid/CCK dependent signals converge at the level of the AP/NTS region. Furthermore, the existence of a satiogenic synergy between amylin and CCK( Reference Bhavsar, Watkins and Young 152 ) might imply that lipid-dependent signals indirectly enhance amylin's feeding suppressive effect via a CCK-dependent action. Unlike the development of hormonal resistance to leptin and insulin as a consequence of prolonged high-fat diet feeding, neither short-term nor long-term high-fat diet feeding leads to amylin resistance at least when amylin's inhibitory action on food intake is used as an index of amylin responsiveness( Reference Boyle, Rossier and Lutz 153 ).

Hormonal interactions involving area postrema and brainstem mechanisms

The dorsal vagal complex is a site of convergence for vagal and blood-borne signals controlling food intake. Brainstem structures including amylin-sensitive sites are reciprocally interconnected with hypothalamic and extra-hypothalamic areas involved in energy homoeostasis( Reference Potes, Lutz and Riediger 154 ). For some hormones known to act via the brainstem synergistic effects have been described, although the existence of a synergy is not always based on equal criteria in the literature. Synergy is often inferred from the observation that the effect of two combined stimuli is higher than the sum of the effects when each stimulus is applied alone. Sophisticated statistical models (e.g. isobolographic analysis) have been used to detect and describe synergistic actions. Several synergistic effects have been demonstrated for amylin in combination with other hormones( Reference Roth, Trevaskis and Turek 155 ). In addition to the synergy between amylin and CCK mentioned earlier, there is a synergistic effect of amylin and leptin to reduce body weight in obese and lean subjects( Reference Roth, Roland and Cole 3 , Reference Turek, Trevaskis and Levin 4 ). Several neuronal mechanisms have been associated with the synergy between amylin and leptin. Amylin seems to enhance neuronal leptin responsiveness as reflected by the reversal of the blunted STAT3 response to leptin in the ventromedial hypothalamus. Amylin also affects leptin signalling in the brainstem because amylin knockout mice tend to show reduced leptin-induced STAT3 phosphorylation in the NTS, and pre-treating leptin-resistant DIO rats with amylin increased leptin-dependent STAT3 signalling in the AP( Reference Roth, Roland and Cole 3 , Reference Turek, Trevaskis and Levin 4 ).

Anorexigenic synergy has also been reported for amylin and PYY(3–36), whereas body weight reduction was additive( Reference Roth, Coffey and Jodka 49 ). The neuronal correlate of this anorexigenic synergy has not yet been identified. While the AP was not required for PYY(3–36)-induced suppression of feeding in one study( Reference Baraboi, Michel and Smith 156 , Reference Cox and Randich 157 ), another study suggested an involvement of the AP in the PYY-dependent effects on gastric acid secretion( Reference Deng, Guarita and Pedroso 158 ). Binding sites for PYY of the Y receptor family are abundant in the AP( Reference Dumont, Fournier and St-Pierre 159 Reference Dumont, Moyse and Fournier 161 ). Interestingly, a dose of full-length PYY that did not trigger a c-Fos response in the AP alone, increased amylin-induced c-Fos expression in the AP( Reference Riediger, Michel and Becskei 105 ) suggesting a possible interaction between amylin and PYY in the AP.

A recent study conducted in non-human primates demonstrated anorexigenic synergy between the potent amylin receptor agonist salmon calcitonin and the GLP-1R agonist exendin-4( Reference Bello, Kemm and Ofeldt 162 ). The mechanism underlying this synergy also remains to be identified. There is evidence that GLP-1 inhibits feeding via an AP-dependent effect after hepatic portal vein infusion( Reference Pacheco-López, Punjabi and Graber 163 ). However, the anorexigenic effect of exendin-4 is not blocked in APX rats( Reference Baraboi, Smith and Ferguson 164 ). Although amylin and GLP-1 activate AP neurons, these hormones seem to have different target cells in the AP. Similar to the aversive stimulus lithium chloride, GLP-1 and exendin-4 almost exclusively activate AP neurons that do not express the calcitonin receptor, which is considered as a marker for the primary target cells for amylin in the AP( Reference Züger, Forster and Lutz 149 ). The functional implication of this dissociation has not yet been specifically investigated. GLP-1R-mediated activation of the AP has been linked to the induction of aversion( Reference Thiele, Seeley and D'Alessio 165 ). Therefore, it is particularly important to exclude aversive mechanisms in approaches based on GLP-1R activation.

Conclusions

Extensive evidence has accumulated demonstrating that the ARC and the AP are responsive to hormonal and nutrient-related signals involved in the homoeostatic feedback control of energy homoeostasis. Overall, the neurophysiological effects that have been described by a multitude of different in vivo and in vitro approaches are consistent with the effects of these signals on food intake, body weight or metabolism. However, for many of the discussed mechanisms, the physiological relevance remains to be confirmed. Even when physiological relevance is established (e.g. amylin) or postulated (ghrelin, PYY and GLP-1) the predictive value of these physiological mechanisms for the effectiveness of mono-therapeutic anti-obesity approaches targeting these mechanisms appears to be weak. Nevertheless, the impressive effectiveness of bariatric surgery suggests the existence of signalling mechanisms that potently reduce body weight and improve metabolic disorders without being compensated by the body. Obviously, the interaction between the different feedback signals has been underestimated, which is reflected by the promising improvements in the therapeutic outcome of combination treatments. The concept of the homoeostatic feedback control of energy homoeostasis needs to be integrated into the increasing knowledge about the non-homoeostatic controls affecting energy balance.

Acknowledgements

The author thanks T.A. Lutz (Institute of Veterinary Physiology, University of Zurich) for the critical reading of the manuscript. The research presented in this work has been continuously supported by the Swiss National Science Foundation, the University of Zurich and the Centre of Integrative Human Physiology, University of Zurich. The author declares no conflicts of interest.

