Central NUCB2/Nesfatin-1-expressing neurones belong to the hypothalamic-brainstem circuitry activated by hypoglycaemia.

Nesfatin-1 is a recently identified 82 amino acid peptide shown to have an anorexigenic effect on rodents when administrered centrally and peripherally. Nesfatin-1 is expressed not only in neurones of various brain areas, including the hypothalamic and brainstem nuclei, but also in peripheral organs, such as the stomach and the pancreas. Nesfatinergic neurones were reported to participate in the regulation of satiety signals and in the responses to other stimuli, including restraint stress, abdominal surgery, and lipopolysaccharide-induced inflammation. The present study aimed to investigate whether NUCB2/nesfatin-1 expressing neurones also take part in the central signalling activated in response to hypoglycaemia and therefore are involved in central glucose sensing. Using immunolabelling methods based on the detection of the neuronal activation marker c-Fos and of nesfatin-1, we showed that peripheral injection of insulin induced a strong activation of nesfatin-1-expressing neurones in the brain vagal-regulatory nuclei, including the arcuate nucleus, paraventricular nucleus, lateral hypothalamic area, dorsal motor nucleus of the vagus (DMNX) and nucleus of the tractus solitarius. In response to intracellular glucopaenia induced by i.p. or i.c.v. 2-deoxyglucose injection, the c-Fos/nesfatin-1 colocalisations observed at the hypothalamic and brainstem levels were similar to those observed after insulin-induced hypoglycaemia. Moreover, using Fluorogold as a retrograde tracer, we showed that nesfatinergic preganglionic DMNX neurones activated by hypoglycaemia target the stomach and the pancreas. Taken together, these results suggest that a subpopulation of nesfatinergic neurones belongs to the central network activated by hypoglycaemia, and that nesfatin-1 participates in the triggering of physiological and hormonal counter-regulations observed in response to hypoglycaemia.

Toward the management of inflammation: recent developments of mPGES-1 inhibitors.

For decades, the struggle against inflammation and related disorders has constituted an important field in medical practice, with strategies mainly aimed at inhibiting compounds produced through the arachidonic acid pathway. Thus, specific COX-2 inhibitors or "coxibs", were recently designed, that play an increasing but controversial role in reducing inflammatory phenomenon. Lately, several patents have been generated which target the specific inhibition of the microsomal Prostanglandin E synthase-1 (mPGES-1). This enzyme, which was cloned and characterized at the end of the nineties, catalyzes under inflammatory stimuli the last step of PGE2 synthesis. A corpus of data is now available illustrating the pivotal role played by this enzyme in numerous symptoms linked to inflammation such as fever, anorexia or pain. The present review highlights the current state of knowledge of the involvement of mPGES-1 in sickness behaviour and in other inflammation-related disorders and summarizes the recent patents related to mPGES-1 and its specific inhibition.

Expression of leptin receptor by glial cells of the nucleus tractus solitarius: possible involvement in energy homeostasis.

Leptin, an adipocyte-derived hormone, regulates food intake and body weight by acting principally on the hypothalamus, which displays the highest expression of leptin receptor (Ob-R). Nevertheless, other regions of the brain express Ob-R and constitute leptin's target sites. The dorsal vagal complex (DVC), an integrative centre of autonomic functions located in the caudal brainstem, is one of these structures. Leptin, by acting through the DVC, affects autonomic and neuroendocrine functions, such as control of food intake and gastric motility. In the present study, we observed Ob-R labelling within the DVC in cells that correspond to neuronal cell bodies. We showed for the first time Ob-R expression in a subpopulation of glial fibrillary acid protein positive cells located at the border between the area postrema and the nucleus tractus solitarius (NTS). These glial cells exhibit an atypical morphology consisting of unbranched processes that radiate rostro-caudally from the fourth ventricle wall. In vitro, the glial cells exhibited both long and short Ob-R expression with a preferential expression of the Ob-Ra and-f isoforms. Interestingly, using i.v and i.c.v. injection of the fluorescent tracer hydroxystilbamidine, we provided evidence that these cells may constitute a diffusion barrier which might regulate entry of molecules into the NTS. Finally, modulation of energy status, by acute or chronic reduction of food intake, modulated especially the short Ob-R isoforms in the DVC. In the light of these results, we hypothesise that Ob-R positive glial cells of the DVC participate in the transport of leptin into the brainstem and thus contribute to regulation of energy homeostasis.

mPGES-1 knock-out mice are resistant to cancer-induced anorexia despite the absence of central mPGES-1 up-regulation in wild-type anorexic mice.

