Actions of releasing factors on isolated secretory granules mediated by calcium.

Synthetic TRH, crude hypothalamic extract and partially purified prolactin releasing factor stimulated prolactin and growth hormone release from isolated secretory granules. Somatostatin and partially purified prolactin release-inhibiting factor inhibited release of both hormones. Calcium promoted hormone release from granules; its releasing action was potentiated by TRH and ionophore A23187 but reduced by somatostatin.     

Growth hormone response to thyrotropin-releasing hormone in liver cirrhosis: unique alteration in anterior pituitary responsiveness to hypothalamic hormones

Patients with chronic liver diseases were evaluated for: 1) the ability of somatostatin to affect the thyrotropin-releasing hormone (TRH) induced growth hormone (GH) rise; 2) the competence of luteinizing-hormone releasing hormone (LH-RH) to release GH; 3) the non-specific releasing effect of TRH and LH-RH on other anterior pituitary (AP) hormones. In 6 patients, infusion of somatostatin (100 micrograms iv bolus + 375 micrograms i.v. infusion) completely abolished the TRH (400 micrograms i.v.)-induced GH rise; in none of 12 patients, of whom 7 were GH-responders to TRH, did LH-RH (100 micrograms i.v.) cause release of GH; 4) finally, LH-RH (12 patients) did not increase plasma prolactin (PRL) and TRH (7 patients) did not evoke a non-specific release of gonadotropins. It is concluded that: 1) abnormal GH-responsiveness to TRH is the unique alteration in AP responsiveness to hypothalamic hormones present in liver cirrhosis; 2) the mechanism(s) subserving the altered GH response to TRH is different from that underlying the TRH-induced GH rise present in another pathologic state i.e. acromegaly, a condition in which the effect of TRH escapes somatostatin suppression and LH-RH evokes GH and PRL release.     

Inactivation of two hyperactive LH-RH analogues by rat hypothalamic peptidases.

Hyperactive analogues of luteinizing hormone-releasing hormone (LH-RH) are beleived to derive their properties from either increased binding affinity to anterior pituitary receptor sites or through decreased susceptibility to enzymic degradation. To investigate the latter suggestion and to examine the possible sites of hypothalamic peptidases inactivating LH-RH, D-Ser(TBU)6-EA10-LH-RH and D-Leu6-EA10-LH-RH, which are known to have considerably greater activity than LH-RH, were incubated with a hypothalamic supernatant fraction containing active peptidases degrading LH-RH, and their gonadotrophin-releasing ability after incubation with the enzymes was tested in normal, adult male rats; LH-RH was also tested in the same way. From a comparison of the relative losses of biological activity, both the LH-RH analogues treated proved to be more resistant to the hypothalamic peptidases than LH-RH itself; the D-Leu6-EA10-LH-RH retained its gonadotrophin-releasing activity longer than the D-Ser(TUB)6-EA10-LH-RH. These findings indicate that increased activity of the analogues may, in part be due to increased resistance to enzymic inactivation and suggest initial sites of cleavage at the Gly-leu and Pro-Gly NH2 bonds in the LH-RH decapeptide by the hypothalamic enzymes. Studies on the action of peptidases on LH-RH and its analogues may yield useful information in the design of peptidase with increased biological activity.     

Phylogenetic Distribution and Function of the Hypophysiotropic Hormones of the Hypothalamus

