Primary structure of ovine hypothalamic somatostatin-28 and somatostatin-25

Somatostatin immunoreactive neurons in the human hippocampus and cortex shown by immunogold/silver intensification on vibratome sections: coexistence with neuropeptide Y neurons, and effects in Alzheimer-type dementia

The distribution of somatostatinlike immunoreactivity was studied in the hippocampal formation, retrohippocampal region, and temporal cortex in the human brain. Tissues from surgical biopsy and postmortem cases were used, and the immunogold/silver method on vibratome sections was introduced for routine applications in conjunction with primary antisera that recognise somatostatin-14 or somatostatin-28. Somatostatin-28 antisera readily stained numerous neurons, dendrites, and extensive axonal networks throughout the hippocampus and neighbouring cortex. Liquid phase absorption provided controls for specificity. The most prominent accumulations of somatostatin immunoreactive neurons and axons occurred in the hilus of the area dentata, in CA1, and in the entorhinal and perirhinal cortices. Axonal plexuses occurred throughout the hippocampal subfields but were particularly dense in those regions rich in somatostatin neurons. The distribution of somatostatin immunoreactive neurons and fibers parallels the distribution of neuropeptide Y (NPY) neurons and fibers in the hippocampus and cerebral cortex to a remarkable extent. Double labelling experiments with antisera against neuropeptide Y and somatostatin indicate a considerable frequency of coexistence of the two peptides in single neurons, particularly in large multipolar cortical neurons and also in the small bipolar white matter neurons. Regional variations exist in the amounts of coexistence found in the hippocampal subfields; somatostatin-NPY coexistence is particularly high in the hilus of the area dentata, the subicular complex, and the deep layers of the entorhinal and perirhinal cortices. In the hippocampi and temporal cortices in cases of Alzheimer-type dementia compared to those of age-matched control brains, there is a significant to severe loss of somatostatin immunoreactive neurons and axons. This loss is most severe in those regions with the highest indices of neurofibrillary tangles and neuritic plaques-the hilus of the area dentata, CA1, and the entorhinal and perirhinal cortices. Surviving somatostatin neurons are distorted with short dendrites and truncated axons. Neuritic plaques identified on double label experiments with thioflavin include somatostatin axons but not neurons.

Biosynthesis of pancreatic islet hormones

We have outlined the various strategies used to characterize the precursors of three pancreatic islet hormones--somatostatin, pancreatic polypeptide and VIP. In each case, isolation of the cDNA clones was facilitated by the use of gastrointestinal tissues that were extremely rich in specific mRNA. Characterization of the structures of the precursors is clearly only the first step in understanding the regulation of pancreatic hormone biosynthesis. It is likely that the availability of the cDNA clones will allow us to define the actual mechanisms underlying hormone production within the pancreas.

Cotranslational and posttranslational proteolytic processing of preprosomatostatin-I in intact islet tissue

Preprosomatostatin-I (PPSS-I) is processed in anglerfish islets to release a 14-residue somatostatin (SS-14). However, very little is known regarding other processing events that affect PPSS-I. This is the first study to identify and quantify the levels of nonsomatostatin products generated as a result of processing of this somatostatin precursor in living islet tissue. The products of PPSS-I processing in anglerfish islet tissue were identified in radiolabeling studies using a number of criteria. These criteria included immunoreactivity, specific radiolabeling by selected amino acids, radiolabel sequencing, and chromatographic comparison to isolated, structurally characterized fragments of anglerfish PPSS-I using reverse-phase high performance liquid chromatography. Intact prosomatostatin-I (aPSS-I) was isolated from tissue incubated with [3H]tryptophan and [14C]leucine. Significant 14C radioactivity was observed in the products of 11 of the first 44 sequencer cycles in positions consistent with the generation of a 96-residue prosomatostatin. These results indicate that signal cleavage occurs after the cysteine located 25 residues from the initiator Met of PPSS-I, resulting in a signal peptide 25 amino acids in length. Nonsomatostatin-containing fragments of the precursor were also found in tissue incubated with a mixture of 3H-amino acids. Only a small quantity of the dodecapeptide representing residues 69-80 in the prohormone was found (10 nmol/g tissue). Two other fragments of aPSS-I, also observed to be present in low abundance, were found to correspond to residues 1-27 (16 nmol/g tissue) and to residues 1-67 (7 nmol/g tissue) of aPSS-I. No evidence for the presence of the fragment corresponding to residues 29-67 was found. However, large quantities of SS-14 were observed (287 nmol/g tissue), indicating that the major site of aPSS-I cleavage is at the basic dipeptide immediately preceding SS-14. Recovery of much lower levels of the nonsomatostatin fragments of aPSS-I suggests that prohormone processing at the secondary sites identified in this study occurs at a low rate relative to release of SS-14 from aPSS-I.

Somatostatin-containing D cells exhibit immunoreactivity for rat somatostatin cryptic peptide in six mammalian species. An electron-microscopical study

Antisera raised against rat somatostatin cryptic peptide (RSCP; corresponding to amino acids 63-77 of rat pro-somatostatin), somatostatin-28-(1-12) and somatostatin-28-(17-28) were used to compare the morphological distribution of these pro-somatostatin-derived sequences within the gastroenteropancreatic system of six mammalian species, including man. Using the immunogold staining procedure, RSCP, SS28-(1-12) and SS28-(17-28) immunoreactivity was found to be present in all the D cells of the tissues investigated. Extra-islet RSCP and SS28-(1-12) immunoreactive cells were also identified in some species. RSCP, SS28-(1-12) and SS-28-(17-28) immunoreactivities were also present in a single case of human duodenal somatostatinoma. Immunostaining of serial ultrathin sections from all specimens in this study revealed that RSCP and both somatostatin immunoreactivities were co-localised in a majority of the reactive cells. Corroborative evidence was obtained by double immunogold staining which further showed that RSCP, SS28-(1-12) and SS28-(17-28) immunoreactivities were co-localised to individual secretory granules in D type cells, both normal and tumour. RSCP and SS28-(17-28) immunoreactivities were invariably co-localised, whereas SS28-(1-12) immunoreactivity was restricted to a sub-population of secretory granules. Our findings suggest that RSCP immunoreactivity is conserved in a number of mammalian species and is stored in each secretory granule type. Consequently, detection of the RSCP sequence may serve as a useful marker for somatostatin-producing systems throughout the diffuse neuroendocrine system.

