Chronic Social Stress Alters Levels of Corticotropin-Releasing Factor and Arginine Vasopressin mRNA in Rat Brain

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Volume 17, Number 12, Issue of June 15, 1997 pp. 4895-4903
Copyright ©1997 Society for Neuroscience

Chronic Social Stress Alters Levels of Corticotropin-Releasing Factor and Arginine Vasopressin mRNA in Rat Brain

David S. Albeck⁴, Christina R. McKittrick¹, D. Caroline Blanchard², Robert J. Blanchard², Julia Nikulina², Bruce S. McEwen¹, and Randall R. Sakai³
¹ Rockefeller University, New York, New York 10021, ² University of Hawaii, Honolulu, Hawaii 96822, ³ University of Pennsylvania, Philadelphia, Pennsylvania 19104, and ⁴ University of Colorado Health Sciences Center, Denver, Colorado 80262

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

In the visible burrow system model of chronic social stress, male rats housed in mixed-sex groups quickly form a dominancehierarchy in which the subordinates appear to be severely stressed.A subgroup of subordinates have an impaired corticosterone responseafter presentation of a novel restraint stressor, leading to theirdesignation as nonresponsive subordinates. To examine the mechanismunderlying the blunted corticosterone response in these animals,in situ hybridization histochemistry was used to quantify corticotropin-releasingfactor (CRF) and arginine vasopressin (AVP) mRNA expression inthe brain. In two separate visible burrow system experiments,the nonresponsive subordinates expressed a significantly loweraverage number of CRF mRNA grains per cell in the paraventricularhypothalamic nucleus compared with stress-responsive subordinates,dominants (DOM), or cage-housed control (CON) rats. The numberof CRF mRNA labeled cells was also significantly lower in nonrespondersthan in responsive subordinates or DOM. In the central amygdala,CRF mRNA levels were increased in both groups of subordinatescompared with CON rats, whereas responsive subordinates exhibitedhigher levels than the DOM rats as well. AVP mRNA levels did notvary with behavioral rank in any subdivision of the paraventricularhypothalamic nucleus. In the medial amygdala, the number of cellsexpressing AVP mRNA was significantly greater in CON rats comparedwith both groups of subordinates, although the average numberof AVP mRNA grains per cell did not vary with rank. In addition,the number of AVP-positive cells significantly correlated withplasma testosterone level.
Key words: stress; corticosterone; CRF; AVP; in situ hybridization; neuropeptide

INTRODUCTION

Adrenal steroids such as corticosterone (CORT) play an important role in mitigating the adverse effects of stress; however,chronic activation of the hypothalamic-pituitary-adrenal (HPA)axis may have pathological consequences for the animal. Exposureto chronic stress has been shown to alter HPA axis responses tosubsequent stressors (Caggiula et al., 1989) as well as to alterbasal HPA activity (Ottenweller et al., 1989, 1992). In addition,stress suppresses testosterone secretion in both rodents and primates,including man (Taché et al., 1980; Armario and Castellanos, 1984;Wheeler et al., 1984; Sapolsky, 1985). Prolonged increases inglucocorticoids elicited by chronic stress or through exogenousadministration can also affect brain physiology (Diamond et al.,1992; Pavlides et al., 1995), neuronal morphology and viability(Sapolsky et al., 1985; Woolley et al., 1990; Magariños and McEwen,1995), and behavior (Katz et al., 1981; Weiss et al., 1981; Garcia-Marquezand Armario, 1987).

Many of these stress-related changes are readily apparent in the visible burrow system (VBS) model of chronic social stress.A dominance hierarchy quickly forms among male rats housed inmixed-sex groups in a complex environment for 14 d. The subordinatemales show sustained elevations in plasma CORT, profound weightloss, impaired testosterone production, thymus involution, andadrenal hypertrophy (Blanchard et al., 1993). In addition, althoughall animals have robust CORT responses to stress before grouphousing, after 2 weeks in the VBS, a subgroup of subordinatesshow an impairment in their ability to produce the characteristicrise in plasma CORT when presented with a novel stressor (Blanchardet al., 1993).

