Regulation of a Putative Neurotransmitter Effect of Corticotropin-Releasing Factor: Effects of Adrenalectomy

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Volume 17, Number 1, Issue of January 1, 1997 pp. 401-408
Copyright ©1997 Society for Neuroscience

Regulation of a Putative Neurotransmitter Effect of Corticotropin-Releasing Factor: Effects of Adrenalectomy

Luis A. Pavcovich and Rita J. Valentino
Department of Psychiatry, Allegheny University, Philadelphia, Pennsylvania 19102

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

This study tested the hypothesis that endogenous glucocorticoids regulate a putative neurotransmitter function of corticotropin-releasingfactor (CRF) in the locus coeruleus (LC). LC spontaneous dischargeand activation by intracerebroventricularly administered CRF,hypotensive challenge, sciatic nerve stimulation, and carbacholwere compared in adrenalectomized and sham-operated halothane-anesthetizedrats. LC spontaneous discharge was higher in adrenalectomizedversus sham-operated rats. Intracoerulear microinfusion of a CRFantagonist decreased LC discharge rates of adrenalectomized ratsto rates comparable with those observed in sham-operated ratsbut had no effect in sham-operated rats. The CRF dose-responsecurve was shifted in a complex manner in adrenalectomized rats,suggesting that a proportion of CRF receptors were occupied beforeCRF administration, and low doses of CRF were additive. Higherdoses of CRF produced effects that were greater than predictedby simple additivity. Hypotensive challenge increased LC dischargerates of adrenalectomized rats by a magnitude greater than thatpredicted on the basis of additivity. In contrast, LC responsesto carbachol and sciatic nerve stimulation were similar in bothgroups. The results suggest that adrenalectomy enhances tonicand stress-induced CRF release within the LC and also alters postsynapticsensitivity of LC neurons to CRF. Because adrenalectomy also altersrelease of neurohormone CRF, the present study suggests that CRFactions as a neurohormone and as a neurotransmitter in the LCmay be co-regulated. Such parallel regulation may underlie thecoexistence of neuroendocrine and noradrenergic dysfunctions instress-related psychiatric disorders.
Key words: corticotropin-releasing factor; locus coeruleus; adrenalectomy; stress; hypotension; carbachol; norepinephrine; nitroprusside; rats

INTRODUCTION

Corticotropin-releasing factor (CRF) has been hypothesized to act as both a neurohormone and a brain neurotransmitter (Valeet al., 1981, 1983; Rivier et al., 1985; Dunn and Berridge, 1990;Owens and Nemeroff, 1991; Valentino et al., 1993). It is wellestablished that hypothalamic CRF is released into the medianeminence, where its actions on anterior pituitary corticotrophspromote secretion of adrenocorticotropin (Vale et al., 1981, 1983;Rivier et al., 1985). The neurotransmitter role of CRF is supportedby the widespread distribution of CRF-immunoreactive terminalsand binding sites in brain (Swanson et al., 1983; DeSouza et al.,1985; DeSouza, 1987; Sakanaka et al., 1987). Consistent with this,central CRF administration mimics many autonomic and behavioralcomponents of stress responses, even in hypophysectomized animals(Dunn and Berridge, 1990; Owens and Nemeroff, 1991; Valentinoet al., 1993). Moreover, central administration of CRF antagonistsor antisera prevents several autonomic and behavioral responseselicited by stressors (Brown et al., 1985; Britton et al., 1986;Tazi et al., 1987; Kalin et al., 1988; Swiergel et al., 1992;Tache et al., 1993). Parallel actions of neurohormone and neurotransmitterCRF may coordinate endocrine with autonomic and behavioral componentsof the stress response.

The noradrenergic nucleus locus coeruleus (LC) is one site at which CRF may function as a neurotransmitter (Valentino et al.,1993). This is supported by recent ultrastructural evidence forsynaptic contacts between CRF-immunoreactive terminals and LCdendrites (Van Bockstaele et al., 1996). CRF increases LC dischargerates (Valentino et al., 1983; Valentino and Foote, 1988) andnorepinephrine release in LC target regions (Lavicky and Dunn,1993; Page and Abercrombie, 1995; Smagin et al., 1995). LC activationelicited by certain physiological stimuli is prevented or attenuatedby microinjection of CRF antagonists into the LC (Valentino etal., 1991; Curtis et al., 1994; Florin et al., 1995). Finally,certain immunological, autonomic, and behavioral responses tostressors can be mimicked by CRF administration into the LC (Butleret al., 1990; Caroleo et al., 1993; Monnikes et al., 1994; Rassnicket al., 1994).

