Mineralocorticoid treatment attenuates activation of oxytocinergic and vasopressinergic neurons by icv ANG II

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Mineralocorticoid treatment attenuates activation of oxytocinergic and vasopressinergic neurons by icv ANG II

Darren M. Roesch, Ruth E. Blackburn-Munro, and Joseph G. Verbalis

Division of Endocrinology and Metabolism, Department of Medicine, Georgetown University, Washington, District of Columbia 20007

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Central oxytocin (OT) neurons limit intracerebroventricular (icv) ANG II-induced NaCl intake. Because mineralocorticoids synergisticallyincrease ANG II-induced NaCl intake, we hypothesized that mineralocorticoidsmay attenuate ANG II-induced activation of inhibitory OT neurons.To test this hypothesis, we determined the effect of deoxycorticosterone(DOCA; 2 mg/day) on icv ANG II-induced c-Fos immunoreactivityin OT and vasopressin (VP) neurons in the supraoptic (SON) andparaventricular (PVN) nuclei of the hypothalamus and also on pituitaryOT and VP secretion in male rats. DOCA significantly decreasedthe percentage of c-Fos-positive (%c-Fos+) OT neurons in the SONand PVN, both in the magnocellular and parvocellular subdivisions,and the %c-Fos+ VP neurons in the SON after a 5-ng icv injectionof ANG II. DOCA also significantly reduced the %c-Fos+ OT neuronsin the SON after 10 ng ANG II and tended to attenuate 10 ng ANGII-induced OT secretion. However, the %c-Fos+ OT neurons in DOCA-treatedrats was greater after 10 ng ANG II, and DOCA did not affect the%c-Fos+ OT neurons in the PVN nor VP secretion or c-Fos immunoreactivityin either the SON or PVN after 10 ng ANG II. DOCA also did notsignificantly alter the effect of intraperitoneal (ip) cholecystokinin(62 µg) on %c-Fos+ OT neurons or of ip NaCl (2 ml of 2 M NaCl)on the %c-Fos+ OT and VP neurons. These findings indicate thatDOCA attenuates the responsiveness of OT and VP neurons to ANGII without completely suppressing the activity of these neuronsand, therefore, support the hypothesis that attenuation of OTneuronal activity is one mechanism by which mineralocorticoidsenhance NaClintake.

deoxycorticosterone acetate; vasopressin; salt appetite; c-Fos

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

BOTH EXCITATORY AND INHIBITORY signals control sodium chloride (NaCl) intake (46). Two of the most potent excitatory stimuliof NaCl intake in rats are ANG II (10) and mineralocorticoids(12, 32, 61). Although some studies have suggested mineralocorticoid-inducedincreases in brain ANG II receptors (20, 38, 60) may accountfor the ability of mineralocorticoids to interact synergisticallywith ANG II to increase NaCl intake (11), the potential effectsof mineralocorticoids on inhibitory controls of sodium appetitehave not beenstudied.

Oxytocinergic (OT) neurons have been found to mediate inhibition of NaCl intake in rats under some conditions (44). Severaltreatments that chronically increase NaCl appetite [e.g., sodiumdeprivation, adrenalectomy, and deoxycorticosterone (DOCA) injections]decrease basal OT levels, and many treatments that stimulate OTsecretion (e.g., hypertonic saline, lithium chloride, and coppersulfate) inhibit intake of NaCl in sodium-deprived rats allowedaccess to concentrated saline solutions (45). However, suchinhibition of NaCl intake by OT appears to be mediated by a subsetof centrally projecting OT neurons that are coactivated with peripherallysecreting magnocellular neurons, because intracerobroventricularly(4) but not systemically (45) administered OT and OT-receptorantagonists affected NaCl intake induced by polyethylene glycol(PEG)-inducedhypovolemia.

We have demonstrated that central inhibitory OT pathways also limit the ability of an intracerebroventricular (icv) injectionof ANG II to induce NaCl intake (3). Because systemically andcentrally administered ANG II has been shown to stimulate pituitaryrelease of OT (8, 21), we hypothesized that ANG II-inducedactivation of centrally projecting OT neurons may account forthe observation that ANG II-induced water consumption precedesand far exceeds ANG II-induced NaCl intake (6, 7, 9).Indeed, we found that icv injections of an OT-receptor antagonistenhanced ANG II-induced NaCl intake without modifying ANG II-inducedwater intake (3), suggesting that inhibitory OT signals mustbe eliminated to allow for maximal NaCl intake in response tothisstimulus.

On the basis of the observation that chronic sodium deprivation attenuates the acute OT response to PEG-induced hypovolemia(43), we have previously speculated that the overall responsivenessof OT neurons to acute stimuli may be suppressed when NaCl appetiteis increased. In this study, we examined the effect of DOCA treatmenton the ability of icv injections of ANG II to initiate NaCl intake,induce c-Fos immunoreactivity in OT neurons in the supraoptic(SON) and paraventricular (PVN) nuclei of the hypothalamus, andstimulate pituitary OT secretion. We also analyzed the effectof DOCA on ANG II-induced c-Fos immunoreactivity in the organumvasculosum of the lamina terminalis (OVLT), median preoptic nucleus(MnPO), and the subfornical organ (SFO), because these brain areasexpress ANG II receptors and are components of the neural circuitryimplicated in ANG II-mediated facilitation of NaCl intake (15,18, 35). Finally, we studied the effect of DOCA on the responsivenessof vasopressin (VP) neurons, another group of closely relatedhypothalamic neurons that is also stimulated by ANG II (19,24, 27) but does not appear to be a primary regulator of NaClappetite in rats (45).

