Thyrotropin releasing hormone

Summary Thyrotropin releasing hormone (TRH) acutely stimulates release of thyrotropin (TSH) and prolactin from anterior pituitary cells. A considerable number of studies have been performed with neoplastic and nonneoplastic pituitary cells in culture to elucidate the sequence of intracellular events involved in this action. Although cyclic AMP was suggested as an intracellular messenger, it has been demonstrated that TRH stimulation of hormone release can be dissociated from changes in cyclic AMP concentration, thereby supporting the contention that cyclic AMP is not a required mediator. In contrast, stimulation of hormone release by TRH requires Ca²⁺ and it seems likely that Ca²⁺ is the intracellular coupling factor between TRH stimulation and hormone secretion. TRH has been shown to stimulate ⁴⁵Ca²⁺ efflux from preloaded pituitary cells. Enhanced ⁴⁵Ca²⁺ efflux is thought to reflect an increase in the free intracellular Ca²⁺ concentration which leads to hormone release; however, the source of this Ca^2– is uncertain. Results are reviewed from a series of experiments in pituitary cells which attempt to determine the pool (or pools) of Ca²⁺ that is affected by TRH. These include the following: the effects of decreasing the extracellular Ca^2– concentration on hormone release stimulated by TRH; the effect of TRH on cellular Ca²⁺ as monitored by chlortetracycline; the effects of TRH on Ca²⁺ influx; the effects of the organic Ca²⁺ channel blocking agents, verapamil and methoxyverapamil, on TRH-stimulated hormone release; and the effects of TRH on plasma membrane potential difference and on Ca²⁺-dependent action potentials. Based on these data, separate hypotheses of the early events in TRH stimulation of hormone release in mammotropes and thyrotropes are proposed. In mammotropes, TRH is thought to stimulate prolactin release optimally by elevating the free intracellular Cat+ concentration by mobilizing cellular Ca^2– only. In contrast, in thyrotropes under normal physiological conditions, TRH is thought to stimulate TSH release by mobilizing Ca² from a cellular pool (or pools) and to augment this effect by also inducing influx of extracellular Ca²⁺ through voltage-dependent channels in the plasma membrane.     

On the existence and separation of the follicle stimulating hormone releasing hormone from the luteinizing hormone releasing hormone.

Porcine hypothalamic fragments were extracted by 2M AcOH at 4°C, and the extractives were subsequently processed in the presence of one protease inhibitor and one anti-oxidant. Gel filtration was performed on Bio-Gel P-2, and supplementary [³H]-LHRH and [¹⁴C]- 3H]-LHRH, and was differentiated from [¹⁴C]- 相似文献   

Increased growth hormone responses to growth hormone releasing hormone and thyrotropin releasing hormone in patients with metastatic testicular cancer

In 16 patients with metastatic testicular cancer and 10 age matched male control subjects growth hormone (GH) responses to growth hormone releasing hormone (GHRH; 1 microgram/kg body weight iv.) and thyrotropin releasing hormone (TRH; 200 micrograms iv.) were measured. Basal GH levels and GH levels following stimulation with GHRH or TRH were significantly increased in cancer patients compared to control subjects. 9 patients with testicular cancer were studied both in the stage of metastatic disease and after they had reached a complete remission. In complete remission GH responses to GHRH tended to decrease but the differences did not reach statistical significance. Our data suggest an alteration of hypothalamic and/or pituitary regulation of GH secretion in patients with metastatic testicular cancer.     

Growth hormone and prolactin response to thyrotropin releasing hormone and growth hormone releasing factor in the immature turkey

Synthetic thyrotropin releasing hormone (TRH) and human pancreatic growth hormone releasing factor (hpGRF) stimulated growth hormone (GH) secretion in 6- to 9-week-old turkeys in a dose-related manner. TRH and hpGRF (1 and 10 micrograms/kg, respectively) each produced a sixfold increase in circulating GH levels 10 min after iv injection. Neither TRH nor hpGRF caused a substantial change in prolactin (PRL) secretion in unrestrained turkeys sampled through intraatrial cannulas. However, some significant increases in PRL levels, possibly related to stress, were noted.     

Adrenal luteinizing hormone releasing hormone receptors.

Paraffin sections of mouse adrenals processed with antiserum to luteinizing hormone-releasing hormone (LHRH) in the unlabeled antibody enzyme method reveal moderate staining in the cytoplasm of cells of zona fasciculata and reticularis. The stain is intensified upon pretreatment of sections with LHRH. Pretreated sections processed with solid phase immunoabsorbed LHRH are unstained. Analogues of LHRH deficient in the C-terminal glycine amide inhibit staining, while analogues deficient in the N-terminal pyroglutamic acid have no effect. It is concluded that the adrenal contains receptors for a ligand resembling LHRH in receptor and immunoreactivity. The possibility is considered that the ligand may be an inhibitor of pineal origin.     

