Neuroendocrine control of gonadotropin secretion

Luteinizing hormone releasing hormone (LHRH), a hypothalmic peptide that is concentrated in granules of neurons, has the capacity to release gonadotropins (luteinizing hormone (LH) and follicle stimulating hormone) from the pituitary gland. LHRH has been found in hypophysial portal blood of rats, monkeys, and rabbits. Antibodies to LHRH depress plasma LH concentrations in castrated animals and evoke testicular atrophy, but passive immunization against LHRH does not block the LH surge induced by estrogen in monkeys. Estrogens, progestin, prolactin, and dopamine have marked effects on LH secretion, yet an association between these effects and altered hypophysial portal blood concentrations of LHRH is not established. In view of the paucity of evidence demonstrating such a cause and effect relationship, two alternative proposals have become tenable. One, hormones and neurotransmitters may not alter the levels of portal blood LHRH, but rather alter the frequency of pulsatile LHRH secretion. Two, hormones, such as estrogens, progesterone, and prolactin, may alter the responsiveness of the gonadotropin-secreting cells to LHRH by affecting the secretion of dopamine.     

Hypothalamic alterations and reproductive aging in female rats: evidence of altered luteinizing hormone-releasing hormone neuronal function

Prior to the age-related loss of regular estrous cycles, female rats exhibit an attenuated preovulatory LH surge, a sign that reproductive decline is imminent. Numerous studies have revealed an important role for the hypothalamus in aging of the reproductive axis in this species. Because LHRH represents the primary hypothalamic signal that regulates gonadotropin release, assessments of LHRH neuronal activity can provide a window into hypothalamic function during reproductive aging. Studies of the dynamic activity of LHRH neurons during times of enhanced secretion have revealed deficits in middle-aged females. Available data are consistent with a decline in LHRH synthesis, transport, and secretion in middle-aged females during times of increased demand for LHRH output. Moreover, the alterations noted in LHRH neuronal function could account, in part, for the attenuation and eventual loss of the preovulatory LH surge with age. Elements extrinsic to LHRH neurons undoubtedly contribute to the decline in the parameters of LHRH neuronal function observed in middle-aged females. Whether alterations intrinsic to LHRH neurons also play a role in the age-associated reduction in LHRH synthesis and secretion remains to be determined. Recent examinations of hormone profiles during the perimenopausal period suggest that a potential hypothalamic contribution to aging of the reproductive axis in women warrants further examination.     

Further evidence that prolactin does not affect gonadotropin release at pituitary level

In a primary monolayer cell culture of the anterior pituitary from mature male rats the effects of exogenous rPrl (rPrl exog.) and endogenously secreted rPrl (rPrl endog.) on basal and LHRH stimulated LH secretion were investigated. In pilot studies basal Prl- and LH secretion as well as influence of various LHRH concentrations (10(-1)-10(+3) ng/ml) on Prl- and LH release were observed. The influence of exogenous rPrl was studied at various concentrations (50-500 ng/ml) and with preincubation periods of 2 hrs and 6 hrs before starting LHRH stimulation. The dopamine agonist bromocriptine and the dopamine antagonist sulpirid were preferentially used to prove physiologic function of the cell system presented. Basal LH secretion started after a delay of 3 hrs, whereas basal Prl secretion began immediately showing a linear rise for 9 hrs. LHRH stimulation resulted in a non-linear dose and time dependent LH secretion. LHRH showed no influence on endogenous Prl (rPrl endog.) secretion of the mammotroph cells. Exogenous Prl (rPrl exog.) did not affect spontaneous Prl release excluding ultra short loop inhibition in this cell system. Furthermore, exogenous Prl had no effect on either basal or LHRH stimulated LH secretion even after a preincubation period of up to 6 hrs and at concentrations generally observed for prolactin secreting tumors. Bromocriptine suppressed endogenous Prl release and did not affect LH secretion. Sulpirid had no influence on either Prl or LH secretion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of central epinephrine in regulation of anterior pituitary hormone secretion

