A Cholecystokinin-Mediated Pathway to the Paraventricular Thalamus Is Recruited in Chronically Stressed Rats and Regulates Hypothalamic-Pituitary-Adrenal Function

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The Journal of Neuroscience, July 15, 2000, 20(14):5564-5573

A Cholecystokinin-Mediated Pathway to the Paraventricular Thalamus Is Recruited in Chronically Stressed Rats and Regulates Hypothalamic-Pituitary-Adrenal Function
Seema Bhatnagar², Victor Viau¹, Alan Chu¹, Liza Soriano¹, Onno C. Meijer¹, and Mary F. Dallman¹
¹ Department of Physiology, University of California at San Francisco, San Francisco, California 94143-0444, and ² Department of Psychology, University of Michigan, Ann Arbor, Michigan 48109

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Chronic stress alters hypothalamic-pituitary-adrenal (HPA) responses to acute, novel stress. After acute restraint, the posteriordivision of the paraventricular thalamic nucleus (pPVTh) exhibitsincreased numbers of Fos-expressing neurons in chronically cold-stressedrats compared with stress-naïve controls. Furthermore, lesionsof the PVTh augment HPA activity in response to novel restraintonly in previously stressed rats, suggesting that the PVTh isinhibitory to HPA activity but that inhibition occurs only inchronically stressed rats. In this study, we further examinedpPVTh functions in chronically stressed rats. We identified afferentprojections to the pPVTh using injection of the retrograde tracerfluorogold. Of the sites containing fluorogold-labeled cells,neurons in the lateral parabrachial, periaqueductal gray, anddorsal raphe containing fluorogold also expressed cholecystokinin(CCK) mRNA. We then examined whether these CCKergic inputs tothe pPVTh were involved in HPA responses to acute, novel restraintafter chronic stress. We injected the CCK-B receptor antagonistPD 135,158 into the PVTh before restraint in control and chronicallycold-stressed rats. ACTH responses to restraint stress were augmentedby PD 135,158 only in chronically stressed rats but not in controls.In addition, CCK-B receptor mRNA expression in the pPVTh was notaltered by chronic cold stress. We conclude that previous chronicstress specifically facilitates the release of CCK into the pPVThin response to acute, novel stress. The CCK is probably secretedfrom neurons in the lateral parabrachial, the periaqueductal gray,and/or the dorsal raphe nuclei. Acting via CCK-B receptors inpPVTh, CCK then constrains facilitated ACTH responses to novelstress in chronically stressed but not naïve rats. These resultsdemonstrate clearly that chronic stress recruits a new set ofpathways that modulate HPA responsiveness to a novelstress.

Key words: paraventricular thalamus; chronic stress; cholecystokinin; lateral parabrachial; ACTH; facilitation

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Neuroendocrine responses to acute stress are modulated by previous experience with other stressful stimuli (Dallman and Bhatnagar,2000). For example, previous chronic stress is associated withnormal or enhanced responsiveness in the hypothalamic-pituitary-adrenal(HPA) axis to a novel stressor despite the negative feedback effectsof circulating glucocorticoids produced by the chronic stressor(Ottenweller et al., 1989; Hauger et al., 1990; Young et al.,1990; Scribner et al., 1991; Bhatnagar and Meaney, 1995; Akanaet al., 1996; Bhatnagar and Dallman, 1998). Furthermore, HPA responsescan decrease with repeated exposure to the same stressor (Armarioet al., 1986; Pitman et al., 1988; Odio and Brodish, 1989; Haugeret al., 1990; Viau and Sawchenko, 1995; Li and Sawchenko, 1998),and these effects are observable for months after the initialstress exposure (van Dijken et al., 1993). These effects of previousexperience with stress cannot be fully explained by differencesin glucocorticoid negative feedback efficacy and are likely causedby plastic changes in the brain produced by previous stress exposure(Dallman and Bhatnagar, 2000).

We have investigated the specific neuronal sites at which previous chronic stress may modify HPA responses to subsequent,novel stress. The paraventricular nucleus of the hypothalamus(PVN), the central, basomedial, and basolateral nuclei of theamygdala, the parabrachial/Kölliker-Fuse area, and the posteriordivision of the paraventricular nucleus of the thalamus (pPVTh)all exhibited increased neuronal activity in response to novel,acute stress in chronically stressed compared with stress-naïveanimals (Bhatnagar and Dallman, 1998). The PVTh is a midline thalamicnucleus receiving multimodal sensory input from the lateral parabrachialnucleus, the locus coeruleus, the nucleus tractus solitarius,and suprachiasmatic nuclei and projects to limbic sites such asthe amygdala, nucleus accumbens, and frontal cortex (Fulwilerand Saper, 1984; Hunt et al., 1987; Moga et al., 1995; Otake andNakamura, 1995). Neuronal activity in the PVTh (as measured byfos mRNA or Fos protein) is increased by exposure to a numberof different stressors administered acutely, including swimming,restraint, ether, and foot shock (Chastrette et al., 1991; Sharpet al., 1991; Imaki et al., 1993; Cullinan et al., 1996). Furthermore,lesions of the entire PVTh increase ACTH responses to acute, novelstress only in rats exposed to previous chronic stress but donot affect responses in control, stress-naïve rats (Bhatnagarand Dallman, 1998). These data suggested that the PVTh is inhibitoryto HPA activity but that inhibition occurs only in animals thathad experienced previous stress. Thus, the PVTh is the only identifiedsite at which previous stress experience acts to modify HPA responsesto novel stress. Because of its well defined connections to limbicand sensory systems, it may also be a site at which previous stressmodifies activity in other stress-sensitivesystems.