The physiological basis for the attenuated HPA responsiveness in these subordinate rats is currently unclear. The lack ofa stress-induced rise in CORT in the nonresponsive subordinates(NRS) may be attributable to a functional breakdown at some levelof the HPA axis. To determine whether the dysfunction of the HPAaxis of the NRS rats is attributable to alterations in the hypothalamiccorticotropic systems, we examined the effect of chronic socialstress on corticotropin-releasing factor (CRF) and arginine vasopressin(AVP) mRNA levels in paraventricular hypothalamic nucleus (PVN).

In addition, we investigated CRF and AVP mRNA in extrahypothalamic sites such as the amygdala, which sends projections toother limbic structures. In these circuits, the neuropeptidesmay be involved in some of the behavioral changes observed inthe VBS animals, because central CRF projections have been shownto mediate stress-related behaviors in rats (Makino et al., 1994),whereas central AVP projections are involved with aggressive (Koolhaaset al., 1990; Compaan et al., 1993) and sexual (Winslow et al.,1993; Minerbo et al., 1994) behaviors in rodents.

MATERIALS AND METHODS
Experimental procedure. The VBS apparatus and experimental protocol has been described previously in detail (Blanchard andBlanchard, 1990). In brief, the burrow system is comprised ofan open field area (85 × 65 cm) connected to a series of tunnelsand two small compartments. Food and water are available ad libitumin the open field area, which is illuminated on a 12:12 hr light/darkschedule, whereas the remainder of the apparatus is shielded fromthe light.

Data from two VBS experiments are presented. Experimental procedures were similar in the two studies. In both experiments,colonies of five male and two female Long-Evans rats were housedin a VBS for 14 d. In experiment 1, control (CON) rats were eitherindividually housed or housed in male-female pairs, whereas inexperiment 2, all CON rats were housed in male-female pairs. CONmales were age- and weight-matched to a specific colony and maintainedon the same light/dark cycle as the VBS colonies. In experiment1, male rats were removed from the VBS on days 3, 6, 8, and 10,then weighed and returned to their individual home cages for 6hr during the light phase to allow free access to food and water.In experiment 2, rats were removed from the VBS daily and placedin their home cages for 4 hr. Pair-housed CON males were separatedfrom the females during this time.

Behavior was monitored during the dark phase of the light/dark cycle using a video camera and infrared light source. A singledominant was identified for each colony based on wound pattern,body weight, and behavioral analysis of specific offensive anddefensive behaviors and time spent in the open field area.

On day 14, animals were removed from the VBS in the early part of the light cycle. In experiment 1, male rats were taken directlyfrom the VBS and placed in restraint tubes, and a blood samplewas quickly drawn from the tail to determine plasma CORT levelsin the context of the VBS. In experiment 2, males were placedin their home cages for 1 hr before the initial sampling to determinebasal CORT levels outside the VBS. In both experiments, the animalsremained in the restrainer for 1 hr, after which another bloodsample was drawn for measurement of stress levels of CORT. A thirdsample was taken 1 hr after the animals had been removed fromthe restrainers and returned to their home cages.

Prestress, stress, and recovery levels of CORT were determined by radioimmunoassay using rabbit antiserum raised against CORT-21-hemisuccinateBSAS (B21-42, Endocrine Sciences, Calabasas, CA). Assay sensitivitywas 10 pg, and the intra-assay coefficient of variability was2-5%. Plasma testosterone levels were measured using a Coat-a-CountRIA kit (Diagnostic Products, Milford, MA) following the manufacturer'sdirections.

The subordinate rats showed a bimodal distribution of their stress CORT levels, with some animals showing an increase in CORTcomparable with DOM and CON rats, whereas others had little orno increase in CORT at all. Subordinates were defined as nonrespondersif they failed to show an increase of at least 10 µg/dl CORT overthe mean prestress CORT level of all subordinates. Statisticalanalysis (ANOVA followed by Fisher's LSD post hoc test) of theCORT data was performed using the Statview statistical program.

