Matching salt intake to physiological need in rats using foraging protocols

Several studies of the quantitative relationship between sodium need and sodium intake in rats are reviewed. Using acute diuretic treatment 24 h beforehand, intake matches need fairly accurately when intake is spread out in time by using a hypotonic solution of NaCl. In contrast, using a hypertonic solution, intake is typically double the need. Using the same diuretic treatment, although the natriuresis occurs within ~1 h, the appetite appears only slowly over 24 h. Increased plasma levels of aldosterone parallel the increased intake; however, treatment with metyrapone blocks the rise in aldosterone but has no effect on appetite. Satiation of sodium appetite was studied in rats using sodium loss induced by chronic diuretic treatment and daily salt consumption sessions. When a simulated foraging cost was imposed on NaCl access in the form of a progressive ratio lever press task, rats showed satiation for NaCl (break point) after consuming an amount close to their estimated deficit. The chronic diuretic regimen produced hypovolemia and large increases in plasma aldosterone concentration and renin activity. These parameters were reversed to or toward non-depleted control values at the time of behavioral satiation in the progressive ratio protocol. Satiation mechanisms for sodium appetite thus do appear to exist. However, they do not operate quantitatively when concentrated salt is available at no effort, but instead allow overconsumption. There are reasons to believe that such a bias toward overconsumption may have been beneficial over evolutionary time, but such biasing for salt and other commodities is maladaptive in a resource-rich environment.

Effects of oral preload, CCK or bombesin administration on short term food intake of melanocortin 4-receptor knockout (MC4RKO) mice.

We investigated whether either heterozygous (HET) or homozygous (knockout, KO) disruption of the melanocortin type 4 receptor (MC4R) gene alters post ingestive responsiveness of mice. Specifically, we tested the hypothesis that hyperphagia in MC4RKO mice might be due to a deficit in processes that sustain intermeal intervals (satiety) and/or processes that terminate ongoing episodes of eating (satiation). To test satiety, mice drank an oral preload and then we monitored intake of a subsequent liquid diet test meal. To test satiation, we examined the effect of exogenous administration of cholecystokinin (CCK) and bombesin (BN) on the size of a liquid diet meal. Experiment 1 was comprised of two studies. In the first, we determined that the intake of all three genotypes following fasts of either 6, 12, or 24h were comparable, and so chose 12h deprivation for the subsequent studies. In the second, 12h fasted mice were allowed to consume a fixed preload, approximately 50% of their expected mean intake and, following delays of either 30 or 60 min, were allowed to consume to satiation. Compared with no preload, the preload significantly reduced meal size comparably in all three genotypes. The reduction in intake was greater when the test meal was presented 30 compared with 60 min after the preload, again with no genotype differences in this decay of satiety. In experiment 2, we administered either CCK or BN and examined suppression of meal size after a 12h fast. Mice were tested repeatedly with CCK-8 (2, 6, or 18 microg/kg ip) or BN (2, 4 or 8 microg/kg ip) with vehicle injection days intervening. The 30 min intakes of HET and KO mice were suppressed more than those of WT following either CCK or BN. These experiments suggest that diminished responsiveness to nutrients or gut satiety hormones is not responsible for hyperphagia in MC4RKO mice.

Food motivated behavior of melanocortin-4 receptor knockout mice under a progressive ratio schedule.

Melanocortin-4 receptor knockout (MC4RKO) mice are hyperphagic and develop obesity under free feeding conditions. We reported previously that MC4RKO mice did not maintain hyperphagia and as a result lost weight when required to press a lever to obtain food on a fixed ratio procurement schedule. To assess the generality of this result, we tested MC4RKO mice and their heterozygous and wild type littermates using progressive ratio (PR) schedules that are believed to be sensitive indicators of motivation. Mice lived in operant chambers and obtained all of their food (20mg pellets) via lever press responding. Food was available according to a PR schedule so that within a meal, food became progressively more costly, and we expected this would provide a stringent test of mechanisms controlling meal size. The schedule reset after either 3 or 20min of no responding, so defining meals, and the highest ratio completed before the reset was defined as the breakpoint. The average daily number of meals was lower and mean size of meals was higher at the 20 compared with the 3min reset condition. Mean daily food intake did not differ between the two reset criteria but did differ as a function of genotype, with MC4RKO mice eating about 25% more than heterozygous or wild type mice. Hyperphagia in the MC4RKO mice was characterized primarily by larger meals (higher breakpoints) and they emitted about twice as many responses as wild type mice. Thus, using a PR schedule, MC4RKO mice exhibit hyperphagia, and show a high level of motivation to support large meal sizes.