SYNOPSIS. Following the isolation, synthesis and subsequentdevelopment of specific and sensitive radioimmunoassays forthe hypothalamic hormones thyrotropin-releasing hormone (TRH),luteinizing hormone-releasing hormone (LH-RH) and growth hormonerelease-inhibiting hormone (somatostatin), it was recognizedthat these peptides were not localized solely in the hypothalamus,but were widely distributed throughout the mammalian nervoussystem. Somatostatin occurs outside the nervous system altogether,being located in the gastrointestinal tract of vertebrates whereit may have a physiologic role in the secretion of gastrointestinalhormones. TRH, also, has been located outside the nervous system,occurring in large quantities in the skin of Rana species whereit may be of physiologic importance in skin function. This tripeptideis found throughout the nervous system of vertebrate and invertebratespecies in situations where it has no pituitary-thyroid function.Thesepeptides are present in brain synaptosomes and enzymatic degradingsystems have been recognized for each in brain tissue. For TRH,specific receptors and synthesizing activity have been detectedoutside the hypothalamic-pituitary system. The anatomic location,phylogenetic distribution, neurophysiologic and behavioral effectsstrongly support a role for these substances in neuronal regulation,apart from control of pituitary secretion. Evolutionary studies,especially of TRH, suggest that their primary function may beas neurotransmitters.     

Effect of synthetic ovine corticotropin-releasing factor on growth hormone secretion in patients with acromegaly

In a significant proportion of patients with acromegaly, a non-specific increase in plasma growth hormone (GH) has been recognized following administration of thyrotropin-releasing hormone (TRH) or luteinizing hormone-releasing hormone (LH-RH), probably due to the lack of the specificity of the receptor in their tumor cells. In this study, the effects of corticotropin-releasing factor (CRF), a newly isolated hypothalamic hormone, in addition to TRH and LH-RH, on plasma levels of GH and the other anterior pituitary hormones were evaluated in 6 patients with acromegaly. Synthetic ovine CRF (1.0 microgram/kg), TRH (500 micrograms) or LH-RH (100 micrograms) was given as an iv bolus injection, in the morning after an overnight fast. Blood specimens were taken before and after injection at intervals up to 120 min, and plasma GH, adrenocorticotropin (ACTH), thyrotropin, prolactin, luteinizing hormone, follicle-stimulating hormone and cortisol were assayed by radioimmunoassays. A non-specific rise in plasma GH was demonstrated following injection of TRH and LH-RH, in 5 of 6 and 2 of 5 patients, respectively. In all subjects, rapid rises were observed in both plasma ACTH (34.3 +/- 6.2 pg/ml at 0 min to 79.5 +/- 9.5 pg/ml at 30 min, mean +/- SEM) and cortisol level (9.1 +/- 1.3 micrograms/dl at 0 min to 23.4 +/- 1.2 micrograms/dl at 90 min). However, plasma levels of GH and the other anterior pituitary hormones did not change significantly after CRF injection. These results indicate that CRF specifically stimulates ACTH secretion and any non-specific response of GH to CRF appears to be an infrequent phenomenon in this disorder.     

New approaches to the therapy of various tumors based on peptide analogues.

The discovery of hypothalamic hormones was briefly reviewed. The development of new hormonal methods for the therapy of various cancers based on analogues of hypothalmic hormones is then presented. My group isolated luteininzing hormone-releasing hormone (LH-RH), also known as Gn-RH, from pig hypothalmi, elucidated its amino acid sequence, and synthesized it in 1971. The interest in medical applications of LH-RH led to the synthesis of LH-RH analogues by various groups. LH-RH agonists substituted in positions 6 or 10 including Decapeptyl, Leuprolide and Zoladex are much more active than LH-RH and on continuous administration produce inhibition of pituitary and gonads. Chronic administration of LH-RH agonists is being utilized for the treatment of prostate and breast cancer. Octapeptide analogues of somatostatin have various applications in Oncology. In 1980 we developed a new endocrine therapy for advanced prostate cancer based on agonists of LH-RH, which is now preferred by 70-90% of prostate cancer patients for primary treatment. LH-RH antagonists such as Cetrorelix can be used for therapy of BPH. On the basis of the presence of specific receptors for hypothalamic peptides on human cancers, we developed targeted cytotoxic analogues of LH-RH, somatostatin, and bombesin/GRP linked to doxorubicin or 2-pyrrolinodoxorubicin. These analogues inhibit the growth of experimental human prostate, breast, ovarian and endometrial cancer, renal cell carcinoma, pancreatic, colorectal and gastric cancers, small cell lung carcinoma (SCLC) and non-SCLC, brain tumors, melanomas, and lymphomas. Cytotoxic LH-RH analogues are now in clinical trials. Recently we demonstrated that growth hormone-releasing hormone (GH-RH) also serves as an autocrine growth factor in many cancers. Antagonistic analogues of GH-RH synthesized in our laboratory inhibit the growth of diverse tumors. The discovery of LH-RH and somatostatin has led to clinical use of their analogues in the field of cancer treatment and GH-RH antagonists also show a great promise.     

