Thyrotropin (TSH)-releasing hormone regulation of TSH subunit biosynthesis and glycosylation in normal and hypothyroid rat pituitaries

The regulation of TSH apoprotein and carbohydrate biosynthesis by TRH was studied by incubating pituitaries from normal and hypothyroid (3 weeks postthyroidectomy) rats in medium containing varying doses of TRH, [14C] alanine or [35S]methionine, and [3H]glucosamine. Samples were sequentially treated with anti-TSH beta to precipitate TSH and free TSH beta, anti-LH beta to remove LH and free LH beta, and anti-LH alpha to precipitate free alpha-subunits. Total proteins were acid precipitated. All precipitates were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. In hypothyroid samples, acute TRH (6 h) stimulated [3H] glucosamine incorporation into secreted combined alpha-subunit to 204% and secreted combined beta-subunit to 227% of control values (P less than 0.01), and stimulated [14C]alanine incorporation into secreted combined alpha-subunit to 201% and secreted combined beta-subunit to 258% of control values (P less than 0.01); pituitary content was not altered by TRH. In hypothyroid incubates, the half-maximal response was 8 X 10(-10) M TRH for both labeled precursors. In contrast, in normal samples, acute TRH (6 H) did not stimulate TSH subunit carbohydrate and apoprotein synthesis, but after 24 h, TRH stimulated [3H]glucosamine incorporation into both subunits of TSH to 270% of control values (P less than 0.02), with no change in [14C]alanine incorporation. Free alpha-subunit synthesis was not altered by TRH in normal or hypothyroid incubates. The glucosamine to alanine ratio of total newly synthesized TSH, reflecting its relative glycosylation, was increased by TRH in both combined subunits in hypothyroid samples as early as 6 h (P less than 0.05) and in normal samples only at 24 h (P less than 0.01). In summary, 1) TRH in hypothyroid incubates stimulated apoprotein and carbohydrate synthesis in combined alpha- and beta-subunits, but not free alpha-subunits, at 6 and 24 h. 2) In normal pituitary incubates, TRH stimulated TSH subunit carbohydrate, but not apoprotein, synthesis only at 24 h. 3) TRH increased the relative glycosylation of TSH in hypothyroid and normal rat pituitary incubates. Such alterations in TSH glycosylation may be due to structural changes in the carbohydrate moiety and may be important for hormone release, biological activity, or clearance.     

Effects of thyrotropin-releasing hormone on phosphoinositides and cytoplasmic free calcium in thyrotropic pituitary cells

We have previously demonstrated differences in several cellular responses to TRH in mouse thyrotropic pituitary (TtT) cells and in rat mammotropic pituitary (GH3) cells. In this report, we further explore the mechanism of TRH action in TtT cells by measuring its effects on phosphoinositides and on cytoplasmic free Ca2+ concentration [( Ca2+]i). We demonstrate that TRH stimulates rapid hydrolysis of phosphatidylinositol 4,5-bisphosphate [PtdIns(4,5)P2] by a phospholipase C and elevates [Ca2+]i. Furthermore, we present evidence that hydrolysis of PtdIns(4,5)P2 is not secondary to the elevation of [Ca2+]i. TRH caused a rapid decrease in the level of PtdIns(4,5)P2 to 57% of control and stimulated an increase in inositoltriphosphate, the unique product of phospholipase C-mediated hydrolysis of PtdIns(4,5)P2, to a peak of 280% of control. In control cells, resting [Ca2+]i was 106 +/- (SE) 27 nM, and TRH stimulated a rapid elevation to 700 +/- 210 nM. In experiments performed to determine whether PtdIns(4,5)P2 hydrolysis induced by TRH may have been caused by the elevation of [Ca2+]i, the following results were obtained: the effect of TRH to decrease the level of PtdIns(4,5)P2 was not reproduced by the calcium ionophore A23187 or by membrane depolarization with 50 mM K+; the calcium antagonist TMB-8 did not inhibit the TRH-induced decrease in PtdIns(4,5)P2; and, most importantly, inhibition by EGTA of the elevation of [Ca2+]i did not inhibit the TRH-induced decrease in PtdIns(4,5)P2. We suggest that phospholipase C-mediated hydrolysis of PtdIns(4,5)P2 to yield inositoltriphosphate may be the initial event in TRH action in TtT cells, as in GH3 cells, that leads to elevation of [Ca2+]i and to TSH secretion.     