The neurohormone action of CRF is highly regulated by glucocorticoids, which affect CRF synthesis and release (Paull and Gibbs,1983; Plotsky and Sawchenko, 1987; Bradbury et al., 1991; Dallmanet al., 1992). This regulation is demonstrated by the effectsof adrenalectomy, which include enhanced CRF synthesis in paraventricularhypothalamic neurons (Sawchenko et al., 1984; Jingami et al.,1985; Young et al., 1986; Imaki et al., 1991) and release intothe median eminence (Suda et al., 1983; Plotsky and Sawchenko,1987; Fink et al., 1988). Previous stress also alters CRF neurohormonefunction (Dallman et al., 1992). Thus, transcription of CRF mRNAin paraventricular hypothalamic neurons, the number of CRF-immunoreactiveneurons in this nucleus, and CRF content in the median eminenceare all altered by repeated or chronic stress (Chappell et al.,1986; Imaki et al., 1991; De Goeij et al., 1992; Mamalaki et al.,1992; Bartanusz et al., 1993).

In contrast to neurohormone CRF, little is known regarding regulation of the putative neurotransmitter actions of CRF. Recentfindings from this laboratory indicate that repeated stress sensitizesLC neurons to low doses of CRF (Curtis et al., 1995). The presentstudy was designed to determine whether adrenalectomy selectivelyaffects the putative neurotransmitter function of CRF in the LC.LC spontaneous discharge rate, activation by exogenous CRF, endogenousCRF (via hypotensive challenge), a muscarinic agonist (carbachol),and an excitatory amino acid input (sciatic nerve stimulation)were quantified and compared in adrenalectomized and sham-operatedrats in the halothane-anesthetized state.

MATERIALS AND METHODS
Animals. The subjects were adult male Sprague Dawley rats (Taconic Farms, Germantown, NY) weighing ~300 gm at the beginningof the experiments. Rats were initially housed three to a cagein a controlled environment (20°C, 12 hr light/dark cycle, lightson at 7:00 A.M.). Food and water were available ad libitum.

Adrenalectomy. Surgical adrenalectomy and sham adrenalectomy were performed under pentobarbital (50 mg/kg, i.p.) anesthesiavia the dorsolateral approach. Surgery was done 14 d before theexperiments. Rats were housed individually after surgery, andfood was available ad libitum. Sham-operated rats were given water,whereas adrenalectomized rats received drinking water containing0.9% NaCl. The completeness of adrenalectomy was determined byassay of plasma corticosterone at the end of the experiment. Experimentswere done on two rats a day (1 adrenalectomized and 1 sham-operated),and the order of experiments was alternated on a daily basis.

Surgery. The procedures used for recording LC discharge of halothane-anesthetized rats were similar to those described previously(Valentino et al., 1983, 1986, 1991). Rats were anesthetized with2% halothane-in-air mixture administered through a nose cone.The jugular vein was cannulated (PE 100, void volume 70 µl) forinfusion of nitroprusside and/or blood sampling. The femoral arterywas cannulated for blood pressure recordings. A tracheal tubewas inserted, and the halothane delivered through this tube. Theanesthetic was maintained at 1% through the experiment. Body temperaturewas maintained at 36-37°C by a feedback-controlled heating pad.Rats were positioned in a stereotaxic instrument using blunt earbars, and the head was oriented at a 15° angle to the horizontalplane (nose down). The skull was exposed, and a hole (~3 mm diameter),centered at 1.1 mm lateral to the midline and 3.7-3.9 mm caudalto the intersection of midline and lambda, was drilled over thecerebellum for approaching the LC. The dura over the cerebellumwas carefully removed using fine iridectomy scissors. Anotherhole was drilled with its center at 1.0 mm caudal to bregma and1.5 mm lateral to the midline for placement of a 26 gauge cannulato be used for intracerebroventricular drug administration. Thecannula was positioned 5.6 mm ventral to the skull surface, placingits tip in the lateral ventricle.

Recording. For most experiments, a glass micropipette pulled to a 2-3 µm diameter tip (4-7 M $Omega$ ) and filled with 2% pontaminesky blue (PSB) dye in 0.5 M sodium acetate buffer was used torecord LC discharge. This was advanced toward the LC with a micromanipulator.Microelectrode signals were amplified and filtered. Impulse activitywas monitored with an oscilloscope and a loudspeaker to aid inlocalizing the LC. LC neurons were tentatively identified duringthe recording by their spontaneous discharge rates (0.5-5 Hz),entirely positive, notched waveforms (2-3 msec duration) and biphasicexcitatory-inhibitory responses to contralateral hindpaw or tailpinch. When stable, unitary action potentials were isolated; awindow discriminator was used to convert the occurrence of eachaction potential into digital pulses, which were led into a Gatewaycomputer via a CED 1401 Plus interface (Cambridge Electronic Design,Cambridge, UK), using Spike 2 software for on-line visualizationand storage and off-line analysis.

