Somatostatin is a tetradecapeptide that is widely distributed in the body. It acts on multiple organs including brain, pituitary, gut, exocrine and endocrine pancreas, adrenals, thyroid, and kidneys to inhibit release of many hormones and other secretory proteins. In addition, it functions as a neuropeptide affecting the electrical activity of neurons. Somatostatin exerts its biological effects by binding to specific high-affinity receptors, which appear in many cases to be coupled to GTP-binding proteins. Here we report the cloning, functional expression, and tissue distribution of two different somatostatin receptors (SSTRs). SSTR1 and SSTR2 contain 391 and 369 amino acids, respectively, and are members of the superfamily of receptors having seven transmembrane segments. There is 46% identity and 70% similarity between the amino acid sequences of SSTR1 and SSTR2. Stably transfected Chinese hamster ovary cells expressing SSTR1 or SSTR2 exhibit specific somatostatin binding, with an apparently higher afflnity for somatostatin-14 than somatostatin-28, an NH2-terminally extended form of somatostatin-14. RNA blotting studies show that SSTR1 and SSTR2 are expressed at highest levels in jejunum and stomach and in cerebrum and kidney, respectively. A SSTR1 probe hybridized to multiple DNA fragments in EcoRI digests of human and mouse DNA, indicating that SSTR1 and SSTR2 are members of a larger family of somatostatin receptors. Thus, the biological effects of somatostatin are mediated by a family of receptors that are expressed in a tissue-specific manner.Somatostatin is a tetradecapeptide that was first isolated from hypothalamic extracts and shown to be a potent inhibitor of growth hormone secretion from the anterior pituitary (1). Subsequent studies have shown that it is widely distributed occurring in the central nervous system and peripheral tissues such as stomach, intestine, and pancreas (2). Somatostatin has diverse physiological effects that are tissue-specific (2). It can function as a neurotransmitter as well as a hormone. Its hormonal effects include suppression of release of many pituitary, pancreatic, and gastrointestinal hormones and other secretory proteins.Somatostatin-14 is a member ofa family of somatostatin-like peptides that also includes an NH2-terminally extended form, somatostatin-28 (3, 4). The two principal bioactive forms of somatostatin, somatostatin-14 and -28, are derived by tissuespecific proteolytic processing of prosomatostatin, the 92-amino acid precursor of somatostatin-14 and -28 (5) and are present at various concentrations in different tissues. Although somatostatin-14 and -28 may have common effects on target tissues, they show different potencies, suggesting that their actions are mediated by different receptors (2). For example, somatostatin-14 appears to be relatively more selective for inhibition of glucagon and gastric acid secretion, whereas somatostatin-28 is a more specific inhibitor of growth hormone, insulin, and pancreatic exocrine secreziin (6).Somatostatin-14 ...
Limited proteolysis is a widely occurring mechanism in protein biosynthesis. Protein precursors can be classified according to their functions, localization within cell compartments, and enzymic cleavage mechanisms. The presecretory proteins represent an important class of very rapidly turning over precursors which play an early role in the sequestration of secretory products and whose cleavage appears to be intimately associated with structures formed at the ribosome-membrane junction during protein synthesis. A model is proposed which predicts that the prepeptide forms a beta-pleated sheet structure with other components of the membrane which results in the transfer of a loop of peptide across the microsomal membrane. Proinsulin is representative of the general class of proproteins that are processed post-translationally within their secretory cells either during the formation and maturation of secretory granules (peptides hormones and neurotransmitters, serum albumins) or during the assembly of macromolecular structures (virus capsules, membrane-associated enzyme complexes). The former group are cleaved by Golgi-associated proteases having tryptic and carboxypeptidase B-like specificity. Some precursors are secreted as such and processed extracellularly either in the circulation or at special sites (procollagens, zymogens, provenoms, vitellogenins).
We have previously identified a structurally abnormal insulin in the serum and pancreas of a middle-aged man with diabetes mellitus which arose from a leucine for phenylalanine substitution at position 24 or 25 of the insulin B chain; further analysis of the patient's leukocyte DNA showed that one of the patient's insulin alleles had undergone mutation resulting in loss of an MboII restriction site normally present in the human insulin gene. Two additional and unrelated patients with the same clinical syndrome have now been identified (ref. 4 and unpublished results). All of these patients showed hyperglycaemia typical of diabetes and with marked hyperinsulinaemia typical of insulin resistance, but all three show normal tolerance to exogenously administered insulin. As the opportunity of examining pancreatic tissue from patients suspected of secreting insulin variants is rare, we have developed a method combining HPLC and radioimmunoassay to identify insulin variants isolated from human sera. By this method we have shown that all three patients noted above secrete structurally variant and chemically distinct insulins. In correction of our original assignment, one is identified as [LeuB25]insulin.