Differential sulfation and sialylation of secreted mouse thyrotropin (TSH) subunits: regulation by TSH-releasing hormone

To determine whether sulfate and/or sialic acid are present on secreted mouse TSH, thyrotropic tumor minces and hypothyroid pituitaries were incubated with [3H]methionine and [35S]sulfate, or [35S]methionine and [3H]N-acetylmannosamine. The metabolically labeled TSH and free alpha-subunits were then analyzed by gel electrophoresis. [3H]N-Acetylmannosamine was a specific precursor (greater than 80%) for the sialic acid [3H]N-acetylneuraminic acid, as established by HPLC characterization of tritium label released by acid hydrolysis. Each of the three secreted subunits (TSH alpha, TSH beta, and free alpha) incorporated both sulfate and sialic acid. The incorporation of these labels was confirmed by the release of [35S]sulfate by endoglycosidase F and of [3H]N-acetylneuraminic acid by neuraminidase. Differential labeling of newly synthesized secreted TSH subunits was observed. In secreted TSH dimer, TSH beta incorporated 1.3 times more [35S]sulfate (P less than 0.05) and 2.5 times more [3H] N-acetylmannosamine (P less than 0.02) per carbohydrate chain than did TSH alpha. Secreted free alpha-subunit incorporated more [3H]N-acetylmannosamine, but less [35S]sulfate, then did secreted TSH alpha. To investigate the effect of TRH on TSH sulfation and sialylation, thyrotropic tumor minces and hypothyroid pituitaries were incubated with [35S]sulfate or [3H]N-acetylmannosamine, with or without 10(-7) M TRH; labeling was then normalized in each case to incorporation of [3H]mannose, a marker of the inner core sugars. TSH secreted in the presence of TRH had a lower sulfate to mannose ratio [28 +/- (+/- SE) 4% of control; P less than 0.05] and a lower sialic acid to mannose ratio (63 +/- 8% of control; P less than 0.05). TSH alpha and TSH beta were affected equally. No change was seen in the labeling of non-TSH secretory proteins. Differential glycoprotein sulfation and sialylation may, in part, explain the previously observed variability in isoelectric point, bioactivity, and MCR of TSH in different physiological states and may represent a point of regulation by TRH.     

Structures of high-mannose and complex oligosaccharides of mouse TSH and free alpha-subunits after in vitro incubation of thyrotropic tissue with TRH.

To determine whether incubation of mouse thyrotropic tissue with TRH in vitro influenced the oligosaccharide structure of TSH, thyrotropic tumor tissue or pituitary tissue was incubated in vitro with [3H]mannose or with [35S]sulfate and [3H]methionine, in the absence or presence of TRH for times up to 24 h. [3H]mannose-labeled oligosaccharides from intracellular TSH and free alpha-subunits were analyzed by paper chromatography, and were predominantly Man9GlcNAc and Man8GlcNAc units both in the absence and presence of TRH. The [35S]sulfate/[3H]methionine ratio in secreted molecules was greater for TSH than for free alpha-subunits; within TSH heterodimers the ratio was greater for beta-subunits than alpha-subunits. The [35S]/[3H] ratio was not altered in TSH or free alpha-subunits by TRH. Analyses of [3H]mannose-labeled charged oligosaccharides by HPLC anion-exchange chromatography revealed similar types of oligosaccharides present on TSH subunits and free alpha-subunits (having one or two sulfate residues, one or two sialic acid residues, or both a sulfate and a sialic acid residue). These charged oligosaccharides occurred in different proportions on TSH subunits compared to free alpha-subunits, and also differed depending on whether the tissue source was tumorous or nontumorous. The proportions of oligosaccharide unit types were not altered by TRH. Thus, while this study provided information concerning the high-mannose and complex oligosaccharides of mouse TSH, there was no evidence that short incubations of tissues with TRH in vitro caused modulation of TSH oligosaccharide structures.     

Role of arachidonic acid in the regulation of adrenocorticotropin release from rat anterior pituitary cell cultures