Twenty-four hour rhythms of hypothalamic corticotropin-releasing hormone, thyrotropin-releasing hormone, growth hormone-releasing hormone and somatostatin in rats injected with Freund's adjuvant

The effect of Freund's adjuvant injection on 24-hour variation of hypothalamic corticotropin-releasing hormone (CRH), thyrotropin-releasing hormone (TRH), GH-releasing hormone (GRH) and somatostatin levels was examined in adult rats kept under light between 0800 and 2000 h daily. Groups of rats receiving Freund's complete adjuvant or its vehicle 3 days before sacrifice were killed at six different time intervals throughout a 24-hour cycle. In the median eminence, adjuvant vehicle-injected rats exhibited significant 24-hour variations for the four hormones examined, with maxima at noon. These 24-hour rhythms were inhibited or suppressed by Freund's adjuvant injection. In the anterior hypothalamus of adjuvant vehicle-treated rats, CRH content peaked at 1600 h, while two peaks were found for TRH and GRH levels, i.e., at 2400-0400 h and 1600 h. Freund's adjuvant injection suppressed 24-hour rhythm of anterior hypothalamic CRH, TRH and GRH content and uncovered a peak in anterior hypothalamic somatostatin levels at 0400 h. In the medial hypothalamus of adjuvant vehicle-treated rats, significant 24-hour variations were detectable for TRH (peaks at 1600 and 2400 h) and somatostatin (peak at 2400 h) which disappeared after Freund's adjuvant injection. In the posterior hypothalamus of adjuvant vehicle-treated rats, two peaks were apparent for CRH, TRH and somatostatin levels, i.e. at 1600 h and 2400-0400 h, this hormonal profile remaining unmodified after Freund's adjuvant administration. The administration of the immunosuppressant drug cyclosporine (5 mg/kg, 5 days) impaired the depressing effect of Freund's adjuvant injection on CRH, TRH and somatostatin content in median eminence, but not that on GRH. In the anterior hypothalamus, cyclosporine generally prevented the effect of immunization on hormone levels an revealed a second maximum in TRH at 0400 h. Cyclosporine also restored 24-hour variations in TRH and somatostatin levels of medial hypothalamus of Freund's adjuvant-injected rats but was unable to modify them in the posterior hypothalamus. The results further support the existence of a significant effect of immune-mediated inflammatory response at an early phase after Freund's adjuvant injection on hypothalamic levels which was partially sensitive to immunosuppression by cyclosporine.     

Effects of hypothalamic-releasing hormones on LH, FSH, and prolactin in pituitary monolayer cultures.

Four-day-old pituitary monolayer cultures were incubated with various hypothalamic releasing hormones. Rat hypothalamic extract stimulated the release of LH, FSH, and PRL by these cultures in a dose-related fashion. Synthetic LH-RH stimulated the release of LH and FSH but not of PRL. Synthetic TRH increased the release of PRL but had no effect on LH or FSH. At 10(-8) M, somatostatin did not affect any of the three adenohypophyseal hormones. Incubation with DBcAMP or theophylline also stimulated PRL release without any detectable effect on LH and FSH release. These data suggest the involvement of cyclic AMP--adenylate cyclase system in the mechanism of PRL release, but their involvement in gonadotropin release requires further studies.     

