Modulation of Hypothalamic-Pituitary-Adrenal Function by Transgenic Expression of Interleukin-6 in the CNS of Mice

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Volume 17, Number 24, Issue of December 15, 1997

Modulation of Hypothalamic-Pituitary-Adrenal Function by Transgenic Expression of Interleukin-6 in the CNS of Mice

Jacob Raber, Ross D. O'Shea, Floyd E. Bloom, and Iain L. Campbell
Department of Neuropharmacology, The Scripps Research Institute, La Jolla, California 92037

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

Interleukin-6 (IL-6) and IL-6 receptor mRNA and protein have been reported in different brain regions under normal and pathophysiologicalconditions. Although much is known about the hypothalamic-pituitary-adrenal(HPA) axis stimulation after acute administration, less is knownabout the chronic effects of IL-6 on the function of the HPA axis.In the present study, we examined the function of the HPA axisin transgenic mice in which constitutive expression of IL-6 underthe control of the glial fibrillary acidic protein (GFAP) promoterwas targeted to astrocytes in the CNS. GFAP-IL6 mice heterozygousor homozygous for the IL-6 transgene had normal basal plasma corticosteronelevels but, after restraint stress, showed abnormally increasedlevels in a gene dose-dependent manner. The increased plasma corticosteronelevels in the IL-6 transgenic mice were associated with increasedadrenal corticosterone content and hyperplasia of both adrenalcortex and medulla. Notably, plasma adrenocorticotrophic hormone(ACTH) levels and pituitary ACTH content were either not changedor decreased in these mice, whereas plasma arginine vasopressin(AVP) was increased, supporting a role for AVP in response toacute immobilization stress. The reduced ACTH response togetherwith the adrenal hyperplasia in the IL-6 transgenic mice suggestsdirect activation at the level of the adrenal gland that may bedirectly activated by AVP or sensitized to ACTH. A similar mechanismmay play a role in the blunted ACTH response and elevated corticosteronelevels under pathophysiological conditions observed in humanswith high brain levels of IL-6.
Key words: interleukin-6; hypothalamus; pituitary; adrenal gland; ACTH; corticosterone; HPA axis; transgenic

INTRODUCTION

Interleukin-6 (IL-6) is a multifunctional inflammatory cytokine (Taga and Kishimoto, 1992). IL-6 mRNA has been detected inthe normal rat brain (Schöbitz et al., 1993; De Kloet et al.,1994; Gadient and Otten, 1994, 1995), and IL-6 and IL-6 receptor(IL-6R) mRNAs have been colocalized in several rat brain regions(Schöbitz et al., 1993; De Kloet et al., 1994), including whitematter areas consisting only of fibers and glial cells (Schöbitzet al., 1993). In contrast to the rat, no IL-6 mRNA was detectablein the brain of normal mice (Campbell et al., 1993, 1994). IncreasedIL-6 levels in the mouse brain are implicated in the developmentof neuropathological alterations (Campbell et al., 1994).

Elevated IL-6 levels have been detected in brain, cerebrospinal fluid, and/or plasma of patients with various disorders, includinginfection of the CNS (Frei et al., 1988; Matsuzono et al., 1995)or immunodeficiency diseases such as human immunodeficiency virus(HIV)-1 infection (Biglino et al., 1995), Alzheimer's disease(Bauer, 1994; Huell et al., 1995), multiple sclerosis (Shimadaet al., 1993; Perez et al., 1995), acute cerebral ischemia (Fassbenderet al., 1994), trauma (Amado et al., 1995), depression (Maes etal., 1993, 1995), and schizophrenia (Ganguli et al., 1993). Ultrastructuralstudies on human neurons in tissue culture have demonstrated thatIL-6 treatment induced large cytoplasmic vacuoles in neural cellswith neuronal morphology (Yeung et al., 1995). In addition, humanbrain cell aggregates, astrocytes, and astrocytoma cells can beinduced to secrete IL-6 (Bauer, 1994; Gitter et al., 1995; Yeunget al., 1995).

