Gonadal steroids modulate pulsatile luteinizing hormone secretion by perifused rat anterior pituitary cells

Recent studies have shown that LH secretion is pulsatile and that LH pulse characteristics are affected by the prevailing steroid environment in both male and female rats. In the present study, a cell perifusion system was used to examine the effects of testosterone (T) and 17 beta-estradiol (E) on LHRH-stimulated pulsatile LH secretion. T inhibited LH secretion, increasing the EC50 for LHRH, while E stimulated secretion, lowering the EC50. Steroid effects were independent of both LHRH pulse amplitude and frequency. E also affected the pattern of LH secretion by facilitating both LHRH self-priming and desensitization to LHRH. These results show that steroids can affect pulsatile LH secretion by actions exerted at the pituitary level and that steroids can induce both quantitative and qualitative changes in LH secretion in the presence of an invariant LHRH stimulus. These results help to elucidate the mechanisms underlying steroid feedback in vivo, since reduction in pituitary responsiveness to LHRH may play an important role in T feedback, while facilitation by E of both self-priming and desensitization may serve to increase the magnitude and shorten the duration of the proestrous LH surge.     

Effects of inhibin from primate Sertoli cells on follicle-stimulating hormone and luteinizing hormone release by perifused rat pituitary cells

We used a pituitary cell perifusion system to investigate the time course and selectivity of the inhibin effect on pulsatile GnRH-stimulated LH and FSH release. Dispersed pituitary cells from 7- to 8-week-old male rats were perifused on a Cytodex bead matrix and stimulated with 10 nM GnRH for 2 min every hour for 8-11 h. The addition of a preparation of inhibin partially purified from primate Sertoli cells reduced pulsatile FSH release within 2 h. After removal of inhibin from the perifusion medium, the effect was reversed within 3 h. GnRH-stimulated LH release was also influenced by inhibin, although the decline in LH was less than that in FSH (80 +/- 3% vs. 68 +/- 4% of control; P less than 0.025). Smaller doses of inhibin suppressed GnRH-induced FSH secretion, but had no effect on LH release. Further, prolonged incubation of pituitary cells with inhibin at the higher dose reduced its FSH inhibitory effect and eliminated the effect on LH. These results indicate that inhibin can reduce both LH and FSH secretion in vitro, although the specificity and magnitude of the effect are a function of both the dose and duration of inhibin treatment. Further, the actions of inhibin and GnRH on the pituitary may be interrelated.     

Gonadotropin-releasing hormone-stimulated luteinizing hormone secretion by perifused pituitary cells from normal, gonadectomized, and testicular feminized rats

To elucidate further the manner in which gonadal steroids influence the secretion of LH, we examined the effects of gonadectomy and the absence of functional androgen receptors on GnRH-induced LH release from dispersed rat anterior pituitary cells. Intact and gonadectomized (GNX) normal rats and androgen-resistant, testicular feminized (Tfm) animals from the King x Holtzman strain (a mutant strain that possesses defective androgen receptors) were used. Dispersed pituitary cells were perifused with Medium 199 during a 4-h equilibration period and then subjected to eight 2.5-min pulses of GnRH introduced at 30-min intervals at concentrations ranging from 0.03-100 nM. Basal LH secretion by cells from intact male and female rats was indistinguishable (P = 0.79) and was substantially lower (P less than 0.0001) than that by cells from GNX male and female animals. Basal LH secretion by cells from Tfm rats was significantly higher (P less than 0.01) than that by cells from intact animals, but lower (P less than 0.005) than that by cells from GNX animals. In response to GnRH, perifused pituitary cells from animals representing all experimental groups demonstrated concentration-dependent LH release. Pituitary cells from intact female rats showed an overall greater (P less than 0.05) response to GnRH than cells from intact male rats. Pituitary cells from Tfm rats demonstrated a greater GnRH-stimulated LH mean response than cells from intact male (P less than 0.0001) or intact female (P less than 0.0001) rats. Gonadectomy of male rats resulted in an overall GnRH-stimulated LH release similar to that exhibited by cells from gonadectomized female rats (P = 0.61). Cells from Tfm animals released more LH in response to GnRH than those from gonadectomized male and female rats (P less than 0.001). These data demonstrate that the release of LH in response to GnRH by pituitary cells from intact male rats (i.e. in the presence of androgen and functional androgen receptors) is less than that seen by cells from intact females rats. Since circulating levels of testosterone and estradiol are known to be elevated in the testicular feminized rat, the heightened GnRH-stimulated LH release by cells from such animals may reflect either the long term lack of androgenic influence and/or the combined effects of androgen resistance and elevated levels of circulating estrogens.     

