Gonadotropin-releasing hormone-dependent regulation of gonadotropin subunit messenger ribonucleic acid levels in the rat

The Nal-Glu GnRH antagonist (GnRHA) was given to castrate male and female rats 7 days after gonadectomy to assess the impact of selective GnRH inhibition on the steady state mRNA levels of FSH beta, LH beta, and alpha-subunit and serum levels of FSH and LH. A low dose of GnRHA (125 micrograms/kg.day) given to female rats for 1, 3, or 7 days resulted in suppression of serum FSH and LH levels by 7 days to 50% and 40%, respectively, of ovariectomized control values. LH beta mRNA levels decreased in a time-dependent manner, so that by 7 days, LH beta mRNA levels were less than those in intact controls. There were significant but less dramatic declines in alpha and FSH beta mRNA levels. A higher dose of GnRHA (500 micrograms/kg.day) for 7 or 14 days administered to castrate male or female rats resulted in inhibition of serum LH and FSH to or below levels in intact controls. At this dose, all three gonadotropin subunit mRNA levels fell from castrate values toward or below those in intact controls. Thus, although low dose GnRHA administration suppressed LH beta mRNA more than FSH beta mRNA levels, high dose GnRHA treatment resulted in equal suppression of all three gonadotropin subunits. No stimulatory effects on alpha-subunit mRNA levels were observed with either dose of GnRHA. We conclude that the pretranslational control of gonadotropin subunit biosynthesis is GnRH dependent. Adequate dose and length of administration of the potent Nal-Glu GnRHA results in suppression of both the serum gonadotropins FSH and LH and the mRNAs for FSH beta, LH beta, and alpha-subunit in female and male rats.     

The frequency of gonadotropin-releasing-hormone stimulation differentially regulates gonadotropin subunit messenger ribonucleic acid expression

The hypothalamic decapeptide GnRH is known to regulate the synthesis and secretion of LH and FSH by pituitary gonadotrope cells. The frequency of pulsatile GnRH secretion changes and LH and FSH are differentially secreted in various physiological situations. To investigate the potential role of altered frequency of GnRH stimulation in regulating differential secretion of LH and FSH, we examined the effects of GnRH frequency on expression of the alpha, LH beta, and FSH beta genes. GnRH pulses (25 ng/pulse) were administered to castrate testosterone-replaced rats at intervals of 8-480 min to cover the range of physiological pulsatile GnRH secretion. Fast frequency GnRH pulses (8-min pulse intervals) increased alpha-subunit mRNA concentrations 3-fold above those in saline-pulsed controls (controls, 1.01 fmol cDNA bound/100 micrograms pituitary DNA) and LH beta mRNA by 50% (controls, 0.18 fmol cDNA bound), but FSH beta mRNA was unchanged (controls, 0.38 fmol cDNA bound). GnRH pulses given every 30 min increased all three subunit mRNAs (alpha, 3-fold, LHbeta, 2-fold; FSH beta, 2-fold), and acute LH release and serum FSH concentrations were maximal after this frequency. Slower frequency GnRH stimuli (120- to 480-min pulse intervals) did not change alpha and LH beta mRNA levels, but increased FSH beta mRNA 2- to 2.5-fold, and FSH secretion was maintained. Equalization of the total dose of GnRH given at different intervals over 24 h confirmed the frequency dependence of subunit mRNA expression. Fast frequency GnRH stimuli (8 min) increased alpha mRNA 1.5- to 2.5-fold, while the same total GnRH doses were ineffective when given at slow frequency (480 min). Similarly, LH beta mRNA was only increased by GnRH pulses given at 8-min intervals. In contrast, FSH beta mRNA increased 2-fold after pulses given every 480 min, and the 8-min pulse interval was ineffective. The data show that the frequency of GnRH stimulation can differentially regulate gonadotropin subunit mRNA expression and may be a mechanism that enables a single GnRH peptide to selectively regulate gonadotropin subunit gene expression and hormone secretion.     