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Animals and maintenance. Male Sprague-Dawley rats were individually housed in a temperature-controlled room with a regular light cycle. Rats were allowedto acclimate to the facility for 5-7 days before a study was begun,and during that time, they were provided with standard chow, tapwater, and 0.3 M NaCl ad libitum. All surgical procedures wereapproved by the Georgetown University Animal Care and Use Committee.After each surgical intervention, rats were given an intramuscular(im) injection of penicillin G procaine (60,000 U, Phoenix Pharmaceutical,St. Joseph, MO). The ability to maintain body weight throughoutthe duration of an experimental period was routinely used as anassessment of good general health; animals that lost 10% or moreof body weight during the course of the study were excluded fromanalysis.

icv Cannula placement. Each rat was anesthetized with an intraperitoneal (ip) injection of equithesin (0.98 g/dl pentobarbital sodium, 4.25 g/dlchloral hydrate, and 2.12 g/dl MgSO₄ administered at a dose of0.3 ml/100 g body wt) and placed in a stereotaxic apparatus. Thefissures on the skull were exposed via a midline incision, anda 22-gauge guide cannula made to extend 4 mm below the surfaceof skull (Plastics One, Roanoke, VA) was inserted into the rightlateral ventricle (1.5 mm lateral and 1.5 mm caudal to bregma).Two jewelers screws were secured in the skull at positions caudaland lateral to lambda. A freshly prepared mixture of dental repairresin (Hygenic, Akron, OH) was poured onto the surface of theskull around the cannula and anchoring screws and over the edgesof the incised skin. After the dental repair resin dried, thecannula was plugged with a custom-made dummy cannula (PlasticsOne). Cannulas were considered to be patent and positioned properlywhen fluid intake induced by an icv injection of 5 ng of ANG IIexceeded 4 ml in 30min.

Jugular vein catheterization. Silicone rubber catheters (0.02 in. ID × 0.037 in. ID, Sil-Med, Taunton, MA) were prepared by allowing a ball of Silasticbrand medical adhesive (Dow-Corning, Midland, MI) to dry aroundthe perimeter 3.1 cm from one end of a 12.5-cm-long piece of tubing.Under methoxyflurane anesthesia (Schering-Plough Animal Health,Union, NJ), the short end of a catheter filled with heparinized(100 U/ml) sterile 0.15 M NaCl was inserted into the jugular vein.The catheter was anchored to the pectoral muscle by tying 4-0surgical silk around the adhesive ball, and a 15-gauge trocar(Becton Dickinson, Sparks, MD) was used to exteriorize the freeend of the catheter in the dorsal scapular region. The incisionwas closed with 9-mm wound clips (Becton Dickinson), and the catheterwas plugged with a 1-cm piece of 21-gauge stainless steel wire(Small Parts, Miami Lakes,FL).

DOCA administration. In studies A and B, DOCA (Sigma) was dissolved in peanut oil and administered daily via a subcutaneous injection (2 mg/0.4ml). Control animals were given subcutaneous injections of oil.In study C, DOCA was administered via a 42-mg pellet that releases2 mg/day for 21 days (Innovative Research of America, Sarasota,FL). Control animals were implanted with a 42-mg pellet of thebiodegradable carrier binder. The pellets were implanted subcutaneouslyin the dorsal scapular region using methoxyflurane anesthesia,and skin incisions were closed with woundclips.

ANG II administration. ANG II (Sigma) was dissolved in sterile 0.15 M NaCl to yield final concentrations of 5 and 10 ng in 5 µl. The ANG II solutionwas drawn into a custom-made 28-gauge internal guide cannula (PlasticsOne) attached to a glass syringe (Hamilton, Reno, NV) via polyethylenetubing (PE-20, 0.043 mm ID × 0.38 mm OD, Becton Dickinson) andwas injected slowly over 30s.

Study A protocol: effect of DOCA on icv ANG II-induced NaCl intake. Sixteen rats weighing 300-375 g were implanted with icv cannulas and allowed to recover for 3 days. DOCA (2 mg/0.4 ml, n =8) or oil (0.4 ml, n = 8) injections were given daily for 8 days,and water and 0.3 M NaCl intake was measured each day. On theeighth day, an icv injection of ANG II (5 ng/5 µl) was given,and water and 0.3 M NaCl intakes were measured 15, 30, 45, and60 min after injection. We have previously found that this doseof ANG II elicits a robust drinking response when injected intothe lateral ventricle (3).

Study B protocol: effect of DOCA on icv ANG II-induced c-Fos immunoreactivity in the forebrain and hypothalamus. Rats weighing 325-425 g were implanted with icv cannulas and allowed to recover for 7-10 days. Water and 0.3 M NaCl intakeswere monitored for 1 h after an icv injection of ANG II to verifycannula placement. DOCA (2 mg/0.4 ml, n = 10) or oil (0.4 ml,n = 10) was then injected daily for 5 days. This duration of DOCAinjection was selected based on the results of study A. At least3 h after the last DOCA injection, an icv injection of ANG II(5 ng/5 µl, n = 7 in each treatment group) or vehicle (5 µl, n= 3 in each treatment group) was given, the animals were euthanized,and their brains were processed for immunohistochemistry 75 minlater. This time was chosen based on previous studies that foundc-Fos immunoreactivity in magnocellular neuron peaks 60-90 minafter stimulation (57).

