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Kainate Receptor Subunit-Positive Gonadotropin-Releasing Hormone Neurons Express c-Fos during the Steroid-Induced Luteinizing Hormone Surge in the Female Rat¹

Department of Anatomy and Neurobiology University of Kentucky College of Medicine, Lexington, Kentucky 40536

Address all correspondence and requests for reprints to: Lothar Jennes, Ph.D., Department of Anatomy and Neurobiology, University of Kentucky College of Medicine, 428 Health Science Research Building, Lexington, Kentucky 40502. E-mail: ljenn0{at}pop.uky.edu

	Abstract

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During the preovulatory and estradiol-progesterone-induced GnRH-LH surge, a subpopulation of GnRH neurons transiently expresses the transcription factor c-fos, which is a useful marker of cell activation. To further characterize this subpopulation of GnRH neurons, multiple immunohistochemical procedures were applied to visualize GnRH, c-Fos, KA2, GluR5, GluR6, and GluR7 receptor subunits during different phases of the estrogen-progesterone-induced LH surge. The results show that the LH surge begins at 1400 h and peaks at 1600 h before returning to baseline late in the evening. At 1400 h, about 50% of the GnRH neurons contained c-Fos, and this percentage remained high at 65% at 1600 and 2000 h. During the surge, 50% of the c-Fos-positive GnRH neurons contained KA2 receptor subunit protein at 1400 h, 65% of the c-Fos-positive GnRH neurons expressed the KA2 subunit at 1600 h, and 50% of the c-Fos-positive GnRH neurons expressed the KA2 subunit at 2000 h. As KA2 subunits require other kainate-preferring subunits to form functional receptor channels, we examined GnRH neurons for the presence of GluR5, GluR6, and GluR7 messenger RNA (mRNA) and protein. The results show that the KA2-containing GnRH neurons also contain GluR5 receptor subunit mRNA and protein, and that these GnRH neurons are c-Fos positive during the steroid-induced LH surge.

To determine whether administration of kainate is sufficient to induce c-Fos in GnRH neurons, steroid-primed animals received iv injections of subseizure-inducing amounts of kainic acid and were processed for immunohistochemistry and in situ hybridization. The results show that kainic acid causes a significant increase in circulating LH; however, it does not induce c-Fos in GnRH neurons, nor does it cause an increase in GnRH mRNA.

Together, the results suggest that a large subset of GnRH neurons expresses KA2 as well as GluR5 receptor subunits, which would allow the formation of functional glutamate receptor channels, and that this subset of GnRH neurons is activated during the steroid-induced LH surge.

	Introduction

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GnRH IS THE KEY hypothalamic hormone that controls the secretory activity of the pituitary gonadotropes throughout all phases of the estrous cycle. The activity of GnRH neurons is governed in turn by positive and negative feedback actions of the ovarian steroids, in particular by estradiol, which inhibits GnRH release during all stages of the cycle, except during proestrus, when a transient change to a positive feedback mode occurs (1). The mechanisms by which the gonadal steroids control GnRH neuronal activity are not clear at present; however, activation of certain neurotransmitter systems that are responsive to estradiol and that innervate GnRH neurons appears to be an important part of the feedback loop system (2, 3). Thus, much evidence has accumulated that the catecholaminergic and glutamatergic neurons are activated by estradiol. For instance, noradrenergic (4) and adrenergic (Lee, E.-J., et al., manuscript submitted) neurons in the rat contain estrogen receptor (ER), and they respond to estradiol with a transient expression of the transcription factor c-fos (5) as well as increased TH messenger RNA (mRNA) levels (6). Similarly, glutamatergic neurons in the hypothalamus contain ER, and administration of estradiol causes an increase in glutamate content (7). As glutamatergic synaptic input to GnRH neurons has been shown in the monkey (8), and noradrenergic synapses occur in the rodent (9), it can be suggested that released neurotransmitter binds to and activates specific membrane receptors located on the plasma membrane of GnRH neurons. For instance, _1B-adrenergic receptor protein has been identified on most GnRH neurons (10), and KA2 subunits of ionotropic glutamate receptors have been described in about 40–50% of the GnRH neurons (11). The distribution of the KA2 receptor subunit expressing GnRH neurons is reminiscent of the distribution of a subpopulation of GnRH neurons that synthesizes the transcription factor c-Fos during the preovulatory surge. These c-Fos-positive GnRH neurons are located preferentially next to the organum vasculosum of the lamina terminalis (OVLT), and they account for about 40–50% of all GnRH neurons (12, 13). Although the exact role of c-Fos in GnRH neurons remains to be clarified, the transient expression of the transcription factor has been a useful indicator of cell activation, and it has been proposed that this c-Fos-positive subset of GnRH neurons initiates or drives the GnRH-mediated LH surge (13). Thus, the aims of the present study were to determine whether the subset of GnRH neurons that expresses KA2 receptor subunits also expresses c-Fos during the surge, and if the administration of kainic acid is sufficient to induce c-Fos protein or to stimulate GnRH synthesis in GnRH neurons. Lastly, as KA2 receptor subunits do not assemble into functional homomeric receptor channels (14, 15), a partner kainate-preferring glutamate receptor subunit needed to be identified.

