Somatostatins and their receptors in fish

Somatostatin (SRIF) is a multigene family of peptides. SRIF-14 is conserved with identical primary structure in species across the vertebrates. The presence of multiple SRIF genes has been demonstrated in a number of fish species. Notably, three distinct SRIF genes have been identified in goldfish. One of these genes, which encodes [Pro(2)]SRIF-14, has also been identified in sturgeon and African lungfish, and is closely associated with the amphibian [Pro(2),Met(13)]SRIF-14 gene and mammalian cortistatin gene. The main neuroendocrine role of SRIF-14 peptide that has been determined in fish is the inhibition of pituitary growth hormone secretion. The functions of SRIF-14 variant or larger forms of SRIF peptide and the regulation of SRIF gene expression remain to be explored. Type one and two SRIF receptors have been identified from goldfish and type three SRIF receptor from an electric fish. Fish SRIF receptors display considerable homology to mammalian counterparts in terms of primary structure and negative coupling to adenylate cyclase. The identification of the multiple gene family of SRIF peptides and multiple types of SRIF receptors in fish opens a new avenue for the study of physiological roles of SRIF, and the molecular and cellular mechanisms of SRIF actions in fish.     

Somatostatin receptors in brain and pituitary

Somatostatin (SRIF) actions in the brain and pituitary are mediated by specific receptors. Using radioiodinated ligands it has been possible to characterize the kinetics of specific binding sites in the brain and pituitary, and to determine their cellular localization by autoradiography. At the pituitary level, the inhibition of growth hormone, prolactin and thyrotropin secretions induced by SRIF is mediated through a single binding site which is coupled to the inhibition of adenylate cyclase. In the brain, SRIF receptors are localized on neurons and glial cells and are also coupled to adenylate cyclase inhibition. Two sites are differentiated in the brain with an analogue of somatostatin, SMS 201995. In humans, SRIF-binding sites have been related to a number of pathologies. At the pituitary level, it has been shown that the number of binding sites was negatively correlated to growth hormone levels in acromegaly. Furthermore, SRIF-binding sites were undetectable in a patient which did not respond to SMS 201995 therapy. In the brain, meningiomas and gliomas are rich in SRIF binding sites. This suggests a possible role for SRIF on glia. In neurodegenerative diseases, cortical SRIF concentrations are decreased in Alzheimer's and Parkinson's disease associated with dementia while SRIF-binding sites are only affected in Alzheimer's disease. In conclusion, the physiological role of SRIF in the brain and pituitary can be evaluated by studying the receptors of the peptide. Such studies allow to question the implication of SRIF in endocrine and neuropathologies.     

Somatostatin receptors

In 1972, Brazeau et al. isolated somatostatin (somatotropin release-inhibiting factor, SRIF), a cyclic polypeptide with two biologically active isoforms (SRIF-14 and SRIF-28). This event prompted the successful quest for SRIF receptors. Then, nearly a quarter of a century later, it was announced that a neuropeptide, to be named cortistatin (CST), had been cloned, bearing strong resemblance to SRIF. Evidence of special CST receptors never emerged, however. CST rather competed with both SRIF isoforms for specific receptor binding. And binding to the known subtypes with affinities in the nanomolar range, it has therefore been acknowledged to be a third endogenous ligand at SRIF receptors. This review goes through mechanisms of signal transduction, pharmacology, and anatomical distribution of SRIF receptors. Structurally, SRIF receptors belong to the superfamily of G protein-coupled (GPC) receptors, sharing the characteristic seven-transmembrane-segment (STMS) topography. Years of intensive research have resulted in cloning of five receptor subtypes (sst(1)-sst(5)), one of which is represented by two splice variants (sst(2A) and sst(2B)). The individual subtypes, functionally coupled to the effectors of signal transduction, are differentially expressed throughout the mammalian organism, with corresponding differences in physiological impact. It is evident that receptor function, from a physiological point of view, cannot simply be reduced to the accumulated operations of individual receptors. Far from being isolated functional units, receptors co-operate. The total receptor apparatus of individual cell types is composed of different-ligand receptors (e.g. SRIF and non-SRIF receptors) and co-expressed receptor subtypes (e.g. sst(2) and sst(5) receptors) in characteristic proportions. In other words, levels of individual receptor subtypes are highly cell-specific and vary with the co-expression of different-ligand receptors. However, the question is how to quantify the relative contributions of individual receptor subtypes to the integration of transduced signals, ultimately the result of collective receptor activity. The generation of knock-out (KO) mice, intended as a means to define the contributions made by individual receptor subtypes, necessarily marks but an approximation. Furthermore, we must now take into account the stunning complexity of receptor co-operation indicated by the observation of receptor homo- and heterodimerisation, let alone oligomerisation. Theoretically, this phenomenon adds a novel series of functional megareceptors/super-receptors, with varied pharmacological profiles, to the catalogue of monomeric receptor subtypes isolated and cloned in the past. SRIF analogues include both peptides and non-peptides, receptor agonists and antagonists. Relatively long half lives, as compared to those of the endogenous ligands, have been paramount from the outset. Motivated by theoretical puzzles or the shortcomings of present-day diagnostics and therapy, investigators have also aimed to produce subtype-selective analogues. Several have become available.     