Gonadotropin-releasing hormone-mediated desensitization of cultured rat anterior pituitary cells can be uncoupled from luteinizing hormone release

GnRH stimulates LH release from pituitary gonadotropes. Prolonged exposure of these cells to GnRH results in decreased sensitivity to further stimulation by the releasing hormone both in vivo and in vitro. Chelation of extracellular Ca++ with EGTA blocks GnRH-stimulated LH release but does not prevent subsequent desensitization. Desensitization occurs when cells are preincubated in EGTA containing 10(-7) M GnRH for a variety of times (20 min to 12 h) or when cells are preincubated for 3 h in EGTA with 10(-10), 10(-9), or 10(-8) M GnRH. A GnRH antagonist does not cause desensitization to GnRH and blocks desensitization in response to GnRH in the Ca++-free medium. Preincubation in EGTA containing 10(-7) M GnRH for 3 h did not alter sensitivity of cells to sn 1,2 dioctanoylglycerol (a protein kinase C activator), Ca++ ionophore A23187, or veratridine (an activator of endogenous ion channels). These results suggest that desensitization results from occupancy of the GnRH receptor by an agonist and may be uncoupled from LH release.     

Effects of glucocorticoids on secretion of luteinizing hormone and follicle-stimulating hormone by female rat pituitary cells in vitro

To determine if the divergent effects of glucocorticoids on the circulating levels of LH and FSH in female rats are exerted directly on the pituitary, adult female pituitary cells were treated either with no glucocorticoids or with 60 or 600 ng/ml cortisol or corticosterone during one or two 48-h incubations. During the second 48 h, some cells from each group were treated with GnRH (1.7 X 10(-12) - 4.6 X 10(-9) M). Concentrations of LH and FSH in media and cells were measured by RIA. Basal secretion of LH was inhibited 38-43% by different glucocorticoid treatment during the first 48 h and 21% by 600 ng/ml corticosterone during the second 48 h. In contrast, basal secretion of FSH was enhanced 22-64% during the first 48 h and 25-124% during the second 48 h. Secretion of LH in response to maximal stimulation with GnRH was unaffected by glucocorticoids, but maximal secretion of FSH was increased 68%. The responsiveness of the cells to GnRH, as determined from the slope of the GnRH dose-response curve for LH, was increased 43-50% by cortisol. The slope of the dose-response curve for FSH was unaffected, but the mean concentration of FSH as a function of the log dose of GnRH was increased 45-79%. Glucocorticoids had no effect on cell content of LH or total LH per dish, either under basal or maximal GnRH-stimulated conditions. Glucocorticoids increased basal cell content of FSH 41-82%, basal total FSH 35-93%, and maximal GnRH-stimulated total FSH 40-84%. These results suggest that the only negative effect of glucocorticoids on reproduction exerted at the level of the pituitary is a slight suppression of basal LH secretion, that glucocorticoids affect the pituitary directly by increasing FSH synthesis, and that the divergent effects of glucocorticoids on LH and FSH provide a novel model for differential regulation of the gonadotropins.     

