Peripheral injection of bombesin induces c-Fos in NUCB2/nesfatin-1 neurons.

As anorexigenic hormones bombesin and nucleobindin2 (NUCB2)/nesfatin-1 decrease food intake in rodents. Both hormones have been described in brain nuclei that play a role in the modulation of hunger and satiety, like the paraventricular nucleus of the hypothalamus (PVN) and the nucleus of the solitary tract (NTS). However, the direct interaction of the two hormones is unknown so far. The aim of study was to elucidate whether bombesin directly interacts with NUCB2/nesfatin-1 neurons in the PVN and NTS. Therefore, we injected bombesin intraperitoneally (ip) at two doses (26 and 32nmol/kg body weight) and assessed c-Fos activation in the PVN, arcuate nucleus (ARC) and NTS compared to vehicle treated rats (0.15M NaCl). We also performed co-localization studies with oxytocin or tyrosine hydroxylase. Bombesin at both doses increased the number of c-Fos positive neurons in the PVN (p<0.05) and NTS (p<0.05) compared to vehicle, while in the ARC no modulation was observed (p>0.05). In the PVN and NTS the number of c-Fos positive neurons colocalized with NUCB2/nesfatin-1 increased after bombesin injection compared to vehicle treatment (p<0.05). Moreover, an increase of activated NUCB2/nesfatin-1 immunoreactive neurons that co-expressed oxytocin in the PVN (p<0.05) or tyrosine hydroxylase in the NTS (p<0.05) was observed compared to vehicle. Our results show that peripherally injected bombesin activates NUCB2/nesfatin-1 neurons in the PVN and NTS giving rise to a possible interaction between bombesin and NUCB2/nesfatin-1 in the modulation of food intake.

Bombesin: a possible role in wound repair.

During tissue regeneration and wound healing of the skin, migration, proliferation and differentiation of keratinocytes are important processes. Here we assessed the effect of a neuropeptide, bombesin, on keratinocytes during regeneration from scratch wounding. Bombesin purified from amphibian skin, is homologous of mammalian gastrin-releasing peptide and is active in mammals. Its pharmacological effects mediate various physiological activities: hypertensive action, stimulating action on gastric secretion, hyperglycemic effect or increased insulin secretion. In vitro it shows a hyperproliferative effect on different experimental models and is involved in skin repair. The aim of this study was to elucidate the effect of Bombesin in an in vitro experimental model on a mechanically injured human keratinocyte monolayer. We evaluated different mediators involved in wound repair such as IL-8, TGFbeta, IL-1, COX-2, VEGF and Toll-like receptors 2 and 4 (TLR2 and TLR4). We also studied the effects of bombesin on cell proliferation and motility and its direct effect on wound repair by observing the wound closure after mechanical injury. The involvement of the bombesin receptors neuromedin receptor (NMBR) and gastrin-releasing peptide receptor (GRP-R) was also evaluated. Our data suggest that bombesin may have an important role in skin repair by regulating the expression of healing markers. It enhanced the expression of IL-8, TGFbeta, COX-2 and VEGF. It also enhanced the expression of TLR2, while TLR4 was not expressed. Bombesin also increased cell growth and migration. In addition, we showed that NMBR was more involved in our experimental model compared to GRP-R.

Bombesin and the brain-gut axis.

Bombesin is the first peptide shown to act in the brain to influence gastric function and the most potent peptide to inhibit acid secretion when injected into the cerebrospinal fluid (CSF) in rats and dogs. Bombesin responsive sites include specific hypothalamic nuclei (paraventricular nucleus, preoptic area and anterior hypothalamus), the dorsal vagal complex as well as spinal sites at T9-T10. The antisecretory effect of central bombesin encompasses a variety of endocrine/paracrine (gastrin, histamine) or neuronal stimulants. Bombesin into the CSF induces an integrated gastric response (increase in bicarbonate, and mucus, inhibition of acid, pepsin, vagally mediated contractions) enhancing the resistance of the mucosa to injury through autonomic pathways. The physiological significance of central action of bombesin on gastric function is still to be unraveled.