Recombinant human activin-A stimulates basal FSH and GnRH-stimulated FSH and LH release in the adult male macaque, Macaca fascicularis

Activin-A is a homodimer of the beta A inhibin subunit that stimulates FSH secretion by pituitary cells in vitro; however, the physiological relevance of this effect is unknown. We have examined whether recombinant human activin-A (activin-A; 80 micrograms/kg/day iv infusion for 50.5 h) has in vivo bioactivity in the adult male macaque (n = 5). Serum FSH and LH bioactivity and serum testosterone (T) levels were measured on 2 control days and after 24 and 48 h of activin-A administration. Basal FSH levels increased significantly (p less than 0.05) by 17% at 24 h and 82% at 48 h during activin-A administration. No changes in basal LH or T levels were seen. The FSH and LH responses to GnRH (5 micrograms/kg, iv bolus) increased significantly (p less than 0.05) by 117% and 55% after 48 h of activin-A, respectively. A small (16%), but statistically significant (p less than 0.05), increase in the T response to the GnRH challenge was also noted. These data are preliminary evidence in support of a physiological role for activin-A in the control of gonadotropin secretion in the male primate.     

Differential regulation of gonadotropin subunit gene expression by gonadotropin-releasing hormone pulse amplitude in female rats

The role of GnRH in regulating gonadotropin subunit gene expression was examined in adult female rats. Animals were ovariectomized, estradiol implants inserted sc, and jugular cannulae placed into the right atria. On the next day, animals were given GnRH pulses (saline to controls) every 30 min for up to 48 h and alpha, LH beta, and FSH beta mRNA levels measured by hybridization to cDNA probes. To determine the effects of GnRH treatment duration, rats received GnRH pulses (25 ng at 30-min intervals) for 6, 12, 24, and 48 h. FSH beta mRNA was increased (by 92%) after 6 h of pulses and remained elevated through 48 h. alpha mRNA was not increased until 12 h (27% increase) and rose further (57%) by 48 h. LH beta mRNA levels were only transiently increased at 12 h (67%) and values were not different from saline controls after 24 or 48 h. To examine whether the rise in serum PRL which is characteristic of the ovariectomized-estradiol animal model was responsible for the decrease in LH beta mRNA responsiveness to GnRH over longer durations, studies were repeated in bromocriptine-treated animals (0.6 mg sc, twice daily). The results showed similar response patterns for all three subunit mRNAs including the decrease in LH beta after 48 h. A third experiment examined the effect of varying GnRH pulse amplitude (0.5-250 ng/pulse at 30-min intervals) over 12 h. alpha mRNA levels were increased by all GnRH doses greater than 5 ng with maximum responses after 250 ng pulses. LH and FSH beta mRNAs were both elevated by GnRH pulse doses of 0.5-25 ng (P less than 0.05 vs. saline controls). Maximal increases (2-fold) were seen after 5 ng pulses for LH beta and after 15-ng pulses for FSH beta mRNA. These results show that pulsatile GnRH increases FSH beta mRNA more rapidly than alpha or LH beta mRNAs in female rats. In addition, high amplitude GnRH pulses increase only alpha mRNA, whereas both LH beta and FSH beta mRNAs show maximum responses to lower doses. The data suggest that alterations in the amplitude of the GnRH pulsatile signal can exert differential effects on gonadotropin gene expression.     

Effects of recombinant human inhibin and testosterone on gonadotropin secretion and subunit mRNA in superfused male rat pituitary cell cultures stimulated with pulsatile gonadotropin-releasing hormone.