For experiments involving intracoerulear administration of CRF or a CRF antagonist, double-barrel glass micropipettes wereused to record single-unit LC discharge and simultaneously microinfusethe peptide (Akaoka and Aston-Jones, 1991). These consisted ofa recording pipette glued using a photopolymerizing resin (Silux,3 M) next to an infusion pipette (Fisher Scientific, Houston,TX). The recording pipette had a 2-4 µm diameter tip (4-7 M $Omega$ )and was filled with PSB. The infusion pipette (20-50 µm diametertip) was angled at ~30-45°, with its tip adjacent to the tip ofthe recording pipette but 100-120 µm dorsal. This was filled witha solution of either CRF (1 mg/ml) or [DPhe¹²,Nle^21,38, CMeLeu³⁷]r/hCRF(12-41) (DPheCRF_12-41; 0.33 mg/ml) and connectedby PE tubing to a source of solenoid-activated pneumatic pressure(Picospritzer, General Valve, Fairfield, NJ). This infusion pipettewas calibrated such that known volumes could be administered (1mm displacement = 60 nl). Intracoerulear infusions were made byapplying small pulses of pressure (5-25 psi, 10-30 msec in duration)to the peptide containing barrel at a frequency of 0.2-1 Hz todeliver a volume of 30 nl.

Protocol. In experiments designed to determine the effects of adrenalectomy on LC spontaneous discharge rate and dischargeevoked by repeated sciatic nerve stimulation, one to five cellswere recorded in a single tract in individual rats. Once an actionpotential was isolated, spontaneous discharge rate was recordedfor at least 6 min. After this, a trial of 60 sciatic nerve stimuli(1 mA, 0.5 msec duration, 0.1 Hz) was initiated. Stimuli wereapplied through a pair of 25 gauge hypodermic needles insertedinto the medial aspect of the contralateral hindpaw, using a Grassstimulator (S88) and stimulus isolation unit (Isoflex, Ampi).LC discharge activity during these trials was recorded and storedas peristimulus time histograms (PSTHs).

For experiments involving intracoerulear infusion of CRF or DPheCRF_12-41, LC discharge rate was recorded for at least6 min before and after the microinfusion. The movement of solutionthrough the calibrated pipette was observed through a microscopethroughout the infusion. Injection of the entire volume at thisrate usually required 1-2 min.

In experiments designed to determine the effect of CRF or carbachol on LC neurons, discharge rate was recorded for at least9 min before intracerebroventricularly drug or peptide administration.CRF [1, 3, 10, or 30 µg in 3-10 µl artificial CSF (ACSF)] or carbachol(0.09 µg in 3 µl ACSF) was injected intracerebroventricularlyover a period of 30-45 sec, and LC discharge rate was recordedfor at least 15 min after intracerebroventricular administration.

In experiments designed to determine the effect of hypotensive challenge on LC discharge rate, baseline LC discharge ratewas recorded for at least 9 min and then nitroprusside was infusedthrough the intravenous cannula (0.33 mg/ml, 30 µl/min, 15 minduration). LC discharge rate and mean arterial blood pressurewere continuously recorded during the infusion. Mean arterialblood pressure was monitored with a pressure transducer and amplifier,and the signal was led to a computer via a CED 1401 Plus interface,using Spike 2 software.

For all experiments involving drug administration, only one cell from an individual rat was tested.

Histology. The recording site was marked by intophoresis ( $-$ 15 µA, 10 min) of PSB at the end of the experiment. Neutral red(5 µl) was injected through the intracerebroventricular cannulato assure placement in the lateral ventricle. Rats were anesthetizedwith pentobarbital (100 mg/kg, i.p.) and perfused with a 10% solutionof paraformaldehyde in phosphate buffer. Brains were removed andcut to visualize neutral red in the ventricular system. They werethen stored for at least 24 hr in this solution. Frozen 40-µm-thickcoronal sections cut on a cryostat were mounted on gelatinizedglass slides and stained with neutral red for localization ofthe PSB spot. The data presented are from neurons that were histologicallyidentified as being within the nucleus LC (for review, see Valentinoet al., 1983).

Corticosterone and ACTH assay. At the end of the experiments, 1-1.5 ml of blood was taken from the intravenous cannula intoa prechilled microtainer containing EDTA and immediately centrifugedat 3000 × g for 15 min at 4°C. Plasma was collected and storedat $-$ 70°C until the assay. Corticosterone and ACTH were assayedby radioimmunoassay (RIA) using an RIA kit from ICN Pharmaceutical(Costa Mesa, CA).

Data analysis. The mean baseline LC spontaneous discharge rate was calculated from three 3 min periods before any treatment(e.g., nitroprusside infusion, drug administration, or sciaticnerve stimulation). PSTH data were analyzed by dividing the histograminto different time components and determining the discharge ratein each component. The first 500 msec represented unstimulatedor tonic activity. The evoked response was defined as the periodafter the stimulus when the LC discharge rate exceeded the meantonic discharge rate plus 2 SD. LC spontaneous discharge rateand different components of the LC sensory response (e.g., tonicdischarge, evoked discharge, and signal-to-noise ratio) were comparedbetween adrenalectomized and sham-operated rats by the Student'st test for independent samples. Absolute LC discharge rates afteradministration of DPheCRF_12-41 were compared between groupsby the Student's t test for independent samples. Additionally,LC discharge rate before and after DPheCRF_12-41 was comparedwithin groups using the Student's t test for paired observations.The effects of DPheCRF_12-41 on the change in LC dischargerate were compared using a one-way ANOVA with repeated measureswithin groups and a two-way ANOVA for comparisons between groups.The effect of nitroprusside on mean arterial pressure was comparedbetween groups using a two-way ANOVA. The maximum increase inLC discharge rate produced by hypotensive challenge or carbacholadministration were compared between groups using the Student'st test for independent samples. Additionally, the effects of nitroprussideon LC discharge were analyzed within groups using a one-way ANOVAwith repeated measures and a two-way ANOVA for comparisons betweengroups. Statistical significance was considered at p < 0.05.

