Neuronal histamine in the hypothalamus suppresses food intake in rats

Using probes to manipulate hypothalamic neuronal histamine, we report here that changes in neuronal histamine modulate physiological feeding behavior in rats. Infusion of α-fluoromethylhistidine (FMH), a “suicide” inhibitor of histidine decar☐ylase (HDC), into the third cerebroventricular induced feeding in the early light phase when the histamine synthesis was most accelerated. FMH at an optimum 2.24 μmol dose elicited feeding in 100% of rats. Treatment of FMH specifically and selectively decreased concentration of histamine without affecting concentrations of catecholamines in the hypothalamus. Immediately before the dark phase, when the histamine synthesis was normally lower, FMH infusion did not affect feeding-related parameters such as meal size, meal duration or latency to eat. Conversely, thioperamide, which facilitates both synthesis and release of neuronal histamine by blocking presynaptic autoinhibitory H₃ receptors, significantly decreased food intake after infusion of a 100-nmol dose into the third cerebroventricle. The effect of thioperamide was abolished with i.p. injection of 26 μmol/kg chlorpheniramine, an H₁ antagonist. FMH at 224 nmol was microinfused bilaterally into the feeding-related nuclei in the hypothalamus. The ventromedial nucleus (VMH) and the paraventricular nucleus (PVN), but not the lateral hypothalamus, the dorsomedial hypothalamus or the preoptic anterior hypothalamus were identified as the active sites for the modulation. Neuronal histamine may convey suppressive signals of food intake through H₁ receptors in the VMH and the PVN with diurnal fluctuation.     

GABA-related feeding control in genetically obese rats

Feeding in response to glucoprivation induced by 2-deoxy-D-glucose (2-DG) is impaired in genetically obese (Zucker) rats. Muscimol, a GABAA-agonist (0.5 nmol/0.5 microliter in each area) increased food intake in lean rats over 3 h but in fatty rats only at 30 min after infusion into the VMH. Injection of muscimol into the DMH and PVN increased feeding of both phenotypes. Picrotoxin, a non-competitive GABAA-antagonist (0.1 nmol/0.5 microliter) increased food intake after infusion into the LH of both phenotypes and decreased food intake over a 3 h period when infused into the VMH. DMH and PVN of fatty rats. In the lean littermates, picrotoxin was only effective in reducing food intake at 30 min after infusion into the VMH and PVN but not the DMH. The present results suggest that the fatty Zucker rat has a disturbance in the GABA-related regulatory mechanism of feeding behavior in the ventromedial hypothalamus, which may be responsible for the impaired response to glucoprivation found in these rats.     

Phaseolus vulgaris leuco-agglutinin tracing of intrahypothalamic connections of the lateral, ventromedial, dorsomedial and paraventricular hypothalamic nuclei in the rat

Intrahypothalamic connections of the lateral (LHA), ventromedial (VMH), dorsomedial (DMH) and paraventricular (PVN) hypothalamic nuclei were studied with anterograde transport of iontophoretically injected Phaseolus vulgaris leuco-agglutinin and the immunocytochemical detection of labeled structures. The LHA was found to give rise to a minor projection in the VMH, whereas the VMH in reverse maintains few connections with the ventromedial part of the tuberal LHA. Tracer deposits in both the LHA and VMH resulted in anterograde terminal labeling in the DMH. The DMH, in turn, donates a small number of projections to the LHA and VMH. The main projection of the DMH is aimed at the parvocellular paraventricular nucleus. Direct outflow pathways from the VMH to the PVN were not found, but lectin injections in the LHA on the other hand gave rise to terminal labeling in both the parvocellular and magnocellular divisions of the PVN. The PVN in turn was found to give only minor reciprocal projections to the LHA, DMH and VMH. These findings indicate that the main stream of connections in the hypothalamus runs from the LHA and VMH to the DMH, and from the DMH to the PVN. The identified circuitry patterns were discussed with respect to the role of the hypothalamus in the control of homeostasis and metabolic regulation, and more specifically in relation to the modulation of the hormone release from the pancreas and adrenal glands.     