An immunohistochemical characterization of somatostatin-28 and somatostatin-281-12 in monkey prefrontal cortex

The distribution of the prosomatostatin-derived peptides (PSDP) somatostatin-28 (SS-28) and somatostatin-281-12 (SS-281-12) was characterized immunohistochemically in the prefrontal cortical regions of both Old World cynomolgus monkeys (Macaca fascicularis) and New World squirrel monkeys (Saimiri sciureus). Comparison of staining with antisera specific for each peptide revealed that these antigens were segregated within immunoreactive neurons such that SS-28 was largely confined to the perinuclear region of the cell body whereas SS-281-12 was primarily found in axons and dendrites. The laminar pattern of immunoreactive fibers was similar in all areas of the prefrontal cortex. The most dense terminal arborization was in layers I, II, and superficial III. Deep III and IV were traversed by radial fibers that had little arborization. Layers V and VI contained both radial fibers and a moderately dense terminal plexus. Labeled fibers were less numerous in the white matter. There were marked regional differences in fiber density. Areas 12 and 24 had the greatest density of immunoreactive fibers, areas 9, 11, and 25 were of intermediate density, and areas 10 and 46 were the least dense. Most of the immunoreactive cells appeared to be multipolar or bitufted. They were found throughout all cortical layers and the white matter. The largest number were located in layers II, superficial III, and deep V and VI. There were also marked regional differences in cell body density, which paralleled the regional differences in fiber density. Area 24 (anterior cingulate) had the greatest density of immunoreactive cell bodies (148 +/- 14/mm2), area 9 was of intermediate density (109 +/- 13/mm2), and area 46 was the least dense (83 +/- 12/mm2). Our findings indicate that PSDP compose a complex and extensive cortical system that is largely or totally intrinsic. The substantial regional heterogeneity in density exhibited by PSDP-containing neurons has not previously been reported for an intrinsic cortical system. The laminar and regional innervation patterns of these fibers and cell bodies suggest that the PSDP cortical system may play an important role in the polymodal information processing that occurs in association regions of prefrontal cortex.

Distribution of immunoreactive somatostatin (ISRIF) in the nervous system of the squid, Loligo pealei

Somatostatin (SRIF) is a neuropeptide with a widespread distribution in the mammalian CNS. In the present study we have examined the distribution of immunoreactive-like SRIF (ISRIF)-containing elements in the nervous system of the cephalopod mollusk Loligo pealei, or the Woods Hole squid. ISRIF was localized by light immunocytochemistry in sections of the squid-optic lobe, circumesophageal ganglia-and in stellate ganglion. In the optic lobe, ISRIF neurons were found in the internal granule cell layer and medulla and immunoreactive fibers were seen throughout the lobe and in the optic tract but were absent from the optic nerve, i.e., the projection between the retina and optic lobe. In the supraesophageal complex, ISRIF neurons were found in all lobes, but primarily in the vertical, subvertical, and frontal. In the subesophageal ganglion, ISRIF neurons were seen mainly following unilateral pallial nerve lesions; these neurons were primarily small-to-medium sized. ISRIF fibers were seen in many of the nerves exiting from the brain and in nerves extending between the sub- and supra-esophageal ganglia. In the stellate ganglion, ISRIF was present in many neurons as well as in a plexus of fibers within the ganglion; the peptide was absent from the second-order fibers and the giant axon. The data suggest that a molecule immunologically similar to vertebrate SRIF may be a major transmitter/modulator in this invertebrate. These results provide a foundation for further studies to evaluate the role of this molecule.

In vivo synthesis and processing of rat hypothalamic prosomatostatin

The in vivo incorporation of [3H]phenylalanine into an apparent 15 kDa prosomatostatin was observed in the hypothalamus of rats injected with the labeled amino acid in the third ventricle. Precursor-product relationships were established between this newly synthesized material and both somatostatin-28 and -14.

Biosynthesis and processing of the somatostatin family of peptide hormones

Understanding of the biosynthesis of the somatostatin family of peptide hormones has greatly increased in recent years. Isolation and sequencing of the rat somatostatin gene indicates that it contains a single intron located between the codons for Gn(-57) and Glu(-56) of pre-prosomatostatin. The gene contains three repetitive sequences, one at the 5' end of the gene and two of them 3' to the coding portion. Two of the sequences consist of alternating purine-pyrimidine bases and have been shown to adopt Z-DNA structures in vitro. The cDNA for rat somatostatin codes for a 116-residue peptide structurally similar to the anglerfish and catfish precursors to the 14-residue somatostatin (SST-14). In addition to SST-14, the catfish and the anglerfish both contain an additional pancreatic somatostatin, each derived from a different gene. The catfish contains a 22-residue somatostatin, which is O-glycosylated at Thr-5. The second somatostatin gene from anglerfish encodes a prosomatostatin that is processed to a 28-residue peptide. The mature peptide contains a hydroxylated lysine at position 23.

Somatostatin receptors

More insight into the biochemical structure and operation of the somatostatin receptor(s) has been gained in recent years from several approaches. The minimal active structure of the receptor(s) has been identified, and active minisomatostatins have been synthesized. High-affinity binding sites (KDS ranging from 0.1 to 1 nM) have been demonstrated in brain and peripheral organs. In pancreas, stomach, and intestine additional low-affinity sites (or states) have been also suggested Furthermore, cytosolic receptors might be present. Binding affinities of synthetic minisomatostatins, somatostatin-14 and somatostatin-28, show different tissue specificities, suggesting the existence of different receptor subtypes. Two possible interactions of somatostatin with stimulus-secretion coupling in secretory cells have been suggested: a direct activation of the GTP-dependent inhibitory subunit of adenylate cyclase and a distal activation of cytosolic phosphoprotein phosphatases.