In the present study we examined afferent inputs to the posterior PVTh that may be important for the regulation of HPA activity.We injected the retrograde tracer fluorogold into the pPVTh toidentify brainstem projection sites to the pPVTh. Some of theseidentified sites are known to synthesize cholecystokinin (CCK),and the pPVTh expresses a moderate density of CCK-B receptors.Therefore, we next asked which of these sites of afferent inputto the pPVTh synthesize CCK using combined fluorogold immunocytochemistryand in situ hybridization for CCK. Finally, we tested the functionalrelevance of the CCK input to the PVTh by measuring ACTH responsesto acute restraint after blockade of CCK-B receptors in the PVThin animals with and without previous experience with intermittentcoldstress.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals
Male Sprague Dawley rats (Bantin-Kingman, Gilroy, CA), weighing 200-225 gm at arrival, were used for all experiments. Animalswere singly housed, maintained on a 12:12 hr light/dark schedule(lights on at 6:30 hr) with access to food (Purina Rat Chow 5008)and water available ad libitum, and allowed at least 2 d to acclimateto the housing conditions before any manipulations were conducted.All experiments were approved by the University of Californiaat San Francisco Committee on AnimalResearch.

Chronic intermittent cold stress paradigm
On each day of cold stress, animals were taken from their home cages and individually housed in polypropylene cages linedwith bedding material with access to food and water. The cageswere placed inside a well lit and well ventilated cold chambermaintained at 4-6°C. The animals remained inside the cold chamberfor 4 hr, generally from 13:00 to 17:00 hr, and then were returnedto their home cages. This procedure was repeated every day for7 consecutive days (CHR animals). Control animals (CTL) were leftundisturbed throughout thistime.

Experiment 1: procedure
Our specific goal was to target the pPVTh with the fluorogold injection because this is the division that exhibits increasedFos immunoreactivity after restraint in chronically stressed rats(Bhatnagar and Dallman, 1998). Twelve rats were anesthetized witha mix of ketamine, xylazine, and acepromazine (77:1.5:1.5 mg/ml,i.p., at 0.1 ml/100 gm of body weight) and placed in a stereotaxicapparatus with the skull flat (the tooth bar at $-$ 3.3 mm). A glassmicropipette, filled with 3% fluorogold in 0.9% saline and withan external diameter between 30 and 100 µm, was lowered to thelevel of the PVTh, using the following coordinates: anteroposterior, $-$ 3.3 mm; dorsoventral, $-$ 6.3 mm. A pulse of 3 µA current for 5min was used to apply the fluorogold iontophoretically. Afterrecovery from this surgery, the rats were returned to their homecages. Two weeks later, rats were perfused intracardially with0.1 M PBS followed by 4% paraformaldehyde. Brains were post-fixedin paraformaldehyde for 4 hr and placed in 30% sucrose at leastovernight. Multiple series of frozen coronal sections (30 µm)throughout the brain were collected and stored in cryoprotectant(30% ethylene glycol and 20% glycerol in 0.05 M phosphate) at $-$ 20°C until in situ hybridization and/or immunohistochemicalprocessing.

Detection of fluorogold-positive cells by immunocytochemistry
This procedure identified neurons that projected to the pPVTh. A single series was immunocytochemically stained for fluorogold.Sections were rinsed in KPBS to remove cryoprotectant and incubatedwith rabbit polyclonal antisera (Chemicon, Temicula, CA) to fluorogoldat a dilution of 1:8000 in KPBS and Triton X-100 containing 2%BSA and 5 mg/ml heparin at 4°C for 48 hr. The tissue was thenexposed to a goat anti-rabbit biotinylated secondary IgG diluted1:200 (Vector Laboratories, Burlingame, CA) for 1 hr and thento the avidin $---$ biotin-peroxidase elite complex for 1 hr at roomtemperature. To visualize fluorogold immunoreactivity, we usedthe AEC substrate kit (Vector Laboratories) that yields a redreaction product. Sections were washed in KPBS, mounted, and coverslippedusing an aqueous medium. An initial global survey of the entirebrain was used to identify regions expressing fluorogold-containingcells. Three rats were identified in this manner as having fluorogoldinjected into the medial/posterior division of thePVTh.

