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)

Several endocrine hormones which influence liver metabolism are known to increase in activity during the acute phase of injury or inflammation. We determined whether these hormones have the potential to influence acute-phase protein production in human and rat hepatoma cells. Catecholamines, glucagon, growth hormone, triiodothyronine, and cyclic nucleotides individually or in combination did not modulate the basal or the interleukin-1 (IL-1)-, IL-6-, and dexamethasone-stimulated levels of acute-phase plasma proteins. Insulin, however, was found to be a rapid, nonspecific, and dose-dependent inhibitor of the cytokine and glucocorticoid stimulation of acute-phase protein gene expression and to exert its effect at the transcriptional level. The insulin inhibition applied to all cytokines tested but to various degrees, depending upon the particular acute-phase gene. Insulin resulted in an early and prominent increase in the transcription of genes encoding the AP-1 components of JunA, JunB, and c-Fos, as has been observed for other growth factors. However, the effect of insulin on C/EBP beta was unexpected and paradoxical: while insulin completely inhibited the transcriptional activation of the C/EBP beta gene in cytokine- and dexamethasone-treated cells, the level of cytoplasmic C/EBP beta RNA was elevated. Quantitation of C/EBP beta mRNA by Northern (RNA) blot analysis and of C/EBP beta DNA binding activity by Southwestern (DNA-protein) blot analysis showed that insulin, when combined with cytokines and dexamethasone, stimulated both the mRNA and DNA binding activity by a factor of 1.6 compared with that of cells treated with cytokines and dexamethasone alone. Transient transfection of H-35 and HepG2 cells with a chloramphenicol acetyltransferase (CAT) gene expression vector containing the C/EBP beta response element also resulted in a 1.5-fold increase of C/EBP beta-mediated transcription in insulin-treated cells. Transfection of CAT gene constructs containing increasing lengths of heptaglobin gene 5' flanking sequences indicated that insulin inhibition of IL-6 stimulation required the presence of the region from -4100 to -1030. These results suggest that insulin has the potential to control the transcription of acute-phase genes by at least two separate mechanisms.
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PMID:Insulin is a prominent modulator of the cytokine-stimulated expression of acute-phase plasma protein genes. 137 89

The molecular mechanism involved in altered regulation of the rate-limiting enzyme in hepatic gluconeogenesis, phosphoenolpyruvate carboxykinase (PEPCK), during endotoxemia is not completely understood. We examined, therefore, the effect of a nonlethal dose of Escherichia coli endotoxin on PEPCK gene expression in fasted rats. 5 h after endotoxin treatment, the PEPCK transcription rate and the amount of mRNA(PEPCK) were significantly decreased at a time when the insulin/glucagon (I/G) molar ratio and plasma corticosterone levels were significantly increased. Similar results were observed in a time course study, in which altered cAMP induction of PEPCK gene expression paralleled changes in the I/G molar ratio. In diabetic rats treated with endotoxin, PEPCK gene expression was decreased in the absence, however, of an increased I/G molar ratio. This finding indicates that other factors, such as inflammatory mediators or cytokines, alter PEPCK gene transcription during endotoxemia. IL-6, a putative mediator of endotoxin action in the liver, had no effect on PEPCK gene expression in fasted rats, but did decrease cAMP induction of PEPCK gene expression. These results indicate that, during endotoxemia, regulation of PEPCK gene expression is influenced by inflammatory mediators in addition to the classical endocrine hormones. IL-6, however, does not appear to be involved directly in the altered regulation of the PEPCK gene during endotoxemia.
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PMID:Altered transcriptional regulation of phosphoenolpyruvate carboxykinase in rats following endotoxin treatment. 165 77