IL-6 has been reported to stimulate the hypothalamic-pituitary-adrenal (HPA) axis (Harbuz et al., 1992; Hu et al., 1993, Mastorakoset al., 1993, 1994; Spath-Schwalbe et al., 1994) and plasma argininevasopressin (AVP) secretion (Mastorakos et al., 1994). The HPAaxis in humans chronically treated with IL-6 (Mastorakos et al.,1993; Spath-Schwalbe et al., 1994) and in patients with variousdisorders associated with elevated IL-6 levels in the brain andcerebrospinal fluid, including Alzheimer's disease, multiple sclerosis,and depression (Gold et al., 1995; Hatzinger et al., 1995), exhibitsa blunting of adrenocorticotrophic hormone (ACTH) but not cortisolresponses, and the diminished ACTH responses resemble those duringchronic stress (Aguilera, 1994). Most studies have described HPAaxis stimulation after acute IL-6 administration; little is knownabout the chronic effects of IL-6 on the modulation of the HPAaxis. Recently, a transgenic model was established in which constitutiveCNS expression of IL-6, under the control of the glial fibrillaryacidic protein (GFAP) gene promoter, produced progressive neurologicaldisease with a spectrum of neuropathological manifestations, includingneurodegeneration, gliosis (Campbell et al., 1993; Chiang et al.,1994; Heyser et al., 1997), and breakdown of the blood-brain barrier(Brett et al., 1995). This model provides an opportunity to investigatethe chronic effects of IL-6 on the CNS.

The objective of the present study was to determine whether transgenic expression of IL-6 in the CNS of mice can influencethe HPA axis under basal conditions or after activation of theaxis by stress.

MATERIALS AND METHODS
Animals. Transgenic mice expressing IL-6 under the control of the GFAP promoter were generated as described previously (Campbellet al., 1993). IL-6 transgenic mice of the G167 line (3-6 monthsof age) and their nontransgenic littermates were used in the currentexperiments. Mice were housed at no more than four per cage underconditions of constant temperature (18°C), regular light cycle,and access to water and food ad libitum. To avoid circadian variation,we tested or killed the mice between 10:00 and 12:00 A.M.

Dissection of hypothalami and amygdala. Mice were killed by decapitation, and the brain was rapidly removed. A brain slicer(San Diego Instruments, San Diego, CA) was used to obtain a 1.5-mm-thickcoronal slice, including structures $-$ 0.7 mm caudal to bregma,according to Slotnick and Leonard (1975). Subsequently the hypothalamusand amygdala were dissected out as described previously (Raberet al., 1997). The dissected tissues were frozen on dry ice andstored at $-$ 70°C until assay for AVP or corticotropin-releasingfactor (CRF) immunoreactivity (n = 10 mice per group).

Immobilization stress. In experiments designed to compare basal plasma corticosterone levels between IL-6 transgenic miceand wild-type littermates, mice were anesthetized with metofanefor 2 min and subsequently tail-bled using heparinized capillarytubes (Natelson; Baxter, McGaw Park, IL) into microfuge tubesthat were kept on ice (n = 5-10). These were considered baselinevalues. The mice used to determine basal plasma ACTH levels wereanesthetized, killed by decapitation, and bled into EDTA-containingtubes (Microtainer; Becton Dickinson, Rutherford, NJ) (n = 5-10).

Restraint stress was used to study whether any IL-6 effect on plasma ACTH and corticosterone was gene dose-dependent. Transgenicmice or controls were placed in a restrainer for 5 or 20 min,anesthetized (as above), killed by decapitation, and bled intoEDTA-containing tubes. After centrifugation at 10,000 × g for10 min at 4°C, supernatants were stored at $-$ 70°C until assay forcorticosterone or ACTH (n = 8-10). To determine the effect ofIL-6 on the pituitary ACTH content and the hypothalamic and amygdaloidAVP and CRF contents, we anesthetized the mice with metofane,and the pituitaries were dissected out and placed on dry ice untilextraction and assay for ACTH, AVP, or CRF (n = 10 mice per group).To assess the effects of IL-6 on adrenal corticosterone content,we stressed the mice for 5 min and anesthetized them (as above),and the adrenals were dissected out and placed on dry ice untilextraction for corticosterone determination.

Hypothalamic and amygdaloid AVP and CRF and pituitary ACTH extraction. The hypothalamic and amygdaloid AVP and CRF and thepituitary ACTH were extracted by addition of 500 µl of 2N aceticacid. Samples were then boiled for 10 min, cooled on ice, andsonicated twice for 3 sec with a Vir Sonic 50 sonicator (The VirtisCompany, Gardiner, NY). The sonicates were centrifuged at 10,000× g for 10 min, and after removal of an aliquot for protein determination(Micro BCA protein assay reagent kit; Pierce, Rockford, IL), samplescontaining 450 µl were lyophilized overnight (Freeze mobile 5SL;The Virtis Company). The lyophilized samples were resuspendedin 450 µl of radioimmunoassay (RIA) buffer (see below) and storedat $-$ 70°C until assay for AVP, CRF, or ACTH immunoreactivity.