Drugs. oCRF and DPheCRF_12-41 were generously supplied by Dr. Jean Rivier (Clayton Foundation Laboratories for PeptideBiology, The Salk Institute, La Jolla, CA). The peptides weredissolved in water to make a 1 mg/ml solution. Aliquots (10 µl)of this solution were concentrated using a Savant Speed Vac concentrator.The 10 µg aliquots were stored at $-$ 70°C and dissolved in ACSFon the day of the experiment. Sodium nitroprusside (Sigma Chemical,Saint Louis, MO) was dissolved in saline (0.33 mg/ml) and infusedintravenously at a rate of 30 µl/min for 15 min. Carbachol (Sigma)was dissolved in ACSF (0.03 mg/ml) and administered intracerebroventricularlyin a volume of 3 µl.

RESULTS

LC spontaneous discharge rate and effects of a CRF antagonist
LC activity was recorded from 126 neurons in 48 sham-operated rats and 162 neurons in 52 adrenalectomized rats. LC spontaneousdischarge rate ranged from 0.4 to 3.8 Hz in sham-operated rats,with a mean rate of 1.7 ± 0.1 Hz. This is similar to the meanLC discharge rate in intact halothane-anesthetized rats reportedin previous studies (Curtis et al., 1994, 1995). LC spontaneousdischarge rates of adrenalectomized rats were significantly higher,with a range of 0.5-5.1 Hz, and a mean of 2.3 ± 0.1 Hz (Fig. 1).
Fig. 1. LC spontaneous discharge rate and effects of DPheCRF_12-41 in sham-operated (solid bars) and adrenalectomized (open bars)rats. The ordinate indicates LC discharge rate (Hz). Bars indicatethe mean discharge rate for 126 neurons in sham-operated ratsand 162 LC neurons in adrenalectomized rats (ALL CELLS); or eightcells in sham-operated and six cells in adrenalectomized ratsbefore (Pre) and 3 min after (Post) DPheCRF_12-41. Verticallines represent ± 1 SEM; *p < 0.05, **p < 0.001, t test for independentsamples, comparison between sham-operated and adrenalectomizedrats; Zvp < 0.02, t test for matched pairs, comparison betweenPre and Post.
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As reported previously in intact rats (Curtis et al., 1994), intracoerulear administration of the CRF antagonist DPheCRF_12-41in a dose that prevents the effects of CRF or hypotensive stresson LC discharge (10 ng in 30 nl) had no effect on spontaneousLC discharge rates of sham-operated rats (Figs. 1, 2). Figure2 shows that LC discharge rate remained stable over the time afterintracoerulear administration of DPheCRF_12-41. In contrast,intracoerulear administration of this dose of DPheCRF_12-41decreased LC discharge rates of adrenalectomized rats. After DPheCRF_12-41,LC discharge rates were similar in adrenalectomized and sham-operatedrats (Fig. 1). Figure 2 shows that this effect peaked by 3 minafter injection.
Fig. 2. Time course of the effect of DPheCRF_12-41. A, Continuous chart record of LC discharge rate before and after intracoerulearinfusion of DPheCRF_12-41 (10 ng in 30 nl). The abscissaeindicate time (s). The ordinates indicate LC discharge rate (Hz).The time of infusion is indicated by the bar and D above the traces.The solid horizontal line represents the mean LC discharge ratedetermined over 6 min before DPheCRF_12-41 infusion. Topand bottom traces were from single neurons recorded in a sham-operatedand adrenalectomized rat, respectively. B, Mean effect of DPheCRF_12-41in sham-operated (solid symbols, n = 8) versus adrenalectomizedrats (open symbols, n = 6). The abscissa indicates time afterDPheCRF_12-41 infusion. The ordinate indicates the changein LC discharge rate from baseline (Hz). The effects of DPheCRF_12-41were significantly different in adrenalectomized versus sham-operatedrats (F_(1,97) = 8.3, p < 0.02). Additionally, DPheCRF_12-41significantly decreased LC discharge rate in adrenalectomized(F_(5,41) = 4.9, p < 0.002) but not sham-operated (F_(7,55) = 0.72)rats.
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LC activation by exogenous CRF
CRF (1-30 µg, i.c.v.) increased LC discharge rate in both adrenalectomized and sham-operated rats (Fig. 3), as reported previouslyin intact rats (Valentino et al., 1983). Because mean spontaneousdischarge rates were significantly different in adrenalectomizedversus sham-operated rats, the percentage increase in LC dischargerate could not be used as an endpoint of the CRF effect. Rather,effects were compared and dose-response curves were generatedusing the absolute change in discharge rate as the dependent variable(Fig. 3).
Fig. 3. CRF dose-response curves in sham-operated and adrenalectomized rats. The abscissa indicates the dose of CRF (log scale), andthe ordinate indicates the increase in LC discharge above pre-CRFrates ( $Delta$ Hz). Solid symbols represent experimental data, and opensymbols represent theoretical curves. Solid circles show the CRFdose-response curve generated in sham-operated rats. Solid squaresrepresent the experimentally determined CRF dose-response curvein adrenalectomized rats. Each point represents the mean of 4-10cells, vertical lines represent mean ± 1 SEM. Open circles representthe theoretical curve based on the equation E = E_max[CRF]/ED₅₀+ [CRF] and assuming that E_max = 1.25 Hz and ED₅₀ = 0.82 µg. Opensquares represent the theoretical curve that would be expectedin adrenalectomized rats based on additivity, E = (E_max[CRF +0.8]/K_d + [CRF + 0.8]) $-$ 0.6.
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The maximum effect produced by CRF in sham-operated rats was an increase in LC discharge rate of 1.25 Hz (Fig. 3, solid circles).The ED₅₀ determined by regression analysis was estimated to be0.82 µg, similar to that observed in intact rats (Curtis et al.,1996). The CRF dose-response curve generated in adrenalectomizedrats was shifted to the right of that generated in sham-operatedrats with a somewhat steeper slope (0.9 vs 0.6, respectively)and approached a higher maximum response (Fig. 3, solid squares).

