Structure-conformation-activity studies of glucagon and semi-synthetic glucagon analogs

Summary Examination of glucagon structure-activity relationships and their use for the development of glucagon antagonists (inhibitors) have been hampered until recently by the lack of high purity of semisynthetic glucagon analogs and inadequate study of full dose-response curves for these analogs in sensitive bioassay systems. Recently a number of highly purified glucagon fragments and semi-synthetic analogs have been prepared and their full dose-response activities examined over a wide concentration range using the hepatic membrane adenylate cyclase assay, the hepatic membrane receptor binding assay, and glycogenolytic activity in isolated rat hepatocytes. The results of these studies have enabled us to identify and dissociate the structural (and in some cases conformational) features of glucagon important for binding from those most responsible for biological activity (transduction). Key findings in these studies were the observation that: (1) the C-terminal region of glucagon is primarily of importance for hormone binding to receptors; (2) glucagon_1–21 and glucagon_1–6 have low potency, but are essentially fully active glucagon derivatives; and (3) highly purified glucagon_2–29 ([1-des-histidine]-glucagon), [1-N-carbamoylhistidine]-glucagon and [1-N-carbamoylhistidine, 12-N-carbamoyllysine]-glucagon are all partial agonists.These and other findings led us to synthesize several semisynthetic analogs of glucagon which were found to possess no intrinsic biological activity in the hepatic adenylate cyclase assay system, but which could block the effect of glucagon (competitive inhibitors) in activating adenylate cyclase in this system. Two of these highly purified analogs [1-des-histidine] [2-N-trinitrophenylserine, 12-homoarginine]-glucagon and [1-N-trinitrophenylhistidine, 12-homoarginine]-glucagon were quite potent glucagon antagonists (inhibitors) with pA₂ values of 7.41 and 8.16 respectively. The latter compound has also been demonstrated to decrease dramatically blood glucose levels of diabetic animals in vivo. These results demonstrate that glucagon is a major contributor to the hyperglycemia of diabetic animals.Examination of the known and calculated conformational properties of glucagon provide insight into the structural and conformational properties of glucagon and its analogs most responsible for its biological activity. Consideration of these features and the mechanism of glucagon action at the membrane receptor level provide a framework for further developing glucagon analogs for theoretical and therapeutic applications.     

Interactions of glucagon and glucagon analogs with isolated canine hepatocytes

We have used glucagon and nine glucagon analogs to investigate the interactions of these ligands with glucagon-binding sites present on isolated canine hepatocytes. Curves reflecting the inhibition of 125I-labeled glucagon or 125I-labeled analog binding to cells by the 10 peptides spanned, overall, a 10(6)-fold range of hormone concentration, were consistent with hormone binding to two classes of binding sites in each case, and fell into two groups, one of which contained curves that were considerably more shallow than the other. Only conditions that emphasized prior binding to low affinity sites resulted in the rapid and extensive dissociation of receptor-bound ligand from isolated cells. Finally, all 10 peptides exhibited a concentration-dependent inhibition of the incorporation of [14C]fructose into hepatocyte glycogen that correlated best with dissociation constants for high affinity rather than for low affinity binding. We conclude that (a) the association of ligand with the high and low affinity glucagon-binding sites of isolated canine hepatocytes is a characteristic of analogs modified at diverse sites throughout the peptide hormone, (b) the different rates of dissociation of ligand from the two populations of binding sites most probably account for the biphasic dissociation of ligand from isolated cells and for the different affinities of the two receptor populations for ligand, and (c) the activity of glucagon and glucagon analogs to inhibit the incorporation of fructose into hepatocyte glycogen arises from the association of ligand with high affinity binding sites.     