Adrenal corticosterone extraction. For adrenal corticosterone extraction, the adrenals were homogenized in 5 ml of 0.1 M PBS,pH 7.4, using a Polytron (The Virtis Company). After adding 5ml of iso-octane and 5 ml of ethylacetate, the samples were vortexedfor 5-8 min using a multitube vortexer and centrifuged at 4000rpm for 5 min in an Omnifuge RT, and the upper organic phase wasextracted according to the protocol of Mellon et al. (1980), asmodified by Akwa et al. (1993). The extraction procedure was repeatedtwice, and the organic phase was evaporated under a stream ofnitrogen gas at 60°C. The pellets were resuspended in 400 µl ofmethanol and 600 µl of steroid diluent (ICN Biomedicals, Cleveland,OH) and stored in the dark at 4°C until assay for corticosterone.

Adrenal histology. To investigate the effect of IL-6 on adrenal structure, we examined the histological appearance of adrenalglands from IL-6 transgenic mice. The adrenal glands were formalin-fixedand paraffin-embedded. Sections (5 µm) were stained with hemotoxylinand eosin, and bright-field photographs were taken on a ZeissAxiophot microscope.

Plasma AVP extraction. To investigate the effect of IL-6 on plasma AVP levels, we used 5 min restraint-stressed IL-6 transgenicmice anesthetized as described above and bled into EDTA-containingtubes (Microtainer; Becton Dickinson). AVP was extracted fromthe plasma after addition of chilled ethanol by vortexing for2 min at room temperature using a multitube vortexer, centrifugingat 2000 × g at 4°C for 15 min, decanting the supernatant intoclean tubes, and evaporating the supernatants to dryness at 37°Cunder a stream of nitrogen gas using a Reacti-Vap III.

AVP and CRF RIA. The concentrations of AVP and CRF were measured in polypropylene tubes by RIA according to the method ofSkowsky et al. (1974), modified by Weitzman et al. (1978), usinga specific rabbit polyclonal antibody against AVP (gift from Dr.A. Burlet, Bordeaux, France) or CRF (gift from Dr. W. Vale, TheSalk Institute, La Jolla, CA) and synthetic vasopressin (giftfrom Dr. P. Plotsky, Atlanta, GA) or synthetic CRF (gift fromDr. W. Vale), as reported previously (Raber et al., 1994, 1995).¹²⁵I-AVP was obtained from Amersham (Arlington Heights, IL), and¹²⁵I-CRF was from DuPont NEN (Boston, MA). Pretitered goat anti-rabbitand normal rabbit serum were obtained from Peninsula Laboratories(Belmont, CA). All standards were measured in triplicate and thesamples in duplicate. The lower detection limit of the assay was3 pg/tube (100 µl of sample volume). The intra- and interassaycoefficients of variation were 3 and 10% for the AVP RIA and 4and 11% for the CRF RIA, respectively.

ACTH and corticosterone RIA. Plasma ACTH was determined using a ACTH RIA kit (Nichols Institute, Capistrano, CA). The intra-and interassay coefficients of variation were 3 and 7%, respectively.Plasma corticosterone was determined using a corticosterone RIAkit for rats and mice (ICN Biomedicals). The intra- and interassaycoefficients of variation were both 7%.

RNA isolation. Hemibrains were removed and snap-frozen in liquid nitrogen. Poly(A⁺)-enriched RNA was isolated, according to the method of Badleyet al. (1988). Briefly, hemibrains were placed in 10 ml of lysisbuffer (0.2 M NaCl, 0.2 M Tris-HCl, pH 7.5, 1.5 mM MgCl₂, 2% SDS,and 200 µg/ml proteinase K) and immediately homogenized. Afterincubation for 60 min at 45°C, the NaCl concentration of the lysatewas adjusted to 0.5 M, and the lysate was mixed with 40 mg ofoligo-dT cellulose (Invitrogen, San Diego, CA) that had been pre-equilibratedin binding buffer (0.5 M NaCl and 0.01 M Tris-HCl, pH 7.5). Afterincubation of the mixture for 60 min at 25°C with gentle rockingand a subsequent wash with binding buffer, poly(A⁺) RNA was eluted from the oligo-dT cellulose with 0.5 ml of elutionbuffer containing 0.01 M Tris-HCl, pH 7.5, precipitated in ethanol,dried, and resuspended in 25 µl of elution buffer. The RNA concentrationwas determined by UV spectroscopy at 260 nm.

