Iodoglucagon. Preparation and characterization.

Iodinated derivatives of glucagon containing an average of 1 to 5 g-atoms of 127I per mol have been prepared by reacting the hormone with increasing amounts of iodine monochloride. Their iodoamino acid composition has been determined by ion-exchange chromatography and electrophoresis, following hydrolysis by pronase. Iodination of the two tyrosyl residues occurs first and is nearly complete after addition of a 4-fold molar excess of ICl. Iodination of the single histidyl residue is a later event and does not exceed an average of one atom per residue. Hydrolysis of iodoglucagon by trypsin and subsequent separation of the iodotyrosyl peptides shows that iodine is equally distributed between tyrosyl residues 10 and 13. Crude iodoglucagon containing an average of 1 g-atom of iodine per mol has been resolved into several components of differing iodine content and iodoamino acid composition by chromatography on DEAE-cellulose. Monoiodoglucagon isolated by this procedure shows a single band when analyzed by polyacrylamide gel electrophoresis. Iodoglucagons containing an average of 1 to 4 g-atoms of iodine per mol are more potent than native glucagon in their ability to stimulate adenylate cyclase activity and to bind to glucagon receptors of liver cell membranes of the rat. The maximal increase in biological potency occurring upon iodination is about 5-fold with respect to adenylate cyclase activity, and 2-fold with respect to binding to receptors; tetra and triiodinated derivatives show, respectively, the highest potency. Similar effects occur whether inactivation by liver membranes is inhibited or not, indicating an enhancement in the intrinsic affinity of iodoglucagon for the receptors. Iodination beyong 4 g-atoms per mol slightly decreases the affinity of the hormone for adenylate cyclase and for the receptors. Iodination causes a 2-20 fold decrease in the ability of liver plasma membranes and of blood plasma to inactivate glucagon in vitro; these effects correlate with the degree of iodination. With liver microsomal membranes, a decrease in glucagon inactivation occurs only at iodine contents exceeding 4 g-atoms per mol, and lower degrees of iodination result in opposite effects. Monoiodination causes a 4-6-fold increase in the plasma concentration of glucagon within the first 18 min following a single intrvenous injection of the hormone to rats. More extensive iodination results, in addition, in a marked decrease in the rate of dissappearance of glucagon from the blood. The immunological reactivity of glucagon is little affected by monoidination, but strongly depressed by higher degrees of iodination...     

Glucagon1-6 binds to the glucagon receptor and activates hepatic adenylate cyclase.

A fragment of glucagon encompassing its first six NH2-terminal residues (His-Ser-Gln-Gly-Thr-Phe) binds to the glucagon receptor and stimulates adenylate cyclase activity in rat liver plasma membranes. Glucagon1-6 is a partial agonist since it stimulates, at saturating concentrations, to the extent of 75% of the maximal activity given by the native hormone. The binding affinity and potency of glucagon1-6 are 0.001% the native hormone. Discussed are the implications of these findings on the structure-function relationships required for the action of glucagon and for preparing clinically useful analogs of the hormone.     

Effect of insulin on glucagon binding to isolated rat epididymal adipocytes

Effect of insulin on glucagon binding to rat epididymal adipocytes was studied in vitro. [125I]iodoglucagon binding to isolated adipocytes was increased by preincubation of the cells with insulin. Maximal increase was observed with 7 X 10(-10) M insulin. In Scatchard analysis, [125I]iodoglucagon competition data generated one binding site with a single affinity for glucagon binding in the cells pretreated with buffer alone. Pretreatment of the cells with insulin increased the affinity without changes in the number of binding sites. [125I]iodoglucagon binding to isolated adipocytes was not affected by pretreatment of the cells with luteinizing hormone, follicle-stimulating hormone, growth hormone, or with prolactin. These results suggest that insulin stimulates glucagon binding to adipocytes.     