Differences in the degradation of hypothalamic releasing factors by rat and human serum

Rat serum is 2–5 fold more active than human serum in cleaving the three hypothalamic releasing hormones, luteinizing hormone releasing hormone (LH-RH), thyrotropin releasing hormone (TRH), and somatostatin. LH-RH was degraded by two distinct enzymatic mechanisms; 1) endopeptidase cleavage, 2) C-terminal cleavage. The C-terminal cleaving enzyme was active in rat serum but present only in trace levels in human. These mechanisms were substantiated by the use of suitably substituted analogs; D-Ala at position 6 of LH-RH prevented cleavage at the -Tyr⁵-D-Ala⁶-Leu⁷-site and the presence of ethylamide (C₂H₅NH₂) at position 10 inhibited significantly the action of the second enzyme. These analogs have an enhanced biological activity $\text{in}$$\text{vivo}$ which correlates well with their decreased rate of degradation. Somatostatin was degraded by endopeptidase cleavage at one or more sites. D-Trip in position 8 blocked cleavage of the -Trp⁸-Lys⁹-bond, reducing significantly the rate of degradation. This also correlates well with the enhanced biological potency of the (D-Trp⁸)-somatostatin analog. TRH was degraded by cleavage of the pyroGlu-His and His-Pro.NH₂ bonds with the release of free His and Pro. The analog (3-Me-His²)-TRH was degraded by a similar mechanism with the release of 3-Me-His.     

Monolayer cultures of dispersed cells from bovine anterior pituitary: responses to synthetic hypophysiotropic peptides.

Cells were dispersed from bovine anterior pituitary glands, by digestion with collagenase, and cultured. After 4 days the cell monolayers were incubated with fresh medium containing synthetic hypophysiotropic peptides for 2, 6, or 20 h, and hormone released into the medium was estimated by radioimmunoassay. After 2 h, thyroid releasing hormone (TRH) stimulated the release of thyroid-stimulating hormone (TSH) up to eightfold, and of prolactin (PRL) and follicle-stimulating hormone (FSH) about twofold at a minimal effective concentration of 1 ng/ml; enhanced growth hormone (GH) release was not apparent until 20 h, and release of luteinizing hormone (LH) and adrenocorticotrophic hormone (ACTH) was unaffected. Luteinizing hormone releasing hormone (LH-RH) enhanced release of LH maximally (three- to fourfold) during a 2 h incubation and was effective at 0.1 ng/ml; FSH release was significantly enhanced by about 50% above control level. Growth hormone release inhibiting hormone (GH-RIH)(somatostatin) showed significant effects only in the 20 h incubation; GH release was inhibited by 50% and release of PRL was slightly, but significantly, enhanced. Pituitary cell monolayers apparently permit maximal expression of releasing activities inherent in the hypothalamic hormones.     

Neuropeptides in the median eminence: Their sources and destinations

By radioimmunoassay and immunocytochemical techniques, 14 neuropeptides have been measured and localized in the rat median eminence. Neuropeptides with inhibitory or stimulatory effects on the anterior pituitary hormones as well as posterior pituitary hormones are present in the median eminence in the highest concentrations of the central nervous system. All these peptides (LH-RH, TRH, somatostatin, CRF, vasopressin, oxytocin) are of preoptic or hypothalamic origin and they are transported to the median eminence by loop-like fiber systems through the lateral retrochiasmatic area. Within the median eminence, the pericapillary space constitutes the main common pathway. Three major transport routes—axons, vessels, liquor spaces—are separated from each others by only basement membranes, which allow free communications downwards to the pituitary but also backwards to the central nervous system.     