Effects of recombinant human inhibin (rh inhibin) and testosterone on follicle-stimulating hormone (FSH) and luteinizing hormone (LH) secretion and mRNA levels of gonadotropin subunits were investigated in superfused male rat pituitary cell cultures. During superfusion, the cells were stimulated with gonadotropin-releasing hormone (GnRH) pulses (10 nM, 6 min/h) and exposed to rh inhibin (2 ng/ml) and/or testosterone (10 nM) for up to 20 h. The concentrations of FSH and LH were measured in effluent media by radioimmunoassay (RIA), and subunit mRNAs were determined by Northern blot hybridizations using rat FSH beta, LH beta and alpha genomic and cDNA probes. Rh inhibin suppressed the secretion of FSH (30-40% of control) and the secretion of LH to 50-60% of control, but inhibited only FSH beta mRNA (to non-detectable levels). Testosterone alone suppressed the release of LH to 50% of control, whereas FSH release was increased to 130-160% (P less than 0.05) of control. This increase was due to higher interpulse values without significant changes in the pulse amplitude. Also FSH beta mRNA level was increased (1.5-fold, P less than 0.05) but only after 17-20 h of treatment. On the other hand, testosterone had no effect on LH beta and alpha subunit mRNA levels. Testosterone in combination with rh inhibin showed an inhibitory effect on LH beta mRNA; however, the pattern of LH release was not significantly different from that observed with rh inhibin or testosterone alone. Combined effects of testosterone and rh inhibin on FSH secretion and FSH beta mRNA were similar to those observed with rh inhibin alone.(ABSTRACT TRUNCATED AT 250 WORDS)     

Gonadal regulation of gonadotropin subunit gene expression: evidence for regulation of follicle-stimulating hormone-beta messenger ribonucleic acid by nonsteroidal hormones in female rats

Gonadectomy results in a rise in gonadotropin secretion and subunit gene expression, although the relative contributions of declining gonadal hormones or increasing hypothalamic GnRH secretion are uncertain. To further delineate the roles of the hypothalamus and gonads in regulation of gonadotropin gene expression, male and female rats were castrated and gonadotropin subunit messenger RNA (mRNA) concentrations measured 2, 7, 14, or 21 days (d) later. In males, FSH beta mRNA was maximal (2-fold increase) by 7 d while peak levels of alpha (3-fold) and LH beta (3-fold) were seen by 14 d. Testosterone (T) replacement restored all three subunit mRNA concentrations to intact values. In females, FSH beta mRNA also reached plateau levels (8-fold increase) earlier than alpha (3-fold) or LH beta (11-fold). When female rats ovariectomized 7 days earlier were given estradiol (E2) and progesterone (P) implants for up to 14 d, suppression of alpha and LH beta to intact levels was observed. However, FSH beta mRNA concentrations only decreased to 67% of castrate values, and remained 2- to 3-fold higher than levels in intact female rats. Female rats were also given E2 replacement at the time of ovariectomy. LH beta mRNA was maintained at intact levels for 14 days while alpha and FSH beta showed partial castration responses (2-fold and 3-fold, respectively). Finally, to determine whether E2 and P regulate gonadotropin subunit expression directly or by reducing GnRH secretion, female rats were ovariectomized and immediately replaced with E2, P, or E2 + P in the presence or absence of a GnRH antagonist (A) for 2 d. alpha mRNA was increased (2-fold) by E2 but not by E2 + A suggesting that E2 requires the presence of GnRH to increase alpha mRNA. P alone was ineffective, but both E2 and A prevented the LH beta mRNA response to ovariectomy. The effects of E2 and A were not additive, suggesting that E suppresses LH beta mRNA by inhibiting the increase in GnRH secretion. In contrast, the FSH beta mRNA response to ovariectomy was only partially suppressed by E2, E2 + P, or E2 + P + A. These data indicate that in castrate males, replacement of T suppresses all three subunit mRNAs to intact levels. However, replacement of E2 to ovariectomized females did not prevent the increase in alpha and FSH beta mRNAs. In female rats, LH beta mRNA is predominantly regulated by GnRH. alpha mRNA expression is also mainly regulated by GnRH, and E2 appears to augment GnRH action on alpha mRNA expression.(ABSTRACT TRUNCATED AT 400 WORDS)     

Follicle-stimulating hormone beta subunit messenger ribonucleic acid concentrations during the rat estrous cycle