Hypothalamic regulation of anterior pituitary hormones is thought to be mediated by the release of stimulatory and/or inhibitory peptides that are, in turn, regulated by catecholaminergic neurons. The recent development of selective epinephrine (EPI) synthesis inhibitors has made it possible to disrupt central EPI neurotransmission without affecting norepinephrine or dopamine. These compounds were used in the present investigation to assess the involvement of brain EPI systems in regulation of GH, LH, and prolactin (PRL) in male and ovariectomized female rats. Inhibition of central EPI synthesis (1) inhibited episodic and morphine-, but not clonidine-induced GH release, and (2) blocked the LH surge induced by estrogen and progesterone, but did not affect episodic LH release in hormonally untreated rats. Inhibition of peripheral (adrenal) EPI synthesis had no effect on these hormones. Results of these studies suggest an excitatory role for EPI in regulation of GH and LH secretion, mediated by stimulation of GH-releasing hormone and LHRH, respectively. EPI does not appear to have a major function in regulation of PRL secretion.     

Changes in circulating levels of immunoreactive follicle stimulating hormone, luteinizing hormone, and testosterone during sexual development in the rhesus monkey, Macaca mulatta

Basal serum levels of follicle stimulating hormone (FSH), luteinizing hormone (LH), and testosterone (T) and the responsiveness of these hormones to a challenge dose of luteinizing hormone releasing hormone (LHRH), were determined in juvenile, pubertal, and adult rhesus monkeys. The monkey gonadotrophins were analyzed using RIA reagents supplied by the World Health Organization (WHO) Special Programme of Human Reproduction. The FSH levels which were near the assay sensitivity in immature monkeys (2.4 +/- 0.8 ng/ml) showed a discernible increase in pubertal animals (6.4 +/- 1.8 ng/ml). Compared to other two age groups, the serum FSH concentration was markedly higher (16.1 +/- 1.8 ng/ml) in adults. Serum LH levels were below the detectable limits of the assay in juvenile monkeys but rose to 16.2 +/- 3.1 ng/ml in pubertal animals. When compared to pubertal animals, a two-fold increase in LH levels paralleled changes in serum LH during the three developmental stages. Response of serum gonadotrophins and T levels to a challenge dose of LHRH (2.5 micrograms; i.v.) was variable in the different age groups. The present data suggest: an asynchronous rise of FSH and LH during the pubertal period and a temporal correlation between the testicular size and FSH concentrations; the challenge dose of LHRH, which induces a significant rise in serum LH and T levels, fails to elicit an FSH response in all the three age groups; and the pubertal as compared to adult monkeys release significantly larger quantities of LH in response to exogenous LHRH.     

Direct hypophysial inhibition of luteinizing hormone release by dopamine in the rabbit.

The role and site of action of dopamine in regulating gonadotropin secretion remain unclear. In the present study, we investigated the possibility that dopamine regulates LH secretion by acting directly on the pituitary gland of the rabbit. The effect of dopamine infusion on LHRH-evoked LH release was determined in intact and pituitary stalk sectioned animals. Intravenous injection of LHRH (1 μg) in intact and acutely stalk sectioned rabbits increased peripheral plasma LH levels from a resting value of 0.2 ng/ml to maximal values of 12–14 ng/ml within 10–20 min. When dopamine was infused iv at a dose of 6.6 μg/min/kg BW from 30 min before LHRH injection until 120 min after, the rise in plasma LH levels in intact and stalk sectioned animals was decreased by 50–70%. However, dopamine infused at a lower dose (0.66 μg/min/kg BW) or at a higher dose (66.0 μg/min/kg BW), did not affect the LHRH-induced secretion of LH. These results suggest that dopamine can exert a direct hypophysial inhibitory effect on release of LH. They also demonstrate that dopamine is inhibitory only within a restricted dose-range, extending to the pituitary an established property of dopamine in the cardiovascular system.     