Isolation and characterization of proSS1-32, a peptide derived from the N-terminal region of porcine preprosomatostatin

A peptide derived from the N-terminal region of porcine prosomatostatin, proSS1-32, has been purified to homogeneity from extracts of porcine upper intestine. Amino acid analysis revealed that the peptide consists of 32 residues. The complete primary structure was determined as: A P S D P R L R Q F L Q K S L A A A A G K Q E L A K Y F L A E L. This sequence obviously comprises residues 1-32 of porcine prosomatostatin since it is identical to the corresponding sequence in human preprosomatostatin. The postulated cleavage site in porcine prosomatostatin is a Leu-Leu bond between residues 32 and 33, thus confirming previous studies of the processing of the somatostatin precursor in the rat and transgenic mouse.

The distribution of somatostatin-like immunoreactivity in the monkey hippocampal formation

The distribution of somatostatin-like immunoreactivity was studied in the hippocampal formation of the Old World (Macaca fascicularis) and New World (Saimiri sciureus) monkeys. Series of coronal sections were processed by the unlabeled second antiserum method using primary antisera which recognize somatostatin-28 (S309) or somatostatin-28(1-12) (S320). Neuronal cell bodies were more readily stained with antiserum S309 and were observed throughout the hippocampal formation. The most prominent accumulations of stained neurons occur in the hilar region of the dentate gyrus, in strata oriens and pyramidale of regio inferior of the hippocampus, and in the deep layers of the entorhinal cortex. Both antisera demonstrated extensive fiber systems which varied in density regionally in the hippocampal formation. Stained fibers were most prominent in the outer two-thirds of the molecular layer of the dentate gyrus, in stratum lacunosum-moleculare of the hippocampus, in layer I of the presubiculum and in layers I, III, and V of the entorhinal cortex.

Anglerfish pancreatic islets produce two forms of somatostatin-28

It has been predicted on the basis of cDNA sequence analysis that anglerfish pancreatic islets contain at least two different preprosomatostatins (I and II). The C-terminal amino acid sequences of preprosomatostatin I and II were predicted to be identical to mammalian hypothalamic somatostatin-14 (SS-14) and its analog [Tyr7, Gly10]SS-14, respectively. That SS-14 is expressed in anglerfish pancreatic islets, has been shown earlier in pulse-chase experiments and by chemical characterization. However, it was observed that [Tyr7, Gly10]SS-14 was not expressed as such, but as part of larger polypeptides. Pulse-chase experiments combined with reverse-phase high pressure liquid chromatography, amino acid analysis with two different chromatographic systems, and complete Edman degradation indicated that preprosomatostatin II is processed in anglerfish islets to two different forms of somatostatin-28 (SS-28). The primary structure of the major form containing hydroxylysine (Hyl) was determined to be: H-Ser-Val-Asp-Ser-Thr-Asn-Asn-Leu-Pro-Pro-Arg- Glu-Arg-Lys-Ala-Gly-Cys-Lys-Asn-Phe-Tyr-Trp-Hyl-Gly-Phe-Thr-Ser-Cys-OH. The amino acid sequence of the minor form differs only at residue 23 by substitution of lysine for hydroxylysine. This is the first time that hydroxylysine, an amino acid which characteristically occurs in collagen or collagen-like structures has been identified in a potential regulatory peptide. It can be speculated that this amino acid is formed by post-translational hydroxylation of a lysine C-terminally linked to a glycine residue and thus modified at a site which has been recognized as hydroxylation site in collagen or collagen-like structures. The biological consequences of this unusual modification are being investigated.

Biosynthesis of rat preprosomatostatin

The biologically active forms of somatostatin, somatostatin-14 (SS-14) and somatostatin-28 (SS-28) arise by post-translational cleavage of prosomatostatin. Prosomatostatin in turn is derived from a larger precursor, preprosomatostatin. We have previously reported the structure of a complementary DNA molecule encoding rat preprosomatostatin. The nucleotide sequence of this cDNA indicated that SS-14 and SS-28 are located at the carboxy-terminus of a 116 amino acid precursor. At the amino-terminus of the precursor is a hydrophobic region characteristic of a leader or pre-sequence. Sequential Edman degradations of cell-free translation products synthesized in the presence of microsomal membranes indicate that preprosomatostatin is cleaved within the endoplasmic reticulum to form prosomatostatin, a precursor of 92 amino acids. To begin to elucidate the factors which regulate the expression of the rat somatostatin gene, we have determined the sequence of the gene isolated from recombinant bacteriophage libraries. The gene spans 1.2 kilobases in length and is interrupted within the coding sequence of prosomatostatin by a single intron of 630 bases. A variant of the Goldberg-Hogness promotor, TTTAAA, is located 31 bases upstream from the transcriptional start point. A repetitive sequence was identified in the 5' region of the gene within 650 bases of the promoter. The nucleotide sequence of this region reveals an alternating GT sequence 42 bases in length characteristic of DNA with Z-forming potential. Such sequences are thought to influence the expression of other eukaryotic genes.

Processing of an anglerfish somatostatin precursor to a hydroxylysine-containing somatostatin 28

A novel 28-residue somatostatin (SS) has been isolated from anglerfish pancreatic islets and characterized by complete Edman degradation, peptide mapping, and amino acid analysis. The primary structure of this anglerfish SS-28 (aSS-28) containing hydroxylysine (Hyl) was established to be H-Ser-Val-Asp-Ser-Thr-Asn-Asn-Leu-Pro-Pro-Arg-Glu-Arg-Lys-Ala-Gly-Cys- Lys-Asn-Phe-Tyr-Trp-Hyl-Gly-Phe-Thr-Ser-Cys-OH. This sequence (with the exception of hydroxylysine-23, which is replaced by lysine) is identical to the sequence of the COOH-terminal 28 residues of prepro-SS II predicted on the basis of cDNA analysis [Hobart, P., Crawford, R., Shen, L., Pictet, R. & Rutter, W. J. (1980) Nature (London) 288, 137-141]. This is the first instance in which hydroxylysine (to date characteristically observed in collagen or collagen-like structures) has been found in a potential regulatory peptide. Chromatographic characterization of peptides, radiolabeled in islet culture, revealed that aSS-28 contained 10-12% of the radioactivity incorporated into the 8000- to 1000-dalton SS-like polypeptides, whereas 88-90% of this radioactivity was detected in anglerfish SS-14. It appears probable that aSS-28 represents the predominant primary cleavage product derived from prepro-SS II by cleavage at the COOH-terminal side of a single arginine. Based on knowledge of the collagen biosynthesis, it is speculated that hydroxylation may take place as an early post-translational event.