Iodination of the progesterone receptor from hen oviduct spares the DNA-binding domain

The progesterone receptor from hen oviduct is isolated as a complex of two subunits, A and B. The A protein binds one molecule of progesterone and also binds to DNA with high affinity. The native A protein can be labeled with iodine with no loss of DNA binding activity. Limited Staphylococcus aureus V8 protease digestion of the labeled preparation results in a number of DNA-binding and non-DNA-binding fragments of the receptor. The progesterone-binding domain contains iodine label. However, two low-molecular-weight DNA-binding fragments do not contain iodine label, indicating a lack of susceptible tyrosine residues near the DNA-binding site of the native receptor. The labeled receptor and its fragments will facilitate studies of the isolated DNA-binding and progesterone-binding domains of the hen A protein as well as of the activity of the native receptor in the presence and absence of hormone.     

High-performance liquid chromatography of iodine-labeled insulin and glucagon derivatives with on-line γ-detection

Insulin and glucagon were labeled with iodine. The reaction products were analyzed by high-performance liquid chromatography. It is shown that the pH of the reaction medium has a large effect on the position and the degree of iodine substitution as well as on the oxidation of the Met-containing glucagon and, furthermore, that the molar ratio of iodine to polypeptide hormone used during the labeling procedure affects not only the amount of iodine incorporated but also the distribution of iodinated products. The results show that certain iodinated derivatives are separated from each other and from the respective unlabeled polypeptide and thus can be obtained in a pure state.     

High-performance liquid chromatography of iodine-labeled insulin and glucagon derivatives with on-line gamma-detection

Insulin and glucagon were labeled with iodine. The reaction products were analyzed by high-performance liquid chromatography. It is shown that the pH of the reaction medium has a large effect on the position and the degree of iodine substitution as well as on the oxidation of the Met-containing glucagon and, furthermore, that the molar ratio of iodine to polypeptide hormone used during the labeling procedure affects not only the amount of iodine incorporated but also the distribution of iodinated products. The results show that certain iodinated derivatives are separated from each other and from the respective unlabeled polypeptide and thus can be obtained in a pure state.     

Partial agonism in the glucagon receptor system is a consequence of the two-state rat hepatic receptor

We have previously demonstrated that the glucagon receptor binds hormone to form a low affinity complex which, by a time- and temperature-dependent mechanism, is converted to a high affinity complex (Horwitz, E.M., Jenkins, W.T., Hoosein, N.M., and Gurd, R.S. (1985) J. Biol. Chem. 260, 9307-9315). In this report we have investigated the effects of agonist concentration, potency, and intrinsic activity on the characteristics of the two, interconvertible states of the glucagon receptor. As the glucagon concentration is increased from 0.02 to 0.50 nM, the initial velocity of binding increases. The conversion of a low affinity to a high affinity complex is the rate-limiting step in the overall binding reaction and approaches its maximal velocity as the hormone concentration exceeds 0.20 nM. At equilibrium, 87-90% of the hormone-receptor complexes are in the high affinity state at all hormone concentrations examined. [S-methyl-Met27]glucagon, a full agonist with reduced potency, binds to the two-state system in a manner analogous to that of native glucagon. The binding of N alpha-biotinyl-N epsilon-acetimidoglucagon, a partial agonist with reduced potency, effects a two-state system where the high affinity state accounts for only 35% of the total hormone-receptor complexes at equilibrium. We conclude that the formation of the high affinity complex is the rate-limiting step involved in glucagon binding; reduction in binding potency with full agonism is due to a reduction in the affinity of the ligand for the unoccupied receptor and not to an alteration of the interconversion of the two states, and decreased intrinsic activity is due to a quantitative decrease in conversion of the low to high affinity state.     

Structure-function relationships in glucagon: properties of highly purified des-His-1-, monoiodo-, and (des-Asn-28, Thr-29)(homoserine lactone-27)-glucagon.