Northern blot analysis. For Northern blot analysis, 5 µg of poly(A⁺) RNA was denatured, electrophoresed in a 1% agarose and 2.2 Mformaldehyde gel, and transferred to a nylon membrane. The membranewas prehybridized in hybridization buffer, containing 6× saline-sodiumphosphate-EDTA (SSPE) buffer, pH 7.6, 50% formamide, 5× Denhardt'ssolution, 0.2% SDS, and 10 mg/ml Salmon sperm DNA, for 1 hr at45°C and hybridized overnight at 45°C with ³²P-labeled cDNA probes. The AVP cDNA probe from rat was a giftfrom Dr. P. P. Sanna, La Jolla, CA. To correct for differencesin loading, we also probed blots for $beta$ -actin. After hybridizationand washing, blots were exposed to x-ray film for 16 hr (for AVP)or 4 hr (for $beta$ -actin) with intensifying screens at $-$ 70°C. Theintensity of the AVP and $beta$ -actin bands was quantified using NationalInstitutes of Health Image 1.57.

Statistical analysis. Data, expressed as mean ± SEM, were analyzed statistically using ANOVA followed by a Tukey test whenappropriate. A p value of <0.05 was considered significant.

RESULTS

Plasma corticosterone levels in GFAP-IL-6 mice
Plasma corticosterone levels were analyzed in IL-6 transgenic mice to determine whether chronic transgene expression of IL-6could modulate the HPA axis. As shown in Figure 1A, basal corticosteronelevels were not significantly altered in heterozygous (+/Tg) orhomozygous (Tg/Tg) IL-6 transgenic mice, compared with nontransgeniclittermate controls.
Fig. 1. Basal and restraint stress-induced plasma corticosterone (A) and ACTH (B) levels in wild-type (+/+) mice and in heterozygous[+/transgenic (Tg)] and homozygous (Tg/Tg) IL-6 transgenic mice.The mice were anesthetized and bled to determine basal levelsor placed in a restrainer for 5 or 20 min, anesthetized, and bledto determine stress-induced levels (n = 5-10 mice per group).
[View Larger Version of this Image (28K GIF file)]

To determine whether there were adaptation and sensitization of the HPA axis in the IL-6 transgenic mice, we assessed theeffect of restraint stress on plasma corticosterone levels in8-week-old mice. After 5 min of restraint stress, there was anincrease in plasma corticosterone levels in nontransgenic mice,which was further increased after 20 min of restraint stress (Fig.1A). After 5 min of restraint stress, the plasma corticosteronelevel in homozygous, but not in heterozygous, IL-6 transgenicmice was significantly higher than in the controls. After 20 minof restraint stress, the plasma corticosterone levels were significantlyhigher in both heterozygous and homozygous IL-6 transgenic micethan in the controls. The increased plasma corticosterone levelsin IL-6 transgenic mice after stress was observed in young aswell as in older animals (6 weeks to 7 months of age) but wasnot age dependent (data not shown).

Plasma ACTH levels and pituitary ACTH content in GFAP-IL-6 mice
Plasma ACTH levels and pituitary ACTH content were analyzed to determine the role of ACTH in the restraint stress-inducedplasma corticosterone elevations. As shown in Figure 1B, therewas no significant difference in the basal plasma ACTH levelsbetween the IL-6 transgenic mice and the controls. After 5 or20 min of restraint stress, plasma ACTH levels increased in bothnontransgenic and IL-6 transgenic mice. However, the rise in plasmaACTH levels in IL-6 transgenic mice was far less than that seenin control mice and was disproportional to the increases in corticosteronelevels. In fact, compared with the controls after 5 min of restraintstress, the plasma ACTH levels were reduced in the IL-6 transgenicmice in a gene dose-dependent manner (Fig. 1B).