Study C protocol: tests for complete DOCA inhibition of OT neurons. Six rats that had been treated for 5 days with subcutaneous DOCA injections were perfused for immunohistochemistry 75 minafter an ip injection of 2 M NaCl (2 ml). This dose of hypertonicsaline has been shown to induce c-Fos immunoreactivity in nearlyall SON and PVN magnocellular neurons (17). An additional ninerats were injected ip with CCK (sulfated octapeptide, ResearchPlus, Bayonne, NJ; 62 µg dissolved in 1 ml of 0.15 M sterile saline)11 days after implantation of a DOCA (n = 4) or placebo (n = 5)pellet and processed for immunohistochemistry. This dose of CCKmaximally stimulates pituitary secretion of OT (55) and hypothalamicc-Fos immunoreactivity (57). The animals used to study the c-Fosresponse to ip injections of 2 M NaCl and CCK were rats that hadbeen rejected from the icv studies due to misplaced icvcannulas.

Study D protocol: effect of DOCA on icv ANG II-induced OT and VP secretion. Rats weighing 225-275 g were implanted with icv cannulas. Two days later, the cannulas were tested for patency and properpositioning. DOCA (n = 4, releasing 2 mg/day) or placebo (n =4) pellets were implanted subcutaneously 2 days later. On thethird day after pellet implantation, catheters were inserted intothe right jugular vein. On the fifth day, venous blood sampleswere taken at baseline and 5 and 20 min after an icv injectionof ANG II (10 ng/ml). A higher dose of ANG II was used in thisstudy, because preliminary studies with 5 ng of ANG II icv yieldedinconsistent elevations of plasma OT and VP levels; thus the higherANG II dose was selected to ensure measurable secretion from theposterior pituitary to determine whether DOCA completely inhibitsor simply decreases the sensitivity of OT and VP neurons to ANGII. On the eighth day after DOCA or placebo pellet implantation,each rat was given an icv injection of ANG II (10 ng/ml) and euthanizedvia perfusion 75 minlater.

Blood sampling. Each jugular catheter was connected to a 100-cm-long piece of polyethylene tubing (PE-60, 0.76 mm ID × 1.22 mm OD, BectonDickinson) filled with heparinized (50 U/ml) saline using a 1-cm-longpiece of 21-gauge stainless steel tubing (Small Parts). The deadspace in this catheter was ~0.5 ml. The catheter was routed tothe exterior of the animal's cage, and a three-way stopcock (VWRScientific) was connected to the end of the catheter with a 21-gaugeblunt needle. The rats were allowed to recover from the stressof handling for at least 30 min before sampling. Thirty minutesbefore icv injection of ANG II, a baseline sample (1.5 ml) wastaken. Additional blood samples (1.5 ml each) were taken 5 and20 min after icv injection of ANG II. Blood samples were withdrawnslowly, and a volume of heparinized saline (50 U/ml) equal tothe sample volume was infused after each sample. Food, water,and saline were not provided during the experiment. Blood sampleswere collected in tubes containing sodium heparin (Vacutainer,Becton Dickinson). The samples were stored on ice until centrifugedat 3,000 rpm in a refrigerated centrifuge. Plasma was stored at $-$ 20°C until radioimmunoassay for OT and VP after acetone-etherextraction as previously described (56).

Tissue preparation. The animals were denied access to food, water, and 0.3 M NaCl after icv injection of ANG II or ip injection of CCK or 2 MNaCl. Seventy-five minutes after the injection, each rat was anesthetizedwith an overdose of pentobarbital sodium (80 mg/kg). The thoraciccavity was opened, the inferior vena cava was clamped, and an18-gauge over-needle Teflon catheter was inserted into the apexof the heart and routed to the entrance of the aorta. Five-hundredunits of heparin were injected into the catheter, and the rightatrium was punctured to allow drainage. The animal was then perfusedtranscardially with 200 ml of 0.15 M NaCl containing 2% sodiumnitrite followed by 200 ml of phosphate-buffered 4% paraformaldehydecontaining 2% acrolein (Polysciences, Warrington, PA) followedby another 200 ml of 0.15 M NaCl containing 2% sodium nitrite.The brains were postfixed overnight in phosphate-buffered 4% paraformaldehydeand then were stored in 25% sucrose until sectioned. Coronal sections(25 µm) were cut from the rostral opening of the lateral ventriclecaudally to the level of the median eminence using a freezingmicrotome (Jung Histoslide 2000, Deerfield, IL). The sectionswere stored at $-$ 20°C in tissue culture dishes containing cryoprotectant(59) untilprocessed.