Analogues of Somatostatin Bind Selectively to Brain Somatostatin Receptor Subtypes

Somatostatin (SRIF) is a neurotransmitter that produces its multiple effects in the CNS through interactions with membrane-bound receptors. Subtypes of SRIF receptors are found in the CNS that are distinguished by their sensitivities to the cyclic hexapeptide MK-678, such that SRIF1 receptors are sensitive to MK-678 and SRIF2 receptors are insensitive to MK-678. In the present study, we further examined the selectivities of a series of structurally diverse SRIF analogues for SRIF receptor subtypes. SRIF receptors were labeled by 125I-Tyr11-SRIF, which has indistinguishable affinities for SRIF receptor subtypes. The inhibition by MK-678 was incomplete, indicating this peptide is highly selective for a subtype of SRIF receptor that we have termed the SRIF1 receptor. The binding of 125I-MK-678 to SRIF1 receptors was monophasically inhibited by SRIF, the octapeptides (such as SMS-201-995), and the hexapeptides (such as MK-678), consistent with the highly selective labeling of a subtype of SRIF receptor. In contrast, the smaller CGP-23996-like analogues did not inhibit 125I-MK-678 binding to SRIF1 receptors. The binding of 125I-CGP-23996 to SRIF receptors was inhibited by SRIF and the octapeptides with Hill coefficients of less than 1, indicating that 125I-CGP-23996 labels multiple SRIF receptor subtypes. The hexapeptides and CGP-23996-like compounds produced only partial inhibitions of 125I-CGP-23996 binding, which were additive, indicating selective interactions of these compounds with the different receptor subpopulations labeled by 125I-CGP-23996. 125I-Tyr11-SRIF binding and 125I-CGP-23996 binding to SRIF receptors were likewise only partially affected by 100 microM guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S), a concentration that completely abolishes specific 125I-MK-678 binding to SRIF1 receptors. The component of 125I-CGP-23996 labeling that was sensitive to GTP gamma S was also MK-678 sensitive. Thus, two subpopulations of SRIF receptors exist in the CNS. The SRIF1 receptor is sensitive to cyclic hexapeptides such as MK-678 and to GTP gamma S but insensitive to smaller CGP-23996-like compounds. The SRIF2 receptor is sensitive to the CGP-23996-like compounds and can be selectively labeled by 125I-CGP-23996 in the presence of high concentrations of the hexapeptides or GTP gamma S because, unlike the SRIF1 receptor, the SRIF2 receptor is insensitive to these agents. The SRIF receptor subtype-selective peptide analogues will be useful in the future characterization of the functions mediated by SRIF receptor subtypes in the CNS.     