Leptin acts centrally to induce the prepubertal secretion of luteinizing hormone in the female rat

Recent data generated from adult male and female rats indicates that leptin is capable of stimulating luteinizing hormone (LH) secretion via a hypothalamic action. Consequently, we hypothesized that this peptide may similarly play a role in controlling LH secretion during late juvenile and peripubertal development; hence, contributing to hypothalamic-pituitary function during sexual maturation. Therefore, this study was conducted to determine if leptin is capable of stimulating LH release during this critical time of development and, if so, to determine whether this action is due to an effect at the hypothalamic level. Results showed that leptin, when administered directly into the brain third ventricle (3V), can stimulate (P < 0. 01) LH release in late juvenile animals at doses of 0.01-1.0 microg. A higher dose of 10 microg was ineffective in stimulating LH release. Immunoneutralization of luteinizing hormone-releasing hormone (LHRH) via 3V administration of LHRH antiserum to late juvenile animals indicated a hypothalamic site of action, since the leptin-induced LH release was blocked in the animals that received anti-LHRH, but not in the control animals that received normal rabbit serum. Leptin did not significantly stimulate LH release from animals in first proestrus, estrus, or diestrus. We also report that the serum levels of leptin increase (P < 0.05) during the late juvenile period of development, then decrease (P < 0.05) once the animal enters the peripubertal period. Collectively, our results show that leptin is capable of acting centrally to stimulate LH release, but only during late juvenile development; thus, we suggest the peptide likely plays a facilitatory role on late juvenile LH secretion, but does not drive the LHRH/LH releasing system to first ovulation and hence, sexual maturity.     

Isolated hypothalami from aging female rats do not exhibit reduced basal or potassium-stimulated secretion of luteinizing hormone-releasing hormone.

Serum LH levels are diminished in middle-aged rats during spontaneous or steroid-induced LH surges and following ovariectomy (ovx). The compromised LH responses are presumed to reflect age-related alterations in LHRH neurosecretion. Direct measurements of LHRH output in middle-aged females are, however, limited. The present study utilizes an in vitro perifusion paradigm to assess basal and stimulated secretory capacity of LHRH neurons in isolated hypothalamic preparations from aging female rats. Individual hypothalamic fragments from middle-aged and young proestrous, ovx, and ovx, estradiol-treated females were perifused for 6 h and effluents were collected continuously at 10-min intervals. After 4 h of unstimulated output, two 10-min depolarizing pulses of KCl were administered. Although stimulated LHRH secretion was comparable in the two age groups, basal LHRH release from aging hypothalami was significantly elevated (pbasal less than 0.001). Furthermore, endocrine influences on LHRH output from aging hypothalami were less pronounced when compared to endocrine influences on LHRH output from young hypothalami, suggesting that steroidal regulation of LHRH secretion may be impaired in middle-aged females. These data demonstrate that LHRH neurons maintain the capacity to respond to a depolarizing stimulus at the time when regular estrous cycles cease and consequently suggest the importance of altered modulation of LHRH neurosecretion to the development of reproductive senescence.     

Changes in the dynamics of luteinizing hormone-releasing hormone-stimulated secretion of luteinizing hormone during sexual maturation of female rats

Our aim was to identify age-related changes in the dynamics of luteinizing hormone (LH) release that may contribute to the decline in pituitary sensitivity to luteinizing hormone-releasing hormone (LHRH) during sexual maturation of female rats. We studied LHRH-stimulated LH secretion curves of superfused pituitaries from rats ranging in age from 10 days to the first estrous cycle. Pituitary fragments were exposed for 10 min to medium alone or to medium plus LHRH; incubation continued in medium alone for 130 min and effluent was collected for LH analysis. Secretion curves were compared on the basis of total secretion (area under the curve), maximal change in LH secretion rate, and rates of rise and decay of the curves. The data show that total LH secretion in response to LHRH is greatest in 15-, 20-day-old and first-proestrus animals. Also, the maximal change in LH secretion rate was greater, and the increase in LH secretion rate faster in younger animals than in 30-day-old animals. Analysis of secretory granules in LH-containing gonadotropes of 15- and 30-day-old animals revealed changes in he granule population with age. We conclude that younger animals respond faster with a greater LH secretion response to LHRH than do 30-day-old or first-estrus animals, and that these age-related changes in the dynamics of LH secretion may be due in part to maturation of the LH secretory granules.     