Serum follicle-stimulating hormone (FSH), pituitary FSH content and FSH beta subunit mRNA concentrations were measured at 1 to 3h intervals throughout the 4 day estrous cycle in rats. Serum FSH was stable (range 200-320 ng/ml) apart from the biphasic proestrus surge (5 fold elevation) which was present from 1800 h of proestrus through 0800 h on estrus. Basal FSH beta mRNA concentrations from late metestrus through the afternoon of proestrus were 0.10 +/- 0.04 f mol cDNA bound/100 micrograms pituitary DNA. The major increase in FSH beta mRNA began at 2000 h on proestrus, 2 h after the initial rise in serum FSH and peak mRNA concentrations (0.43 +/- 0.08 f mol cDNA bound) occurred at 0200 h on estrus. FSH beta subunit mRNA concentrations were again increased at 2300 h on estrus (peak 0.24 f mol cDNA bound) and remained elevated through 1700 h on metestrus. Pituitary FSH content was transiently increased during metestrus and diestrus, but was elevated at 1000 h through 1900 h on proestrus (peak 5-fold increase). FSH content fell rapidly at 2000 h and remained low until 1400 h on estrus when values again rose. These data show that FSH beta mRNA is increased 4-5 fold during the proestrus FSH surge, and a smaller increase occurs on metestrus in the absence of elevated FSH secretion. The increased concentrations of FSH beta mRNA occurred at different times to the previously reported changes in alpha and LH beta mRNAs. Therefore, the data suggest that different mechanisms are involved in the regulation of LH and FSH beta subunit gene expression during the 4-day estrous cycle in rats.     

Follicle-stimulating hormone beta subunit messenger ribonucleic acid concentrations during the rat estrous cycle

Serum follicle-stimulating hormone (FSH), pituitary FSH content and FSH beta subunit mRNA concentrations were measured at 1 to 3h intervals throughout the 4 day estrous cycle in rats. Serum FSH was stable (range 200-320 ng/ml) apart from the biphasic proestrus surge (5 fold elevation) which was present from 1800h of proestrus through 0800 h on estrus. Basal FSH beta mRNA concentrations from late metestrus through the afternoon of proestrus were 0.10 +/- 0.04 f mol cDNA bound/100 micrograms pituitary DNA. The major increase in FSH beta mRNA began at 2000 h on proestrus, 2 h after the initial rise in serum FSH and peak mRNA concentrations (0.43 +/- 0.08 f mol cDNA bound) occurred at 0200 h on estrus. FSH beta subunit mRNA concentrations were again increased at 2300 h on estrus (peak 0.24 f mol cDNA bound) and remained elevated through 1700 h on metestrus. Pituitary FSH content was transiently increased during metestrus and diestrus, but was elevated at 1000 h through 1900 h on proestrus (peak 5-fold increase). FSH content fell rapidly at 2000h and remained low until 1400 h on estrus when values again rose. These data show that FSH beta mRNA is increased 4-5 fold during the proestrus FSH surge, and a smaller increase occurs on metestrus in the absence of elevated FSH secretion. The increased concentrations of FSH beta mRNA occurred at different times to the previously reported changes in alpha and LH beta mRNAs. Therefore, the data suggest that different mechanisms are involved in the regulation of LH and FSH beta subunit gene expression during the 4-day estrous cycle in rats.     

Effect of recombinant activin-A on gonadotropin secretion in the female rat

Repeated injections of recombinant human (rh) activin-A over a 2- to 3-day period are reportedly needed to stimulate the in vivo secretion of FSH. In this paper we present results showing that acute treatment with rh-activin-A caused marked and dose-dependent increases in plasma FSH, but not LH, levels in adult female rats. After one injection, maximum FSH release was observed 4 h after the administration of activin, while two injections of 100 micrograms activin/kg, 5 h apart, maintained elevated FSH levels for more than 10 h in intact diestrous day 1 females. Removal of the GnRH drive by pretreatment of ovariectomized animals with the GnRH antagonist ([Ac-D2Nal1,DCpa2,D3Pal3,Arg5,D-p-methoxyphenyl) 5- oxo-2-amino-pentanoic acid6, DAla10]GnRH; 100 micrograms/kg;) or repeated injections of the GnRH agonist ([DTrp6,Pro9,NEt,NH2]GnRH; 1 microgram/h for 5 days) did not prevent the stimulatory action of activin. Concomitant treatment with rh-inhibin-A (30 micrograms/kg], on the other hand, completely blocked FSH secretion induced by 100 micrograms activin/kg. These results indicate that activin-A is a powerful stimulus for FSH secretion in the female rat and exerts this effect independently of GnRH.     