We have compared the ability of glucagon and three highly purified derivatives of the hormone to activate hepatic adenylate cyclase (an expression of biological activity of the hormone) and to compete with [125]glucagon for binding to sites specific for glucagon in hepatic plasma membranes. Relative to that of glucagon, biological activity and affinity of [des-Asn-28,Thr-29](homoserine lactone-27)-glucagon, prepared by CNBr treatment of glucagon, were reduced equally by 40- to 50-fold. By contrast, des-His-1-glucagon, prepared by an insoluble Edman reagent and highly purified (less than 0.5% contamination with native glucagon), displayed a 15-fold decrease in affinity but a 50-fold decrease in biological activity relative to that of the native hormone. At maximal stimulating concentrations, des-His-1-glucagon yielded 70% of the activity given by saturating concentrations of glucagon. Thus, des-His-1-glucagon can be classified as a partial weak agonist. Highly purified monoiodoglucagon and native glucagon displayed identical biological activity and affinity for the binding sites. Our findings suggest that the hydrophilic residues at the terminus of the carboxy region of glucagon are involved in the process of recognition at the glucagon receptor but do not participate in the sequence of events leading to activation of adenylate cyclase. The amino-terminal histidyl residue in glucagon plays an important but not obligatory role in the expression of hormone action and contributes to a significant extent in the recognition process.     

Iodination of Ricin D

Approximately five tyrosine residues of ricin D were iodinated preferentially under appropriate conditions probably forming diiodotyrosine. Iodination of this toxin carried out in 0.1 m phosphate buffer at pH 7.0 and 0°C for 60 min with a 20 fold molar excess of iodine per mole of protein, yielded a main component which appeared as a single band on polyacrylamide gel disc electrophoresis. Analysis of protein-bound radioactivity and the content of diiodotyrosine of ¹⁸¹I-labeled ricin D revealed that two tyrosine residues in the isoleucyl chain and three in the alanyl chain were substituted. The toxicity of iodinated ricin D decreased to one hundredth of that of native protein, However, the hemagglutinating activity of this protein was not affected by the iodination reaction.     

Glucagon receptors on isolated hepatocytes and hepatocyte membrane vesicles. Discrete populations with ligand- and environment-dependent affinities

Analysis of glucagon and deshistidine glucagon binding to isolated canine hepatocytes and to hepatocyte membrane vesicles (formed by budding of hepatocytes in hypotonic medium) reveals two separate populations of hormone binding sites. Mathematical modeling further shows that the high affinity population represents 1% of the total in all four cases. Although calculated dissociation constants for hormone binding range from 0.2 to 400 nM, whether considering glucagon or deshistidine glucagon binding, or binding to the high affinity or low affinity receptor populations, receptor affinity increases 2- to 100-fold in the environment of the membrane vesicle; concomitant with this alteration in receptor affinity, receptor selectivity for the structure of the native hormone decreases 1.5- to 40-fold in hepatocyte-derived vesicles. Consideration of receptor affinity in relation to receptor number suggests that hepatocyte glucagon binding is distributed about equally between high and low affinity receptor populations at typical portal hormone levels. Nevertheless, consideration of receptor binding in relation to biological activity suggests that the activity of glucagon in inhibiting carbohydrate flux into glycogen is attributable to occupancy of the high affinity receptor population.     

Effects of iodination on the distribution of peptide hormones in aqueous two-phase polymer systems

1. The effect of iodination on the distribution of peptide hormones into the aqueous two-phase dextran-polyethylene glycol system and on the solubility of these hormones in aqueous polyethylene glycol and in water was assessed. Hormones that were studied included insulin, glucagon and parathyroid hormone. 2. The partition coefficient of native insulin in the dextran-polyethylene glycol system showed a minimum (about 1) near the isoelectric point of the hormone (pH 5). Partial iodination of insulin (one atom per molecule) caused little change in the distribution of the hormone. More extensive iodination markedly decreased the partition coefficient in the region of the isoelectric point and displaced the pH value at which the partition coefficient was a minimum towards lower values. 3. The solubility of native insulin in aqueous polyethylene glycol and in water showed a pH-dependence similar to that observed for the distribution in the dextran-polyethylene glycol system. Iodination of insulin decreased the solubility of the hormone in polyethylene glycol and in water in parallel, and decreased the pH value at which solubility was a minimum. The changes in solubility correlated with the degree of iodination and accounted for the changes in distribution observed at high concentrations of insulin. 4. Comparable effects of iodination on distribution and solubility were also observed with glucagon. 5. At concentrations of insulin below its maximum solubility, serum proteins caused a decrease in the partition coefficient of iodinated hormone, but not of native hormone. These effects correlated with the degree of iodination and resulted from a co-precipitation of iodinated insulin with serum proteins.     