Functional characterization of luteinizing hormone responsiveness and desensitization in perifused interstitial cells

The characteristics of the steroidogenic response of isolated rat testis interstitial cells to repeated 10 min pulses of ovine LH at 2 h intervals were examined in a Bio-gel perifusion system. Maximal responsiveness of the perifused interstitial cells could be maintained for 6-8 h. Thereafter, both basal and LH-stimulated testosterone production declined gradually despite supplementation of the perifusion medium with 1% and 5% foetal calf serum or 0.5 microgram/ml insulin. In contrast to the time-related steroidogenic decline, a dose-dependent refractoriness of the interstitial cells could be induced by repeated exposure to LH pulses from 0.01 to 10 ng/ml during the first 6 h of perifusion. The higher the stimulating dose of LH, the greater was the rate and magnitude of the resultant desensitization. With lower doses (0.01 and 0.1 ng/ml) of LH, an initial sensitization or priming effect was also observed. These changes in steroidogenic response occurred in the absence of any significant alterations in LH/hCG receptor binding of the perifused interstitial cells, nor could the refractory state be overcome by stimulation with analogues of cAMP. The perifused interstitial cells, when desensitized with low doses of LH (0.1 ng/ml), were capable of increasing or maintaining testosterone production in response to further stimulation with higher doses of LH (1 and 10 ng/ml). The mechanism(s) underlying the in vitro desensitization of perifused interstitial cells by LH may best be explained on the basis of the interaction between the negative effects of substrate depletion and the positive influence of mobilization of substrate(s) into the metabolically active pool for cholesterol side-chain cleavage. It was concluded that the dose of LH used in the pulsatile stimulation of perifused interstitial cells is critically important not only in determining the total amount of testosterone produced, but also in the pattern of response in terms of the degree of sensitization and desensitization induced.     

Identification of human luteinizing hormone, follicle-stimulating hormone, luteinizing hormone beta-subunit and gonadotrophin alpha-subunit in foetal and adult pituitary glands.

Specific radioimmunoassays were used to assess the content of LH, FSH, the gonadotrophin alpha-subunit and the LH beta-subunit in four adult, 19 normal foetal pituitary glands (9-5--32 weeks of gestation) and a pituitary extract from an anencephalic foetus (36 weeks). The hormones and subunits were further identified by column chromatography on Sephadex G-100. All pituitary glands contained free alpha-subunit and intact LH but the alpha-subunit:LH ratio was significantly higher in the early foetal pituitaries (9-5--16 weeks) than in the four adult pituitaries. Only small or undetectable amounts of LH beta-subunit and 'undetectable' FSH were found in these early foetal pituitaries (9-5--11-5 weeks). The concentration of intact hormones or subunits in the pituitaries showed no significant sex difference in any of the groups. In contrast to these results, only alpha-subunit was detectable in the pituitary of the anencephalic foetus. For 14 early foetuses (age of gestation 10--16 weeks) the serum levels of LH-HCG, FSH, and alpha-subunit in the circulation were significantly higher than in 26 foetuses at term (37--41 weeks). On the basis of these results a theory for the development of the gonadotrophin secretion from the foetal pituitary gland is outlined.     

Effects of luteinizing hormone (LH)-releasing hormone pulse amplitude and frequency on LH secretion by perifused rat anterior pituitary cells

Recent studies have shown that LH secretion in vivo is pulsatile. In the present study, a cell perifusion system was employed to characterize the pituitary response to changes in LHRH pulse amplitude and frequency. Increases in pulse amplitude consistently elevated both mean LH levels and the amount of LH released in response to individual LHRH pulses. The EC50 for LHRH was approximately 3 nM. Increases in pulse frequency also increased mean LH levels, but frequencies of three or more pulses per h were associated with a decrease in the amount of LH released per pulse. Alterations in LHRH pulse characteristics changed qualitative as well as quantitative aspects of LH secretion, with high frequency, high amplitude pulses producing a biphasic response to LHRH. Initially a self-priming response was seen during the second and third hours of stimulation; this was followed by increasing desensitization of the cultures to LHRH. These results, by defining the pituitary response to specific conditions of stimulation, will help to clarify the relationship of LHRH stimulation to LH secretion in vivo.     