Because the results presented in Figures 1 and 2 suggested that CRF was tonically released in adrenalectomized rats, it waspredicted that a proportion of CRF receptors were occupied beforeCRF administration, and addition of exogenous CRF would resultin an additive effect. Therefore, the experimental dose-responsecurves generated in sham-operated and adrenalectomized rats werecompared with the theoretical dose-response curves that wouldbe predicted on the basis of no previous occupancy or additivity,respectively. The theoretical curve for sham-operated rats shownin Figure 3 was based on the equation E = E_max [CRF]/ED₅₀ + [CRF],where E_max = 1.25 and the ED₅₀ = 0.82 µg. As expected, the CRFdose-effect curve generated in sham-operated rats coincided wellwith the predicted dose-response curve (Fig. 3, cf. solid circles-solidline vs open circles-dashed line). The theoretical dose-effectcurve predicted for additivity was generated based on the assumptionthat the difference in baseline discharge rates between adrenalectomizedand sham-operated rats (0.6 Hz, see Fig. 1) corresponded to adose of ~0.8 µg CRF. The predicted effect of this dose additionis to shift the curve upward for low doses of CRF and approachthe same maximum effect. Subtraction of the baseline effect (0.6Hz) from all points of this curve yielded the predicted dose-effectcurve in adrenalectomized rats based on additivity (Fig. 3, opensquares-dashed line). This curve is shifted downward with a decreasedmaximum response from both the actual (solid circles-solid line)and theoretical (open circles-dashed line) dose-effect curvesfor sham-operated rats. In adrenalectomized rats, the effect oflower doses of CRF (1 and 3 µg) fell on the curve predicted byadditivity (cf. solid squares-solid line vs open squares-dashedline). In contrast, administration of 10 and 30 µg produced effectsthat were much greater than would be predicted on the basis ofadditivity (Fig. 3).

To determine whether the enhanced effects of high doses (10 and 30 µg) of intracerebroventricularly administered CRF in adrenalectomizedrats were attributable to alterations within or outside of theLC, the effects of a near maximally effective dose of intracoerulearlyadministered CRF (30 ng) (Curtis et al., 1996) were compared insham-operated (n = 9) and adrenalectomized (n = 9) rats. MeanLC discharge rates before local microinfusion of CRF in the LCwere 2.2 ± 0.3 Hz and 1.6 ± 0.3 Hz for adrenalectomized and sham-operatedrats, respectively. As was observed after intracerebroventricularadministration of 30 µg CRF, intracoerulear administration of30 ng CRF tended to be more effective in adrenalectomized rats,increasing LC discharge rate by 1.6 ± 0.2 Hz versus 1.0 ± 0.3Hz, but this apparent difference was not statistically significant(p = 0.12). Importantly, on the basis of additivity alone, thisdose would be predicted to be less effective in adrenalectomizedrats.