After trauma or sepsis, the liver undergoes a reprioritization of export protein synthesis with elevated production of some acute-phase reactants and reduced production of others. We have examined the effects of combinations of insulin and the counterregulatory hormones (dexamethasone, glucagon, and epinephrine), in the presence or absence of interleukin (IL)-6, on the production by isolated hepatocytes of the positive acute-phase proteins C-reactive protein, alpha 1-antichymotrypsin, alpha 1-acid glycoprotein, and haptoglobin, and the negative acute-phase proteins prealbumin and transferrin. The effect of IL-6 on the production of the above proteins was influenced significantly by insulin and all of the counterregulatory hormones. Significant three-way interactions as well as higher order interactions between the stress hormones and insulin were seen in the case of C-reactive protein. The results indicate that both positive and negative acute-phase proteins respond differently to insulin and the counterregulatory hormones and that the potential exists for the regulation of synthesis of individual acute-phase reactants by interaction between the cytokine network and the classical endocrine hormones.
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PMID:Insulin and counterregulatory hormones influence acute-phase protein production in human hepatocytes. 754 33

"Septic autocannabalism" been coined to describe the metabolic response that follows severe sepsis in humans. The normal protein- and energy-conserving mechanisms evoked during simple starvation are not observed following the onset of sepsis. The metabolic response to sepsis entails rapid breakdown of the body's reserves of protein, carbohydrate, and fat. Hyperglycemia with insulin resistance, profound negative nitrogen balance, and diversion of protein from skeletal muscle to splanchnic tissues are prominent features. These responses are believed to be mediated in large part by inflammatory cytokines such as tumor necrosis factor alpha (TNFalpha), interleukin 1beta (IL-1beta), and IL-6. Secondary induction of catecholamines, cortisol, and glucagon by cytokines is likely to be another important effector mechanism. Infection and inflammation elicit a complex network of interwoven responses, and no single mediator alone accounts for the responses observed. Sepsis also commonly involves alterations in cardiovascular function with altered flow to key metabolic sites, hypoxia, damage to the gut's mucosal barrier, secondary organ failure, and alterations in capillary permeability. These structural and functional alterations also strongly influence the metabolic profile during infection. If these catabolic responses persist for more than a few days, severe malnutrition results and is likely to be an important risk factor for mortality in these patients. The altered metabolic milieu during sepsis prevents effective use of exogeneously delivered glucose and protein; at best, administration of these agents ameliorates but does not prevent the persistence of catabolism. Delivery of agents that antagonize cytokines and other moieties such as glutamine and growth hormone may, in the future, help to restore nitrogen balance during sepsis.
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PMID:Metabolism of sepsis and multiple organ failure. 866 35

