Thyrotropin-releasing hormone rapidly stimulates a biphasic secretion of prolactin and growth hormone in GH4C1 rat pituitary tumor cells

The characteristics of TRH-induced acute PRL and GH secretion were studied in GH4C1 cells, a clonal rat anterior pituitary tumor cell line which secretes PRL and GH. The experiments were carried out both in a flow system in which microcarrier (Cytodex)-attached cells were perifused at a constant rate and in a conventional static culture system. In both systems, cells responded to TRH in a qualitatively similar manner. TRH significantly stimulated PRL and GH secretion within 5 sec without a detectable lag period. The secretion rate was highest during the initial 1 min, declined sharply thereafter despite the continuous presence of TRH, and plateaued at a lower level. The maximum dose of TRH caused 250-700% of basal secretion during the early period (approximately 8 min; first phase) and about 150% of basal secretion thereafter (second phase). The sustained lower secretion (second phase) was maintained as long as cells were exposed to TRH (up to 2.5 h), and the secretion rate returned to the basal level within 30 min of removal of TRH from the medium. The half-maximal doses for the first and second phase secretion were 2-3 and 0.5-1 nM, respectively, in both the perifusion and static culture systems. Over a 2-day period, TRH stimulated PRL synthesis and inhibited GH synthesis. The dose-response curves for these long term effects on hormone synthesis were similar to the dose-response curves for the first phase of release. [N3-methyl-His2]TRH gave similar results, but was more potent than TRH. [N3-methyl-His2]TRH stimulated first phase release with an ED50 of 0.4-0.8 nM, second phase release with an ED50 of 0.1-0.2 nM, and hormone synthesis with an ED50 of 0.7-0.8 nM. Preincubation of the cells with Ca+2-free medium significantly depressed both first and second phase secretion. Preexposure of the cells to cycloheximide (10 micrograms/ml) had little effect on the first phase of secretion, but reduced second phase secretion. The acute effects of TRH on GH and PRL were identical, except that the secretory response tended to be greater for PRL. We conclude that 1) TRH causes hormone secretion very rapidly in a biphasic manner; 2) the first phase of secretion consists primarily of the release of stored hormone, whereas the second phase includes the release of newly synthesized hormone; 3) the dose-response curve of second phase secretion is shifted to the left compared with that of first phase secretion; and 4) both phases of secretion are at least partially dependent on extracellular Ca+2.     

Induction of hypothyroidism and hypoprolactinemia by growth hormone producing rat pituitary tumors.

The GH3 rat pituitary tumor cell line which secretes both growth hormone (GH) and prolactin (PRL) stopped releasing PRL when transplanted to animals; furthermore, it suppressed PRL production by the hosts' pituitary glands. When the same tumor was transferred back to cell culture, PRL production resumed. The PRL to GH ratio in cell culture medium and cells ranged from 5 to 1 while in the tumor and serum of the host animals it averaged 0.09 and 0.001, respectively. To investigate further this phenomenon, female rats were transplanted with GH3 tumors (T) and compared to intact normal (N) and to thyroidectomized (Tx) rats. T animals were larger and had splanchnomegaly but smaller pituitaries and thyroids. Serum PRL concentrations in the basal state were decreased, as were levels of triiodothyronine (T3), thyroxine (T4), and free T4 index. Despite reduced serum thyroid hormone concentrations, and in contrast to Tx animals, the serum thyrotropin (TSH) level in T rats was not elevated and they did not show a supranormal TSH response to thyrotropin-releasing hormone (TRH) administration. The PRL response to TRH in T animals was completely abolished while all N and Tx animals responded by a significant increase in serum PRL. Serum corticosteroids and estrogens were normal in T rats. Pituitary content of PRL was decreased and that of TSH increased in T rats. Tx animals, however, had a reduced pituitary content of PRL, TSH, and GH. When GH3 cells were grown in cell culture media containing serum from T animals, there was a reduction of PRL content in cells and released in the medium. Addition of T3 to the T serum did not alter its suppressive effect on PRL nor did rat GH added to N serum alter PRL production and release in vitro. In a preliminary experiment, rats injected ip with 50 mug hGH in two divided doses for eighteen days, suppressed serum T4 and T3 concentrations; pituitary content of TSH was significantly increased and that of PRL slightly decreased. Injection with 250 mug oPRL or saline, on the same schedule and for the same length of time, had no significant effect on the levels of serum thyroid hormones. Thus, GH, but also possibly other substance(s) secreted by GH3 tumors in vivo a) suppress the production of tumor and pituitary PRL; b) suppress the release of TSH, causing mild hypothyroidism; c) inhibit the PRL and TSH responses to TRH; and d) decrease the production of PRL in tissue culture. Although no simple and unifying theory could explain these findings, an hypothesis implicating somatomedin is presented.     