	Materials and Methods

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Animals
Brain tissue was obtained from adult female Sprague Dawley rats that were housed in the animal facilities of the University of Kentucky Medical Center in a temperature- and light-controlled environment (14 h of light and 10 h of dark, lights on at 0500 h). All procedures involving animals were conducted in accordance with NIH guidelines for the care and use of laboratory animals and were approved by the institutional animal care and use committee of the University of Kentucky.

Immunohistochemistry
Animals were deeply anesthetized with ketamine-acepromazine maleate (50 and 5 mg/kg BW, respectively), and blood was collected by heart puncture for RIA of LH. Animals were then perfusion fixed with 4% paraformaldehyde and 7.5% saturated picric acid in 0.1 M phosphate buffer (pH 7.4; 400 ml/animal). Brains were removed and postfixed overnight in above fixative. Serial 30-µm thick coronal vibratome sections were collected in five series from the region between the medial septum and the suprachiasmatic nucleus and kept in cryoprotectant at -20 C until use. At least five sections per animal/experiment were analyzed.

Double immunohistochemistry
Sections were washed in Tris-HCl buffer (0.05 M; pH 7.6) to remove the cryoprotectant and incubated in blocking buffer (10% normal horse serum, 0.2% Triton X-100, and 0.1% sodium azide in Tris-HCl buffer) for 1 h. Sections were then incubated in rabbit anti-c-Fos antibody (AP-5, Oncogene, Cambridge, MA) at a dilution of 1:30,000 in blocking buffer overnight at room temperature followed by exposure for 1 h to biotin-conjugated donkey antirabbit IgG (1:500; Jackson ImmunoResearch Laboratories, Inc., West Grove, PA). Sections were processed with the ABC Elite Standard kit (Vector Laboratories, Inc., Burlington, CA) according to the instructions of the manufacturer and stained with filtered (25 mg; Millipore Corp., Bedford, MA) diaminobenzidine and nickel ammonium sulfate (2 g) in the presence of 2 µl H₂O₂ (30%)/100 ml sodium acetate buffer (0.1 M; pH 6.5). The stained sections were then washed extensively in Tris-HCl buffer and blocking buffer and incubated overnight in monoclonal mouse anti-GnRH IgG containing tissue culture supernatant (1:100; AB 4H10, Jennes). Sections were washed in Tris-HCl buffer and exposed to biotinylated donkey antimouse IgG and avidin-biotin complex, as described above, and stained with diaminobenzidine (50 mg and 5 µl H₂O₂/100 ml Tris-HCl). GnRH immunoreactivity was identified as a brown precipitate in the cytoplasm, and c-Fos immunoreactivity appeared as a black precipitate over cell nuclei.