Changes in the responsiveness of perifused rat adenohypophysial cells to repeated stimulation with luteinizing hormone releasing hormone

The ability of luteinizing hormone releasing hormone (LRH) to stimulate the release of luteinizing hormone (LH) from columns of enzymatically dispersed perfused adenohypophysial cells is being used to study the mechanisms controlling the secretion of LH. LRH stimulated the release in vitro of LH from columns of rat pituitary cells. However, when exposed repeatedly (1 pulse every 12 min) to the same submaximal dose (8 nmol/l) of LRH the cells always exhibited a marked progressive increase and subsequent decrease in their responsiveness. Similar effects occurred when the interval between pulses was extended to 20, 30 or 45 min. The enhanced responsiveness of the cells was prevented by the inclusion of protein synthesis inhibitors, cycloheximide or puromycin, in the perifusion fluid. Cells removed from rats ovariectomized 14 days previously also failed to exhibit increased responsiveness when stimulated repeatedly with LRH. LH secretion was also elicited by K+ (50 nmol/l), 8-bromoadenosine 3'-5'-cyclic monophosphate (8-Br-cAMP, 6 nmol/l), 8-bromoguanosine 3'-5'-cyclic monophosphate (8-Br-cGMP, 6 nmol/l) and a calcium ionophore (A23187, 40 mumol/l) but the responses to these secretagogues differed markedly from those to LRH for the tachyphylaxis which resulted from repeated exposure was not preceded by an increase in responsiveness. The decreased responsiveness to K+ developed in parallel with that to LRH. Diminished responses to the cyclic nucleotides and the Ca++ ionophore developed more rapidly, but the refractory cells responded readily to stimulation with LRH or K+.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of recombinant inhibin on luteinizing hormone and follicle-stimulating hormone secretion in the rat

We investigated the effect of the iv injection of recombinant human (rh) inhibin on FSH and LH secretion in the female rat under various experimental circumstances. Rh inhibin caused dose-related decreases in mean plasma FSH, but not LH, levels in ovariectomized female rats 14 days old and older. The duration of this inhibition was proportional to the dose of rh inhibin, but no consistent changes in FSH secretion were observed until 4 h after treatment. Maximum suppression of FSH release was observed at about 15 micrograms rh inhibin/kg BW and lasted 8-10 h. Measurement of the area under the curve from 4-12 h after injection of inhibin indicated a dose-related decrease in total FSH secreted. When blood samples were withdrawn every 10 min to evaluate pulsatile gonadotropin release, analysis of FSH pulse parameters indicated that rh inhibin (25 micrograms/kg) interfered with pulse frequency, amplitude, and peak levels in both intact and ovariectomized rats. In contrast, pulsatile LH secretion was not measurably altered. These results demonstrate that rh inhibin acts primarily at the level of the pituitary to inhibit all parameters of FSH secretion and suggest that this effect is at least not entirely mediated by changes in GnRH receptors.     

The stimulation of luteinizing hormone and follicle-stimulating hormone secretion in quail with complete and skeleton photoperiods

Photostimulation of quail by long daylengths stimulates LH and FSH release, the earliest increases in these hormones being detectable after 1 long day. Reproductive maturity is complete within 1 month. Steroid feedback becomes important during the second week of photostimulation and restricts LH and FSH secretion to a fraction of the concentrations observed in gonadectomized birds. The photoperiodic response is not all-or-none, and above a certain “critical daylength” the rate of gonadal growth, primarily controlled by the levels of FSH and testosterone, is proportional to daylength. Photoperiodic responses are qualitatively identical in gonadectomized and intact quail, arguing that stimulatory daylengths act directly on the hypothalamo-pituitary axis to alter LH and FSH secretion, and do not act by altering steroid feedback sensitivity and thereby gonadotrophin release. Any changes in feedback sensitivity are a consequence not a cause of the photoperiodic drive on the system. The use of “skeleton” photoperiods to mimic complete photoperiods is discussed. Whether or not one or two peaks of photoperiodic induction appear in asymmetric skeleton experiments depends both upon the duration of the first light period and of the night break itself. The rate of induction is less when quail are photostimulated with night breaks than with “complete” daylengths. The temporal position of the circadian rhythm(s) involved in photoperiodic time measurement in quail is controlled by both “dawn” and “dusk,” and so the position of the rhythm is phase-delayed as the days lengthen, occurring later and later in the night. This arrangement might have some bearing on the seasonal shift in critical daylength that occurs in quail exposed to natural photoperiods. The situation is compared with that in insects and plants.     

