Interaction of serotonin and cholecystokinin in the lateral parabrachial nucleus to control sodium intake

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Interaction of serotonin and cholecystokinin in the lateral parabrachial nucleus to control sodium intake

Juliana Irani Fratucci De Gobbi¹, Laurival Antonio De Luca Jr.¹, Alan Kim Johnson², and José Vanderlei Menani¹

¹ Department of Physiology and Pathology, School of Dentistry, Paulista State University (UNESP), 14801 - 903 Araraquara, São Paulo, Brazil; and ² Departments of Psychology and Pharmacology and Exercise Science and the Cardiovascular Center, University of Iowa, Iowa City, Iowa 52242 - 1407

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Serotonin [5-hydroxytryptamine (5-HT)] and CCK injected into the lateral parabrachial nucleus (LPBN) inhibit NaCl and waterintake. In this study, we investigated interactions between 5-HTand CCK into the LPBN to control water and NaCl intake. Male Holtzmanrats with cannulas implanted bilaterally in the LPBN were treatedwith furosemide + captopril to induce water and NaCl intake. BilateralLPBN injections of high doses of the 5-HT antagonist methysergide(4 µg) or the CCK antagonist proglumide (50 µg), alone or combined,produced similar increases in water and 1.8% NaCl intake. Lowdoses of methysergide (0.5 µg) + proglumide (20 µg) produced greaterincreases in NaCl intake than when they were injected alone. The5-HT_2a/2c agonist 2,5-dimetoxy-4-iodoamphetamine hydrobromide(DOI; 5 µg) into the LPBN reduced water and NaCl intake. Afterproglumide (50 µg) + DOI treatment, the intake was not differentfrom vehicle treatment. CCK-8 (1 µg) alone produced no effect.CCK-8 combined with methysergide (4 µg) reduced the effect ofmethysergide on NaCl intake. The data suggest that functionalinteractions between 5-HT and CCK in the LPBN may be importantfor exerting inhibitory control of NaClintake.

5-hydroxytryptamine; proglumide; methysergide; NaCl intake; sodium appetite; angiotensin II

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

THE LATERAL PARABRACHIAL NUCLEUS (LPBN) is an important central site involved in the control of water and NaCl intake in rats(2, 17-21, 23, 24). This structure in the rat lies dorsolateralto the superior cerebellar peduncle in the pons and is reciprocallyconnected with several forebrain areas such as the paraventricularnucleus of the hypothalamus, central nucleus of amygdala, medianpreoptic nucleus (1, 7, 10, 11, 13), and more caudalregions such as the area postrema (AP) and the medial portionof the nucleus of the solitary tract (mNTS) (9, 14, 22).Recent studies have shown that bilateral LPBN injections of methysergide,a serotonergic receptor antagonist, markedly increase NaCl intakeinduced by ANG II administered either intracerebroventricularlyor into the subfornical organ (2, 21). Methysergide injectedbilaterally into the LPBN also increased NaCl intake induced bycombined treatment with the diuretic furosemide (Furo) and theangiotensin converting enzyme inhibitor captopril (Cap) injectedsubcutaneously (21). The injection of 2,5-dimetoxy-4-iodoamphetaminehydrobromide [DOI, a serotonergic 5-hydroxytryptamine (5-HT)_2A/2C-receptoragonist] into the LPBN reduced Furo + Cap-induced NaCl intake(21). Other studies have shown that methysergide injected intothe LPBN increases water and hypertonic NaCl intake induced by24 h of water deprivation or by injection of Furo followed by24 h of sodium-deficient diet (18). Not only 5-HT, but alsoCCK action in the LPBN is involved in the inhibition of waterand NaCl intake. Bilateral injections of proglumide, a CCK-receptorantagonist, into the LPBN increased ANG II and Furo + CAP-induced0.3 M NaCl intake (20).