Differential effects of thyrotropin-releasing hormone, vasoactive intestinal peptide, phorbol ester, and depolarization in GH4C1 rat pituitary cells

The sequence of PRL and GH release from GH4C1 cells was studied in perifusion and static culture systems. The secretory pattern elicited by TRH differed from those caused by depolarizing concentrations of KCl (Ca2+-initiated secretion), vasoactive intestinal peptide (VIP), 8-bromo-cAMP, and forskolin (cAMP-mediated secretion), and 12-O-tetradecanoylphorbol-13-acetate (TPA) (protein kinase C activation). TRH, K+, VIP, and TPA all caused secretion within 1 min in the perifusion system but the peak response to TRH and depolarization occurred earlier than the peak responses to TPA and VIP. PRL and GH release in response to a pulsatile application of TRH (0.4-min pulse every 5 min for 25 min) did not decline with a low dose, indicating that acute desensitization does not occur, but did decrease with a high concentration. When cells in the perifusion system were subjected to continuous stimulation, TRH caused a biphasic response with a 2- to 3-min period of high secretion followed by a second phase in which GH and PRL secretion were 60-70% the rates in the first phase. KCl caused predominantly first-phase secretion, and TPA caused a biphasic secretory pattern with a delay in its peak of action. VIP caused a modest but prolonged response whether administered in a pulsatile or sustained manner. When GH-cells were exposed to 100 nM TRH for 2 days, [3H] [N3-methyl-His2]TRH binding was decreased (down-regulation), intracellular PRL was increased (170% of control), and intracellular GH was decreased (65% of control). In these down-regulated cells, baseline PRL and GH secretion were changed in proportion to the relative intracellular hormone content. The responsiveness to TRH, KCl, and TPA during the initial 10-min period (first phase) was reduced; however, the responsiveness to these substances in the subsequent 50-min period (second phase) was unchanged. The ED50 for TRH stimulation of hormone release was increased 2- to 4-fold in down-regulated cells, but the dose-response curves for other secretagogues were not shifted. These data suggest that the initial burst of hormone release caused by TRH is mediated by Ca2+, and that prolonged exposure to TRH causes homologous desensitization.     

Human pituitary null cell adenomas and oncocytomas in vitro: effects of adenohypophysiotropic hormones and gonadal steroids on hormone secretion and tumor cell morphology.

Human pituitary null cell adenomas and oncocytomas are not associated with evidence of excess hormone secretion in vivo; their cellular derivation has not been clarified by morphologic investigation. In this study we examined 41 null cell adenomas and 58 oncocytomas in vitro to determine hormone release and its response to several adenohypophysiotropic hormones and gonadal steroids. In vitro, 96/99 tumors released LH, FSH, and/or alpha-subunit of glycoprotein hormones. TSH was released by 11 tumors. GH, PRL, and ACTH were found in small quantities in 11, 8, and 5 tumors, respectively. Only 3 tumors released no detectable hormones. Incubations with test substances were examined at 2- and 24-h periods for up to 72 h. All but 3 of 53 tumors showed marked and persistent increases in the release of LH, FSH, and/or alpha-subunit in response to GnRH in short and long duration experiments. Secretion of LH, FSH, or alpha-subunit was stimulated to more than 150% of control by TRH in 37/48 tumors, by CRH in 10/20, by GRH in 7/20. Estradiol, progesterone, and testosterone increased release of FSH, LH, and/or alpha-subunit in 23/32, 3/12, and 3/12 tumors, respectively, and reduced their release in 6/32, 5/12, and 7/12, respectively. In tumors which showed no response to gonadal steroids, GnRH in combination with estradiol, progesterone, or testosterone yielded the same result as GnRH alone; in tumors inhibited by gonadal steroids, GnRH in combination with one of those substances reduced the response to GnRH. No secretion of GH, PRL, ACTH, or TSH was detected after incubation with GRH, estradiol, CRH, or TRH except in the tumors which initially released GH, PRL, or TSH. Ultrastructural examination of cultured cells from 15 cases revealed morphologic alterations that correlated with changes in hormone release and could be quantified by morphometry. This study represents the largest analysis of hormone production and release in vitro and morphologic correlation of clinically nonfunctioning pituitary adenomas. The responsiveness of gonadotropin secretion by null cell adenomas and oncocytomas to GnRH and gonadal steroids resembles that of gonadotroph adenomas. However, the unexpected increases in gonadotropin release attributable to several other adenohypophysiotropic hormones and the release of multiple hormones suggests that null cell adenomas and oncocytomas may represent neoplasms derived from uncommitted or committed precursor cells that can undergo differentiation towards several cell lines.     