Photoaffinity labeling of the glucagon receptor with a new glucagon analog

The flash excitation of the pyridoxal 5'-phosphate cofactor of glycogen phosphorylase b by an ultraviolet laser produces a transient state from a proton transfer of the bound cofactor. The rate of decay of this transient state is sensitive to the ionization state of the cofactor. This proved a useful probe for the ionization state of the 5'-phosphate group of the cofactor on the binding by the enzyme of various substrates. The decay rate data show, for the binding of glucose 1-phosphate, a partially negative 5'-HPO4- and evidence for a PO4-PO4 interaction. The data is interpreted in terms of a dynamic shift of substrates at the active site.     

GPR40 is expressed in glucagon producing cells and affects glucagon secretion

The free fatty acid receptor, GPR40, has been coupled with insulin secretion via its expression in pancreatic beta-cells. However, the role of GPR40 in the release of glucagon has not been studied and previous attempts to identify the receptor in alpha-cells have been unfruitful. Using double-staining for glucagon and GPR40 expression, we demonstrate that the two are expressed in the same cells in the periphery of mouse islets. In-R1-G9 hamster glucagonoma cells respond dose-dependently to linoleic acid stimulation by elevated phosphatidyl inositol hydrolysis and glucagon release and the cells become increasingly responsive to fatty acid stimulation when overexpressing GPR40. Isolated mouse islets also secrete glucagon in response to linoleic acid, a response that was abolished by antisense treatment against GPR40. This study demonstrates that GPR40 is present and active in pancreatic alpha-cells and puts further emphasis on the importance of this nutrient sensing receptor in islet function.     

The role of salt bridge formation in glucagon: an experimental and theoretical study of glucagon analogs and peptide fragments of glucagon

BACKGROUND: Glucagon is a 29-residue peptide produced in the alpha cells of the pancreas that interacts with hepatic receptors to stimulate glucose production and release, via a cAMP-mediated pathway. Type 2 diabetes patients may have an excess of glucagon and, as such, glucagon antagonists might serve as diabetes drugs. The antagonists that bind to the glucagon receptor but do not exhibit activity could be analogs of glucagon. The presence of salt bridges between some residues of glucagons (such as aspartic acid) and others (such as lysine) might influence both the binding to the receptor and the activity. MATERIALS AND METHODS: Experimental-The solid phase method with 4-methylbenzilhydrilamine resin (p-MBHA resin) was used for the synthesis of glucagon analogs. Rat liver membranes were prepared from male Sprague-Dawley rats by the Neville procedure. The receptor binding essay was performed in 1% BSA, 1 mM dithiothreitol, 25 mM Tris-HCl buffer, pH 7.2. Adenyl cyclase activity was measured in an assay medium containing 1% serum albumin, 25 mM MgCl2, 2 mM dithiothreitol, 0.025 mM GTP, 5 mM ATP, 0.9 mM theophylline, 17.2 mM creatine phosphate, and 1 mg/ml creatine phosphokinase. Theoretical-Quantum chemical calculations using the Titan program with the 6-31G* basis set were performed to calculate the binding energies of salt bridges between aspartic or glutamic acids and lysine. The relative stability of cyclic conformations of glucagon segments versus the extended segments was determined. RESULTS: It was found that the cyclic Glu9-Lys12 amide compound displayed a 20-fold decrease in binding affinity. DesHis1 cyclic compounds Glu20-Lys24 amide and DesHis1Glu9 Glu20-Lys24 amide behave as glucagon antagonists. The calculations show that cyclic conformations of tetrapeptidic and pentapeptidic segments of glucagon are more stable than the extended species. CONCLUSIONS: The biological data and the theoretical calculations show that an intramolecular salt bridge might impart stability to some glucagon antagonists and, when situated at the C-terminus of glucagon, might facilitate induction of an alpha-helix upon initial hormone association with the membrane bilayer. These findings might be a useful tool for the design of new glucagon antagonists.     