Animals were killed by decapitation on the day after the restraint stress test. Brains were quickly removed, frozen on powdereddry ice, and stored at $-$ 70°C.

In situ hybridization. The in situ hybridization technique used has been described previously in detail (Albeck et al., 1994).Sixteen micrometer coronal sections were cut on a cryostat andthaw-mounted onto gelatin-coated slides. Sections were kept at $-$ 70°C until use. Slides were brought to room temperature in adessicator, fixed in 4% formaldehyde solution, rinsed in PBS,acetylated, dehydrated in a series of ethanol baths, delipidizedin chloroform, and dried.

In situ hybridization histochemistry for CRF was performed on sections from both experiments 1 and 2 using a 48-mer cDNA oligoprobecorresponding to amino acids 22-37 of preprocorticotropin-releasinghormone (Thompson et al., 1987). In situ hybridization for AVPwas performed on sections from experiment 2 using a 27-mer (AVP)directed against amino acids 110-118 of rat prepropressophysin(Schmale et al., 1983). The 3 $'$ end was labeled with [³⁵S]dATP using terminal transferase (Boehringer Mannheim, Indianapolis,IN) following the manufacturer's instructions. Labeled probe waspurified over a Nuctrap column (Stratagene, La Jolla, CA). Typicalactivity was 3-5 × 10⁵ cpm/µl.

Sections were hybridized in a solution of 50% formamide/50% hybridization buffer (600 mM NaCl, 80 mM Tris-HCl, 4 µM EDTA,0.1% sodium pyrophosphate, 0.2% SDS, 0.2 mg/ml heparin, and 10%dextran sulfate) at 42°C overnight. Subsequently, coverslips werefloated off in 1×SSC, and the tissue was washed four times for15 min each at 45°C in baths containing 50% formamide and 50%2× SSC. Slides were then rinsed in 1× SSC for 1 hr at room temperature,dipped in ddH₂O, dipped in 70% EtOH, and dried.

Image analysis and grain-counting. Slides were exposed to Kodak (Rochester, NY) XAR x-ray film, and relative optical densitywas measured by computer-assisted densitometry (Imaging Research,M4 version, St. Catharine's, Ontario). For each animal, an averageoptical density was obtained, consisting of at least three anatomicallymatched brain slices.

Slides were then dipped in Kodak NTB2 emulsion and exposed for varying lengths of time [29 d for CRF in the PVN, 11 d forAVP in the PVN, 45 d for CRF in the central amygdala (ACE), and50 d for AVP in the amygdaloid nucleus (AME)]. Emulsions weredeveloped and counterstained with cresyl violet to histologicallyverify anatomical location.

Two methods of grain-counting were used to quantify CRF and AVP mRNA expression levels in the medial PVN. In both methods,four sections per animal on two different slides correspondingto approximately $-$ 1.8 mm from bregma (Paxinos and Watson, 1982)were counted bilaterally. Background was subtracted from eachreading.

The first method was used to measure CRF mRNA in experiment 1 and to measure AVP mRNA in experiment 2. In the first method,a 300 × 260 µm field of the medial parvocellular region parallelto the third ventricle was digitized for analysis under 20× magnification.The number of grains > 50 cells in this field was quantified usingan annulus 35 µm in diameter. Average parvocellular cell diameterwas 20 µm. An average of 10 annulus readings over portions ofthe field that did not contain cells was used to calculate thebackground value for each individual PVN.

The second grain-counting method was used to quantify CRF mRNA grains in experiment 2. This method consisted of digitizingthe same region of the medial PVN and counting the total numberof grains over this field. This number was then divided by thetotal number of cells present in the field. This approach yieldedslightly lower, but very comparable, average grains per cell comparedwith the first method. Background values were obtained by measuringthe total number of grains in the same size field in cerebralcortex, an area of brain that expresses low CRF mRNA levels. Thenumber of CRF mRNA labeled cells in experiment 2 was not calculated,because the grain-counting method used in experiment 2 did notprovide this measure.