Serotonin and CCK inhibit food intake (3-5, 8, 15, 29, 30). The reduction of food intake induced by intraperitonealinjection of CCK-8 was antagonized by intraperitoneal injectionof metergoline (a 5-HT-receptor antagonist) (8). Devazepide,a type A CCK-receptor antagonist, injected subcutaneously, significantlyantagonized the reduction in meal size induced by intraperitonealinjection of fenfluramine, an indirect 5-HT agonist, showing areciprocal interaction between 5-HT and CCK (8). To explainthe effects of antagonists and agonists of these two neurotransmitterson food intake, Cooper and Dourish (3) proposed a model ofinterdependence and cooperativity between 5-HT and CCK. The authorssuggested that, in response to food ingestion, both endogenous5-HT and CCK are released. The cooperativity assumption is thatelevated 5-HT release and action tend to increase CCK releaseand action and vice versa. The interdependence assumption is thatboth 5-HT and CCK action at their respective receptors is necessaryfor the normal development of satiety. Pharmacological interventionsthat block either 5-HT or CCK receptors reduce the satiety-inducingeffects of either transmitter. In the present study, we investigatedwhether the model proposed by Cooper and Dourish to control foodintake could also be applied to 5-HT and CCK in the LPBN to inhibitwater and sodiumintake.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Animals. Male Holtzman rats weighing 280-300 g were used. The animals were housed in individual stainless steel cages with free accessto normal sodium diet (Purina Rat Chow), water, and 1.8% NaClsolution. Temperature was maintained at 23 ± 2°C, and humiditywas maintained at 55 ± 10% on a 12:12 light-dark cycle with lightonset at 7:30AM.

Cerebral cannulas. Rats were anesthetized with tribromoethanol (200 mg/kg of body wt) and placed in a Kopf stereotaxic instrument. The skullwas leveled between bregma and lambda. Stainless steel 23-gaugecannulas were implanted bilaterally into the LPBN using the followingcoordinates: 9.5 mm caudal to bregma, 2.2 mm lateral to the midline,and 4.1 mm below the dura mater. The tips of the cannulas werepositioned at a point 2 mm above each LPBN. The cannulas werefixed to the cranium using dental acrylic resin and jeweler screws.A 30-gauge metal obturator filled the cannulas between tests.When surgery was complete, the rats were allowed to recover 6days before drug injections into theLPBN.

Injections into the LPBN. Injections into the LPBN were made using 10-µl Hamilton syringes connected by polyethylene tubing (PE-10) to 30-gauge injectioncannulas. At the time of testing, obturators were removed andthe injection cannulas (2 mm longer than the guide cannulas) wereintroduced in the brain. The injection volume into the LPBN was0.2 µl each site. The obturators were replaced after the injection,and the rats were placed back into thecage.

Drugs. Furo (Sigma Chem., St Louis, MO) was administered subcutaneously at 10 mg/kg of body weight. Cap (Sigma Chemical, St Louis,MO) was administered subcutaneously at 5 mg/kg of bodyweight.

Methysergide maleate, DOI, proglumide sodium, and CCK-8 sulfated {cholecystokinin fragment 26-33,[Tyr (SO₃H)²⁷]-amide} were purchased from Research Biochemicals Internationals(Natick, MA). Methysergide (0.5 and 4 µg/0.2 µl) was dissolvedin propylene glycol and water 2:1 (vehicle), DOI (5 µg/0.2 µl)and proglumide (20 and 50 µg/0.2 µl) were dissolved in saline.CCK-8 (1 µg/0.2 µl) was dissolved in distilledwater.

Water and NaCl intake. Rats were tested in their home cages. Water and 1.8% NaCl were provided from burettes with 0.1-ml divisions that were fittedwith metal drinking spouts. Water and 1.8% NaCl intake were inducedby treatment with subcutaneous Furo (10 mg/kg of body wt) + Cap(5 mg/kg of body wt) as described previously (6, 21). Cumulativewater and 1.8% NaCl intakes were measured at 30, 60, 90, and 120min starting 1 h after Furo + Cap treatment when water and NaClwere available foranimals.

Rats received Furo + Cap treatments and were returned to their home cages in the absence of water and 1.8% NaCl solution.Forty minutes later, the animals received the first bilateralinjections into the LPBN (first treatment) followed 10 min laterby the second bilateral injections into the LPBN (second treatment)according to the combinations of treatments presented in Table1. Water and 1.8% NaCl were available to the animals 10 min afterthe second LPBN treatment.