Triple and quadruple immunohistochemistry
The staining of c-Fos protein was conducted as described above. The stained sections were thoroughly washed in Tris-HCl and blocking buffer and incubated in a mixture of rabbit anti-KA2 (R52–4, Jennes and Eyigor, 1:2000) and guinea pig anti-GnRH (GP8–4, Jennes, 1:1000) in blocking buffer for 72 h at 4 C. For quadruple immunohistochemistry, mouse antiglutamate receptor 5/6/7 (GluR5/6/7, 1:400, PharMingen, San Diego, CA) was added to this mixture. After two washes in Tris-HCl buffer of 15 min each, sections were incubated in a mixture of affinity-purified and cross-absorbed second antibodies that were labeled with different fluorescent markers (Jackson ImmunoResearch Laboratories, Inc.). For triple labeling, Texas Red-labeled donkey antirabbit (1:100) was coincubated with FITC-labeled donkey antiguinea pig (1:100), and for quadruple labeling, a Cy-5-labeled second antibody was added. Sections were washed in Tris-HCl buffer, mounted onto glass slides, dried, and coverslipped with ProLong antifade mounting medium (Molecular Probes, Inc., Eugene, OR) 1 h before the analysis. Dual and triple labeled sections were analyzed with an Olympus Corp. BH-2 microscope (New Hyde Park, NY) equipped with the appropriate excitation-barrier filter combinations, whereas quadruple labeled sections were observe with a Leica TCS NT confocal microscope (Leica, Rockleigh, NJ).

Control experiments included absorption of the primary antibodies with 50 µg antigen/ml dilute antiserum, omission of primary antisera, as well as extensive tests of cross-reactivity of the second antibodies. All control experiments resulted in the absence of staining.

In situ hybridization
Deeply anesthetized animals were decapitated, trunk blood was collected for RIA determinations of LH levels, and brains were removed and frozen on dry ice. Twelve-micron thick sections were cut on a cryostat and collected on positively charged slides that were kept in air-sealed boxes at -80 C until use.

Preparation of complementary RNA (cRNA) probes
Complementary DNA (cDNA) clones complementary to glutamate receptor subunits GluR5, GluR6, and GluR7 were provided by Dr. Boulter, Molecular Neurobiology Laboratory at The Salk Institute (La Jolla, CA), whereas the GnRH cDNA clone was a gift from Dr. Adelman, Vollum Institute (Portland, OR). Plasmids containing the cDNA clone complementary to rat GluR5 were linearized with NotI, whereas the other plasmids were linearized with EcoRI (GluR6), BamHI (GluR7), or HincII (GnRH) and transcribed in vitro in the presence of [³⁵S]UTP and T7 RNA polymerase for antisense probes. The characteristics of these clones have been described previously: GluR5, EMBL/GenBank accession no. M83560 (16); GluR6, accession no. Z11548 (17); GluR7, accession no. M83552 (18); and GnRH, accession no. M31670 (19).

For dual in situ hybridization experiments, linearized GnRH cDNA was transcribed in vitro in the presence of digoxigenin-11-UTP (Roche Molecular Biochemicals, Mannheim, Germany) with T7 polymerase, resulting in a 275-base long cRNA probe.