For counting AVP mRNA grains in the AME, three sections per animal were quantified bilaterally. An annulus 35 µm in diameterwas centered around each labeled cell. Only labeled cells (3×background) were counted. Background was obtained by averaging10 annulus placements over areas devoid of cells and was subtractedfrom each cell.

Relative optical density readings and grain-counting procedures were performed with the experimenter blind to the behavioralranking of the subjects. Data were analyzed using one-way ANOVAfollowed by Fisher's LSD post hoc test or by simple regression(Statview program).

RESULTS

Stress responses
Prestress, stress, and recovery plasma CORT levels from both experiments are presented in Figure 1. There were no differencesbetween the single and pair-housed CON rats from both experiments,thus these data have been grouped together. In experiment 1, bloodwas drawn immediately on removal from the VBS for the prestress"VBS" CORT measurement, whereas in experiment 2, rats were removedfrom the VBS and placed into their home cages for 1 hr beforeblood was drawn ("Homecage" CORT). In experiment 1, "VBS" plasmaCORT levels were significantly higher in the dominant (DOM), NRS,and stress-responsive subordinate (SRS) rats compared with CON"Homecage" levels (⁺p < 0.05). The DOM and SRS groups in experiment 1 also exhibitedsignificantly higher levels of CORT at the prestress "VBS" timepoint than when compared with the prestress "Homecage" level ofthe DOM group in experiment 2. All except NRS rats showed thecharacteristic increase in plasma CORT when exposed to 1 hr novelrestraint stress (*p < 0.05 vs NRS rats). The DOM group in experiment2 had significantly lower CORT levels at the recovery time pointthan did CON rats at the recovery time point ( $bullet$ p < 0.05).
Fig. 1. Plasma CORT responses to a novel restraint stressor in animals from both VBS experiments. In experiment 1, prestress CORTwas measured in tail blood samples taken immediately after removalfrom the VBS; in experiment 2, prestress samples were taken afteranimals had been removed from the VBS and placed in their homecages for 1 hr. In both studies, stress CORT levels were measuredafter 1 hr in a plexiglass restrainer, and recovery CORT was measured1 hr after termination of the stressor. Recovery CORT level wassignificantly lower for the DOM group in experiment 2 than theCON rat recovery value. CON animals were combined from both studies.DOM, Dominant rats; NRS, nonresponder subordinate rats; SRS, stress-responsivesubordinate rats. Values represent the mean ± SEM; *p < 0.0001versus NRS rats; ⁺p < 0.05 versus CON rats; p < 0.05 versus the DOM group in experiment 2.
[View Larger Version of this Image (39K GIF file)]

CRF mRNA in PVN
Dark-field photographs of CRF mRNA expression in the PVN are shown in Figure 2; the top row of photographs in Figure 2 illustratesexamples of CRF mRNA levels in experiment 1, whereas the bottomrow of photographs is from experiment 2. The population resultsare presented in Figure 3. In experiment 1 (Fig. 3A), NRS ratsexhibited a statistically lower average number of CRF mRNA grainsper cell than both the DOM and SRS rats (F_(3,27) = 3.58, p < 0.05),whereas in experiment 2 (Fig. 3B), NRS rats expressed significantlyfewer CRF mRNA grains per cell than did DOM, SRS, and CON rats(F_(3,24) = 5.76, p < 0.005). In experiment 1, the average numberof CRF mRNA-labeled cells in the PVN was significantly higherin SRS than in NRS and CON rats, whereas DOM also had a highernumber of labeled cells than did NRS rats (Figure 3C) (F_(3,27)= 6.98, p < 0.001).
Fig. 2. Dark-field photographs of CRF mRNA expression in the PVN of the hypothalamus. In both experiment 1 (top row) and experiment2 (bottom row), NRS rats exhibit significantly lower levels ofCRF mRNA compared with DOM and SRS rats. In experiment 2, NRSrats also have significantly less CRF mRNA compared with CON rats.Scale bar, 100 µm.
[View Larger Version of this Image (101K GIF file)]