NMDA receptors in the medial prefrontal cortex and the dorsal hippocampus regulate methamphetamine-induced hyperactivity and extracellular amino acid release in mice

The cerebellar fastigial nucleus (FN), together with the interpositus nucleus (IN), constitutes the two final output nuclei of the spinocerebellum and plays an important role in body and limb movements. Previous studies have revealed a direct histaminergic projection from the hypothalamus to the cerebellar nuclei and an excitatory effect of histamine on the IN neurons. However, role of hypothalamic histaminergic projection in the FN has been still little known. Here we show that histamine elicited the FN neurons of rats a concentration-dependent excitatory response in vitro. The histamine-induced excitation on FN neurons was mediated by postsynaptic histamine H₂ rather than H₁ receptors. In behavioral tests, microinjection of histamine into bilateral FNs remarkably improved motor performances of rats on both accelerating rota-rod and balance beam. Selective H₂ receptor antagonist ranitidine considerably declined those motor performances and selective H₂ receptor agonist dimaprit mimicked the facilitation effect of histamine on the movements. But selective H₁ receptor antagonist triprolidine and agonist 2-pyridylethylamine had no effect. Furthermore, microinjection of histamine into bilateral FNs narrowed stride width of footprint but did not influence wire suspension, whereas microinjection of histamine into bilateral INs increased stride length and promoted suspension. These results demonstrate that histamine enhances rat motor balance and coordination through modulation of both proximal and distal muscles by activation of histamine H₂ receptors in the cerebellar FN and IN, and suggest that the hypothalamocerebellar histaminergic projections may modulate the final outputs of the spinocerebellum and participate in the cerebellum-mediated motor control.     

Effects of intracerebroventricularly infused histamine and selective H1, H2 and H3 agonists on food and water intake and urine flow in Wistar rats

The actions of intracerebroventricularly infused histamine and selective histamine H₁, H₂ and H₃ receptor agonists on food and water intake and urine flow were studied in rats. It was found that 100–800 nmoles of histamine significantly suppressed feeding. The H₁ agonist 2-(3-trifluoromethylphenyl)histamine (FMPH) decreased food intake, whereas the H₂ agonist dimaprit was without effect. Histamine- and FMPH-induced suppressions of feeding were attenuated by blockade of H₁ but not by H₂ receptors. The results clearly demonstrate that activation of brain H₁ receptors decreases food intake. In subsequent studies, we found that both metoprine and thioperamide, which increase histaminergic activity through different mechanisms, also reduced food intake. This finding indicates that the brain histaminergic system is associated with feeding behavior. The same is true with body water homeostasis. Histamine caused a long-lasting diuresis. Also dimaprit and metoprine increased urine flow and the blockade of H₂ receptors abolished the diuretic responses to histamine and dimaprit. On the other hand, the H₃ agonist (R)-α-methylhistamine elicited drinking and this effect could be prevented by thioperamide pretreatment. The results imply that activation of H₃ receptors predominantly provokes drinking, whereas central H₂ receptors mediate the diuretic effect of histamine.     

Opioid-induced feeding: Localization of sensitive brain sites

These experiments were designed to identify brain sites at which opioids might act to influence ingestive behavior and to determine which opioid receptor types are involved. After food deprivation, rats were given microinjections of naloxone into several brain regions and food intake was measured. Injections into or near the paraventricular (PVN) or ventromedial (VMH) hypothalamic nuclei or the globus pallidus (GP) reduced food intake; injections into the striatum or lateral hypothalamus (LH) were ineffective. A second study examined the ingestive effects of roughly equimolar doses (1.43-1.75 nmol) of dynorphin A (DYN), beta-endorphin (beta-END), and D-Ala2,D-Leu5-enkephalin (DADLE) when injected into 4 different brain regions. Only DYN significantly increased food intake, and this effect was seen only with injections into the PVN and VMH. Beta-END stimulated water intake when injected into the PVN, VMH and GP but not the LH. Further studies indicated that with PVN injections, DYN was effective at a dose as low as 0.47 nmol, and that a higher dose of DADLE (4.39 nmol) did stimulate food intake. These studies support an important role for dynorphin and the kappa opioid receptor in the regulation of feeding and suggest that the opioid regulation of food and water intake can be differentiated both by sites of action and by effective agonists.     