Inhibition of growth hormone synthesis by somatostatin in cultured pituitary of rainbow trout

Summary When the pituitary of rainbow trout (Oncorhynchus mykiss) was incubated in a serum-free medium, a high level of growth hormone release as well as an activation of growth hormone synthesis were observed, suggesting the existence of hypothalamic inhibitory factor(s) on growth hormone synthesis. Although an inhibitory effect of somatostatin on growth hormone release is well established in both mammals and teleosts, an effect on growth hormone synthesis has not been demonstrated. In this study, we examined the effect of somatostatin on growth hormone synthesis in organ-cultured trout pituitary using immunoprecipitation and Northern blot analysis. Somatostatin inhibited growth hormone release from the cultured pituitary within 10 min after addition without affecting prolactin release. Incubation of the pituitary with somatostatin also caused a significant reduction in newly-synthesized growth hormone in a dose-related manner, as assessed by incorporation of [³H]leucine into immunoprecipitable growth hormone. There were no changes in the level or molecular length of growth hormone mRNA after somatostatin treatment, as assessed by Northern slot blot and Northern gel blot analyses. Human growth hormone-releasing factor stimulated growth hormone release, although the spontaneous synthesis of growth hormone was not augmented. However, somatostatin-inhibited growth hormone synthesis was restored by growth hormone-releasing factor to the control level. The spontaneous increase in growth hormone synthesis observed in the organ-cultured trout pituitary may be caused, at least in part, by the removal of the inhibitory effect of hypothalamic somatostatin.Abbreviations GH growth hormone - GHRF GH-releasing factor - PRL prolactin - SDS sodium dodecyl sulphate - SRIF somatostatin (somatropin release-inhibiting factor)     

Pituitary responsiveness to LH-RH and TRH and the effects of progesterone or progesterone and oestradiol treatment in anoestrous sheep.

Pituitary responsiveness to 200 microgram synthetic LH-RH and to 10 microgram TRH was determined in anoestrous sheep before and after treatment for 3 weeks with progesterone (100 mg/day), or oestradiol (250 microgram/day) plus progesterone (100 mg/day). There was a marked decrease in pituitary responsiveness to LH-RH after progesterone (P is less than 0.01), or oestradiol plus progesterone (P is less than 0.01) treatments, and an increase in response to TRH after oestradiol plus progesterone (P is less than 0.01) treatment. The results demonstrate selective and simultaneous feedback effects of oestradiol and progesterone on pituitary responsiveness to two hypothalamic releasing hormones.     

The effect of somatostatin and of prolyl-leucyl-glycinamide (MIF) on ACTH release in dispersed pituitary cells.

The hypothalamic releasing and release-inhibiting peptides have multiple effects on more than one pituitary hormone. In this study the action of the two hypothalamic inhibiting factors, somatostatin (GH-IH) and MSH release-inhibiting factor, prolyl-leucyl-glycinamide (MIF), on ACTH release were studied. Increasing concentrations of GH-IH and MIF were added to 1 ml of a suspension of dispersed anterior pituitary cells from male rats. Both GH-IH and MIF (10^?5 to 10^?11 M) were without effect on basal ACTH secretion of normal and of adrenalectomized rats. However, both peptides, within certain concentration ranges, inhibited the ACTH release stimulated by rat hypothalamic extracts or by arginine vasopressin. The most effective concentrations were 35 nM MIF or 6 nM GH-IH. Beyond these concentrations no further suppression was observed. Our results indicate that somatostatin and MIF can inhibit ACTH release, but only in a state of steroid deprivation and within a limited dose range.     

Multifactorial Modulation of TRH Metabolism

1. Thyrotropin releasing hormone (TRH), synthesized in the paraventricular nucleus of the hypothalamus (PVN), is released in response to physiological stimuli through medianeminence nerve terminals to control thyrotropin or prolactin secretion from the pituitary.2. Several events participate in the metabolism of this neuropeptide: regulation of TRH biosynthesis and release as well as modulation of its inactivation by the target cell.3. Upon a physiological stimulus such as cold stress or suckling, TRH is released and levels of TRH mRNA increase in a fast and transient manner in the PVN; a concomitant increase in cfos is observed only with cold exposure.4. Hypothalamic cell cultures incubated with cAMP or phorbol esters show a rise in TRH mRNA levels; dexamethasone produces a further increase at short incubation times.TRH mRNA are thus controlled by transsynaptic and hormonal influences.5. Once TRH is released, it is inactivated by a narrow specificity ectoenzyme, pyroglu-tamyl peptidase II (PPII).6. In adenohypophysis, PPII is subject to stringent control: positive by thyroid hormones and negative by TRH; other hypothalamic factors such as dopamine and somatostatin also influence its activity.7. These combined approaches suggest that TRH action is modulated in a coordinate fashion.     