Release of pro-opiomelanocortin (POMC)-derived peptides is involved in HPA axis activation. In addition to ACTH, we also assessedthe plasma levels of the POMC-derived $beta$ -endorphin in the IL-6transgenic mice. After 20 min of restraint stress, there was nodifference in plasma $beta$ -endorphin levels between IL-6 transgenicand control mice (data not shown). Next we determined whetherthe reduced ACTH levels might reflect alterations in the pituitaryACTH content. Pituitary ACTH was slightly lower (not statisticallysignificant) in the heterozygous IL-6 transgenic mice than inthe controls and was significantly lower in the homozygous IL-6transgenic mice than in the controls (Fig. 2).
Fig. 2. Pituitary ACTH content in wild-type (+/+) mice and in heterozygous (+/Tg) and homozygous (Tg/Tg) IL-6 transgenic mice. Thepituitary ACTH content was determined as described in Materialsand Methods (n = 9-10 mice per group).
[View Larger Version of this Image (14K GIF file)]

ACTH secretagogues and plasma AVP levels in IL-6 transgenic mice
Plasma AVP levels were analyzed in IL-6 transgenic mice to determine whether AVP could play a direct role in the activationof the adrenal gland. The plasma AVP levels after 5 min of restraintstress were highly elevated in heterozygous IL-6 transgenic mice[123.9 ± 47.3 pg/ml (n = 6)] versus control mice [15.9 ± 3.6 pg/ml(n = 4)].

We next determined the tissue levels of the ACTH secretagogues AVP and CRF in the hypothalamus and amygdala. The hypothalamicand amygdaloid AVP and CRF contents in the heterozygous and homozygousIL-6 transgenic mice were not significantly different from thatof nontransgenic littermates (Table 1). Cerebral AVP mRNA levelswere determined in the IL-6 transgenic and control mice. As shownin Table 2, there was no significant difference in the cerebralAVP mRNA content of heterozygous and homozygous IL-6 transgenicmice compared with that of nontransgenic controls.

Table 1. AVP and CRF content of hypothalamus and amygdala in GFAP-IL-6 transgenic mice

IL-6 transgenic mice AVP content^a (pg/µg protein)
CRF content^a (pg/µg protein)

Hypothalamus Amygdala Hypothalamus Amygdala

+/+ 0.040 ± 0.018 0.016 ± 0.009 0.129 ± 0.035 0.061 ± 0.012

+/Tg 0.030 ± 0.010 0.019 ± 0.006 0.105 ± 0.025 0.043 ± 0.013

Tg/Tg 0.045 ± 0.018 0.024 ± 0.009 0.046 ± 0.009 ND

^a The AVP and CRF contents were determined as described in Materials and Methods; n = 10 mice/group; ND, not determined.

Table 2. Cerebrum AVP mRNA levels in GFAP-IL-6 transgenic mice

IL-6 transgenic mice AVP/actin

Average SEM

+/+ 0.45 0.11

+/Tg 0.54 0.08

Tg/Tg 1.19 0.46

Poly(A⁺) RNA from cerebrum (brain less cerebellum and olfactory bulb) was used for Northern blot analysis as described in Materialsand Methods; n = 3 mice per group.

To determine whether hypothalamic release of CRF and AVP might mediate the increased plasma corticosterone levels, we comparedthe release of these factors from superfused hypothalamic slicesfrom IL-6 transgenic and control mice, but no significant differencein basal or acetylcholine-induced release of either CRF or AVPwas observed (data not shown).

Adrenal corticosterone and pituitary AVP content in IL-6 transgenic mice
As shown in Table 3, after 5 min of restraint stress, there was a significant increase in adrenal corticosterone contentin heterozygous IL-6 transgenic mice compared with nontransgeniclittermate controls, which is in agreement with the increasedplasma corticosterone after restraint stress in the IL-6 transgenicmice. Pituitary AVP levels were examined because increased plasmacorticosterone levels might relate to alterations in pituitaryAVP content. The increased adrenal corticosterone content in theheterozygous IL-6 transgenic mice was paralleled by a trend towarda higher pituitary AVP content, but this change did not reachstatistical significance.

Table 3. Adrenal corticosterone and pituitary AVP content in GFAP-IL-6 transgenic mice¹

IL-6 transgenic mice (5 min restraint-stressed) Adrenal corticosterone content^a (ng/mg protein) Pituitary AVP content^a (pg/µg protein)

+/+ 0.54 ± 0.13 0.059 ± 0.019

+/Tg 1.34 ± 0.28^* 0.093 ± 0.015

^a The adrenal corticosterone and pituitary AVP contents were determined as described in Materials and Methods; n = 10 mice/groupfor pituitary AVP; ^* p < 0.01 versus +/+.

