UNIPROT:P01275 - FACTA Search

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Query: UNIPROT:P01275 (glucagon)
26,492 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Examination of insulin and glucagon degradation by rat kidney subcellular fractions revealed that most degrading activity was localized to the 100 000 X g pellet and 100 000 X g supernatant fractions. Further characterization of the degrading activities of the 100 000 X g pellet and supernatant suggested that three types of enzymatic activity were present at neutral pH. From the cytosol an enzyme with characteristics of the insulin glucagon protease of skeletal muscle was purified. This enzyme appeared to be responsible for insulin degradation by the kidney at physiological insulin concentrations. This enzyme also contributed to glucagon degradation but was not the most active mechanism for this. In the 100 000 X g pellet at least two separate enzymatic activities were present. One of these had properties consistent with those described for glutathione insulin transhydrogenase and appeared to be responsible for insulin degradation at high insulin concentration. The other enzyme was associated with the brush border and had properties consistent with the brush border neutral protease. This enzyme appeared responsible for glucagon degradation at both low and high substrate concentrations. An apparent marked synergism between the 100 000 X g pellet and the 100 000 X g supernatant was noted for insulin degradation at physiological insulin concentrations. Pellet glucagon-degrading activity and soluble insulin-degrading activity were necessary for this. The mechanism was found to be limited insulin degradation by the soluble enzyme resulting in both trichloroacetic acid-precipitable trichloroacetic acid-soluble fragments followed by further degradtion of the fragments by the glucagon-degrading enzyme resulting in an additional increase in trichloroacetic acid-soluble products.
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PMID:Insulin and glucagon degradation by the kidney. II. Characterization of the mechanisms at neutral pH. 0 6

Cyclic GMP and cyclic AMP have been localized in rat liver, small intestine, and testis by a fluorescent immunocytochemical procedure. In liver, cyclic AMP is distributed along sinusoids predominantly, and increased fluorescence is seen sinusoidal areas after glucagon administration. Cyclic GMP is located in nuclear elements and on the plasma membranes of hepatocytes. In jejunum, cyclic AMP is found predominantly at the basal and lateral sides of brush border cells and in the lamina propria, while cyclic GMP is located to the brush border membrane, smooth muscle, and nuclear elements. In testis, cyclic AMP is found in cytoplasm of cells at the perimeter of the seminiferrous tubules and in interstitial cells, while cyclic AMP is visualized on the plasma membrane of the cells lining the tubules. Cyclic GMP is also seen on chromosomes of premeiotic spermatocytes and in sperm. These data provide histological evidence implicating diverse roles for the nucleotides in these tissues. The nuclear localization of cyclic GMP in all of these tissues suggests a role for the nucleotide in nucleus-directed events.
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PMID:Immunohistochemical localization of 3': 5'-cyclic AMP and 3': 5'-cyclic GMP in rat liver, intestine, and testis. 16 76

The possible trophic influence of the capsaicin-sensitive extrinsic innervation of the gastrointestinal mucosa was investigated. Rats were treated neonatally with capsaicin. The gastrointestinal content of serotonin and glucagon-like immunoreactivity were used as a measure of the effect on the endocrine gut mucosa and gastrointestinal aminopeptidase and alkaline phosphatase activities were used as a measure of the effect on the gut brush-border. The gastrointestinal content of the neuropeptides substance P, VIP and CGRP were used to monitor effects on the innervation of the gut. The depletion of substance P-immunoreactivity(-IR) and calcitonin gene-related peptide(CGRP)-IR in extracts of urinary bladder and lung from the capsaicin-treated rats is evidence of the efficacy of capsaicin treatment in affecting a loss of C-fibre sensory nerves. The significant depletion of CGRP-IR measured in the stomach and duodenum of capsaicin-treated rats indicated the loss of the C-fibre sensory innervation to the gastrointestinal tract. The gastrointestinal content of VIP and substance P, which are predominantly within intrinsic gut neurones, were unaffected by capsaicin treatment. In all regions of the gastrointestinal tract of capsaicin-treated rats, the serotonin and glucagon-IR levels were not significantly different from those in controls. Similarly the levels of activity of the brush-border enzymes were not significantly effected by capsaicin treatment. This suggest the absence of any major trophic influence of capsaicin-sensitive sensory nerves on the gut endocrine mucosa and the brush border.
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PMID:Regulatory peptide and serotonin content and brush-border enzyme activity in the rat gastrointestinal tract following neonatal treatment with capsaicin; lack of effect on epithelial markers. 170 47