In addition to cAMP-dependent mechanisms, stimulation of pituitary ACTH secretion by various stimuli, including CRF, may involve phospholipid and arachidonic acid turnover. To determine the role of phospholipase A2 activation in corticotroph function, we studied the effect of exogenous arachidonic acid, phospholipase A2, and the phospholipase A2 activator melittin on ACTH release in cultured rat anterior pituitary cells. Incubation with 1-100 micron arachidonic acid, 0.01-1 micron melittin, 0.1-10 U/ml phospholipase A2, and 0.01-10 nM CRF caused dose-dependent increases in ACTH release to 8.1 +/- 1.1- (+/- SE), 16.2 +/- 0.9-, 13.6 +/- 1.2-, and 2.9 +/- 0.3-fold; respectively. The participation of the major pathways of arachidonic acid metabolism in the control of ACTH release was analyzed in cells treated with nordihydroguaiaretic acid, a lipoxygenase inhibitor; indomethacin, a cycloxygenase inhibitor; and 5,8,11,14-eicosatetraynoic acid, an inhibitor of both pathways. The effects of arachidonic acid, melittin, and CRF were partially blocked by 10 micron nordihydroguaiaretic acid and 5,8,11,14-eicosatetraynoic acid, but were significantly enhanced by 10 micron indomethacin. These results suggest that arachidonic acid is mainly metabolized through the lipoxygenase pathway to a stimulatory metabolite and, to a lesser extent, through the cycloxygenase pathway to an inhibitory metabolite. Arachidonic acid release from anterior pituitary cells labeled with [3H]arachidonic was analyzed during cell column perifusion and stimulation by CRF and other secretagogues. Two-minute pulses of CRF (10 nM), vasopressin (10 nM) and phorbol 12-myristate 13-acetate (100 nM) caused immediate 1.5- to 2-fold increases in [3H]arachidonic acid release, and melittin (100 nM) caused a 5-fold increase in [3H]arachidonic acid release. The ability of both exogenously added and endogenously generated arachidonic acid to stimulate ACTH secretion, together with the stimulation of arachidonic acid release by ACTH secretagogues and the attenuation of stimulated ACTH release by lipoxygenase blockers, indicate that lipoxygenase products of arachidonic acid metabolism participate in the control of ACTH secretion.     

Changes in thyrotropin (TSH) carbohydrate structure and response to TSH-releasing hormone during postnatal ontogeny: analysis by concanavalin-A chromatography

We have studied the carbohydrate structure of TSH as well as its response to TRH during postnatal ontogenesis in the rat using Concanavalin-A (Con A)-Sepharose chromatography of labeled glycopeptides. Pituitaries from neonatal (5-day-old) rats with low levels of endogenous TRH and mature (56-day-old) rats were incubated for 24 h in medium containing [3H] glucosamine in the presence or absence of 10(-7) M TRH. Both intracellular and secreted TSH were immunoprecipitated, treated with Pronase to generate glycopeptides, and analyzed by chromatography on Con A-Sepharose. The total amount of [3H]glucosamine-labeled TSH was greater per pituitary in mature rats compared to that in neonatal rats (P less than 0.05), while there was no significant difference between the groups in the concentration of total labeled TSH per microgram pituitary DNA. RIA determination of total TSH was greater in the older animals than in the younger animals when normalized both per pituitary and per microgram pituitary DNA (P less than 0.01 and P less than 0.02, respectively). However, for both labeled and unlabeled TSH the percentage of TSH secreted was greater in mature rats than in neonatal rats (P less than 0.02 and P less than 0.01, respectively), indicating a less active hormonal secretory process in the younger animals. In control animals, the proportion of labeled TSH glycopeptides that did not bind to Con A was greater in 56- than in 5-day-old animals for both intrapituitary and secreted forms (P less than 0.01), reflecting a shift toward more multiantennary and/or bisected biantennary complex carbohydrate structures in the older animals. In response to TRH in vitro, the total amount of labeled secreted TSH was increased more than 2-fold in both 5-day-old (P less than 0.05) and 56-day-old (P = NS) animals. However, there was a marked difference in the glycopeptide distribution between these two ages. Five-day-old animals showed a small but not significant decrease in the percentage of secreted TSH glycopeptides that bound to Con A-Sepharose, while 56-day-old animals had a specific increase in the glycopeptide fractions that bound and corresponded to biantennary complex and/or unusual hybrid forms (P less than 0.01). These studies in the rat suggest differences in TSH carbohydrate structure and secretion as well as a differential response to TRH during postnatal ontogenesis.     

The effects of anterior hypothalamic deafferentation on thyrotropin (TSH) biosynthesis and response to TSH-releasing hormone