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Table 1. Summary of the combinations of treatments into the LPBN

Each group of rats received four tests of water and NaCl intake. In each group, one of the blocks of four combinations presentedin Table 1 was tested. In each test, one-half of the rats receivedone combination of treatments and the remaining animals receivedanother combination of treatments. The combinations of treatmentsin different tests in the same group of rats were randomized.At the end of the four tests, each rat of the group received allof the four combinations of one of the blocks indicated in Table1.

The higher doses of methysergide (4 µg/0.2 µl) and proglumide (50 µg/0.2 µl) were based on previous studies (2, 18-21).

Histology. At the end of the experiments, the animals received bilateral injections of methylene blue solution (0.2 µl) into the LPBN.They were then deeply anesthetized with pentobarbital sodium (80mg/kg) and perfused transcardially with saline followed by 10%formalin. The brains were removed, fixed in 10% formalin, frozen,cut in 50-µm sections, stained with cresyl violet, and analyzedby light microscopy to confirm the injection sites into theLPBN.

Statistical analysis. The results are reported as means ± SE. Repeated-measures ANOVA and Newman-Keuls tests were used for comparisons (GB STATsoftware, Dynamic Microsystems, Silver Spring, MD). Differenceswere considered significant at P < 0.05.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Histological analysis. Similar to the results seen in previous reports (2, 18-21), the LPBN injection sites were centered in the central lateraland dorsal lateral portions of the LPBN [see Fulwiler and Saper(7) for definitions of LPBN subnuclei]. Figure 1 shows typicalLPBN injection sites. Injections reaching the ventral lateraland external lateral portions as well as the Kölliker-Fuse nucleuswere observed in some rats, and the results from these rats wereincluded in the analysis.

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Fig. 1. Photomicrograph of transverse section of a rat brain showing injection sites, as indicated by the arrows, in the lateral parabrachial nucleus (LPBN).

From a total of 72 rats used in this study, 53 had histologically confirmed LPBN bilateral injections as describedabove.

Effects of bilateral injections of methysergide + proglumide into the LPBN on Furo + Cap-induced 1.8% NaCl and water intake. With the higher doses of the drugs tested, bilateral injections of only methysergide (4 µg/0.2 µl each site) or of only proglumide(50 µg/0.2 µl each site) into the LPBN produced similar increasesof 1.8% NaCl intake (14.5 ± 4.1 and 14.2 ± 3.2 ml/2 h, respectively,vs. control: 2.9 ± 0.9 ml/2 h), [Fig. 2A; F(3,36) = 3.07; P <0.05]. The combination of both antagonists injected into the LPBNresulted in no additional change in 1.8% NaCl intake (16.3 ± 3.2ml/2 h) compared with the effect of each antagonist alone deliveredto the LPBN (Fig. 2A). The increase in water intake was similarfor all treatments (methysergide: 17.7 ± 2.3 ml/2 h; proglumide:17.4 ± 2.3 ml/2 h; and methysergide + proglumide: 20.4 ± 3.4 ml/2h vs. control: 10.3 ± 1.1 ml/2 h; Fig. 2B). An ANOVA showed significantinteraction between treatments and time for water intake [F(9,108)= 2.56; P < 0.05].

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Fig. 2. A: cumulative 1.8% NaCl intake; B: cumulative water intake induced by combined subcutaneous treatment of furosemide (Furo) + captopril (Cap) in rats that received bilateral injections of methysergide (methy; 4 µg/0.2 µl), proglumide (prog, 50 µg/0.2 µl), methy + prog, or vehicle + saline (veh + sal; control) into the LPBN. Results are expressed as means + SE; n, no. of rats.