Pretreatment, hybridization, and posttreatment
Slides were equilibrated to room temperature and fixed for 15 min in 4% paraformaldehyde, followed by two 5-min rinses in PBS (0.1 M), two 5-min rinses in PBS containing 10 mM glycine, and two 5-min PBS rinses. The sections were then incubated for 10 min in triethanolamine (0.1 M; pH 8.0) and 0.25% acetic anhydride, dehydrated in ascending ethanol concentrations, and air-dried. Sections were hybridized overnight at 60 C with 1.5 x 10⁶ cpm ³⁵S-labeled kainate-preferring subunit cRNA probe/60 µl·slide and 2 µl digoxigenin-labeled GnRH cRNA probe in hybridization buffer containing salmon sperm DNA (100 µg/ml), yeast total RNA (250 µg/ml), yeast transfer RNA (250 µg/ml), Tris-HCl (pH 7.4; 20 mM), EDTA (1 mM), NaCl (300 mM), deionized formamide (50%, vol/vol), dextran sulfate (10%, vol/vol), Denhardt’s solution (1 x), dithiothreitol (100 mM), SDS (0.1%, wt/vol), and sodium thiosulfate (0.1%, wt/vol). For single in situ hybridization, saturating amounts of ³⁵S-labeled GnRH cRNA probe were used. Sections were then rinsed in 2 x SSC (standard saline citrate) and treated with ribonuclease (10 mg/100 ml) for 30 min at 45 C to reduce the nonspecific binding. The sections were then washed in 0.2 x SSC and kept for 1 h at 60 C in 0.1 x SSC, followed by brief rinses in the same stringency wash at room temperature and 70% and 95% ethanol concentrations and air-dried. For dual in situ hybridization, sections were then incubated in 2% lamb serum in buffer A (100 mM Tris-HCl, pH 7.5, and 150 mM NaCl) with 0.05% Triton X-100 for 2–3 h followed by an overnight incubation in buffer A containing sheep antidigoxigenin Fab conjugated to alkaline phosphatase (1:1,000; Roche Molecular Biochemicals), 1% normal lamb serum, and 0.3% Triton X-100. After washes in buffer A and buffer B (100 mM Tris-HCl, pH 9.5; 100 mM NaCl; and 50 mM MgCl₂), sections were stained in the dark for 1–3 h in chromogen solution (45 µl nitro blue tetrazolium-chloride, 35 µl 5-bromo-4-chloro-3-indolyl phosphate, and 10 mg levamisole/10 ml buffer B). The reaction was stopped in buffer B, followed by rapid rinses in 70% and 95% ethanol. Air-dried sections were coated with 3% parlodion in isoamyl acetate and dried again. The slides were then dipped in Kodak photographic emulsion NTB2 (Eastman Kodak Co., Rochester, NY), diluted 1:1 with water, kept at 4 C, in a light- and humidity-free environment, and exposed for 72 h for single labeling with [³⁵S]GnRH and for 3–8 weeks for dual in situ hybridization. After developing (Kodak Developer D19) and fixing (Kodak Rapid Fixer), sections were analyzed with an Olympus Corp. BH-2 microscope. Specificity controls included incubation with ³⁵S-labeled sense probe, pretreatment with ribonuclease, and coincubation with a 100-fold excess of unlabeled antisense probe. Control experiments resulted in the absence of specific labeling.

Image analysis
Each GnRH-immunoreactive neuron was examined for the presence of KA2 protein in cytoplasm and, when appropriate, for c-Fos immunoreactivity.

Image analysis of the slide autoradiograms was based on measurements of the areas occupied by silver grains over labeled neurons using NIH Image software. Images were captured, and the gray level threshold was adjusted to allow measurements of pixels corresponding to silver grains. The same threshold setting was maintained for the duration of the analysis. For sampling, individual cells were outlined under x40 oil objective on the basis of grain distribution, and the measurements were taken by subtracting the background.

For dual in situ hybridization experiments, slides were analyzed for the coexistence of silver grains with the blue-brown immunostaining reaction product. GnRH neurons were considered double labeled if the number of silver grains over the neurons was at least 3 times higher than background.

Data analysis
Data are expressed as the mean ± SEM for each animal, and then using the individual animal values, a grand mean ± SEM were determined for each group. Data then were subjected to two-way ANOVA, followed by Student’s t test. Differences were considered statistically significant at P < 0.05.

RIA for LH
Plasma LH was measured by a standard double antibody RIA, using the reagents provided by the National Hormone and Pituitary Program, NIDDK. Purified rat LH was iodinated with Iodogen (Pierce Chemical Co., Rockford, IL) and separated from free ¹²⁵I by passage over a Bio-Gel P-60 column (Bio-Rad Laboratories, Inc., Hercules, CA).