References

1. Ferchak, CV & Meneghini, LF (2004) Obesity, bariatric surgery and type 2 diabetes – a systematic review. Diabetes Metab Res Rev 20, 438445.CrossRefGoogle ScholarPubMed
2. Ahn, SM, Pomp, A & Rubino, F (2010) Metabolic surgery for type 2 diabetes. Ann N Y Acad Sci 1212, E37E45.CrossRefGoogle ScholarPubMed
3. Roth, JD, Roland, BL, Cole, RL, et al. (2008) Leptin responsiveness restored by amylin agonism in diet-induced obesity: evidence from nonclinical and clinical studies. Proc Natl Acad Sci USA 105, 72577262.CrossRefGoogle ScholarPubMed
4. Turek, VF, Trevaskis, JL, Levin, BE, et al. (2010) Mechanisms of amylin/leptin synergy in rodent models. Endocrinology 151, 143152.CrossRefGoogle ScholarPubMed
5. Zhang, Y, Proenca, R, Maffei, M, et al. (1994) Positional cloning of the mouse obese gene and its human homologue. Nature 372, 425432.CrossRefGoogle Scholar
6. Chua, S, Chung, W, Wu-Peng, X, et al. (1996) Phenotypes of mouse diabetes and rat fatty due to mutations in the OB (leptin) receptor. Science 271, 994996.CrossRefGoogle ScholarPubMed
7. Broberger, C, Johansen, J, Johansson, C, et al. (1998) The neuropeptide Y/agouti gene-related protein (AGRP) brain circuitry in normal, anorectic, and monosodium glutamate-treated mice. Proc Natl Acad Sci USA 95, 1504315048.CrossRefGoogle ScholarPubMed
8. Ellacott, K & Cone, R (2004) The central melanocortin system and the integration of short- and long-term regulators of energy homeostasis. Recent Prog Horm Res 59, 395408.CrossRefGoogle Scholar
9. Cowley, M, Smart, J, Rubinstein, M, et al. (2001) Leptin activates anorexigenic POMC neurons through a neural network in the arcuate nucleus. Nature 411, 480484.CrossRefGoogle ScholarPubMed
10. Spanswick, D, Smith, M, Groppi, V, et al. (1997) Leptin inhibits hypothalamic neurons by activation of ATP-sensitive potassium channels. Nature 390, 521525.CrossRefGoogle ScholarPubMed
11. Woods, SC & Seeley, RJ (2000) Adiposity signals and the control of energy homeostasis. Nutrition 16, 894902.CrossRefGoogle ScholarPubMed
12. Heymsfield, SB, Greenberg, AS, Fujioka, K, et al. (1999) Recombinant leptin for weight loss in obese and lean adults: a randomized, controlled, dose-escalation trial. JAMA 282, 15681575.CrossRefGoogle ScholarPubMed
13. Boden, G, Chen, X, Mozzoli, M, et al. (1996) Effect of fasting on serum leptin in normal human subjects. J Clin Endocrinol Metab 81, 34193423.Google ScholarPubMed
14. Weigle, DS, Duell, PB, Connor, WE, et al. (1997) Effect of fasting, refeeding, and dietary fat restriction on plasma leptin levels. J Clin Endocrinol Metab 82, 561565.Google ScholarPubMed
15. Kojima, M, Hosoda, H, Date, Y, et al. (1999) Ghrelin is a growth-hormone-releasing acylated peptide from stomach. Nature 402, 656660.CrossRefGoogle ScholarPubMed
16. Tschop, M, Smiley, D & Heiman, M (2000) Ghrelin induces adiposity in rodents. Nature 407, 908913.CrossRefGoogle ScholarPubMed
17. Asakawa, A, Inui, A, Kaga, T, et al. (2001) Ghrelin is an appetite-stimulatory signal from stomach with structural resemblance to motilin. Gastroenterology 120, 337345.CrossRefGoogle ScholarPubMed
18. Shiiya, T, Nakazato, M, Mizuta, M, et al. (2002) Plasma ghrelin levels in lean and obese humans and the effect of glucose on ghrelin secretion. J Clin Endocrinol Metab 87, 240244.CrossRefGoogle Scholar
19. Traebert, M, Riediger, T, Whitebread, S, et al. (2002) Ghrelin acts on leptin-responsive neurones in the rat arcuate nucleus. J Neuroendocrinol 14, 580586.CrossRefGoogle Scholar
20. Riediger, T, Traebert, M, Schmid, HA, et al. (2003) Site-specific effects of ghrelin on the neuronal activity in the hypothalamic arcuate nucleus. Neurosci Lett 341, 151155.CrossRefGoogle Scholar
21. Becskei, C, Bilik, KU, Klussmann, S, et al. (2008) The anti-ghrelin Spiegelmer NOX-B11-3 blocks ghrelin- but not fasting-induced neuronal activation in the hypothalamic arcuate nucleus. J Neuroendocrinol 20, 8592.CrossRefGoogle Scholar
22. Wang, L, Saint-Pierre, DH & Tache, Y (2002) Peripheral ghrelin selectively increases Fos expression in neuropeptide Y – synthesizing neurons in mouse hypothalamic arcuate nucleus. Neurosci Lett 325, 4751.CrossRefGoogle ScholarPubMed
23. Guan, X, Yu, H, Palyha, O, et al. (1997) Distribution of mRNA encoding the growth hormone secretagogue receptor in brain and peripheral tissues. Brain Res Mol Brain Res 48, 2329.CrossRefGoogle ScholarPubMed
24. Willesen, M, Kristensen, P & Romer, J (1999) Co-localization of growth hormone secretagogue receptor and NPY mRNA in the arcuate nucleus of the rat. Neuroendocrinology 70, 306316.CrossRefGoogle ScholarPubMed
25. Hewson, AK, Viltart, O, McKenzie, DN, et al. (1999) GHRP-6-induced changes in electrical activity of single cells in the arcuate, ventromedial and periventricular nucleus neurones [correction of nuclei] of a hypothalamic slice preparation in vitro . J Neuroendocrinol 11, 919923.CrossRefGoogle Scholar
26. Salome, N, Haage, D, Perrissoud, D, et al. (2009) Anorexigenic and electrophysiological actions of novel ghrelin receptor (GHS-R1A) antagonists in rats. Eur J Pharmacol 612, 167173.CrossRefGoogle ScholarPubMed
27. Tung, YC, Hewson, AK & Dickson, SL (2001) Actions of leptin on growth hormone secretagogue-responsive neurones in the rat hypothalamic arcuate nucleus recorded in vitro . J Neuroendocrinol 13, 209215.Google ScholarPubMed
28. Cowley, MA, Smith, RG, Diano, S, et al. (2003) The distribution and mechanism of action of ghrelin in the CNS demonstrates a novel hypothalamic circuit regulating energy homeostasis. Neuron 37, 649661.CrossRefGoogle ScholarPubMed
29. Dickson, SL & Luckman, SM (1997) Induction of c-Fos messenger ribonucleic acid in neuropeptide Y and growth hormone (GH)-releasing factor neurons in the rat arcuate nucleus following systemic injection of the GH secretagogue, GH-releasing peptide-6. Endocrinology 138, 771777.CrossRefGoogle ScholarPubMed
