UNIPROT:P61278 - FACTA Search

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Query: UNIPROT:P61278 (somatostatin)
22,083 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Regulation of GH gene expression by GRF involves cAMP as a second messenger. We have demonstrated that a 500-basepair fragment of the human GH (hGH) gene 5' flanking region can confer cAMP inducibility upon the chloramphenicol acetyltransferase transcription unit in transient transfections of rat pituitary tumor cells treated with forskolin, an activator of adenyl cyclase. The same hGH construct is not induced by forskolin in nonpituitary-derived cells. Experiments with hGH deletion constructs reveal that binding sites for transcription factor AP-2 and the pituitary-specific factor GHF-1 are not required for forskolin stimulation, but that GHF-1 may potentiate the effect. RNA analyses reveal that forskolin also stimulates accumulation of transcripts initiated at the hGH promoter. Other agents that elevate cAMP levels also stimulate hGH expression. Since the hGH 5' flanking region contains no sequences homologous to the cAMP-responsive element of the somatostatin gene, and the AP-2 sites do not appear to be required for the forskolin response, these results suggest that a novel cAMP-responsive element exists within 82 basepairs upstream from the transcriptional start of the hGH gene and that hGH regulation by GRF may involve interaction between a tissue-specific element and a cAMP-inducible element.
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PMID:Induction of human growth hormone promoter activity by the adenosine 3',5'-monophosphate pathway involves a novel responsive element. 254 55

The pathophysiology of mammosomatotroph adenomas remains unclear. We studied a mammosomatotroph adenoma removed from an 8-year old boy with a 5-year history of growth acceleration and acromegalic gigantism at presentation. Elevated basal GH (mean 28 micrograms/l) and PRL (mean 120 micrograms/l) plasma levels were observed, as well as paradoxical responses of GH to L-dopa, TRH and oral glucose administration; PRL was reduced by L-dopa and slightly increased by TRH; GHRH stimulated release of both GH and PRL. Two operations were required to remove the very large tumour and the patient was treated with bromocriptine before the second. Hormonal secretion by tumour explants in culture was evaluated under basal conditions and after stimulation or inhibition. High levels of GH and PRL were secreted for up to 24 days. Furthermore, GHRH and TRH caused a dose-related stimulation of both hormones, while somatostatin and dopamine were effective in suppressing either basal or stimulated hormone release only at very high (microM) concentrations. Intracellular events were studied by determination of the guanosine triphosphate binding (G) protein levels and adenylate cyclase (AC) activity in the tumour tissue. Before bromocriptine treatment, AC activity was very high in the tumour and could be further stimulated by various agents; very high levels of the AC-stimulatory G protein alpha subunit Gs alpha and very low amounts of the AC-inhibiting G protein alpha subunit Gi3 alpha and of the phospholipase C-stimulating G protein alpha subunit Gq alpha were found in the tumour. After bromocriptine, baseline AC activity was normalized and could no longer be stimulated; Gs alpha and Gi3 alpha levels were unchanged while those of Gq alpha were normalized. Screening of tumour DNA after amplification by polymerase chain reaction followed by single-strand conformational polymorphism analysis did not reveal any mutations in the hot spots of G protein alpha subunits (alpha s, alpha i2, alpha o2 and alpha 11) genes or in the H-ras and p53 genes. Gs alpha and GH transcription factor-1 (pit-1) expression were evaluated by amplification of cDNA. While the mRNA expression of pit-1 decreased after bromocriptine treatment, that of Gs alpha increased. These data suggest the possibility of an oncogenic process involving overexpression of Gs alpha, resulting in chronic activation of adenylate cyclase. Furthermore, our results suggest that the anti-secretory and anti-proliferative effects of bromocriptine may be mediated through a decrease in Pit-1 secondary to the inhibition of adenylate cyclase activity.
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PMID:Mammosomatotroph adenoma causing gigantism in an 8-year old boy: a possible pathogenetic mechanism. 762 75

