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Query: UNIPROT:P01275 (
glucagon
)
26,492
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The identification of position 9
aspartic acid
in
glucagon
as a critical residue for transduction reinforced the notion that specific residues in the peptide sequence dictate either receptor recognition or biological activity. It was evident from our studies that Asp9 operates in conjunction with His1 as part of the activation mechanism that follows binding to the glucagon receptor. This investigation was conducted to delineate structural features of histidine that contribute to its role in
glucagon
action. We report, based on binding and activity data from 10 replacement analogs, that the imidazole ring of His1 furnishes an aromatic determinant for receptor binding affinity and that its protonatable imidazole nitrogen is important for transduction.
...
PMID:The role of histidine-1 in glucagon action. 838 34
Glucagon
-like peptide-1(7-36)amide (GLP-1(7-36)amide) and its own receptor have been found in the hypothalamus and brain stem of the rat. In an attempt to gain further insight into the role of this peptide in brain functioning we investigated the effects of GLP-1 (7-36)amide on the release of excitatory amino acid neurotransmitters by the ventromedial hypothalamus using an experimental microdialysis approach. GLP-1(7-36)amide produced an immediate increase in the extracellular concentrations of
aspartic acid
and glutamine, p < 0.01 and p < 0.05, respectively. By contrast, extracellular concentrations of glutamic acid, alanine, threonine, and tyrosine were unaffected. The results of this study show a stimulatory effect of GLP-1(7-36)amide on the release of
aspartic acid
and glutamine by the ventromedial hypothalamus of the rat.
...
PMID:Glucagon-like peptide-1(7-36)amide induces the release of aspartic acid and glutamine by the ventromedial hypothalamus of the conscious rat. 866 66
Extensive evidence gathered from structure-activity relationship analysis has identified and confirmed specific positions in the
glucagon
sequence that are important either for binding to its receptor or for signal transduction. Fifteen
glucagon
analogues have been designed and synthesized by incorporating structural changes in the N-terminal region of
glucagon
, in particular histidine-1, phenylalanine-6, and
aspartic acid
-9. This investigation was conducted to study the role of phenylalanine at position 6 on the
glucagon
mechanism of action. These
glucagon
analogues have been made by either deleting or substituting hydrophobic groups, hydrophilic groups, aromatic amino acids, or a D-phenylalanine residue at this position. The structures of the new analogues are as follows: [des-His1, des-Phe6, Glu9]
glucagon
-NH2 (1); [des-His1,Ala6,Glu9]
glucagon
-NH2 (2); [des-His1,Tyr6,Glu9]
glucagon
-NH2 (3); [des-His1,Trp6,Glu9]-
glucagon
-NH2 (4); [des-His1,D-Phe6,Glu9]
glucagon
-NH2 (5); [des-His1,Nle6,Glu9]
glucagon
-NH2 (6); [des-His1,Asp6,Glu9]
glucagon
-NH2 (7); [des-His1,des-Gly4,Glu9]
glucagon
-NH2 (8); [desPhe6,-Glu9]
glucagon
-NH2 (9); [des-Phe6]
glucagon
-NH2 (10); [des-His1, des-Phe6]
glucagon
-NH2 (11); [des-His1, des-Phe6,Glu9]
glucagon
(12); [des-Phe6,Glu9]
glucagon
(13); [des-Phe6]
glucagon
(14); and [des-His1, des-Phe6]
glucagon
(15). The receptor binding potencies IC50 values are 48 (1), 126 (2), 40 (3), 19 (4), 100 (5), 48 (6), 2000 (7), 52 (8), 113 (9), 512 (10), 128 (11), 1000 (12), 2000 (13), 500 (14), and 200 nM (15). All analogues were found to be antagonists unable to activate the adenylate cyclase system even at concentrations as high as 10(-5) M except for analogues 6 and 8, which were found to be weak partial agonists/partial antagonists with maximum stimulation between 6-12%. In competitive inhibition experiments, all the analogues caused a right shift of the
glucagon
-stimulated adenylate cyclase dose-response curve. The pA2 values were 8.20 (1), 6.40 (2), 6.20 (3), 6.25 (4), 6.30 (5), 6.30 (7), 6.05 (8), 6.20 (9), 6.30 (10), 6.25 (11), 6.10 (12), 6.20 (13), 6.20 (14), and 6.35 (15).
...