Regulation of ingestion by CRF and bombesin-like peptides: distinct meal-related peptide level changes.

Bombesin (BN) and corticotropin-releasing factor (CRF) have both been shown to induce satiety in rats when injected centrally. The present study assessed temporal changes in the utilization of BN- and CRF-like peptides in relationship to feeding status, fluctuations that may indicate the physiological participation of these peptides in the regulation of feeding. Alterations in the endogenous levels of CRF- and BN-like peptides associated with the initial spontaneous meal of the nocturnal cycle were determined in 15 hypothalamic and extrahypothalamic brain nuclei in the following three groups of rats: 1) a preprandial group consisting of rats killed before feeding, 2) a prandial group consisting of rats killed during the meal, and 3) a postprandial group consisting of rats killed 8-12 min after the meal. Findings revealed site-specific changes in BN and CRF content during the course of a meal. During ingestion, levels of BN were significantly elevated at the paraventricular, arcuate, and dorsomedial nuclei of the hypothalamus and reduced at the nucleus accumbens. In the case of CRF, feeding-related alterations were observed at the lateral (LH) and ventromedial (VMH) hypothalamic nuclei and at the central nucleus of the amygdala (Ce). At the LH, CRF content decreased after feeding compared with preprandial levels. At the VMH, CRF levels were significantly elevated both before and after food intake compared with prandial levels. In contrast, at the Ce marked increases in CRF concentrations were observed during ingestion. These data demonstrate, for the first time, site-specific fluctuations of BN and CRF in relationship to the animal's feeding status and suggest that these peptides may play a role in the regulation of food intake.

Physiologic approaches to the control of obesity.

Morbid obesity is a major health problem in this country and throughout the world. In addition to its social stigma (in the western world), obesity exacerbates several disease states such as diabetes, hypertension, cardiac disease and restrictive lung disease. When effective medical treatment of obesity becomes available, it will depend in part upon understanding the physiologic factors that control satiety. This review summarizes the information available on brain and gut control mechanisms of satiety. Brain nuclei located in the lateral hypothalamus, ventromedial hypothalamus, and other paraventricular areas are the sites of action for potent neuropeptides, such as cholecystokinin (CCK) and neuropeptide Y, that appear to regulate feeding. Exogenous CCK has been used clinically to decrease meal size in obese patients. The sites of the satiety cascade that are most often manipulated are the gastric and intestinal phases. Physiologic gastric distension is a potent inhibitor of feeding, whereas the intermeal interval may be regulated by intestinal signals released by food in the gut. Jejunal-ileal bypass has fallen from favor and has been replaced by gastric restrictive procedures that create a small proximal gastric pouch that empties into the small bowel (gastric bypass) or the distal stomach (gastroplasty). These operations rely partially on their ability to produce gastric distension in the proximal gastric pouch at an early stage during a meal. Thus, failure results if the pouch compensates by distending or if the stoma widens with subsequent loss of slow emptying. Improved medical and surgical treatment will be designed to intervene at specific sites of the satiety cascade as knowledge of the physiologic control mechanisms of satiety increases.

[The central nervous system and appetite: possible sites of activity for food intake therapy]. / Sistema nervoso centrale e appetito: possibili siti d'azione per una terapia dell'assunzione di cibo.

Recent progress in the field of neurochemical and neuropharmacological research into food intake control by the central nervous system is discussed. Particular emphasis is laid on the fundamental role played by the hypothalamus as the integration centre for the various afferent impulses and the processor of behavioural patterns aimed at the quest for, and ingestion of food. Physiopathological knowledge of central appetite regulation mechanisms is essential for the understanding of the aetiopathogenesis of many clinical forms of human obesity and is the best basis for decisions on the pharmacological and behavioural approach to the treatment of this disease.