The effects of hypothalamic deafferentation on TSH synthesis were studied by making cuts of 180 degrees arc in the anterior hypothalamus (n = 18) or sham cuts (n = 12) in rats. After 21 days, pituitaries were incubated with [35S]methionine (MET), [3H]glucosamine (GLCN), with or without 10(-8)M TRH for 24 h. TSH and free alpha-subunits were immunoprecipitated and analyzed by gel electrophoresis. In the deafferented group as compared to sham, MET incorporation into both subunits of secreted TSH was decreased (alpha, 96 +/- (SE) 9 X 10(3) vs. 180 +/- 20 X 10(3) dpm/mg protein; beta, 35 +/- 9 X 10(3) vs. 84 +/- 15 X 10(3) dpm/mg protein; P less than 0.05). Basal GLCN incorporation into both subunits of secreted TSH was also decreased in the deafferented group (alpha, 6.5 +/- 11 X 10(3) vs. 132 +/- 17 X 10(3) dpm/mg protein; beta, 36 +/- 8 X 10(3) vs. 101 +/- 29 X 10(3), P less than 0.05). In vitro TRH did not stimulate MET incorporation into secreted TSH in the sham controls but did in the deafferented group (alpha, 270% of basal; beta, 374% of basal; P less than 0.01). In vitro TRH increased GLCN incorporation in secreted TSH in both the sham (alpha, 253% of basal; beta, 245% of basal; P less than 0.02) and the deafferented group (alpha, 692% of basal; beta, 630% of basal; P less than 0.01). GLCN/MET ratio, reflecting relative glycosylation, did not differ for sham or deafferented groups but increased 2-fold with in vitro TRH in each group for both secreted subunits (P less than 0.01). Free alpha-synthesis and intrapituitary TSH were not altered by deafferentation or TRH. In summary, 1) anterior hypothalamic deafferentation decreases basal TSH protein and carbohydrate synthesis; 2) such deafferentation increases sensitivity to TRH stimulation of TSH synthesis, most notably apoprotein synthesis; 3) TRH increases relative glycosylation of secreted TSH in both deafferented and sham groups. These data suggest that TRH plays a significant role in regulating basal TSH protein and carbohydrate synthesis, glycosylation of TSH subunits, and subsequent bioactivity.     

Nocturnal serum thyrotropin (TSH) surge and the TSH response to TSH-releasing hormone: dissociated behavior in untreated depressives

TSH secretion, with particular regard to the nocturnal surge of the hormone, was evaluated in 15 women (age range, 35-66 yr; mean, 50 yr) with untreated major endogenous depression and 15 healthy women (age range, 32-67 yr; mean, 53 yr) using an ultrasensitive assay. Mean morning (0830 h) TSH values did not differ in the 2 groups (1.3 +/- 02 mU/L in depressives and 1.4 +/- 0.1 mU/L in controls), whereas mean nighttime (2400-0200 h) values were significantly reduced in depressives (1.5 +/- 0.3 vs. 3.1 +/- 0.3 mU/L; P less than 0.0005). At variance with the control group, morning and nighttime TSH values did not differ in the depressives. The nocturnal serum TSH surge was abolished in 14 of 15 depressed patients. The mean peak TSH value after TRH was slightly yet significantly lower in the depressives. Patients with subnormal (less than 0.4 mU/L) TSH values in the morning had a serum TSH increase after TRH less than 2 mU/L in 5 of 6 cases and a lack of the nocturnal TSH surge in 6 of 6. Among the 9 patients with normal TSH values in the morning, the nocturnal serum TSH surge was lost in 8 of 9, whereas the response to TRH was normal in all. The depressives, at variance with other reports, showed significantly lower values of total and free thyroid hormones. Mean serum sex hormone-binding globulin (SHBG) and ferritin were also significantly reduced. In conclusion, major endogenous depression is associated with a major impairment of TSH secretion, which baseline TSH measurements in the morning and the evaluation of the TSH response to TRH may not reveal. In this regard, the loss of the nocturnal serum TSH rise would appear to be a more sensitive indicator of hypothalamus-pituitary-thyroid axis alterations in depressives than the TRH test, which is commonly used in the evaluation of these patients. The lack of the nocturnal TSH surge may be responsible for the reduced thyroid hormone secretion and supports the case for some degree of central hypothyroidism in endogenous depression.     

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.     

Evidence supporting a correlation between arachidonic acid release and prolactin secretion from GH3 cells