The immune and endocrine mediators that are released during sepsis (e.g., tumor necrosis factor [TNF] alpha, interleukin [IL]-1, IL-6, transforming growth factor [TGF] beta, prostaglandin [PG] E2, catecholamines, vasopressin, glucagon, insulin, and glucocorticoids) can produce inappropriate detrimental cellular responses contributing to exacerbation of septic injury. Examples of such sepsis-related inappropriate responses are: exaggerated hepatic acute-phase protein (APP) expression and release skeletal muscle insulin resistance, and suppressed T-lymphocyte proliferation. The studies discussed in this article present evidence that the generation of the sepsis-related hepatic, skeletal muscle, and T-lymphocyte responses emanate from alterations in intracellular Ca2+ (Ca2+i) homeostasis. In hepatocytes, there is indication of a sepsis-mediated increase in Ca2+ influx from the extracellular milieu leading to a sustained increase in the apparent resting cell Ca2+i concentration ([Ca2+]i) and its depressed elevation on stimulation with Ca2+-mobilizing hormones such as catecholamines and vasopressin. These Ca(2+)- related changes can affect not only the signaling pathways in which Ca2+i itself serves as a signaling component, but also the signaling systems turned on by other sepsis-induced agonists which may not be dependent on Ca2+ signaling. TGF-beta, IL-1, TNF alpha, and IL-6 activate a primarily protein kinase C (PKC)-dependent intracellular signal system for the elicitation of a normal hepatic APP response (APPR). The increased apparent basal [Ca2+]i in sepsis can hypersensitize PKC activation and thus lead to an exaggerated APPR. In the skeletal muscle, an evident increase in Ca2+ membrane flux during sepsis pointed to an increase in the basal [Ca2+]i resulting from a plausible cytokine-mediated overactivation of the voltage-sensitive Ca2+ channels. The increased basal [Ca2+]i can negatively modulate the insulin-mediated stimulation of GLUT4-dependent glucose transport despite the possibility that Ca2+i might not participate as a component in the insulin-receptor-regulated signaling pathway. Increased [Ca2+]i in skeletal myocytes can either directly promote the phosphorylation of GLUT4 or prevent its dephosphorylation, both of which effectively block insulin stimulation of glucose uptake, thereby contributing to insulin resistance. In T lymphocytes, septic injury appears to induce an attenuation in the mitogen and, thus, presumably a T-cell antigen receptor (TCR)-mediated elevation in [Ca2+]i without affecting the basal [Ca2+]i. This decrease in TCR-related Ca2+i mobilization evidently contributes to the suppression of T lymphocyte proliferation during sepsis, probably via an in vivo action of prostaglandin (PG) E2 on the T cells during sepsis. The blockade of PGE2 production after indomethacin administration to septic animals prevents alterations in both T-cell Ca2+i mobilization and proliferation. PGE2 probably acts through its second messenger, cyclic adenosine 3'5'-monophosphate, which can antagonize Ca2+i signaling in T cells.
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PMID:Alterations in calcium signaling and cellular responses in septic injury. 868 77

The development and function of the immune system is regulated by neuroendocrine factors. Immune function may be divided into adaptive and natural immunity. Adaptive immune responses are driven by specific determinants of the antigen (epitopes), require 5-10 d to fully develop, and show an accelerated or memory response after repeated exposure to the same antigen. Natural immunity may be divided into host defense mediated by non-immune factors (e.g., antimicrobial proteins, enzymes, mucus etc.) and polyspecific responses of the immune system. This polyspecific response relies on natural antibodies and on some other serum proteins (e.g., lipopolysaccharide-binding protein-LBP, C-reactive protein-CRP), and on surface receptors of macrophages, natural killer cells and B and T lymphocytes for activation. Highly conserved homologous (crossreactive) epitopes, or homotopes for short, are recognized by the natural immune system. Natural antibodies, LBP, and CRP are capable of activating the entire immune system after combination with the appropriate homotope. During febrile illness natural immune host defense is promptly elevated because of the rapid rise of natural antibodies, LBP, and CRP in the serum. This is known as the acute phase response (APR), which is initiated by a sudden rise of cytokines in the circulation, such as IL-1, IL-6, and TNF-alpha. The cytokines act on the brain, the neuroendocrine system, and on other tissues and organs, which leads to fever and profound hormonal and metabolic changes. The hypothalamus-pituitary adrenal axis is activated and serves as the primary regulator of immune and inflammatory reactions. Insulin, glucagon, and catecholeamine levels are also raised. Bone marrow activity and leukocyte function are high and the liver is converted to the rapid production of acute-phase proteins (APP). APP include LBP, CRP, fibrinogen, some complement components, enzyme inhibitors, and anti-inflammatory proteins, which may rise in the serum from several hundred to a thousand times within 24-48 hr. Therefore, natural immunity is a polyspecific response to homotopes, which functions as an instantaneous defense mechanism in health and which is rapidly boosted by cytokines and hormones during febrile illness. This is a highly successful defense reaction, as in the overwhelming majority of cases, febrile illness leads to recovery and the development of adaptive immunity in man and higher animals.
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PMID:Neuroimmunoregulation and natural immunity. 978 30