Effect of exogenous somatostatin infusion on gastrointestinal blood flow and hormones in the conscious dog

The purpose of this study was to investigate the effects of intravenous somatostatin infusion on gastrointestinal blood flow and hormone release in conscious dogs. Gastric, duodenal, jejunal, and pancreatic blood flows, quantitated using radioactive microspheres, were significantly decreased during somatostatin infusion (200 and 500 ng/kg min), resulting in an overall 30% reduction in summed portal blood flow. Fasting blood levels of glucose fell an average of 10 mg/dl. Immunoreactive insulin, gastrin, glucagon, and pancreatic polypeptide were all profoundly suppressed by somatostatin infusion. Our studies provide one possible explanation for somatostatin's apparent effectiveness in the control of upper gastrointestinal hemorrhage.

Effects of somatostatin-14 and somatostatin-28 on plasma hormonal and gastric secretory responses to cephalic and gastrointestinal stimulation in man

This study was designed to determine the influence of cephalic and gastrointestinal meal stimulation on plasma levels of somatostatin-like immunoreactivity (SLI) and to compare plasma hormonal and gastric secretory effects of somatostatin-14 (SS-14) and its putative prohormone, somatostatin-28 (SS-28), in humans. Cephalic stimulation induced by modified sham feeding did not affect plasma SLI, whereas a gastric liver extract meal caused a significant increase in SLI. Infusion of SS-28 dose-dependently suppressed gastric acid, serum gastrin, and plasma pancreatic polypeptide (PP) responses to cephalic and gastrointestinal stimulation. SS-28 was equipotent with SS-14 as gastric inhibitor when compared on the basis of molar doses infused but was 4-10 times less potent on the basis of plasma SLI concentrations obtained. A lower and more physiological dose of SS-14 (75 pmol/kg-h) reduced gastric acid and PP responses but failed to affect the serum gastrin response to a meal; whereas a larger, pharmacological dose (500 pmol/kg-h) also suppressed serum gastrin responses. We conclude that meal releases SLI into the circulation and that SS-28 mimics the gastric secretory and plasma hormonal effects of SS-14 but is several times less potent than SS-14 in terms of circulating hormone levels.

Proteolytic events in the post-translational processing of somatostatin precursors from rat brain cortex and anglerfish pancreatic islets

An Arg-Lys esteropeptidase which converts somatostatin-28 (S-28) into somatostatin-14 (S-14) was detected in rat brain cortical extracts using a synthetic undecapeptide substrate mimicking the octacosapeptide sequence at the restriction site. This enzyme system was unable to release either the octacosapeptide or S-14 from the 15,000 mol wt (15K) rat hypothalamic precursor. This argues in favor of sequential degradation of the precursor into S-14 via S-28 as an obligatory intermediate. Another in vivo processing system was analyzed in the anglerfish pancreatic Brockmann organs. Here, cloning of two cDNA corresponding to two mRNA species predicts two distinct somatostatins precursors, called prosomatostatins I and II (Hobart et al., Nature 288:137, 1980). While a single S-14 can be detected in extracts made from this pancreatic tissue, indistinguishable from the mammalian species, two S-28 species could be separated by HPLC. Immunochemical and biochemical evidence indicates that the second species should correspond to anglerfish S-28 (AF S-28), the product of prosomatostatin-II processing in vivo. Amino acid analysis, together with the determined complete amino acid sequence of this peptide, demonstrates that this is indeed the case and that AF S-28 contains in its C-terminal half the [Tyr7, Gly10] derivative of S-14. These observations give an example of a AF S-28 being a terminal active product of prosomatostatin processing. They suggest that this octacosapeptide, which is potent on the inhibition of growth hormone release by anterior pituitary cells, may play such a role in the gastrointestinal tract of the anglerfish. These results, while not excluding alternative routes, give support to a sequential processing of the 15 K precursor----S-28----S-14.

Somatostatin-28 [1-12]-like peptides

The search for a peptide corresponding to the NH2-terminus of somatostatin-28 (SS-28) in tissues has led to the isolation and characterization of somatostatin-28[1-12] from pancreas and hypothalamus. Somatostatin-28[1-12]-like immunoreactivity [SS-28 [1-12]-LI] is widely distributed throughout the central nervous system and the digestive system of rodents and primates, reaching levels comparable to those of somatostatin-14 (SS-14). Antibodies directed against the C-terminal end of the dodecapeptide are more specific and constitute excellent markers for the "prosomatostatin" system in mammalian tissues. In rat brain, SS-28[1-12]-LI material is highly concentrated in nerve fibres and terminals, especially in the median eminence, layer I of neocortex, the outer molecular layer of the dentate gyrus and the striatum. Additionally, immunoreactivity is observed in large multipolar or occasionally pyramidal-like neurons of the neocortex. SS-28[1-12] is secreted from hypothalamus and amygdala by a calcium dependent mechanism. No biological role is presently known for the dodecapeptide. Two other peptides of Mr = 8000 (8 K) and Mr = 5000 (5 K) which contain SS-28[1-12] at their carboxy-termini are present in acid extracts from rat pancreas, brain and spinal cord. These two peptides were isolated from an acid extract of rat brains using ion-exchange chromatography, gel permeation chromatography and reverse-phase HPLC. Results from amino acid analysis and partial sequencing were compared to the sequence of the cDNA encoding rat pre-prosomatostatin (prepro-SS) and revealed that the 8 K peptide is a 76 amino acid molecule corresponding to prepro-SS[25-100] and that the 5K peptide, which contains 44 amino acids, corresponds to prepro-SS [57-100]. The 5 K peptide was generated after cleavage of a Leu-Leu bond at position 56-57 of prepro-SS. The four most predominant peptides of the "prosomatostatin system" presently characterized are: SS-14, SS-28[1-12], SS-28 and prepro-SS[25-100]. Studies on pooled perfusates from rat hypothalamic tissue show that prepro-SS[25-100] is released with SS-28[1-12] in vitro and accounts for 22% of the total SS-28[1-12]-like immunoreactive material released during depolarization. The 5 K peptide is apparently not secreted. The presence of prepro-SS[25-100] in brain implies that, first, prosomatostatin can serve as an immediate precursor for SS-14 without going through SS-28 as an intermediate step and second, other peptides could conceivably be derived from the cryptic portion of the precursor.