Effect of [D-Trp6]LHRH infusion on prolactin secretion by perifused rat pituitary cells

The effect of a superactive agonistic analog of luteinizing hormone-releasing hormone (LHRH), [D-Trp6]LHRH on prolactin (PRL) secretion by perifused rat pituitary cells was investigated. Constant infusion of [D-Trp6]LHRH (0.5 ng/min) for 2-3 h elicited a significant decrease in PRL secretion by these cells. This decrease in PRL release started ca. 30 min after the beginning of the infusion with the LHRH analog and lasted up to 1.5-2 h. [D-Trp6]LHRH significantly stimulated luteinizing hormone (LH) secretion during the first 30 min of peptide infusion; thereafter, LH levels began to return to control values. In animals pretreated in vivo with 50 micrograms of [D-Trp6]LHRH (s.c.) 1 h before sacrifice, PRL secretion by the rat pituitary cell perifusion system was significantly lower than vehicle-injected controls throughout the entire [D-Trp6]LHRH infusion period. On the other hand, thyrotropin-releasing hormone (TRH)-stimulated PRL secretion was slightly, but significantly imparied by [D-Trp6]LHRH infusion, while dopamine (DA) inhibition of PRL release was unaffected by this same treatment. These results reinforce previous observations of a modulatory effect of [D-Trp6]LHRH, probably mediated by pituitary gonadotrophs, on PRL secretion by the anterior pituitary. In addition, our findings suggest that basal PRL secretion by the lactotroph may be dependent on a normal function of the gonadotroph. The collected data from this and previous reports support the existence of a functional link between gonadotrophs and lactotrophs in the rat pituitary gland.     

Seasonal changes in thyroid-gonadal interactions in the edible dormouse,Glis glis

Summary This study was conducted to determine changes in thyroid-gonadal interaction in the edible dormouse during the phase of the annual cycle that corresponds to the end of the breeding season (from June to September). We evaluated intra-hypothalamic luteinizing hormone-releasing hormone (LHRH) content, and plasma concentrations of luteinizing hormone (LH), testosterone, thyroid-stimulating hormone (TSH) and thyroxine (T4) in three groups of dormice: (1) controls; (2) dormice receiving sufficient T4 supplementation to maintain June levels in control animals until September, thus counteracting the seasonal reduction of T4 that normally begins in July; and (3) thyroidectomized dormice. The effect of thyroidectomy was only detectable in June, when plasma T4 concentration in the control group was maximal, and consisted of a significant decrease in plasma testosterone levels. This provides strong support for the hypothesis that thyroid function positively influences gonadal function during the breeding season. The T4 supplementation resulted in a decrease in hypothalamic LHRH concentration, suggesting that an increased LHRH release led to the observed stimulated hypophyseal secretion of LH in June and September and the increased circulating testosterone levels in September. There was no detectable effect in July and August. These results show that thyroid axis activation of the hypothalamic-pituitary-gonadal system is only possible during certain phases of the annual cycle, particularly evidenced here during the breeding season. They also reinforce our conclusions drawn from the thyroidectomy results. Conversely, the summer testicular regression which normally occurs after the breeding season is no longer controlled by plasma T4 levels. Even though the sensitivity of the gonadal axis to the thyroid axis appears to reappear at the end of the summer, results of previous studies indicate that this resumption is only temporary.Abbreviations LH luteinizing hormone - LHRH luteinizing hormone-releasing hormone - RIA radioimmunoassay - T4 thyroxine - TSH thyroid-stimulating hormone     