Experiments
Exp 1: Do KA2 subunit expressing GnRH neurons also express c-Fos during the steroid-induced LH surge? Our previous studies (11, 20) showed that the KA2 receptor-expressing GnRH neurons are localized in a distribution pattern similar to that of the subgroup of c-Fos-positive GnRH neurons (12, 13). To assess whether the two groups of GnRH neurons are identical or overlap, triple labeling immunohistochemistry was employed to identify GnRH, KA2 subunit, and c-Fos. Fifty-day-old female rats were ovariectomized 12 days before sc implantation at 0900 h of a SILASTIC brand capsule (20 mm long; id, 1.57 mm; od, 3.18 mm; Dow Corning Corp., Midland, MI) containing estradiol (180 µg/ml in sesame oil). Two days later, the animals received one sc injection of progesterone (50 mg/kg BW in sesame oil) at 0900 h. Five groups of animals (n = 4–7) were perfusion fixed as described above at 1000, 1200, 1400, 1600, and 2000 h on the day of the progesterone injection. Ovariectomized control animals received identical sc capsules filled with sesame oil and 2 days later a sc injection of sesame oil.
After immunohistochemical staining for GnRH, c-Fos, and KA2 receptor subunit, sections were analyzed with an Olympus Corp. BH-2 microscope with brightfield and fluorescent illumination.

Exp 2: Which kainate-preferring glutamate receptor subunits are coexpressed with KA2 subunits in GnRH neurons?
KA2 subunits need to assemble with other kainate-preferring glutamate receptor subunits to form a functional heteromeric ion channel (14). We used dual in situ hybridization and triple and quadruple immunohistochemistry to identify a possible expression of GluR5, GluR6, or GluR7 subunits in GnRH neurons. Intact adult female rats were killed in the morning and processed for dual in situ hybridization for GnRH mRNA and one of the above kainate-preferring subunit mRNAs. To identify the subunit proteins and a possible relationship to c-Fos-expressing GnRH neurons, tissues of animals treated as described in Exp 1 were used, and immunohistochemical procedures were applied to identify simultaneously GnRH, KA2, Glur5/6/7, and c-Fos as described above.

Exp 3: Does activation of kainate-preferring glutamate receptors by kainic acid cause an increase in GnRH mRNA levels and/or induction of c-Fos synthesis?. Previous studies have shown that administration of kainic acid to estradiol-treated animals induces an increase in GnRH-mediated LH release (3). To determine whether activation of kainate receptors in GnRH neurons can induce c-Fos synthesis and increase GnRH mRNA levels, in situ hybridization for GnRH mRNA and dual immunohistochemistry for c-Fos and GnRH were applied. Two groups of animals (10 animals/group) were ovariectomized for 2 weeks and treated with estradiol as described in Exp 1. The next day, animals were fitted with an atrial catheter through the right jugular vein. At 0900 h on the following day, animals in both groups received a sc injection of progesterone as in Exp 1, and between 1000–1100 h, group 1 received kainic acid (2.5 mg/kg in saline, iv) and group 2 received saline iv. This time point was chosen because estradiol-induced changes in LH release or c-Fos expression in GnRH neurons have not yet occurred. Blood samples (0.2 ml; replaced with 0.2 ml saline) were collected 10 min before and 10 min after the injections for LH RIA. Thirty minutes after kainate or saline injections, animals were decapitated and processed for in situ hybridization with ³⁵S-labeled GnRH cRNA probe (5 animals/group) or were perfusion fixed 2 h after the injections and processed for immunohistochemistry (5 animals/group) as described above.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Exp 1: Do KA2 subunit expressing GnRH neurons also express c-Fos during the steroid-induced LH surge?
The sequential estradiol-progesterone treatment of ovariectomized female rats resulted in a transient surge in circulating LH concentrations during the afternoon. In this animal model, plasma LH concentrations were basal until 1200 h; they began to rise at 1400 h and reached their peak level at 1600 h before returning to the basal levels late in the day (Fig. 1A).

View larger version (27K): [in this window] [in a new window]   Figure 1. Mean plasma LH levels in female rats during the steroid-induced LH surge (A) *, LH levels at 1600 h are significantly higher (P < 0.05) than those at all other time points. B shows the effect of steroid priming on c-Fos expression in GnRH neurons during the steroid-induced LH surge, showing a large increase in the number of GnRH neurons that express c-Fos during the afternoon (*, P < 0.05) compared with those at the 1000 and 1200 h points. C shows that approximately 50% of all GnRH neurons express KA2 receptor subunit protein during all times of the surge. D shows that during the afternoon of the LH surge, about 50–60% of the c-Fos-positive GnRH neurons also express KA2 receptor subunit (P < 0.05, compared with 1000 and 1200 h points). E shows that about 30% of all GnRH neurons express KA2 and c-Fos at 1400 h and that this percentage increases to 45% at 1600 h. *, Significant differences (P < 0.05) compared with 1000 and 1200 h points; #, significant difference (P < 0.05) compared with 1400 h point.