LC activation by endogenous CRF (hypotensive challenge)
Baseline mean arterial blood pressure was similar in adrenalectomized versus sham-operated rats (84 ± 2 mmHg and 87 ± 2 mmHg,respectively) (Fig. 4B). The time course and magnitude of hypotensionproduced by intravenous infusion of nitroprusside were not differentin adrenalectomized versus sham-operated rats (Fig. 4B). Consistentwith previous reports in intact rats (Valentino and Wehby, 1988),this hypotensive challenge was temporally correlated with an increasein LC discharge rate in both sham-operated and adrenalectomizedrats (Fig. 4A), and the magnitude of the increase in LC dischargerate was similar in both groups (Fig. 4A). In sham-operated rats,hypotensive challenge was approximately as effective as 1 µg CRF(0.72 Hz increase in LC discharge rate) (see Fig. 3B). In contrast,this same challenge produced an effect equivalent to a dose of4 µg CRF (0.78 Hz increase in discharge rate) in adrenalectomizedrats.
Fig. 4. Effect of hypotensive challenge on LC discharge rate and mean arterial blood pressure in sham-operated (solid circles) andadrenalectomized (open circles) rats. The abscissae indicate time(min). Nitroprusside was administered from 0 to 15 min, as indicatedby the bar above the abscissae. A, The ordinate indicates thechange in LC discharge rate above the baseline rate determinedover 9 min before nitroprusside infusion. Each point is the meanof at least five rats. Vertical lines represent ± 1 SEM. Hypotensivechallenge increased LC discharge rates in both adrenalectomizedand sham-operated rats (F_(5,41) = 4.9, p < 0.001 and F_(4,29) =6.7, p < 0.01, respectively), and the magnitude of the increasewas not different (F_(1,9) = 0.15). Mean LC discharge rates beforenitroprusside infusion were 1.5 ± 0.2 and 3.1 ± 0.4 for sham-operatedand adrenalectomized rats, respectively. B, The ordinate indicatesmean arterial blood pressure (mm Hg). The magnitude of hypotensionproduced by nitroprusside infusion was similar in adrenalectomizedand sham-operated rats (F_(1,101) = 2.06, p = 0.17).
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LC activation by an excitatory amino acid input and a muscarinic agonist
The pattern of LC discharge in response to repeated sciatic nerve stimulation, which activates the LC via excitatory aminoacid inputs (Ennis and Aston-Jones, 1988, Ennis et al., 1992),was similar in adrenalectomized and sham-operated rats in thisstudy, as reported in intact rats in previous studies (Valentinoand Foote, 1987). Thus, sciatic nerve stimulation was associatedwith an increase in LC discharge and was followed by a periodof relatively inhibited activity. Like LC spontaneous dischargerate, tonic LC discharge rate determined during the unstimulatedperiod of the trial was significantly higher in adrenalectomized(2.2 ± 0.2 Hz) versus sham-operated rats (1.6 ± 0.2 Hz) (Fig.5A). However, the evoked LC discharge rates were comparable inboth groups (Fig. 5A). Additionally, the ratio of evoked-to-tonicdischarge (signal-to-noise ratio) of the sensory response wassimilar in the two groups (data not shown).
Fig. 5. LC activation by sciatic nerve stimulation (A) and carbachol (B) in sham-operated (solid bars) versus adrenalectomized (openbars) rats. A, The ordinate represents LC discharge rate (Hz).Bars represent the mean rate during the tonic and evoked componentsof the LC response to repeated sciatic nerve stimulation for 21neurons of sham-operated and adrenalectomized rats. Vertical linesrepresent mean ± 1 SEM *p < 0.05, t test for independent samples.B, The ordinate indicates the increase in LC discharge rate abovethe mean discharge rate determined over 9 min before carbachol(0.09 µg, i.c.v.) administration. Bars are the mean of eight ratsin both sham-operated and adrenalectomized groups. Carbachol produceda similar increase in LC discharge rate in both groups of rats(t test, independent samples). The mean LC discharge rates beforecarbachol administration were 1.6 ± 0.2 and 2.4 ± 0.4 Hz for sham-operatedand adrenalectomized rats, respectively.
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Like CRF, carbachol, administered in a dose that was shown previously to be submaximal in increasing LC discharge rate (Valentinoand Aulisi, 1987), significantly increased LC discharge ratesof both adrenalectomized and sham-operated rats (Fig. 5B). However,in contrast to CRF, carbachol produced a comparable increase inLC discharge rates of adrenalectomized and sham-operated rats(Fig. 5B).

Effects of adrenalectomy on plasma corticosterone and ACTH
Plasma corticosterone levels determined at the end of experiments were below the limit of detection in adrenalectomized rats.The mean plasma corticosterone level of the pooled group of sham-operatedrats was 263 ± 27 ng/ml. As reported previously (Bradbury et al.,1991), plasma ACTH levels were greater in the pooled group ofadrenalectomized (1.66 ± 0.04 ng/ml) versus sham-operated rats(0.68 ± 0.006 ng/ml).

DISCUSSION
The present study demonstrated elevated LC spontaneous discharge rates in adrenalectomized rats and a reversal of this effectafter intracoerulear microinfusion of a CRF antagonist. Additionally,the CRF dose-response curve was shifted in adrenalectomized ratsin a manner that suggested that a proportion of CRF receptorswere occupied before CRF administration. Finally, in adrenalectomizedrats, LC responses to hypotensive stress were greater than wouldbe predicted on the basis of additivity. These results supportthe hypothesis that adrenalectomy increases tonic- and stress-elicitedCRF release in the LC. Because LC activation by a muscarinic agonistor an excitatory amino acid input was not altered by adrenalectomy,the changes produced by adrenalectomy may be selective for LC-CRFinteractions. Taken together with studies demonstrating increasedsynthesis and release of neurohormone CRF after adrenalectomy(Paull and Gibbs, 1983; Plotsky and Sawchenko, 1987; Bradburyet al., 1991; Dallman et al., 1992), the present results suggestthat the neurohormone action of CRF and its putative neurotransmitteractions in the LC may be regulated in parallel.