Immunohistochemical and hybridization characterization
This procedure was used to identify regions that were immunocytochemically stained for fluorogold and expressed CCK mRNA.A combination of fluorogold, visualized immunocytochemically withthe DAB reaction, and in situ hybridization for CCK mRNA was usedon a single series of sections through specific brain regionsthat were identified previously with the AEC staining describedabove. The AEC reaction product cannot withstand the temperaturesand washes required for the in situ hybridization procedure. Therefore,fluorogold was histochemically characterized using DAB as thechromogen. Sections were immunocytochemically stained for fluorogold(as described above except all buffers were made with DEPC-treatedwater) and hybridized for CCK mRNA and an adjacent series wasstained with cresyl violet to facilitate localization ofstructures.
Hybridization histochemical localization was performed using a ³³P-labeled antisense cRNA probe transcribed from a full-lengthcDNA encoding CCK mRNA (Dr. John Walsh, University of Californiaat Los Angeles, Los Angeles, CA). The techniques for riboprobesynthesis, hybridization, and autoradiographic localization ofthe mRNA signal were adapted according to the methods of Chanet al. (1993) and Watts and Swanson (1989). After immunocytochemistryfor fluorogold using the DAB reaction, free-floating sectionswere first rinsed in 0.1 M phosphate buffer, pH 7.4, and thenmounted and vacuum dried on glass slides overnight. After post-fixationwith 10% formaldehyde for 30 min at room temperature, slides wererinsed four times in KPBS for 7 min each at room temperature.Sections were digested with protease K (250 µl of 10 mg/ml stockin 250 ml of buffer) for 30 min at 37°C, rinsed once in DEPC-treatedwater for 3 min, rinsed once in 0.1 M triethanolamine (TEA; 2.5mM acetic anhydride and 0.1 M TEA, pH 8.0) for 3 min, acetylatedfor 10 min in TEA, rinsed in 2× SSC for 5 min, rapidly dehydratedby dipping in ascending ethanol concentrations (50-100%), andthen vacuum dried for at least 2 hr. Radionucleotide cRNA probeswere used at concentrations approximating 10⁷ cpm/ml in a solution of 50% formamide, 0.3 M NaCl, 10 mM Tris,pH 8.0, 1 mM EDTA, 10 mM dithiothreitol, 1× Denhardt's solution,and 10% dextran sulfate and applied to individual slides. Slideswere coverslipped and then incubated overnight at 55°C, afterwhich the coverslips were removed and the sections were rinsedonce in 4× SSC (0.15 M NaCl and 15 mM citric acid, pH 7.0) atroom temperature, treated with ribonuclease A (14 µg/ml of 0.1M Tris, 0.5 M NaCl, and 1 mM EDTA) for 30 min at 37°C, incubatedin buffer only for 30 min at 37°C, incubated in 1× SSC with mildagitation for 15 min at room temperature, stringently washed in0.5× SSC for 30 min at 68°C, and dehydrated by dipping in ascendingethanol concentrations. Sections hybridized with the ³³P-labeled CCK cRNAs were then exposed to x-ray film (HypermaxMP; Amersham, Arlington Heights, IL) for 48 hr, defatted in xylenes,and subsequently coated with Kodak NTB2 liquid autoradiographicemulsion and exposed at 4°C in the dark with dessicant for 6 d,as determined by the strength of the signal on the x-ray film.Slides were developed with Kodak D-19 for 5 min at 25°C, rinsedvigorously in tap water, fixed in Kodak fixer for 5 min, and washedin running water at room temperature for 30 min. A qualitativeanalysis was used to determine cells that were labeled for fluorogoldand CCK mRNA. A cell was considered CCK expressing if the densityof grains was three times greater than background. Brain regionsexpressing fluorogold-containing cells from Experiment 1 wereexamined for CCK-expressingcells.

Experiment 2: procedure
In this experiment, one set of control and one set of chronically stressed animals were killed on day 8 under basal conditions.Brains were removed, embedded in OTC compound, frozen, and storedat $-$ 80°C. Brains were sliced at 15 µm on a cryostat, and sectionswere stored at $-$ 80°C until processing for in situ hybridizationfor CCK-B receptor expression. There were five animals per groupin thisstudy.

In situ hybridization detection of CCK-B receptors in the PVTh
On the basis of the sequence of the CCK-B receptor gene (2243 bp in length) provided by Wank et al. (1992), we cloned a 372bp long portion of the CCK-B receptor from rat brain cDNA. Thefragment was amplified with PCR (using primers for nucleotides715-736 and 1065-1087). This sequence was cloned in a pBluescriptvector, linearized with XbaI, and transcribed with T3 RNA polymerase.Frozen sections collected at 15 µm were fixed with 4% paraformaldehydefor 5 min on ice, incubated in 0.1 M PBS on ice for 2 min, rinsedbriefly in 0.1 M TEA, and acetylated in 0.1 M TEA and acetic anhydridefor 10 min at room temperature with vigorous stirring. The tissuewas then rinsed in 2× SSC and dehydrated 2 min in ascending gradesof ethanol. Last, sections were defatted in chloroform for 5 minat room temperature, dipped in 95% ethanol for 2 min, and storedat roomtemperature.
[³³P]UTP-labeled ribonucleotide cRNA probe was used at concentrations approximating 10⁷ cpm/ml in a solution of 50% formamide, 0.3 M NaCl, 10 mM Tris,pH 8.0, 1 mM EDTA, 10 mM dithiothreitol, 1× Denhardt's solution,and 10% dextran sulfate and applied to individual slides. Slideswere coverslipped, then incubated overnight at 55°C, rinsed oncein 4× SSC (0.15 M NaCl and 15 mM citric acid, pH 7.0) at roomtemperature to remove the coverslips, treated with ribonucleaseA (14 µg/ml of 0.1 M Tris, 0.5 M NaCl, and 1 mM EDTA) for 30 minat 37°C, desalted in 1× SSC with mild agitation at room temperature,washed in 0.5× SSC for 30 min at 68°C, and dehydrated in ascendingethanol concentrations. Sections hybridized with the ³³P-labeled CCK-B receptor cRNAs were then exposed to x-ray film(HyperFilm MP; Amersham) for 3 d, subsequently coated with KodakNTB2 liquid autoradiographic emulsion, and exposed at 4°C in thedark with dessicant for 15 d, as determined by the strength ofthe signal on the x-ray film. Slides were developed with KodakD-19 for 5 min at room temperature, vigorously dipped in tap waterfor 15 sec, and then dipped in Kodak fixer for 5 min. Sectionswere then incubated in running tap water for 30 min and lightlystained with cresyl violet. Semiquantitative densitometric analysisof the levels of CCK-B receptor mRNA was performed, using Macintosh-drivenNIH Image software (version 1.61; William Rasband, National Institutesof Health, Bethesda, MD), in three levels of the PVTh: the anterior( $-$ 1.8 mm from bregma), middle ( $-$ 2.8 mm from bregma), and posterior( $-$ 3.3 mm from bregma) divisions. At least two sections per levelof PVTh per animal wereanalyzed.