Studies on a possible pituitary effect of monoamines on luteinizing hormone release in ovariectomized rats

Incubation of anterior pituitaries from ovariectomized rats with LHRH and various concentrations of dopamine, norepinephrine or serotonin indicated that none of these neurotransmitters could decrease pituitary LH secretion in response to the releasing hormone. This indicated that the inhibitions of pulsatile LH release previously observed in our laboratory in ovariectomized rats in response to intraventricularly administered catecholamines or stimulation of brain serotoninergic neurons are due to central rather than pituitary effects of these transmitters.     

Release of LHRH in vitro and anterior pituitary responsiveness to LHRH in vivo during sexual maturation in pullets (Gallus domesticus)

An in-vitro superfusion technique was used to study basal and depolarization-induced (32 mmol K+/l) release of LHRH from the mediobasal hypothalamus (MBH) of pullets at 8-25 weeks of age. Plasma LH concentrations and the incremental change (delta LH) after an i.v. injection of 1 or 15 micrograms synthetic ovine LHRH/kg body weight were also determined. Between 8 and 25 weeks of age, significant (P less than 0.01) increases in basal and depolarization-induced release of LHRH (93 and 330%, respectively) were accompanied by a significant (P less than 0.01) rise in the residual LHRH content of MBH tissue (152%), observations which suggest that the ability of the hypothalamus to synthesize and secrete LHRH increases as sexual maturation proceeds. However, plasma LH, which reached a maximum concentration of 2.05 +/- 0.43 micrograms/l at 15 weeks, fell significantly (P less than 0.05) to 1.14 +/- 0.05 micrograms/l at 25 weeks. Since delta LH in response to exogenous LHRH showed a marked and progressive decline between 12 and 20 weeks of age, the low plasma concentration of LH typical of the mature hen is probably attributable to a direct negative-feedback action of ovarian steroids on the anterior pituitary gland rather than to an impaired secretion of LHRH from the median eminence. It is suggested that a dramatic increase in the responsiveness of LHRH nerve terminals in the MBH to depolarization by 32 mmol K+/l between 20 and 25 weeks of age (mean age at onset of lay 21.9 weeks; range 19-25 weeks) may reflect the development of hypothalamic responsiveness to the positive feedback action of progesterone.     

Chromatographic and biologic analysis of ME and OVLT LHRH

The luteinizing hormone (LH)-releasing activities a pooled rat organum vasculosum lamina terminalis (OVLT) and median eminence (ME) tissues were evaluated for chromatographic and biologic similarity and compared to those of synthetic decapeptide LH-releasing hormone (LHRH). The LHRH detected in these extracts appeared similar chromatographically (Sephadex G-25) to synthetic LHRH. These extracts, as well as synthetic LHRH, were also capable of stimulating dose dependent gonadotropin release form cultures rat gonadotrophs. These findings suggest a physiological role of the LHRH present in the rat OVLT in the control of gonadotropin secretion.     

Melanin-concentrating hormone stimulates the release of luteinizing hormone-releasing hormone and gonadotropins in the female rat acting at both median eminence and pituitary levels