Enzymes processing somatostatin precursors: an Arg-Lys esteropeptidase from the rat brain cortex converting somatostatin-28 into somatostatin-14

The post-translational proteolytic conversion of somatostatin-14 precursors was studied to characterize the enzyme system responsible for the production of the tetradecapeptide either from its 15-kDa precursor protein or from its COOH-terminal fragment, somatostatin-28. A synthetic undecapeptide Pro-Arg-Glu-Arg-Lys-Ala-Gly-Ala-Lys-Asn-Tyr(NH2), homologous to the amino acid sequence of the octacosapeptide at the putative Arg-Lys cleavage locus, was used as substrate, after 125I labeling on the COOH-terminal tyrosine residue. A 90-kDa proteolytic activity was detected in rat brain cortex extracts after molecular sieve fractionation followed by ion exchange chromatography. The protease released the peptide 125I-Ala-Gly-Ala-Lys-Asn-Tyr(NH2) from the synthetic undecapeptide substrate and converted somatostatin-28 into somatostatin-14 under similar conditions (pH 7.0). Under these experimental conditions, the product tetradecapeptide was not further degraded by the enzyme. In contrast, the purified 15-kDa hypothalamic precursor remained unaffected when exposed to the proteolytic enzyme under identical conditions. It is concluded that this Arg-Lys esteropeptidase from the brain cortex may be involved in the in vivo processing of the somatostatin-28 fragment of prosomatostatin into somatostatin-14, the former species being an obligatory intermediate in a two-step proteolytic mechanism leading to somatostatin-14.

Characterization of a somatostatin-28 containing the (Tyr-7, Gly-10) derivative of somatostatin-14: a terminal active product of prosomatostatin II processing in anglerfish pancreatic islets

Anglerfish (Lophius piscatorius) Brockmann organs contain a form of somatostatin-14, identical to the hypothalamic tetradecapeptide, and two distinct forms of somatostatin-28, which can be separated by reversed-phase high-pressure liquid chromatography (HPLC). Analysis of the NH2-terminal amino acid sequence and comparison of the ability to incorporate 125I indicate that one of these forms corresponds to an octacosapeptide including in its sequence the (Tyr-7, Gly-10) derivative of somatostatin-14 (somatostatin II). Exposure of this somatostatin-28 species to an endopeptidase activity from the rat brain cortex generates a peptide immunologically related to somatostatin and undistinguishable from synthetic (Tyr-7, Gly-10) somatostatin-14 II by HPLC. This somatostatin-28 II exhibits a potent inhibitory effect on growth hormone release by rat anterior pituitary cells, comparable to the other somatostatin-28 form. Since (Tyr-7, Gly-10) somatostatin-14 II cannot be detected in anglerfish pancreatic islets, these results indicate that somatostatin-28 II represents the terminal active product of prosomatostatin II processing, whose structure was predicted from the cDNA nucleotide sequence corresponding to the second mRNA cloned from anglerfish Brockmann organs [Hobart, P., Crawford, R., Shen, L. P., Pictet, R. & Rutter, W. J. (1980) Nature (London) 288, 137-141].

Complete amino acid sequence of human seminal plasma beta-inhibin. Prediction of post Gln-Arg cleavage as a maturation site

The complete sequence of a 94 amino acid human seminal plasma polypeptide exhibiting inhibin-like activity is presented. This molecule, called beta-inhibin, selectively and specifically suppresses the release of pituitary FSH in vivo as well as in vitro. It does not affect the secretion of LH. Such a novel acidic protein contains a very basic C-terminal segment which is easily cleaved by mild tryptic digestion. It is predicted that the FSH inhibiting activity may reside within this region of the molecule. This would imply a post Gln-Arg cleavage to release the basic C-terminal active moiety.

The complete amino-acid sequence of anglerfish somatostatin-28 II. A new octacosapeptide containing the (Tyr7, Gly10) derivative of somatostatin-14 I

A new somatostatin-28 has been isolated from the Teleostean fish (Lophius piscatorius) Brockmann organs. Determination of its aminoacid sequence indicates that it corresponds to an octacosapeptide containing in its C-terminal end the Tyr-7 Gly-10 derivative of somatostatin-14 I. This structure is in agreement with the one predicted by Hobart et al. (Nature (1980) 288, 137-141) from a cDNA nucleotide sequence. It demonstrates that, since the corresponding somatostatin-14 II cannot be detected in this organ, S-28 II is a terminal product of prosomatostatin II processing in anglerfish pancreatic islets.

Purification of radioiodinated somatostatin-related peptides by reversed-phase high-performance liquid chromatography

In order to set up specific radioimmunoassays for the two N- and C-terminal tetradecapeptides of somatostatin-28 the peptides somatostatin SS14 and SS28 and the somatostatin by-products 1-Tyr-SS14, 11-Tyr-14 and desaminotyrosyl-beta-alanine fragment (1----14) of SS28 were radioiodinated by the chloramine-T or Bolton-Hunter techniques. Reversed-phase high-performance liquid chromatography was shown to be a very efficient and reliable method for the purification of different radioactive reaction media. The corresponding labelled peptides were tested for their relative immunological (radioimmunoassay) and biological (binding studies) properties.