GLYCOPROTEIN HORMONE ALPHA-SUBUNIT AND PROLACTIN RELEASE BY CULTURED PITUITARY ADENOMA CELLS FROM ACROMEGALIC PATIENTS: CORRELATION WITH GH RELEASE

In-vitro data of pituitary adenoma cells from 28 acromegalic patients were evaluated. In addition to GH, PRL was produced by 16 adenomas (57%) and alpha-subunit by 15 adenomas (54%) while there was a significantly higher incidence of tumours producing PRL and alpha-subunit simultaneously. From 26 pituitary adenomas enough cells were obtained in order to perform secretion studies. Percentage basal hormone release (medium: (medium + intracellular hormone)) x 100% of GH and alpha-subunit by 11 adenomas showed a close correlation while such a correlation for GH and PRL was present only in a subgroup of 10 of 13 adenomas. The responses of GH and alpha-subunit release to 10nM SMS201-995, 10nM bromocriptine, 100 nM TRH and 10nM GHRH were closely related in that a response or an absent response of GH release to the four secretagogues was virtually always attended with a response or an absent response respectively of alpha-subunit release. Such a relationship was less evident with respect to the effects of SMS201-995, bromocriptine. TRH and GHRH on GH and PRL release. We conclude that basal and secretagogue-induced alpha-subunit release by cultured pituitary adenoma cells from acromegalic patients closely follows the pattern of GH release while such a relationship for GH and PRL is present only in a subgroup of the adenomas secreting GH and PRL simultaneously.     

Thyrotropin-releasing hormone stimulates growth hormone release from the anterior pituitary of hypothyroid rats in vitro

We have examined the interaction of thyroid hormone and TRH on GH release from rat pituitary monolayer cultures and perifused rat pituitary fragments. TRH (10(-9) and 10(-8)M) consistently stimulated the release of TSH and PRL, but not GH, in pituitary cell cultures of euthyroid male rats. Basal and TRH-stimulated TSH secretion were significantly increased in cells from thyroidectomized rats cultured in medium supplemented with hypothyroid serum, and a dose-related stimulation of GH release by 10(-9)-10(-8) M TRH was observed. The minimum duration of hypothyroidism required to demonstrate the onset of this GH stimulatory effect of TRH was 4 weeks, a period significantly longer than that required to cause intracellular GH depletion, decreased basal secretion of GH, elevated serum TSH, or increased basal secretion of TSH by cultured cells. In vivo T4 replacement of hypothyroid rats (20 micrograms/kg, ip, daily for 4 days) restored serum TSH, intracellular GH, and basal secretion of GH and TSH to normal levels, but suppressed only slightly the stimulatory effect of TRH on GH release. The GH response to TRH was maintained for up to 10 days of T4 replacement. In vitro addition of T3 (10(-6) M) during the 4-day primary culture period significantly stimulated basal GH release, but did not affect the GH response to TRH. A GH stimulatory effect of TRH was also demonstrated in cultured adenohypophyseal cells from rats rendered hypothyroid by oral administration of methimazole for 6 weeks. TRH stimulated GH secretion in perifused [3H]leucine-prelabeled anterior pituitary fragments from euthyroid rats. A 15-min pulse of 10(-8) M TRH stimulated the release of both immunoprecipitable [3H]rat GH and [3H]rat PRL. The GH release response was markedly enhanced in pituitary fragments from hypothyroid rats, and this enhanced response was significantly suppressed by T4 replacement for 4 days. The PRL response to TRH was enhanced to a lesser extent by thyroidectomy and was not affected by T4 replacement. These data suggest the existence of TRH receptors on somatotrophs which are suppressed by normal amounts of thyroid hormones and may provide an explanation for the TRH-stimulated GH secretion observed clinically in primary hypothyroidism.     