PACAP is a pleiotropic neuropeptide that belongs to the secretin/glucagon/VIP family. PACAP functions as a hypothalamic hormone, neurotransmitter, neuromodulator, vasodilator, and neurotrophic factor. Its structure has been remarkably conserved during evolution. The PACAP receptor is G protein-coupled with seven transmembrane domains and also belongs to the VIP receptor family. PACAP, but not VIP, binds to PAC1-R, whereas PACAP and VIP bind to VPAC1-R and VPAC2-R with a similar affinity. Despite the sizable homology of the structures of PACAP and VIP and their receptors, the distribution of these peptides and receptors is quite different. At least eight subtypes of PACAP specific, or PAC1-R, result from alternate splicing. Each subtype is coupled with specific signaling pathways, and its expression is tissue or cell specific. Although PACAP fulfills most requirements for a physiological hypothalamic hypophysiotropic hormone, it does not consistently stimulate secretion of the adenohypophysial hormones, except for stimulation of IL-6 release from the FS cells of the pituitary. The major regulatory role of PACAP in pituitary cells appears to be the regulation of gene expression of pituitary hormones and/or regulatory proteins that control growth and differentiation of the pituitary glandular cells. These effects appear to be exhibited directly and indirectly through a paracrine or autocrine action. Although PACAP stimulates the release of AVP, the physiological role of neurohypophysial PACAP remains unknown. One important action of PACAP in the endocrine system is its role as a potent secretagogue for adrenaline from the adrenal medulla through activation of TH. PACAP also stimulates the release of insulin and increases [Ca2+]i from pancreatic beta-cells at an extremely small concentration. The stage-specific expression of PACAP in testicular germ cells during spermatogenesis suggests its regulatory role in the maturation of germ cells. In the ovary, PACAP is transiently expressed in the granulosa cells of the preovulatory follicles and appears to be involved in the LH-induced cellular events in the ovary, including prevention of follicular apoptosis. In the central nervous system, PACAP acts as a neurotransmitter or neuromodulator, which has been supported by IHC and electrophysiological methods. More important, PACAP is a neurotrophic factor that may play an important role during the development of the brain. In the adult brain, PACAP appears to function as a neuroprotective factor that attenuates the neuronal damage resulting from various insults.
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PMID:Perspectives on pituitary adenylate cyclase activating polypeptide (PACAP) in the neuroendocrine, endocrine, and nervous systems. 985 40

The rheological properties of plasma and blood cells are markedly influenced by the surrounding milieu: physicochemical factors, metabolism and hormones. Acid/base status, osmolality, lipid status and plasma protein pattern are well known to exert a major influence. The oxidative stress induced by increased free radicals production decreases red cell deformability. Among circulating substances, the divalent cations magnesium and zinc improve red cell deformability probably via calcium antagonistic effects. Some metabolites like lactate or ketone bodies decrease red cell deformability, although the former has apparently the opposite effect in highly trained individuals. Endothelium-derived factors such as nitric oxide (NO) and several arachidonic acid derivatives modulate both RBC and white cell mechanics. Endothelium regulates also blood rheology via the release of PAI-1 which governs plasma fibrinogen levels. However, endothelium is not the only organ involved in the regulation of blood rheology: the kidney (by releasing erythropoietin which is a major "viscoregulatory" factor), the endocrine pancreas (via the action of insulin and glucagon on red cells), the adrenal gland (norepinephrine) and the endocrine heart (atrial natriuretic peptide) are also likely to exert important effects. Recently, increasing evidence is accumulating for a role of two other endocrine tissues in the regulation of blood rheology: the adipose tissue (free fatty acids, PAI-1, IL-6, leptin) and the pituitary gland (growth hormone-somatomedin axis, including the somatomedin carrier protein IGFBP1). These organs provide a link between body composition and hemorheology, since GH and somatomedins are major regulators of the body content in fat and water while the endocrine activity of fat mass is apparently proportional to its size. These mechanisms explain to some extent why many situations, either physiological (diet, exercise) or pathological (diabetes, uremia) are associated with marked changes in blood rheology that may in turn modify micro and macrocirculatory hemodynamics and the distribution of O(2) and fuels to tissues.
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PMID:Hormones, metabolism and body composition as major determinants of blood rheology: potential pathophysiological meaning. 1208 54