Fig. 3. CRF mRNA expression in the PVN of the hypothalamus of VBS animals. A, CRF mRNA in experiment 1 expressed as grains per cell.B, CRF mRNA in experiment 2 expressed as grains per cell. C, Numberof CRF mRNA-labeled cells in experiment 1. Values represent themean ± SEM; *p < 0.05 versus NRS; ⁺p < 0.05 versus CON.
[View Larger Version of this Image (23K GIF file)]

CRF mRNA in the ACE
The dark-field photographs in Figure 4 illustrate examples of CRF mRNA expression within the ACE. Population results showthat SRS and NRS rats have statistically higher levels of CRFmRNA than do CON rats (Fig. 5), whereas SRS rats also had a higherlevel than did DOM rats (F_(3,22) = 5.99, p < 0.05).
Fig. 4. Dark-field photographs of CRF mRNA expression in the ACE. NRS and SRS rats exhibit significantly higher levels of CRF mRNAthan do CON rats. Additionally, SRS rats show greater CRF mRNAexpression than DOM rats. Scale bar, 50 µm.
[View Larger Version of this Image (121K GIF file)]

Fig. 5. Population results of the relative optical density of CRF mRNA levels in the ACE across the behavioral groups. Values representthe mean ± SEM; *p < 0.05 versus CON; ⁺p < 0.05 versus DOM.
[View Larger Version of this Image (23K GIF file)]

AVP mRNA in PVN
As shown in Table 1 (top row), relative optical density measures of AVP mRNA levels in the lateral magnocellular PVN didnot vary across behavioral rank. Grain-counting was used to quantifyAVP mRNA levels in the medial parvocellular PVN. As seen in thesecond and third rows, respectively, of Table 1, neither theaverage number of AVP mRNA grains per cell nor the number of AVPmRNA labeled cells in the medial parvocellular PVN differed significantlyacross ranks.

Table 1. AVP mRNA expression in the paraventricular nucleus (PVN) of the hypothalamus

CON DOM NRS SRS

Magnocell × = 0.780 × = 0.786 × = 0.820 × = 0.775

  ROD SD = 0.074 SD = 0.0667 SD = 0.073 SD = 0.064

Parvocell × = 9.09 × = 10.84 × = 8.69 × = 11.06

  grains/cell SD = 2.46 SD = 2.79 SD = 2.70 SD = 2.87

Parvocell × = 27.53 × = 34.12 × = 25.81 × = 30.89

  ^# Cells SD = 7.67 SD = 8.02 SD = 5.85 SD = 7.27

AVP mRNA data obtained from experiment 2; values are mean (×) ± SD. Top row, Relative optical densities (ROD) for AVP mRNAlevels in the lateral magnocellular PVN. Middle row, Average numberof grains expressed per cell in the medial PVN. Bottom row, Averagenumber of AVP mRNA-labeled cells in the medial PVN. No significantdifferences in AVP mRNA were found across behavioral groups.

AVP mRNA in the AME
Examples of AVP mRNA expression in the AME are shown in the dark-field photographs of Figure 6. The average number of AVPmRNA grains per cell did not differ as a function of behavioralrank in the AME (Fig. 7A). However, the average number of AVPmRNA-labeled cells in the AME did vary with behavioral rank. Posthoc tests revealed that NRS and SRS rats had a significantly lowernumber of AVP mRNA-positive cells than did CON rats (Fig. 7B)(p < 0.05). In addition, there was a significant positive correlationbetween the number of AVP mRNA-positive cells in the AME and plasmatestosterone level (Fig. 8) (Y = 0.54× + 11.05, r² = 0.153, F_(1,24) = 4.32, p < 0.05).
Fig. 6. Dark-field photographs of AVP mRNA expression in the AME. NRS and SRS rats exhibit significantly fewer AVP mRNA-labeled cellsthan do CON rats in the AME. Scale bar, 50 µm.
[View Larger Version of this Image (113K GIF file)]