In vitro effects of thyrotropin-releasing hormone and somatostatin on prolactin and growth hormone release by the pituitary of Poecilia latipinna. I. An electrophoretic study

Pituitary glands were removed from Poecilia latipinna which had been maintained in one-third seawater and were incubated for 18 hr in media of either 300 mosmol/kg (OP300) or 340 mosmol/kg (OP340) osmotic pressure for measurement of both total and newly synthesised prolactin (PRL) and growth hormone (GH) release. Thyrotropin-releasing hormone (TRH) at 100 ng/ml increased release of total and newly synthesised PRL into OP340, but not into OP300, medium. Conversely, 300 ng/ml of somatotropin-release-inhibiting factor (SRIF) inhibited total and newly synthesised PRL release into OP300, but not OP340, medium. At 1000 ng/ml, SRIF inhibited total PRL release into both media, but newly synthesised PRL release was reduced significantly only in OP300 medium. The release of GH was unaffected by 100 ng/ml TRH in OP300 medium, but both total and newly synthesised GH release were enhanced by this dose in OP340 medium. SRIF at 300 ng/ml reduced total GH release into OP300 medium, whereas the release of newly synthesised GH was inhibited in OP340 medium. At 1000 ng/ml, SRIF inhibited total GH release into both media, but release of the newly synthesised hormone was not significantly altered. These results suggest that TRH can stimulate and SRIF inhibit both PRL and GH release by Poecilia pituitaries, but that these effects may be modulated by plasma osmotic pressure.     

Selectivity of melatonin pituitary inhibition for luteinizing hormone-releasing hormone

The pineal indole melatonin suppresses the neonatal rat luteinizing hormone (LH) and follicle-stimulating hormone (FSH) responses to LH-releasing hormone (LHRH), as shown in previous studies from this laboratory. We show in this study that the melatonin inhibition is a selective effect and is not due to general inhibition of pituitary function. The effects of the indole on the responses to thyrotropin-releasing hormone (TRH) and somatostatin (SRIF) and on basal pituitary hormone secretion were examined with cells in culture. Neonatal rat anterior pituitary cells dissociated with collagenase and hyaluronidase were cultured overnight and distributed to 35-mm dishes at the time of use. For examination of melatonin effects on the response to releasing hormones, the cells were incubated for 3 h in control medium or medium containing LHRH (10-9-10-6 M), TRH (10-10-10-6 M), or SRIF (10-9-10-6 M), either alone or in the presence of melatonin (10-8 or 10-6 M). For examination of basal hormone secretion, the cells were incubated for 1.5, 3, 6, 15, or 24 h in either medium alone or medium containing melatonin (10-6 M). Medium and cell lysate concentrations of LH, FSH, thyroid-stimulating hormone (TSh), prolactin (PRL) and growth hormone (GH) were determined by double antibody RIA. As previously, melatonin (10-8 M) significantly suppressed LH and FSH release by all concentrations of LHRH. This concentration of the indole produced maximal suppression of both LH and FSH responses to LHRH. By contrast, melatonin at a 100-fold greater concentration (10-6 M) had no effect on TRH stimulation of TSH or PRL release or on SRIF inhibition of GH release. Similarly, melatonin had no effect on basal release of TSH, PRL, or GH at the times examined. These findings show that melatonin inhibition of the gonadotroph response to LHRH is a selective effect.     

Cultures of GH3 cells contain both single and dual hormone secretors

Analysis of GH3 cultures by fixed sequential plaque assays revealed the presence of cells that release GH only, as well as those that release both GH and PRL (mammosomatotropes). Chronic treatment of these cultures with 17 beta-estradiol and TRH (factors found to alter the amounts of GH and PRL secreted) caused shifts in the overall proportions of GH to PRL secreting cells. Each agent, however, influenced the cultures differently. Estradiol treatment resulted in cultures which contained only mammosomatotropes, whereas TRH treatment resulted in cultures that contained PRL-only cells in addition to the other two functional cell types present in control populations. These results indicate that factors which alter the amounts of GH and PRL secreted by GH3 cultures also change the types of secretors present. Moreover, the manner in which the proportions of dual hormone secretors changed in response to these factors supports the view that multipotential cells serve as a transitional cell type in a conversion from GH to PRL secretors.     