With the low doses of the drugs, bilateral injections of only methysergide (0.5 µg/0.2 µl) or only proglumide (20 µg/0.2 µl)into the LPBN produced similar increases of 1.8% NaCl intake (13.2± 2.7 and 11.1 ± 2.1 ml/2 h, respectively, vs. control: 2.8 ±0.8 ml/2 h), (Fig. 3A). The combined bilateral injections of methysergide(0.5 µg/0.2 µl) and proglumide (20 µg/0.2 µl) into the LPBN producedgreater increases in 1.8% NaCl intake (20.6 ± 2.3 ml/2 h) comparedwith the effect of each antagonist alone [Fig. 3A; F(3,36) = 10.29;P < 0.01]. As in the effects observed with the high doses, thelow doses of the antagonists produced similar increases of waterintake in all treatments (methysergide: 17.7 ± 3.2 ml/2 h; proglumide:19.4 ± 1.9 ml/2 h; and methysergide + proglumide: 23.0 ± 3.1 ml/2h vs. control: 12.1 ± 1.7 ml/2 h; Fig. 3B). An ANOVA showed asignificant interaction between treatments and time for waterintake [F(9,108) = 3.00; P < 0.01].

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Fig. 3. A: cumulative 1.8% NaCl intake; B: cumulative water intake induced by combined subcutaneous treatment of Furo + Cap in rats that received bilateral injections of methy (0.5 µg/0.2 µl), prog (20 µg/0.2 µl), methy + prog, or veh + sal into the LPBN. Results are expressed as means + SE.

Effects of bilateral injections of proglumide + DOI into the LPBN on Furo + Cap-induced 1.8% NaCl and water intake. Bilateral injections of DOI (5 µg/0.2 µl each site) into the LPBN decreased 1.8% NaCl intake [1.8 ± 0.4 vs. control: 4.9 ±0.9 ml/2 h; Fig. 4A; F(3,76) = 14.03; P < 0.01]. Proglumide (50µg/0.2 µl each site) injected bilaterally into the LPBN significantlyincreased 1.8% NaCl intake (15.4 ± 2.8 ml/2 h). With the combinationof bilateral injections of proglumide and DOI into the LPBN, the1.8% NaCl intake was not different from the control treatment(5.9 ± 1.3 vs. control: 4.9 ± 0.9 ml/2 h; Fig. 4A).

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Fig. 4. A: cumulative 1.8% NaCl intake; B: cumulative water intake induced by combined subcutaneous treatment of Furo + Cap in rats that received bilateral injections of prog (50 µg/0.2 µl), 2,5-dimetoxy-4-iodoamphetamine hydrobromide (DOI; 5 µg/0.2 µl), prog + DOI, or sal + sal (sal + sal, control) into the LPBN. Results are expressed as means + SE.

Water intake significantly decreased with bilateral injections of DOI (5 µg/0.2 µl) into the LPBN [6.4 ± 0.8 vs. control:11.7 ± 0.9 ml/2 h; Fig. 4B; F(3,76) = 11.38; P < 0.01]. Proglumideincreased water intake (17.3 ± 2.2 ml/2 h). With the combinationof proglumide and DOI injected into the LPBN, water intake wasnot different from control (9.6 ± 1.4 vs. saline: 11.7 ± 0.9 ml/2h; Fig. 4B).

Effects of bilateral injections of methysergide + CCK-8 into the LPBN on Furo + Cap-induced 1.8% NaCl and water intake. Bilateral injections of only methysergide (4 µg/0.2 µl, each site) into the LPBN increased 1.8% NaCl intake (16.3 ± 3.7 vs.control: 3.0 ± 0.9 ml/2 h; Fig. 5A). CCK-8 (1 µg/0.2 µl, eachsite) alone injected bilaterally into the LPBN produced no changein 1.8% NaCl intake (3.7 ± 1.3 ml/2 h). During the first 30 minof the test with the combination of bilateral LPBN injectionsof methysergide and CCK-8, 1.8% NaCl intake (6.7 ± 2.7 ml/30 min)was reduced compared with NaCl intake with methysergide injectedalone into the LPBN [F(3,32) = 8.02; P < 0.01; Fig. 5A].

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Fig. 5. A: cumulative 1.8% NaCl intake; B: cumulative water intake induced by combined subcutaneous treatment of Furo + Cap in rats that received bilateral injections of methy (4 µg/0.2 µl), CCK-8 (1 µg/0.2 µl), methy + CCK-8, or veh + water (veh + water; control) into the LPBN. Results are expressed as means + SE.