Opposite dopaminergic activity in lateral and median hypothalamic nuclei in relation to the feeding effect ofd-Ser-Leu-Enk-Thr (DSLET)

The Leu-enkephalin analogue D-Ser2-Leu-Enk-Thr6 (DSLET) had been shown to enhance feeding in rats, increase dopaminergic activity in the striatum like other opiate agonists, and particularly to decrease dopaminergic activity in the hypothalamus. In this study, the latter effect was found to be localized in the hypothalamic nuclei involved in the regulation of feeding such as the paraventricular (PVN), ventromedian (VMH), dorsomedian (DMH) nuclei and the lateral hypothalamus (LH). DSLET produced the same decrease in dopaminergic activity in the LH as in the whole hypothalamus. In the median nuclei (PVN and VMH and to a lesser extent in the DMH), an opposite effect was observed, resembling that in the striatum. The relevance of these opposite variations with regard to the feeding effect of DSLET is discussed. The decreased dopaminergic activity in the LH would appear to be the most specifically related to the behavioural effect given the known role of dopamine in this region. These data reconcile apparently contradictory aspects of the role of dopamine and the functional opposition between the lateral and median hypothalamus in food intake control.     

Histaminergic control of energy balance in rats

Manipulating neuronal histamine in the hypothalamus, its effects on brain functions were assessed in nonobese normal rats and Zucker rats. Alpha-fluoromethylhistidine (FMH), an inhibitor of histamine synthesis, induced feeding dose-dependently after 2.24 mumol infusion at 1100 h, when hypothalamic histamine was normally high. This dose of FMH selectively decreased hypothalamic histamine, but not other neurotransmitters. Thioperamide, an antagonist of autoinhibitory H3-receptors, decreased food intake after infusion at 1940 h, when hypothalamic histamine was normally low. Bilateral microinfusion of 224 nmol FMH or 26 nmol chlorpheniramine, an H1-antagonist, into the ventromedial hypothalamus (VMH) and the paraventricular nucleus (PVN), elicited feeding. However, Zucker obese rats showed no significant responses to chlorpheniramine, thioperamide or histamine. Concentration of their hypothalamic histamine was excessively lower than that of the nonobese. Contents of hypothalamic histamine were lowered at 4 degrees C and raised at 31 degrees C. FMH attenuated increase in histamine, and then disrupted adaptive behavior. These findings indicate that neuronal histamine may convey the suppressive signal of food intake through H1-receptors in the VMH and/or the PVN, and play critical roles in homeostatic control of adaptive behavior.     

Central control of gastric acid secretion by extralateralhypothalamic nuclei

Whether secretion of gastric acid (GAS) is in response to peripheral and/or central administration of chemical or electrical stimuli can be differentiated by vagotomy. GAS has been shown to be controlled by specific lateral hypothalamic (LHA) neurons. Application of 2-deoxy-D-glucose (2-DG) or insulin to the LHA by microinjection or iontophoresis has experimentally induced GAS. The paraventricular nucleus (PVN) has now been found to also affect GAS. GAS was produced more copiously and more quickly by rostral PVN lesion than by lesion of the ventromedial (VMH) or dorsomedial (DMH) nucleus, and nearly as much by caudal PVN lesion. Microinjection of 2-DG into the LHA induced GAS more potently in animals with rostral PVN lesions than in those with caudal PVN, VMH or DMH lesions, or in intact animals. Results indicate that the PVN may be an additional central site from which GAS is affected.     

Histamine H1 receptors in the brain and spinal cord of the cat

The regional distribution of histamine H₁ receptors in the feline brain and spinal cord was determined in vitro using the radio-actively labeled histamine H₁ antagonist, [³H]pyrilamine. This distribution of H₁ receptors, which was different from that reported for other species, was highest in the hypothalamus and mammillary bodies. Intermediate levels of binding were observed in the cerebral cortical and limbic regions, corpus striatum, colliculi, cerebellum, and medulla. The lowest binding was found in the pons and spinal cord. Binding in the spinal cord was concentrated in the gray matter, but the number of binding sites detected in the dorsal and ventral horns did not differ. The equilibrium dissociation constants for [³H]pyrilamine were similar for the various regions and were in the range of 2–3 nM and the pharmacological characteristics of the feline brain and spinal H₁ receptors were similar to those found in the brains of other mammalian species with the exception of the guinea pig.     