The absorption of zinc is increased when the dietary zinc supply is low. This is caused by increased intestinal transport and reduced secretion of endogenous zinc into the intestine. Kinetic analysis of zinc transport, based on data from either the isolated perfused intestine or brush border membrane vesicles, demonstrates uptake velocity is increased homeostatically by a carrier-mediated phase of transport in response to low dietary zinc. Zinc within intestinal cells binds to high molecular weight proteins and metallothionein. Expression of the metallothionein gene is altered by zinc status and the protein appears to have a function in intestinal cells. Zinc transport across the basolateral membrane is also carrier-mediated and may be ATP-driven. Newly absorbed zinc is transported via albumin, first to the liver and then is redistributed to other tissues, particularly muscle and bone which provide the greatest reserves. Plasma zinc levels remain relatively constant except during periods of dietary zinc depletion and acute responses to stress, infection or inflammation where they are depressed. Experiments with intact rats and isolated rat liver parenchymal cells have shown that hepatic zinc turnover is rapid. Stimulation of liver cells by glucocorticoids, glucagon, epinephrine, cAMP or interleukin-1-like factors alters uptake/exchange kinetics such that there is a net accumulation of cellular zinc. Metallothionein gene expression is enhanced by these hormonal signals, and a considerable portion of the newly accumulated zinc is accounted for as that associated with this zinc-binding protein.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Toward a molecular understanding of zinc metabolism. 242 May 2

Transport and hydrolysis of glucagon in the rabbit proximal nephron were studied. Iodinated glucagon (0.34 +/- 0.02 pg/nl, mean +/- SE) was microperfused (16.0 +/- 1.1 nl/min) in vitro through proximal straight nephron segments for 30 min. Radiolabeled material, primarily 125I-tyrosine, appeared in the bathing medium in a linear fashion as a function of time (0.406 pg glucagon X mm tubule length-1 X min-1). Hydrolysis of glucagon by proximal tubule homogenates was pH dependent, with a large peak of activity observed at pH 7.0-7.4 and a smaller one at pH 3.0. Analytical cell fractionation studies of proximal tubule cells revealed glucagon-hydrolyzing activity associated with the brush border and cytosol at pH 7.4. Less than 3% of activity was found associated with the contraluminal membrane. Substantial catabolism was observed at lysosomes on lowering the pH to 5.0. Incubation of glucagon directly in the presence of isolated renal cortical microvilli confirmed the presence of a high-capacity glucagon-degrading hydrolase. In addition to glucagon-hydrolyzing activity associated with the proximal nephron, noncortical activity was observed that was not accounted for by proximal tubule hydrolases. The data suggest several mechanisms for renal extraction of glucagon, including hydrolysis by enzymes at the brush border of the proximal tubule, prior to reabsorption of metabolites there. Conversely, enzymes associated with the contraluminal membrane of the proximal nephron probably contribute little to its hydrolysis. Nonproximal extracortical degradation of glucagon may account for its previously observed peritubular hydrolysis.
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PMID:Transport and hydrolysis of glucagon in the proximal nephron. 287 55