Injections of only CCK-8 into the LPBN did not alter the water intake (10.5 ± 1.7 vs. control: 10.1 ± 1.2 ml/2 h; Fig. 5B).Water intake increased with bilateral injections of only methysergideand with the association of methysergide and CCK-8 into the LPBN[18.3 ± 2.4 and 20.1 ± 3.4 ml/2 h; F(3,32) = 4.91; P < 0.01].

Specificity of injections into the LPBN to produce the reported results. The specificity of the LPBN as the site of injections that produce the effects of the drugs was confirmed by results fromrats in which the injections did not reach one or both LPBN sites.Table 2 shows the total ingestion of water and 1.8% NaCl (120min of intake) produced by the different treatments in rats inwhich the injections did not reach one or both LPBN sites. ANOVAshowed no significant differences on cumulative water and NaClintake in these rats with any of the treatments.

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Table 2. Water and 1.8% NaCl intake induced by combined subcutaneous treatment with Furo + Cap in rats in which 1 or both injections did not reach LPBN sites

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The effects of the combined administration of serotonergic and CCKergic agonists and antagonists into the LPBN on Furo + Cap-inducedNaCl intake suggest the presence of important interactions betweenthe two neurotransmitters in the control of sodium intake. Onthe other hand, the results showed no clear interaction between5-HT and CCK in the control of Furo + Cap-induced water intake.In most of the experiments, the rats ingested significant amountsof 1.8% NaCl that can, in turn, induce significant water intakedue to the increase in body fluid osmolality. Consequently, thewater intake recorded in the protocols was likely to have beenconfounded by large intakes of hypertonic NaCl. Therefore, itis not appropriate to consider possible interactions between 5-HTand CCK to control water intake in the protocol used in the presentstudy.

The present results show an interaction between inhibitory serotonergic and cholecystokinergic mechanisms in the LPBN on thecontrol of sodium chloride intake (sodium appetite) that seemsto work like the model of cooperativity and interdependence between5-HT and CCK proposed by Cooper and Dourish to explain the inhibitorycontrol of feeding by these two neurotransmitters (3). Cooperand Dourish proposed that elevated 5-HT release and action tendto increase CCK release and action and vice versa. The interdependenceassumption is that both 5-HT and CCK action at their respectivereceptors is necessary for the normal development of satiety.Pharmacological interventions that block either 5-HT or CCK receptorsreduce the satiety-inducing effects of either transmitter. Oneassumption of this idea is that elevated 5-HT and CCK activityis necessary for satiety to be fullyexpressed.

The combination of methysergide and proglumide administered in high doses into the LPBN produced an increase of 1.8% NaCland water intake that was equivalent to the increase producedby the injections of either antagonist alone. With low doses,bilateral LPBN injections of only methysergide or only proglumideproduced comparable increases in 1.8% NaCl intake. The combinedtreatment with low doses of both antagonists administered intothe LPBN produced a significantly greater increase in sodium intake.Considering the effects of bilateral LPBN injections of methysergideand proglumide in light of the model of cooperativity and interdependence,the treatment with a high dose of methysergide not only preventsthe action of 5-HT, but also may reduce CCK release, thereforenearly abolishing the action of both inhibitory mechanisms withinthe LPBN. Similarly, proglumide treatment prevents the actionof CCK but also may reduce 5-HT release, producing the same effectsas methysergide. Thus the effects of one or both antagonists inhigh doses injected in the LPBN are the same; that is, with highdoses, combined injections of both antagonists did not producea greater 1.8% NaCl intake, because the blockade of only one receptorsystem seems to be sufficient to abolish the action of both systems.Injections of low doses of each antagonist, methysergide or proglumide,produce only a partial impairment in each mechanism. The combinationof both receptor antagonists given in low doses into the LPBNcan produce a more intense blockade of each mechanism comparedwith single injections of each antagonist, thereby producing anincreased sodiumintake.