Cross tolerance between anorectic action and induction of Fos-ir with dexfenfluramine and 5HT1B/2C agonists in rats.

RATIONALE: We have shown that the anorectic effect of dexfenfluramine (DFEN), an agent that acutely increases synaptic availability of serotonin (5-HT), shows complete tolerance after 2-3 prior applications when using acute feeding protocols and low dosages. It is unlikely this is due to either accumulative weight loss or presynaptic 5-HT depletion. In this study, we examined the possible contribution of 5-HT1B/2C receptors to behavioral tolerance by testing for cross tolerance between DFEN and the 5-HT1B/2C receptor agonists, m-chloro- and trifluoromethyl-substituted phenylpiperazines (mCPP and TFMPP). Additionally, we sought neuronal correlates of the behavioral changes by study of the induction of Fos-like immunoreactivity (ir) in discrete brain regions. METHODS: Sprague-Dawley rats received two or three pre-injections, at 2-day intervals, of 2 mg/kg DFEN or vehicle. The rats were then food deprived for 24 h and, 30 min prior to a 1-h feeding test, received a s.c. injection of either DFEN, TFMPP (1 mg/kg), or mCPP (2 mg/kg). Additional groups received mCPP preinjections and test injection of either DFEN or mCPP. Rats in Fos-ir studies received similar injection regimens but were not food deprived and were perfused 1.5 h after the test injection. RESULTS: DFEN-pretreated rats showed complete anorectic tolerance to DFEN, TFMPP, and mCPP. However, rats given this regimen of mCPP pretreatment were tolerant to neither mCPP nor DFEN. Fos-ir induced by DFEN in each brain region examined was either significantly reduced or abolished by prior DFEN injections. TFMPP induced less Fos-ir in these regions than DFEN and this was attenuated by prior DFEN. CONCLUSIONS: The behavioral data indicate that tolerance to DFEN anorexia is mediated partially or completely by functional subsensitivity at 5-HT1B and/or 5-HT2C receptors. The brain regions implicated include the paraventricular hypothalamus, medial striatum, lateral parabrachial nucleus, and nucleus of the solitary tract.

Dexfenfluramine and norfenfluramine: comparison of mechanism of action in feeding and brain Fos-ir studies.

Dexfenfluramine (dF) and dexnorfenfluramine (dNF), its metabolite, are anorectic agents that release serotonin (5-HT) and may have a direct postsynaptic action. The effects on the anorectic effects of dF and dNF of either acute (p-chlorophenylalanine, PCPA) or chronic (5,7-dihydroxytryptamine, 5,7-DHT) brain 5-HT depletions were studied in rats and compared with the actions of a 5-HT uptake inhibitor (fluoxetine) and 5-HT(1B/2C) receptor agonists [1-(3-trifluoromethyl-phenyl)-piperazine and 1-(3-chlorophenyl) piperazine]. The anorexia caused by these agonists was enhanced in rats with 5,7-DHT lesions, possibly a result of receptor supersensitivity. In contrast, fluoxetine anorexia was somewhat reduced in one study and was unchanged in a second. Both dF and dNF anorexias were enhanced in rats with 5,7-DHT lesions. In contrast, the anorectic effects of either dF or dNF were unchanged in PCPA-treated rats relative to controls. Compared with controls, 5, 7-DHT-lesion rats showed greatly increased dF- and dNF-induced Fos-like immunoreactivity (ir) in the paraventricular (PVN) and supraoptic (SON) hypothalamic nuclei, and in the median preoptic area (MnPO), but were similar to controls in most other areas. PCPA pretreatment increased dF- and dNF-induced Fos-ir in the PVN, SON, and MnPO. In controls, equianorectic doses of dF and dNF induced Fos-ir in similar brain regions, but dNF produced relatively larger effects than dF in SON, PVN, and MnPO. The data are discussed in terms of multiple pathways in the anorectic actions of dF and dNF.

Dietary NaC1 during pregnancy and lactation: effect on brain angiotensin II receptors and behavior.