30. Geary, N (2004) Endocrine controls of eating: CCK, leptin, and ghrelin. Physiol Behav 81, 719733.CrossRefGoogle Scholar
31. Kirchner, H, Heppner, KM & Tschop, MH (2012) The role of ghrelin in the control of energy balance. Handb Exp Pharmacol, 161184.CrossRefGoogle ScholarPubMed
32. Cummings, DE, Weigle, DS, Frayo, RS, et al. (2002) Plasma ghrelin levels after diet-induced weight loss or gastric bypass surgery. N Engl J Med 346, 16231630.CrossRefGoogle ScholarPubMed
33. Dickson, SL, Egecioglu, E, Landgren, S, et al. (2011) The role of the central ghrelin system in reward from food and chemical drugs. Mol Cell Endocrinol 340, 8087.CrossRefGoogle ScholarPubMed
34. Borg, CM, le Roux, CW, Ghatei, MA, et al. (2006) Progressive rise in gut hormone levels after Roux-en-Y gastric bypass suggests gut adaptation and explains altered satiety. Br J Surg 93, 210215.CrossRefGoogle ScholarPubMed
35. le Roux, CW, Aylwin, SJ, Batterham, RL, et al. (2006) Gut hormone profiles following bariatric surgery favor an anorectic state, facilitate weight loss, and improve metabolic parameters. Ann Surg 243, 108114.CrossRefGoogle ScholarPubMed
36. le Roux, CW, Welbourn, R, Werling, M, et al. (2007) Gut hormones as mediators of appetite and weight loss after Roux-en-Y gastric bypass. Ann Surg 246, 780785.CrossRefGoogle ScholarPubMed
37. Chandarana, K, Gelegen, C, Karra, E, et al. (2011) Diet and gastrointestinal bypass-induced weight loss: the roles of ghrelin and peptide YY. Diabetes 60, 810818.CrossRefGoogle ScholarPubMed
38. Grandt, D, Schimiczek, M, Beglinger, C, et al. (1994) Two molecular forms of peptide YY (PYY) are abundant in human blood: characterization of a radioimmunoassay recognizing PYY 1-36 and PYY 3-36. Regul Pept 51, 151159.CrossRefGoogle ScholarPubMed
39. Dumont, Y, Fournier, A, St-Pierre, S, et al. (1995) Characterization of neuropeptide Y binding sites in rat brain membrane preparations using [125I][Leu31,Pro34]peptide YY and [125I]peptide YY3-36 as selective Y1 and Y2 radioligands. J Pharmacol Exp Ther 272, 673680.Google Scholar
40. Degen, L, Oesch, S, Casanova, M, et al. (2005) Effect of peptide YY3-36 on food intake in humans. Gastroenterology 129, 14301436.CrossRefGoogle ScholarPubMed
41. Sloth, B, Holst, JJ, Flint, A, et al. (2007) Effects of PYY1-36 and PYY3-36 on appetite, energy intake, energy expenditure, glucose and fat metabolism in obese and lean subjects. Am J Physiol Endocrinol Metab 292, E1062E1068.CrossRefGoogle ScholarPubMed
42. Batterham, RL, Cowley, MA, Small, CJ, et al. (2002) Gut hormone PYY(3-36) physiologically inhibits food intake. Nature 418, 650654.CrossRefGoogle ScholarPubMed
43. Ghamari-Langroudi, M, Colmers, WF & Cone, RD (2005) PYY3-36 inhibits the action potential firing activity of POMC neurons of arcuate nucleus through postsynaptic Y2 receptors. Cell Metab 2, 191199.CrossRefGoogle ScholarPubMed
44. Riediger, T, Bothe, C, Becskei, C, et al. (2004) Peptide YY directly inhibits ghrelin-activated neurons of the arcuate nucleus and reverses fasting-induced c-Fos expression. Neuroendocrinology 79, 317326.CrossRefGoogle ScholarPubMed
45. Batterham, RL, Cohen, MA, Ellis, SM, et al. (2003) Inhibition of food intake in obese subjects by peptide YY3-36. N Engl J Med 349, 941948.CrossRefGoogle ScholarPubMed
46. Adams, SH, Lei, C, Jodka, CM, et al. (2006) PYY[3-36] administration decreases the respiratory quotient and reduces adiposity in diet-induced obese mice. J Nutr 136, 195201.CrossRefGoogle ScholarPubMed
47. Koegler, FH, Enriori, PJ, Billes, SK, et al. (2005) Peptide YY(3-36) inhibits morning, but not evening, food intake and decreases body weight in rhesus macaques. Diabetes 54, 31983204.CrossRefGoogle Scholar
48. Talsania, T, Anini, Y, Siu, S, et al. (2005) Peripheral exendin-4 and peptide YY(3-36) synergistically reduce food intake through different mechanisms in mice. Endocrinology 146, 37483756.CrossRefGoogle Scholar
49. Roth, JD, Coffey, T, Jodka, CM, et al. (2007) Combination therapy with amylin and peptide YY[3–36] in obese rodents: anorexigenic synergy and weight loss additivity. Endocrinology 148, 60546061.CrossRefGoogle Scholar
50. Orskov, C, Wettergren, A & Holst, JJ (1996) Secretion of the incretin hormones glucagon-like peptide-1 and gastric inhibitory polypeptide correlates with insulin secretion in normal man throughout the day. Scand J Gastroenterol 31, 665670.CrossRefGoogle ScholarPubMed
51. Kreymann, B, Williams, G, Ghatei, MA, et al. (1987) Glucagon-like peptide-1 7-36: a physiological incretin in man. Lancet 2, 13001304.CrossRefGoogle ScholarPubMed
52. Holst, JJ (2007) The physiology of glucagon-like peptide 1. Physiol Rev 87, 14091439.CrossRefGoogle ScholarPubMed
53. Larsen, PJ, Tang-Christensen, M, Holst, JJ, et al. (1997) Distribution of glucagon-like peptide-1 and other preproglucagon-derived peptides in the rat hypothalamus and brainstem. Neuroscience 77, 257270.CrossRefGoogle ScholarPubMed
54. Merchenthaler, I, Lane, M & Shughrue, P (1999) Distribution of pre-pro-glucagon and glucagon-like peptide-1 receptor messenger RNAs in the rat central nervous system. J Comp Neurol 403, 261280.3.0.CO;2-5>CrossRefGoogle ScholarPubMed
55. Alvarez, E, Roncero, I, Chowen, JA, et al. (1996) Expression of the glucagon-like peptide-1 receptor gene in rat brain. J Neurochem 66, 920927.CrossRefGoogle ScholarPubMed
56. Turton, MD, O'Shea, D, Gunn, I, et al. (1996) A role for glucagon-like peptide-1 in the central regulation of feeding. Nature 379, 6972.CrossRefGoogle ScholarPubMed