The effect of altered thyroid status on pituitary hormone messenger ribonucleic acid concentrations in the rat

To study the effects of altered thyroid status on pretranslational control of pituitary hormones, adult male rats were given propylthiouracil for 6 weeks and underwent the following studies. 1) Rats were injected with T3 at 10 micrograms/100 g BW daily for 10 days. 2) Rats were given T3 injections at 0, 0.01, 0.1, 1.0, or 10 micrograms/100 g BW for 10 days. 3) Rats were killed 0, 1, 6, or 24 h after a single injection of T3 at 10 micrograms/100 g BW or after 5 or 10 days of daily T3 injections. Pituitary mRNA concentrations of TSH beta, alpha-subunit, PRL, GH, POMC, FSH beta, and LH beta were determined for individual animals. Marked increases in TSH beta and alpha-subunit mRNAs occurred after PTU treatment, and these changes were reversed by 1.0 microgram/100 g BW T3 and within 24 h of a single T3 injection of 10 micrograms/100 g BW. Further increases in the dose or time course of T3 administration led to a relatively greater suppression of TSH beta mRNA levels than alpha-subunit mRNA levels. In contrast, GH and PRL mRNA levels were low in hypothyroid animals, and both rose toward control levels with 0.1 microgram/100 g BW T3 and by 24 h after a single T3 dose. Induction of hyperthyroidism did not further increase GH mRNA levels above control, but increased PRL mRNA levels 2-fold over control. No changes were seen in FSH beta, LH beta, or POMC mRNA levels with any treatment. Thus, studies of altered thyroid status in the rat reveal dose-response and time-course variability in the pretranslational control of TSH beta, alpha-subunit, GH, and PRL by thyroid hormone.     

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.     

The role of luteinizing hormone in regulation of testicular inhibin alpha and beta-B subunit messenger RNAs in immature and adult animals

In vivo and in vitro evidence indicates that FSH is a primary regulator of testicular inhibin production. However, recent reports suggest that LH may also promote inhibin secretion in vivo. To investigate whether LH regulates inhibin subunit messenger RNA (mRNA) expression as well, we examined the effects of hypophysectomy and LH replacement on the testicular content of inhibin alpha and beta-B subunit mRNAs in sexually immature and adult rats. Twenty- and 60-day-old intact and hypophysectomized rats received saline or 0.25, 2.5, 25.0, or 250 micrograms ovine LH/100 g body wt sc, twice daily for 7 days beginning on the day after hypophysectomy (n = 5/group in three separate experiments). The inhibin subunit mRNA content of each testis was measured for statistical analysis by dot-blot hybridization, and experimental results were confirmed by northern analysis of poly(A) RNA from each sample. In immature animals, the testicular content of both inhibin subunit mRNAs was decreased after hypophysectomy; inhibin alpha and beta-B mRNA levels were decreased to 6.9 +/- 0.9% and 31.7 +/- 2.7% of intact control values, respectively. In adult animals, hypophysectomy resulted in a more modest decrease in inhibin alpha subunit mRNA per testis (44.9 +/- 3.1% of controls) but had no effect on beta-B subunit mRNA. Replacement of LH to immature hypophysectomized animals did not alter levels of mRNA for either inhibin subunit. However, in adults LH restored testicular inhibin alpha subunit mRNA content in testes of hypophysectomized animals to levels seen in intact, saline-treated control animals. LH replacement also slightly but consistently decreased testicular beta-B subunit mRNA content compared to levels seen in hypophysectomized, saline-treated rats. These results indicate that although the response of inhibin subunit mRNAs to pituitary input decreases as a function of sexual maturation, LH may play an important role in regulation of inhibin subunit mRNA expression in adult but not immature testes. The mechanism(s) of LH action on testicular inhibin subunit gene expression is currently unknown, but may involve either direct actions of LH on Leydig cell inhibin subunit mRNAs or indirect actions of interstitial cell factors on Sertoli cell inhibin subunit gene expression.     