The purpose of this study was to investigate whether melanin-concentrating hormone (MCH) acts directly on the median eminence and on the anterior pituitary of female rats regulating LHRH and gonadotropin release. In addition, immunohistochemistry was used to examine the density and distribution of MCH-immunoreactive fibers in the median eminence of proestrous rats. MCH-immunoreactive fibers were found in both the internal and external layers of the median eminence and in close association with hypophysial portal vessels. In the first series of in vitro experiments, median eminences and anterior pituitaries were incubated in Krebs-Ringer bicarbonate buffer containing two MCH concentrations (10(-10) and 10(-8) M). The lowest MCH concentration (10(-10) M) increased (P < 0.01) LHRH release only from proestrous median eminences. Anterior pituitaries incubated with both MCH concentrations also showed that 10(-10) M MCH increased gonadotropin release only from proestrous pituitaries. In the second series of experiments, median eminences and pituitaries from proestrous rats were incubated with graded concentrations of MCH. MCH (10(-10) and 10(-9) M) increased (P < 0.01) LHRH release from the median eminence, and only 10(-10) M MCH increased (P < 0.01) LH and FSH release from the anterior pituitary. The effect of MCH on the stimulation of both gonadotropins from proestrous pituitaries was similar to the effect produced by LHRH. Simultaneous incubation of pituitaries with MCH and LHRH did not modify LH but increased the FSH release induced by LHRH. The present results suggest that MCH could be involved in the regulation of preovulatory gonadotropin secretion.     

Effects of aging on pituitary and testicular luteinizing hormone-releasing hormone receptors in the rat

Aging exerts profound influences on the function of the hypothalamic-pituitary-testicular-axis. This work has been performed in order to verify whether, in male rats, the decreased secretion of LH and testosterone (T) occurring in old animals is reflected by modifications of luteinizing hormone-releasing hormone (LHRH) receptors at the level of the anterior pituitary and of the testes. To this purpose, the affinity constant (Ka) and the maximal binding capacity (Bmax) for the LHRH analog [D-Ser(tBu)6]des-Gly10-LHRH-N-ethylamide were evaluated, by means of a receptor binding assay, in membrane preparations derived from the anterior pituitary and testicular Leydig cells of male rats of 3 and 19 months of age. Serum levels of LH and T were measured by specific RIAs. The results obtained show that, in aged male rats, the concentration of pituitary LHRH receptors is significantly lower than that found in young animals. On the other hand, the concentration of LHRH binding sites is significantly increased on the membranes of Leydig cells of old rats. In no instance the Ka for the LHRH analog is significantly affected. Serum levels of LH and T are significantly lower in old than in young male rats. In conclusion, these results suggest that the reduced secretion of LH in old male rats may be linked, at least partially, to a decrease of the number of pituitary LHRH receptors. The impaired production of testosterone occurring in aged rats is accompanied by a significant increase of the number of testicular LHRH receptors, indicating that also the intratesticular mechanisms controlling testosterone release undergo significant alterations with aging.     

Release of luteinizing hormone in prepubertal and middle-aged ovariectomized rats

Concentrations of circulating LH were determined in conscious, free-moving ovariectomized rats. All of the animals had been ovariectomized at 24 days of age. Between 30 and 90 days there was an increase in mean blood LH concentrations; a more vigorous pulsatile release of LH characterized by an increase in amplitude and frequency of LH release; and an elevated responsiveness to LHRH administration. Rats which had been ovariectomized for 1 year still had elevated blood LH levels but had episodic pulses of reduced amplitude and a decrease in responsiveness to LHRH. These data suggest that important alterations occur with age in the neuroendocrine mechanisms responsible for the release of LH.     

Immortalized hypothalamic luteinizing hormone-releasing hormone (LHRH) neurons: A new tool for dissecting the molecular and cellular basis of LHRH physiology