Female rats were fed diets containing either a basal (0.12%), mid- (1%) or high (3%) level of NaCl during pregnancy and lactation. Plasma aldosterone was elevated approximately 5- and 15-fold in dams fed basal compared with either the mid- or high-NaCl diets at the end of both pregnancy and lactation (Postnatal Day 21), respectively. Dams fed basal diet and killed at the end of lactation had a higher density of angiotensin II receptors in the organum vasculosum laminae terminalis, paraventricular hypothalamus, and median preoptic nucleus than did rats fed either mid- or high-NaCl diets. Other dams, treated identically, were returned to rodent chow (approximately 0.2% NaCl) at the end of lactation for intake tests during the next week. Dams that had received basal diet did not differ from mid-NaCl and high-NaCl groups in sodium appetite induced by either acute sodium depletion or mineralocorticoid administration but showed the lowest spontaneous intake of NaCl solution.

Roles of aldosterone and angiotensin in maturation of sodium appetite in furosemide-treated rats.

When rats are treated with furosemide, there is a rapid natriuresis. However, increased sodium appetite does not occur until some time later. One hypothesis to explain this delay is that increased circulating levels of the hormones of sodium depletion prime or sensitize the brain circuits involved in sodium appetite, perhaps by induction of target gene(s). In the present study, we describe the time course of the temporal maturation of sodium appetite after furosemide treatment and the associated changes in plasma levels of ANG II and aldosterone and in plasma volume. Sodium appetite is modest 3 h after furosemide treatment, is increased after 12 h, and is still larger after 24 h. This pattern is evident with repeated testing. Plasma levels of aldosterone and plasma renin activity are substantially increased 3 h after furosemide treatment, and so the NaCl appetite cannot result simply from progressively increasing levels of these hormones. Furthermore, activation of the subfornical organ and the ventral lamina terminalis, assessed with c-Fos immunocytochemistry, did not differ across these three times. Metyrapone, an inhibitor of adrenal steroid synthesis, was used to examine sodium appetite in the absence of elevations in aldosterone after furosemide treatment. Although metyrapone effectively blocked the increase in aldosterone, it was without effect on the appetite 3 or 24 h after furosemide treatment. Furthermore, elevations of plasma aldosterone by the use of minipumps for several days before furosemide treatment did not prime or potentiate but instead tended to inhibit the induced sodium appetite, despite achieving levels of aldosterone and plasma renin activity typically associated with a robust sodium appetite. Infusions of DOCA gave a similar result. Lastly, minipump infusions of ANG II also did not potentiate sodium appetite. Thus neither addition nor subtraction of these hormones alone influenced sodium appetite under these conditions.

Glossopharyngeal nerve transection eliminates quinine-stimulated fos-like immunoreactivity in the nucleus of the solitary tract: implications for a functional topography of gustatory nerve input in rats.

The relationship between specific gustatory nerve activity and central patterns of taste-evoked neuronal activation is poorly understood. To address this issue within the first central synaptic relay in the gustatory system, we examined the distribution of neurons in the nucleus of the solitary tract (NST) activated by the intraoral infusion of quinine using Fos immunohistochemistry in rats with bilateral transection of the chorda tympani (CTX), bilateral transection of the glossopharyngeal nerve (GLX), or combined neurotomy (DBLX). Compared with nonstimulated and water-stimulated controls, quinine evoked significantly more Fos-like-immunoreactive (FLI) neurons across the rostrocaudal extent of the gustatory NST (gNST), especially within its dorsomedial portion (subfield 5). Although the somatosensory aspects of fluid stimulation contributed to the observed increase in FLI neurons, the elevated number and spatial distribution of FLI neurons in response to quinine were remarkably distinguishable from those in response to water. GLX and DBLX produced a dramatic attenuation of quinine-evoked FLI neurons and a shift in their spatial distribution such that their number and pattern were indiscernable from those observed in water-stimulated controls. Although CTX had no effect on the number of quinine-evoked FLI neurons within subfield 5 at intermediate levels of the gNST, it produced intermediate effects elsewhere; yet, the spatial distribution of the quinine-evoked FLI neurons was not altered by CTX. These findings suggest that the GL provides input to all FLI neurons responsive to quinine, however, some degree of convergence with CT input apparently occurs in this subpopulation of neurons. Although the role of these FLI neurons in taste-guided behavioral responses to quinine remains speculative, their possible function in oromotor reflex control is considered.

Area postrema and the anorectic actions of dexfenfluramine and amylin.