Adrenal histology in IL-6 transgenic mice
The changes in adrenal corticosterone content were paralleled by a number of histological alterations (Fig. 3). The adrenalcortex and medulla of the IL-6 transgenic mice, which showed increasedadrenal corticosterone content, were hyperplastic. The cells didnot look tumorous, but the number of cells was increased. Thecortex of the IL-6 transgenic mouse specimen was approximatelydouble the thickness of the cortex of the wild-type control specimen,and there were both an increased number of cells (in the glomerulosalayer) and a hypertrophic response with nuclei spaced fartherapart (in the layers reticularis and fasciculata).
Fig. 3. Histological appearance of the adrenal glands from wild-type (+/+) (A) mice and heterozygous (+/Tg) (B) IL-6 transgenic mice.The adrenal histology was determined as described in Materialsand Methods. Arrows indicate the corticomedullary junction. Notethat the cortex of the IL-6 transgenic mouse specimen is approximatelydouble the thickness of the cortex of the wild-type control specimenand that there are both an increased number of cells (in the glomerulosalayer) and a hypertrophic response with nuclei spaced fartherapart (in the layers reticularis and fasciculata). C, Cortex;M, medulla. Scale bar, 25 m.
[View Larger Version of this Image (171K GIF file)]

IL-6 transgene expression
IL-6 transgene expression in the pituitary and adrenal gland was examined by RNase protection assay because increased IL-6levels in these organs could contribute to the HPA axis activation.However, no IL-6 mRNA expression was detected in either the pituitaryor adrenal gland (data not shown). To determine whether IL-6 inthe plasma could directly activate the adrenal gland, possiblyin synergism with plasma ACTH, we assessed the levels of IL-6in the plasma of transgenic IL-6 mice by bioassay and ELISA. Therewas no detectable IL-6 present in the plasma of IL-6 transgenicmice or of controls (data not shown).

DISCUSSION
The present results demonstrate that chronic cerebral expression of IL-6 results in activation of the HPA axis via a novelmechanism primarily effected at the adrenal gland. After restraintstress, the plasma corticosterone responses were greater in theheterozygous and homozygous IL-6 transgenic mice in a gene dose-dependentmanner, but their plasma and pituitary ACTH contents were eithernot changed or reduced compared with the levels in controls. However,the adrenal corticosterone content and plasma AVP levels wereelevated in stressed IL-6 transgenic mice, in parallel with hyperplasiaof both the adrenal cortex and medulla. The reduced ACTH responsetogether with the adrenal hyperplasia in the IL-6 transgenic micesuggests direct activation at the level of the adrenal gland,which may be directly activated by AVP and/or sensitized to ACTH.

Most studies on the central effects of IL-6 have been done in the rat, and little is known about its effects in the mouse.There may be an important species difference between central IL-6effects in rat and mouse, because IL-6 mRNA has been detectedin normal rat brain (Schöbitz et al., 1993; De Kloet et al.,1994; Gadient and Otten, 1994, 1995) but not in mouse brain (Campbellet al., 1993). In rat, the site of action for the IL-6 stimulationof the HPA axis seems to be at the level of not only the hypothalamus(Loxley et al., 1991, 1993; Lyson et al., 1991; Navarra et al.,1991; Lyson and McCann, 1992; Spinedi et al., 1992; Raber et al.,1994; Yasin et al., 1994; Kageyama et al., 1995) but also thepituitary (Bateman et al., 1989; Stephanou et al., 1992; Muramamiet al., 1993; Sarlis et al., 1993) and adrenal gland (Muramamiet al., 1993, Gonzalez-Hernandez et al., 1994). IL-6 mRNA hasbeen reported in the rat anterior pituitary (Vankelecom et al.,1989; Spangelo et al., 1990, 1994), in which it is increased inconditions associated with chronic stimulation of the HPA axis(Stephanou et al., 1992), and is under the control of glucocorticoidfeedback (Sarlis et al., 1993). In addition, IL-6 induces ACTHrelease both in vivo and in vitro (Bateman et al., 1989; Spangeloet al., 1994). Furthermore, lipopolysaccharide (LPS) is able toactivate the pituitary-adrenal axis in rats with paraventricularnucleus (PVN) lesions (Elenkov et al., 1992) and to increase serumIL-6 levels and IL-6 mRNA in peripheral organs (Schöbitz et al.,1993), supporting a direct effect on the pituitary or extrapituitarynon-PVN pathways of HPA axis activation (Elenkov et al., 1992).