In this study, pharmacological agents that alter phospholipase A2 activity were examined for their effects on PRL release and arachidonic acid mobilization in GH3 cells, a pituitary tumor cell line. Stimulators of phospholipase A2 activity, melittin and mastoparan, increased PRL release during short term incubation. This stimulation was reduced by carbachol, a cholinergic receptor ligand that inhibits PRL release from GH3 cells. Melittin also caused release of [3H]arachidonic acid that had previously been incorporated into phospholipids. Increased levels of free [3H]arachidonic acid in the medium were associated with a loss of radiolabel from the phospholipid fraction of the cells. The [3H]arachidonic acid in phosphatidylcholine, phosphatidylethanolamine, phosphatidylserine, and phosphatidylinositol was reduced during melittin exposure. In contrast, two inhibitors of phospholipase A2, dibromoacetophenone (BAP) and U10029A, inhibited spontaneous PRL release. BAP also decreased basal release of [3H]arachidonic acid, blocked melitin-induced PRL secretion, and inhibited melittin-induced [3H] arachidonic acid release. Exogenous arachidonic acid at doses from 10 nM to 1 microM stimulated PRL secretion. The phospholipase A2 inhibitor BAP blocked TRH- and vasoactive intestinal peptide-induced PRL release, whereas U10029A blocked cAMP-induced and blunted TRH- and vasoactive intestinal peptide-induced PRL release. The hydrolysis of membrane phospholipids generating free arachidonic acid and lysophospholipid under our experimental conditions correlated with PRL secretion in GH3 cells. Addition of arachidonic acid to the culture medium stimulated PRL secretion. These data suggest that release of arachidonic acid and its subsequent actions may participate in the intracellular regulation of PRL secretion.     

Altered thyrotropin (TSH) carbohydrate structures in hypothalamic hypothyroidism created by paraventricular nuclear lesions are corrected by in vivo TSH-releasing hormone administration

TSH is a glycoprotein hormone composed of two subunits with attached carbohydrate chains that have varying structural characteristics. To determine the role of TRH in vivo in regulating structural characteristics of TSH carbohydrate chains, adult rats received paraventricular nuclear (PVN) lesions (n = 6) or sham lesions (n = 6). The PVN contain large amounts of TRH, and rats with lesions in these hypothalamic nuclei have been shown to have decreased plasma thyroid hormone levels. At 10 days after surgery, sc osmotic pumps infusing saline or 1 mg/kg/day TRH were placed. At 14 days after surgery, pituitaries were removed and incubated with [3H]glucosamine for 24 h. Glycopeptides prepared from secreted TSH were sequentially eluted from Concanavalin-A chromatography columns selecting unbound, weakly bound, and strongly bound forms. Plasma free T4 was lower in the PVN lesioned rats treated with saline than sham lesioned rats treated with saline (1.6 +/- 0.4 vs. 5.2 +/- 0.1 ng/dl, P less than 0.001). In vivo TRH administration in the PVN lesioned group normalized plasma free T4 but had no effect on free T4 in the sham group. Secreted TSH glycopeptides in the PVN lesioned rats treated with saline as compared to sham lesioned rats treated with saline had fewer unbound forms reflecting multiantennary structures (43 +/- 4 vs. 57 +/- 1%; P less than 0.05) and more weakly bound forms reflecting biantennary structures (50 +/- 4 vs. 35 +/- 2%; P less than 0.05). TRH administration in vivo normalized the Concanavalin-A binding pattern of secreted TSH glycopeptides in the PVN lesioned group but had no significant effect in the sham lesioned group. TSH alpha-subunit demonstrated both multi- and biantennary forms but TSH-beta subunit showed a predominance of multiantennary forms in both the PVN and sham lesioned groups treated with saline. In vivo changes in TRH levels altered TSH carbohydrate characteristics as described above for both subunits. In summary, hypothalamic hypothyroidism altered TSH carbohydrate structures, and in vivo TRH administration normalized these structures in parallel with the correction of serum free T4. In addition to reported quantitative changes in TSH in response to TRH, these qualitative changes may have an important effect on TSH action.     

Thyrotropin-releasing hormone stimulation of prolactin secretion is coordinately but not synergistically regulated by an elevation of cytoplasmic calcium and 1,2-diacylglycerol

The precise roles of the calcium and lipid pathways in TRH-stimulated PRL secretion from rat pituitary (GH3) cells are controversial. In particular, it is debated whether elevation of cytoplasmic free Ca2+ concentration [( Ca2+]i) is sufficient to cause burst secretion (0-2 min) or whether an increase in 1,2-diacylglycerol must accompany the Ca2+ elevation. In this study, the effects of TRH, which elevates 1,2-diacylglycerol, on [Ca2+]i and stimulation of burst secretion were compared with those of depolarization by high extracellular K+, which does not increase 1,2-diacylglycerol. A maximal concentration of TRH (1 microM) and depolarization by 17.5 mM K+ caused elevation of [Ca2+]i from the resting level of 140 +/- 20 nM to 470 +/- 70 nM and 514 +/- 60 nM, respectively, and stimulated burst secretion from 0.6 +/- 0.2 ng/10(6) cells/min to 3.3 +/- 0.8 and 3.1 +/- 0.4 ng/10(6) cells/min, respectively, when a small component of TRH-stimulated secretion that is independent of elevation of [Ca2+]i was subtracted. A detailed comparison of multiple levels to which [Ca2+]i was elevated (up to 600 nM) and the degree of stimulation of burst phase secretion demonstrated the same positive linear correlation (correlation coefficient = 0.96) for TRH and K+ depolarization. Hence, elevation of [Ca2+]i is sufficient to cause burst secretion irrespective of elevation of 1,2-diacylglycerol. Optimal stimulation by TRH of sustained secretion of PRL did not depend on elevation of [Ca2+]i; sustained PRL secretion stimulated by 10 nM TRH was 2.6 +/- 0.4 and 2.7 +/- 0.2 ng/10(6) cells/min in control cells and arachidonic acid-pretreated cells in which [Ca2+]i was not elevated, respectively. The data from this and previous studies demonstrate that elevation of [Ca2+]i and 1,2-diacylglycerol may act coordinately, but not synergistically, to mediate TRH stimulation of PRL secretion from GH3 cells.     