Degradation of Thyrotropin-Releasing Hormone and Luteinising Hormone-Releasing Hormone by Enzymes of Brain Tissue

Abstract: In this article, the enzymes of brain and associated tissues that can degrade thyrotropin-releasing hormone (TRH) and luteinising hormone-releasing hormone (LH-RH) are reviewed. As both TRH and LH-RH are considered to act as neurotransmitters or neuromodulators in the CNS, attention is paid to the subcellular location of the enzymes described and how their topographies and substrate specificities fit them to playing roles as inactivating agents for TRH and LH-RH or as regulators of intracellular concentrations of TRH and LH-RH. Consideration is also given to enzymes involved in biotransformation of TRH to secondary metabolites that exhibit biological activity and to enzymes involved in the metabolism of secondary metabolites.     

Luteinizing hormone-releasing hormone and thyrotropin-releasing hormone in human and bovine milk

Two hypothalamic peptide hormones, luteinizing hormone-releasing hormone (LHRH) and thyrotropin-releasing hormone (TRH), have been isolated from human milk and bovine colostrum. Acidified methanolic extracts, prepared from human milk, bovine colostrum and rat hypothalami, as well as synthetic LHRH and TRH markers were subjected to high-pressure liquid chromatography (HPLC). The eluates were tested for the presence of LHRH and TRH by specific radioimmunoassays. It was found that milk extracts contain significant amounts of LHRH (3.9 - 11.8 ng/ml) and TRH (0.16 - 0.34 ng/ml), which comigrate with the corresponding marker hormones and with those of hypothalamic origin. The HPLC-purified LHRH from both human and bovine milk was bioactive in a dose-response manner similar to synthetic LHRH.     

Stimulatory effect of thyrotrophin-releasing hormone (TRH) on the release of luteinizing hormone (LH) from rat anterior pituitary cells in vitro

The effect of thyrotrophin-releasing hormone (TRH, 10(-7) M) on luteinizing hormone (LH) release from rat anterior pituitary cells was examined using organ and primary cell culture. The addition of TRH to the culture medium resulted in a slightly enhanced release of LH from the cultured pituitary tissues. However, the amount of LH release stimulated by TRH was not greater than that produced by luteinizing hormone-releasing hormone (LH-RH, 10(-7) M). Actinomycin D (2 X 10(-5) M) and cycloheximide (10(-4) M) had an inhibitory effect on the action of TRH on LH release. The inability of TRH to elicit gonadotrophin release from the anterior pituitary glands in vivo may partly be due to physiological inhibition of its action by other hypothalamic factor(s).     

Effect of opioid peptides and potassium on the release of vasoactive intestinal polypeptide and thyrotropin releasing hormone from perifused rat hypothalami

Opioid peptides have been demonstrated to stimulate prolactin secretion, and it has been postulated that this is mediated, at least in part, by an effect on hypothalamic prolactin releasing and release-inhibiting factors and neurotransmitters. The aim of this study was to investigate the effect of opioid peptides and depolarizing concentrations of K+ on the release of both vasoactive intestinal polypeptide (VIP) and thyrotropin releasing hormone (TRH) from perifused rat hypothalami. Both met-enkephalin and beta-endorphin stimulated the release of VIP significantly whilst not affecting the release of TRH. In addition, leu-enkephalin was found to have no effect on the release of either VIP or TRH. In contrast, depolarizing concentrations of K+ (50 mM) were found to cause the immediate release of TRH, but not VIP, from the same perifusion. The results suggest a role for VIP, but not TRH, in opioid peptide stimulated release of prolactin. In addition, the data indicates that a substance may be released in response to K+ depolarization which is inhibitory to the release of VIP.