Cognitive domains affected by histamine H1-antagonism in humans: A literature review

The neurotransmitter histamine has been suggested to be involved in cognitive functioning. Generally, studies in animals have shown a decrease in performance after decreasing histamine neurotransmission and improved performance after increasing histamine neurotransmission. It is unclear, however, what role histamine plays in cognition in humans. Up until now, most data are derived from studies and reviews that aimed to assess the sedative potential of H₁-antagonists and not the effects on cognition in particular. The objective of this paper is specifically to review which cognitive domains are affected by H₁-antagonists. Taken together, 90 experimental studies on the performance effects of sedative H₁-antagonists published between 1973 and 2009 were reviewed. Results showed that psychomotor skills and attention are most frequently impaired and memory the least. Tasks assessing memory that were affected usually required rapid responses. It was concluded that both the complexity of the task as well as the demand for information processing speed determines the sensitivity to the effects of central H₁-antagonism. The importance of the sensitive cognitive domains to histaminergic dysfunction, as well as the relation between histamine related decrease in arousal and task performance deserve further research.     

Hippocampal histamine receptors: Possible role on the mechanisms of memory in the rat,II

Summary In this paper it was studied the role of histamine and histamine receptors in the hippocampus of rats on an active avoidance response induced by an ultrasonic tone. The animals had to learn to walk through a swinging door into a safe compartment only after the conditioning ultrasonic tone was on in order to avoid an electric shock to their feet. Trained animals were implanted in the ventral hippocampus with microinjection cannulae and injected twice with 1 l of saline solution containing pyrilamine (PYR, H₁-HA antagonist), ranitidine (RAN, H₂-HA antagonist) or histamine. The histamine antagonists were applied in a dose of 65.5 nmol each while histamine was administered in a dose of 45 nmol. The two variables measured were the time in sec the rats take to present the conditioned avoidance response and the accumulated percentage of conditioned avoidance response (CAR). Results showed that histamine administration significantly increased the latency time to escape and decreased the % CAR. These effects were not blocked by the administration of RAN. However, administration of PYR completely counteracted the HA effects. Present findings confirm our previous findings about the inhibitory effect of histamine on the hippocampal retrieval mechanisms and give further support to the hypothesis that HA acts on the memory processes in the hippocampal formation, by activation of H₁-histamine receptors.     

Anorexic action of a new potential neuropeptide Y antagonist [d-Tyr, d-Thr]-NPY (27–36) infused into the hypothalamus of the rat

Neuropeptide Y (NPY) produces a vigorous feeding response in several species when it is injected into hypothalamic structures involved in eating behavior. The purpose of this study was to determine whether a unique carboxy terminal fragment of NPY would alter the pattern of eating induced in the rat either by NPY injected into the hypothalamus or by a 24-h period of food deprivation. In this case, two l-tyrosine residues and one t.-threonine residue of the NPY_27–36 fragment were transformed to their D-conformation to produce [d-Tyr^27,36,d-Thr³²]-NPY (27–36), i.e., D-NPY_27–36. Guide cannulae for microinjection were implanted stereotaxically just dorsal to the paraventricular nucleus (PVN) or ventromedial hypothalamus (VMH) of 24 adult male Sprague-Dawley rats. Following postoperative recovery, a microinjection of artificial CSF or 1.1 jig or 3.3 μg of a peptide was made directly into the PVN or VMH as follows; native NPY; D-NPY_27–36; or [L-Tyr^27,36 L-Thr³²]-NPY (27–36), i.e., L-NPY_27–36. Food intakes were measured at intervals of 0.25, 0.5, 1.1, 2.0, 4.0, and 24 h. When D-NPY_27–36 was microinjected at NPY reactive sites in the PVN or VMH of the rat 15 min before a similar microinjection of NPY, the intense eating response induced by the peptide was reduced significantly. Not only was the effect dose dependent, but D-NPY_27–36 also augmented the latency to feed. A mixture of the two doses of NPY and DNPY_27–36 injected at the same hypothalamic loci did not attenuate the intake of food but tended to enhance the feeding response in the rats. After the rats were deprived of food for 24 h, D-NPY_27–36 microinjected in the same hypothalamic sites similarly caused a dose-dependent suppression of normal feeding behavior. However, the CSF control vehicle and L-NPY_27–36 microinjected in the PVN or VMH were without effect on the pattern of eating. Further, D-NPY_27–38 injected in the same hypothalamic sites affected neither body temperature nor water intakes of the rats significantly. These results demonstrate that the D substitution of this C-fragment of the NPY molecule, i.e., D-NPY_27–36, serves to inhibit feeding evoked in the rat by hypothalamic NPY as well as the natural eating response to food deprivation. Thus, the D-NPY_27–36 molecule may act as an antagonist at one or more subtypes of the NPY receptor in the brain of the rat.     