Somatostatin receptors

In 1972, Brazeau et al. isolated somatostatin (somatotropin release-inhibiting factor, SRIF), a cyclic polypeptide with two biologically active isoforms (SRIF-14 and SRIF-28). This event prompted the successful quest for SRIF receptors. Then, nearly a quarter of a century later, it was announced that a neuropeptide, to be named cortistatin (CST), had been cloned, bearing strong resemblance to SRIF. Evidence of special CST receptors never emerged, however. CST rather competed with both SRIF isoforms for specific receptor binding. And binding to the known subtypes with affinities in the nanomolar range, it has therefore been acknowledged to be a third endogenous ligand at SRIF receptors.This review goes through mechanisms of signal transduction, pharmacology, and anatomical distribution of SRIF receptors. Structurally, SRIF receptors belong to the superfamily of G protein-coupled (GPC) receptors, sharing the characteristic seven-transmembrane-segment (STMS) topography. Years of intensive research have resulted in cloning of five receptor subtypes (sst₁-sst₅), one of which is represented by two splice variants (sst_2A and sst_2B). The individual subtypes, functionally coupled to the effectors of signal transduction, are differentially expressed throughout the mammalian organism, with corresponding differences in physiological impact. It is evident that receptor function, from a physiological point of view, cannot simply be reduced to the accumulated operations of individual receptors. Far from being isolated functional units, receptors co-operate. The total receptor apparatus of individual cell types is composed of different-ligand receptors (e.g. SRIF and non-SRIF receptors) and co-expressed receptor subtypes (e.g. sst₂ and sst₅ receptors) in characteristic proportions. In other words, levels of individual receptor subtypes are highly cell-specific and vary with the co-expression of different-ligand receptors. However, the question is how to quantify the relative contributions of individual receptor subtypes to the integration of transduced signals, ultimately the result of collective receptor activity. The generation of knock-out (KO) mice, intended as a means to define the contributions made by individual receptor subtypes, necessarily marks but an approximation. Furthermore, we must now take into account the stunning complexity of receptor co-operation indicated by the observation of receptor homo- and heterodimerisation, let alone oligomerisation. Theoretically, this phenomenon adds a novel series of functional megareceptors/super-receptors, with varied pharmacological profiles, to the catalogue of monomeric receptor subtypes isolated and cloned in the past. SRIF analogues include both peptides and non-peptides, receptor agonists and antagonists. Relatively long half lives, as compared to those of the endogenous ligands, have been paramount from the outset. Motivated by theoretical puzzles or the shortcomings of present-day diagnostics and therapy, investigators have also aimed to produce subtype-selective analogues. Several have become available.     

Identification of the subunits of GTP-binding proteins coupled to somatostatin receptors.

Somatostatin (SRIF) induces its biological effects by interacting with membrane-bound receptors that are linked to cellular effector systems via G proteins. We have studied SRIF receptor-G protein associations by solubilizing the SRIF receptor from rat brain and AtT-20 cells and immunoprecipitating the receptor-G protein complex with peptide-directed antisera against the different subunits of the G protein heterotrimer. Antiserum 8730, which selectively interacts with all Gi alpha subtypes, maximally and specifically immunoprecipitated SRIF receptor-Gi alpha complexes. To identify the subtypes of Gi alpha that are coupled to SRIF receptors, the subtype-selective antisera 3646, 1521, and 1518, which specifically interact with Gi alpha 1, Gi alpha 2, and Gi alpha 3, respectively, were used to immunoprecipitate SRIF receptor-Gi alpha complexes. Antiserum 3646 immunoprecipitated SRIF receptor-Gi alpha 1 complexes from both brain and AtT-20 cells. Antiserum 1521 immunoprecipitated Gi alpha 2 from both brain and AtT-20 cells but did not immunoprecipitate SRIF receptors from these tissues. Antiserum 1518 immunoprecipitated AtT-20 cell SRIF receptors but uncoupled brain SRIF receptor-G protein complexes. This result was confirmed with another peptide-selective antiserum, SQ, directed against Gi alpha 3. The findings from these studies indicate that Gi alpha 1 and Gi alpha 3 are coupled to SRIF receptors, whereas Gi alpha 2 is not. Even though brain and AtT-20 cell SRIF receptors were both coupled to Gi alpha, the receptors from these tissues differed in their coupling to Go alpha. Antiserum 2353, which is directed against Go alpha, immunoprecipitated SRIF receptors from AtT-20 cells, but did not immunoprecipitate or uncouple SRIF receptor-G protein complexes from rat brain. To determine the beta subunits associated with the SRIF receptor, antisera directed against G beta 36 and G beta 35 were used to immunoprecipitate SRIF receptor-G protein complexes from brain. Peptide-directed antiserum against G beta 36 selectively immunoprecipitated solubilized brain SRIF receptors. However, antiserum directed against the G beta 35 subunit did not immunoprecipitate brain SRIF receptors, suggesting that brain SRIF receptors may preferentially associate with G beta 36. In addition to coimmunoprecipitating with Gi alpha and G beta, brain SRIF receptors coimmunoprecipitated the G protein gamma subunits, G gamma 2 and G gamma 3. These results provide the first evidence that SRIF receptors are coupled to different subunits of G proteins and suggest that selectivity exists in the association of different G protein subunits with the SRIF receptor.     

