Effects of naloxone,morphine and methionine enkephalin on serum prolactin,luteinizing hormone,follicle stimulating hormone,thyroid stimulating hormone and growth hormone

The response of 5 anterior pituitary hormones to single injections of naloxone, morphine and metenkephalin administration was measured in male rats. Morphine and met-enkephalin significantly increased serum prolactin and GH concentrations, and significantly decreased serum LH and TSH concentrations. Naloxone reduced serum prolactin and GH concentrations, increased serum LH and FSH, but had little effect on serum TSH concentrations. Concurrent injections of naloxone with morphine or met-enkephalin reduced the response to each of the drugs given separtely. These results suggest that endogenous morphinomimetic substances may participate in regulating secretion of anterior pituitary hormones.     

Lithium-induced changes in the plasma and pituitary levels of luteinizing hormone,follicle stimulating hormone and prolactin in rats

Adult male Sprague-Dawley rats, maintained under a controlled photoperiod of LD 14:10 (white lights on at 06:00 h, CST), were injected with lithium chloride and changes in the levels of plasma and pituitary homogenates of luteinizing hormone (LH), follicle-stimulating hormone (FSH) and prolactin (PRL) were examined to evaluate the effects of this anti-manic drug on reproductive function. Two groups of rats were injected with lithium chloride intraperitoneally, twice daily at 09:00 and 16:00 h, for 2 and 7 days at a dosage of 2.5 meg/Kg body weight. Plasma and pituitary levels of LH, FSH and PRL were measured by radioimmunoassay. Plasma levels of LH were significantly (P<0.05) increased after 2 days of lithium treatment. In contrast, a significant (P<0.005) reduction in plasma levels of LH was evident when lithium injections were continued for 7 days. The plasma levels of FSH remained unaffected by lithium treatment by either time period. Lithium administered for 2 days did not bring about any significant alteration in the plasma levels of PRL, although there was a significant (P<0.002) reduction in plasma PRL levels after 7 days treatment. The concentrations of pituitary LH, FSH and PRL remained unchanged after 2 and 7 days of lithium treatment.     

Culture of human pituitary prolactin and growth hormone cells

Summary Fragments of pituitary tissue obtained from a total of 37 patients with either breast cancer, diabetic retinopathy, galactorrhea, or acromegaly were dissociated into single cell suspensions prior to cell culture. Release of human growth hormone (hGH) and human prolactin (hPRL) into the culture medium was measured by radioimmunoassay. During a 3-week culture period, prolactin cells released 9–13 times the intracellular levels of hPRL at the time of seeding, whereas hGH release from growth hormone cells was only 1–2 times that of their initial intracellular level during this same time. Both growth hormone and prolactin cells retained distinctive ultrastructural features during culture. The prolactin cells responded to TRH stimulation by elevated release of PRL into the medium. No evidence for mitotic division of prolactin cells in vitro was found.This work was supported by NCI Contract NO 1-CB-23863     

Occurrence of a new melanocyte stimulating hormone in the salmon pituitary gland

A new melanocyte stimulating hormone has been identified in the pituitary of the teleost, $\text{Oncorhynchus keta}$ (chum salmon). The newly isolated MSH like peptide is a heptadeca peptide, which differs in size from salmon α-MSH (13 residues) and β-MSH I and II (17 residues each). The structural determination, however, revealed that it is similar to but distinct form α-MSH, with following amino acid sequence, Ac-Ser-Tyr-Ser-Met-Glu-His-Phe-Arg-Trp-Gly-Lys-Pro-Ile-Gly-His-OH. This peptide, named α-MSH II is the third line of evidence in the salmon that the teleost pituitary gland secretes two different forms of processed hormones, for which the precursor molecules are coded on two separate genes.     

Characterization of pituitary IGF-I receptors: modulation of prolactin and growth hormone

There have been no studies in any vertebrate that have localized insulin-like growth factor (IGF)-I receptors in prolactin (PRL) cells or that have correlated pituitary binding to the potency of IGF-I in regulating both PRL and growth hormone (GH) secretion. We show that IGF-I binds with high affinity and specificity to the pituitary gland of hybrid striped bass (Morone saxatilis x M. chrysops). IGF-I and IGF-II were equipotent in inhibiting saturable (125)I-IGF-I binding, whereas insulin was ineffective. IGF-I binds with similar affinity to the rostral pars distalis (>95% PRL cells) as the whole pituitary gland and immunohistochemistry colocalizes IGF-I receptors and PRL in this same region. Des(1-3)IGF-I, a truncated analog of IGF-I that binds with high affinity to IGF-I receptors but weakly to IGF-I binding proteins (IGFBPs), showed a similar inhibition of saturable (125)I-IGF-I binding, but it was more potent than IGF-I in stimulating PRL and inhibiting GH release. These results are the first to localize IGF-I receptors to PRL cells, correlate IGF-I binding to its efficacy in regulating GH and PRL secretion, as well as demonstrate that IGFBPs may play a significant role in modulating the disparate actions of IGF-I on PRL and GH secretion.     