We have identified specific binding sites for pancreatic polypeptide (PP) on the mucosal lining of canine small intestine. The present study was undertaken to further characterize these binding sites (receptors) on purified intestinal membranes and to establish their location on the brush border or basolateral surface of the intestinal enterocyte. Basolateral and brush border membranes were prepared by sorbitol density centrifugation. PP receptors were localized predominantly to the vascular surface, and thus binding of PP 125I-labeled on Tyr-27 to the basolateral preparation was used to evaluate receptor characteristics. Binding of PP was calcium, time, temperature, and pH dependent. Maximum specific binding of labeled PP occurred after an 8-hr incubation at 4 degrees C with 5 mM calcium at pH 6.8. Data analysis by Scatchard plot showed high- and low-affinity binding sites with relative affinities of 1.5 x 10(-9) M and 2.6 x 10(-8) M and with corresponding binding capacities of 0.23 pmol/mg and 0.84 pmol/mg of protein, respectively. This receptor was specific for PP since peptide YY and neuropeptide Y, peptides of the PP family, cross-reacted by less than 3%, as judged from comparisons of half-maximal displacement of label. Structurally dissimilar peptides, insulin and glucagon, did not compete for binding. Specific 125I-labeled PP binding was localized primarily to basolateral membranes (9.8 +/- 0.8%) with little binding by brush border membranes (0.8 +/- 0.2%). Thus, we have identified highly specific receptors for PP, located predominantly on the vascular surface of the small intestinal mucosa. These data suggest that the mucosal lining of the small intestine is a target tissue for PP and that PP participates in the hormonal regulation of fuel metabolism and substrate transport in the small intestinal mucosa.
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PMID:Characterization of specific pancreatic polypeptide receptors on basolateral membranes of the canine small intestine. 338 34

The effects of chronic (72 h) glucagon treatment on active nutrient uptake by the rat jejunum have been determined using in-vitro electrophysiological and autoradiographic methods together with an in-vivo technique which measures absorption across a cannulated segment of upper jejunum. Glucagon caused a marked increase in the potential difference across the brush border membrane from a mean value of -47.6 mV under control conditions to -54.2 mV following treatment with the hormone (P less than 0.025). A similar hyperpolarization was also noted after 24 h glucagon administration. The magnitude of the depolarization induced by the addition of D-galactose (4 mmol/l) to the mucosal fluid was increased from 6.0 to 14.3 mV following 72 h glucagon treatment (P less than 0.05). Phloridzin (0.1 mmol/l) abolished the galactose-induced depolarization in both control and treated animals. Glucagon induced significant increases of 49.9 and 61.0% respectively for glucose and galactose absorption measured under in-vivo conditions. Autoradiographic studies revealed that following glucagon treatment, L-valine uptake occurred earlier during enterocyte migration along the villus. This resulted in an enhanced accumulation of the amino acid at the villus tip. We conclude that glucagon increases nutrient transport across the small intestine. The raised electrical gradient for Na+- coupled nutrient entry into the enterocyte is likely to be a major factor in the transport response.
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PMID:Hyperglucagonaemia: effects on active nutrient uptake by the rat jejunum. 378 84