Anorexic action of a new potential neuropeptide Y antagonist [ -Tyr, -Thr]-NPY (27–36) infused into the hypothalamus of the rat

Neuropeptide Y (NPY) produces a vigorous feeding response in several species when it is injected into hypothalamic structures involved in eating behavior. The purpose of this study was to determine whether a unique carboxy terminal fragment of NPY would alter the pattern of eating induced in the rat either by NPY injected into the hypothalamus or by a 24-h period of food deprivation. In this case, two -tyrosine residues and one t.-threonine residue of the NPY_27–36 fragment were transformed to their D-conformation to produce [ -Tyr^27,36, -Thr³²]-NPY (27–36), i.e., D-NPY_27–36. Guide cannulae for microinjection were implanted stereotaxically just dorsal to the paraventricular nucleus (PVN) or ventromedial hypothalamus (VMH) of 24 adult male Sprague-Dawley rats. Following postoperative recovery, a microinjection of artificial CSF or 1.1 jig or 3.3 μg of a peptide was made directly into the PVN or VMH as follows; native NPY; D-NPY_27–36; or [L-Tyr^27,36 L-Thr³²]-NPY (27–36), i.e., L-NPY_27–36. Food intakes were measured at intervals of 0.25, 0.5, 1.1, 2.0, 4.0, and 24 h. When D-NPY_27–36 was microinjected at NPY reactive sites in the PVN or VMH of the rat 15 min before a similar microinjection of NPY, the intense eating response induced by the peptide was reduced significantly. Not only was the effect dose dependent, but D-NPY_27–36 also augmented the latency to feed. A mixture of the two doses of NPY and DNPY_27–36 injected at the same hypothalamic loci did not attenuate the intake of food but tended to enhance the feeding response in the rats. After the rats were deprived of food for 24 h, D-NPY_27–36 microinjected in the same hypothalamic sites similarly caused a dose-dependent suppression of normal feeding behavior. However, the CSF control vehicle and L-NPY_27–36 microinjected in the PVN or VMH were without effect on the pattern of eating. Further, D-NPY_27–38 injected in the same hypothalamic sites affected neither body temperature nor water intakes of the rats significantly. These results demonstrate that the D substitution of this C-fragment of the NPY molecule, i.e., D-NPY_27–36, serves to inhibit feeding evoked in the rat by hypothalamic NPY as well as the natural eating response to food deprivation. Thus, the D-NPY_27–36 molecule may act as an antagonist at one or more subtypes of the NPY receptor in the brain of the rat.     

Effects of hypothalamic lesion on pancreatic autonomic nerve activity in the rat

The effects of hypothalamic lesions and intravenous glucose infusion on the efferent activity of vagal and splanchnic nerves to the pancreas were studied in anesthetized rats. Lesions of the ventromedial hypothalamic (VMH), the dorsomedial hypothalamic (DMH) and the paraventricular (PVN) nuclei increased vagal and reduced splanchnic nerve activity. Lesion of the lateral hypothalamic area (LHA) decreased pancreatic vagal nerve activity, and produced either increased or decreased activity of pancreatic splanchnic nerve. Intravenous glucose infusion increased activity of the vagal nerve and reduced that of the splanchnic nerve. These glucose responses were influenced by hypothalamic lesions only slightly or not at all. The findings suggest that hypothalamic modulation of pancreatic hormone secretion involves both the parasympathetic and sympathetic nervous systems, and provide evidence that not only the VMH and the LHA but also the DMH and the PVN are involved in this mechanism.     

Hypothalamic stimulation induces vagally mediated hypocalcemia in the rat

A hypothalamo-vagal mechanism of immobilization (IMB) stress-induced hypocalcemia was investigated in rats. Bilateral lesions in the Ventromedial nucleus of the hypothalamus (VMH), but not those of the lateral hypothalamic area (LHA) or the paraventricular nucleus (PVN), eliminated the calcium-lowering effect of IMB. None of these lesions, however, affected the basal levels of the blood calcium. An electrical stimulation of the VMH induced a significant decrease in the blood calcium level (0.07 mM fall) 60 min after stimulation. The hypocalcemic response was eliminated by a vagotomy of the gastric branches but not by that of the thyroid/parathyroid branches. These results suggest that the VMH mediates IMB-induced hypocalcemia through its influence on the gastric vagus.     