Prolactin modulates the gonadotropin response to the negative feedback effect of testosterone in immature male rats

The effects of hyperprolactinemia (hyperPRL) and hypoprolactinemia (hypoPRL) on pituitary gonadotropin secretion and the feedback sensitivity to testosterone (T) were evaluated in immature male rats. At 34 days of age, rats were divided into three groups: group 1, controls, injected with oil; group 2, treated with bromocriptine mesylate (CB-154; 250 micrograms in oil/rat X day); and group 3, subjected to the transplantation of one pituitary from an adult female rat under the kidney capsule and treated with oil. The treatments were continued for 14 days. On day 8, each of these groups were further divided into three subgroups: intact, castrated, and castrated plus T treated. T treatment consisted of injection of T propionate (TP; 50 micrograms in oil/rat) on alternate days starting immediately after castration. Blood samples were obtained by cardiac puncture throughout the study. Plasma PRL levels were significantly reduced by CB-154 treatment and significantly increased by the pituitary graft (P less than 0.001). In intact immature male rats, hyper- or hypoPRL did not affect plasma LH levels, whereas hyperPRL reduced (P less than 0.01) plasma FSH concentrations. The postcastration increase in circulating LH levels was significantly increased (P less than 0.001) in rats treated with CB-154 24 h after castration. Moreover, the suppressive effects of TP on plasma LH and FSH levels were significantly (P less than 0.05) attenuated in hypoPRL rats. In pituitary-grafted rats, effects of castration and TP replacement on plasma LH levels did not differ from those in control rats. These results demonstrate that subnormal levels of PRL reduce the sensitivity of the hypothalamic-pituitary system to feedback inhibition by T. In contrast to previous findings in the adult rats, acute hyperPRL in immature male rats did not affect the negative feedback action of T on gonadotropin secretion.     

Tamoxifen does not block the inhibitory effect of testosterone on FSH release in rats

The aim of the present experiments was to analyze whether the inhibitory effect exerted by testosterone on FSH release might be mediated by the intracerebral transformation of the hormone into oestrogenic metabolites. Advantage has been taken of the availability of the potent antioestrogen tamoxifen. Two series of experiments have been performed. In the first one, adult male rats have been castrated and submitted, beginning immediately after surgery, to a 6-day treatment with testosterone propionate (2 mg/rat/day), tamoxifen (50 or 200 micrograms/rat/day) or testosterone propionate (2 mg/rat/day) plus tamoxifen (either 50 or 200 micrograms/rat/day). In the second experiment, adult male rats have been castrated and submitted to the same 6-day treatments, beginning 4 weeks following orchidectomy. In both experiments, the animals were killed 24 h after the last injection, and serum levels of FSH and LH have been measured by radioimmunoassays. The results have clearly shown that, in both experiments, the administration of testosterone results in a significant decrease of serum FSH and in a total suppression of LH release. The administration of tamoxifen, in either dose, does not modify the elevated serum FSH and LH levels present in the orchidectomized animals, and does not antagonize the inhibitory effect on FSH and LH secretion exerted by the concomitant treatment with testosterone propionate. It is concluded that testosterone inhibits FSH secretion in orchidectomized rats acting as such, and not following aromatization to oestrogens.     

Estradiol negatively regulates secretogranin II and chromogranin A messenger ribonucleic acid levels in the female rat pituitary but not in the adrenal