Fluorescent glucagon derivatives. I. Synthesis and characterisation of fluorescent glucagon derivatives

The synthesis of monofluorescein, monorhodamine, and mono-4-nitrobenz-2-oxa-1,3-diazole (NBD) derivatives of glucagon is reported. The fluorescent groups were introduced by converting tryptophan-25 to 2-thioltryptophan using thiol-specific fluorescent reagents. All derivatives retained the ability to activate adenylate cyclase when compared to glucagon and thus were considered full agonists. IC50 values of 6.8.10(-9), 1.7.10(-8), 1.8.10(-8) and 5.4.10(-9) M were measured in rat liver membranes for NBD-, fluorescein-, rhodamine-Trp25-glucagon and native glucagon, respectively. From the IC50 values Kd values of 2.16.10(-9), 4.10(-9), 2.10(-9) and 1.72.10(-9) M were calculated for the binding of NBD-, fluorescein-, rhodamine-Trp25-glucagon and native glucagon, respectively. The highest quantum yield (0.18) of the monomer derivatives was obtained with fluorescein-Trp25-glucagon in phosphate-buffered saline (pH 7.4). Difluorescein-glucagon was also prepared by reacting the amino groups of histidine-1 and lysine-12 with fluorescein isothiocyanate and dimer derivatives were prepared using fluorescein-labelled 2-thiolTrp25-glucagon. Difluorescein-glucagon bound only weakly to glucagon receptors and displayed antagonist properties. The dimer derivative formed from two difluorescein-2-thiolTrp25-glucagon molecules had similar poor binding qualities, whereas the dimer formed from difluorescein-2-thiolTrp25-glucagon and 2-thiolTrp25-glucagon exhibited, at low concentrations, properties similar to monofluorescein-glucagon. Both dimer derivatives were only sparingly soluble in aqueous medium. Specific binding of fluorescein-Trp25-glucagon and difluorescein-glucagon to rat hepatocytes was followed using flow cytometry.     

Partial purification and characterization of the glucagon receptor

Specific labeling of liver plasma membrane glucagon receptors has been achieved by the photoincorporation of a 125I-labeled photoderivative of glucagon, NE-4-azidophenylamidinoglucagon. Identification of glucagon receptors was facilitated by irradiating membranes in the presence of excess unlabeled glucagon. Isoelectric focusing of radioiodinated membrane proteins revealed one major band of glucagon displaceable material which had an isoelectric point of 5.85. When this material was isolated and run on SDS-polyacrylamide gels a major labeled band of Mr55000 was obtained which had properties consistent with those of the glucagon receptor. These studies indicate that a purification of the glucagon receptor of greater than 700-fold can be attained through the use of isoelectric focusing and SDS-polyacrylamide electrophoresis.     

Effect of glucagon antiserum on somatostatin,glucagon and insulin release from the isolated perfused rat pancreas

In order to elucidate the effect of glucagon antiserum on the endocrine pancreas, the release of somatostatin, glucagon, and insulin from the isolated perfused rat pancreas was studied following the infusion of arginine both with and without pretreatment by glucagon antiserum. Various concentrations of arginine in the presence of 5.5 mM glucose stimulated both somatostatin and glucagon secretion. However, the responses of somatostatin and glucagon were different at different doses of arginine. The infusion of glucagon antiserum strongly stimulated basal secretion in the perfusate total glucagon (free + antibody bound glucagon) and also enhanced its response to arginine, but free glucagon was undetectable in the perfusate during the infusion. On the other hand, the glucagon antiserum had no significant effect on either insulin or somatostatin secretion. Moreover, electron microscopic study revealed degrannulation and vacuolization in the cytoplasm of the A cells after exposure to glucagon antiserum, suggesting a hypersecretion of glucagon, but no significant change was found in the B cells or the D cells. We conclude that in a single pass perfusion system glucagon antiserum does not affect somatostatin or insulin secretion, although it enhances glucagon secretion.     