A high molecular weight form of somatostatin-28 (1-12)-like immunoreactive substance without somatostatin-14 immunoreactivity in the rat pancreas. Evidence that somatostatin-14 synthesis can occur independently of somatostatin-28

Synthesis of somatostatin-14 (S-14) could occur through direct enzymatic processing of precursor somatostatin (prosomatostatin) or via sequential breakdown of prosomatostatin leads to somatostatin-28 (S-28) leads to S-14. If direct processing is important, it should theoretically generate S-14 and a molecule equivalent to prosomatostatin without the S-14 sequence. In an attempt to identify such a molecule, I characterized the molecular forms of S-28(1-12)-like immunoreactivity (S-28(1-12) LI) in the rat pancreas and compared the relative amounts of these forms with those of S-14-like immunoreactivity (S-14 LI). Pancreatic extracts were chromatographed on Sephadex G-50 and Sephadex G-75 columns (Pharmacia Fine Chemicals Inc., Piscataway, NJ) under denaturing conditions and immunoreactivity in the eluting fractions was analyzed by region-specific radioimmunoassays (RIAs). For RIA of S-28(1-12) LI we used a newly developed rabbit antibody R 21 B, 125I-Tyr12 S-28(1-14), and S-28(1-12) standards. This system detects S-28, S-28(1-12), high molecular weight forms of S-28(1-12), but not S-14. S-14 LI was measured using antibody R149, which detects S-14, S-28, and higher molecular weight S-14-like substances, but not S-28(1-12). Three forms of S-28(1-12) LI were identified: Mr 9,000-11,000, Mr 1,200 (corresponding to S-28(1-12), and Mr less than 1,000, comprising, respectively, 35, 53, and 12% of total immunoreactivity. The relative abundance of the 9,000-11,000 mol wt S-28(1-12) LI material was unchanged following removal of S-14 LI from pancreatic extracts by affinity chromatography before gel filtration. Serial dilutions of fractions containing 9-11,000 and 1,200 mol wt materials exhibited parallelism with synthetic S-28(1-12). The total pancreatic concentration of S-28(1-12) LI was 1.56 pmol/mg protein, of which S-28(1-12) accounted for 0.83 pmol/mg protein and 9-11,000 S-28(1-12) LI comprised 0.55 pmol/mg protein. Pancreatic S-14 LI concentration was 2.07 pmol/mg protein, of which 98% corresponded to S-14. S-28-related peaks accounted for <1% of immunoreactivity in both RIAs. I concluded that (a) S-14 is the main form of pancreatic S-14 LI; (b) S-28 is present in very small quantities, in the pancreas; (c) S-28(1-12) LI consist mainly of S-28(1-12) and 9-11,000 mol wt S-28(1-12) LI; (d) 9-11,000 l wt S-28(1-12) LI could represent prosomatostatin without the S-14 sequence; (e) the finding of high concentrations of 9-11,000 mol wt S-28(1-12) LI suggests that S-14 synthesis can occur independently of S-28 and that direct processing of prosomatostatin is an important pathway for S-14 synthesis in the pancreas.

Structure of somatostatin isolated from bovine retina

Somatostatin-like immunoreactivity (SLI) from bovine retina was purified and its structure determined. Retinal tissue (1868 g) extracted with 3% acetic acid yielded 18.6 nmol SLI. This peptide was purified by chromatography on an affinity column made with anti-somatostatin antiserum, a reverse-phase C-18 HPLC column, and three sequential applications on a reverse-phase phenyl HPLC column. The peptide was purified 103,000-fold from the initial extract with an overall yield of 14.4%. Amino acid sequence determination by an automatic Edman degradation technique revealed the sequence to be as follows: Ser-Ala-Asn-Ser-Asn-Pro-Ala-Met- Ala-Pro-Arg-Glu-Arg-Lys-Ala-Gly-(Cys)-Lys- Asn-Phe-Phe-Trp-Lys-Thr-(Phe, Thr, Ser, Cys). The apparent identity of this peptide with somatostatin octacosapeptide (S28) purified from other mammalian tissue indicates the phylogenetic conservation of its structure and facilitates the use of the retina as a model system for studying the neurotransmitter function of somatostatin.

Characterization of rat hypothalamic growth hormone-releasing factor

The importance of the hypothalamus in the regulation of growth hormone (GH) secretion from the adenohypophysis has been supported by experimental and clinical evidence. It has been observed that GH secretion is in part controlled by hypothalamic GH release-inhibiting factors, two forms of which, somatostatin-14 (ref. 5) and somatostatin-28 (refs 6-9), have been characterized. Peptides with GH-releasing activity were recently purified from two human pancreatic tumours of acromegalic patients and characterized. Synthetic versions of these human pancreatic tumour GH-releasing factors (hpGRFs) were found to be potent GH secretagogues in vitro and in vivo and to exhibit actions and interactions similar to those observed with partially purified hypothalamic GRF. GH-releasing peptides have been purified from hypothalami of various species but the structure of natural hypothalamic GRF has not yet been reported. We now describe the purification, sequence analysis and synthesis of a 43-residue polypeptide isolated from rat hypothalamic extracts on the basis of its ability to stimulate GH secretion from cultured rat adenohypophyseal cells. The native polypeptide and its synthetic replicate do not differ significantly in their biological potencies and intrinsic activities. We propose that this polypeptide, which shows 67% homology with the corresponding N-terminal 43 residues in hpGRF-44, is the long-sought rat hypothalamic GRF (rhGRF).

Release of somatostatin-28(1-12) from rat hypothalamus in vitro

Following the discovery of the growth hormone release-inhibiting factor somatostatin from extracts of ovine hypothalamus, an N-terminally extended somatostatin of 28 amino acids has been identified in mammalian tissue. The original peptide, somatostatin-14 (SS14), corresponds to the C-terminus of somatostatin-28 (SS28). Both SS28 and SS14 have biological activity, occur in several rat brain regions, are present in cell bodies and nerve terminals and can be released in vitro upon depolarization in a calcium-dependent manner. Further, high-affinity binding sites were described for SS14, which also bind SS28 (refs 20-23). Recently, a dodecapeptide which corresponds to the N-terminus of somatostatin-28, somatostatin-28(1-12), has been characterized in rat hypothalamus. Radioimmunological and immunohistochemical studies have indicated the presence of SS28(1-12)-like immunoreactivity in several cortical and subcortical regions of the rat brain. This peptide was found to be unevenly distributed with the highest concentration in the hypothalamus, and preferentially localized to dendritic and axonal processes and terminals. These observations suggest that SS28(1-12) may be a neurotransmitter. In this study, we describe a calcium-dependent release of a SS28(1-12)-like peptide from hypothalamic slices in vitro. This finding supports a neurotransmitter function for this peptide.