Immunohistochemistry. To ensure that the immunohistochemical analyses were representative of the entire extent of the sectioned brain area, eachanalysis consisted of sections that were cut ~150 µm apart (everysixth section). The tissue was rinsed with PBS and treated witha solution of 1% sodium borohydride for 20 min. Next, the tissuewas incubated for 48-72 h at 4°C with a rabbit-derived antibodydirected against the amino terminal of c-Fos (Oncogene Sciences,Manhasset, NY; diluted 1:400,000 in PBS containing 0.4% TritonX-100). Then the tissue was incubated for 1 h at room temperaturewith a biotinylated goat anti-rabbit IgG (Vector Laboratories,Burlingame, CA; diluted 1:10,000 in PBS-Triton X-100 mixture).Finally, the tissue was incubated for 1 h at room temperaturewith avidin and a biotinylated horseradish peroxidase (VectastainElite ABC Kit, Vector Laboratories, 4.5 µl of reagents A and B/ml)in PBS-Triton X-100 mixture. The presence of the antibody-peroxidasecomplex was detected by incubating with nickel sulfate (25 mg/ml),3,3'-diamino-benzidine (DAB; 0.2 mg/ml), and hydrogen peroxide(0.4 µl of 30% H₂O₂/ml) in 0.175 M sodium acetate for 10-20 min.This reaction product was black. To identify OT- and VP-containingneurons, the same sections were double-stained with antibodiesdirected against OT or VP. The tissue was incubated for 48 h at4°C with a rabbit-derived antibody directed against OT (studiesB-D, courtesy of Dr. Marianna Morris, diluted 1:400,000 in PBS-TritonX-100 mixture), VP (study B, diluted 1:5,000, courtesy of Dr.Ann-Judith Silverman), or VP neurophysin [study C, diluted 1:450,000,courtesy of Dr. Gloria Hoffman (34)]. Peroxidase was attachedto the antibody as described above, and the presence of the peroxidasewas detected by incubating with DAB and hydrogen peroxide in 0.05M Tris-buffered (pH 7.2) 0.15 M NaCl. This reaction product waslight brown. Throughout the staining procedure, the tissue wasrinsed in PBS multiple times after each incubation step. The tissuewas mounted on Superfrost Plus glass slides (Fisher Scientific),air-dried overnight, serially dehydrated in alcohol, cleared inHistoclear, and placed on a coverslip with Histomount (NationalDiagnostics, Atlanta,GA).

Tissue slices were visualized using a Nikon Eclipse E600 microscope fitted with a linear encoder (type MSA 001-6, RSF Electronics,Rancho Cordova, CA) connected to a digital-readout device (MicrocodeII, Boeckeler Instruments, Tucson, AZ), a video camera (DEI-750,Optronics Engineering, Goleta, CA), and a microcomputer runningthe Bioquant software package (R & M Biometrics, Nashville, TN).The tissue slices were visualized using a ×40 objective lens (×400,final magnification), the brain regions of interest were outlinedusing a rat-brain atlas (29) as a guide, and the number of totalc-Fos+, or OT and c-Fos+ OT, or total VP and c-Fos+ VP immunoreactivecells was counted. Because the results of previous studies conductedin this laboratory suggested that centrally projecting OT pathwaysmediate the inhibition of NaCl intake (3), the centrally projectingparvocellular OT neurons were separated from the posterior pituitary-projectingmagnocellular OT neurons using the cytoarchitectonic analysesof Swanson and Kuypers as a guide (48). With the use of theBioquant software package, each individual immunoreactive cellwas marked during the counting process, eliminating the possibilityof double-counting identified cells. Because OT cells are generallywell separated in the SON and PVN, quantification of total OTand c-Fos+ OT immunoreactive cells was very objective. In contrast,it is more difficult to distinguish the borders of immunoreactiveVP cells because they often overlapped one another; consequently,the total VP and c-Fos+ VP immunoreactive cell counts were somewhatmore subjective. By staining every sixth coronal section (at 150-µmintervals), it was possible to quantify one section of each OVLT,1-3 sections of each SFO, 3-9 sections of each MnPO nucleus, and6-12 sections through the rostral-caudal extent of each SON (1,078± 63 total cells counted) and PVN (433 ± 30 total cells counted)for each brain analyzed. To assess the degree of activation ofall immunoreactive OT and VP neurons, cell counts were expressedas the percentile ratio of c-Fos+ OT or VP cells to the totalnumber of OT or VP cells in eachanimal.

Statistical analyses. Measurements taken over time (water and 0.3 M NaCl intake and OT and VP secretion) were analyzed by two-way ANOVA correctedfor repeated measures. Individual means were compared using aStudent-Newman-Keuls multiple-comparison test. Cell counts werecompared using an unpaired t-test. The null hypothesis was rejectedwhen P < 0.05. Data are expressed as means ±SE.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Study A: effect of DOCA on daily and ANG II-induced water and 0.3 M NaCl intake. Daily water and 0.3 M NaCl intakes are presented in Table 1. Water intake was similar in oil (42.8 ± 2.7 ml)- and DOCA-treated(41.5 ± 4.9 ml) rats 24 h after the first injection, and dailyintake did not significantly change over time in either treatmentgroup. In contrast, there was a significant effect of treatment(P < 0.001) but not time on daily 0.3 M NaCl intake. Daily 0.3M NaCl intake was significantly higher in DOCA-treated rats 48h after the first injection (14.1 ± 4.1 vs. 2.3 ± 0.9 ml; P =0.04), and daily intake remained significantly increased in DOCA-treatedrats throughout the course of the experiment (P < 0.001 on day7, Table 1).