Bilateral injections of the serotonergic receptor agonist DOI alone into the LPBN decreased water and 1.8% NaCl intake. Withthe combination of bilateral LPBN injections of proglumide andDOI, water and 1.8% NaCl intake returned to control level. Thissuggests that the association of proglumide and DOI abolishedthe inhibition of sodium intake produced by activation of theserotonergic inhibitory mechanism with DOI as well as the increaseof sodium intake produced by the deactivation of cholecystokinergicmechanism with proglumide. According to the model of cooperativityand interdependence between 5-HT and CCK, the activation of theserotonergic inhibitory mechanism of the LPBN with DOI may alsostimulate local CCK release, resulting in a reduction of NaClintake as a consequence of the action of DOI and CCK on theirrespective receptors. Proglumide treatment prevents CCK actionon its receptors and may reduce the inhibitory effect of DOI,which is also dependent on CCK action. Why would the proglumideeffect disappear when proglumide is associated with DOI? Proglumideblocking CCK receptors prevents the direct inhibitory action ofCCK and also the stimulant effect of CCK on 5-HT release. Theresult may be due also to a reduced endogenous 5-HT release andalmost a complete blockade of both inhibitory mechanisms withinthe LPBN. However, DOI injections activating serotonergic receptorscan partially restore the inhibition, impairing the normal effectof proglumide. The effect of DOI is partial, because without CCKparticipation, the effect of serotonergic receptor activationis notcomplete.

Bilateral injections of CCK-8 alone into the LPBN did not change either water or 1.8% NaCl intake. Compared with the intakewith bilateral injections of methysergide alone, the combinationof CCK-8 and methysergide injected into the LPBN reduced 1.8%NaCl intake during the first 30 min of testing. The lack of aneffect of CCK-8 when administered alone into the LPBN on NaClintake is consistent with previous results showing that bilateralinjections of CCK-8 into the LPBN did not reduce Furo + Cap-induced1.8% NaCl intake (20). To explain the lack of an effect of CCK-8injected into the LPBN on NaCl intake, Menani and Johnson (20)proposed that the CCK normally present in the LPBN is enough tointeract with 5-HT and sufficient to exert a complete inhibitoryeffect on sodium intake. Thereby, exogenous CCK-8 would not increasethe inhibition of sodium intake. According to the model of cooperativityand interdependence between 5-HT and CCK, the blockade of 5-HTreceptors impairs CCK release. Therefore, only methysergide treatmentcan increase 1.8% NaCl intake by indirectly reducing CCK release.Replacing CCK by injecting exogenous CCK-8 may restore part ofthe inhibition, so it is possible to observe a partial reductionof 1.8% NaCl intake in association with methysergide and CCK-8into theLPBN.

The LPBN is a major site that receives ascending projections from AP/mNTS and sends efferent projections to areas of the forebraininvolved in the control of fluid and electrolyte balance suchas hypothalamic areas and amygdala (1, 7, 9-11, 13, 14).The AP/mNTS is an important area of the hindbrain that receivesafferent projections from volume receptors (arterial baroreceptors,cardiopulmonary receptors), gustatory receptors, and other visceralreceptors that can influence water and NaCl intake (12, 22,27, 28). Central or peripheral administration of the atrialnatriuretic peptide (ANP) has also been shown to reduce waterand sodium intake (16). Because the AP lacks a blood-brain barrier,plasma ANP released by atrial distension may have activated thisarea, and this information about blood-borne levels of ANP isthen carried to the LPBN. Neurotransmitters such as 5-HT and CCKhave been identified in the projections from AP/mNTS to the LPBN(14, 25, 26). Thus the LPBN can play a key role in the centralcircuitry that controls water and NaCl intake. Figure 6 is representingthe interdependence and cooperativity between 5-HT and CCK inthe LPBN to control NaCl intake. The proposed model suggests thatthe release and the action of 5-HT and CCK in the LPBN are essentialfor complete inhibition of NaCl intake.

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Fig. 6. Modified schematic model showing the interaction between 5-hydroxytryptamine (5-HT) and CCK into the LPBN in the control of NaCl intake [adapted from the model proposed by Cooper and Dourish (3)]. ANP, atrial natriuretic peptide; AP, area postrema; NTS, nucleus of the solitary tract.

Perspectives

The demonstration of an interaction between inhibitory serotonergic and CCKergic mechanisms in the LPBN to control NaCl intakerepresents an important advance in our understanding of the centralmechanisms involved in the control of fluid and electrolyte balance.Future studies should deal with the origin and nature of the stimulithat induce serotonin and CCK release in the LPBN and whether5-HT and CCK interact in the LPBN to control waterintake.