Estradiol (E2) effects on the pituitary and adrenal secretogranin II (SgII) and chromogranin A (CgA) proteins and mRNA levels were analyzed in the adult female rat. Animals were ovariectomized or sham-operated for 2 weeks and then daily injected with various doses of 17 beta-E2 (from 5-100 micrograms) for the following week. SgII and CgA levels were determined by Western blot analysis using two specific antisera. Messenger RNA (mRNA) levels were measured by RNA slot blot analysis using specific cDNA probes. Simultaneously, pituitary LH content and gonadotropin subunit (LH beta, FSH beta, alpha) mRNAs were quantified. Ovariectomy promoted a significant increase in pituitary SgII and CgA proteins (2-fold vs. sham-operated animals, P less than 0.01) and a concomitant rise in their mRNA levels (2.5-fold and 4.5-fold for SgII mRNA and CgA mRNA, respectively, P less than 0.01). In the same animals LH beta, FSH beta, and alpha-subunit mRNA levels increased by 20-, 12-, and 6-fold, respectively. Estrogen replacement resulted in a parallel decrease of CgA and LH beta mRNA to the control values, starting from the lowest steroid dose (5 micrograms). The SgII mRNA decrease was initiated only with a higher concentration of E2 (10 micrograms), as was that of alpha-subunit mRNA; yet, the SgII mRNA level remained significantly higher than in the control pituitary, even with the highest steroid dose (P less than 0.05) at variance with the alpha-mRNA level. Concerning protein concentration, the postcastration increase in CgA was fully reverted with 10 micrograms E2 while that of SgII remained unaffected, as was the pituitary LH content. In the adrenal gland, neither the ovariectomy nor the E2 therapy altered significantly the SgII or CgA protein and mRNA concentrations. We conclude that, in rats, 1) ovarian factors regulate the pituitary SgII and CgA protein and mRNA steady-state levels while such factors are inefficient in the adrenal gland, 2) CgA and LH beta mRNAs exhibit the same sensitivity to E2 while SgII and alpha-subunit mRNAs appear less sensitive, and 3) SgII and LH pituitary contents present a similar pattern of variations when the estrogenic status of the animal is modified.     

Gamma-aminobutyric acidA receptors mediate 3 alpha-hydroxy-5 alpha-pregnan-20-one-induced gonadotropin secretion

3 alpha-Hydroxy-5 alpha-pregnan-20-one (3 alpha, 5 alpha-THP), can selectively release LH in estrogen-primed ovariectomized rats. This progesterone metabolite does not bind to the progesterone receptor. Recently, 3 alpha,5 alpha-THP has been reported to be a potent modulator of the gamma-aminobutyric acidA (GABAA) receptor in the brain. Therefore, the purpose of this study was to determine whether 3 alpha,5 alpha-THP's effect on gonadotropin secretion is GABAA receptor mediated. Ovariectomized immature rats were primed for 2 days with estradiol (2 micrograms/rat.day). On the morning of the third day, 3 alpha,5 alpha-THP was administered either with or without prior treatment with progesterone receptor antagonist (RU486) or the GABAA receptor antagonist picrotoxin. When 3 alpha,5 alpha-THP was administered alone, a dose-related effect on LH and FSH release was observed. The 0.8 mg/kg BW dose of 3 alpha,5 alpha-THP stimulated both LH and FSH release, whereas the 1.6 mg/kg BW dose released only LH. The GABAA receptor antagonist picrotoxin had no significant effect on LH or FSH secretion. However, administration of picrotoxin 30 min before 0.8 mg/kg BW 3 alpha,5 alpha-THP resulted in antagonism of 3 alpha,5 alpha-THP's ability to release LH and FSH. The effects of 1.6 mg/kg BW 3 alpha,5 alpha-THP on serum LH were also blocked by picrotoxin. Picrotoxin was ineffective in altering the gonadotropin-stimulating response of progesterone and deoxycorticosterone. These steroids do not bind to the GABAA receptor. The progesterone receptor antagonist RU486 administered alone had no effect on serum LH or FSH levels. When RU486 was administered before 3 alpha,5 alpha-THP treatment, it was ineffective in blocking 3 alpha,5 alpha-THP's ability to release LH. These studies indicate that the GABAA receptor is responsible for mediating 3 alpha,5 alpha-THP-induced gonadotropin secretion.     