The interpretation that elevated LC discharge rates in adrenalectomized rats result from increased CRF release relies on theselectivity of DPheCRF_12-41 as a CRF antagonist. Our previousstudies support this selectivity, because DPheCRF_12-41 antagonizedLC activation by CRF and hypotensive challenge but not LC activationby sciatic nerve stimulation (Curtis et al., 1994), which hasbeen shown to be mediated by excitatory amino acid inputs to theLC (Ennis and Aston-Jones, 1988; Ennis et al., 1992). Conversely,excitatory amino acid antagonists were ineffective as antagonistsof hypotensive challenge (Valentino et al., 1991). Taken togetherwith the finding that LC discharge rates are consistently higherin adrenalectomized versus sham-operated rats, the antagoniststudy strongly supports the hypothesis that CRF is tonically releasedwithin the LC of adrenalectomized but not sham-operated rats,resulting in elevated spontaneous discharge rates.

The shift in the CRF dose-response curve produced by adrenalectomy, which for low doses was consistent with additivity andprevious occupancy of a proportion of CRF receptors, supportsthe above hypothesis. A shift to the right in the CRF dose-effectcurve in adrenalectomized rats could be associated with a decreasein postsynaptic sensitivity to CRF. Given the high concentrationof corticosteroid receptors in the LC (Harfstrand et al., 1986),the potential for adrenalectomy producing such postsynaptic changescannot be ruled out. However, taken together with the consistentlyhigher LC discharge rates, the effects of the CRF antagonist,the different slope of the dose-response curve generated in adrenalectomizedrats, and the greater apparent maximum effect, the adrenalectomy-associatedshift in the CRF dose-response curve is more likely the resultof a combination of additivity (at low doses of CRF) and a noveleffect of higher doses of CRF (discussed below).

Studies using other endpoints of LC activation are consistent with the hypothesis that the LC-noradrenergic system is tonicallyactivated in adrenalectomized rats. Thus, increased norepinephrineturnover in brain regions innervated by the LC (Javoy et al.,1968), increased tyrosine hydroxylase (TH) expression in LC neurons(measured by immunoblot), and elevated levels cAMP-dependent proteinkinase (which co-varies with TH expression) have been reportedin adrenalectomized rats (Melia et al., 1992). However, otherstudies measuring TH mRNA in LC neurons or activity of TH (asmeasured by DOPA accumulation) have reported a lack of effectof adrenalectomy (Smith et al., 1991; Lachuer et al., 1992). LCdischarge rate may be a more sensitive and direct measure of activation.A recent study showed that LC discharge rates recorded 2 d afteradrenalectomy tended to be elevated, consistent with the presentfindings, although the effect was not statistically significantat this time (Borsody and Weiss, 1996). It is likely that thecellular changes involved in the effects reported in the presentstudy require a longer period of glucocorticoid absence to befully expressed.

The effects of adrenalectomy on LC spontaneous discharge imply that the CRF that activates the LC is negatively regulatedby circulating adrenal steroids. Because glucocorticoid administrationdoes not alter LC activity of intact rats, as indicated by spontaneousdischarge rate (Valentino and Wehby, 1988, 1989), TH level, orcAMP-dependent protein kinase levels in the LC (Melia et al.,1992), it is possible that corticosteroid receptors on CRF afferentsto the LC are sufficiently occupied by endogenous ligand to maskany effect of additional corticosteroid. Thus, in intact rats,tonic secretion of the CRF, which impacts on the LC, is inhibited,and CRF antagonists have no effect on LC discharge rate, as wehave observed in intact rats in previous studies (Valentino etal., 1991; Page et al., 1992, 1993; Curtis et al., 1994) and insham-operated rats in the present study. These observations suggesta role for type 1 (high-affinity), as opposed to type 2 (low-affinity),corticosteroid receptors in the regulation of CRF release in theLC.

The CRF that is responsible for tonic LC activation in adrenalectomized rats could arise from the ventricular system (possiblyas a source of neurohormone CRF) or from CRF terminals in theLC region (neurotransmitter CRF). A diurnal rhythm of CSF CRFlevels has been reported (Owens et al., 1990), but the sourceof this CRF and the effects of adrenalectomy on CSF CRF are unknown.However, to account for the change in LC discharge rate producedby adrenalectomy in this study, the CSF CRF level would have tobe in the range of 1.6 µg/ml (0.8 µg in 500 µl of CSF in the ratventricular system). Because this concentration is much greaterthan that measured in the median eminence, even after stress (e.g.,<1 ng/ml) (Plotsky and Vale, 1984), the possibility that CRF activatingthe LC in adrenalectomized rats arises from the CSF is unlikely.Because CRF-immunoreactive terminals have been visualized in theLC (Swanson et al., 1983; Sakanaka et al., 1987; Valentino etal., 1992) and synapses demonstrated between CRF-immunoreactiveterminals and LC dendrites (Van Bockstaele et al., 1996), it ismore likely that the source of CRF activating the LC in this studyis from terminals within the LC. The neuronal origin of theseterminals and probable sites of corticosteroid regulation areunknown at this time.