57. Rodriquez de Fonseca, F, Navarro, M, Alvarez, E, et al. (2000) Peripheral versus central effects of glucagon-like peptide-1 receptor agonists on satiety and body weight loss in Zucker obese rats. Metab Clin Exp 49, 709717.CrossRefGoogle ScholarPubMed
58. Dakin, CL, Small, CJ, Batterham, RL, et al. (2004) Peripheral oxyntomodulin reduces food intake and body weight gain in rats. Endocrinology 145, 26872695.CrossRefGoogle ScholarPubMed
59. Reidelberger, RD, Haver, AC, Apenteng, BA, et al. (2011) Effects of exendin-4 alone and with peptide YY(3-36) on food intake and body weight in diet-induced obese rats. Obesity (Silver Spring) 19, 121127.CrossRefGoogle ScholarPubMed
60. Verdich, C, Flint, A, Gutzwiller, JP, et al. (2001) A meta-analysis of the effect of glucagon-like peptide-1 (7-36) amide on ad libitum energy intake in humans. J Clin Endocrinol Metab 86, 43824389.Google ScholarPubMed
61. Ruttimann, EB, Arnold, M, Hillebrand, JJ, et al. (2009) Intrameal hepatic portal and intraperitoneal infusions of glucagon-like peptide-1 reduce spontaneous meal size in the rat via different mechanisms. Endocrinology 150, 11741181.CrossRefGoogle ScholarPubMed
62. Punjabi, M, Arnold, M, Geary, N, et al. (2011) Peripheral glucagon-like peptide-1 (GLP-1) and satiation. Physiol Behav 105, 7176.CrossRefGoogle ScholarPubMed
63. Le Quellec, A, Kervran, A, Blache, P, et al. (1992) Oxyntomodulin-like immunoreactivity: diurnal profile of a new potential enterogastrone. J Clin Endocrinol Metab 74, 14051409.Google ScholarPubMed
64. Baggio, LL, Huang, Q, Brown, TJ, et al. (2004) Oxyntomodulin and glucagon-like peptide-1 differentially regulate murine food intake and energy expenditure. Gastroenterology 127, 546558.CrossRefGoogle ScholarPubMed
65. Sandoval, DA, Bagnol, D, Woods, SC, et al. (2008) Arcuate glucagon-like peptide 1 receptors regulate glucose homeostasis but not food intake. Diabetes 57, 20462054.CrossRefGoogle Scholar
66. Dakin, CL, Gunn, I, Small, CJ, et al. (2001) Oxyntomodulin inhibits food intake in the rat. Endocrinology 142, 42444250.CrossRefGoogle Scholar
67. Riediger, T, Eisele, N, Scheel, C, et al. . (2010) Effects of glucagon-like peptide 1 and oxyntomodulin on neuronal activity of ghrelin-sensitive neurons in the hypothalamic arcuate nucleus. Am J Physiol Regul Integr Comp Physiol 298, R1061R1067.CrossRefGoogle ScholarPubMed
68. Klonoff, DC, Buse, JB, Nielsen, LL, et al. (2008) Exenatide effects on diabetes, obesity, cardiovascular risk factors and hepatic biomarkers in patients with type 2 diabetes treated for at least 3 years. Curr Med Res Opin 24, 275286.CrossRefGoogle ScholarPubMed
69. Rosenstock, J, Klaff, LJ, Schwartz, S, et al. (2010) Effects of exenatide and lifestyle modification on body weight and glucose tolerance in obese subjects with and without pre-diabetes. Diabetes Care 33, 11731175.CrossRefGoogle ScholarPubMed
70. Vilsboll, T, Christensen, M, Junker, AE, et al. (2012) Effects of glucagon-like peptide-1 receptor agonists on weight loss: systematic review and meta-analyses of randomised controlled trials. BMJ 344, d7771.CrossRefGoogle ScholarPubMed
71. Schwartz, MW, Woods, SC, Porte, D Jr. et al. (2000) Central nervous system control of food intake. Nature 404, 661671.CrossRefGoogle ScholarPubMed
72. Wang, L, Martinez, V, Barrachina, MD, et al. (1998) Fos expression in the brain induced by peripheral injection of CCK or leptin plus CCK in fasted lean mice. Brain Res 791, 157166.CrossRefGoogle ScholarPubMed
73. Ueyama, E, Morikawa, Y, Yasuda, T, et al. (2004) Attenuation of fasting-induced phosphorylation of mitogen-activated protein kinases (ERK/p38) in the mouse hypothalamus in response to refeeding. Neurosci Lett 371, 4044.CrossRefGoogle Scholar
74. Mistry, AM, Helferich, W & Romsos, DR (1994) Elevated neuronal c-Fos-like immunoreactivity and messenger ribonucleic acid (mRNA) in genetically obese (ob/ob) mice. Brain Res 666, 5360.CrossRefGoogle ScholarPubMed
75. Becskei, C, Lutz, TA & Riediger, T (2009) Diet-derived nutrients mediate the inhibition of hypothalamic NPY neurons in the arcuate nucleus of mice during refeeding. Am J Physiol Regul Integr Comp Physiol 297, R100R110.CrossRefGoogle ScholarPubMed
76. Coppola, A, Liu, ZW, Andrews, ZB, et al. (2007) A central thermogenic-like mechanism in feeding regulation: an interplay between arcuate nucleus T3 and UCP2. Cell Metab 5, 2133.CrossRefGoogle ScholarPubMed
77. Sanchez, E, Singru, PS, Acharya, R, et al. (2008) Differential effects of refeeding on melanocortin-responsive neurons in the hypothalamic paraventricular nucleus. Endocrinology 149, 43294335.CrossRefGoogle ScholarPubMed
78. Singru, PS, Sanchez, E, Fekete, C, et al. (2007) Importance of melanocortin signaling in refeeding-induced neuronal activation and satiety. Endocrinology 148, 638646.CrossRefGoogle ScholarPubMed
79. Wang, R, Liu, X, Hentges, ST, et al. (2004) The regulation of glucose-excited neurons in the hypothalamic arcuate nucleus by glucose and feeding-relevant peptides. Diabetes 53, 19591965.CrossRefGoogle ScholarPubMed
80. Fioramonti, X, Contie, S, Song, Z, et al. (2007) Characterization of glucosensing neuron subpopulations in the arcuate nucleus: integration in neuropeptide Y and pro-opio melanocortin networks? Diabetes 56, 12191227.CrossRefGoogle ScholarPubMed
81. Muroya, S, Yada, T, Shioda, S, et al. (1999) Glucose-sensitive neurons in the rat arcuate nucleus contain neuropeptide Y. Neurosci Lett 264, 113116.CrossRefGoogle ScholarPubMed
82. Claret, M, Smith, MA, Batterham, RL, et al. (2007) AMPK is essential for energy homeostasis regulation and glucose sensing by POMC and AgRP neurons. J Clin Invest 117, 23252336.CrossRefGoogle ScholarPubMed
83. Parton, LE, Ye, CP, Coppari, R, et al. (2007) Glucose sensing by POMC neurons regulates glucose homeostasis and is impaired in obesity. Nature 449, 228232.CrossRefGoogle ScholarPubMed