Immunocytochemical localisation of prolactin and growth hormone in the ovine pituitary

Summary Using the peroxidase-antiperoxidase immunocytochemical staining technique, prolactin and growth hormone cells have been identified and described in the ovine pituitary. The image analysing computer, Quantimet 720, was used to assess accurately the size range of the secretory granules in these cell types. The area size distributions of the prolactin and growth hormone granules are similar. An increased proportion of larger granules was observed in the prolactin cells post-partum. Serial sections stained alternately for prolactin or growth hormone confirmed that the cells contain either prolactin or growth hormone but not both.     

Evidence for a stimulating factor of prolactin and growth hormone secretion present in brewery draff

Aquous extracts of brewery draff injected intravenously into ewes and cows induced prolactin and growth hormone (GH) secretion. The same draff added to the feed of cows appeared to be unable to significantly stimulate the blood level of prolactin and GH. In these experimental conditions, milk production was not enhanced by draff. Pure beta-glucan extracted from barley also stimulated hormone secretion when administered by the intravenous route. Barley, bier and draff therefore contain a beta-glucan-like factor which stimulates lactogenic hormone secretion. The amount present in draff is probably unable to cause an increase in hormones when administered orally. Hence, the well-established stimulatory effect of draff on milk production results from their nutritive value rather than from their ability of modulating the endocrine system.     

Ultrastructural localization of prolactin,growth hormone and luteinizing hormone by immunocytochemical techniques in the bovine pituitary

Summary The technique of ultrastructural immunocytochemistry involving the unlabeled antibody and the soluble peroxidase-antiperoxidase complex was used to identify and describe the prolactin (P) cells, somatotropic (STH) cells and luteinizing hormone (LH) cells in the bovine anterior pituitary gland. This method was used to localize the three hormones at the electron microscopic level. Staining of varying intensity was found on the secretory granules and on the small granules and vesicles within the Golgi complex. No stain was found in nuclei, on mitochondria or in the endoplasmic reticulum.     

Immunocytochemical localisation of prolactin and growth hormone in the perinatal sheep pituitary

Summary The peroxidase anti-peroxidase immunocytochemical staining technique has been used to identify prolactin and growth hormone cells in pituitaries from fetal and neonatal sheep. The size of the secretory granules in these cell types has been measured using the image analysing computer Quantimet 720. The area size distributions of the fetal prolactin and growth hormone granules were compared with those in the neonate and the adult. It appears that the gestational age of the fetus may influence the size range of prolactin secretory granules.     

Developmental expression of growth hormone and prolactin genes in the bovine pituitary

Cell-free translation was used to initially characterize the major mRNA species present in the bovine anterior pituitary as a function of development. The only detectable change in translation products, which occurred during the transition from fetus to adult, was a reversal in the relative ratio of pituitary growth hormone and prolactin. Subsequent hybridization analysis with cloned growth hormone and prolactin cDNA probes indicated that growth hormone mRNA comprised over 40% of the total fetal mRNA and was 50- to 100-fold higher than prolactin mRNA. The steady state levels of growth hormone mRNA remained relatively constant throughout gestation. In contrast, prolactin mRNA levels, which were low early in gestation, increased during development to become the principal mRNA in the adult pituitary. Since growth hormone and prolactin are synthesized and secreted by specialized cells (somatotrophs and mammotrophs, respectively) immunochemical staining was used to determine whether the changes in the mRNA levels for these two hormones were a reflection of specific cell proliferation. For growth hormone, there was a close correlation between the number of somatotrophs and the relative levels of growth hormone mRNA. In contrast, the increase in prolactin mRNA exceeded the increase in the number of mammotrophs. Thus, the cellular concentration of growth hormone mRNA remains relatively constant during development, while the cellular concentration of prolactin mRNA increases by more than an order of magnitude.     

Ultrastructural immunocytochemical localization of prolactin and growth hormone in the porcine pituitary

Summary The immunocytochemical peroxidase-antiperoxidase technique was used to identify prolactin- and growth hormone-producing cells in the porcine pituitary at the ultrastructural level. The growth hormone-producing cells contain round secretory granules (300 nm to 500 nm in diameter). The prolactin-producing cells can be identified by their distinct round and ovoid secretory granules which vary in size. Most of these cells contain large granules (450 nm to 750 nm in diameter), but some prolactin-producing cells display smaller secretory granules (250 nm to 500 nm). The two hormones were localized exclusively in the secretory granules. Staining for prolactin was observed in round and ovoid granules, as well as in small and polymorphic granules within the Golgi complex. This study confirmed (i) that the two hormones are located in different cells, and (ii) that under normal physiological conditions no one cell can synthesize and store both hormones simultaneously.     

Nanism with short limbs, dysmorphism, renal dysplasia, growth hormone deficiency with pituitary hypoplasia and psychomotor delay: a new syndrome?