Localization of messenger ribonucleic acids for somatostatin receptor subtypes (sstr1-5) in the rat adrenal gland.

Somatostatin (somatotropin-release inhibitory factor, SRIF) exerts multiple inhibitory actions throughout the central nervous system and the periphery by binding to specific membrane-bound SRIF receptors (sstrs) of which five subtypes (sstr1-5) have now been identified. Individual sstr subtypes have been suggested to mediate selective biological actions of SRIF. Although the adrenal gland is a known target of SRIF action, the sstr subtypes involved in its actions are unclear. This study examined the expression of sstr1-5 in rat adrenal gland by RT-PCR analysis and in situ hybridization (ISH) histochemistry. Using RT-PCR expression combined with Southern blotting, sstr1, -2, -4, and -5 mRNAs were shown in the adrenal gland. ISH histochemistry revealed strong expression of sstr2 mRNA alone localized to the zona glomerulosa of the adrenal cortex and moderate labeling in scattered cells of the adrenal medulla, indicating a possible role for sstr2 in mediating SRIF physiology in this tissue by altering adrenal aldosterone and catecholamine secretion. These data also point to potential roles for sstr subtypes sstr1, -4, and -5 in the adrenal gland.     

Differential desensitization of somatostatin receptor subtypes in atT-20 cells

Nonpeptidyl agonists for the somatostatin (SRIF) receptor family have been developed. We have studied the desensitization effects for two of these agonists upon SRIF receptor function in AtT-20 cells, a neuroendocrine tumor cell, which endogenously expresses two distinct SRIF receptor, subtypes. We observe that SRIF and the nonpeptidyl, subtype selective agonists, differentially regulate SRIF receptor subtypes in the AtT-20 cell.     

Somatostatin family of peptides and its receptors in fish

Somatostatin (SRIF or SS) is a phylogenetically ancient, multigene family of peptides. SRIF-14 is conserved with identical primary structure in species of all classes of vertebrates. The presence of multiple SRIF genes has been demonstrated in a number of fish species and could extend to tetrapods. Three distinct SRIF genes have been identified in goldfish. One of these genes, which encodes [Pro2]SRIF-14, is also present in sturgeon and African lungfish, and is closely associated with amphibian [Pro2,Met13]SRIF-14 gene and mammalian cortistatin gene. The post-translational processing of SRIF precursors could result in multiple forms of mature SRIF peptides, with differential abundance and tissue- or cell type-specific patterns. The main neuroendocrine role of SRIF-14 peptide that has been determined in fish is the inhibition of pituitary growth hormone secretion. The functions of SRIF-14 variant or larger forms of SRIF peptide and the regulation of SRIF gene expression remain to be explored. Type 1 and type 2 SRIF receptors have been identified from goldfish and a type 3 SRIF receptor has been identified from an electric fish. Fish SRIF receptors display considerable homology with mammalian counterparts in terms of primary structure and negative coupling to adenylate cyclase. Although additional types of receptors remain to be determined, identification of the multiple gene family of SRIF peptides and multiple types of SRIF receptors opens a new avenue for the study of physiological roles of SRIF, and the molecular and cellular mechanisms of SRIF action in fish.     