PMID:The role of phenylalanine at position 6 in glucagon's mechanism of biological action: multiple replacement analogues of glucagon. 925 62
Glucagon
is a peptide hormone that plays a central role in the maintenance of normal circulating glucose levels. Structure-activity studies have previously demonstrated the importance of histidine at position 1 and the absolute requirement for
aspartic acid
at position 9 for transduction of the hormonal signal. Site-directed mutagenesis of the receptor protein identified Asp64 on the extracellular N-terminal tail to be crucial for the recognition function of the receptor. In addition, antibodies generated against
aspartic acid
-rich epitopes from the extracellular region competed effectively with
glucagon
for receptor sites, which suggested that negative charges may line the putative
glucagon
binding pocket in the receptor. These observations led to the idea that positively charged residues on the hormone may act as counterions to these sites. Based on these initial findings, we synthesized
glucagon
analogs in which basic residues at positions 12, 17, and 18 were replaced with neutral or acidic residues to examine the effect of altering the positive charge on those sites on binding and adenylyl cyclase activity. The results indicate that unlike N-terminal histidine, Lys12, Arg17, and Arg18 of
glucagon
have very large effects on receptor binding and transduction of the hormonal signal, although they are not absolutely critical. They contribute strongly to the stabilization of the binding interaction with the glucagon receptor that leads to maximum biological potency.
...
PMID:Positively charged residues at positions 12, 17, and 18 of glucagon ensure maximum biological potency. 955 84
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.
...
PMID:Roles of specific extracellular domains of the glucagon receptor in ligand binding and signaling. 1226 22
Aspartame has been previously shown to increase satiety. This study aimed to investigate a possible role for the satiety hormones cholecystokinin (CCK) and
glucagon
-like peptide-1 (GLP-1) in this effect. The effects of the constituents of aspartame, phenylalanine and
aspartic acid
, were also examined. Six subjects consumed an encapsulated preload consisting of either 400 mg aspartame, 176 mg aspartic acid+224 mg phenylalanine, or 400 mg corn flour (control), with 1.5 g paracetamol dissolved in 450 ml water to measure gastric emptying. A 1983-kJ liquid meal was consumed 60 min later. Plasma CCK, GLP-1, glucose-dependent insulinotropic polypeptide (GIP), glucose, and insulin were measured over 0-120 min. Gastric emptying was measured from 0 to 60 min. Plasma GLP-1 concentrations decreased following the liquid meal (60-120 min) after both the aspartame and amino acids preloads (control, 2096.9 pmol/l min; aspartame, 536.6 pmol/l min; amino acids, 861.8 pmol/l min; incremental area under the curve [AUC] 60-120 min, P<.05). Desire to eat was reduced from 60 to 120 min following the amino acids preload (control, -337.1 mm min; aspartame, -505.4 mm min; amino acids, -1497.1 mm min; incremental AUC 60-120 min, P<.05). However, gastric emptying rates, plasma CCK, GIP, insulin, and glucose concentrations were unaffected. There was a correlation between the increase in plasma phenylalanine and decrease in desire to eat after the liquid meal following the constituent amino acids (r=-.9774, P=.004). In conclusion, it is unlikely that aspartame increases satiety via CCK- or GLP-1-mediated mechanisms, but small changes in circulating phenylalanine concentrations may influence appetite.
...
PMID:Physiological mechanisms mediating aspartame-induced satiety. 1278 8
In this study, the polypeptide hormone
glucagon
was used as a model to investigate the mechanisms of
aspartic acid
cleavage and glutaminyl deamidation in acidic aqueous solutions. Kinetic studies have shown that cleavage at Asp-21 occurred at significantly slower rates than at Asp-9 and Asp-15 while deamidation rates were similar at the three Gln residues. The role of side-chain ionization in the cleavage mechanism was investigated by determining the pK(a) values of the three Asp residues using TOCSY and NOESY NMR methods. The role of proton transfer was investigated using kinetic solvent isotope effect studies (KSIE). The pK(a) values for the sidechains of Asp-9, Asp-15, and Asp-21 were found to be 3.69, 3.72, and 4.05 respectively. No kinetic solvent isotope effect was observed for the cleavage reaction whereas an inverse effect was observed for deamidation. Based on the lack of sequence effects, pH-rate behavior, and KSIE, the deamidation mechanism was proposed to involve direct hydrolysis of the amide side-chain by water. Based on substrate ionization, pH-rate profiles, and KSIE, the proposed mechanism for Asp cleavage involved nucleophilic attack of the ionized side-chain carboxylate on the protonated carbonyl carbon of the peptide bond to give a cyclic anhydride intermediate.
...