Cultures of GH3 cells are functionally heterogeneous: thyrotropin-releasing hormone, estradiol and cortisol cause reciprocal shifts in the proportions of growth hormone and prolactin secretors

Utilization of reverse hemolytic plaque assays revealed that cultures of GH3 cells are not functionally homogeneous, but contain approximately twice as many GH as PRL secretors. Chronic treatment of these cultures with TRH, estradiol, or cortisol (factors that induce reciprocal alterations in the amount of GH and PRL released by entire cultures of GH3 cells) caused reciprocal shifts in the proportions of GH and PRL cells, without influencing the combined percentages of hormone-secreting cell types present. These results indicate that alterations in hormone release caused by these modulatory factors may in part be due to changes in the ratios of cells committed to the secretion of each hormone. Moreover, the reciprocal nature of these shifts suggests that an interconversion of one cell type to another may have occurred.     

Normal and adenomatous human pituitaries secrete thyrotropin-releasing hormone in vitro: modulation by dopamine, haloperidol, and somatostatin

TRH is present in human normal pituitaries and in pituitary adenomas. In this study we demonstrated that the same tissues can release TRH in vitro. Fragments from seven normal pituitaries (10-15 mg/syringe) and dispersed cells from eight prolactinomas, four GH-secreting and two nonsecreting adenomas (1-3 x 10(6) cells/syringe) were perifused using a Krebs-Ringer culture medium. After 1 h of equilibration the perifusion medium was collected every 2 min (1 mL/fraction) for 3 h. TRH, PRL, and GH were measured by RIA under basal conditions and in the presence of 10(-10) to 10(-6) mol/L dopamine (DA), alone or concomitant with haloperidol, or in the presence of 10(-10) or 10(-6) mol/L somatostatin. Both normal pituitary fragments and pituitary adenomatous cells (from all types of adenomas studied) spontaneously released TRH in vitro. TRH was detected in the perifusion medium either immediately after the end of the equilibration period or 30-60 min later. The molecular identity of TRH was assessed by high pressure liquid chromatography. There was no difference in the profile and the rate of TRH secretion between normal and tumoral tissues, and no correlation was found between the level of TRH release and that of PRL or GH secretion. DA stimulated TRH release from normal pituitaries and from PRL- and GH-secreting adenomas at doses as low as 10(-10) mol/L. A concomitant decrease in PRL and GH release was observed from adenomatous cells and in one case of normal tissue. Haloperidol (10(-7) mol/L) antagonized the effect of 10(-8) mol/L DA on both TRH and PRL secretion in normal pituitary and in prolactinomas. DA had no effect on TRH release from two nonsecreting tumors. The amounts of TRH released during 1 h of perifusion were 60-1640 pg/2 mg wet wt tissue in normal pituitaries and 54-2174 pg/10(6) cells in adenomas; these values were very high compared to those precedently reported within the tissues. These results indicate that pituitary cells can release TRH in vitro and suggest that TRH might be synthesized in situ. We suggest that TRH could act on pituitary hormone secretion and/or cell proliferation via a paracrine and/or an autocrine mechanism.     

Regulation of thyroid hormone receptors and responses by thyrotropin-releasing hormone in GH4C1 cells

The present study was undertaken to test the effects of TRH on thyroid hormone receptors and responses in GH4C1 rat pituitary tumor cells. TRH caused a loss of up to 32% of specific nuclear thyroid hormone binding sites with an ED50 of approximately 1 nM, and this loss was additive to the receptor down-regulation caused by T3 itself. Scatchard analysis of nuclear T3 binding revealed that 10 nM TRH decreased the concentration of T3 receptors from Bmax (femtomoles per mg protein) of 110 to 50 while receptor affinity in serum-free medium changed from dissociation constant (Kd) 110 to 50 pM with TRH. TRH lowered the GH response to 0.5 nM T3 from 215% to 127% of control. The concentrations of TRH required to decrease T3 receptors and T3 responses were similar and indicated that these TRH effects are mediated by the TRH receptor. In the absence of added thyroid hormone TRH had little effect on the rate of GH synthesis. TRH did not affect the binding of 0.5 nM [125I]T3 to receptors during the first 8 h but reduced T3 receptor occupancy up to 25-50% in different experiments after 24 h. TRH blocked the induction of GH by T3 only after 48 h or longer. When cells were incubated for 2 weeks with or without 2 nM T3 and 10 nM TRH, the stimulation of cell growth by T3 was decreased by TRH (2- vs. 5-fold increase in cell number) as was stimulation of GH by T3 (5- vs. 13-fold). As expected, T3 blunted the PRL response to TRH from 19- to 3-fold. The effects of TRH on the density of thyroid hormone receptors could be mimicked by the calcium channel agonist BAY K8644 plus a protein kinase C-activating phorbol ester which together caused a 53% reduction in thyroid hormone binding. The dose-response and temporal relationships suggest a causal relationship between the TRH-mediated decrease in thyroid hormone receptors and the decrease in thyroid hormone responses in GH4C1 cells. It has previously been shown that thyroid hormones decrease the concentration of TRH receptors and TRH responsivity in pituitary cells. The results shown here for GH4C1 cells suggest that TRH regulation of T3 responses may also be important in feedback control at the pituitary level.     