Experiment 3a: procedure
All animals were allowed 48 hr to acclimate to the housing conditions. Guide cannulae (28 ga; Plastic Products, Roanoke, VA)were implanted in all animals using the coordinates and proceduredescribed below. All animals were allowed at least 48 hr to recoverfrom surgery. Animals were divided into two groups, control andchronically stressed. Chronically stressed animals were exposedto chronic, intermittent cold stress for 7 d while the controlanimals remained undisturbed. On day 8, a 31 ga injection cannulawas inserted into the guide cannula so that it protruded 1 mmbelow its tip, aimed just into the dorsal portion of the middle/posterior PVTh. Half of the control and half of the chronicallystressed animals were injected with the CCK-B receptor antagonistPD 135,158 (Hughes et al., 1990) at 62 ng in 200 nl [doses inthis range have been used previously by Popoli et al. (1995)]over 1 min. Remaining rats were injected with 200 nl of vehicle(0.9% saline). Thirty minutes after the injections, all animalswere placed in a restrainer, and a blood sample was immediatelytaken from a tail vein (the 0 min time point). Samples were alsocollected at 15 and 30 min during restraint. Animals were thenremoved from the restrainer and replaced in their home cages.Thirty minutes later (at 60 min), all animals were killed by decapitation.There were 7-14 rats per group in thisstudy.

Experiment 3b: procedure
A separate group of animals was subjected to the following procedure. On day 8, half of the CTL and CHR animals were injectedwith sulfated CCK-8 [CCK-8s, the high-affinity agonist to theCCK-A receptor (Benedetti, 1997)] at a dose of 10 ng in 200 nl(Bloch et al., 1989; Crawley, 1992), and the other half received200 nl of vehicle (0.9% saline). Thirty minutes later, all animalswere exposed to restraint and sampled as above. There were 5-13rats per group in thisstudy.

Experiment 3c: procedure
A separate group of animals was subjected to the following procedure. On day 8, half of the CTL and CHR animals were injectedwith unsulfated CCK-8 [the high-affinity agonist to the CCK-Breceptor (Benedetti, 1997)] at a dose of 10 ng in 200 nl (Blochet al., 1989; Crawley, 1992), and the other half received 200nl of vehicle. Thirty minutes later, all animals were exposedto restraint and sampled as above. There were 6-11 rats per groupin thisstudy.

Guide cannula implantation into the PVTh
Rats were anesthetized with a mix of ketamine, xylazine, and acepromazine (77:1.5:1.5 mg/ml, i.p., at 0.1 ml/100 gm of bodyweight) and placed in a stereotaxic apparatus with the skull flat(the tooth bar at $-$ 3.3 mm). A 28 ga guide cannula was lowereddown the midline to the following coordinates: anteroposterior, $-$ 2.8 mm, and dorsoventral, $-$ 5.3 mm. A 31 ga dummy cannula cutto the length of the guide cannula was inserted into the guidecannula.

Confirmation of PVTh cannula implantations
At the end of Experiments 3a-c, all animals were decapitated; brains were collected, post-fixed in 4% formalin followed by30% sucrose, and sliced at 30 µm on a sliding microtome. One seriesof sections was stained with cresyl violet to visualize placementof the cannula. All brains were examined in a blind manner. Toscore a "hit" of an injection into the PVTh, there had to be histologicalevidence of the needle trajectory and clear damage of the ependymaof the ventricle overlying the PVTh. If ependymal damage was notapparent, the injectate was assumed to have been delivered intothe ventricle, and the rat was scored as a "miss." Injection trackslateral or ventral to the PVTh were also scored as misses. Consequently,approximately half of the animals injected with CCK agonists orantagonists in Experiment 3 were scored asmisses.

ACTH and corticosterone radioimmunoassays
Plasma ACTH was measured by radioimmunoassay using a specific antiserum generously donated by Dr. William Engeland (Universityof Minnesota) at a final dilution of 1:120,000 and ¹²⁵I-ACTH as a tracer (Incstar, Stillwater, MN). The ACTH antiserumcross-reacts 1% with ACTH1-39, ACTH1-18, and ACTH 1-24 but notwith ACTH1-16, B-endorphin, $alpha$ -MSH, or B-lipotropin (<0.1%). Plasmawas incubated for 48 hr at 40°C with antiserum and tracer; thenprecipitation serum (Peninsula Laboratories, Belmont, CA) wasadded and incubated for 2 hr. Bound peptide was obtained by centrifugationat 5000 × g for 45 min. The minimum level of detection of theassay was 10 pg/ml. Plasma B was measured using a kit fromIncstar.

Drugs
PD 135,158, the CCK-B receptor antagonist (Research Biochemicals, Natick, MA), was dissolved in 0.9% saline and injected ata dose of 62.5 ng/200 nl into the PVTh. Sulfated and unsulfatedCCK-8 (BACHEM), the CCK-A and -B receptor agonists, respectively,were used in equimolar doses (Crawley, 1992), initially dissolvedin NaHCO₃ and brought up to volume in 0.9% saline. CCK-8s andCCK-8 were injected (10 ng/200 nl) into the PVTh. Saline (0.9%)served as the vehicle injection in allexperiments.