Influences of protein synthesis inhibitors on TRH-stimulated secretion of glycosylated TSH

The significant influence of protein synthesis inhibitors on TRH-stimulated secretion of glycosylated TSH was investigated in the rat anterior pituitary in vitro. TRH stimulated secretion of (3H)glucosamine-labeled TSH but did not change incorporation of its labeled precursor into the pituitary TSH. Addition of cycloheximide significantly inhibited both incorporation of (14C)alanine into the pituitary protein and of (3H)glucosamine into the pituitary TSH even 3 hours after incubation, while it did not cause a significant change in secretion of glucosamine-labeled TSH. Apparent inhibition of (14C)alanine incorporation into the pituitary protein was produced by addition of actinomycin D in the 3 and 6 hour-incubation, but the same drug did not cause the significant change in the amount of (3H)-glucosamine-labeled TSH in the anterior pituitary and medium. It is concluded from the present study that TRH plays a potential role in regulating carbohydrate synthesis of TSH prior to secretion, and messenger RNA is not essential for its role in the glycosylation of TSH.     

Effects of repetitive administration of thyrotropin-releasing hormone at short intervals in acromegaly

We investigated the pattern of GH secretion in response to repetitive TRH administration in patients with active acromegaly and in normal subjects. Nine acromegalic patients and 10 normal subjects received three doses of 200 micrograms of TRH iv at 90-min intervals. There was a marked serum GH rise in acromegalic patients after each TRH dose (net incremental area under the curve [nAUC]: first dose = 4448 +/- 1635 micrograms.min.l-1; second dose = 3647 +/- 1645 micrograms.min.l-1; third dose = 4497 +/- 2416 micrograms.min.l-1; NS), though individual GH responses were very variable. In normal subjects TRH did not elicit GH secretion even after repeated stimulation. Each TRH administration stimulated PRL release in acromegalic patients, though the nAUC of PRL was significantly higher after the first (1260 +/- 249 micrograms.min.l-1) than after the second and the third TRH administration (478 +/- 195 and 615 +/- 117 micrograms.min.l-1, respectively; P less than 0.01). In normal subjects too, PRL secretion was lower after repeated stimulation (first dose = 1712 +/- 438 micrograms.min.l-1; second dose = 797 +/- 177 micrograms.min.l-1; third dose = 903 +/- 229 micrograms.min.l-1 P less than 0.01), though different kinetics of PRL secretion were evident, when compared with acromegalic patients. TSH secretion, assessed in only 4 patients, was stimulated after each TRH dose, though a minimal but significant reduction of nAUC of TSH after repeated TRH challenge occurred. Both T3 and T4 increased steadily in the 4 patients. The same pattern of TSH, T3, and T4 secretion occurred in normal subjects.(ABSTRACT TRUNCATED AT 250 WORDS)     