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Table 1. Effect of DOCA on daily water and 0.3 M NaCl intake

There was a significant effect of time (P < 0.001) but not treatment on icv ANG II-induced water intake. In oil-treated rats,an icv injection of 5 ng of ANG II induced a robust intake ofwater (13.6 ± 1.0 ml over 60 min; Fig. 1A), and ANG II-inducedwater intake was not significantly different in DOCA-treated rats(Fig. 1A). In contrast, there was a significant effect of bothtime (P < 0.001) and treatment (P = 0.02) on icv ANG II-induced0.3 M NaCl intake. An icv injection of 5 ng of ANG II induceda moderate intake of 0.3 M NaCl in oil-treated rats (3.1 ± 1.0ml over 60 min; Fig. 1B), and ANG II-induced 0.3 M NaCl intakewas significantly augmented in DOCA-treated rats (10.2 ± 2.5 vs.3.1 ± 1.0 ml over 60 min, P = 0.014 compared with oil-treatedrats; Fig. 1B).

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Fig. 1. Effect of chronic (7 days) DOCA administration on acute intake of water (A) and 0.3 M NaCl (B) induced by a 5-ng intracerebroventricular (icv) injection of ANG II in oil (open symbols, n = 8)- and DOCA-treated (solid symbols, n = 8) rats. *P < 0.05 compared with oil-treated controls.

Study B: effect of DOCA on ANG II-induced (5 ng) c-Fos immunoreactivity. As shown in Fig. 2, injection of vehicle alone stimulated very minimal c-Fos immunoreactivity in the SON and PVN using thesemethods. Consequently, the c-Fos immunoreactivity after ANG IIinjections could not be attributable to the injection processitself. As expected from previous studies (15, 35), ANG IIinduced abundant c-Fos immunoreactivity in the OVLT, MnPO, andSFO. However, DOCA treatment did not significantly alter the ANGII-induced c-Fos immunoreactivity in any of these regions (Table2).

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Fig. 2. Representative photomicrographs (×400) of the effect of an icv injection of vehicle (0.15 M NaCl) on c-Fos immunoreactivity in the paraventricular (PVN; A and B) and supraoptic nuclei (SON; C and D) of the hypothalamus. The rats were treated with oil (A and C) or DOCA (B and D). On the 5th day of treatment, the rats were given an icv injection of vehicle (5 µl), and their brains were processed for immunohistochemistry 75 min later. The tissues were stained for oxytocin (OT; golden brown cytoplasmic stain) and c-Fos (black nuclear stain).

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Table 2. Effect of DOCA administration on ANG II-induced c-Fos immunoreactivity in the OVLT, MnPO, and SFO

In the SON of control rats, 387 ± 23 OT neurons were counted, and ANG II induced c-Fos immunoreactivity in 57.9 ± 7.2% ofthese neurons. In the PVN of control rats, 276 ± 41 OT neuronswere counted, and 41.4 ± 7.5% of these neurons were immuonreactivefor c-Fos (Fig. 3A). Significantly fewer OT neurons stained forc-Fos after icv ANG II in the DOCA-treated rats compared withoil-treated rats. In the SON, 19.1 ± 3.1% of the 386 ± 46 OT neuronsthat were counted were immunoreactive for c-Fos (P = 0.0003) inDOCA-treated rats, and in the PVN, 15.5 ± 2.3% of 309 ± 35 OTneurons counted (P = 0.007) were immunoreactive for c-Fos in DOCA-treatedrats (Fig. 3A). Representative photomicrographs are presentedin Fig. 4.

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Fig. 3. Effect of chronic (5 days) DOCA administration on the percentage of c-Fos immunoreactive OT (A) and vasopressin (VP; B) neurons in the SON and PVN of the hypothalamus after a 5-ng icv injection of ANG II in oil (open bars, n = 7)- and DOCA-treated (filled bars, n = 7) rats. *P < 0.05 compared with oil-treated controls.

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Fig. 4. Representative photomicrographs (×400) of c-Fos immunoreactive OT neurons in oil (A and D)- and DOCA-treated (B, C, E, and F) rats after a 5-ng icv injection of ANG II (A, B, D, and E) or an intraperitoneal (ip) injection of 2 M NaCl (C and F). A-C: PVN. D-F: SON. The black nuclear stain indicates c-Fos immunoreactivity; the golden brown cytoplasmic stain indicates OT immunoreactivity.

To estimate whether the effect of DOCA on ANG II-induced c-Fos immunoreativity in OT neurons in the PVN was limited to centrallyor peripherally projecting portions of this nucleus, the cellsin the magnocellular and parvocellular divisions of this nucleuswere counted separately. Similar numbers of magnocellular PVNneurons were counted in control (188 ± 38) and DOCA-treated (148± 19) rats. ANG II induced c-Fos immunoreactivity in 44.5 ± 9.8%of the OT cells in the magnocellular division of the PVN in controlrats, and DOCA treatment significantly reduced the percentageof ANG II-induced c-Fos immunoreative cells to 15.6 ± 7.8% (P= 0.01). In the parvocellular division of the PVN, 126 ± 17 OTneurons were counted in control rats, and 141 ± 9 OT neurons werecounted in DOCA-treated rats. DOCA treatment also significantlyreduced ANG II-induced c-Fos immunoreativity in parvocellularOT neurons in the PVN (control, 34.3 ± 8.4%; DOCA-treated, 11.8± 5.0%; P = 0.02). The results of these analyses indicate thatDOCA significantly attenuated ANG II-induced c-Fos immunoreactivityboth in the posterior pituitary-projecting magnocellular and thecentrally projecting parvocellular (P = 0.02) OT neurons in thePVN (Table 3).