Statistical analyses
Experiment 2. A one-way ANOVA (control vs chronically stressed groups) was performed to determine whether chronic stress alteredthe density of CCK-B receptor mRNA in the PVTh. There were fiveanimals per group in thisstudy.
Experiment 3. Because the purpose of this experiment was to examine the effects of injection of CCK receptor antagonist andagonists into the PVTh on HPA activity in CTL and CHR animals,each drug-injected group was compared with its vehicle-injectedcontrol and with the missed-injection groups. Data were analyzedusing two-way ANOVA [group (drug-injected vs vehicle-injectedvs missed injections) × time (repeated variable)]. Scheffé posthoc tests were used when the overall p was <0.05.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Experiment 1

Because our previous data indicated a specific role for the posterior division of the PVTh in regulating facilitated HPA activity(Bhatnagar and Dallman, 1998), our principal goal was to determinethe sources of afferent inputs to this particular division ofthe PVTh. We found that in three rats the dense core of the fluorogolddeposit was in the pPVTh, with some diffusion into the middledivision but none in the anterior PVTh. Brains in which more thanthe outer margins of fluorogold diffusion were localized outsidethe pPVTh into the lateral or medial habenulae or into other thalamicnuclei or in which the core of the fluorogold deposit was notfound in the pPVTh at all were not examined further. In all animalsinjected with fluorogold into the pPVTh, the pattern and intensityof fluorogold accumulation within the forebrain and brainstemstructures were similar. In addition, no pattern of fluorogoldlabeling was found in the brain that could be interpreted as resultingfrom fluorogold deposits into other thalamic nuclei. The extentof spread of the fluorogold injection into the PVTh is shown ina representative animal in Figure 1.

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Figure 1. A representative injection of fluorogold in the posterior PVTh [ $-$ 3.30 mm from bregma based on Paxinos and Watson (1986) in a] and visualized immunocytochemically in b (see Materials and Methods). In the experiments presented here, fluorogold injections were limited to the middle/posterior divisions of the PVTh.

Retrograde labeling after pPVTh fluorogold injections
The pattern of fluorogold labeling observed in this study is in strong agreement with that of previous surveys of afferentinputs to the PVTh after injections of fluorogold into the medial/posteriorPVTh (Eberhart et al., 1985; Otake and Nakamura, 1995; Otake andRuggiero, 1995).
Hypothalamus and limbic structures. Scattered fluorogold-labeled cells were found in the PVN, arcuate nucleus, and amygdala.Heavy labeling was observed in the zona incerta (data notshown).
Brainstem. In the lateral parabrachial nucleus (Fig. 2a-d), moderate numbers of fluorogold-labeled cells were found in thecentral division, and somewhat lower numbers were found in thedorsal division [divisions based on Saper and Loewy (1980)]. Somefluorogold-labeled cells were also found in the locus coeruleus.Heavy fluorogold staining was observed in the lateral, dorsolateral,and ventrolateral divisions of the periaqueductal gray (Fig. 2e,f).More caudally, fluorogold-labeled cells were only seen in theventrolateral portion of this region. Moderate numbers of fluorogold-labeledcells were found throughout the rostrocaudal extent of the dorsalraphe, but none were found in the median raphe (Fig. 3). Somefluorogold-labeled cells were observed in the supramammillaryarea, and higher numbers were in the lateral mammillary nucleus.Fluorogold-labeled cells were also found in the ventral tegmentalarea (VTA), but none were in the substantia nigra.

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Figure 2. Fluorogold-labeled cells in the dorsal (a, b; approximately $-$ 9.3 mm from bregma) and central (c, d; approximately $-$ 8.72 mm from bregma) divisions of the lateral parabrachial and in the periaqueductal gray (e, f; approximately $-$ 7.64 mm from bregma) after fluorogold injection into the pPVTh. Pictures on the right (b, d, f) are higher magnifications of the boxed areas shown on the left (a, c, e). Coordinates are based on the atlas of Paxinos and Watson (1986). scp, Superior cerebellar peduncle; 4v, fourth ventricle.

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Figure 3. Fluorogold-labeled cells in the caudal (approximately $-$ 9.16 mm from bregma) levels of the dorsal raphe after fluorogold injection into the pPVTh. b is a higher magnification of a. Coordinates are based on the atlas of Paxinos and Watson (1986). mlf, Medial longitudinal fasciculus.

Regions containing double-labeled fluorogold and CCK mRNA cells
Through those regions described above that were found to stain for fluorogold, a second series of sections was stained forfluorogold and processed for CCK mRNA. Only a few areas containedcells that were double labeled for fluorogold and CCK mRNA. Someof the fluorogold cells in the central division of the lateralparabrachial nucleus expressed CCK mRNA, whereas most of the fluorogold-labeledcells in the dorsal division also expressed CCK mRNA (Fig. 4a-d).A few double-labeled cells were observed in the ventrolateral,but none in the dorsal, periaqueductal gray (Fig. 4e,f). Mostfluorogold-labeled cells in the dorsal raphe at its caudal extentalso expressed CCK mRNA (Fig. 4g,h); however, we saw no doublylabeled cells in the more rostral levels of the dorsal raphe.Fluorogold-labeled cells in the locus coeruleus, supramammillaryregion, mammillary nucleus, and VTA regions were not found tocontain CCK mRNA.