Thyrotropin receptors in normal human thyroid. Nonclassical binding kinetics not explained by the negative cooperativity model

Saturation analysis of equilibrium binding of iodinated thyrotropin (125I-TSH) to normal human thyroid preparations yielded linear Scatchard plots under non-physiological conditions of pH 6.0 or 20 mM Tris/acetate buffer, pH 7.4. The apparent equilibrium dissociation constant of this binding was approximately 10(-8) M. By contrast, nonlinear plots were obtained under standard conditions of pH 7.4 and 40 mM Tris/acetate buffer. Resolution of the components of these curves by computer analysis revealed the presence of at least two classes of binding sites, one of which is of a low capacity and high affinity (approximately 10(-10) M) consistent with receptor binding. The other component is of a high capacity and lower affinity. Binding to non-target tissues of muscle, parathyroid, mammary carcinoma, and placenta was only demonstrable at pH 6.0 or in 20 mM Tris/acetate buffer, pH 7.4, yielding linear Scatchard plots with similar binding affinity (approximately 10(-8)M) to normal thyroid but much reduced capacity. Preincubation of thyroid tissue at 50 degrees C resulted in an apparent selective loss of the high affinity component of binding measured under standard conditions. Kinetic experiments on the dissociation of bound 125I-TSH were undertaken to determine whether the non-linearity of Scatchard plots was due to two or more classes of binding sites or negative cooperativity. It was found that the experimental determinant that is presently ascribed to a negative cooperativity phenomenon regulating receptor affinity (i.e. an enhanced dilution-induced dissociation rate in the presence of excess native hormone), although apparently hormone-specific, was demonstrated under nonphysiological binding conditions and in non-target tissue. Significantly, the phenomenon was found under conditions of pH 6.0 or 20 mM Tris where a linear Scatchard plot was obtained. The evidence thus suggests that 125I-TSH binds to heterogeneous binding sites (of which the high affinity is probably the receptor for TSH) and that the enhanced dilution-induced dissociation of bound hormone by native hormone for this system, is only a characteristic of the low affinity binding site (maybe gangliosides).     

Effects of GTP on binding of (3H) glucagon to receptors in rat hepatic plasma membranes.

In this study, we report the preparation of [3H]glucagon and its characteristics of binding to receptors in the rat liver plasma membrane. Binding of the labeled hormone is optimal at pH 7.0. In the absence of GTP, [3H]glucagon binding to receptors is slow and the time of equilibration is inversely proportional to the hormone concentration. In the presence of GTP, equilibrium is reached within 30 s regardless of hormone levels, and the kinetics of binding are in accord with the kinetics of activation of adenylate cyclase by native glucagon in the presence of the nucleotide. Equilibrium binding measurements indicate that, in the absence of GTP, the binding isotherm is sigmoidal with an apparent Kd of 2 nM. The addition of GTP results in a complex binding isotherm with about 90% of the binding sites having a considerably lower apparent dissociation constant (greater than 10 nM) and a small population of sites having high affinity for the hormone. The binding properties of [3H]glucagon are compared with those of 125I-glucagon, and the implications of the actions of GTP on glucagon binding are discussed in relation to the overall regulation of adenylate cyclase by hormone and the nucleotide.     