The present study examined whether the area postrema and adjacent nucleus of the solitary tract (AP/NTS) is necessary for the expression of anorexia to two classes of anorectic agent. The first agent is the serotonergic agonist, dexfenfluramine (DFEN) and the second is the pancreatic peptide, amylin. Rats were prepared with either aspiration lesions of the AP/NTS or a sham operation. Rats with such lesions (APX) displayed normal anorexia following administration of DFEN, but the anorectic effect of amylin was completely eliminated. The magnitude of a conditioned flavor aversion to DEN was similar in APX and sham operated controls but, unlike controls, APX rats did not reduce total intake in the two-bottle preference test. Finally, the induction of Fos-like immunoreactivity (Fos-ir) following either DFEN or amylin was examined in both APX and sham operated groups. Both agents induced Fos-ir in the AP and/or NTS of sham operated rats, and this region was entirely absent in the APX rats. DFEN-induced Fos-ir was reduced greatly in the PVN of APX rats, but appeared normal in several other regions surveyed, including the central nucleus of the amygdala and the dorsal striatum. In contrast, amylin-induced Fos-ir was reduced in many rostral brain regions of APX rats. These data indicate that neither the anorexia nor the flavor aversion that are produced by DFEN are dependent upon the AP, and in particular that Fos-ir induced by DFEN in the LPBE is not due to afferents from the AP/NTS. In contrast, the anorectic effect of amylin seems to be due principally to its direct action at the AP/NTS.

Expression of Fos immunoreactivity in rat brain during dehydration: effect of duration and timing of water deprivation.

Water deprivation induces expression of the immediate early gene c-fos in specific brain regions, most likely as a result of the activation of cells that are responsive to changes in osmolality and/or blood volume. We hypothesized that the magnitude of c-fos expression would be a function of both the duration of water deprivation and the time of day at which the deprivation started. This study was designed to examine the pattern of Fos-like immunoreactivity (FLI) following water deprivation in rats under normal light/dark conditions (nLD) and reverse light/dark conditions (rLD). Rats were deprived of water but not food either for 0, 5, 16, 24 or 48 h. As expected, hematocrit ratio (HCT), osmolality (OSM), plasma renin activity (PRA) and weight loss increased as a function of duration of water deprivation. In non-deprived rats (0 h), very little FLI was observed in most brain regions. The number of cells showing FLI increased with duration of water deprivation in the supraoptic nucleus (SON), paraventricular nucleus (PVN), organum vasculosum laminae terminalis (OVLT), median preoptic nucleus (MnPO) and subfornical organ (SFO) in both nLD and rLD conditions. However, the pattern of FLI differed between nLD and rLD conditions. Compared to corresponding nLD groups after 5 or 24-h water deprivation, rLD groups had significantly more FLI in SON and PVN, and higher PRA and HCT. Also, weight loss and FLI in the MnPO were greater after 5 h, and FLI in the SFO was greater after 24 h under rLD compared to nLD conditions. Our findings indicate that the magnitude of c-fos expression, and change in weight and plasma parameters were a function of both the duration of water deprivation and the time of day at which the deprivation started. This may result from ingestion of food early in the deprivation periods during the rLD tests, thus producing greater change in osmolality and blood volume.

Central injection in rats of alpha-melanocyte-stimulating hormone analog: effects on food intake and brain Fos.

Lateral cerebroventricular (LCVT) administration of the alpha-MSH agonist analog Nle4DPhe7alpha-MSH (NDP-MSH) inhibited food intake in food-deprived rats, but did not inhibit water intake in water-deprived rats. When NDP-MSH was administered into the fourth ventricle (4CVT), comparable suppressions of food intake were observed. LCVT and 4CVT administration of NDP-MSH also reduced spontaneous 24 h food intake. LCVT injection of NDP-MSH greatly attenuated food intake stimulated in sated rats by acute CVT administration of neuropeptide Y (NPY). These and other data suggest that alpha-MSH is an important endogenous regulator of food intake, possibly acting downstream of NPY. In an attempt to assess further the sites of action of NDP-MSH, a qualitative mapping study of Fos-like immunoreactive (Fos-ir) neurons was performed following LCVT administration of NDP-MSH. LCVT injection of NDP-MSH induced Fos-ir in several forebrain regions including cortex, striatum, bed nucleus of the stria terminalis, paraventricular nucleus of the hypothalamus and arcuate nucleus. The combination of NPY and NDP-MSH did not produce obvious antagonism or cancellation of effects in any region examined. Thus, the site(s) of action of NDP-MSH on food intake remain to be clarified.