84. Miki, T, Liss, B, Minami, K, et al. (2001) ATP-sensitive K+ channels in the hypothalamus are essential for the maintenance of glucose homeostasis. Nat Neurosci 4, 507512.CrossRefGoogle ScholarPubMed
85. Levin, BE, Routh, VH, Kang, L, et al. (2004) Neuronal glucosensing: what do we know after 50 years? Diabetes 53, 25212528.CrossRefGoogle ScholarPubMed
86. Kahn, BB, Alquier, T, Carling, D, et al. (2005) AMP-activated protein kinase: ancient energy gauge provides clues to modern understanding of metabolism. Cell Metab 1, 1525.CrossRefGoogle ScholarPubMed
87. Minokoshi, Y, Alquier, T, Furukawa, N, et al. (2004) AMP-kinase regulates food intake by responding to hormonal and nutrient signals in the hypothalamus. Nature 428, 569574.CrossRefGoogle ScholarPubMed
88. Becskei, C, Lutz, TA & Riediger, T (2008) Glucose reverses fasting-induced activation in the arcuate nucleus of mice. Neuroreport 19, 105109.CrossRefGoogle ScholarPubMed
89. Morgan, K, Obici, S & Rossetti, L (2004) Hypothalamic responses to long-chain fatty acids are nutritionally regulated. J Biol Chem 279, 3113931148.CrossRefGoogle ScholarPubMed
90. Obici, S, Feng, Z, Morgan, K, et al. (2002) Central administration of oleic acid inhibits glucose production and food intake. Diabetes 51, 271275.CrossRefGoogle ScholarPubMed
91. Wang, R, Cruciani-Guglielmacci, C, Migrenne, S, et al. (2006) Effects of oleic acid on distinct populations of neurons in the hypothalamic arcuate nucleus are dependent on extracellular glucose levels. J Neurophysiol 95, 14911498.CrossRefGoogle ScholarPubMed
92. Jo, YH, Su, Y, Gutierrez-Juarez, R, et al. (2009) Oleic acid directly regulates POMC neuron excitability in the hypothalamus. J Neurophysiol 101, 23052316.CrossRefGoogle ScholarPubMed
93. Loftus, TM, Jaworsky, DE, Frehywot, GL, et al. (2000) Reduced food intake and body weight in mice treated with fatty acid synthase inhibitors. Science 288, 23792381.CrossRefGoogle ScholarPubMed
94. Kim, EK, Miller, I, Landree, LE, et al. (2002) Expression of FAS within hypothalamic neurons: a model for decreased food intake after C75 treatment. Am J Physiol Endocrinol Metab 283, E867E879.CrossRefGoogle Scholar
95. Miller, I, Ronnett, GV, Moran, TH, et al. (2004) Anorexigenic C75 alters c-Fos in mouse hypothalamic and hindbrain subnuclei. Neuroreport 15, 925929.CrossRefGoogle ScholarPubMed
96. He, W, Lam, TK, Obici, S, et al. (2006) Molecular disruption of hypothalamic nutrient sensing induces obesity. Nat Neurosci 9, 227233.CrossRefGoogle ScholarPubMed
97. Obici, S, Feng, Z, Arduini, A, et al. (2003) Inhibition of hypothalamic carnitine palmitoyltransferase-1 decreases food intake and glucose production. Nat Med 9, 756761.CrossRefGoogle ScholarPubMed
98. Jacinto, E & Hall, MN (2003) Tor signalling in bugs, brain and brawn. Nat Rev Mol Cell Biol 4, 117126.CrossRefGoogle ScholarPubMed
99. Cota, D, Proulx, K, Smith, KA, et al. (2006) Hypothalamic mTOR signaling regulates food intake. Science 312, 927930.CrossRefGoogle Scholar
100. Blouet, C, Jo, YH, Li, X, et al. (2009) Mediobasal hypothalamic leucine sensing regulates food intake through activation of a hypothalamus-brainstem circuit. J Neurosci 29, 83028311.CrossRefGoogle ScholarPubMed
101. Bagnasco, M, Tulipano, G, Melis, MR, et al. (2003) Endogenous ghrelin is an orexigenic peptide acting in the arcuate nucleus in response to fasting. Regul Pept 111, 161167.CrossRefGoogle ScholarPubMed
102. Helmling, S, Maasch, C, Eulberg, D, et al. (2004) Inhibition of ghrelin action in vitro and in vivo by an RNA-Spiegelmer. Proc Natl Acad Sci USA 101, 1317413179.CrossRefGoogle ScholarPubMed
103. Kobelt, P, Helmling, S, Stengel, A, et al. (2006) Anti-ghrelin Spiegelmer NOX-B11 inhibits neurostimulatory and orexigenic effects of peripheral ghrelin in rats. Gut 55, 788792.CrossRefGoogle ScholarPubMed
104. Becskei, C, Lutz, TA & Riediger, T (2010) Reduced fasting-induced activation of hypothalamic arcuate neurons is associated with hyperleptinemia and increased leptin sensitivity in obese mice. Am J Physiol Regul Integr Comp Physiol 299, R632R641.CrossRefGoogle ScholarPubMed
105. Riediger, T, Michel, S, Becskei, C, et al. (2007) Diet-derived nutrients and PYY modulate the effects of amylin on c-Fos expression in the area postrema and on food intake. 2007 Neuroscience Meeting Planner. San Diego, CA: Society for Neuroscience, 2010. Online. Program No. 299.7/UU3.Google Scholar
106. Halaas, JL, Boozer, C, Blair-West, J, et al. (1997) Physiological response to long-term peripheral and central leptin infusion in lean and obese mice. Proc Natl Acad Sci USA 94, 88788883.CrossRefGoogle ScholarPubMed
107. Bjorntorp, P (1997) Body fat distribution, insulin resistance, and metabolic diseases. Nutrition 13, 795803.CrossRefGoogle ScholarPubMed
108. Munzberg, H, Flier, JS & Bjorbaek, C (2004) Region-specific leptin resistance within the hypothalamus of diet-induced obese mice. Endocrinology 145, 48804889.CrossRefGoogle ScholarPubMed
109. Gamber, KM, Huo, L, Ha, S, et al. (2012) Over-expression of leptin receptors in hypothalamic POMC neurons increases susceptibility to diet-induced obesity. PLoS One 7, e30485.CrossRefGoogle ScholarPubMed
110. Enriori, PJ, Evans, AE, Sinnayah, P, et al. (2007) Diet-induced obesity causes severe but reversible leptin resistance in arcuate melanocortin neurons. Cell Metab 5, 181194.CrossRefGoogle ScholarPubMed
111. Briggs, DI, Enriori, PJ, Lemus, MB, et al. (2010) Diet-induced obesity causes ghrelin resistance in arcuate NPY/AgRP neurons. Endocrinology 151, 47454755.CrossRefGoogle ScholarPubMed
112. Levin, BE, Govek, EK & Dunn-Meynell, AA (1998) Reduced glucose-induced neuronal activation in the hypothalamus of diet-induced obese rats. Brain Res 808, 317319.CrossRefGoogle ScholarPubMed