Somatostatin decreases voltage-gated Ca2+ currents in GH3 cells through activation of somatostatin receptor 2

The secretion of growth hormone (GH) is inhibited by hypothalamic somatostatin (SRIF) in somatotropes through five subtypes of the somatostatin receptor (SSTR1-SSTR5). We aimed to characterize the subtype(s) of SSTRs involved in the Ca2+ current reduction in GH3 somatotrope cells using specific SSTR subtype agonists. We used nystatin-perforated patch clamp to record voltage-gated Ca2+ currents, using a holding potential of -80 mV in the presence of K+ and Na+ channel blockers. We first established the presence of T-, L-, N-, and P/Q-type Ca2+ currents in GH3 cells using a variety of channel blockers (Ni+, nifedipine, omega-conotoxin GVIA, and omega-agatoxin IVA). SRIF (200 nM) reduced L- and N-type but not T- or P/Q-type currents in GH3 cells. A range of concentrations of each specific SSTR agonist was tested on Ca2+ currents to find the maximal effective concentration. Activation of SSTR2 with 10(-7) and 10(-8) M L-797,976 decreased the voltage-gated Ca2+ current and abolished any further decrease by SRIF. SSTR1, SSTR3, SSTR4, and SSTR5 agonists at 10(-7) M did not modify the voltage-gated Ca2+ current and did not affect the Ca2+ current response to SRIF. These results indicate that SSTR2 is involved mainly in regulating voltage-gated Ca2+ currents by SRIF, which contributes to the decrease in intracellular Ca2+ concentration and GH secretion by SRIF.     

Functional aspects of the somatostatinergic system in the retina and the potential therapeutic role of somatostatin in retinal disease

The somatostatinergic system of the retina has been investigated in a variety of studies. A considerable amount of experimental evidence is available concerning the patterns of expression of somatostatin (SRIF) and its receptors in vertebrate retinas. However the functional roles of this peptidergic system in retinal physiology are far from being elucidated. Nonetheless, data have been provided concerning the regulatory action of SRIF on the excitability of different retinal cell types and on the modulation of ion channels in different vertebrate retinas. The present review is focused on recent and unpublished investigations of the mouse retina relative to the involvement of specific SRIF receptors in the regulation of ion channels and transmitter release, the transduction pathways coupled to SRIF receptors, and the mechanisms regulating the expression of SRIF and its receptors as derived from studies in transgenic animal models. In these models, altered expression levels of SRIF or of specific SRIF receptors have also been found to affect the morphology of retinal cell types (namely the rod bipolar cells) and to result in functional alterations at the level of both ion channel regulation and transmitter release. These new pieces of evidence constitute an important step forward in the understanding of the functional actions of the retinal somatostatinergic system, although our current knowledge is far from being exhaustive. The ultimate goal of understanding SRIF functional actions in the retina is concerned with the possibility of using SRIF or its analogs as therapeutic agents to cure retinal diseases. Indeed, encouraging results are being obtained in clinical investigations focused on the use of SRIF analogs to treat diabetic retinopathy, a retinal disease with high social impact and originating as a complication of diabetes. The closing part of the present paper examines the evidence supporting SRIF as a promising therapeutic agent in this disease.     