EFFECT OF LOW-DOSE DOPAMINE INFUSION ON BASAL AND STIMULATED TSH AND PROLACTIN CONCENTRATIONS IN MAN

Dopamine (DA) infused at pharmacological doses in man inhibits thyrotrophin (TSH) secretion, although the physiological significance of this observation is unclear. The effect of low-dose DA infusion (0.1 microgram/kg/min) on TSH and prolactin (PRL) concentrations during stimulation with thyrotrophin releasing hormone (TRH) in normal male subjects is reported. Six subjects were given intravenous DA or placebo infusions for 165 min on separate days. A bolus of TRH (7.5 micrograms) was given at + 90 min, followed by infusion of the tripeptide (750 ng/min) for 45 min during both DA and placebo studies. In all subjects TRH administration caused a small rise in TSH which was partially inhibited by DA (peak 5.73 +/- 0.85 mU/l vs 4.58 +/- 1.09, P less than 0.05). PRL response to TRH was almost totally inhibited by DA (620 +/- 164 mU/l vs 234 +/- 96, P less than 0.05); integrated TSH and PRL responses to TRH were similarly inhibited by DA. Circulating plasma DA concentration during infusion of the catecholamine was 3.46 +/- 1.00 ng/ml, which is within the range reported in pituitary stalk plasma of other species. These data support the hypothesis that DA is a physiological modulator of TSH secretion in normal man. Major differences in the time course of TSH and PRL responses to TRH, and in the suppressive effect of DA on these responses suggest that there are fundamental differences in stimulus-secretion coupling for TRH and the lactotroph and thyrotroph.     

Interactions among epinephrine, thyrotropin (TSH)-releasing hormone, dopamine, and somatostatin in the control of TSH secretion in vitro

Epinephrine and TRH independently release TSH from rat anterior pituitary cells in primary monolayer culture (ED50, 11 and 5 nM, respectively; maximum responses, 80% and 110%, respectively). The effects of these compounds together are additive, even at concentrations at which each is maximally effective alone. Dopamine inhibited basal and epinephrine-stimulated TSH secretion by 25 +/- 5% (+/-SE; ED50, 50 +/- 9 nM in each case). Somatostatin was effective against epinephrine-stimulated, but not basal, TSH secretion (80 +/- 4% inhibition; ED50, 1 +/- 3 nM). The data show that epinephrine is a potential regulator of TSH secretion by its own action and via its interactions with TRH, dopamine, and somatostatin.     

Effects of in vivo bolus versus continuous TRH administration on TSH secretion, biosynthesis, and glycosylation in normal and hypothyroid rats

The effects of in vivo TRH administered either as bolus or continuous doses on TSH secretion, synthesis, and glycosylation were studied in normal and hypothyroid rats. Nine-week-old normal or 3-week postthyroidectomy rats were administered bolus doses of saline or TRH (0.5 mg/kg) twice daily or continuous saline or TRH (1 mg/kg/day) via an osmotic pump. After 5 days, pituitaries were removed and incubated with [35S]methionine (MET) and [3H]glucosamine (GLCN), with or without 10(-8) M TRH, for 6 and 24 h. Samples were precipitated with anti-TSH beta sera and then analyzed by gel electrophoresis. In normal rats, plasma TSH, T4 and T3 increased with continuous in vivo TRH but not with bolus TRH; in hypothyroid rats, plasma TSH, T4 and T3 were not altered by continuous or bolus doses of TRH. Additionally, in normal rats, continuous in vivo TRH increased incorporation of MET in secreted TSH (477 vs. 212 X 10(3) dpm/mg DNA; P less than 0.05) and intrapituitary TSH (5035 vs. 2124 X 10(3) dpm/mg DNA; P less than 0.05), and GLCN in secreted TSH (148 vs. 50 dpm/mg DNA; P less than 0.05) and intrapituitary TSH (2344 vs. 744 X 10(3) dpm/mg DNA; P less than 0.05). In contrast, in hypothyroid animals, continuous in vivo TRH did not alter MET or GLCN incorporation in TSH. Bolus TRH did not alter secreted or intrapituitary MET or GLCN incorporation into TSH in the normal rat. However, bolus TRH in the intrapituitary MET or GLCN incorporation into TSH in the normal rat.(ABSTRACT TRUNCATED AT 250 WORDS)     

Decreased TSH response to TRH induced by amiodarone

In order to test the reactivity of TSH to TRH during amiodarone treatment we investigated 7 hypothyroid subjects treated with 50 micrograms T3/day. A TRH test (200 micrograms iv) was performed before and after 6 weeks of treatment with 400 mg amiodarone/day. Amiodarone treatment induced a significant increase in serum total and free T3 (from 2.17 +/- 0.13 to 3.55 +/- 0.58 nmol/l and from 5.6 +/- 0.61 to 9.46 +/- 1.41 pmol/l). Basal TSH levels were significantly decreased and the maximal stimulation of TSH 20 min after TRH injection was only 20.0 +/- 3.3 mU/l during amiodarone treatment compared with 61.4 +/- 10.4 mU/l before treatment. These results indicate that in hypothyroid patients treated with amiodarone, the TSH response to TRH is blunted and that this is likely to be related to the higher total and free T3 levels or to a direct effect of amiodarone at the pituitary level.     