113. Becskei, C, Lutz, TA & Riediger, T (2009) Blunted fasting-induced hypothalamic activation and refeeding hyperphagia in late-onset obesity. Neuroendocrinology 90, 371382.CrossRefGoogle ScholarPubMed
114. Banks, WA & Farrell, CL (2003) Impaired transport of leptin across the blood-brain barrier in obesity is acquired and reversible. Am J Physiol Endocrinol Metab 285, E10E15.CrossRefGoogle ScholarPubMed
115. Banks, WA, Coon, AB, Robinson, SM, et al. (2004) Triglycerides induce leptin resistance at the blood-brain barrier. Diabetes 53, 12531260.CrossRefGoogle ScholarPubMed
116. Baskin, DG, Breininger, JF & Schwartz, MW (2000) SOCS-3 expression in leptin-sensitive neurons of the hypothalamus of fed and fasted rats. Regul Pept 92, 9–15.CrossRefGoogle ScholarPubMed
117. Morrison, CD, White, CL, Wang, Z, et al. (2007) Increased hypothalamic protein tyrosine phosphatase 1B contributes to leptin resistance with age. Endocrinology 148, 433440.CrossRefGoogle ScholarPubMed
118. Baskin, DG, Seeley, RJ, Kuijper, JL, et al. (1998) Increased expression of mRNA for the long form of the leptin receptor in the hypothalamus is associated with leptin hypersensitivity and fasting. Diabetes 47, 538543.CrossRefGoogle Scholar
119. Baskin, DG, Breininger, JF, Bonigut, S, et al. (1999) Leptin binding in the arcuate nucleus is increased during fasting. Brain Res 828, 154158.CrossRefGoogle ScholarPubMed
120. van der Kooy, D & Koda, LY (1983) Organization of the projections of a circumventricular organ: the area postrema in the rat. J Comp Neurol 219, 328338.CrossRefGoogle ScholarPubMed
121. Ritter, S, McGlone, JJ & Kelley, KW (1980) Absence of lithium-induced taste aversion after area postrema lesion. Brain Res 201, 501506.CrossRefGoogle ScholarPubMed
122. Hyde, TM & Miselis, RR (1983) Effects of area postrema/caudal medial nucleus of solitary tract lesions on food intake and body weight. Am J Physiol Regul Integr Comp Physiol 244, R577R587.CrossRefGoogle ScholarPubMed
123. Miselis, RR, Hyde, TM & Shapiro, RE (1984) Area postrema and adjacent solitary nucleus in water and energy balance. Fed Proc 43, 29692971.Google ScholarPubMed
124. Bird, E, Cardone, CC & Contreras, RJ (1983) Area postrema lesions disrupt food intake induced by cerebroventricular infusions of 5-thioglucose in the rat. Brain Res 270, 193196.CrossRefGoogle ScholarPubMed
125. Young, A (2005) Tissue expression and secretion of amylin. Adv Pharmacol 52, 1945.CrossRefGoogle ScholarPubMed
126. Lutz, TA, Del Prete, E & Scharrer, E (1994) Reduction of food intake in rats by intraperitoneal injection of low doses of amylin. Physiol Behav 55, 891895.CrossRefGoogle ScholarPubMed
127. Lutz, TA, Geary, N, Szabady, MM, et al. (1995) Amylin decreases meal size in rats. Physiol Behav 58, 11971202.CrossRefGoogle ScholarPubMed
128. Arnelo, U, Reidelberger, R, Adrian, TE, et al. (1998) Sufficiency of postprandial plasma levels of islet amyloid polypeptide for suppression of feeding in rats. Am J Physiol Regul Integr Comp Physiol 275, R1537R1542.CrossRefGoogle ScholarPubMed
129. Reidelberger, RD, Haver, AC, Arnelo, U, et al. (2004) Amylin receptor blockade stimulates food intake in rats. Am J Physiol Regul Integr Comp Physiol 287, R568R574.CrossRefGoogle ScholarPubMed
130. Lutz, TA, Del Prete, E & Scharrer, E (1995) Subdiaphragmatic vagotomy does not influence the anorectic effect of amylin. Peptides 16, 457462.CrossRefGoogle Scholar
131. Lutz, TA, Mollet, A, Rushing, PA, et al. (2001) The anorectic effect of a chronic peripheral infusion of amylin is abolished in area postrema/nucleus of the solitary tract (AP/NTS) lesioned rats. Int J Obes Relat Metab Disord 25, 10051011.CrossRefGoogle ScholarPubMed
132. Lutz, TA, Senn, M, Althaus, J, et al. (1998) Lesion of the area postrema/nucleus of the solitary tract (AP/NTS) attenuates the anorectic effects of amylin and calcitonin gene-related peptide (CGRP) in rats. Peptides 19, 309317.CrossRefGoogle ScholarPubMed
133. Mack, CM, Soares, CJ, Wilson, JK, et al. (2010) Davalintide (AC2307), a novel amylin-mimetic peptide: enhanced pharmacological properties over native amylin to reduce food intake and body weight. Int J Obes (Lond) 34, 385395.CrossRefGoogle ScholarPubMed
134. Christopoulos, G, Perry, KJ, Morfis, M, et al. (1999) Multiple amylin receptors arise from receptor activity-modifying protein interaction with the calcitonin receptor gene product. Mol Pharmacol 56, 235242.CrossRefGoogle ScholarPubMed
135. Becskei, C, Riediger, T, Zund, D, et al. (2004) Immunohistochemical mapping of calcitonin receptors in the adult rat brain. Brain Res 1030, 221233.CrossRefGoogle ScholarPubMed
136. Barth, SW, Riediger, T, Lutz, TA, et al. (2004) Peripheral amylin activates circumventricular organs expressing calcitonin receptor a/b subtypes and receptor-activity modifying proteins in the rat. Brain Res 997, 97–102.CrossRefGoogle ScholarPubMed
137. Riediger, T, Schmid, HA, Lutz, T, et al. (2001) Amylin potently activates AP neurons possibly via formation of the excitatory second messenger cGMP. Am J Physiol Regul Integr Comp Physiol 281, R1833R1843.CrossRefGoogle ScholarPubMed
138. Rowland, NE, Crews, EC & Gentry, RM (1997) Comparison of Fos induced in rat brain by GLP-1 and amylin. Regul Pept 71, 171174.CrossRefGoogle Scholar
139. Riediger, T, Zuend, D, Becskei, C, et al. (2004) The anorectic hormone amylin contributes to feeding-related changes of neuronal activity in key structures of the gut-brain axis. Am J Physiol Regul Integr Comp Physiol 286, R114R122.CrossRefGoogle ScholarPubMed
140. Potes, CS, Turek, VF, Cole, RL, et al. (2010) Noradrenergic neurons of the area postrema mediate amylin's hypophagic action. Am J Physiol Regul Integr Comp Physiol 299, R623R631.CrossRefGoogle ScholarPubMed