Immunocytochemical localization of prosomatostatin fragments in maturing and mature secretory granules of pancreatic and gastrointestinal D cells

Pancreatic and gastrointestinal D cells were examined by immunocytochemistry using antisera against somatostatin-28 (SS28) and its NH2-terminal fragment SS28-(1-12), followed by the staphylococcal protein A-gold (pAg) complex. In pancreatic and gastric D cells incubated with antiserum against SS28-(1-12) the gold particles produced intense staining of the mature secretory granules but weaker staining of the immature granules associated with the Golgi area, whereas after SS28 antiserum treatment the particles accumulated selectively over the population of immature secretory granules. In intestinal D cells not only SS28-(1-12) but also SS28 antiserum produced an intense gold staining over the mature delta granules. These observations show that the relative amounts of immunoreactive sites related to SS28 and its cleavage product SS28-(1-12) in maturing and mature secretory granules are different in pancreatic, gastric, and intestinal D cells.

Biosynthesis of somatostatin-like immunoreactivity by frog retinas in vitro

Somatostatin-like immunoreactivity has been localized to a wide variety of central nervous system neurons, including the retina. We utilized the unique advantages the retina provides for in vitro studies of nerves to examine the biosynthesis of somatostatin. Extracts of frog retinas pulse-labeled with [35S]cysteine for various time periods revealed uptake of radioactivity into material adsorbable by anti-somatostatin antibody linked to affinity beads. This uptake increased in a curvilinear fashion for 4 h and was inhibited by cycloheximide (0.2 mM) or by boiling the retinas prior to labeling. Pulse-chase experiments revealed that affinity-adsorbable radioactivity from retinal extracts decreased with time of incubation in chase medium; 89% of this decrease could be accounted for by increased in the affinity-adsorbable radioactivity of the chase medium. Chromatography of the retinal extracts on Sephadex G50 (superfine) revealed four elution peaks, whereas only one peak, co-eluted with somatostatin-14, could be identified in the medium. Chromatographic elution patterns of affinity-adsorbable radioactivity from extracts of pulse-labeled retinas incubated in chase medium for various times showed a gradual shift of radioactivity from the earlier-eluting peaks to the later ones. These studies indicate that biosynthesis of somatostatin occurs in frog retinas in vitro. The retina may be a useful model for further study of peptidergic neurons.

Biosynthesis of immunoreactive somatostatin by hypothalamic neurons in culture

The neuronal biosynthesis of somatostatin-like immunoreactivity (SLI) was investigated using mechanically dispersed neonatal rat hypothalamic cells kept in culture for up to 6 wk. Immunohistochemically, SLI was specifically localized to a small subpopulation of parvicellular neurons and their cell processes. By radioimmunoassay the cellular SLI content declined steadily during the first 2 wk in culture (nadir value of 60 fmol/dish at day 15) but then increased progressively to reach a maximum value of 381 fmol/dish at day 46. Gel chromatographic analysis showed this immunoreactivity to consist of forms corresponding to tetradecapeptide somatostatin (S-14), somatostatin-28 (S-28), and a 15,000-mol-wt molecule. After incubation of the cells with [3H]phenylalanine, the cellular extracts, purified by adsorption to C18 silica, contained material that bound specifically to an immobilized antisomatostatin antibody. Analysis by gel chromatography and high performance liquid chromatography of the specifically bound label provided evidence for the presence of labeled S-14, S-28, and the 15,000-mol-wt molecule. Pulse-chase experiments (20-min pulse, 20-min chase) demonstrated a transfer of radioactivity from the 15,000-mol-wt form to material corresponding to S-14 as well as to S-28. These studies demonstrate that cultured hypothalamic neurons are capable of synthesizing three somatostatin-like peptides (15,000-mol-wt SLI, S-28, S-14), one of which (15,000-mol-wt SLI) serve as a biosynthetic precursor for both S-28 and S-14. This in vitro system should provide a powerful tool for further investigation of the biosynthesis and regulation of biosynthesis of somatostatin in the hypothalamus.

Isolation of glucagon-37 (bioactive enteroglucagon/oxyntomodulin) from porcine jejuno-ileum. Characterization of the peptide

A peptide isolated from porcine gut according to its glucagon-like activity in liver (bioactive enteroglucagon) has been characterized immunologically, biologically and chemically: its potency relative to pancreatic glucagon in interacting with an antiglucagon antibody, hepatic glucagon-binding sites and hepatic adenylate cyclase was approximately 100%, 20% and 10%, respectively. In contrast, it is approximately 20-times more potent than glucagon in oxyntic glands, justifying the term 'oxyntomodulin'. Chemically, it consists in the 29 amino acid-peptide glucagon elongated at its C-terminal end by the octapeptide Lys-Arg-Asn-Lys-Asn-Asn-Ile-Ala; accordingly, it is called 'glucagon-37'.

Sequence of a cDNA encoding pancreatic preprosomatostatin-22

We report the nucleotide sequence of a precursor to somatostatin that upon proteolytic processing may give rise to a hormone of 22 amino acids. The nucleotide sequence of a cDNA from the channel catfish (Ictalurus punctatus) encodes a precursor to somatostatin that is 105 amino acids (Mr, 11,500). The cDNA coding for somatostatin-22 consists of 36 nucleotides in the 5' untranslated region, 315 nucleotides that code for the precursor to somatostatin-22, 269 nucleotides at the 3' untranslated region, and a variable length of poly(A). The putative preprohormone contains a sequence of hydrophobic amino acids at the amino terminus that has the properties of a "signal" peptide. A connecting sequence of approximately 57 amino acids is followed by a single Arg-Arg sequence, which immediately precedes the hormone. Somatostatin-22 is homologous to somatostatin-14 in 7 of the 14 amino acids, including the Phe-Trp-Lys sequence. Hybridization selection of mRNA, followed by its translation in a wheat germ cell-free system, resulted in the synthesis of a single polypeptide having a molecular weight of approximately 10,000 as estimated on Na-DodSO4/polyacrylamide gels.