LC activation by hypotensive challenge is thought to be mediated by CRF release in the LC, because it is prevented by intracoeruleuaradministration of doses of CRF antagonists that do not alter LCactivation by other stimuli (Valentino et al., 1991; Curtis etal., 1994). In the present study, the magnitude of LC activationby hypotensive challenge in sham-operated rats was similar tothat produced by 1 µg CRF administered intracerebroventricularly.Based on the CRF dose-response curve generated in adrenalectomizedrats, this same challenge would be predicted to produce a muchsmaller increase in LC discharge rate. However, the effect producedby this stimulus in adrenalectomized rats was equivalent to 4µg of CRF. These results suggest that in addition to increasingtonic CRF release, adrenalectomy also results in higher stress-evokedCRF release in the LC. This is consistent with increased pituitaryresponse to stressors in adrenalectomized rats (Rivier and Vale,1987).

The response of LC neurons to high doses of CRF (10 and 30 µg) observed in adrenalectomized rats was not predicted on thebasis of simple additivity. At these doses, the CRF dose-responsecurve became steeper, and the apparent maximum effect was greaterthan predicted. Possible explanations for this include activationof multiple CRF receptors in the LC or activation of other excitatoryinputs to the LC by intracerebroventricularly administered CRF.The finding that similar results were obtained with intracoerulearadministration of a near-maximal dose of CRF argues against thelatter possibility. The possibility that adrenalectomy unmasksan additional effect of CRF on LC neurons that occurs at highdoses requires additional investigation.

That LC responses to CRF are selectively altered by adrenalectomy is suggested by the findings that LC responses to sciaticnerve stimulation and a muscarinic agonist were not differentin sham-operated versus adrenalectomized rats. In intact rats,LC activation by these stimuli is thought to be mediated solelyby excitatory amino acid receptors or muscarinic receptors, respectively(Enberg and Svensson, 1980; Ennis and Aston-Jones, 1988; Enniset al., 1992). Although it is possible that adrenalectomy altersLC responses to these stimuli such that CRF now plays a role inthe mediation of these effects, the present findings showing similarresponses in sham-operated versus adrenalectomized rats argueagainst this possibility.

The implication from these results that a putative neurotransmitter action of CRF is regulated in a similar manner as theneurohormone action of CRF is intriguing, because these actionshave been thought to be either insensitive to regulation or regulateddifferentially. For example, glucocorticoid manipulation alteredpituitary but not brain CRF receptors (Wynn et al., 1984; Haugeret al., 1987), and adrenalectomy affected CRF mRNA levels in paraventricularhypothalamic neurons only (Imaki et al., 1991). In other studies,glucocorticoids reduced CRF mRNA in paraventricular hypothalamicneurons and increased CRF mRNA in amygdala neurons (Swanson andSimmons, 1989; Makino et al., 1994). In contrast, evidence existsfor a facilitation of both CRF neurohormone activity (Dallmanet al., 1992) and CRF neurotransmitter effects in the LC (Curtiset al., 1995) in repeatedly stressed rats. Thus, both adrenalectomyand a previous history of stress may similarly co-regulate bothCRF systems.

Parallel regulation of pituitary and LC activation by CRF has important clinical implications. Dysfunctions in the regulationof neurohormone CRF have been implicated in neuroendocrine disordersthat accompany depression (Gold et al., 1988). Consistent withthis, evidence exists for hypersecretion of neurohormone CRF indepressed subjects (Nemeroff et al., 1984). Hypersecretion ofCRF in the LC could underlie some of the cognitive symptoms ofdepression, such as disturbances of sleep and attention. Importantly,this proposed parallel regulation may explain the coexistenceof neuroendocrine and cognitive symptoms in depression.

FOOTNOTES

Received June 12, 1996; revised Sept. 6, 1996; accepted Oct. 7, 1996.

This work was supported by U.S. Public Health Service Grants MH42796 and MH00840 (a Research Scientist Development Award toR.J.V.). We thank Dr. Jean Rivier for the generous gifts of CRFand DPheCRF_12-41, Dr. Paul McGonigle for comments on datapresentation and interpretation, and Dr. Randall R. Sakai fortechnical advice in performing adrenalectomies. The expert technicalassistance of Mr. Bowen Kang and Ms. Wei Ping Pu is appreciated.

Correspondence should be addressed to Dr. Rita J. Valentino, Department of Psychiatry, Allegheny University MS 403, Broadand Vine Streets, Philadelphia, PA 19102-1192.

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