Mechanism of thyroid hormone inhibition of thyrotropin-releasing hormone action

The addition of thyroid hormone to cultures of GH3 or GH4C1 pituitary tumor cells maintained in medium with hypothyroid serum decreased the concentration of specific receptors for TRH. The relationship between thyroid hormone effects on TRH receptors and TRH responses was examined by testing the concentration dependence, time course, and specificity of these changes. The concentrations of T3 giving half-maximal decreases in [3H]TRH binding and inhibition of the PRL response to TRH were 0.20 and 0.24 nM, respectively. TRH stimulated the rate of [3H]uridine uptake by 50% in cultures incubated without added T3 but did not increase [3H]uridine uptake in cells incubated with thyroid hormone. The PRL response to TRH was substantially inhibited 12 h after the addition of T3, and the uridine uptake response was completely blocked in 8 h. Two other stimuli of PRL secretion, sodium butyrate and isobutylmethylxanthine, were effective in the presence or absence of T3. Thyroid hormone did not reduce the specific binding of either [125I-Tyr1]somatostatin or [125I]iodoepidermal growth factor. Somatostatin decreased the secretion of GH and PRL by pituitary tumor cells grown with or without T3. The data show that the effects of thyroid hormones on TRH receptors are specific and suggest that regulation of receptor concentrations may be the direct cause of thyroid hormone regulation of pituitary responsiveness to TRH.     

Hormone secretion in vitro by plurihormonal pituitary adenomas of the acidophil cell line.

Pituitary tumors producing GH and PRL are morphologically classified as monomorphous bihormonal acidophil stem cell adenomas (ASCAs) which cause hyperprolactinemia and two tumor types which are usually associated with acromegaly, the monomorphous plurihormonal mammosomatotroph adenomas (MSAs) and bimorphous mixed somatotroph-lactotroph adenomas. We studied 12 MSAs, 2 ASCAs, and 10 mixed adenomas in vitro to assess the secretory behavior of these tumors diagnosed by immunohistochemistry and electron microscopy. GH release by MSAs and all but one mixed tumor was greater than that of PRL; the opposite was true of the ASCAs. One mixed tumor which caused impotence and hyperprolactinemia contained predominantly lactotrophs and released greater amounts of PRL than of GH in vitro. All 12 MSAs and 6 of 10 mixed tumors released alpha-subunit of glycoprotein hormones. Incubation with GHRH increased release of GH and PRL by all tumors and of alpha-subunit when present; the responses of all hormones were parallel among MSAs whereas among mixed adenomas, GH and alpha-subunit had greater responses than PRL. TRH stimulated GH, PRL, and alpha-subunit release by MSAs in parallel; among mixed adenomas, PRL response was generally greater than that of GH or alpha-subunit. SRIH markedly reduced GH release by all MSAs; it inhibited GH and alpha-subunit release by mixed tumors more than it affected PRL. Bromocriptine inhibited GH, PRL, and alpha-subunit release by most MSAs and mixed tumors but did not inhibit GH or PRL release by ASCAs. This study demonstrates release of GH, PRL, and alpha-subunit by these morphologically classified plurihormonal tumors in vitro. Variable quantities of GH and PRL released by the different tumor types correlate with immunohistochemical and clinical data. The dynamic studies indicate that regulation of GH, PRL, and alpha-subunit release can be affected by GHRH, TRH, SRIH, and bromocriptine in these adenomas and suggest differences in receptor status. Our data strengthen the view that these three plurihormonal adenomas of the acidophil cell line are not only morphologically but also functionally different and warrant separation.     