PMID:Studies on the mechanism of aspartic acid cleavage and glutamine deamidation in the acidic degradation of glucagon. 1605 57
Ghrelin is produced by A-like cells (ghrelin cells) in the mucosa of the acid-producing part of the stomach. The mobilization of ghrelin is stimulated by nutritional deficiency and suppressed by nutritional abundance. In an attempt to identify neurotransmitters and regulatory peptides that may contribute to the physiological, nutrient-related regulation of ghrelin secretion, we challenged the ghrelin cells in situ with a wide variety of candidate messengers, including known neurotransmitters (e.g. acetylcholine, catecholamines), candidate neurotransmitters (e.g. neuropeptides), local tissue hormones (e.g. serotonin, histamine, bradykinin, endothelin), circulating gut hormones (e.g. gastrin, CCK, GIP, neurotensin, PYY, secretin) and other circulating hormones/regulatory peptides (e.g. calcitonin,
glucagon
, insulin, PTH). Microdialysis probes were placed in the submucosa of the acid-producing part of the rat stomach. Three days later, the putative messenger compounds were administered via the microdialysis probe (reverse microdialysis) at a screening dose of 0.1 mmol l(-1) for regulatory peptides and 0.1 and 1 mmol l(-1) for amines and amino acids. The rats were awake during the experiments. The resulting microdialysate ghrelin concentration was monitored continuously for 3 h (radioimmunoassay), thereby revealing stimulators or inhibitors of ghrelin secretion. Dose-response curves were constructed for each candidate messenger that significantly (p<0.05) affected ghrelin mobilization at the screening dose. Peptides that showed a (non-significant) tendency to affect ghrelin release at the screening dose were also given at a dose of 0.3 or 1 mmol l(-1). Adrenaline, noradrenaline, endothelin and secretin stimulated ghrelin release, while somatostatin and GRP inhibited. Whether these agents act directly or indirectly on the ghrelin cells remains to be investigated. All other candidate messengers were without measurable effects, including acetylcholine, serotonin, histamine, GABA,
aspartic acid
, glutamic acid, glycine, VIP, PACAP, CGRP, substance P, NPY, PYY, PP, gastrin, CCK, GIP, insulin,
glucagon
, GLP and glucose.
...
PMID:Secretion of ghrelin from rat stomach ghrelin cells in response to local microinfusion of candidate messenger compounds: a microdialysis study. 1757 35
Previous studies in children with diabetes found that hyperglycemia induces memory dysfunction. In this study, we investigated memory and synaptic plasticity in streptozotocine (STZ)-induced diabetic rats during the juvenile period. We further investigated the effects of
glucagon
-like peptide-1 (GLP-1) on the diabetes-induced profiles. STZ (85 mg/kg, i.p.) was administered to 17-day-old Wistar rats to induce type-1 juvenile diabetes mellitus (JDM). In the Y-maze test, JDM rats showed significant impairment of learning and memory, which were improved by GLP-1 (7-36) amide (1 microg/5 microl/rat, i.c.v.). Extracellular recording at Schaffer collateral synapses in the CA1 region of hippocampal slices showed that long-term potentiation and paired-pulse facilitation in JDM rats were similar to age-matched control rats. However, the input-output relation was strengthened, and long-term depression (LTD) and responses of N-methyl d-
aspartic acid
through NR2B subunits were weakened in the JDM rats. GLP-1 (7-36) amide (100 nM) increased the magnitude of LTD and the responses through NR2B in the JDM rats. These results indicate that the lack of LTD and NR2B responses may contribute to impairment of memory associated with JDM, suggesting the potential usefulness of GLP-1 in the treatment of memory dysfunction in JDM.
...
PMID:The influences of juvenile diabetes on memory and hippocampal plasticity in rats: improving effects of glucagon-like peptide-1. 1932 Nov 33
Receptor targeting with radiolabelled peptides has become very important in nuclear medicine and oncology in the past few years. The overexpression of many peptide receptors in numerous cancers, compared to their relatively low density in physiological organs, represents the molecular basis for in vivo imaging and targeted radionuclide therapy with radiolabelled peptide-based probes. The prototypes are analogs of somatostatin which are routinely used in the clinic. More recent developments include somatostatin analogs with a broader receptor subtype profile or with antagonistic properties. Many other peptide families such as bombesin, cholecystokinin/gastrin,
glucagon
-like peptide-1 (GLP-1)/exendin, arginine-glycine-
aspartic acid
(RGD) etc. have been explored during the last few years and quite a number of potential radiolabelled probes have been derived from them. On the other hand, a variety of strategies and optimized protocols for efficient labelling of peptides with clinically relevant radionuclides such as (99m)Tc, M(3+) radiometals ((111)In, (86/90)Y, (177)Lu, (67/68)Ga), (64/67)Cu, (18)F or radioisotopes of iodine have been developed. The labelling approaches include direct labelling, the use of bifunctional chelators or prosthetic groups. The choice of the labelling approach is driven by the nature and the chemical properties of the radionuclide. Additionally, chemical strategies, including modification of the amino acid sequence and introduction of linkers/spacers with different characteristics, have been explored for the improvement of the overall performance of the radiopeptides, e.g. metabolic stability and pharmacokinetics. Herein, we discuss the development of peptides as radiopharmaceuticals starting from the choice of the labelling method and the conditions to the design and optimization of the peptide probe, as well as some recent developments, focusing on a selected list of peptide families, including somatostatin, bombesin, cholecystokinin/gastrin, GLP-1/exendin and RGD.
...
PMID:Radiopharmaceutical development of radiolabelled peptides. 2238 24
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