Fig. 7. Population results showing AVP mRNA expression in the AME. A, Average number of AVP mRNA grains expressed per cell. B, Averagenumber of AVP mRNA-labeled cells in the AME as a function of behavioralrank; *p < 0.05 versus CON.
[View Larger Version of this Image (24K GIF file)]

Fig. 8. Number of AVP mRNA-labeled cells in the AME correlates with plasma testosterone level. Data from individual rats are chartedshowing the positive relationship between testosterone level andnumber of AVP mRNA cells in the AME (Y = 0.54× + 11.05, r² = 0.153, F_(1,24) = 4.32, p < 0.05).
[View Larger Version of this Image (16K GIF file)]

DISCUSSION
Fourteen days of mixed-sex housing in a VBS leads to a variety of stress-related changes in the behavior (Blanchard and Blanchard,1990), endocrine function (Blanchard et al., 1993, 1995), andneurochemistry (Chao et al., 1993; McKittrick et al., 1995, Watanabeet al., 1995) of the male rats. In all animals, total plasma CORTlevels measured immediately after removal from the VBS are elevatedcompared with levels in cage-housed CON rats, suggesting tonicactivation of the HPA axis within the VBS environment.

In addition, a subgroup of subordinates did not exhibit the expected increase in plasma CORT when presented with the novelstressor of restraint. Compared with VBS rats, which showed thestress-induced increase in plasma CORT, NRS rats showed a deficitof CRF mRNA, but not of AVP mRNA, in the PVN. The NRS rats appearto be the most severely stressed in the VBS model, because theyshow the greatest degree of body weight loss and adrenal hypertrophy;the NRS rats also have the lowest levels of testosterone and CORT-bindingglobulin compared with the other VBS groups (McKittrick et al.,1994). Recent evidence indicates that the NRS characteristicsdevelop gradually over the 14 d period in the VBS rats, suggestingthat they are manifestations in individual rats of their responseto the chronic stress situation (our unpublished observations).

NRS and SRS rats show similarities in neuropeptide mRNA levels in the amygdala in contrast to in the PVN. In the amygdala,CRF mRNA expression was elevated in both groups of subordinatescompared with that in the CON rats. SRS rats also showed a higherlevel of CRF mRNA than did DOM rats; the difference between NRSand DOM rats did not reach statistical significance, most likelybecause of the limited number of animals in the NRS group. Theelevated CRF mRNA levels may be the result of the direct effectof CORT on CRF gene expression, because other researchers havereported that plasma CORT correlates positively with CRF mRNAin the ACE, and negatively with CRF mRNA in the PVN (Makino etal., 1994).

CRF and AVP act as neuromodulators in limbic circuits originating in the amygdala. The CRF projections originating in theamygdala are believed to play an important role in the expressionof stress-induced behaviors distinct from the effects of CRF inthe PVN (Makino et al., 1994). The behavioral effects of centraladministration of CRF mimic those seen in response to stress,such as place aversion, increased grooming and locomotor activity,and decreased sexual activity and sleeping (Sirinathsinghji etal., 1983; Sherman and Kalin, 1986; Berridge and Dunn, 1987; Leeet al., 1987; Cador et al., 1992). In stressed animals, CRF administrationpotentiates these behaviors (Britton et al., 1982), whereas CRFantagonists administered intracerebroventricularly or to the ACEcan block the behavioral effects of stress (Berridge and Dunn,1987; Kalin and Takahashi, 1990; Swiergiel et al., 1993). EnhancedCRF expression in the ACE of the subordinates likely contributesto the stress-induced behavioral changes described previouslyin this model (Blanchard and Blanchard, 1990).