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Table 3. Effect of DOCA on the percent of c-Fos+ OT neurons in the parvocellular and magnocellular divisions of the PVN after an icv injection of ANG II (5 ng)

In the SON of control rats, 678 ± 99 VP neurons were counted, and ANG II induced c-Fos immunoreactivity in 59.4 ± 7.1% ofthese neurons. DOCA treatment significantly (P = 0.02) attenuatedANG II-induced c-Fos immunoreactivity in SON neurons; of the 704± 57 VP neurons in the SON that were counted in DOCA-treated rats,15.5 ± 2.9% of these were immunoreactive for c-Fos. In contrast,DOCA treatment did not significantly alter ANG II-induced c-Fosimmunoreactivity in VP neurons in the PVN. Representative photomicrographsare presented in Fig. 5.

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Fig. 5. Representative photomicrographs (×400) of c-Fos immunoreactive VP neurons in oil (A and D)- and DOCA-treated (B, C, E, and F) rats after a 5-ng icv injection of ANG II (A, B, D, and E) or an ip injection of 2 M NaCl (C and F). A-C: PVN. D-F: SON. The black nuclear stain indicates c-Fos immunoreactivity; the golden brown cytoplasmic stain indicates VP immunoreactivity.

Study C: effect of ip CCK and 2 M NaCl on c-Fos immunoreactivity in DOCA-treated rats. In oil-treated rats, an ip injection of CCK (62 µg) induced c-Fos immunoreactivity in 46.6 ± 12.0% of supraoptic and 47.2± 12.7% of paraventricular OT neurons. DOCA treatment did notsignificantly alter the effect of ip CCK on c-Fos immunoreactivityin OT neurons in the SON (42.4 ± 10.6%) or PVN (55.7 ± 16.4%).As we have previously observed in adult control rats (33), anip injection of 2 M NaCl induced c-Fos immunoreactivity in nearlyall OT and VP neurons in both the SON and PVN of DOCA-treatedrats (representative photomicrographs are presented in Figs. 4and 5).

Study D: effect of DOCA on ANG II-induced (10 ng) OT and VP secretion and c-Fos immunoreactivity. Two-way ANOVA corrected for repeated measures revealed a significant effect of time (P < 0.001) but not treatment (P = 0.2)on plasma OT after icv injection of 10 ng of ANG II. However,in DOCA-treated rats, the peak plasma OT level at 5 min (14.5± 1.5 pg/ml) tended to be lower than the peak level attained inoil-treated rats (22.7 ± 4.8 pg/ml; Fig. 6A). In this study, DOCAtreatment also significantly attenuated the c-Fos immunoreactivityinduced in OT neurons by 10 ng of ANG II in the SON (60.1 ± 4.9pg/ml vs. 76.9 ± 3.6% in controls, P = 0.03), but DOCA treatmentdid not significantly change ANG II-induced c-Fos immunoreactivityin OT neurons in the PVN (Fig. 6B). Baseline plasma VP levelswere not significantly different in DOCA-treated rats comparedwith oil-treated rats (1.2 ± 0.5 vs. 1.7 ± 0.3 pg/ml, not significant;Fig. 6C). Two-way ANOVA corrected for repeated measures revealeda significant effect of time (P = 0.04) but not treatment on plasma(Fig. 6C). In this study, DOCA treatment also did not significantlyattenuate c-Fos immunoreactivity induced in VP neurons by 10 ngof ANG II in either the SON or PVN (Fig. 6D).

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Fig. 6. Effect of chronic (5 days) DOCA administration on pituitary secretion of OT (A and B) and VP (C and D) in response to icv injection of ANG II. A and C: OT (A) and VP (C) secretion. B and D: the percentage of c-Fos immunoreactive OT (B) and VP (D) neurons in the SON and PVN of the hypothalamus after a 10-ng icv injection of ANG II in oil (open symbols and bars, n = 4)- and DOCA-treated (solid symbols and bars, n = 4) rats. *P < 0.05 compared with oil-treated controls.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The results of this study confirm that chronic mineralocorticoid treatment enhances icv ANG II-induced NaCl intake, but inaddition, they demonstrate that the same treatment attenuatesicv ANG II-induced c-Fos expression in OT and VP neurons in theSON and OT neurons in the PVN and tends to reduce pituitary OTsecretion. These results therefore indicate that systemic mineralocorticoidsreduce the responsiveness of both OT and VP neurons to icv ANGII. However, although DOCA treatment attenuates the responsivenessof OT and VP neurons to ANG II, our studies also indicate thatDOCA does not completely suppress these neurons, because largedoses of CCK and hypertonic saline increased c-Fos immunoreactivityin OT and VP neurons equally in DOCA- and oil-treated rats. Furthermore,the percentages of OT and VP neurons that were immunoreactivefor c-Fos in both oil- and DOCA-treated rats after a 10-ng bolusof ANG II were higher than the percentages that were immunoreactiveafter a 5-ng bolus. This finding suggests that DOCA decreasesthe relative sensitivity of OT neurons to ANG II but does notrender OT neurons completely unresponsive to thisstimulus.