	ACKNOWLEDGEMENTS

We thank Silas Pereira Barbosa and Sílvia Fóglia for expert technical assistance and Silvana A. D. Malavolta for secretarialassistance. We also thank Ana L. V. de Oliveira for animalcare.

	FOOTNOTES

This research was supported by public funding from Fundação de Amparo a Pesquisa do Estado de São Paulo; Coordenaçãode Aperfeiçoamento de Pessoal de Nível Superior, Conselho Nacionalde Pesquisa-Programa de Apoio a Núcleos de Excelência and NationalHeart, Lung and Blood Institute Grants HL-14388 and HL-57472.

This work is part of the requirements to obtain a Master's degree by J. I. F. De Gobbi in the graduate program in physiologicalsciences at the Federal University of SãoCarlos.

Address for reprint requests and other correspondence: J. V. Menani, Dept. of Physiology and Pathology, School of Dentistry,UNESP, Rua Humaitá, 1680, 14801-903 Araraquara-SP,Brazil.

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

Received 30 May 2000; accepted in final form 13 November 2000.

	REFERENCES

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

1. Ciriello, J, Lawrence D, and Pittman QJ. Electrophysiological identification of neurons in the parabrachial nucleus projecting directly to the hypothalamus in the rat. Brain Res 322: 388-392, 1984[ISI][Medline].

2. Colombari, DSA, Menani JV, and Johnson AK. Forebrain angiotensin type 1 receptors and parabrachial serotonin in the control of NaCl and water intake. Am J Physiol Regulatory Integrative Comp Physiol 271: R1470-R1476, 1996[Abstract/Free Full Text].

3. Cooper, SJ, and Dourish CT. Multiple cholecystokinin (CCK) receptors and CCK-monoamine interactions are instrumental in the control of feeding. Physiol Behav 48: 849-857, 1990[Medline].

4. Corp, ES, Curcio M, Gibbs J, and Smith GP. The effect of centrally administered CCK-receptor antagonists on food intake in rats. Physiol Behav 61: 823-827, 1997[Medline].

5. Dorre, D, and Smith GP. Cholecystokinin B receptor antagonist increases food intake in rats. Physiol Behav 65: 11-14, 1998[Medline].

6. Fitts, DA, and Masson DB. Forebrain sites of action for drinking and salt appetite to angiotensin or captopril. Behav Neurosci 103: 865-872, 1989[ISI][Medline].

7. Fulwiler, CE, and Saper CB. Subnuclear organization of the efferent connections of the parabrachial nucleus in the rat. Brain Res Rev 7: 229-259, 1984.

8. Grignaschi, G, Mantelli B, Fracasso C, Anelli M, Caccia S, and Samanin R. Reciprocal interaction of 5-hydroxytryptamine and cholecystokinin in the control of feeding patterns in rats. Br J Pharmacol 109: 491-494, 1993[ISI][Medline].

9. Herbert, H, Moga MM, and Saper CB. Connections of the parabrachial nucleus to the solitary tract and the medullary reticular formation in the rat. J Comp Neurol 293: 540-580, 1990[ISI][Medline].

10. Jhamandas, JH, Harris KH, Petrov T, and Krukoff TL. Characterization of the parabrachial nucleus input to the hypothalamic paraventricular nucleus in the rat. J Endocrinol 4: 461-471, 1992.

11. Jhamandas, JH, Petrov T, Harris KH, Vu T, and Krukoff TL. Parabrachial nucleus projection to the amygdala in the rat. Electrophysiological and anatomical observations. Brain Res Bull 39: 115-126, 1996[ISI][Medline].

12. Johnson, AK, and Thunhorst RL. Sensory mechanisms in the behavioral control of body fluid balance: thirst and salt appetite. In: Progress in Psychobiology and Physiological Psychology, edited by Fluharty SJ, Morrison AR, Sprague JM, and Stellar E.. New York: Academic, 1995, vol. 16, p. 145-176.

13. Krukoff, TL, Harris KH, and Jhamandas JH. Efferent projections from the parabrachial nucleus demonstrated with the anterograde tracer Phaseolus vulgaris leucoagglutinin. Brain Res Bull 30: 163-172, 1993[ISI][Medline].