Cell-specific localization of insulin-like growth factor binding protein mRNAs in rat liver

The liver is a major source of circulating insulin-like growth factor I (IGF-I), and it also synthesizes several classes of IGF binding proteins (IGFBPs). Synthesis of IGF-I and IGFBPs is regulated by hormones, growth factors, and cytokines. They are nutritionally regulated and expressed in developmentally specific patterns. To gain insight into cellular regulatory mechanisms that determine hepatic synthesis of IGF-I and IGFBPs and to identify potential target cells for IGF-I within the liver, we studied the cellular sites of synthesis of IGF-I, IGF receptor, growth hormone (GH) receptor, and IGFBPs in freshly isolated rat hepatocytes, endothelial cells, and Kupffer cells. We also localized cellular sites of IGFBP synthesis by in situ hybridization histochemistry. Western ligand and immunoblot analyses were used to determine IGFBP secretion by isolated cells. Two IGF-I mRNA subtypes with different 5' ends (class 1 and class 2) were detected in all isolated liver cell preparations. Type 1 IGF receptor mRNA was detected in endothelial cells, indicating that these cells are a local target for IGF actions in liver. GH receptor was expressed in all cell preparations, consistent with GH regulation of IGF-I and IGFBP synthesis in multiple liver cell types. The IGFBPs expressed striking cell-specific expression. IGFBP-1 was synthesized only in hepatocytes, and IGFBP-3 was expressed in Kupffer and endothelial cells. IGFBP-4 was expressed at high levels in hepatocytes and at low levels in Kupffer and endothelial cells. Cell-specific expression of distinct IGFBPs in the liver provides the potential for cell-specific regulation of hepatic and endocrine actions of IGF-I.     

sst5 somatostatin receptor mRNA induction by mitogenic activation of human T-lymphocytes.

SRIF has neuro-immunomodulatory actions on immune cells, including T-lymphocytes. Molecular mechanisms involved in these actions were studied by RT-PCR analysis of SRIF receptor expression in resting and initogen-activated human T-lymphocytes. Our results point to the mitogen-associated induction of sst5 receptor subtype. Conversely, sst3 receptor appears constitutively expressed in both activity states. Assessment of biologic actions of SRIF14 in activated T-lymphocytes indicates that, in nanomolar concentration range, this peptide moderately inhibits mitogen-induced IL-2 secretion. Nevertheless, T-lymphocyte proliferation is not inhibited in the presence of SRIF14 but is even slightly increased. Altogether these data suggest a complex mechanism of SRIF neuro-immunomodulatory actions.     

Characterization of 17-beta-estradiol-dependent and -independent somatostatin receptor subtypes in rat anterior pituitary

Previous studies from this laboratory showed that treatment with 17-beta-estradiol (E2) caused an acquisition of inhibitory effect of somatostatin (SRIF) on prolactin release with an increased number of SRIF-binding sites in the rat anterior pituitary. The aim of this study was to characterize the E2-dependent SRIF receptor in comparison with the E2-independent one, which was expressed in ovariectomized rats. The following observations were obtained: 1) both of the E2-dependent and E2-independent SRIF receptors, measured with 125I-Tyr11-SRIF as a radiolabeled ligand, were enriched in the plasma membrane fraction of the cells, displaying a single class of binding site (E2-dependent: Kd, 32 pM, Bmax, 2.3 pmol/mg protein; E2-independent: Kd, 83 pM, Bmax, 0.26 pmol/mg protein). The ligand binding to both receptors was sensitive to monovalent and divalent cations, and GTP. 2) Among the SRIF analogs tested, the relative potencies of SRIF28 and its analog and cyclosomatostatin compared with SRIF were lower in the E2-dependent receptor than in the E2-independent one. 3) A cross-linking study with N-hydroxysuccinimidyl-4-azido-benzoate revealed that the molecular weight of the cross-linked E2-dependent receptor was approximately 94,000, whereas that of the E2-independent one was 82,000, irrespective of the presence of a reducing reagent. The molecular weight of SRIF receptor from normal male or female rat pituitary was similar to the E2-independent type. 4) Both types of the cross-linked SRIF receptors were solubilized by sucrose monolaurate, adsorbed to a wheat germ agglutinin-agarose column, and eluted with N-acetyl-glucosamine. 5) SRIF inhibited the forskolin-stimulated adenylate cyclase activity in the pituitary membranes from E2-treated rats, but it did not in the E2-depleted membranes. These results demonstrate that there are at least two subtypes of SRIF receptor in the rat anterior pituitary, one of which is exclusively expressed by the treatment with E2, and that these subtypes are distinct with respect to ligand binding specificity, molecular weight, and coupling to adenylate cyclase inhibition.     