Physical or psychological stress increases plasma IL-6 in rats with kinetics that resembles the increase in plasma corticosterone;these changes are attenuated by adrenalectomy, and IL-6 inducesacute-phase proteins with glucocorticoids from the adrenal gland(Zhou et al., 1993). IL-6 mRNA was also reported in 17 $alpha$ -hydroxylase-immunoreactivesteroid cells in the inner zone of the adrenal cortex and in CD-6-positivemacrophages in the zona reticularis in humans (Gonzalez-Hernandezet al., 1994).

However, the inability to detect IL-6 mRNA in the pituitary and adrenal gland or IL-6 in the plasma of the IL-6 transgenicmice strongly suggests a central site of action of the cytokineand argues against a direct systemic effect of IL-6 on the pituitaryor adrenal gland. A central site for the effect of IL-6 is furthersupported by the failure of LPS or IL-1 $beta$ to produce fever in IL-6deficient mice, which can be overcome by intracerebroventricularinjection of the cytokine (Chai et al., 1996). Acute in vitroexposure of the rat hypothalamus to IL-6 stimulates hypothalamicfactors, including CRF (Lyson et al., 1991; Navarra et al., 1991;Lyson and McCann, 1992; Spinedi et al., 1992; Yasin et al., 1994).Conflicting reports exist concerning the effect of IL-6 on AVPrelease from the rat hypothalamus (Loxley et al., 1991, 1993;Spinedi et al., 1992; Raber et al., 1994). However, the IL-6-inducedACTH response was significantly suppressed by intracerebroventricularinjection of antibodies against either CRF or AVP into the thirdventricle (Kageyama et al., 1995).

In general, activation of the HPA axis is characterized by stimulation of CRF neurons, which can coproduce AVP, in the PVNof the hypothalamus and by secretion of these ACTH secretagoguesfrom secretory terminals in the external zone of the median eminence.This, in turn, stimulates ACTH release from the anterior pituitaryand subsequently causes the secretion of adrenal steroids. A singleexposure to LPS, IL-1, brain surgery, or electric footshocks increasesthe AVP stores in terminals of CRF neurons in the external zoneof the median eminence (Schmidt et al., 1995, 1996). During chronicor repeated stress, there is a shift from non-AVP-producing toAVP-producing CRF neurons, an increase in AVP vesicles in themedian eminence (De Goeij et al., 1992a,b,c; Bartanusz et al.,1993), and release of AVP but not of CRF (Plotsky and Sawchenko,1987; De Goeij et al., 1992a; Aguilera, 1994). This is consistentwith the proposed role for AVP in maintaining the activity ofthe HPA axis after repeated stimulation (Hashimoto et al., 1988;Hauger et al., 1988; Scaccianoce et al., 1991; Lightman, 1994).The increased plasma AVP levels in the stressed IL-6 transgenicmice suggest a pivotal role for AVP in modulating the HPA axisafter acute immobilization stress but do not exclude a role forCRF after other stressors in this model.

The finding of increased plasma AVP levels in the IL-6 transgenic mice suggests that IL-6 activates the magnocellular AVPneurons, which directly secrete AVP into the general circulationthrough the vasculature of the posterior pituitary. The elevatedstress-induced plasma AVP levels in the IL-6 transgenic mice maycontribute to the hyperplasia of the adrenal gland. Intraperitonealadministration of vasopressin induces neural modulation of changesin catecholamines in the pigeon adrenal medulla (Mahata and Ghosh,1991) and increases plasma corticosterone in addition to basaland ACTH-stimulated corticosterone secretory activity of zonafasciculata cells (Mazzocchi et al., 1995). A role for directactivation of AVP at the level of the adrenal gland is supportedby the reported stimulation by AVP of inositol phosphates in adrenalmedullary cultures (Bunn et al., 1990) and by increases in cytosolicfree calcium (Larcher et al., 1992a). In addition, vasotocin (AVT),the amphibian counterpart of AVP produced by adrenochromaffincells, stimulates corticosterone secretion in vitro from frogadrenocortical cells (Larcher et al., 1992b), which are homologousto the glomerulosa layer of the mammalian adrenal cortex (Delarueet al., 1981). Interestingly, the IL-6 transgenic mice exhibithypertrophy in the glomerulosa layer (Fig. 3), and prolonged AVPadministration was shown to stimulate this layer in the rat bypromoting both hypertrophy and hyperplasia of the parenchymalcells (Payet and Lehoux, 1980; Payet et al., 1984; Lesniewskaet al., 1991), whereas AVP antagonists depress the growth andsecretory capacity of this layer (Mazzochi et al., 1995).