1. A neutral peptidase, previously shown to be located in the brush border of the proximal tubule, and assayed by its ability to hydrolyse [(125)I]iodoinsulin B chain was purified from rabbit kidney. 2. The starting material for the purification was a microsomal pellet prepared from a homogenate of cortical tissue. The membrane-bound enzymes were solubilized by treatment with toluene and trypsin. About half the neutral peptidase activity was released by this treatment in a form that no longer sedimented with the microsomal pellet and which penetrated polyacrylamide gels when subjected to disc electrophoresis. Other treatments with detergents or proteolytic enzymes either inactivated the peptidase or failed to convert it into a genuinely soluble form. 3. Chromatography with successive columns of Sephadex G-200, DEAE-cellulose and hydroxyl-apatite yielded an enzyme that was free of other brush-border peptidase activities and which was homogeneous on disc electrophoresis and ultracentrifugation. 4. The purified enzyme attacked [(125)I]iodoglucagon at a rate comparable with that for [(125)I]iodoinsulin B chain. It did not appear to attack proteins (insulin, albumin and casein) that had been similarly iodinated. 5. Unlabelled insulin B chain and unlabelled glucagon were substantially hydrolysed by the endopeptidase, whereas insulin and albumin released only trivial amounts of ninhydrin-reacting material. The resistance of insulin to attack by endopeptidase, even after prolonged incubation, was confirmed by biological and immunoassay. 6. The specificity of the peptidase was determined by analysis of the products after incubating unlabelled insulin B chain, and some oligopeptide substrates, including pentagastrin, with the enzyme. All of the bonds readily cleaved were those involving the alpha-amino group of hydrophobic residues, i.e. x-Leu-, x-Val-, x-Tyr-, x-Phe- and x-Met-, provided that the residues were not C-terminal. 7. The enzyme showed only endopeptidase activity. Substrates suitable for aminopeptidases, carboxypeptidases or esterases were not attacked.
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PMID:The purification and specificity of a neutral endopeptidase from rabbit kidney brush border. 442 92

Jejunal mucosa of 6 d-old rats were cultured for 24 and 48 h in the presence of thyroxine, insulin, pentagastrin, glucagon, epidermal growth factor (EGF) or dibutyryl-A-3:5-MP cyclic with or without dexamethasone (DX). The enzymes were assayed on the purified brush borders. The various agents added alone to the basic culture medium had no effect with the exception of DX on the levels of enzyme activities. Dexamethasone alone induced sucrase, stimulated maltase, and protected other brush border enzyme activities (aminopeptidase, lactase, and alkaline phosphatase). When added to DX-supplemented medium, only the following factors modified the levels of enzymatic activities observed with DX alone. Insulin (10(-6) M) increased maltase, alkaline phosphatase, and lactase activity to a greater extent than DX at 24 h culture, the effect being maintained at 48 h on alkaline phosphatase only. At 48 h culture, both EGF (10(-8) M) and dbcAMP (10(-3) M) decreased DX-induced sucrase activity. The latter agent also depressed DX-stimulated aminopeptidase activity.
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PMID:Organ culture of suckling rat intestine: comparative study of various hormones on brush border enzymes. 674 50

Filtered proteins including insulin are absorbed in the proximal tubule by means of pinocytosis. The first step in this process is binding of the protein to brush border membrane. As it is not known whether absorption exhibits specificity, we set out to determine whether specific binding sites for insulin are present in brush border membranes. Rabbit-isolated brush border membranes were incubated with 125I-insulin and varying concentrations of cold insulin or other peptide hormones. Binding and degradation of 125I-insulin occurred in a time- and temperature-dependent manner. Native insulin competitively inhibited 125I-insulin binding, but calcitonin, arginine vasopressin, glucagon, and growth hormone (10(-6) M) were relatively ineffective. Nonspecific binding averaged one-third of the total radioactivity bound. Scatchard analysis of binding data revealed two classes of insulin receptors: high affinity, low capacity receptors and low affinity, high capacity receptors. Gel filtration analysis of 125I-insulin exposed to brush border membrane revealed the formation of low-molecular-weight products similar to that produced by intact kidneys. The degrading process exhibited some specificity, for cold insulin (10(-6) M) was more effective than calcitonin, vasopressin, glucagon, or growth hormone in inhibiting degradation (32% versus less than 13% inhibition; P less than 0.01). Whether this reflects inhibition of insulin specific binding before exposure to degradation or inhibition of specific enzymes is unclear. In summary, it appears that renal brush border membranes have a major insulin-specific receptor component that could potentially mediate tubular insulin absorption. In addition, there is a smaller nonspecific component that may also have the potential to mediate insulin absorption. Finally, it appears that brush border membranes have the ability to degrade insulin to low-molecular-weight products by a process that exhibits some specificity for insulin.
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PMID:Binding and degradation of insulin by isolated renal brush border membranes. 676 Dec

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