Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P61278 (somatostatin)
 22,083 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Transforming growth factor alpha (TGF alpha) evokes diverse responses in transgenic mouse tissues in which it is over-expressed, including the gastric mucosa, which experiences aberrant growth and a coincident repression of hydrochloric acid production. Here we show that ectopically expressed TGF alpha induces an age-dependent cellular reorganization of the transgenic stomach, in which the surface mucous cell population in the gastric pit is greatly expanded at the expense of cells in the glandular base. Immunohistochemical analysis of BrdU incorporation into DNA demonstrated that although mature surface mucous cells were not proliferating, DNA synthesis was enhanced by approximately 67% in the glandular base and isthmus, where progenitor cells reside. RNA blot and in situ hybridization were employed to determine temporal and spatial expression patterns of specific markers representing a variety of exocrine and endocrine gastric cell types. Mature parietal and chief cells were specifically depleted from the glandular mucosa, as judged by a 6- to 7-fold decrease in the expression of genes encoding H+,K(+)-ATPase, which is required for acid secretion, and pepsinogen C, respectively. The reduction of these markers coincided in time with the activation of TGF alpha transgene expression in the neonatal stomach. The rate of cell death in the glandular region was not overtly different. Significantly, the loss of parietal and chief cells occurred without a concomitant loss of their respective cellular precursors. In contrast to exocrine cells, D and G endocrine cells were much less severely affected, based on analysis of somatostatin and gastrin expression. Analysis of these dynamic changes indicates that TGF alpha can induce selective alterations in terminal differentiation and proliferation in the gastric mucosa, and suggests that TGF alpha plays an important physiological role in the normal regulation of epithelial cell renewal.
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PMID:Transforming growth factor alpha disrupts the normal program of cellular differentiation in the gastric mucosa of transgenic mice. 786 96

Transforming growth factor alpha (TGF alpha) stimulates DNA synthesis in adult rat hepatocytes, and plays a physiological role after partial hepatectomy by an autocrine mechanism. Somatostatin (SS-14) is a potent inhibitor of gastrointestinal function and inhibits proliferation in various cell types. We examined the proliferative effect of TGF alpha and the inhibitory effect of SS-14 on hepatocytes isolated at various times after partial hepatectomy. To study the mechanism of SS-14 further, we treated rats with the long acting SS-14 analog, octreotide, before or after 70% hepatectomy to determine whether or not a differential effect could be seen. We confirmed the proliferative effects of TGF alpha, and the inhibitory action of SS-14 in the early phase of liver regeneration in vitro. Regenerating hepatocytes isolated from hepatectomized livers respond to TGF alpha only at early time points (2 h) but do not respond to SS-14. In addition, the long acting SS-14 analog, octreotide, inhibited hepatic regeneration only when administered prior to hepatectomy. We conclude that exogenous peptide stimulation is effective only in the early phase of the hepatic proliferative response. After the initial changes brought about by hepatectomy, subsequent steps of the regenerative process appear refractory to external stimuli.
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PMID:The effects of transforming growth factor alpha and somatostatin on regenerating hepatocytes in the rat. 809 89

The stimulus-secretion coupling of the insulin-producing pancreatic islet beta cell is subject to functional maturation during fetal life. We studied the maturation of a glucose-responsive insulin release from fetal rat islets and specifically investigated the impact of peptidergic regulation. To this end, islets were isolated from 21-day-old fetal rats and maintained for 7 days in tissue culture at 3.3 or 11.1 mM glucose and various supplements. In islets cultured in low glucose, acutely raising the ambient glucose concentration to 16.7 mM evoked a modest stimulation of short-term insulin release that was more pronounced in islets maintained in high glucose. Moreover, the insulin content was much higher in islets cultured in high than in low glucose. Culture with growth hormone (GH) markedly amplified both basal and stimulated short-term insulin secretion from islets maintained in either low or high glucose. Additionally, GH significantly elevated the insulin content in islets maintained in low glucose. Transforming growth factor alpha (TGF-alpha) increased basal, but not glucose-stimulated, insulin release and insulin content in islets cultured in low glucose. Gastrin, expressed in islets during fetal life, did not affect basal or glucose-stimulated insulin release, or insulin content, in islets maintained in either low or high glucose. The addition of gastrin to TGF-alpha did not affect the results obtained with the latter peptide. Gastrin-releasing peptide failed to influence basal or glucose-responsive insulin secretory rates, and insulin content, at either glucose concentration during culture. The somatostatin analog Sandostatin (octreotide acetate) neither influenced basal nor stimulated short-term insulin release at any glucose concentration present during culture, whereas the hormone significantly decreased the insulin content of islets cultured in high glucose. Pancreastatin, produced by porcine islet beta and delta cells, failed to influence basal or glucose-responsive insulin secretory rates, and islet insulin content, at either glucose concentration during culture. Culture with gastric inhibitory peptide (GIP) or glucagon-like peptide I (GLP-1), two proposed incretins, did not affect short-term insulin secretion in response to 3.3 or 16.7 mM glucose irrespective of the ambient glucose concentration during culture. To the contrary, GLP-1, but not GIP, increased the content of insulin in islets cultured in low glucose. We conclude that islet beta-cell differentiation and functional maturation of the stimulus-secretion coupling can be modulated in vitro in fetal rat pancreatic tissue by peptidergic regulation and glycemic stimulation. We suggest that GH and TGF-alpha stimulate, while somatostatin, through paracrine interaction, may inhibit, these processes. These effectors may be of regulatory significance in the in vivo development of glucose-sensitive beta cells, and defects in these mechanisms may result in glucose intolerance in adult subjects.
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PMID:Peptidergic regulation of maturation of the stimulus-secretion coupling in fetal islet beta cells. 1076 55