Functional variations among prolactin cells from different pituitary regions

Reverse hemolytic plaque assays were used to compare the responsiveness of cells from different pituitary regions to the modulatory effects of human pancreatic GH-releasing factor (GRF), TRH, and dopamine (DA). Tissues from the peripheral rim (outer zone) and the central region (inner zone) of adenohypophyses from day 10 lactating rats were dispersed with trypsin, and the cells were placed into culture. On the following day, these cells were subjected to GH plaque assays (conducted in the presence or absence of GRF) and PRL plaque assays (performed with or without TRH and DA). Cells from both zones responded similarly to GRF with a rapid acceleration of GH plaque formation. However, the rate of PRL plaque formation in response to TRH and DA differed between cells from these regions. For outer zone cells, plaque development increased greatly with TRH treatment, but was only moderately affected by DA. Plaque formation from inner zone cells was influenced slightly by TRH, but markedly inhibited by DA. These results suggest that PRL, but not GH, cells from these pituitary regions are differentially responsive to at least two hypothalamic secretagogues. We then performed fixed sequential plaque assays to determine whether the proportions of cells that released PRL only (classical mammotropes) or those that released both GH and PRL (mammosomatotropes) also differed between the inner and outer zones. Using this approach, we found that the outer zone contained a much larger proportion of dual hormone secretors than did the inner zone. These results, when taken together with the responsiveness differences discussed above, raise the possibility that the release of PRL from mammotropes and mammosomatotropes is regulated differently and that the ratio of these two cell types may dictate, in part, the manner in which a specific region of the pituitary responds to hypothalamic input.     

Disparate release of prolactin and growth hormone from the tilapia pituitary in response to osmotic stimulation

In most teleost fishes, prolactin (PRL) plays a key role in freshwater (FW) adaptation, whereas growth hormone (GH) is involved in seawater (SW) adaptation in salmonids and certain euryhaline species including the tilapia, Oreochromis mossambicus. Consistent with its osmoregulatory activity, PRL release increases in response to physiologically relevant reductions in extracellular osmolality. When dispersed PRL and GH cells from FW-acclimatized fish were incubated in media of varying osmolalities, PRL release increased significantly in response to a 12% reduction in medium osmolality during 1 and 4h of exposure. By contrast, cells from SW-acclimatized fish responded only to a 24% reduction in osmolality. Growth hormone release on the other hand increased whether medium osmolality was reduced or raised. Cell volume increased together with PRL release during the perifusion of dispersed PRL cells in direct proportion to the reduction in medium osmolality. Growth hormone release increased whether GH cell volume increased or decreased. In in vivo studies, circulating PRL levels increased as early as 1h after the transfer of fish from SW to FW, whereas GH levels remained unchanged during 24h of acclimatization. These results indicate that while PRL and GH cells are osmosensitive, the PRL cells respond to reductions in extracellular osmolality in a manner that is consistent with PRL's physiological role in the tilapia. While the rise in GH release following the reduction in osmolality is of uncertain physiological significance, the rise in GH release with the elevation of medium osmolality may be connected to its role in SW adaptation.     

PERSISTENT TRH-INDUCED GROWTH HORMONE RELEASE AFTER SHORT-TERM AND LONG-TERM L-THYROXINE REPLACEMENT THERAPY IN PRIMARY CONGENITAL HYPOTHYROIDISM

No appreciable changes in plasma GH levels after TRH stimulation have been observed in normal subjects, whereas acute GH release has been reported in primary hypothyroidism and other pathophysiological states. To evaluate the effect of the T4 replacement therapy on TRH-induced GH release, 28 patient volunteers with primary congenital hypothyroidism (PCH), were studied before (11 subjects), after 1 month (nine subjects) and after long-term T4 replacement therapy (eight subjects). All patients underwent a TRH test with measurement of TSH, PRL and GH levels, and were compared to 28 age-matched normal subjects. An increase of plasma GH after TRH was found in 46% of patients without any therapy, in 67% of patients after one month of T4 administration and in 75% of patients after long-term therapy. No changes were observed in plasma GH levels in controls. The TSH response to TRH was inhibited and the response of PRL was reduced step by step by T4 replacement therapy in our patients with PCH. Our results suggest that: (i) Replacement T4 therapy in PCH does not abolish the paradoxical GH response to TRH, in spite of inhibiting the TSH response and reducing the exaggerated PRL response; (ii) the GH response to TRH in PCH seems to be unrelated to low thyroid hormone levels and/or to high TSH levels, but it could be due to changes in hypothalamic-pituitary regulation which are not improved by T4 replacement therapy.     