The molecular characterization of GHRH and the GHRH receptor provides a framework for understanding the hypothalamic regulation of pituitary somatotroph function. The signaling events discerned from our investigation of GHRH receptor structure and function form the basis of a model for GHRH action, which is shown in Fig. 20. GHRH interaction with its seven transmembrane domain Gs-coupled receptor on the somatotroph (step 1) leads to the release of growth hormone from secretory granules (step 2), which is likely to involve a G protein-mediated interaction with ion channels, and to a stimulation of intracellular cAMP accumulation (step 3) (Mayo, 1992; Lin et al., 1992; Gaylinn et al., 1993). In several cell types tested, elevated cAMP leads to the phosphorylation and activation of the transcription factor CREB by protein kinase A (Gonzalez and Montminy, 1989; Sheng et al., 1991), and one target gene for CREB action is the pituitary-specific transcription factor Pit-1 or GHF-1 (step 4) (Bodner et al., 1988; Ingraham et al., 1988; McCormick et al., 1990). Pit-1 is a prototypic POU domain protein that is required for the appropriate regulation of the growth hormone gene in somatotroph cells, thus providing a pathway by which a GHRH signal can lead to increased growth hormone synthesis in the pituitary (step 5). In addition, Pit-1 is likely to directly regulate the synthesis of the GHRH receptor (step 6), in that the receptor is not expressed in the pituitary of dw/dw mice that lack functional Pit-1 (Lin et al., 1992), and a cotransfected Pit-1 expression construct can activate the GHRH receptor promoter in transiently transfected CV1 cells (Lin et al., 1993). It remains to be determined whether additional direct regulation of the GHRH receptor gene in response to the cAMP signaling pathway occurs (step 7). The inhibitory peptide somatostatin presumably interacts with this same signaling pathway through G protein-mediated suppression of the cAMP pathway (Tallent and Reisine, 1992; Bell and Reisine, 1993). In agreement with the importance of this signaling system for normal growth, a transgene encoding a nonphosphorylatable mutant CREB protein, which blocks the function of the endogenous CREB protein, is able to cause somatotroph hypoplasia and dwarfism in mice when its expression is targeted to pituitary somatotrophs (Struthers et al., 1991). Several steps in the signaling pathway leading to growth hormone secretion are subject to disruption, resulting in growth hormone deficiency.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Growth hormone-releasing hormone: synthesis and signaling. 774 Jan 67

Human growth hormone (hGH) is a single chain, 22 kd-protein with two intramolecular disulfide bonds. The hGH gene is located on chromosome 17 at band q22-q24 and has four introns separating five coding exons. The expression of hGH is restricted to the pituitary and regulated by GHF-1 which binds to the hGH promoter acting in concert with several other more ubiquitous DNA binding proteins. The secretion of hGH is regulated by GH releasing hormone (GRH) and somatostatin. GRH controls GH synthesis by stimulating transcription of GH mRNA while somatostatin determines the timing and amplitude of GH pulses. Pulsatile GH secretion is influenced by a number of neurogenic, metabolic and hormonal factors.
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PMID:[Synthesis and regulation of growth hormone secretion]. 790 78

Somatostatin receptor (SSTR) subtype genes are differentially expressed in brain and various peripheral tissues. RNA blotting and semiquantitative PCR analyses have revealed low levels of SSTR1 mRNA in the gastrointestinal tract and relatively high levels in GH3 anterior pituitary cells. As a first step in the investigation of the regulation of SSTR1 gene expression, we isolated a genomic fragment that contains the promoter region and determined the transcriptional initiation site. The SSTR1 gene lacks introns and TATA and CAAT motifs, but possesses several consensus recognition sequences for the transcription factors GCF and AP-2. The presence, also, of two Pit-1 binding sites could explain the high SSTR1 mRNA levels in GH3 cells.
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PMID:Sequence analysis of the promoter region of the rat somatostatin receptor subtype 1 gene. 806 Mar 91

Much knowledge was accumulated in the regulation of plasma renin activity and renin secretion during recent years. However, the mechanisms of renin gene transcription, especially for the human gene, have been poorly studied because of the lack of cell lines expressing renin. Cells derived from chorion tissue were used to study renin gene transcription because these cells express renin and regulate renin secretion in a similar way to JG cells. The present study was performed to determine the cis-regulatory elements and the trans-acting factors involved in human renin gene expression using chorionic cells. Transient DNA transfections were performed with various constructs containing the 5'-flanking region of the human renin gene. 5'-Deletion analysis of the human renin promoter (from -2616 to -67 bp) revealed the presence of two proximal negative cis-regulatory elements between -374 and -273 bp and between -273 and -137 bp. These elements were not present in a non-renin-producing cell line, JEG-3 cells. DNase I footprinting revealed that two sequences located within these regions bind trans-factors present in chorionic cellular nuclear extract: AGE3-like sequence (-293/-273) and apolipoprotein A1 regulatory protein-1-like sequence (-259/-245). The first 110 bp of the renin promoter were sufficient to direct specific expression in chorionic cells and contained two footprints sharing homology with ets (-29/-6) and pituitary-specific factor (Pit-1) (-70/-62) sequences. Furthermore, one footprint (-234/-214) contained the sequence TAGCGTCA, which shares strong homology to the cAMP-responsive element (CRE) binding site. Gel shift analysis showed specific DNA/protein complexes within this region, which were displaced by the somatostatin consensus CRE. Finally, luciferase analysis of 5'-deletion mutant revealed that -273 to +16 bp of the renin promoter was sufficient to confer complete forskolin stimulation, whereas deletion to -130 (deletion of the CRE) decreased cAMP responsiveness by 50% and those to -67 bp (deletion of the CRE and Pit-1-like sequences) suppressed it. Thus, these latter two sequences probably act together to confer complete cAMP responsiveness.
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PMID:cis-regulatory elements and trans-acting factors directing basal and cAMP-stimulated human renin gene expression in chorionic cells. 815 25