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Figure 4. Characterization of CCK-expressing afferents to the pPVTh using fluorogold injections into the pPVTh and in situ hybridization for CCK mRNA. Left, Dark-field photomicrographs illustrating that CCK mRNA is expressed with varying degrees of prominence in the central and dorsal lateral parabrachial nuclei (a, c, respectively), the ventrolateral periaqueductal gray (PAG; e), and the caudal dorsal raphe (g). Right, Higher magnification bright-field views of the regions on the left (see arrows) showing the distribution of the CCK transcript relative to that of retrogradely labeled fluorogold afferents. Many fluorogold-labeled neurons in the parabrachial (b, d) and caudal dorsal raphe nuclei (h) are CCK positive (see arrowheads). Only occasional instances of fluorogold-CCK colocalization were encountered in the ventrolateral PAG (f). See Results for more details. 4v, Fourth ventricle.

Experiment 2: CCK-B receptor mRNA in the PVTh

CCK-B receptors were localized throughout the entire extent of the PVTh, and similar densities of receptor expression werefound in the anterior, midde, and posterior divisions of the PVTh.However, there were no significant differences in CCK-B receptormRNA between control and chronically stressed animals in any ofthe three levels of the PVTh (Fig. 5, Table 1).

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Figure 5. Dark-field (a) and bright-field (b) images of the CCK receptor mRNA distribution in the posterior division of the PVTh (approximately $-$ 3.30 mm from bregma). Neurons in b are lightly stained with cresyl violet. Chronic stress did not alter CCK-B receptor mRNA in any division of the PVTh. Coordinates are based on the atlas of Paxinos and Watson (1986).


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Table 1. CCK-B receptor mRNA in the three divisions of the PVTh in control animals and in animals exposed to chronic, intermittent cold stress

Experiment 3

Histology of injection sites
Figure 6 shows micrographs of the pPVTh region from three rats. Figure 6a shows clear evidence that the injection needle piercedthe ependyma, suggesting that the injectate was delivered directlyinto PVTh parenchyma. This animal was grouped in the hit category.Figure 6b shows a brain in which the trajectory of the injectionneedle can be seen, but there is no evidence of a break in theependymal lining of the ventricle. This animal was grouped inthe missed category. In Figure 6c, the injection needle trackis lateral to the PVTh proper and is also misplaced more anteriorlyin the nucleus. This animal was also grouped in the missed category.Similar criteria were used to categorize all cannula placementsresulting in three groups of control and chronically stressedrats: vehicle injected into the PVTh, drug injected into areasother than the PVTh (missed), and drug injected into the PVTh.

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Figure 6. Representative photomicrographs of the track of an injector cannula placed in the pPVTh (a) and in the ventricle (b) and a missed placement lateral to the PVTh (c).

ACTH responses to the CCK-B receptor antagonist PD 135,158
In both control and chronically stressed animals, ACTH and corticosterone (B) responses to restraint were similar after injectionof PD 135,158 into areas other than the PVTh and after vehicleinjection into the PVTh. Thus, the effects of injecting PD 135,158into the PVTh were specific to this nucleus and were not causedby diffusion through the cerebrospinal fluid and action elsewhereor by its effect on other nearby nuclei (Fig. 7).

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Figure 7. ACTH responses during and after a 30 min period of restraint in control animals and in animals exposed to chronic, intermittent cold stress. Control and chronically stressed animals had PVTh injections of either vehicle (VEH) or the CCK-B receptor antagonist PD 135,158 (CCK-B ANT) or injections of the antagonist into areas other than the PVTh (CCK-B ANT MISSED). For control groups, VEH, n = 6-7; CCK-B ANT, n = 10; CCK-B ANT MISSED, n = 4-5. For chronic stress groups, VEH, n = 6-7; CCK-B ANT, n = 7; CCK-B ANT MISSED, n = 4-7. *p $<=$ 0.05.

Injection of the CCK-B receptor antagonist PD 135,158 into the PVTh did not significantly affect plasma ACTH responses torestraint in control animals compared with the responses withvehicle injections or injections of PD 135,158 into other areas.In marked contrast, injection of PD 135,158 into the PVTh significantlyincreased ACTH secretion after restraint in the chronically stressedrats. ACTH tended to increase at 15 min (p = 0.08) and significantlyincreased at 30 min [Fig. 7; F_(1,11) = 3.48; *p = 0.04] in CHRanimals compared with the response in the vehicle-injected andmissed groups. B levels were not significantly affected by PD135,158 injected in either CTL or CHR animals, probably becauseACTH levels (300-500 pg/ml) were above the saturation level forthe adrenal corticosterone response (Dallman et al., 1987) (datanotshown).

ACTH responses to the unsulfated CCK agonist CCK-8
Injection into the PVTh of the CCK-B receptor-preferring agonist CCK-8 did not significantly alter ACTH or B responses torestraint in either CTL or CHR animals (Fig. 8).

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Figure 8. ACTH responses during and after a 30 min period of restraint in control animals and in animals exposed to chronic, intermittent cold stress. Control and chronically stressed animals had PVTh injections of either vehicle (VEH) or the CCK-B receptor agonist unsulfated CCK-8 (CCK-8) or injections of the agonist into areas other than the PVTh (CCK-8 MISSED). For control groups, VEH, n = 6; CCK-8, n = 6; CCK-8 MISSED, n = 3. For chronic stress groups, VEH, n = 6-7; CCK-8, n = 5; CCK-8 MISSED, n = 6.

ACTH and B responses to the sulfated CCK agonist CCK-8s
Injection of the CCK-A receptor-preferring agonist CCK-8s into the PVTh did not significantly alter ACTH or B responses torestraint in either CTL or CHR animals (Fig. 9).