Anorexia-cachexia syndrome is a very common symptom observed in individuals affected by chronic inflammatory diseases. The present study was designed to address the possible involvement of the inducible microsomal prostaglandin E synthase-1 (mPGES-1) in the hypopaghia observed during these pathological states. To this end, we used a model of cancer-induced anorexia and we report here that despite the absence of up-regulation of the mPGES-1 enzyme within the brain during anorexia-cachexia syndrome, mPGES-1 knock-out mice exhibit resistance to tumor-induced anorexia and maintain their body mass.

c-Fos immunoreactivity induced by intraperitoneal LPS administration is reduced in the brain of mice lacking the microsomal prostaglandin E synthase-1 (mPGES-1).

The aim of the present study was to investigate the impact of the deletion of the microsomal prostaglandin E synthase-1 (mPGES-1) gene on lipopolysaccharide (LPS)-induced neuronal activation in central nervous structures. The mPGES-1 catalyses the conversion of COX-derived PGH(2) to PGE(2) and has been described as a regulated enzyme whose expression is stimulated by proinflammatory agents. Using the immediate-early gene c-fos as a marker of neuronal activation, we determined whether deletion of the mPGES-1 gene altered the neuronal activation induced by LPS in structures classically recognized as immunosensitive regions. No significant difference in the c-Fos immunostaining was observed in the brain of saline-treated mPGES-1+/+, mPGES-1+/- and mPGES-1-/- mice. However, we observed that LPS-induced neuronal activation was reduced in most of the centres known as immunosensitive nuclei in mPGES-1-/- mice compared with heterozygous and wild-type mice. The decrease in the number of c-Fos positive nuclei occurred particularly in the caudal ventrolateral medulla, the medial, intermediate and central parts of the nucleus tractus solitarius, area postrema, parabrachial nucleus, locus coeruleus, paraventricular nucleus of the hypothalamus, ventromedial preoptic area, central amygdala, bed nucleus of the stria terminalis and to a lesser extent in the ventrolateral part of the nucleus tractus solitarius and rostral ventrolateral medulla. These results suggest that the mPGES-1 enzyme is strongly needed to provide sufficient PGE(2) production required to stimulate immunosensitive brain regions and they are discussed with regard to the recent works reporting impaired sickness behavior in mPGES-1-/- mice.

Involvement of central microsomal prostaglandin E synthase-1 in IL-1beta-induced anorexia.

In response to infection or inflammation, individuals develop a set of symptoms referred to as sickness behavior, which includes a decrease in food intake. The characterization of the molecular mechanisms underlying this hypophagia remains critical, because chronic anorexia may represent a significant health risk. Prostaglandins (PGs) constitute an important inflammatory mediator family whose levels increase in the brain during inflammatory states, and their involvement in inflammatory-induced anorexia has been proposed. The microsomal PGE synthase (mPGES)-1 enzyme is involved in the last step of PGE2 biosynthesis, and its expression is stimulated by proinflammatory agents. The present study attempted to determine whether an upregulation of mPGES-1 gene expression may account for the immune-induced anorexic behavior. We focused our study on mPGES-1 expression in the hypothalamus and dorsal vagal complex, two structures strongly activated during peripheral inflammation and involved in the regulation of food intake. We showed that mPGES-1 gene expression was robustly upregulated in these structures after intraperitoneal and intracerebroventricular injections of anorexigenic doses of IL-1beta. This increase was correlated with the onset of anorexia. The concomitant reduction in food intake and central mPGES-1 gene upregulation led us to test the feeding behavior of mice lacking mPGES-1 during inflammation. Interestingly, IL-1beta failed to decrease food intake in mPGES-1(-/-) mice, although these animals developed anorexia in response to a PGE2 injection. Taken together, our results demonstrate that mPGES-1, which is strongly upregulated during inflammation in central structures involved in feeding control, is essential for immune anorexic behavior and thus may constitute a potential therapeutic target.