The mechanism by which ANG II stimulates OT and VP neurons is not known. Although there are two subtypes of ANG II receptors(AT₁ and AT₂), autoradiographic studies suggest that primarilyAT₁ receptors are expressed in the hypothalamic PVN and SON (13,37, 39, 41). However, there is currently no evidence tosuggest direct regulation of hypothalamic OT neurons by the AT₁receptor. In situ hybridization studies have only colocalizedthe AT₁ receptor with corticotropin-releasing hormone and VP inthe parvocellular PVN (1, 23), and the AT₁ receptor has notbeen colocalized with VP in magnocellular neurons in the PVN orSON or with OT in the SON or either division of the PVN (1,23). These findings suggest that ANG II most likely stimulatesOT and magnocellular VP neurons indirectly through neuronal projections.Several circumventricular organs (the OVLT, MnPO nucleus, andthe SFO in the anterior third ventricular region and the areapostrema in the brain stem) and the amygdala and the bed nucleiof the stria terminalis (BNST) are rich in ANG II receptors andare known to send projections to the PVN and SON (10, 30,62). ANG II may stimulate neurons in these nuclei that innervatehypothalamic OT neurons, in which case corticosteroids may regulatethe sensitivity of these sites to ANG II and/or the transmissionof signals from these sites. Indeed, corticosteroid receptorshave been localized in many of these extrahypothalamic sites (16).

Two nuclear receptors mediate corticosteroid actions in the brain: a high affinity, low-capacity mineralocorticoid receptor(MR) and a lower affinity, higher-capacity glucocorticoid receptor(GR) (31, 42). The genomic effects of DOCA on NaCl intakeare probably mediated via the MR, because other investigatorshave found that although high doses of DOCA can activate GR, thisreceptor does not appear to mediate DOCA-induced NaCl intake (36,51). Early studies of radioligand binding in brain homogenates(20, 60) and neuronal cultures (47) indicated that DOCAtreatment increases ANG II-receptor expression in the rat brain.These studies would suggest either that mineralocorticoid inhibitionof OT and VP is mediated via a mechanism other than DOCA-inducedchanges in ANG II-receptor expression or that DOCA actually decreasesANG II-receptor expression in a specific brain region. However,a more recent autoradiographic study was not able to localizea brain region where DOCA induced any significant changes in AT₁-or AT₂-receptor density (39), suggesting that DOCA-induced changesin ANG II-receptor expression may not play a major role in theregulation of the OT and VP responses to ANGII.

Few studies have been able to localize the MR in the PVN or SON (16), making it unlikely that DOCA regulates OT sensitivityby a direct genomic action on MR in OT neurons. Because the amygdalaand BNST both express MR (16) and the circumventricular organshave been observed to accumulate MR-specific ligands (2), DOCAmay mediate the transmission of the ANG II signal to hypothalamicOT neurons in these sites. However, we were not able to observea significant effect of DOCA on ANG II-induced c-Fos in the forebraincircumventricular organs and ANG II induced minimal c-Fos expressionin the amygdala and BNST (not shown), suggesting that if DOCAchanges the sensitivity of these neurons to ANG II, this differenceis not detectable by c-Fos immunohistochemistry. Alternatively,some recent hypothalamic explant studies suggest that some steroidsmay directly inhibit neurohypophyseal secretion via nongenomicmechanisms (28, 49), and further studies will be necessaryto evaluate whether these mechanisms participate in the effectsof chronic DOCA administration on OT and VPactivation.

Differential mineralocorticoid regulation of direct and indirect ANG II stimulation of the PVN and SON could also accountfor the finding that the attenuation of c-Fos expression in VPneurons in the SON after the 5-ng dose of icv ANG II was completelyoverridden by the 10-ng dose of ANG II and the finding that DOCAdid not prevent activation of c-Fos in VP neurons in the PVN aftereither dose of ANG II. Because ANG II receptors are located onparvocellular VP neurons (1), ANG II probably stimulates theseneurons directly, and this may account for our inability to observea DOCA-induced attenuation of ANG II-induced c-Fos immunoreactivityin VP neurons in the PVN. In contrast, VP neurons in the SON andOT neurons in both nuclei are most likely stimulated by ANG IIvia indirect neuronal projections. Therefore, we hypothesize thatDOCA selectively inhibits the responsiveness of the neurons thatindirectly transmit the ANG II signal to the SON and PVN or theresponsiveness of the SON and PVN to these indirectsignals.

In addition to increasing c-Fos immunoreactivity in hypothalamic OT neurons, the 10-ng icv ANG II injection used in thesestudies also stimulated pituitary OT secretion. This finding isin agreement with other studies that indicate that icv injectionsof ANG II stimulate pituitary OT secretion and c-Fos immunoreactivityin OT neurons (3, 8, 21). As a result, it was possibleto measure circulating OT levels as a second measure of OT neuronalactivation under these conditions. In contrast, the 10-ng icvANG II injection did not significantly stimulate pituitary VPsecretion at the same time it stimulated c-Fos immunoreactivityin VP neurons. Although other investigators have reported thaticv injections of ANG II stimulate peripheral VP secretion (19,24, 40), these studies used higher doses of ANG II in anesthetizedrats (24), took blood samples more rapidly (e.g., 90 s) afterstimulation (19), or injected ANG II directly into the PVN (40).Consequently, it is impossible to compare the results of thosestudies with the conditions used in the current study. Becauseof this, it was necessary to use c-Fos immunoreactivity in VPneurons as the sole measure of VP neuronal activation in thesestudies, rendering these results more subject to question thanthose involving OT neuronalactivation.