Immunohistochemical dual stainings for GnRH and KA2 receptor subunit protein showed that about 50% of all GnRH neurons contain this kainate receptor subunit and that this percentage did not change throughout the day of the estrogen-progesterone-induced LH surge (Fig. 1C). Subsequent triple stainings for GnRH, c-Fos, and KA2 subunit revealed that at 1400 h, about 50% of the c-Fos-positive GnRH neurons also contained KA2 subunit protein; this percentage remained high at about 65% at 1600 h and 50% at 2000 h (Fig. 1D). If the data are expressed as the percentage of total GnRH neurons that contained both c-Fos and KA2 subunit, then about 30% of all GnRH neurons contained both c-Fos and KA2 receptor subunit protein at 1400 h; this percentage significantly increased to about 45% at 1600 h (P < 0.05) and had declined to about 35% by 2000 h (Fig. 1E). The data are summarized in Table 1, the locations of c-Fos containing GnRH neurons with and without KA2 receptor subunit protein from a representative animal are detailed in Fig. 2, and an example of a triple labeled GnRH neuron containing c-Fos and KA2 subunit protein is shown in Fig. 3, A–D.

View larger version (20K): [in this window] [in a new window]   Figure 2. Anatomical distribution of GnRH neurons that express KA2 receptor subunit protein (), c-Fos protein (•), or KA2 receptor subunit and c-Fos () or without KA2 receptor subunit and c-Fos proteins () at the peak of the steroid-induced LH surge. Drawings of coronal sections were taken from five hypothalamic levels (200 µm apart) where most GnRH neurons are located: the level of the vertical limb of the diagonal band of Broca (A), OVLT (B), anteroventral periventricular nucleus (C), rostral medial preoptic nucleus (D), and caudal medial preoptic nucleus (E). A representative animal (CR10) was taken from the group of animals that were killed at 1600 h.

View larger version (59K): [in this window] [in a new window]   Figure 3. Simultaneous localization of kainate-preferring glutamate receptor subunits and c-Fos in GnRH neurons using confocal laser scanning microscopy. A–D show a GnRH neuron (A) that expresses KA2 subunit protein (B) and c-Fos (C). D is an overlay of A–C. E–H show a GnRH neuron (E) that contains GluR5/6/7 (F) and KA2 receptor subunits (G). H is an overlay of E–G. I–L show a c-Fos-positive (L) GnRH neuron (I) that contains both GluR5/6/7 and KA2 immunoreactivity (J and K, respectively). Arrows indicate GnRH neurons; arrowheads point to GnRH-negative KA2-positive neurons. Bars, 10 µm.

View larger version (75K): [in this window] [in a new window]   Figure 4. Representative photomicrograph of a GnRH neuron (arrow) that also contains GluR5 mRNA, as determined by dual in situ hybridization histochemistry using digoxigenin-labeled GnRH cRNA probe (blue/black staining) and 35S-labeled GluR5 cRNA probe (silver grains). Bar, 10 µm.

View larger version (12K): [in this window] [in a new window]   Figure 5. Effect of kainic acid (2.5 mg/kg, iv) on plasma LH levels in ovariectomized, steroid-primed, adult female rats 10 min before and after injection (mean ± SEM). *, P < 0.05.

View larger version (13K): [in this window] [in a new window]   Figure 6. Effect of kainic acid (2.5 mg/kg, iv) on GnRH mRNA content in ovariectomized, steroid-primed, adult female rats 30 min after the injection. Data are expressed as the mean ± SEM areas of GnRH neurons occupied by silver grains.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

Glutamate release in the preoptic area is increased before and during the surge (31), and blockade of glutamate receptors with antagonists prevents the surge (25, 32, 33). These data suggest that activation of glutamate receptors is required for an appropriate surge, but it is not sufficient to induce massive GnRH release. It appears, therefore, that glutamate is probably not the neurotransmitter that is the driving force for the activation of GnRH neuronal activity during the surge but, instead, may be important in setting excitability thresholds of GnRH neurons or modifying the responsiveness to other neurotransmitters.