Administration of a GnRH-antagonist to immature rats affects subsequent female and male pubertal development differently

Gonadotropin secretion was inhibited in immature male and female rats by sc administration of the GnRH-antagonist ORG30276 (GnRH-A) on days 6, 9, 12 and 15. In GnRH-A-treated females this resulted in suppression of the temporarily increased plasma LH and FSH levels, which normally occur in prepubertal female rats. Ovarian weight was decreased. Although vaginal opening in GnRH-A-treated rats occurred earlier, the age of 1st estrus and the number of ova shed at first ovulation were not affected. Fertility at 4 months of age was normal. After initial suppression of gonadotropin levels, the FSH levels in GnRH-A-treated males, however, sharply increased to about twice the control levels. Plasma FSH remained elevated at least until 4 months of age. The LH levels at adult age were not affected by antagonist treatment and neither were testosterone levels. Testicular weight was decreased by GnRH-A from about 50% on day 15 to about 30% at 4 months of age. Pubertal development as measured by balano-preputial separation was delayed by about 7-10 days. At 4 months of age fertility was decreased. Thus, suppression of early gonadotropin secretion by GnRH-A treatment had dramatic effects on subsequent pubertal development in the male, but not in the female rat.     

Comparison of the effects of cycloheximide and inhibin on the gonadotropin subunit messenger ribonucleic acids.

Cycloheximide (CHX) has been shown to mimic the action of inhibin on gonadotropin secretion by pituitary cell cultures. We showed previously that suppression of FSH secretion by inhibin is associated with a rapid and profound suppression of FSH beta mRNA levels. The present study was designed to examine the mechanism of action of CHX and to determine whether inhibin's actions involve new proteins synthesis. Pituitary cell cultures were treated with control medium or medium containing inhibin, CHX, or inhibin plus CHX for 2 or 6 h. At 6 h, secretion of FSH was decreased by inhibin (72% of control), CHX (58% of control), and the combined inhibitors (56% of control). LH secretion was not significantly changed, while that of free alpha-subunit was reduced only by CHX (68% of control). Levels of FSH beta, LH beta, and alpha-subunit mRNAs were measured by Northern analysis. At 2 h inhibin decreased FSH beta mRNA to 49% of the control value. CHX alone had no effect, while CHX plus inhibin produced intermediate levels (77% of control). By 6 h, however, inhibin and CHX each decreased FSH beta mRNA to very low levels (12% and 15% of control, respectively), and in cultures treated with both inhibin and CHX, this RNA was barely detectable. To determine the reversibility of the effects of these inhibitors, cells were incubated with fresh control medium after 6 h. Secretion of FSH and free alpha-subunit remained suppressed 4 h later; recovery was complete by 16 h in inhibin treated cultures. FSH beta mRNA returned to control levels by 4 h in inhibin-treated and by 16 h in CHX-treated cultures. Levels of LH beta and alpha-subunit mRNA were comparable to control values at all times. In conclusion, 1) CHX, like inhibin, suppresses FSH beta mRNA levels, although its actions are less rapid and less rapidly reversible; 2) inhibin requires ongoing protein synthesis for full expression of its inhibitory effects; 3) the synthesis and secretion of LH are much less sensitive to inhibition by either inhibin or CHX than are the synthesis and secretion of FSH; and 4) secretion of free alpha-subunit involves a labile protein(s).     

Involvement of inhibin in the regulation of follicle-stimulating hormone concentrations in prepubertal and adult, male and female rats

Administration of steroid-free bovine follicular fluid (bFF), containing inhibin-like activity, depressed levels of FSH measured 4 h after injection in intact adult and 35-day-old female rats, but not in younger females. Suppression of FSH was also observed in intact male rats, aged 55 days, but not in older and younger male rats. Eight hours after injection of bFF, FSH levels were depressed in 15-day-old and older immature and adult rats of both sexes. Male and female rats, gonadectomized 2 days earlier, responded similarly to bFF treatment as did the intact animals. In a second experiment it was found that the rise of FSH levels, occurring within 8 h of gonadectomy, decreased with age in male and increased with age in female rats. Steroid treatment was found to prevent the rise in FSH levels partially in 15-day-old male and completely 25-day-old female rats, whereas treatment with bFF was fully effective in blocking the FSH rise in both immature and adult rats of both sexes. It is concluded that inhibin might be a major physiological factor in a fast-acting control of FSH concentrations from at least the age of 25 days onwards in female rats. In male rats its physiological significance might be limited to the prepubertal period, despite the fact that pituitary secretion of FSH is suppressed by exogenous inhibin-like activity at all ages studied.