Semisynthetic D-His1,N epsilon-acetimidoglucagon: structure-function relationships

The histidine residue at the amino terminus of lysine-12 protected glucagon was replaced by its D-isomer by an established semisynthetic strategy to extend a stepwise series of replacements at this position. The product was examined for its secondary structure and its function. Circular dichroism spectra obtained at concentrations from 0.25 to 1.09 mg/ml at pH 10.2 in 0.2 M phosphate buffer were similar to those obtained with native hormone. Competitive binding assays and adenylate cyclase activation assays with partially purified rat liver plasma membranes show this D-His1 analog of glucagon to be a full agonist, causing the same maximum activation of adenylate cyclase as native hormone; but both binding and activation assays show the binding affinity to be diminished about 10-fold. The data suggest that the adjustment of the bonding of the imidazole group to the receptor to bring about transduction results in constraints on the conformation along the peptide sequence which interfere with the peptide adopting the same binding conformation achieved by the native hormone.     

The role of nonspecific hydrophobic interactions in the biological activity of N epsilon-acyl derivatives of glucagon. Studies of conformation, receptor binding, and adenylate cyclase activation

Glucagon was acylated at position 12 using conditions favoring reaction with the epsilon-amino group of lysine. The N epsilon-acetyl, N epsilon-hexanoyl, and N epsilon-decanoyl derivatives were prepared and purified. Secondary structure as measured by circular dichroism was lower in all derivatives than in glucagon, both in 95% methanol and in 25 mM sodium dodecyl sulfate at pH 2 and pH 12. N epsilon-Acetyl glucagon was less active than the native hormone in a radioreceptor assay and higher concentrations of this derivative were required to stimulate the adenylate cyclase activity of rat liver plasma membranes. The maximal extent of cyclase activation by this derivative was less than that found with the native hormone. N epsilon-Hexanoyl glucagon and N epsilon-decanoyl glucagon had greater activity than N epsilon-acetyl glucagon in receptor binding as well as in adenylate cyclase activation, although these two derivatives were not as active as the native hormone. N epsilon-hexanoyl glucagon and N epsilon-decanoyl glucagon were more potent in receptor binding than in adenylate cyclase activation. From these results it appears that the positive charge of the epsilon-amino groups may have a specific role in obtaining maximal biological activity, while the acyl groups contribute to the nonspecific hydrophobic interactions between the hormone and its receptor. In addition, a possible relationship between stabilization of the amphipathic helix in solution and the activity of these and other N epsilon-derivatives of glucagon is discussed.     

Non-equivalence of the carboxyl groups of glucagon in the carbodiimide-promoted reaction with nucleophiles and the role of carboxyl groups in the ability of glucagon to stimulate the adenyl cyclase of rat liver

The polypeptide hormone glucagon can react with the nucleophiles; glycinamide, taurine or ethylenediamine in the presence of 1-ethyl-3-(3-dimethylaminopropylcarbodiimide). The number of carboxyl groups which are modified depend on the concentration of guanidine hydrochloride in the reaction media. These results demonstrate an additional property which glucagon possesses in common with larger globular proteins and suggests that the hormone has a specific, folded structure in dilute aqueous solution. In the absence of guanidine hydrochloride only one taurine residue is incorporated into the terminal carboxyl group of the peptide. In 7 M guanidine hydrochloride all four of the carboxyl groups react with glycinamide or taurine while only two and a half residues of ethylenediamine are incorporated. All of these derivatives and glucagon have identical circular dichroism spectra in dilute aqueous solution. The taurine modified derivative has greatly enhanced solubility compared with glucagon but still associates to structures of higher helical content. Both of the taurine derivatives of glucagon have the ability to stimulate the adenyl cyclase of rat liver membranes but at concentrations several fold higher than is needed for the native hormone. It is suggested that each carboxyl group contributes to the binding of the hormone to the specific membrane receptor sites.     

Specific binding of covalently cross-linked mouse nerve growth factor to responsive peripheral neurons.