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Figure 9. ACTH responses during and after a 30 min period of restraint in control animals and in animals exposed to chronic, intermittent cold stress. Control and chronically stressed animals had PVTh injections of either vehicle (VEH) or the CCK-A receptor agonist sulfated CCK-8 (CCK-8S) or injections of the agonist into areas other than the PVTh (CCK-8S MISSED). For control groups, VEH, n = 7; CCK-8S, n = 6; CCK-8S MISSED, n = 4. For chronic stress groups, VEH, n = 5-6; CCK-8S, n = 7; CCK-8S MISSED, n = 3.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Taken as a whole, our results show that the posterior PVTh inhibits ACTH responses to acute stress via stimulation of CCK-Breceptors by CCK released from a distinct set of brain regionsconsisting of the lateral parabrachial, periaqueductal gray, and/ordorsal raphe. These CCKergic inputs to the pPVTh are specificallystimulated by acute stress superimposed on a background of previouschronic stress, because there was no effect of blockade of CCK-Breceptors on ACTH secretion in control animals. These effectsare not caused by differences in the expression of CCK-B receptormRNA in the pPVTh. Thus, activation of PVTh CCK-B receptors byCCK, probably released from neurons in brainstem areas, representsone mechanism by which previous experience with chronic stressalters subsequent HPAactivity.

The posterior PVTh responds to multimodal stimuli and has been characterized as a part of the visceral limbic system (Turnerand Herkenham, 1991; Otake et al., 1994). It receives input fromthe nucleus tractus solitariius and parabrachial nuclei (Saperand Loewy, 1980; Fulwiler and Saper, 1984; Otake and Ruggiero,1995) and projects preferentially to the basomedial, basolateral,and central nuclei of the amygdala (Su and Bentivoglio, 1990;Turner and Herkenham, 1991; Moga et al., 1995). To identify afferentprojections to the posterior PVTh that may contribute to effectsof previous chronic stress on stimulated ACTH secretion, we injectedthe retrograde tracer fluorogold into this pPVTh. We focused onthe results of tracer injected into the posterior division ofthe PVTh because this site specifically exhibits increased neuronalactivity in response to restraint in chronically stressed animalsand it projects preferentially to the amygdala subnuclei thatalso showed increased neuronal activity in chronically stressedcompared with control rats (Bhatnagar and Dallman, 1998).

We found fluorogold-labeled cells in the amygdala, zona incerta, scattered hypothalamic sites, supramammillary area, and VTAafter application of fluorogold into the pPVTh. We also foundfluorogold-containing neurons in a number of regions further caudalin the brainstem, including the lateral parabrachial nuclei, periaqueductalgray, and the pontine dorsal raphe (B6). Labeling of cells withfluorogold in most of these structures has been shown previouslyafter injection of this tracer into the medial/posterior divisionof the PVTh (Eberhart et al., 1985; Otake and Nakamura, 1995;Otake and Ruggiero, 1995).

However, we became particularly interested in the lateral parabrachial, dorsal raphe, and periaqueductal gray for two reasons.First, our previous studies showed a tendency for preferentialincreases in the lateral parabrachial and dorsal raphe in thenumbers of Fos-positive cells after acute restraint in chronicallystressed rats compared with naïve controls (Bhatnagar and Dallman,1998). Second, the lateral parabrachial and dorsal raphe nucleias well as the periaqueductal gray are important in mediatinggustatory responses, analgesia, and arousal, among other functions(Saper and Loewy, 1980; Eberhart et al., 1985; Bandler and Shipley,1994; De Oca et al., 1998; Lonstein et al., 1998). These nucleihave widespread connections with brainstem and spinal sensoryareas and with hypothalamic, cortical, and limbic cell groups.They also have all been implicated in the regulation of ACTH secretion(Ward et al., 1976; Bereiter and Gann, 1990; Carlson et al., 1994).Additionally, the lateral parabrachial, dorsal raphe, locus coeruleus,and periaqueductal gray all provide the amygdala, the paraventricularnuclei of the hypothalamus, and the PVTh with sensory input relatedto these functions (Fulwiler and Saper, 1984; Floyd et al., 1996).Thus, it seemed likely that projections from these brainstem cellgroups to the PVTh would be important in terms of the functionalregulation of HPAactivity.

We approached our investigation of the role of these brainstem projections to the PVTh by determining potential peptides orneurotransmitters contained in these projections. Although thePVTh is richly innervated by peptidergic and aminergic fibers(Freedman and Cassell, 1994; Otake and Ruggiero, 1995), CCK heavilyinnervates the posterior PVTh (Hunt et al., 1987; Freedman andCassell, 1994; Otake and Ruggiero, 1995), and the PVTh is decoratedwith CCK receptors, primarily CCK-B (Harro et al., 1993; Hondaet al., 1993; Benedetti, 1997). In common, the lateral parabrachial,dorsal raphe, and periaqueductal gray synthesize CCK (Vanderhaeghen,1985). Furthermore, CCK has effects on HPA activity and is wellknown for its effects on food intake, and we have shown previouslythat the pPVTh is involved in both these functions (Bhatnagarand Dallman, 1998, 1999). Together, these studies pointed to apotentially important role for CCK cell bodies in the lateralparabrachial, dorsal raphe, and periaqueductal gray as mediatorsfor the pPVTh regulation of HPA activity. We first determinedwhether these brainstem areas did indeed provide CCK inputs tothe PVTh by examining the distribution of fluorogold-labeled cellsthat also synthesized CCK. Of the regions containing fluorogold-labeledcells, only cells in the central and dorsal divisions of the lateralparabrachial nuclei, the ventrolateral periaqueductal gray, andcaudal dorsal raphe nuclei also contained CCK mRNA. Thus, thesestructures constituted the sources of afferent CCK inputs to thePVTh.