141. Funahashi, M & Adachi, A (1993) Glucose-responsive neurons exist within the area postrema of the rat: in vitro study on the isolated slice preparation. Brain Res Bull 32, 531535.CrossRefGoogle Scholar
142. Riediger, T, Schmid, HA, Lutz, TA, et al. . (2002) Amylin and glucose co-activate area postrema neurons of the rat. Neurosci Lett 328, 121124.CrossRefGoogle ScholarPubMed
143. Ritter, S, Dinh, TT & Zhang, Y (2000) Localization of hindbrain glucoreceptive sites controlling food intake and blood glucose. Brain Res 856, 3747.CrossRefGoogle ScholarPubMed
144. Schvarcz, E, Palmer, M, Aman, J, et al. (1995) Hypoglycemia increases the gastric emptying rate in healthy subjects. Diabetes Care 18, 674676.CrossRefGoogle ScholarPubMed
145. Gedulin, BR & Young, AA (1998) Hypoglycemia overrides amylin-mediated regulation of gastric emptying in rats. Diabetes 47, 9397.CrossRefGoogle ScholarPubMed
146. Young, A (2005) Inhibition of gastric emptying. Adv Pharmacol 52, 99–121.CrossRefGoogle ScholarPubMed
147. Young, AA (2012) Brainstem sensing of meal-related signals in energy homeostasis. Neuropharmacology 63, 3145.CrossRefGoogle ScholarPubMed
148. Michel, S, Becskei, C, Erguven, E, et al. (2007) Diet-derived nutrients modulate the effects of amylin on c-Fos expression in the area postrema and on food intake. Neuroendocrinology 86, 124135.CrossRefGoogle ScholarPubMed
149. Züger, D, Forster, K, Lutz, TA, et al. (2011) The sensitivity of AP neurons to amylin and GLP-1 is modulated by the feeding status. Appetite 57, Suppl. 1, S48S49.CrossRefGoogle Scholar
150. Ritter, S & Taylor, JS (1990) Vagal sensory neurons are required for lipoprivic but not glucoprivic feeding in rats. Am J Physiol Regul Integr Comp Physiol 258, R1395R1401.CrossRefGoogle Scholar
151. Monnikes, H, Lauer, G, Bauer, C, et al. (1997) Pathways of Fos expression in locus ceruleus, dorsal vagal complex, and PVN in response to intestinal lipid. Am J Physiol Regul Integr Comp Physiol 273, R2059R2071.CrossRefGoogle ScholarPubMed
152. Bhavsar, S, Watkins, J & Young, A (1998) Synergy between amylin and cholecystokinin for inhibition of food intake in mice. Physiol Behav 64, 557561.CrossRefGoogle ScholarPubMed
153. Boyle, CN, Rossier, MM & Lutz, TA (2011) Influence of high-fat feeding, diet-induced obesity, and hyperamylinemia on the sensitivity to acute amylin. Physiol Behav 104, 2028.CrossRefGoogle ScholarPubMed
154. Potes, CS, Lutz, TA & Riediger, T (2010) Identification of central projections from amylin-activated neurons to the lateral hypothalamus. Brain Res 1334, 3144.CrossRefGoogle ScholarPubMed
155. Roth, JD, Trevaskis, JL, Turek, VF, et al. (2010) “Weighing in” on synergy: preclinical research on neurohormonal anti-obesity combinations. Brain Res 1350, 8694.CrossRefGoogle ScholarPubMed
156. Baraboi, ED, Michel, C, Smith, P, et al. (2010) Effects of albumin-conjugated PYY on food intake: the respective roles of the circumventricular organs and vagus nerve. Eur J Neurosci 32, 826839.CrossRefGoogle ScholarPubMed
157. Cox, JE & Randich, A (2004) Enhancement of feeding suppression by PYY(3-36) in rats with area postrema ablations. Peptides 25, 985989.CrossRefGoogle ScholarPubMed
158. Deng, X, Guarita, DR, Pedroso, MR, et al. (2001) Area postrema lesion alters the effects of peptide YY on 2-DG-stimulated pancreatic exocrine secretion. Dig Dis Sci 46, 24602469.CrossRefGoogle ScholarPubMed
159. Dumont, Y, Fournier, A, St-Pierre, S, et al. (1996) Autoradiographic distribution of [125I]Leu31,Pro34]PYY and [125I]PYY3-36 binding sites in the rat brain evaluated with two newly developed Y1 and Y2 receptor radioligands. Synapse 22, 139158.3.0.CO;2-E>CrossRefGoogle ScholarPubMed
160. Dumont, Y, Fournier, A & Quirion, R (1998) Expression and characterization of the neuropeptide Y Y5 receptor subtype in the rat brain. J Neurosci 18, 55655574.CrossRefGoogle ScholarPubMed
161. Dumont, Y, Moyse, E, Fournier, A, et al. (2007) Distribution of peripherally injected peptide YY ([125I] PYY (3-36)) and pancreatic polypeptide ([125I] hPP) in the CNS: enrichment in the area postrema. J Mol Neurosci 33, 294304.CrossRefGoogle ScholarPubMed
162. Bello, NT, Kemm, MH, Ofeldt, EM, et al. (2010) Dose combinations of exendin-4 and salmon calcitonin produce additive and synergistic reductions in food intake in nonhuman primates. Am J Physiol Regul Integr Comp Physiol 299, R945R952.CrossRefGoogle ScholarPubMed
163. Pacheco-López, G, Punjabi, M, Graber, M, et al. (2010) Hindbrain glucagon-like peptide-1 receptors (GLP-1R) mediate the eating-inhibitory effect of hepatic portal vein (HPV) GLP-1 infusions. Appetite 54, 668.CrossRefGoogle Scholar
164. Baraboi, ED, Smith, P, Ferguson, AV, et al. (2010) Lesions of area postrema and subfornical organ alter exendin-4-induced brain activation without preventing the hypophagic effect of the GLP-1 receptor agonist. Am J Physiol Regul Integr Comp Physiol 298, R1098R1110.CrossRefGoogle ScholarPubMed
165. Thiele, TE, Seeley, RJ, D'Alessio, D, et al. (1998) Central infusion of glucagon-like peptide-1-(7-36) amide (GLP-1) receptor antagonist attenuates lithium chloride-induced c-Fos induction in rat brainstem. Brain Res 801, 164170.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Continuous rate meter recording of a spontaneously active neuron from the medial arcuate nucleus of the rat. Consecutive superfusions of ghrelin and the anorectic hormone peptide YY (PYY) at the indicated times caused opposite effects on neuronal activity. While ghrelin induced a strong excitatory response, PYY effectively decreased the discharge rate. Reproduced with permission (published in Riediger et al.(44)).