Ca+2 dependence of gonadotropin-releasing hormone-stimulated luteinizing hormone secretion: in vitro studies using continuously perifused dispersed rat anterior pituitary cells

A continuously perifused dispersed rat anterior pituitary cell system was used to determine the importance of calcium (Ca+2) on the release of LH by GnRH. In response to continuous exposure to 10 nM GnRH, LH was released in a biphasic fashion; arbitrarily, phase I was defined as being the LH released during the initial 40 min and phase II as the subsequent release. Withdrawal of Ca+2 from the perifusion medium during phases I or II of LH release led to a rapid inhibition of the LH secretion. Cells were exposed to GnRH for 2.5 min, washed with medium for 30 min, and then reexposed to GnRH for 30 min. This sequence was repeated 1 h later under identical conditions in the presence of a Ca+2 blocking agent; D600 (20 or 100 microM). D600 inhibited both the 2.5- and the 30-min GnRH-stimulated LH release. The results were expressed as the ratio obtained by dividing the total LH released during the second GnRH exposure (either 2.5 or 30 min) by the total LH released during the respective initial GnRH exposure of same duration. For the cells perifused with 20 microM D600 the ratios +/- SE (D600 vs. control) were 0.48 +/- 0.06 vs. 1.28 +/- 0.13 (P = 0.0001) and 0.29 +/- 0.05 vs. 1.01 +/- 0.08 (P less than or equal to 0.0001) for the 2.5- and 30-min exposures, respectively. For the cells perifused with 100 microM D600 the ratios +/- SE (D600 vs. control) were 0.18 +/- 0.05 vs. 1.28 +/- 0.13 (P less than or equal to 0.00001) and 0.12 +/- 0.03 vs. 1.01 +/- 0.08 (P = 0.002) for the 2.5- and 30-min exposures, respectively, revealing an even more profound inhibitory effect of D600 on GnRH stimulated LH secretion. Our data both confirm previous reports that Ca+2 is involved in LH release and demonstrate that Ca+2 is an essential requirement during both phases of GnRH-stimulated LH release in perifused dispersed rat anterior pituitary cells.     

Growth hormone enhances follicle-stimulating hormone-induced differentiation of cultured rat granulosa cells

Suppression of serum GH levels in immature rats is associated with delayed onset of puberty and decreased ovarian steroidogenic responsiveness to FSH. To investigate possible direct effects of GH on the differentiation of ovarian cells, granulosa cells from hypophysectomized estrogen-treated rats were cultured with FSH in the presence or absence of GH for 3 days. FSH stimulated granulosa cell LH receptor formation and steroid production in a dose-dependent manner. Concomitant treatment with GH increased LH receptor content by enhancing the action of low doses of FSH without substantial increases in the maximal response. This increase was due to an elevation in the receptor number rather than changes in their affinity for hCG. At 3 ng/ml FSH, concomitant treatment with ovine or bovine GH increased LH/hCG binding in a dose-dependent manner, with 300 ng/ml GH increasing the FSH action by about 3-fold. LH receptors in the GH-treated cells were functional, as indicated by the enhanced cAMP production of these cells in response to LH treatment. The cellular protein content in the FSH-treated cultures was slightly increased by GH (18%), but cell number and viability were unaffected. The change in cell protein content could not account for the increases in the amount of LH receptors. In addition to its effects on LH/hCG receptor content, GH also augmented FSH-stimulated progesterone and 20 alpha-hydroxy-4-pregnen-3-one production in a dose-dependent manner, with 100 ng/ml GH causing significant increases in FSH-induced progesterone production. In contrast, GH treatment did not significantly affect FSH-stimulated estrogen production. The augmentating effects of GH on LH receptor formation and progestin biosynthesis were associated with an enhancement of FSH-stimulated cAMP production. In addition, GH increased forskolin- and 8-bromo-cAMP-induced LH receptor formation and progestin production. Thus, GH-augmented LH receptor induction and progestin biosynthesis may be due to both increased cAMP production and enhanced action of cAMP. The present data have demonstrated that GH augments gonadotropin-stimulated differentiation of ovarian granulosa cells, suggesting an important regulatory role of GH in follicular growth and pubertal development.     