Pituitary vasoactive intestinal peptide regulates prolactin secretion in the hypothyroid rat

In this study, we demonstrated that the cell content and basal secretion of vasoactive intestinal peptide (VIP) in primary rat pituitary cell cultures were increased in hypothyroidism. VIP release from hypothyroid pituitary cells in vitro was stimulated by thyrotropin releasing hormone (TRH 10(-8) to 10(-6) M) and growth hormone (GH)-releasing hormone (GHRH 10(-9) to 10(-8) M) but not by corticotropin-releasing hormone or luteinizing hormone-releasing hormone in concentrations up to 10(-6) M. In the presence of anti-VIP antisera, there was a significant decrease in basal prolactin secretion from cultured hypothyroid pituitary cells (p less than 0.005) indicating that VIP exerts a tonic stimulatory effect on prolactin (PRL) secretion. The increment in PRL secretion following TRH was not affected by exposure to anti-VIP indicating that PRL release after TRH is not mediated by VIP at the pituitary level. In contrast to changes in PRL, exposure to anti-VIP had no effect on basal GH secretion, indicating that the PRL changes are hormone specific. Similarly, GHRH-induced GH release was unaffected by VIP immunoneutralization.     

Effects of thyrotropin-releasing hormone on prolactin compartments in normal rat pituitary cells in primary culture

PRL compartments have been studied in normal rat pituitary cells cultured for 6 days. The cells were pulse-labeled for 15 min with 35S-methionine and then chased for 24 h in the absence or presence of cycloheximide (3.6 X 10(-5) M). TRH (30 nM) was introduced into the medium either at the beginning or after increasing durations of chase. The findings were compared with those obtained with GH3B6 cells in similar experimental conditions. Despite the fact that normal PRL cells differ from GH3B6 cells by a large intracellular PRL store, several similarities were found between the two systems: newly synthesized PRL was rapidly and preferentially released in basal conditions, the pattern of the decay of the specific radioactivity of PRL released into the medium suggested the existence of at least two PRL pools with different half-lives: 2.5 h and 22 h, respectively, TRH induced the preferential release of stored PRL synthesized before the pulse, only 20% of the pulse-labeled PRL was released into the medium after 24 h of chase. However, normal PRL cells differed in several respects from GH3B6 cells: the turnover time of the two PRL pools is 8 times greater in normal PRL cells, an asynchrony in the time of appearance of labeled PRL in the medium was observed, suggesting a functional heterogeneity of these cells, at the end of the chase, 40% of the pulse-labeled PRL was lost in the case of normal cells, but not of GH3B6 cells, and this was prevented by cycloheximide, polyacrylamide gel electrophoresis analysis of this labeled immunoprecipitated intracellular material revealed the existence, in addition to the mol wt of 23,000 PRL and the large PRL-like forms (mol wt, 45,000 and 50,000), as observed with GH3B6 cells, of smaller proteins (mol wts, 39,000, 36,000, 20,000, 18,000, 15,000), which might represent degradation products.     

Effects of thyrotropin-releasing hormone on prolactin compartments in clonal rat pituitary tumor cells

PRL compartments were studied in a clonal strain of rat pituitary tumor cells (GH3B6). The cells were pulse-labeled for 10 min with 35S-methionine and then chased for 20 h in the absence or presence of TRH (30 nM) or cycloheximide (3.6 X 10(-5) M), or both. The specific radioactivity (SA) of PRL was followed in the cells and chase medium as a function of chase time and treatments. The transit of labeled and unlabeled PRL has been investigated in cells treated with monensin (1 microM), a drug which is known to perturb the Golgi zone. Newly synthesized PRL was rapidly (15 min of chase) and preferentially released in basal conditions. The pattern of the decay of the SA of PRL released in the medium suggested the existence of at least two PRL pools with different half-lives: 15 min and 3 h, respectively. TRH induced the preferential release of a PRL pool synthesized before the labeling pulse. Monensin decreased the basal release of total radioimmunoassayable PRL without affecting that of the newly synthesized PRL. In contrast, it did not affect the stimulating effect of TRH on the release of unlabeled PRL. These results are in favor of the existence of different intracellular routes for the basal release of PRL (mostly newly synthesized) and the TRH-stimulated release of PRL (mostly stored). Moreover, after 20 h of chase a large fraction (approximately 80%) of the labeled immunoprecipitated material remained intracellularly located and not degraded. This material was not mobilizable by TRH even in the presence of cycloheximide. Polyacrylamide gel electrophoresis analysis revealed that it consisted of large immunoreactive proteins (mol wt, 45,000 and 50,000) instead of mol wt 23,000 PRL which was found in the medium.