AVP mRNA expression in the AME also varied as a function of behavioral rank, with fewer cells expressing AVP in the two subordinategroups compared with CON rats. There was also a significant positivecorrelation between the number of cells expressing AVP and plasmatestosterone levels, suggesting that the decrease in AVP is relatedto the suppression of testosterone in these animals. Althoughthe type II glucocorticoid receptor agonist dexamethasone hasbeen shown to suppress AVP mRNA levels in AME, gonadal steroidsseem to be more important in the regulation of AVP in this region,because the decrease is contingent on a concomitant suppressionof testosterone levels (Urban et al., 1991). Testosterone hasalso be shown to play a key role in the regulation of extrahypothalamicAVP expression in other models, because castration leads to adecrease in AVP mRNA and immunoreactivity, an effect that canbe reversed by testosterone administration (DeVries et al., 1985;Miller et al., 1989; Szot and Dorsa, 1994).

Behaviors mediated by the vasopressinergic circuit arising from the AME include aggression (Koolhaas et al., 1990; Compaanet al., 1993), copulation (Smock et al., 1992), and social recognition(Lehman et al., 1980; Bolhuis et al., 1984; Bluthe et al., 1990).The decreased AVP expression in the AME may play a role in thereduction of aggressive and sexual behaviors in the subordinateanimals after the stress-induced decline in testosterone secretion.

Why are the NRS rats stress-nonresponsive and deficient in CRF mRNA in the PVN?
The results presented here suggest that the failure of the NRS rats to mount a sufficient CORT response to the psychologicalstress of restraint may be attributable to a breakdown in HPAaxis function at the level of the hypothalamus. Although AVP mRNAlevels in the PVN did not vary as a function of behavioral rank,CRF mRNA was significantly altered after VBS housing. In two separateVBS experiments, the amount of CRF mRNA expressed per cell inthe PVN was lower in NRS compared with DOM or SRS rats; in oneexperiment, the CRF mRNA per cell in NRS was lower than in CONrats as well. In experiment 1, the number of CRF mRNA-positivecells in the PVN was also lower in the NRS compared with boththe DOM and the SRS rats, but did not differ from that in theCON rats.

High levels of CRF mRNA expression are not necessary for rats to be able to show a stress-induced rise in plasma CORT, becausethe CON rats have CRF mRNA levels comparable with the NRS rats.The difference between these two groups is the chronic stressof the VBS affecting the HPA axis of the NRS rats. The rats thathave experienced the chronic stress of the VBS and are still capableof showing a CORT response to a novel stressor (DOM and SRS rats)exhibit slightly elevated CRF mRNA expression in the PVN, whereasthe NRS rats do not. This relative increase in CRF expressionis consistent with that seen by others after both acute and chronicstress paradigms (Lightman and Young, 1988; Harbuz and Lightman,1989; Makino et al., 1994, 1995) and probably helps maintain HPAfunction. The increase in CRF expression by DOM and SRS rats abovecontrol levels is likely to be attributable to the effects ofchronic stress within the VBS, because all animals were giventhe acute restraint stress. The number or sensitivity of the CRFreceptors in the pituitary may have decreased in response to chronicstimulation. Increased CRF release may be needed to overcome theeffects of this downregulation. This hypothesis is supported bythe observation that prolonged administration of CRF reduces theACTH and CORT responses to a novel stressor (Tizabi and Aguilera,1992). Another possible explanation might be an increased inhibitoryinput from GABA neurons that synapse on CRF neurons in the PVN(Herman et al., 1996). Additional studies are necessary to evaluatemore fully the mechanisms underlying the NRS phenomenon.

Chronic high levels of glucocorticoids may be partially responsible for the low level of CRF mRNA in the NRS rats via negativefeedback mechanisms. All behavioral ranks within the VBS showelevated CORT levels when blood is drawn immediately on removalfrom the VBS. Plasma CORT provides inhibitory feedback at CRFmRNA expression by acting directly on CRF-secreting neurons andvia inputs to these neurons from the hippocampus. Because theNRS rats have the lowest levels of CORT-binding globulin in additionto elevated total CORT, free CORT is presumably highest in theseanimals. Thus, negative feedback inhibition is likely to be greatestin the NRS rat because of high free CORT combined with the lackof a downregulation in hippocampal type II glucocorticoid receptorsthat is observed in SRS rats (Chao et al., 1993).