Pituitary transcription factor-1 (Pit-1 or GHF-1) is a transcription factor specific to the anterior pituitary and is involved in the expression and regulation of the growth hormone (GH), prolactin (PRL) and thyroid-stimulating hormone (TSH) beta-subunit genes. The expression of these three genes can be modulated by changes in the hormone environment and it is thought that some of these effects are mediated through Pit-1, but little is known about the physiological regulation of this transcription factor. Therefore, we first asked whether Pit-1 gene expression is modified as a result of changes in the in vivo gonadal steroid environment and if this could be correlated with changes in GH and/or PRL mRNA levels. Secondly, we sought to determine if sex steroids affect the mRNA levels of these three peptides by acting at the level of the pituitary and whether these effects are androgen or estrogen mediated. Finally, how sex steroids modulate the response of these three genes to the hypothalamic neuropeptides growth hormone-releasing hormone (GHRH) and somatostatin (SS) was analyzed. To this end, we compared Pit-1, GH and PRL mRNA levels in the anterior pituitary of intact, castrated, and castrated testosterone-replaced adult male rats. In addition, primary cultures of adult male pituitaries were used to study the direct effects of both androgens and estrogens on Pit-1, GH, and PRL mRNA levels. In situ hybridization histochemistry was used to compare relative levels of Pit-1, GH and PRL mRNA. Densitometric analysis of the in vivo studies showed that castration resulted in a 57, 40 and 55% decline in Pit-1, GH and PRL mRNA signal levels, respectively. Furthermore, replacement with testosterone (T) at the time of castration completely prevented the decline in all three mRNA species (ANOVA: Pit-1 mRNA, p < 0.0001; GH mRNA, p < 0.0001; PRL mRNA, p < 0.0001). In vivo, both T (10(-7) M) and estradiol (10(-9) M) were capable of stimulating Pit-1 mRNA and PRL mRNA levels, while dihydrotestosterone (DHT; 10(-7) M) had no effect. There was no effect of any of these steroid treatments on GH mRNA levels in vitro. Addition of GHRH to the cultures increased GH mRNA levels, as well as those of Pit-1 and PRL, and SS had the opposite effect on GH mRNA levels. Whereas the GH response to GHRH was not significantly modified by exposure to sex steroids, the effect of SS was. The presence of sex steroids was capable of modifying the Pit-1 and PRL responses to both GHRH and SS. These results clearly indicate that changes in circulating levels of sex steroids modulate the expression of Pit-1 in the anterior pituitary and that these changes can be correlated with commensurate modifications in GH and PRL mRNA levels. Furthermore, the effect on both Pit-1 and PRL mRNA levels occurs, at least in part, at the level of the anterior pituitary and is an estrogen-receptor-mediated event. In contrast, the effects of gonadal steroids on GH mRNA levels are less direct and are most likely mediated at the level of the hypothalamus, as well as through modulation of the response of the somatotroph to hypothalamic factors. We conclude that the transcription factor Pit-1 is actively regulated physiologically and may be involved in mediating some of the effects of sex steroids and hypothalamic factors on the synthesis of certain anterior pituitary hormones.
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PMID:In vivo and in vitro regulation of pituitary transcription factor-1 (Pit-1) by changes in the hormone environment. 883 50

Activation of the cAMP pathway from the cell surface to the nucleus plays a major role in somatotroph differentiation and growth. This pathway is regulated mainly by the antagonistic hypothalamic hormones GHRH and somatostatin. Several pituitary-specific, as well as ubiquitous, expressed genes are regulated by cAMP in GH-secreting cells. Among them are the GH, GHF-1/Pit-1, c-fos and GHRH-receptor genes. Protein kinase A phosphorylation of Ser 133 of the transcription factor cAMP-responsive element binding protein (CREB), seems to play a pivotal role in the activation of the cAMP pathway in normal and tumoral somatotrophs. The oncogenic activating mutations of the G-protein as subunit stimulate transcription and CREB phosphorylation in somatotroph cells. The implications of the nuclear targets of cAMP in the differentiation and growth of somatotrophs are discussed in this review.
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PMID:Nuclear effects of the cAMP pathway activation in somatotrophs. 916 59