The authors present the case of a male infant affected with short limbed dwarfism already detected in utero by ultrasound. In addition, facial dysmorphism, bilateral hypoplasia and dysplasia of the kidneys with altered renal function, hypotonia and non-evolutive developmental delay are noted. Endocrine tests show a severe and isolated growth hormone deficiency. Metabolic investigations are negative, including peroxisomal functions. Prometaphase chromosomes are normal. Bone x-rays reveal generalized osteoporosis with absence of post-natal osseous maturation and the presence of wormian bones. Major pituitary hypoplasia is demonstrated by nuclear magnetic resonance. The present observation is compared to the case reported by Stratton & Parker (Am. J. Med. Genet., 1989, 32, 169-173). Available data do not allow either to affirm or to exclude the identity of the syndromes presented by these 2 isolated cases.     

Monomeric pituitary growth hormone and prolactin variants in man characterized by immunoperoxidase electrophoresis

Immunoperoxidase electrophoresis, combining SDS--ME--PAGE and the 'double bridge' immunoperoxidase staining was applied to crude human pituitary homogenates. With anti-hGH and anti-hPL sera, 4 hGH-related monomers were characterized: a Mr 22 000 peptide corresponding to hGH; a Mr 20 000 peptide corresponding to the known hGH variant and two unknown hGH variants (Mr 65 000 and Mr 75 000). With anti-ovine, rat and human PRL sera, 4 PRL-related monomers were immunostained: one comigrated with purified hPRL (Mr 25 000), and 3 were unknown (Mr 29 000; Mr 45 000; Mr 16 000).     

Localization of cells producing thyroid stimulating hormone in the pituitary gland of the domestic drake

Summary Cells binding anti-bovine TSH serum were found exclusively in the rostral lobe of the adenohypophysis of the drake using the peroxidase-antiperoxidase complex unlabelled antibody method. The specificity of the binding of the anti-serum to TSH cells was established by relating the morphology and relative abundance of immunochemically stained cells to the TSH content of the adenohypophysis after experimentally altering the activity of the pituitary-thyroid axis. The TSH activity of the adenohypophysis was assessed indirectly, by the weight of the thyroid glands, and directly, by bioassay. As determined by bioassay, the TSH content of the rostral lobe of the adenohypohysis was much greater than that of the caudal lobe. Compared with control drakes, immunochemically stained cells in birds fed a goitrogen, methimazole, seemed to be enlarged and were closer together, while the stained cells in drakes injected with thyroxine were shrunken and less intensely stained. The TSH content of the adenohypophysis was increased in drakes fed methimazole. Castration did not alter the TSH content of the adenohypophysis or change the morphology of immunochemically stained cells. These observations suggest that in the drake: 1) anti-bovine TSH serum binds specifically to TSH cells; 2) the TSH cells occur in the rostral and not in the caudal lobe of the adenohypophysis; and 3) the activity of TSH cells is not inhibited by the feedback effects of gonadal steroids.We thank Dr. L.E. Reichert Jr. and the National Institute of Arthritis, Metabolic and Digestive Diseases for the gift of ovine TSH and Mr. R. Wilkie for technical assistance. We are grateful to Dr. M.F. El Etreby, Professor B.K. Follett, Dr. C.G. Scanes, Dr. J. Seth and Dr. J.G. Pierce for gifts of immunochemicals     

Cell cycle distributions, growth characteristics, and variation in prolactin and growth hormone production in cultured rat pituitary cells.

Clonal strains of rat pituitary tumour cells (GH3 cells) spontaneously produce and secrete prolactin and growth hormone. Chromosome analysis and DNA ploidy measurements revealed that the GH3 cells in the present study were triploid and had a decreased chromosome number compared to the parent strain. Monolayer cultures of these cells grow exponentially for 6-7 days with a mean doubling time of 54 h. Cell cycle distributions and phase durations were determined by micro-flow fluorometric measurements of cellular DNA content combined with computer calculations. During exponential growth the cell cycle distribution did not change (65.4% cells with a G1 phase DNA content, 24.9% with an S phase DNA content, and 9.7% with a (G2 + M) phase DNA content). Counting of mitoses gave 1.4% cells in M phase. The 3H-Tdr labeling indices were determined by autoradiography, and the results were in good agreement with the number of cells in S phase as calculated by micro-flow fluorometry. The phase durations were: Ts=15.9 h, TG2=6.2 h, TM=1.1 h, and TG1=30.9 h. TS and TM calculated from 3H-Tdr labeled and Colcemid treated cultures gave corresponding results. In plateau phase cultures the number of cells with a G1 DNA content increased to 80% and the number of cells with an S phase DNA content decreased to between 5% and 10%. The specific production of prolactin and growth hormone determined by radioimmunoassay showed two and four-fold increases respectively, during exponential growth. The hormone values decreased to initial or subinitial values (day 2 values) when approaching plateau phase. We conclude: that changes in the cell cycle distribution of the cell population cannot be responsible for the spontaneous alterations in hormone production during growth and that most of the hormone-producing cells must be in the G1 phase.