The elevated plasma corticosterone levels in the IL-6 transgenic mice were achieved with a smaller increase in the ACTH responsecompared with the controls. Downregulation of pituitary CRF (Tizabiand Aguilera, 1992) and AVP receptors (Aguilera, 1994) might beinvolved in desensitization of the pituitary ACTH response. Theinhibitory effect of chronic osmotic stimulation on ACTH secretiondespite high circulating levels of AVP has been proposed to resultfrom a diminished activity of parvicellular PVN neurons and downregulationof pituitary AVP receptors (Aguilera, 1994). This downregulationof the pituitary CRF and AVP receptors might be caused eitherby prolonged stimulation of ACTH secretagogues or by an alteredsensitivity to glucocorticoid feedback inhibition.

Modulation of the HPA axis in mice centrally expressing IL-6 could contribute to the pathology found in these mice (Campbellet al., 1993; Chiang et al., 1994; Heyser et al., 1997). Glucocorticoidscan induce neuropathological alterations (Landfield, 1987; DeLeonet al., 1988; Sapolsky, 1992; Starkman et al., 1992; for review,see Sapolsky, 1996), which might involve the effect of corticosteroneon brain-derived neurotrophic factor (Segal et al., 1995; Smithet al., 1995) and interaction with various transcription factors(Auphan et al., 1995; Scheinman et al., 1995; Wilckens, 1995).IL-1 may also contribute to the modulation of the HPA, becausethere is concurrent IL-1 $alpha$ / $beta$ mRNA expression with the transgenicIL-6 expression (Chiang et al., 1994).

In summary, we found that transgenic expression of IL-6 in the CNS modulates the HPA axis. These findings support a role forIL-6 in interactions between the immune system and the nervoussystem not only at the peripheral (Straub et al., 1995) but alsoat the central level. Increased corticosterone levels in stressedIL-6 transgenic mice are associated with increased adrenal corticosteronecontent and plasma AVP levels and are paralleled by hyperplasiaof the adrenal cortex and medulla. The decreased ACTH responsetogether with the adrenal hyperplasia in the IL-6 transgenic micesuggests direct activation at the level of the adrenal gland,which may be directly activated by AVP or sensitized by ACTH (Fig.4). The exact mechanism of the HPA axis modulation by AVP remainsto be determined, but these data support an important role forAVP in acute immobilization stress under conditions of chronicallyelevated brain levels of IL-6.
Fig. 4. Diagram of proposed HPA axis modulation in IL-6 transgenic mice. This study demonstrates that chronic expression of IL-6 inthe CNS can elevate plasma corticosterone with a smaller increasein the ACTH response compared with the controls, similar to thereported blunting of ACTH but not cortisol responses under pathophysiologicalconditions of high brain levels of IL-6 observed in humans. Theincrease in plasma AVP in the IL-6 transgenic mice may reflectactivation of the magnocellular AVP neurons by IL-6 in this model(2). The adrenal gland could be directly activated by AVP or sensitizedto ACTH (1).
[View Larger Version of this Image (24K GIF file)]

FOOTNOTES

Received July 30, 1997; revised Sept. 29, 1997; accepted Oct. 1, 1997.

This work was supported by National Institutes of Health Grants MH47680 (F.E.B.) and MH50426 (I.L.C.), by the National Healthand Medical Research Council (Australia) C. J. Martin Fellowship(R.D.O.), and by the Schumacher-Kramer Foundation (J.R.). Thisis manuscript 10670-NP from the Scripps Research Institute. Weare grateful to Elena F. Battenberg for help with the histologicalanalysis of the adrenal gland.

Correspondence should be addressed to Dr. Jacob Raber, The Gladstone Molecular Neurobiology Program and Department of Neurology,University of California, P.O. Box 419100, San Francisco, CA 94141-9100.

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