Effects of lactate on glucose-sensing neurons in the solitary tract nucleus.

For nervous tissue, lactate is a valuable energy substrate that can be extracted from glucose by astrocytes and released for neuronal use. Therefore, we hypothesized that the glucose-sensing neurons that signal the glycemic changes involved in the control of body energy homeostasis may be responsive to extracellular lactate as well. To test this hypothesis, neuronal activity was recorded extracellularly in the solitary tract nucleus of anesthetized rats in order to compare the effects of microelectrophoretic applications of glucose and lactate and of moderate hyperglycemia and to assess the possible effects of lactate on the response to glucose. About 90% of the investigated neurons behaved in a similar manner after local ejections of glucose and lactate. Among them, most neurons activated by glucose were also activated by lactate and all neurons depressed by glucose were also depressed by lactate. This result suggests that the response to these two compounds is mediated by a common mechanism related to their utilization as oxidizible substrates. In half of the tested neurons, the response to glucose was eliminated or significantly reduced after repeated lactate ejections. This inhibitory effect is a likely result of a modification in glucose metabolism induced by a high extracellular lactate level. Most glycemia-sensitive neurons responded similarly to moderate hyperglycemia and to local lactate ejection, suggesting that high brain lactate levels might interfere with the brain mechanisms that mediate glucoprivic eating.

Involvement of adenosine triphosphate-sensitive K+ channels in glucose-sensing in the rat solitary tract nucleus.

The presence of adenosine triphosphate-sensitive (ATP-sensitive) K+ channels (K(ATP) channels) in the caudal nucleus tractus solitarii (NTS), and their possible involvement in glucose-sensing, were assessed by extracellular recording of neuronal activity in rat hindbrain slices. In 21 out of 36 recorded cells, firing was increased by sulfonylureas and decreased by K+ channel opener (KCO), indicating the existence of K(ATP) channels in the caudal NTS. In seven out of the nine neurons activated by a 2 mM increase in the glucose level, the effects of sulfonylureas and KCO were consistent with the involvement of K(ATP) channels in the glucose response. Conversely, the mechanism(s) underlying the response of glucose-depressed neurons remains to be clarified. Finally, the presence of K(ATP) channels was also detected in some neurons that were unresponsive to a 2 mM change in the glucose level. Thus, K(ATP) channels were pharmacologically identified in the caudal NTS, where they may be partly involved in glucose sensing.

Solitary tract nucleus sensitivity to moderate changes in glucose level.

Many neurons in the caudal nucleus tractus solitarii (NTS) recorded in vivo respond to moderate glycemic fluctuations through the local action of glucose molecules. To investigate this sensitivity in vitro, the extracellular activity of 112 neurons was recorded in hindbrain slices: 57 changed in firing rate when the glucose level in the bathing medium was increased by 2 mM. Since the glucose-responding neurons were located in catecholaminergic regions and depressed by the alpha-2 adrenoceptor agonist clonidine, they were likely to be adrenergic or noradrenergic. A comparison of the responses to glucose and 2-deoxy-D-glucose suggested that the bioenergetic metabolism is involved in NTS sensitivity to glucose.

Neuronal responses to delta 9-tetrahydrocannabinol in the solitary tract nucleus.

The effects of delta 9-tetrahydrocannabinol on single-unit activity in the subpostremal division of the nucleus tractus solitarii were investigated by extracellular recording in rat brain slices. The spontaneous firing rate of 54.8% of the recorded neurons was significantly changed after bath applications of delta 9-tetrahydrocannabinol. Putative nutrition-related neurons responding to a moderate increase in glucose concentration were selectively sensitive to delta 9-tetrahydrocannabinol. The delta 9-tetrahydrocannabinol-sensitive neurons were depressed by clonidine and are therefore likely to be adrenergic or noradrenergic. These observations suggest that some catecholaminergic, glucose-responsive neurons in the subpostremal nucleus tractus solitarii might mediate the influence of cannabinoids on feeding behaviour. Furthermore, most delta 9-tetrahydrocannabinol-sensitive neurons in the nucleus tractus solitarii showed opposite responses to delta 9-tetrahydrocannabinol and the 5-HT3 receptor agonist 1-phenylbiguanide, and might therefore be involved in the nausea-reducing effects of cannabinoids.