Signal transduction via the growth hormone receptor

Rapid progress has been made recently in the definition of growth hormone (GH) receptor signal transduction pathways. It is now apparent that many cytokines, including GH, share identical or similar signalling components to exert their cellular effects. This review provides a brief discourse on the signal transduction pathways, which have been demonstrated to be utilized by GH. The identification of such pathways provides a basis for understanding the pleiotropic actions of GH. The mechanisms by which the specific cellular effects of GH are achieved remain to be elucidated.     

A question of rhythm: recent advances in growth hormone research.

Research by Dr. Gloria Shaffer Tannenbaum at the McGill University-Montreal Children''s Hospital Research Institute has led to the development of a new test to differentiate children who are deficient in growth hormone from those who are short but growing normally. This clinical application is the fruit of Tannenbaum''s discovery that growth hormone secretion occurs in a rhythmic pattern regulated by intricate interactions between two neurohormones: growth hormone-releasing hormone (GHRH) and somatotropin release-inhibiting factor (SRIF). In the test an analogue of SRIF is used to allow stores of growth hormone to build up. A subsequent challenge with GHRH is then used to identify children with a genuine deficiency. Tannenbaum''s research also indicates that there are sexual differences in the pattern of growth hormone release and that growth hormone regulates its own secretion by means of a negative feedback system.     

Effect of growth hormone on protein phosphorylation in isolated rat hepatocytes

Hepatocytes from male rats were incubated with [32P]Pi for 40 min at 37 degrees C, thereby equilibrating the cellular ATP pool with 32P. Subsequent exposure to bovine growth hormone for 10 additional min did not change the specific activity of cellular [gamma-32P]ATP. Two-dimensional gel electrophoresis or chromatofocusing followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis was used to fractionate phosphoproteins solubilized from control or hormone-stimulated cells. Stimulation of hepatocytes with 5 nM growth hormone for 10 min at 37 degrees C affected the phosphorylation of a number of proteins including an Mr 46,000 species of pI 4.7 whose phosphorylation was augmented (2.65 +/- 0.50)-fold. A significant fraction of the maximal effect of growth hormone on phosphorylation of the Mr 46,000 species was elicited by 1-5% receptor occupancy. Bovine growth hormone, which binds to somatogenic receptors with great specificity, or recombinant human growth hormone, which is not contaminated with other hormones, affected phosphorylation of hepatic proteins similarly. The Mr 46,000 phosphoprotein was isolated in a fraction enriched in cytosol after centrifugation of cellular homogenates. Phosphorylation of the Mr 46,000 phosphoprotein was also increased (1.75 +/- 0.35)-fold and (2.15 +/- 0.50)-fold by insulin and glucagon, respectively. These observations are consistent with the possibility that selective changes in the phosphorylation state of cellular proteins may mediate growth hormone actions in cells.     

Clinical applications of somatostatin

Because of its wide distribution in the organism, natural somatostatin (SRIF) demonstrates an ample spectrum of actions, involving mainly the central neuroendocrine system and the enteropancreatic area. In the former, this peptide may find its field of application in conditions characterized by excessive GH, TSH or ACTH secretion, depending on the central or peripheral cause of the inappropriate hormone control. The inhibitory effect of SRIF on gastrointestinal and pancreatic hormones may be useful in the management of tumors originating in this system and also in the treatment of inflammatory processes such as pancreatitis, in malignant diarrhea, and in gastrointestinal bleeding. A complex action of SRIF and its derivative on insulin release and glucose homeostasis may offer some advantages in the control of unstable diabetes. Dampening of organic functions in the upper digestive tract may also render SRIF and its analogues useful in the exploration of the gallbladder, gastric and pancreatic functions. The effect of such peptides on tissue growth and on the regulation of blood pressure are the subject of present investigations. Cytoprotection, an interesting aspect of SRIF application, is discussed elsewhere in this compendium. Finally, some comments on the possible use of SRIF as an additive to the conventional treatment of burns and sepsis close this review.