Stress-induced increases in plasma CORT return to baseline faster in dominant rats than in subordinates. Only DOM rats showedstatistically lower levels of plasma CORT in the prestress "Homecage"measurements and at the recovery time point in experiment 2. Thissuggests that the mechanisms responsible for terminating the HPAresponse are more efficient in the DOM than in the subordinatesrats. In adrenalectomized rats, administration of the type IIglucocorticoid receptor agonist RU 28362 has been shown to reduceCRF gene expression in the PVN (Albeck et al., 1994), whereasin intact rats, dexamethasone treatment reduces both basal andstress-stimulated levels of CRF mRNA (Lightman and Young, 1989),with the PVN implicated as a key site of dexamethasone action(Harbuz and Lightman, 1989). The hippocampus, an area that containssubstantial concentrations of both type I and type II glucocorticoidreceptor subtypes (McEwen et al., 1968; Reul and De Kloet, 1985),has been shown to play a role in the CORT-mediated containmentof HPA responses (Jacobson and Sapolsky, 1991; Feldman and Conforti,1980). As suggested above, inhibitory inputs from the hippocampusto the PVN (Herman et al., 1996) may be enhanced in NRS comparedwith SRS rats.

Neural inputs to the PVN from monoaminergic systems are also important regulators of CRF mRNA expression. The PVN receivesinnervation from the serotonergic and noradrenergic systems, bothof which are stimulated in response to stress (Abercrombie andJacobs, 1987; Vahabzadeh and Fillenz, 1994; McKittrick and McEwen,1996) and have been implicated in the regulation of CRF release(Plotsky et al., 1989; Pan and Gilbert, 1992). Both of these systemsare also modulated by chronic social stress in the VBS model (McKittricket al., 1995; Watanabe et al., 1995), and differential regulationof these neurotransmitter systems may contribute to the differencesin CRF mRNA expression seen among the NRS rats and other groups.

Many of the behavioral and endocrine changes in the subordinate rats are similar to those seen in humans with depressive illness.Both subordinate animals and depressed patients have lower overallactivity levels and disrupted patterns of sleep, feeding, andsexual activity (Gold et al., 1988a; Blanchard et al., 1995).Function of the HPA axis is often dysregulated in depressed patientsas well, because many exhibit elevated basal cortisol concentrations,impaired glucocorticoid feedback, and blunted responses to stimulation(Gold et al., 1988b; Pearson Murphy, 1991; Krishnan et al., 1993;Platt et al., 1994). Furthermore, regarding one specific aspectof our results, the lack of HPA stress response in NRS rats maybe related to a phenomenon found in a subset of depressed humansubjects, who show blunted responsiveness of their HPA axis (Plattet al., 1994; Kim et al., 1995). Additional study of the neurochemicalchanges associated with HPA dysfunction after chronic social stressmay provide insight into the mechanisms responsible for similarchanges in humans with depressive illness.

In conclusion, chronic psychosocial stress in the VBS is particularly stressful to subordinate rats, some of which show aprogressive development of a paradoxical "Stress Nonresponsive"state characterized by reduced levels of CRF mRNA in the PVN inconjunction with impaired CORT responses to stress. We postulatethat this state is the result of enhanced inhibitory input toPVN neurons attributable to increased glucocorticoid feedbackor to increased inhibitory neural input.

FOOTNOTES

Received Aug. 21, 1996; revised April 2, 1997; accepted April 8, 1997.

This work was supported by National Science Foundation Grants IBN95-11349 (D.C.B., R.J.B., R.R.S.) and MH41256 (B.S.M.).

Correspondence should be sent to Prof. David Albeck, University of Colorado Health Sciences Center, 4200 East 9th Avenue,Department of Basic Sciences and Oral Research, Campus Box C286,Denver, CO 80262.

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