We next tested whether the CCK-containing inputs to the PVTh were involved in regulating HPA activity by blocking the predominantCCK-B receptors in the PVTh with injections of the CCK-B antagonistPD 135,158. Blockade of PVTh CCK-B receptor selectively enhancedACTH responses to restraint in chronically stressed animals buthad no effect on ACTH responses in control animals. Thus, blockingthe effects of endogenously released CCK in the PVTh is selectiveto the state of chronic stress. Furthermore, we found that thiseffect is probably not attributable to a change in CCK-B receptorexpression in the PVTh as a consequence of chronic stress exposure,because CCK-B receptor mRNA was not different between controland chronically stressed animals. Therefore, as in our previousfindings with lesions of the PVTh, blockade of CCK-B receptorsin this region provides further evidence of the PVTh as a siteat which previous stress information is processed. That is, thePVTh has a state-dependent effect on the regulation of novel,acute stress-induced ACTHsecretion.

On the basis of these effects of the CCK-B receptor antagonist, we expected that injection of a CCK-B receptor agonist intothe PVTh before restraint might further inhibit the ACTH response.However, injection into the PVTh of agonists specific either toCCK-B [unsulfated CCK-8 (Benedetti, 1997)] or CCK-A [sulfatedCCK-8 (Benedetti, 1997)] receptors had no effect on ACTH responsesto restraint in either control or chronically stressed animals.It may be that the timing or dose of the agonist administeredwas inappropriate although both have been used in studies in whichsimilar doses of these agonists were effective when microinjectedinto specific brain regions (Bloch et al., 1989; Crawley, 1992).Alternatively, it is possible that CCK effects in the paraventricularthalamus require corelease of another transmitter. For example,serotonin from the raphe or CRF from the parabrachial (Otake andNakamura, 1995) may act in concert with CCK at the paraventricularthalamus in chronically stressed rats but may not be releasedin control rats since neither blockade nor stimulation had anyeffect in this group. Thus, we hypothesize that, in chronicallystressed animals, the CCK input to the pPVTh is specifically activatedand that the pPVTh then further activates an upstream pathwaythat ultimately acts at the PVN to determine HPA responsivenessin chronically stressedindividuals.

The critical controls in these microinjection studies were provided by results from the injection of drug into areas otherthan the PVTh, our missed groups. In Experiment 3 there were nosignificant differences between injection of vehicle into thePVTh and injection of the drugs into areas other than the PVTh.These results support our contention that any effects of injectingthe CCK-B antagonist or either agonist into the PVTh are specificto the actions of these drugs in the PVTh and not caused by anaction at some othersite.

On the basis of the present data, we propose that ascending CCKergic pathways originating in the lateral parabrachial, dorsalraphe, and/or periaqueductal gray to the pPVTh are recruited inchronically stressed rats exposed to a new stress stimulus. Thisnovel stressor results in the release of CCK that acts via associationwith CCK-B receptors in the PVTh to cause inhibition of HPA responsesto stress. The lack of effect of either CCK-B receptor agonistsor antagonists in control animals suggests that the CCK pathwaysto the PVTh are not recruited in control animals in response toacute restraint. Furthermore, it is likely that this recruitmentof ascending CCK pathways to the pPVTh in chronically stressedanimals occurs only under stimulated conditions of a novel stressorand not under basal conditions because basal HPA activity is notdifferent between control and chronically stressed animals. Thus,after novel stress, the magnitude of the ACTH response is constrainedby release of CCK into the pPVTh in chronically stressed animalseven in the presence of the known facilitatory effect of previousstress on ACTH secretion (Akana and Dallman, 1997).

Our results do not preclude the possibility that neurotransmitters or peptides, other than CCK, are released into the pPVThand either constrain or produce facilitation of HPA activity.Indeed, the existence of afferents to the pPVTh originating inthe locus coeruleus and dorsal raphe would suggest that norepinephrineand serotonin may also play a role in PVTh regulation of HPA activityunder chronic stress conditions. Nevertheless, our data suggestan important role for CCK in this process. Together, the presentresults and our related work demonstrate a mechanism by whichplasticity in the regulation of HPA activity occurs as a consequenceof previous chronic stress. There is recruitment of CCK pathwaysinnervating the PVTh that occurs exclusively in animals that haveexperienced previous chronic stress. Because of the limbic projectionsof the PVTh, it is likely that this plasticity produced by chronicstress is not unique to regulation of the HPA axis but might alsooccur in neural circuits that underlie the effects of chronicstress on anxiety and fear-related behavior, energy balance (Bhatnagarand Dallman, 1999), and sympathetic (Bhatnagar et al., 1995) andimmune function (Bhatnagar et al., 1996), as well as behavioraland cardiovascular responses to painful stimuli (Bhatnagar etal., 1998). Our current results provide an anatomic and neuropeptideframework with which to explore further the central mechanismsby which environmental events such as chronic stress can altersubsequent physiology andbehavior.

  FOOTNOTES

Received Aug. 18, 1999; revised May 4, 2000; accepted May 5, 2000.

This research was funded by the National Institute of Diabetes and Digestive and Kidney Diseases Grant 28172 to M.F.D. S.B.was funded by a Medical Research Council of Canada postdoctoralfellowship and a National Alliance for Research on Schizophreniaand Depression Young Investigator award. We thank Allan Basbaumfor discussions regarding data in thismanuscript.
Correspondence should be addressed to Dr. Seema Bhatnagar, Department of Psychology, 525 East University, University of Michigan,Ann Arbor, MI 48109-1109. E-mail: bhatnags{at}umich.edu.

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DISCUSSION
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