Our finding that KA2 receptor protein is preferentially expressed in those GnRH neurons that synthesize c-Fos during the surge is intriguing and indicates that this subset of GnRH neurons is functionally different from the other GnRH neurons. The transient presence of c-Fos in neurons has been an useful indicator to distinguish activated from nonactivated cells in many neuroendocrine systems (34), and in the case of the GnRH system, a parallelism between the number of c-Fos-positive GnRH neurons and the magnitude of GnRH-stimulated LH release has been proposed (35). This view is supported by our finding as well as the data reported by Attardi et al. (36) that the percentage of c-Fos-positive GnRH neurons is higher during the steroid-induced surge than during a physiological proestrous surge. The exact role of c-fos in GnRH neurons is not known, but the induction of the c-fos gene does not appear to be required for the generation of a preovulatory surge, as c-fos-deficient mice can reproduce (37). On the other hand, Wang et al. (38) found that c-Fos-expressing GnRH neurons contain more GnRH mRNA than c-Fos-negative GnRH neurons. As the GnRH promoter contains an activating protein-1 site to which a c-Fos heterodimer can bind (19), it is possible that c-Fos expression is related to replenishing GnRH peptide in these activated neurons.

c-Fos expression can be induced in neurons by many different stimuli, such as growth factors, membrane depolarization, or neurotransmitters (39). In particular, glutamate agonists have been shown to induce c-Fos synthesis in several seizure models, although it is not fully understood at present whether these effects are mediated solely by activation of the relevant glutamate receptors on the c-fos-expressing target cells or if an agonist-induced reduction of an inhibitory -aminobutyric acid (GABA) tone contributes to the induction of c-Fos synthesis (40). In these models, kainate is the most potent glutamate agonist inducing c-Fos synthesis (40), and based on our finding that most c-Fos-positive GnRH neurons also contain KA2 receptors, it can be speculated that activation of these receptors is responsible for the induction of c-Fos synthesis. However, as peripheral administration of subseizure levels of kainic acid fails to induce c-Fos in GnRH neurons, but not in hippocampal neurons, it is clear that other factors are required to induce c-Fos synthesis in GnRH neurons. It is possible that other neurotransmitters, such as, endogenous GABA, for which the GnRH neurons have receptors (41), prevent c-Fos expression in GnRH neurons during all stages of the estrous cycle, except during the rising phase of the LH surge, when GABA release is reduced. To date, all attempts have failed to induce c-Fos in GnRH neurons by pharmacological treatments with NMDA (42), kainic acid (this report), adrenergic receptor agonists, GABA antagonists, or combinations of these (Eyigor, O., and L. Jennes, unpublished observations), and the only treatment that has been successful is the administration of gonadal steroids. Based upon the finding that treatments with pentobarbital or the glutamate antagonist MK 801 (42) prevent expression of c-Fos in GnRH neurons after treatment with gonadal steroids, it is apparent that the c-Fos-inducing effects of the steroids are mediated by activation/inhibition of neurotransmitter systems that innervate GnRH neurons and not by direct actions of the steroids on GnRH neurons. It is likely that a precisely timed activation of glutamate and/or adrenergic receptors and inhibition of GABA release are required to induce c-Fos synthesis in GnRH neurons and to induce a robust GnRH-mediated LH surge.

In conclusion, the data of this study suggest that a large subset of GnRH neurons expresses KA2 as well as GluR5 receptor subunits, which would allow the assembly of functional glutamate receptor channels, and that this subset of GnRH neurons is activated during the steroid-induced LH surge, as indicated by the transient synthesis of c-Fos.

	Acknowledgments

 
We gratefully acknowledge Mr. Adrian Centers’ excellent technical help.

	Footnotes

 
¹ This work was supported by a predoctoral fellowship (to O.E.) from Uludag University (Bursa, Turkey) and by NIH Grants AG-13444 and MH-59890 (to L.J.).

Received July 21, 1999.

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