Although IL-6 is a key modulator of immune function, it also plays a role in regulating substrate metabolism. To determine whether IL-6 affects lipid metabolism, 18 healthy men were infused for 3 h with saline (Con; n = 6) or a high dose (High-rhIL6; n = 6) or a low dose (Low-rhIL6; n = 6) of recombinant human IL-6 (rhIL-6). The IL-6 concentration during Con, Low-rhIL6, and High-rhIL6 was at a steady state after 30 min of infusion at approximately 4, 140, and 320 pg/ml, respectively. Either dose of rhIL-6 was associated with a similar increase in fatty acid (FA) concentration and endogenous FA rate of appearance (R(a)) from 90 min after the start of the infusion. The FA concentration and FA R(a) continued to increase until the cessation of rhIL-6 infusion, reaching levels approximately 50% greater than Con values. The elevated levels reached at the end of rhIL-6 infusion persisted at least 3 h postinfusion. Triacylglycerol concentrations were unchanged during rhIL-6 infusion, whereas whole body fat oxidation increased after the second hour of rhIL-6 infusion. Of note, during Low-rhIL6, the induced elevation in FA concentration and FA R(a) occurred in the absence of any change in adrenaline, insulin, or glucagon, and no adverse side effects were observed. In conclusion, the data identify IL-6 as a potent modulator of fat metabolism in humans, increasing fat oxidation and FA reesterification without causing hypertriacylglyceridemia.
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PMID:Interleukin-6 stimulates lipolysis and fat oxidation in humans. 1284 33

Adiponectin is a novel adipocytokine negatively correlated with parameters of the metabolic syndrome, such as body mass index (BMI), body fat mass (BFM), and circulating insulin levels. Furthermore, metabolic actions directly on the liver have been described. The aim of the present study was to characterize circulating adiponectin levels, hepatic turnover, and the association of adiponectin with key parameters of hepatic as well as systemic metabolism in cirrhosis, a catabolic disease. Circulating adiponectin levels and hepatic turnover were investigated in 20 patients with advanced cirrhosis. Hepatic hemodynamics [portal pressure, liver blood flow, hepatic vascular resistance, indocyanine green (ICG) half-life], body composition, resting energy expenditure, hepatic free fatty acids (FFA) and glucose turnover, and circulating levels of hormones (catecholamines, insulin, glucagon) and proinflammatory cytokines (IL-1beta, TNF-alpha, IL-6) were also assessed. Circulating adiponectin increased dependently on the clinical stage in cirrhosis compared with controls (15.2 +/- 1.7 vs. 8.2 +/- 1.1 microg/ml, respectively, P < 0.01), whereas hepatic extraction decreased. Adiponectin was negatively correlated with parameters of hepatic protein synthesis (prothrombin time: r = -0.62, P = 0.003; albumin: r = -0.72, P < 0.001) but not with transaminases or parameters of lipid metabolism. In addition, circulating adiponectin increased with portal pressure (r = 0.67, P = 0.003), hepatic vascular resistance (r = 0.60, P = 0.008), and effective hepatic blood flow (ICG half-life: r = 0.69, P = 0.001). Adiponectin in cirrhosis was not correlated with BMI, BFM, parameters of energy metabolism, insulin levels, hepatic FFA and glucose turnover, and circulating proinflammatory cytokines. These results demonstrate that 1) adiponectin plasma levels in cirrhosis are significantly elevated, 2) the liver is a major source of adiponectin extraction, and 3) adiponectin levels in cirrhosis do not correlate with parameters of body composition or metabolism but exclusively with reduced liver function and altered hepatic hemodynamics.
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PMID:Elevated circulating adiponectin levels in liver cirrhosis are associated with reduced liver function and altered hepatic hemodynamics. 1501 Mar 38

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