Figure 1

Fig. 2. Representative recording showing the excitatory effect of glucagon-like peptide-1 (GLP-1) on a ghrelin-inhibited neuron of the arcuate nucleus. Reproduced with permission (published in Riediger et al.(67).

Figure 2

Fig. 3. Refeeding with chow completely reversed the fasting-induced c-Fos expression in the arcuate nucleus (ARC). Representative ARC sections immunostained for c-Fos of 14-h fasted (A), chow-refed (B) and ad libitum chow-fed (C) mice. Bar charts show the quantitative results of c-Fos expression (D). a,b Different letters indicate significant differences between groups (P < 0·05). 3 V: 3rd ventricle. Scale bar: 100 μm. Reproduced with permission (published in Becskei et al.) (75).

Figure 3

Fig. 4. Effect of exogenous leptin-induced hyperleptinaemia during fasting on arcuate nucleus (ARC) activation in lean mice. Representative ARC sections immunostained for c-Fos of young lean mice treated with saline or leptin every 3 h during a 14-h food-deprivation period. Leptin treatment significantly increased the leptin plasma concentration and attenuated the fasting-induced c-Fos expression in the ARC (**P < 0·01 for both effects). 3 V: 3rd ventricle. Scale bar: 100 μm. Reproduced with permission (published in Becskei et al.)(104).

Figure 4

Fig. 5. Co-sensitivity of an area postrema (AP) neuron to glucose and amylin. Decreasing the glucose concentration in the superfusion solution from the standard concentration of 10 mM to 2, 4 and 6 mM during the indicated time caused concentration-dependent decreases of the spontaneous discharge rate. Superfusion of amylin elicited a strong excitatory effect. Reproduced with permission (published in Riediger et al.(142)).

Figure 5

Fig. 6. Effect of amylin (5 μg/kg s.c.) on food intake in rats kept on different test diets (NED, non-energy diet, vanilla-flavoured cellulose) for 24 h prior to injection. Bars represent group means and sem (n12). *P < 0·05 and ***P < 0·001, significantly different from respective control (saline) group (paired Student t test). Modified and reproduced with permission (published in Michel et al.(148)).