Comparison of Fos induced in rat brain by GLP-1 and amylin.

The patterns of Fos-like immunoreactivity (Fos-ir) in rat brain were compared following treatment of rats with two anorectic 'gut' peptides. Central administration of GLP-1 produced dose-related increases in Fos-ir in the area postrema (AP) and caudal nucleus of the solitary tract (cNTS) as well as strong activation in the lateral parabrachial nucleus (LPBE), hypothalamic paraventricular nucleus (PVN), bed nucleus of the stria terminalis (BNST) and central nucleus of the amygdala (CeA). At centrally-active doses, peripheral administration of GLP-1 did not induce Fos-ir in brain. In contrast, peripheral administration of amylin produced strong Fos-ir in the AP and cNTS, as well as the BNST and CeA, but not in the PVN. The common activation of the LPB-BNST-CeA by these and other previously-studied anorectics suggest this is an important circuit involved in satiety.

Role of angiotensin in the dipsogenic effect of bradykinin in rats.

We have previously shown that peripheral administration of bradykinin (BK) induces water intake in rats acutely pretreated with captopril, a kininase II inhibitor. We now show that BK-induced drinking is also observed in rats treated chronically with dietary captopril, and that this is reversed by Hoe 140, a BK receptor antagonist. Both acute and chronic captopril in combination with BK caused a large increase in plasma renin activity. Fos-like immunoreactivity (Fos-in used as a marker of cellular activation) was induced by BK + captopril in regions of the brain previously associated with action of angiotensin (Ang) II, including the circumventricular organs and the magnocellular hypothalamic nuclei. However, while water intake induced by peripheral administration of Ang I was potentiated by acute administration of captopril, it was suppressed by chronic captopril treatment. Fos-IR induced in brain by Ang I was not markedly affected by either acute or chronic treatment with captopril. The simultaneous occurrence of potentiated drinking to BK and inhibited drinking to Ang I following chronic treatment with captopril suggest that different mechanisms of action are involved. In order to further examine this possibility, rats were given lesions of the anterodorsal third ventricle region. Lesions that completely abolished the water intake following administration of Ang II only partly attenuated water intake induced by BK + captopril. Further, Fos-IR induced by BK + captopril was only partly (31%) reduced in the supraoptic and paraventricular nuclei of lesioned rats compared with sham operated controls. We suggest that at least two mechanisms, one Ang-related, underlie drinking after BK+captopril.

Losartan inhibition of angiotensin-related drinking and Fos immunoreactivity in hypertensive and hypotensive contexts.

We assessed the ability of acute peripheral administration of the AT-1 receptor antagonist, losartan, to reverse both the water intake and Fos-immunoreactivity (Fos-ir) induced in rats by either peripheral or cerebroventricular (i.c.v.) administration of angiotensin (Ang) II. We compared this with endogenous generation of Ang II during either hypovolemia or hypotension. Relatively low doses of losartan blocked the dipsogenic effect of peripherally administered exogenous Ang II, but a higher dose (20 mg/kg) was needed to block the dipsogenic effect of i.c.v.-administered Ang II. Fos-ir induced by i.c.v. Ang II was attenuated in SFO and SON by 10-20 mg losartan/kg given peripherally, but Fos-ir in the MnPO and PVN was unaffected. These findings suggest that losartan has limited permeability into the brain. We used peripheral losartan to assess the contribution of Ang II to water intake and Fos-ir responses to peripheral injection of either polyethylene glycol (PEG; a colloid that produces non-hypotensive hypovolemia) or isoproterenol (hypotensive agent). Water intakes were unaffected by the higher dose of losartan given s.c. Intraperitoneal injection of EXP 3174, the active metabolite of losartan that may more readily penetrate the blood-brain barrier, inhibited isoproterenol-, but not PEG-induced water intakes. Fos-ir was induced by PEG and isoproterenol in several regions of the brain also activated by Ang II. Fos-ir was greatly attenuated in the SFO by losartan following administration of PEG, but not isoproterenol, and was either unaffected or increased in SON and PVN after either agent. These data suggest that the increased circulating Ang II following PEG or isoproterenol acts at the SFO and is more readily reversible by losartan in normotensive (PEG) than in hypotensive (isoproterenol) states. Non-Ang neural input to the SON and PVN, presumably from baroreceptors, appears to be sufficient to produce strong Fos-ir in these regions, as well as to engage drinking.