The effect of luteinizing hormone releasing hormone and anti-luteinizing hormone releasing hormone antibodies on chorionic gonadotropin and progesterone secretion by human placental villiin vitro

Gonadotropin releasing hormone has been located and found to be secreted by the human placenta in culture. Addition of the releasing hormone upto 1μg concentration in the placental cultures brings about stimulation of chorionic gonadotropin and progesterone secretion. Higher amounts of the decapeptide has an inhibitory influence on both the gonadotropin and the steroid production. The action of the releasing hormone on the placenta could be blocked by the anti-luteinizing hormone releasing hormone monoclonal antibodies indicating a possible site of action of the antibodies for control of fertility     

Human placental receptors for luteinizing hormone releasing hormone

The GTPase activity of the tubulin-colchicine complex has been studied at different tubulin-colchicine concentrations. The specific activity was found to decrease at low concentrations. Several hypothesis accounting for this observation have been discarded, and the activation via collisions between two molecules of tubulin has been considered as a possible model explaining the origin and observed concentration dependence of the GTPase activity. The activation of tubulin-colchicine by unliganded tubulin or tubulin-podophyllotoxin has been investigated within this model which emphasizes the connection between some specific tubulin-tubulin interactions and the conformation of the exchangeable nucleotide site on tubulin.     

Leydig cell receptors for luteinizing hormone releasing hormone and its agonists and their modulation by administration or deprivation of the releasing hormone

Leydig cells isolated from adult rat testes bound ¹²⁵I-labelled luteinizing hormone releasing hormone (LHRH) agonist with high affinity (K_A=1.2 × 10⁹M) and specificity. LHRH and the 3–9 and 4–9 fragments of LHRH agonist competed for binding sites with ¹²⁵I-LHRH agonist but with reduced affinities, whereas fragments of LHRH, and oxytocin and TRH were largely inactive. Somatostatin inhibited binding at high (10^?4M) concentrations but was inactive at 10^?6M and less. Pretreatment of rats for 7 days with 5 μg/day of LHRH agonist reduced binding of ¹²⁵I-LHRH agonist to Leydig cells $\text{in vitro}$ by 25%, whilst inhibition of endogenous LHRH by antibodies for 7 days caused a 40% decrease.     

Isolation and structural characterization of chicken hypothalamic luteinizing hormone releasing hormone

Studies on partially purified chicken hypothalamic luteinizing hormone releasing hormone (LHRH) utilizing chromatography, radioimmunoassay with region-specific antisera, enzymic inactivation, and chemical modification established that the peptide is structurally different from mammalian hypothalamic LHRH. These studies demonstrated that arginine in position 8 is substituted by a neutral amino acid. On the basis of conformational criteria and evolutionary probability of amino acid interchange for arginine, the most likely substitution was glutamine. We therefore synthesized [Gln8]-LHRH and established that it had identical chromatographic, immunologic, and biological properties to the natural chicken peptide. In concurrent studies, purification of 17 micrograms of an LHRH from 249,000 chicken hypothalami was achieved using acetic acid extraction, immuno-affinity chromatography, and cation exchange and reverse phase high performance liquid chromatography. Amino acid composition and sequence analyses confirmed the structure of this form of chicken LHRH as pGlu-His-Trp-Ser-Tyr-Gly-Leu-Gln-Pro-Gly-NH2.     

In vitro pituitary hormone releasing activity of 40 residue human pancreatic tumor growth hormone releasing factor

The hypophysiotropic activities of a synthetic human pancreatic growth hormone releasing factor (hpGRF) with 40 residues was examined in vitro using rat pituitary halves. At concentrations from 10(-10) M to 10(-7) M the peptide stimulated GH release in a dose-dependent manner with the ED50 being 1.2 x 10(-9) M. The concentration of 10(-10) M hpGRF is comparable to the basal hypophyseal portal blood levels of other known hypothalamic hypophysiotropic hormones. However, GH release was enhanced three-fold by concentration as low as 10(-12) M, though no dose-response relationship was observed up to 10(-10) M. Thus, this peptide not only stimulates the release of GH in a dose-dependent manner, but at lower concentrations also maintains elevated GH levels. The release of ACTH, beta-endorphin, LH, and FSH was not affected by hpGRF at any of the concentrations tested. At hpGRF concentrations less than 10(-7) M, the release of TSH and PRL were unaffected. However, at 10(-6) M, TSH release was enhanced about 2.5 fold and prolactin release was elevated slightly.     

Effect of thyrotropin releasing hormone injection on blood growth hormone (GH), TSH and growth hormone releasing hormone (GHRH) concentrations in cancer patients

In order to investigate whether endogenous GHRH and somatostatin were involved in the mechanism of the paradoxical GH rise after TRH injection, changes in serum GH and plasma GHRH were examined before and after TRH injection in 12 cancer patients and changes in serum TSH and GH were similarly studied in 76 cancer patients including 31 GH-responders and 45 GH-nonresponders to TRH. TRH stimulated GH secretions without altering the circulating GHRH concentration in 4 of the 12 cancer patients. There was neither a significant correlation between the increase from the basal to maximum GH and GHRH after TRH injection in the 12 cancer patients nor a reciprocal relationship between the increase in GH and TSH after TRH injection in the 76 cancer patients. These findings suggested that the paradoxical GH rise after TRH injection in cancer patients was exerted by its direct action at the pituitary level, and not mediated through the hypothalamus.