The effects of thyroid hormone deprivation in vivo and in vitro on growth hormone (GH) responses to human pancreatic (tumor) GH-releasing factor (1-40) by dispersed rat anterior pituitary cells

Anterior pituitary cells from euthyroid and hypothyroid male rats have been cultured as monolayers for 3 days with or without 5 nM T3 and stimulated with either human pancreatic GH-releasing factor 1-40 (hpGRF), TRH, or the Ca2+ channel ionophore A23187. Basal GH secretion was reduced in the hypothyroid cultures (P less than 0.001) and basal TSH secretion increased (P less than 0.001). Culture with T3 increased GH secretion and intracellular GH content in euthyroid and hypothyroid cultures but suppressed TSH secretion with no effect on intracellular TSH content in either euthyroid or hypothyroid cultures. hpGRF released more GH from euthyroid [3.52 +/- 0.2 (SE) micrograms/6 h X 10(5) cells] than hypothyroid cultures of (0.17 +/- 0.01 micrograms/6 h X 10(5) cells, P less than 0.001) without a change in ED50 (approximately 0.02 nM). The reduction in hpGRF-induced GH release remained significant when corrected for the reduced intracellular GH content in the hypothyroid cultures. hpGRF-induced GH release also declined relative to A23187-induced GH release in hypothyroid cultures. Culture with 5 nM T3 doubled maximum hpGRF-induced GH release in euthyroid cultures and increased maximum release 10-fold in hypothyroid cultures without altering the ED50 of hpGRF action. In contrast, T3 suppressed TRH-induced TSH release in euthyroid cultures but was without effect on TRH-induced TSH release in the hypothyroid cultures. T3 did not effect the ED50 of TRH action (2-5 nM). In summary, hypothyroid rat anterior pituitary cells in culture have a reduced maximal GH response to hpGRF, but the same ED50. hpGRF activity can be partially restored by physiological concentrations of T3 in vitro.     

Thyrotropin (TSH)-releasing hormone-stimulated TSH release and TSH concentration in the guinea pig pituitary, as determined by a heterologous radioimmunoassay

Little is known regarding how the guinea pig (GP) compares with the rat in terms of TSH economy. To develop a heterologous RIA for GP TSH, rabbits were injected with GP TSH. In one rabbit (anti-gpTSH-8), antibodies that bound 125I-labeled bovine (b) TSH and rat (r) TSH but not 125I-labeled bLH or rPRL were generated. The binding of anti-gpTSH-8 to [125I]bTSH was inhibited in a parallel manner by bTSH over a range of 0.047-5.42 ng, rTSH over a range of 0.24-25 ng, and dilutions of GP pituitary extracts. This system, with bTSH as the standard, was employed as the basis for a heterologous TSH RIA (GP TSH RIA). The cross-reactions of rTSH and bLH in the GP TSH RIA were 45% and 7%, respectively. Rat and bovine FSH, GH, and PRL had little or no cross-reaction. GP pituitaries were incubated in vitro and dosed with LHRH and TRH. The GP TSH RIA detected an 11-fold increase in TSH in the medium in response to TRH and no change in immunoreactivity in response to LHRH. In contrast, a RIA for bLH detected a 25-fold increase in LH in the medium in response to LHRH and no increase in response to TRH. The TSH content in GP pituitaries was significantly lower than that in the rat (GP, 16.8 +/- 1.6 ng/mg; rat, 80.3 +/- 6.2 ng/mg; P less than 0.05) as were serum TSH concentrations (GP, 0.8 +/- 0.4 ng/ml; rat, 4.5 +/- 1.1 ng/ml; P less than 0.05). Thyroid hormone administration (T4 Rx) in both GP and rat produced a significant reduction in pituitary TSH content (GP control, 4.8 +/- 0.4 ng/mg; T4 Rx, 2.1 ng/mg; P less than 0.05; rat control, 52.4 +/- 4.0 ng/mg; T4 Rx, 20.5 +/- 1.6 ng/mg; P less than 0.05) and TSH release (GP control, 9.4 +/- 2.3 ng/ml; T4 Rx, 4.3 +/- 1.5 ng/ml; P less than 0.05; rat control, 357 +/- 81 ng/ml; T4 Rx, 133 +/- 27 ng/ml; P less than 0.05) from incubated hemipituitaries. Thyroidectomy in the rat was associated with a decrease in pituitary TSH content, but no change in pituitary content was found in thyroidectomized GPs. These studies demonstrate the feasibility of estimating GP TSH with a heterologous RIA that employs polyvalent antiserum against GP TSH as the first antibody and bTSH as the tracer and standard.(ABSTRACT TRUNCATED AT 400 WORDS)