Effects of glucocorticoids on responsiveness of luteinizing hormone and follicle-stimulating hormone to gonadotropin-releasing hormone by male rat pituitary cells in vitro

To determine if the inhibitory effects of glucocorticoids on GnRH-stimulated secretion of LH observed in male rats in vivo are exerted directly on the pituitary, dispersed pituitary cells from adult male rats were treated with 60 or 600 ng/ml cortisol (F) or corticosterone (B) during one or two 48-h incubations. Control cells received no glucocorticoids. During the second 48 h, some cells from each group were treated with GnRH (2.4 X 10(-11)-6.2 X 10(-8) M). Concentrations of LH and FSH in media and cells were measured by RIA. Treatment with steroids had no effect on basal secretion or maximal GnRH-stimulated secretion of LH, or on maximal secretion of FSH. Treatment with 600 ng/ml B for 96 h increased basal secretion of FSH relative to controls. All treatments with glucocorticoids increased the slopes of the GnRH dose-response curves for both LH and FSH, cell content of LH, total (cells + medium) LH, and total FSH. Incubation with 6 micrograms/ml F or B or 60 ng/ml dexamethasone gave similar results. Decreasing the time period of the second incubation to 6 h results in no significant differences between control cells and cells treated with B or F. These results show that glucocorticoids have different effects in vivo and in vitro, suggesting that inhibitory effects of glucocorticoids on secretion of LH in vivo may not be exerted directly on the pituitary but are exerted elsewhere, perhaps by altered hypothalamic secretion of GnRH. Also, these results show that male and female pituitaries in vitro respond differently to glucocorticoids.     

Gonadotropin-releasing hormone desensitization preferentially inhibits expression of the luteinizing hormone beta-subunit gene in vivo

In this study we investigated changes in steady state cytoplasmic mRNA levels for LH subunits in pituitaries of male rats desensitized by continuous infusion of GnRH in vivo. Seven days of GnRH infusion (340 micrograms/day) reduced (P less than 0.01) LH beta mRNA levels in intact adult male rats and prevented the LH beta mRNA rise observed after castration. In contrast, common alpha mRNA doubled (P less than 0.05) in intact rats, and the elevated alpha mRNA after 7 days castration was unchanged. Serum and pituitary LH levels were suppressed below values of intact controls. Fourteen days of GnRH infusion (290 micrograms/day) further reduced LH beta mRNA levels in both intact and castrated male rat pituitaries. alpha mRNA levels in intact rat pituitaries were unchanged by 14 days of GnRH infusion, while in castrated rats there was a 23% (P less than 0.05) decrease, though values were still twice those of intact controls. As at 7 days, serum and pituitary LH were suppressed. Infusion of a superagonist analog (Buserelin) at a dose of 14 micrograms/day for 28 days reduced LH beta mRNA to 15% of intact control values in both castrated and intact rats. Common alpha mRNA was significantly (P less than 0.05) increased in intact rats and reduced by 13% (P less than 0.05) in castrates by superagonist infusion. These results were similar to those produced by 20- to 30-fold higher doses of native GnRH. GnRH and agonist analog effects were specific since no changes were observed in other mRNA species (GH, PRL, actin). These results indicate that in GnRH-desensitized gonadotropes LH beta gene expression is inhibited, and this may largely explain the reduced LH biosynthesis. However, there is a differential effect of continuous GnRH or agonist analog treatment on LH subunit gene expression, with a time-dependent stimulation of common alpha gene expression in intact rats. This may be caused by a stimulatory interaction between GnRH and progestagens at the level of the gonadotrope. Thus, common alpha gene expression is less tightly coupled than that of LH beta to GnRH action.