In order to evaluate the cause of the greatly decreased receptor-binding potency of the naturally occurring mutant human insulin Insulin Wakayama ([LeuA3]insulin, 0.2% relative potency), we examined (by the semisynthesis of insulin analogues based on N alpha-PheB1,N epsilon-LysB29-bisacetyl-insulin) the importance of aliphatic side chain structure at positions A2 and A3 (Ile and Val, respectively) in directing the interaction of insulin with its receptor. Analogues bearing glycine, alanine, alpha-amino-n-butyric acid, norvaline, norleucine, valine, isoleucine, allo-isoleucine, threonine, tert-leucine, or leucine at positions A2 or A3 were assayed for their potencies in competing for the binding of 125I-labeled insulin to isolated canine hepatocytes, as were analogues bearing deletions from the A-chain amino terminus or the B-chain carboxyl terminus. Selected analogues were also analyzed by far-UV CD and absorption spectroscopy of Co2+ complexes. Our results identify that (a) Ile and Val serve well at position A2, whereas residues with other side chains (including those with straight chains, alternatively configured beta-branches, or a gamma-branch) exhibit relative receptor-binding potencies in the range 1-5%; (b) greater flexibility is allowed side-chain structure at position A3, with Ile, allo-Ile, alpha-amino-n-butyric acid, and tert-Leu exhibiting relative receptor-binding potencies in the range 11-36%; and (c) simultaneous replacements at positions A2 and A3, and deletions of the COOH-terminal domain of the insulin B chain in related analogues, yield cumulative effects. These findings are discussed with respect to a model for insulin-receptor interactions that involves a structure-orienting role for residue A2, the direct interaction of residue A3 with receptor, and multiple separately defined elements of structure and of conformational adjustment.
A B S T R A C T The in vivo hepatic metabolism of connecting peptide (C-peptide) in relation to that of insulin has not been adequately characterized. A radioimmunoassay for dog C-peptide was therefore developed and its metabolism studied in conscious mongrel dogs, with sampling catheters chronically implanted in their portal and hepatic veins and femoral artery. The hepatic extraction of endogenous C-peptide under basal conditions was negligible (4.3±4.5%) and was similar to the hepatic extraction of C-peptide measured during the constant exogenous infusion of C-peptide isolated from dog pancreas. Simultaneously measured hepatic extraction of endogenous and exogenously infused insulin were 43.8±7.6 and 47.5±4.4%, respectively. The metabolic clearance rate of infused C-peptide was 11.5±0.8 ml/kg per min and was constant over the concentration range usually encountered under physiological conditions. In additional experiments, the effect of parenteral glucose administration on the hepatic extraction of C-peptide and insulin was investigated. The hepatic extraction of C-peptide (6.2±4.0%) was again negligible in comparison with that of insulin (46.7±3.4%). Parenteral glucose administration did not affect the hepatic extraction of either peptide irrespective of whether it was infused peripherally, intraportally, or together with an intraportal infusion of gastrointestinal inhibitory polypeptide. The fasting C-peptide insulin molar ratio in both the portal vein (1.2±0.1) and femoral
Studies on naturally occurring and man-made mutations in the insulin gene have provided new insights into insulin biosynthesis, action, and metabolism. Ten families have been identified in which one or more members have single-point mutations in their insulin genes that result in amino acid substitutions within the proinsulin molecule. Six of these cause the secretion of biologically defective insulin molecules due to changes within the A or B chains. Replacing A3-Val with Leu, B24-Phe with Ser, or B25-Phe with Leu results in molecules that have essentially normal immunoreactivity but greatly reduced insulin-receptor-binding potency. Individuals with these mutations have a syndrome of mild diabetes or glucose intolerance, which is inherited in an autosomal-dominant mode and is associated with hyperinsulinemia and altered insulin-C-peptide ratios. Although affected individuals are heterozygous and coexpress both normal and abnormal molecules, the elevated circulating insulin consists mainly of the biologically defective form, which accumulates because it fails to be rapidly metabolized via receptor-mediated endocytosis. Four additional families have mutations that are associated with relatively asymptomatic hyperproinsulinemia. A point mutation affecting proinsulin occurs in 3 of the 4 families, leading to replacement of Arg-65 by His, which prevents recognition of the C-peptide-A-chain dibasic cleavage site by the appropriate beta-cell processing protease and results in the circulation of a type II proinsulin intermediate form (des 64, 65 HPI). Members of a fourth family with hyperproinsulinemia have a substitution of B10-His with Asp, resulting in a proinsulin that exhibits markedly altered subcellular sorting behavior.(ABSTRACT TRUNCATED AT 250 WORDS)
Insulin isolated from the pancreas of a diabetic patient with fasting hyperinsulinaemia showed decreased activity in binding to cell membrane insulin receptors and in stimulating cellular 2-deoxyglucose transport and glucose oxidation. Chemical studies suggest that the isolated hormone is a mixture of normal insulin and an abnormal variant which contains a leucine for phenylalanine substitution at position 24 or 25 of the insulin B-chain.
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