Identification of the glucagon receptor by covalent labeling with a radiolabeled photoreactive glucagon analogue

The photoreactive 125I-labeled glucagon-NAPS [125I-labeled 2-[2-nitro-4-azidophenyl)sulfenyl]-Trp25-glucagon] was used to label the glucagon receptor sites in rat liver plasma membranes. The proteins labeled were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis with or without reduction with dithiothreitol. The photoaffinity peptide specifically labeled a number of bands with apparent molecular weights greater than 200000 and probably at least two protein bands in the molecular weight range 52000-70000. The relative amounts of radioactivity associated with these bands and their relative mobilities differed in samples from reduced and unreduced membranes. Their relative mobilities also differed with percent acrylamide cross-linking, suggesting a glycoprotein nature and the presence of intramolecular disulfide bonds. A nonspecifically labeled band with an apparent molecular weight of 27000-28000 also displayed a similar behavior. Photolabeling in the presence of 0.1 mM guanosine 5'-triphosphate (GTP) decreased the amount of radiolabeling of these bands, suggesting their involvement in the glucagon stimulation of adenylate cyclase. The photolabeled receptor in the membranes, solubilized with Lubrol-PX and fractionated on an Ultrogel AcA22 column, eluted with an apparent molecular weight of 200000-250000. Addition of GTP to the solubilized glucagon receptor of nonirradiated membranes caused complete dissociation of the complex. Gel electrophoresis of the partially purified radiolabeled receptor identified the same protein components observed in photolabeled membranes. These results indicate that the glucagon receptor is an oligomer probably composed of at least two different subunits that are linked together or greatly stabilized by disulfide bonds. They also show that 125I-labeled glucagon-NAPS can be used effectively to covalently label the putative glucagon receptor and thus aid in its further characterization.     

Three distinct epitopes on the extracellular face of the glucagon receptor determine specificity for the glucagon amino terminus

The glucagon and glucagon-like peptide-1 (GLP-1) receptors are homologous family B seven-transmembrane (7TM) G protein-coupled receptors, and they selectively recognize the homologous peptide hormones glucagon (29 amino acids) and GLP-1 (30-31 amino acids), respectively. The amino-terminal extracellular domain of the glucagon and GLP-1 receptors (140-150 amino acids) determines specificity for the carboxyl terminus of glucagon and GLP-1, respectively. In addition, the glucagon receptor core domain (7TM helices and connecting loops) strongly determines specificity for the glucagon amino terminus. Only 4 of 15 residues are divergent in the glucagon and GLP-1 amino termini; Ser2, Gln3, Tyr10, and Lys12 in glucagon and the corresponding Ala8, Glu9, Val16, and Ser18 in GLP-1. In this study, individual substitution of these four residues of glucagon with the corresponding residues of GLP-1 decreased the affinity and potency at the glucagon receptor relative to glucagon. Substitution of distinct segments of the glucagon receptor core domain with the corresponding segments of the GLP-1 receptor rescued the affinity and potency of specific glucagon analogs. Site-directed mutagenesis identified the Asp385 --> Glu glucagon receptor mutant that specifically rescued Ala2-glucagon. The results show that three distinct epitopes of the glucagon receptor core domain determine specificity for the N terminus of glucagon. We suggest a glucagon receptor binding model in which the extracellular ends of TM2 and TM7 are close to and determine specificity for Gln3 and Ser2 of glucagon, respectively. Furthermore, the second extracellular loop and/or proximal segments of TM4 and/or TM5 are close to and determine specificity for Lys12 of glucagon.     