14. Lança, AJ, and van der Kooy D. A serotonin-containing pathway from the area postrema to the parabrachial nucleus in the rat. Neuroscience 14: 1117-1126, 1985[ISI][Medline].

15. Leibowitz, SF, and Alexander JT. Hypothalamic serotonin in the control of eating behavior, meal size, and body weight. Biol Psychiatry 44: 851-864, 1998[ISI][Medline].

16. McCann, SM, Franci C, Gutkowska J, Favaretto AL, and Antunes-Rodrigues J. Neural control of atrial natriuretic peptide actions on fluid intake and excretion. Proc Soc Exp Biol Med 213: 117-127, 1996[Medline].

17. Menani, JV, Colombari DSA, Beltz TG, Thunhorst RL, and Johnson AK. Salt appetite: interaction of forebrain angiotensinergic and hindbrain serotonergic mechanisms. Brain Res 801: 29-35, 1998[ISI][Medline].

18. Menani, JV, De Luca LA, Jr, and Johnson AK. Lateral parabrachial nucleus serotonergic mechanisms and salt appetite induced by sodium depletion. Am J Physiol Regulatory Integrative Comp Physiol 274: R555-R560, 1998[Abstract/Free Full Text].

19. Menani, JV, and Johnson AK. Lateral parabrachial serotonergic mechanisms: angiotensin-induced pressor and drinking responses. Am J Physiol Regulatory Integrative Comp Physiol 269: R1044-R1049, 1995[Abstract/Free Full Text].

20. Menani, JV, and Johnson AK. Cholecystokinin actions in the parabrachial nucleus: effects on thirst and salt appetite. Am J Physiol Regulatory Integrative Comp Physiol 275: R1431-R1437, 1998[Abstract/Free Full Text].

21. Menani, JV, Thunhorst RL, and Johnson AK. Lateral parabrachial nucleus and serotonergic mechanisms in the control of salt appetite in rats. Am J Physiol Regulatory Integrative Comp Physiol 270: R162-R168, 1996[Abstract/Free Full Text].

22. Norgren, R. The central organization of the gustatory and visceral systems in the nucleus of the solitary tract. In: Brain Mechanisms of Sensation, edited by Katsuki Y, Norgren R, and Sato M.. New York: Wiley, 1981, p. 143-160.

23. Ohman, LE, and Johnson AK. Lesions in the lateral parabrachial nucleus enhance drinking to angiotensin II and isoproterenol. Am J Physiol Regulatory Integrative Comp Physiol 251: R504-R509, 1986.

24. Ohman, LE, and Johnson AK. Role of the lateral parabrachial nucleus in the inhibition of water intake produced by right atrial stretch. Brain Res 695: 275-278, 1995[ISI][Medline].

25. Saleh, TM, and Cechetto DF. Peptides in the parabrachial nucleus modulate visceral input to the thalamus. Am J Physiol Regulatory Integrative Comp Physiol 264: R668-R675, 1993[Abstract/Free Full Text].

26. Saleh, TM, and Cechetto DF. Peptides changes in the parabrachial nucleus following cervical vagal stimulation. J Comp Neurol 366: 390-405, 1996[ISI][Medline].

27. Thunhorst, RL, and Johnson AK. Effects of arterial pressure on drinking and urinary responses to intracerebroventricular angiotensin II. Am J Physiol Regulatory Integrative Comp Physiol 264: R211-R217, 1993[Abstract/Free Full Text].

28. Thunhorst, RL, and Johnson AK. Renin-angiotensin, arterial blood pressure and salt appetite in rats. Am J Physiol Regulatory Integrative Comp Physiol 266: R458-R465, 1994[Abstract/Free Full Text].

29. Willis, GL, Hansky J, and Smith GC. Central and peripheral proglumide administration and cholecystokinin-induced satiety. Regul Pept 15: 87-98, 1986[ISI][Medline].

30. Zhang, D-M, Bula W, and Stellar E. Brain cholecystokinin as a satiety peptide. Physiol Behav 36: 1183-1186, 1986[Medline].

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