Comparison of changes in blood pressure and dipsogenic responsiveness to angiotensin II in male and female rats chronically exposed to cold.

In most forms of experimentally induced hypertension in rats, females develop a less severe form of the disease than males. The objective of the present study was to compare the two genders with respect to the development of cold-induced hypertension. The results of the study indicate that both males and females develop comparable elevations of blood pressure and at approximately the same rate. Thus, the blood pressures of both groups increased significantly within 2 weeks of exposure to cold and reached similar maximal levels by the seventh week. The dipsogenic responsiveness of both groups of cold-exposed rats to acute administration of the peptide hormone, angiotensin II (AngII), was increased to approximately the same extent above that of warm-adapted counterparts, suggesting an increase in the responsiveness to AngII in the brain. To assess this possibility, the induction of the oncogene, cFos, was studied in brain following IV infusion of AngII (333 ng/kg/min). Fos-like immunoreactivity (FLI) was greater (p < 0.01) in subfornical organ, supraoptic and paraventricular hypothalamic nuclei of both cold-exposed groups compared to warm-adapted controls. Thus, both male and female rats have similar elevations of blood pressure as well as increased dipsogenic and FLI responsiveness to administration of AngII during chronic exposure to cold.

Centrally mediated vasodilation of the rat's tail by angiotensin II.

Acute peripheral administration of angiotensin II (AngII) to rats vasodilates the tail and reduces both metabolic rate and body temperature. To assess the role of the brain in these responses to AngII, a discrete lesion was aimed at the subfornical organ (SFO). Such lesions are known to abolish drinking and other responses to circulating AngII. A control group was sham-operated. Following recovery from surgery, dipsogenic responses to administration of AngII (150 micrograms/kg, SC) were tested. All lesioned rats failed to drink. One week later, the changes in colonic (TC) and tail skin (TSK) temperatures were measured following an identical injection of AngII. As reported before, control rats showed a substantial rise in in TSK (maximum rise 2.5 degrees C after 12 min). In contrast, the lesioned rats showed very little rise (0.3 degrees C) in TSK, significantly less than controls. The maximal drop in TC of the control group was slightly more (0.3 degrees C) than that of the lesioned group (0.2 degrees C), but the difference was not significant. The rats were, next, acutely exposed to cold (5 degrees C). Control rats showed a significantly larger decrease in TSK than lesioned rats. Lesions were verified both anatomically and using the functional metric of AngII-induced Fos-like immunoreactivity (Fos-IR). AngII induced strong Fos-IR in the SFO, median preoptic nucleus (MnPO), and in the magnocellular hypothalamic regions of control rats. The lesions ablated the anterior part of the SFO and dorsal MnPO, and greatly attenuated AngII-induced Fos-IR in the magnocellular hypothalamic regions. Thus, there appears to be central (SFO/MnPO) mediation of both the increase in TSK following administration of AngII and the decrease in TSK in the cold.

Expression of Fos in rat brain in relation to sodium appetite: furosemide and cerebroventricular renin.

Two experiments were performed to investigate the relationship between the expression of sodium appetite and the appearance of Fos-like immunoreactivity (Fos-IR) in the brain of rats. In the first experiment, rats were depleted of sodium by treatment with furosemide 24 h prior to sacrifice and without access to either food or sodium solution. Some rats had access to distilled water, and others had no fluids available during the 24 h. All of the furosemide-treated rats showed Fos-IR in both the subfornical organ (SFO) and around the organum vasculosum laminae terminalis (OVLT). Rats with access to distilled water during the depletion period showed no Fos-IR in the supraoptic (SON) or paraventricular hypothalamic nuclei (PVN) and, in parallel behavioral studies, comparably-treated rats consumed only 0.3 M NaCl solution at the end of the 24 h. In rats that had no fluids during the deprivation period, only about one half showed Fos-IR in SON and PVN and, in parallel behavioral studies, comparably treated rats consumed both water and 0.3 M NaCl solution at the end of 24 h. In a second experiment, cerebroventricular administration of renin stimulated short latency intake of 0.3 M NaCl and water. The relative intakes of water and NaCl were comparable at a low dose of renin, but intake of water exceeded that of NaCl after higher doses. Renin induced Fos-IR in SFO, MnPO, peri-OVLT region, SON and PVN. Both Fos-IR and fluid intake were antagonized by administration of losartan, an angiotensin II type 1 receptor antagonist. Thus, only the circumventricular organs of the lamina terminalis showed Fos-IR during each natriorexigenic regimen in these studies. These data support the view that Ang II of both central and peripheral origin activates the SFO and/or peri-OVLT region and contributes to sodium appetite.