Several transactivating factors specifically involved in the differentiation and proliferation of anterior pituitary cell types have been recently identified. Among them Pit-1 a member of the POU-domain transcription factors family is specific of anterior pituitary cells, and was initially identified and cloned as a transactivator of the GH and PRL genes and as a regulator of the TSH beta gene. Pit-1 play a key role during embryogenesis in the differentiation and proliferation of somatotrophs, lactotrophs and thyreotrophs. The importance of Pit-1 as a regulator in the anterior pituitary development has been further demonstrated by naturally occurring mutations or delections in dwarf mouse strains. In the Snell and Jackson dwarf mice, the levels of Pit-1 gene expression are low or undetectable, GH, PRL and TSH beta gene expression are absent and lactotrophs, somatotrophs, and threotrophs fail to proliferate. Furthermore Pit-1 carries out similar functions in humans. This is supported by the fact that children with mutations of the Pit-1 gene present with a congenital combined GH, PRL and TSH deficiency analogous to the phenotype of the Snell and Jackson dwarf mice. In children who were born to healthy consanguinous parents and present such combined deficiencies we recently reported a Pit-1 mutation causing a transition from a Phe to a Cys in a region of the protein known to be involved in DNA binding. Pit-1 transcripts identical in size and sequence to those observed in normal pituitary were described in human GH, PRL and TSH secreting pituitary adenomas. The Pit-1 beta isoform, raised through alternative splicing of exon 2 of the Pit-1 gene, is a more potent inducer of GH transcription than the major Pit-1 form. However no difference in the level of expression of the different Pit-1 isoforms was observed between tumors identified as pure GH or PRL producing tumors. The results support the existence of other transcription factors interacting with Pit-1 to coordinately regulate the activity of the GH and PRL promotors in a cell specific manner. In contrast, variable Pit-1 expression was observed in prolactinomas, according to their sensitivity to bromocriptine treatment. A highly significant correlation was indeed evidenced between the D2 receptors mRNA and the Pit-1 mRNA levels. These results raise the possibility that Pit-1 may either directly or indirectly affect the transcription of the D2 dopaminergic receptor gene. In fact, receptors for other hypothalamic neurohormones such a GHRH and somatostatin are known to be potential Pit-1 target genes. Such mechanisms could be implicated in the differentiation and proliferation of lactotrophs and somatotrophs.
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PMID:[Homeoproteins and pituitary adenoma]. 920 61

Somatostatin and its receptors are widely distributed in the central nervous system and peripheral tissues including those of the gastrointestinal tract (GI tract). The expression patterns of the five known SSTR genes have been analysed in detail by reverse transcription polymerase chain reaction amplifications and in situ hybridizations using tissues dissected from different parts of rat stomach and gut. While SSTR1 mRNA is present at relatively high amounts throughout the gastrointestinal tract, the levels of SSTR2, 3 and 4 mRNAs vary in different regions and SSTR5 mRNA has not been detected. In situ hybridizations revealed the presence of SSTR3 mRNA in enterocytes and in neurons of the myenteric and submucous plexus. These findings are consistent with a role of SSTR3 in the observed somatostatin-mediated inhibition of acetylcholine release from myenteric neurons and of secretomotor neuron activity in the submucous plexus. Sequence analyses of the SSTR1 gene promoter revealed the absence of the canonical TATA and CAAT motifs and the presence of a variety of potential binding sites for transcriptional regulators. Among these are binding sites for GCF, AP-2, AP-4, response elements for somatostatin (SOM-RE), epidermal growth factor (EGF-RE) and cytocines (GAS and NFIL) as well as for tissue-specific factors such as Pit-1 (pituitary) and IDX-1 (pancreatic cells). Mobility shift assays have confirmed that nuclear proteins of pancreatic RIN1046-38 and pituitary GH3 tumour cells bind to oligonucleotides containing the overlapping Pit-1 and IDX-1 binding sites. Thus, the Pit-1/IDX-1 sites may be critical for the activation of the SSTR1 gene in these cell-types.
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PMID:Localization of somatostatin receptor subtype mRNA in the rat gastrointestinal tract and regulation of SSTR1 gene expression. 955 32

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