Studies on the complex formed between glucagon and dicaprylphosphatidylcholine

The interaction between glucagon and dicaprylphosphatidylcholine (DCPC) was studied by fluorescence, circular dichroism and calorimetry, as well as by ¹H- and ³¹P-nuclear magnetic resonance. The water-soluble lipid-protein complex was also characterized by gel filtration and ultracentrifugation. The complex appeared to be monodisperse by sedimentation equilibrium measurements, with a molecular weight of (4.55 ± 0.57)·10⁴. This complex contained approximately 7 molecules of glucagon and 35 molecules of phospholipid. Proton-decoupled ³¹P-NMR spectra of the phospholipid in the lipid-protein complex display narrower resonances than those of sonicated vesicles of DCPC, and ¹H-³¹P coupling could be detected in proton coupled spectra. These NMR results, together with gel-filtration results, suggest that glucagon ‘solubilizes’ phospholipid aggregates, forming a lipid-protein complex which is smaller than sonicated preparations of DCPC. ¹H-NMR resonance of both the methionine methyl group (met-27) and the aromatic envelope of glucagon are broadened by the phospolipid, indicating that the C-terminal region and the aromatic residues are involved in the interaction with the phospholipid. Nuclear magnetic resonance titrations of the imidazole ring C(2) and C(4) protons of the histidine residue of glucagon show that DCPC lowers the pK of the imidazole. The alterations caused by the phospholipid in the far and near ultraviolet CD spectra of glucagon reflect, respectively, the increased helix content of the hormone and the fact that the aromatic residues are located in a more structured environment. The phospholipid also alters the fluorescence properties of glucagon, shifting the fluorescence emission maximum of the hormone to shorter wavelength, and enhancing its relative intensity. This suggests that the fluorophore is experiencing a more hydrophobic environment in the presence of the lipid. Binding of glucagon to the phospholipid was analysed by Scatchard plots of the enhancement of fluorescence caused by the phospholipid and showed that the equilibrium binding constants of glucagon to DCPC are (4.4 ± 0.5)·10⁴M^?1 and (7.5±0.5)·10⁴M^?1, at 15°C and 25°C, respectively. The average number of moles of phospholipid bound per mole of glucagon is 4.4±0.6. The isothermal enthalpy of reaction of glucagon with DCPC is ?20.5 kcal/mol of glucagon at 25°C and ?32.5 kcal/mol of glucagon at 15°C. The observed enthalpies can arise from glucagon-induced cyrstallization of the phospholipid, from the non-covalent interactions between the peptide and lipid as well as from the lipid-induced conformational change in the protein. These results demonstrate that, unlike the complexes formed between glucagon and phospholipids which form more stable bilayers, the complex formed between glucagon and DCPC is stable over a wide range of temperatures, including temperatures well above the phase transition.     

Evolution of glucagon genes

Statistical analyses of DNA sequences of the preproglucagon genes from bovine, human, hamster, and anglerfish suggest that a gene duplication creating two anglerfish genes (AF I and II) occurred about 160 Myr ago, long after the separation of fish and mammals. The analyses further suggest that the internal duplication producing the glucagon and glucagon-like peptide II (GLP-II) regions occurred about 1.2 billion years ago, which would indicate that the GLP-II region was present in the ancestral anglerfish sequence but was silenced or deleted before the gene duplication separating AF I and II. The glucagon-like peptide I (GLP-I) was derived from a duplication of the ancestral glucagon region about 800 Myr ago. The rate of synonymous substitution in these genes is approximately 4.3 x 10(-9) substitutions per year per synonymous site. The rate of nonsynonymous substitution in the signal peptide region is about 1.1 x 10(-9) substitutions per year per nonsynonymous site, a high rate comparable to that in the C-peptide region of preproinsulin. The rate of nonsynonymous substitution in the glicentin-related pancreatic polypeptide (GRPP) region is 0.63 x 10(-9) for the comparisons between mammalian species and 1.8 x 10(-9) for the comparisons between fish and mammals; the moderate rate in mammals suggests a physiological role for GRPP. The glucagon region is extremely conservative; no nonsynonymous substitution is observed in the mammalian genes, and a nonsynonymous rate of 0.18 x 10(-9) was obtained from the comparisons between fish and mammals. In the GLP-I region, the rate of nonsynonymous substitution was estimated to be 0.08 x 10(-9) for the comparisons between mammalian species and 0.30 x 10(- 9) for the comparisons between fish and mammals. In the GLP-II region, the rate was estimated to be 0.25 x 10(-9) for the comparisons between mammalian species. Thus, GLP-I and II are also very conservative, which suggests an important physiological role for these peptides.