Mineralocorticoids have several well-known systemic effects (5) that could also indirectly contribute to inhibition ofOT and VP neurons. Although these parameters were not measuredin these studies, DOCA is well known to augment renal sodium reabsorptionand increase plasma volume, and chronic DOCA treatment and dietarysodium loading induce hypertension (5). Because more than 5days of DOCA treatment and dietary sodium loading are requiredto induce hypertension in rats (52), it is unlikely that theanimals became hypertensive in this study. However, because DOCA-inducedincreases in plasma volume (58) and sodium concentration (25)have been shown to precede the development of hypertension, itis possible that DOCA-induced changes in these parameters couldhave occurred during the course of the present experiment andindirectly contributed to the decrease in responsiveness of theOT and VP neurons to ANG II. Stimulation of cardiac volume receptorsvia right atrial distension has been shown to decrease stimulatedNaCl intake in rats that are volume depleted by peritoneal dialysiswith hyperoncotic colloid (50), but acute stimulation of cardiacvolume receptors has been shown to stimulate rather than decreaseOT secretion (14). We have also found that the OT and VP responsesto hypertonic saline, hypovolemia, and CCK are reduced in a 1-desamino-8-D-argininevasopressin-induced model of chronic volume expansion and hyponatremia(54), demonstrating that chronic hyponatremic volume expansiondoes attenuate OT and VP responses (53). However, DOCA treatmentinduces a hypernatremic volume expansion, and chronic hypernatremiacauses stimulation rather than inhibition of OT and VP secretion.Consequently, the net effect of a hypertonic volume expansionon the responsiveness of OT and VP neurons is difficult toestimate.

In summary, DOCA treatment attenuates neurohypophyseal responses to icv ANG II, and particularly OT neuronal activation, viaas yet incompletely understood mechanism(s). This attenuationappears to be relatively specific for ANG II, because it doesnot occur in DOCA-treated rats given hypertonic saline or CCKas a stimulus to neurohypophyseal secretion, although this effectmay be a function of stimulus intensity rather than specificity.Indeed, higher doses of ANG II appear to override the DOCA-inducedattenuation of OT in the PVN and VP in the SON and PVN. Thesefindings therefore suggest that DOCA causes a relative attenuationof the responsiveness of OT and VP neurons to ANG II but withoutcompletely suppressing the activity of these neurons either toother stimuli or to larger angiotensinstimuli.

Perspectives

We have previously observed that circulating OT levels correlate inversely with NaCl intake (45), and we have shown thatintracerebroventricularly (4) but not systemically (45) administeredOT and OT-receptor antagonists inhibit and disinhibit stimulatedNaCl intake, respectively. As a result of these studies, we haveproposed that a subset of centrally projecting parvocellular OTneurons may mediate, in part, inhibition of NaCl intake (44).The activity of these centrally projecting OT neurons is mostlikely reflected by the c-Fos analyses and secretion measurementsmade in this study, because peripheral OT secretion correlateswell with c-Fos immunoreactivity in OT neurons (17) and manycentrally projecting parvocellular OT neurons are known to becoactivated with pituitary-projecting magnocellular OT neurons(22, 26). More direct evidence in support of this hypothesiscomes from the analysis of c-Fos expression in the parvocellularsubdivisions of the PVN that shows a decreased responsivity toANG II administration in DOCA-treated rats that is quantitativelysimilar to that found in the posterior magnocellular subdivisionof this nucleus. These studies therefore support the hypothesisthat attenuation of the stimulated activity of a subset of centrallyprojecting OT neurons that are inhibitory to NaCl ingestion representsone mechanism by which mineralocorticoids exert their well-knowneffect to enhance NaCl intake in rats. However, this effect probablydoes not occur in isolation but rather likely works in concertwith other potential mechanisms that are excitatory to NaCl ingestion,such as mineralocorticoid-induced enhanced angiotensin-receptorexpression and/or synergistic effects of mineralocorticoids andANG II on individual neurons. Thus, by combined effects of reducinginhibition concurrently with increasing stimulation, mineralocorticoidscan more effectively enhance NaClintake.

	ACKNOWLEDGEMENTS

We thank E. A. Baker, A. Demko, M. Shi, and Dr. Ying Tian for expert technical assistance during various phases of these studiesand Dr. Edward Stricker for advice and helpfulsuggestions.

	FOOTNOTES

This research was supported by National Institutes of Health Grant PO1-MH43787.

Present address for R. E. Blackburn-Munro: Department of Psychopharmacology and Depression, H. LUNDBECK A/S, 9 Ottiliavej,DK 2500 Valby, Copenhagen,Denmark.

Address for reprint requests and other correspondence: D. M. Roesch, 350 Bldg. D, Georgetown Univ., 4000 Reservoir Road, NW,Washington, DC 20007 (E-mail: roeschd{at}gunet.georgetown.edu).

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

Received 27 January 2000; accepted in final form 18 January 2001.

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