Hypothalamic neuronal histamine modulates ad libitum feeding by rats

Manipulating histamine endogenously, its effects on brain functions were assessed in rats. alpha-Fluoromethylhistidine (FMH), an inhibitor of histamine synthesis, elicited feeding (P less than 0.01) after intra-third cerebroventricular infusion at the early light phase when hypothalamic histamine was normally highest. No periprandial drinking was observed. The effect of FMH was attenuated, and thioperamide, an antagonist of auto-inhibitory effects on both histamine synthesis and release at presynaptic H3-receptor, conversely suppressed food intake (P less than 0.05), when these probes were carried out during the minimum histamine level early in the dark period. Bilateral microinfusion of FMH into the ventromedial hypothalamus (VMH) and the paraventricular nucleus (PVN) selectively induced feeding, but the infusion into the remaining sites of the hypothalamus had no effect. These data show that neuronal histamine plays a physiological role in feeding suppression through the VMH and the PVN in the rat.     

Efferent projections from the paraventricular nucleus mediating α2-noradrenergic feeding

Feeding behavior elicited by central injection of the α-noradrenergic agonists, norepinephrine (NE) and clonidine (CLON), are believed to be mediated via postsynapticα₂-type receptors located in the paraventricular nucleus (PVN). To map the course taken by essential efferent (descending) fibers of this PVN system for noradrenergically-stimulated feeding, the impact of diencephalic and lower brainstem coronal knife cuts, on the responses elicited by PVN-injected NE and CLON, was assessed. Rats that sustained damage in the periventricular gray area of the caudal thalamus and midbrain exhibited significant losses in feeding elicited by PVN injections of these drugs. In the case of animals with midbrain periventricular gray knife cuts, a significant increase in daily food intake was also observed, and this increase was positively correlated in magnitude with the attenuation of NE-induced feeding. This decrease in sensitivity toα₂-noradrenergic stimulation occurred with discrete periventricular knife cuts extending only 0.5 mm lateral to midline. In contrast, large ventral or lateral coronal knife cuts throughout the dorsal and ventral midbrain tegmentum left intact NE- and CLON-induced feeding. These findings provide evidence for localization of anatomical substrates which underlie PVNα₂-noradrenergic feeding. The efferent fibers of this system appear to exit from the PVN in a dorsomedial direction and course through the thalamic periventricular area. As this projection descends into the midbrain, it remains quite medial, maintaining this position throughout the midbrain central gray substance. At the level of the pons, just rostral to the locus coeruleus, this fiber projection appears to course ventrolaterally into the dorsolateral pontine tegmentum and possibly continue towards the dorsal vagal complex of the dorsomedial medulla.     

NOS isoenzyme content in brain nuclei as related to food intake in experimental cancer cachexia

Evidence implies that nitric oxide (NO) in the central nervous systems mediates anorexia in tumor-bearing hosts. We have therefore evaluated, by immunohistochemical image analyses, net alterations of nitric oxide synthases (nNOS, eNOS, iNOS) in brain nuclei [paraventricular hypothalamic nucleus (PVN), medial habenular nucleus (MHB), lateral habenular nucleus (LHB), paraventricular thalamic nucleus (PV), lateral hypothalamic area (LHA), ventromedial hypothalamic nucleus (VMH), nucleus of the solitary tract (NTS)] of tumor-bearing mice (TB) with prostanoid-related anorexia. Pair-fed (PF) and freely fed (FF) non-tumor-bearing mice were used as controls. c-fos was analyzed as indicator of neuronal activation. nNOS was significantly increased in VMH and PVN from TB mice, while eNOS was significantly increased in LHB and LHA. iNOS was significantly increased in LHA and PVN nuclei, but decreased in MHB, LHB and VMH from tumor-bearers. However, several of these alterations were similarly observed in brain nuclei from pair-fed controls. Provision of unspecific NOS-antagonists to TB mice increased nNOS, eNOS and iNOS in several brain nuclei (PVN, LHA, VMH), but left tumor-induced anorexia unchanged. c-fos was significantly increased in all brain nuclei in PF mice except for NTS, LHA and PVN compared to controls, while tumor-bearing mice had increased c-fos in LHA and PVN only compared to controls. Our results demonstrate a complex picture of NOS expression in brain areas of relevance for appetite in tumor-bearing hosts, where most changes seemed to be secondary to stress during negative energy balance. By contrast, NOS content in PVN and LHA nuclei remains candidate behind anorexia in tumor disease. However, nitric oxide does not seem to be a primary mediator behind tumor-induced anorexia. NO may rather secondarily support energy intake in conditions with negative energy balance.