Effect of chronic dexfenfluramine on Fos in rat brain.

The acute appetite suppressant effect of dexfenfluramine (DF) in rats, which may depend upon its action to release serotonin (5-HT) in the brain, often declines with repeated dosing (tolerance). The mechanisms of this tolerance remain unclear. Previously, we used Fos-like immunoreactivity (Fos-IR) to map potential brain sites activated by single injections of DF in rats. A dose of 5 mg DF/kg activated the central amygdala (CeA), bed nucleus of the stria terminalis (BST), caudate-putamen (CPu), lateral parabrachial nucleus (LPB), nucleus tractus solitarius (NST), frontal cerebral cortex and the parvocellular paraventricular hypothalamic nucleus (PVN). We now report studies using Fos-IR in an attempt to understand which regions might underlie tolerance to the action of DF. Pretreatment of rats with an escalating dosage regimen of DF (0.5-4 mg/kg, i.p.) was associated with complete loss of Fos-IR to a probe dose (5 mg DF/kg) in the cortex, CPu, PVN and NTS, and partial loss of Fos-IR in the BST, CeA and LPB. Second, repeated treatment with DF (2 mg/kg), which has been shown to produce tolerance the anorexia caused by DF but not cholecystokinin (CCK), likewise reduced Fos-IR induced in the above brain regions, but had no effect on Fos-IR induced by either CCK or the 5-HT agonist, 5-carboxamidotryptamine. Third, repeated treatment with 5-HT (2 mg/kg, s.c.) had no effect on Fos-IR induced by a probe dose of DF. These data show that regionally heterogeneous hyporesponsiveness to the induction of Fos by DF develops after repeated low doses of DF; however, the Fos response to other putative anorectics or weight reducing agents is not affected. This may be related to behavioral tolerance.

Peripherally and centrally administered bombesin induce Fos-like immunoreactivity in different brain regions in rats.

Bombesin (BBS) suppresses food intake when administered either peripherally or centrally to rats, but the brain systems involved in the anorectic action remain unclear. We addressed this question by examining Fos-like immunoreactivity (Fos-IR), a marker of neuronal activation, in rat brain following either intraperitoneal (i.p.) or 4th cerebroventricular (4V) administration of BBS. It was found that the hypothalamic paraventricular nucleus showed strong Fos-IR following either i.p. BBS in the dose range 20-80 micrograms/kg, or 4V BBS at a dose of 60 ng/rat. Additionally, different effects of i.p. and 4V BBS were observed in the following regions: (1) a strong Fos-IR was seen in the area postrema (caudal part) only following i.p. but not 4V BBS; (2) while i.p. BBS-induced Fos-IR was almost evenly distributed throughout the medial subdivision of the nucleus of the solitary tract, 4V BBS-induced Fos-IR was much stronger in the rostral part than in the caudal part of this region; (3) although the lateral parabrachial nucleus, the central nucleus of the amygdala and the bed nucleus of the stria terminalis showed strong Fos-IR following both i.p. and 4V BBS, subregional distribution of the Fos-IR was not the same. These sites were previously found to show strong Fos-IR after administration of either cholecystokinin (CCK) or dexfenfluramine (DF), but with different subregional distribution. The Fos-IR pattern induced by i.p. BBS was similar to that induced by CCK, and the Fos-IR pattern induced by 4V BBS was similar to that induced by DF.

Satietin: Fos mapping of putative brain sites of action.

A purified extract of a blood-borne satiety factor, called satietin, was injected into the cerebral ventricles of rats that were either fed ad libitum or were food deprived. The animals were killed 2 h after injection and their brains subsequently sectioned and stained for Fos-like immunoreactivity (Fos-IR) to determine the putative sites of action for satietin in the brain. Fos-IR was induced in only a few locations, the most prominent sites being the bed nucleus of the stria terminalis, the central nucleus of the amygdala, and the parvocellular division of the paraventricular nucleus of the hypothalamus. Each of these areas has previously been implicated in the control of feeding behavior. Sites in the hindbrain that are associated with nausea were devoid of satietin-induced Fos-IR. Finally, these sites of action of satietin show some differences from sites that are prominently activated by other classes of anorectic agents.