The binding characteristics of [¹²⁵I]nerve growth factor, covalently cross-linked with dimethyl suberimidate, to chick embryonic dorsal root ganglia are indistinguishable from the iodinated native hormone. Both show non-saturability, non-linear Scatchard plots and acceleration of dissociation of hormone-receptor complexes by native hormone which is reflected in the binding constants calculated. These results demonstrate that dimerization of the native hormone at the receptor is not responsible for the negatively cooperative behavior observed for native nerve growth factor. Further, experiments with amino-silylated glass tubes also eliminate interaction between hormone and reaction vessel as an explanation of the non-saturable and multiple affinity properties of the observed binding.     

Development of prolactin receptor antagonists with reduced pH‐dependence of receptor binding

The cytokine hormone prolactin has a vast number of diverse functions. Unfortunately, it also exhibits tumor growth promoting properties, which makes the development of prolactin receptor antagonists a priority. Prolactin binds to its cognate receptor with much lower affinity at low pH than at physiological pH and since the extracellular environment around solid tumors often is acidic, it is desirable to develop antagonists that have improved binding affinity at low pH. The pK_a value of a histidine side chain is ～6.8 making histidine residues obvious candidates for examination. From evaluation of known molecular structures of human prolactin, of the prolactin receptor and of different complexes of the two, three histidine residues in the hormone–receptor binding site 1 were selected for mutational studies. We analyzed 10 variants by circular dichroism spectroscopy, affinity and thermodynamic characterization of receptor binding by isothermal titration calorimetry combined with in vitro bioactivity in living cells. Histidine residue 27 was recognized as a central hot spot for pH sensitivity and conservative substitutions at this site resulted in strong receptor binding at low pH. Pure antagonists were developed earlier and the histidine mutations were introduced within such background. The antagonistic properties were maintained and the high affinity at low pH conserved. The implications of these findings may open new areas of research in the field of prolactin cancer biology. Copyright © 2010 John Wiley & Sons, Ltd.     

Practical considerations in analyzing radioreceptor assays by Scatchard analysis and capacity determination in irreversible hormone receptor interactions

The Scatchard plot in a radioreceptor assay depends upon the definition of specific binding and the quality of the iodinated hormone used. Iodination of protein hormones may alter it so that it no longer binds to the receptor and methods are available to measure the extent of this inactivation. When appropriate corrections are made for specific binding and the amount of inactive iodinated hormone in an assay, both qualitative and quantitative differences were observed in estimates of binding capacity and affinity in some well characterised hormone receptor systems. Theoretical predictions derived from Scatchard analysis of irreversible unimolecular hormone-receptor interactions were applicable, both qualitatively and quantitatively to two irreversible hormone-receptor systems. A method described permits a more accurate estimate of capacity from radioreceptor assay data.     

Roles of specific extracellular domains of the glucagon receptor in ligand binding and signaling

To identify structural determinants of ligand binding in the glucagon receptor, eight receptor chimeras and additional receptor point mutants were prepared and studied. Amino acid residues 103-117 and 126-137 in the extracellular N-terminal tail and residues 206-219 and 220-231 in the first extracellular loop of the glucagon receptor were replaced with the corresponding segments of the glucagon-like peptide-1 receptor or the secretin receptor. Specific segments of both the N-terminal tail and the first extracellular loop of the glucagon receptor are required for hormone binding. The 206-219 segment of the first loop appears to be important for both glucagon binding and receptor activation. Functional studies with a synthetic chimeric peptide consisting of the N-terminal 14 residues of glucagon and the C-terminal 17 residues of glucagon-like peptide 1 suggest that hormone binding specificity may involve this segment of the first loop. The binding selectivity may arise in part from aspartic acid residues in this segment. Mutation of R-202 located at the junction between the second transmembrane helix and the first loop resulted in a mutant receptor that failed to bind glucagon or signal. We conclude that high-affinity glucagon binding requires multiple contacts with residues in the N-terminal tail and first extracellular loop domain of the glucagon receptor, with hormone specificity arising primarily from the amino acid 206-219 segment. The data suggest a model whereby glucagon first interacts with the N-terminal domain of the receptor followed by more specific interactions between the N-terminal half of the peptide and the first extracellular loop of the receptor, leading to activation.