Human somatostatin I: sequence of the cDNA

RNA has been isolated from a human pancreatic somatostatinoma and used to prepare a cDNA library. After prescreening, clones containing somatostatin I sequences were identified by hybridization with an anglerfish somatostatin I-cloned cDNA probe. From the nucleotide sequence of two of these clones, we have deduced an essentially full-length mRNA sequence, including the preprosomatostatin coding region, 105 nucleotides from the 5' untranslated region and the complete 150-nucleotide 3' untranslated region. The coding region predicts a 116-amino acid precursor protein (Mr, 12.727) that contains somatostatin-14 and -28 at its COOH terminus. The predicted amino acid sequence of human somatostatin-28 is identical to that of somatostatin-28 isolated from the porcine and ovine species. A comparison of the amino acid sequences of human and anglerfish preprosomatostatin I indicated that the COOH-terminal region encoding somatostatin-14 and the adjacent 6 amino acids are highly conserved, whereas the remainder of the molecule, including the signal peptide region, is more divergent. However, many of the amino acid differences found in the pro region of the human and anglerfish proteins are conservative changes. This suggests that the propeptides have a similar secondary structure, which in turn may imply a biological function for this region of the molecule.

Large-molecular-weight somatostatin in human adrenal medullary tissue

Three human catecholamine-secreting adrenal medullary tumours, identified as phaeochromocytoma, were found to contain 774, 168, and 78 pmol/g of somatostatin-like immunoreactivity (SLI), compared to 40 pmol/g in a sample of normal human adrenal medulla. Sephadex-G50 gel-filtration chromatography of extracts from these tissues revealed SLI eluting in the position of somatostatin-14, somatostatin-28, and a peak eluting with a mol. wt. of about 5 K. After digestion of eluted material with clostridiopeptidase B, the predominant form of adrenal medullary SLI was found to elute in the position of a 7-K polypeptide.

Characterization of the somatostatin-like immunoreactivity extracted from an adrenal medullary tumour

Significant amounts of somatostatin-like immunoreactivity (SLI) were detected in the extract of a human catecholamine-secreting adrenal medullary tumour. After salt fractionation and reconstitution the major portion of SLI was purified by gel filtration and two HPLC steps; in all three systems it eluted in the position of somatostatin-14. The purified somatostatin-like peptide inhibited, in a dose-related manner, growth hormone release from stimulated perfused rat anterior pituitary cells in vitro. Amino acid analysis showed the purified peptide to have an identical composition to somatostatin found in other species.

Presence of somatostatin-28-(1-12) in hypothalamus and pancreas

Acid extracts from rat pancreas and hypothalamus were analyzed for the presence of the antigenic determinant corresponding to the NH2 terminus of somatostatin-28 (SS28), using an antiserum directed against amino acids 1 to less than or equal to 11 of the SS28 molecule. On gel permeation chromatography the majority of the immunoreactive material from each tissue extract eluted in one zone compatible with a peptide of 1250 daltons. Purification of this immunoreactive material by reverse-phase HPLC and cation-exchange chromatography yielded two immunoreactive peptides from each tissue extract. The amino acid compositions of both peptides in pancreas and hypothalamus correspond to the fragment 1-12 of SS28. The more hydrophobic peptide from each tissue coeluted with synthetic SS28-(1-12) on HPLC, while the other one coeluted with synthetic SS28-(1-12)-amide. We conclude that the prosomatostatin fragment Ser-Ala-Asn-Ser-Asn-Pro-Ala-Met-Ala-Pro-Arg-Glu-OH is present in both rat hypothalamus and rat pancreas.

Pancreatic preproglucagon cDNA contains two glucagon-related coding sequences arranged in tandem

We have constructed and cloned in bacteria recombinant plasmids containing DNA complementary to the mRNA encoding a pancreatic preproglucagon (Mr 14,500), a product of cell-free translation of angler fish islet mRNAs shown previously by immunoprecipitation analyses to be a precursor of glucagon. cDNAs of 630, 180, and 120 base pairs were isolated and correspond to most of the mRNA for the preproglucagon (650 bases). The cDNAs contain a protein coding sequence of 372 nucleotides and 5'- and 3'-untranslated regions of 58 and 206 nucleotides, respectively. From the coding sequence of the cDNAs, we find that the sequence of glucagon, identical to mammalian glucagon in 20 of 29 positions, resides in the preproglucagon of 124 amino acids flanked by NH2- and COOH-peptide extensions of 52 and 43 amino acids, respectively. The peptide extensions are linked to the glucagon by Lys-Arg sequences characteristic of the sites that are cleaved during the posttranslational processing of prohormones. Notable is the finding that, following the initial Lys-Arg sequence in the COOH-peptide extension is a pentapeptide. Ser-Gly-Val-Ala-Glu, followed by another Lys-Arg and a sequence of 34 residues that shows striking homology with glucagon and the other peptides of the glucagon family--gastric inhibitory peptide, vasoactive intestinal peptide, and secretin. Thus, the preproglucagon mRNA contains two glucagon-related coding sequences arranged in tandem. The finding of Lys-Arg sequences flanking the glucagon and glucagon-related sequences suggests that these two peptides and a pentapeptide are formed in vivo by posttranslational cleavages of a common precursor.

Sequence analysis of a cDNA coding for a pancreatic precursor to somatostatin

A synthetic oligonucleotide having the sequence d(T-T-C-C-A-G-A-A-G-A-A) deduced from the amino acid sequence Phe-Phe-Trp-Lys of somatostatin-14 was used to prime the synthesis of a cDNA from channel catfish (Ictalurus punctatus) pancreatic poly(A)-RNA. The major product of this reaction was a cDNA fragment of 565 nucleotides. Chemical sequence analysis of the cDNA fragment revealed that it was complementary to a mRNA coding for somatostatin. The 565-nucleotide cDNA hybridizes strongly with a poly(A)-RNA estimated to be 1000 nucleotides in length. An amino acid sequence of the somatostatin precursor was predicted from the nucleotide sequence. Oyama et al. [Oyama, H., Bradshaw, R. A., Bates, O. J. & Permutt, A. (1980) J. Biol. Chem. 255, 2251-2254] have reported the isolation of a somatostatin from the catfish that is 22 residues in length (somatostatin-22). This peptide differs from somatostatin-14 in amino acid sequence. The cDNA sequence obtained by this laboratory codes for somatostatin-14 and predicts another somatostatin gene product from this species. Thus it would appear that there are at least two somatostatin gene products.