Summary 1. Two LHRH neuronal cell lines were developed by targeted tumorigenesis of LHRH neuronsin vivo. These cell lines (GN and GT-1 cells) represent a homogeneous population of neurons. GT-1 cells have been further subcloned to produce the GT1-1, GT1-3, and GT1-7 cell lines. While considerable information is accumulating about GT-1 cells, very little is currently known about the characteristics and responses of GN cells.2. By both morphological and biochemical criteria, GT-1 cells are clearly neurons. All GT-1 cells immunostain for LHRH and the levels of prohormone, peptide intermediates, and LHRH in the cells and medium are relatively high.3. GT-1 cells biosynthesize, process, and secrete LHRH. Processing of pro-LHRH appears to be very similar to that reported for LHRH neuronsin vivo. At least four enzymes may be involved in processing the prohormone to LHRH.4. LHRH neurons are unique among the neurons of the central nervous system because they arise from the olfactory placode and grow back into the preoptic-anterior hypothalamic region of the brain. Once these neurons reach this location, they send their axons to the median eminence. With respect to the immortalized neurons, GN cells were arrested during their transit to the brain. In contrast, GT-1 cells were able to migrate to the preoptic-anterior hypothalamic region but were unable correctly to target their axons to the median eminence. These problems in migration and targeting appear to be due to expression of the simian virus T-antigen.5. While GT-1 cells are a homogeneous population of neurons, they are amenable to coculture with other types of cells. Coculture experiments currently under way should help not only to reveal some of the molecular and cellular cues that are important for neuronal migration and axonal targeting, but they should also highlight the nature of the cellular interactions which normally occurin situ.6. GT-1 cells spontaneously secrete LHRH in a pusatile manner. The interpulse interval for LHRH from these cells is almost identical to that reported for release of LH and LHRHin vivo. GT-1 cells are interconnected by both gap junctions and synapses. The coordination and synchronization of secretion from these cells could occur through these interconnections, by feedback from LHRH itself, and/or by several different compounds that are secreted by these cells. One such compound is nitric oxide.7. GT-1 cells have Na⁺, K⁺, Ca²⁺, and Cl^– channels. Polymerase chain reaction experiments coupled with Southern blotting and electrophysiological recordings reveal that GT-1 cells contain at least five types of Ca²⁺ channels. R-type Ca²⁺ channels appear to be the most common type of channel and this channel is activated by phorbol esters in the GT-1 cells.8. LHRH is secreted from GT-1 cells in response to norepinephrine, dopamine, histamine, GABA (GABA-A agonists), glutamate, nitric oxide, neuropeptide Y, endothelin, prostaglandin E₂, and activin A. Phorbol esters are very potent stimulators of LHRH secretion. Inhibition of LHRH release occurs in response to LHRH, GABA (GABA-B agonists), prolactin, and glucocorticoids.9. Compared to secretion studies, far fewer agents have been tested for their effects on gene expression. All of the agents which have been tested so far have been found either to repress LHRH gene expression or to have no effect. The agents which have been reported to repress LHRH steady-state mRNA levels include LHRH, prolactin, glucocorticoids, nitric oxide, and phorbol esters. While forskolin stimulates LHRH secretion, it does not appear to have any effect on LHRH mRNA levels.     

Effects of short photoperiod on the ability of golden hamster pituitaries to secrete prolactin and gonadotropins in vitro

Transfer of male golden (Syrian) hamsters from a 14L:10D (light:dark) to a 5L:19D photoperiod induced significant changes in pituitary function tested in vitro. Within 27 days after transfer to a 5L:19D photoperiod, basal prolactin (Prl) release was significantly depressed and response to dopamine (DA) was significantly enhanced as compared to Prl release by pituitaries from 14L: 10D hamsters. Follicle-stimulating hormone (FSH) release tended to be depressed after 9 or 27 days of 5L:19D exposure, but the effect was not significant. After 77 days of 5L:19D exposure, Prl release was further suppressed, while FSH release surpassed that seen in 14L:10D pituitaries. In vitro FSH response to luteinizing hormone releasing hormone (LHRH) was also enhanced at this time. After 15 weeks of exposure to a short photoperiod, FSH secretion was still elevated above control levels, but Prl release and Prl response to DA were no longer different from that of 14L: 10D controls. Secretion of luteinizing hormone (LH) in vitro, either basal or LHRH stimulated, was not affected by photoperiod at any time tested. From these results, we conclude that short photoperiod exposure does not reduce the pituitary's ability to secrete LH or FSH, although secretion of Prl is severely attenuated.