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)

A patient developed insulin-dependent diabetes mellitus at the age of 9 years, complicated by a sensory/autonomic polyneuropathy which presented with a respiratory arrest at the age of 41 years. The neuropathy increased in severity over the subsequent two decades. At the age of 52 years she had hypopituitarism, hypothyroidism and low normal adrenal function. Autopsy at the age of 59 years revealed loss of pituitary tissue with evidence of hypophysitis, a lymphocytic thyroiditis and severe adrenal atrophy with lymphocytic infiltration of the medulla. The pancreas showed reduced numbers and size of the islets of Langerhans with total loss of immunoreactivity for insulin but intact glucagon-producing cells. These features are consistent with a type 2 autoimmune polyendocrine syndrome, in which lymphocytic hypophysitis has not previously been recorded. There was severe loss of myelinated nerve fibres in the sural nerve and rostrally accentuated fibre degeneration in the gracile fasciculi, but only mild cell loss in the dorsal root ganglia. This combination suggests the presence of a central-peripheral distal axonopathy. The cervical sympathetic ganglia were severely atrophic. Minor inflammatory infiltration was observed in the dorsal root and sympathetic ganglia. Significant vascular abnormalities were not present in the peripheral nerves. This, and the pattern of nerve fibre degeneration, suggest that in this case the neuropathy was likely to have been related to metabolic rather than vascular causes. The inflammatory infiltrates in sensory and sympathetic ganglia raise the possibility of an autoimmune inflammatory contribution to the neuropathy.
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PMID:Severe sensory-autonomic neuropathy and endocrinopathy in insulin-dependent diabetes. 854 64

1. Insulin sensitivity was quantified using a modified euglycaemic technique after hepatic cholinergic blockade with atropine and compared with that after surgical denervation. 2. Intraportal administration of atropine produced dose-dependent inhibition of insulin sensitivity in glucose metabolism. ED50 of atropine was 0.99 mg kg-1 (1 mg = 1.5 microM) with maximum inhibition of 40.3 +/- 11.6%. 3. Atropine (3 mg kg-1) reduced insulin sensitivity by a similar amount (33.6 +/- 3.4%) to that produced by hepatic surgical denervation (37.8 +/- 9.8%). Doses greater than 3 mg kg-1 failed to further alter the insulin resistance produced by surgical denervation or atropine (3 mg kg-1) administration, suggesting that activation of hepatic parasympathetic nerves is necessary to fully express the insulin effect. 4. Atropine reduced insulin sensitivity without changes in plasma concentrations of glucagon or insulin. The temporal response to insulin in this euglycaemic study was not changed after atropine administration or after surgical hepatic denervation. 5. It is suggested that hepatic parasympathetic nerves show a synergistic effect with insulin. Disease states that result in hepatic parasympathetic neuropathy would be expected to produce an insulin resistant liver. 6. The modified euglycaemic clamp method for assessing insulin responses was shown to be reproducible up to four times in the same animal and was sufficiently sensitive and quantitative to be able to generate a dose-response curve in each animal for atropine-induced insulin resistance.
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PMID:Induction of insulin resistance by cholinergic blockade with atropine in the cat. 874 76

Optimal blood glucose levels and normal insulin sensitivity are aims in the treatment of insulin-dependent diabetes mellitus (IDDM). Insulin sensitivity and insulin reserve are closely interrelated. It is essential to know more about both of these parameters at clinical diagnosis, because their preservation may delay the occurrence of diabetes-related complications. B-cell function is likely to be retained for a longer period in patients with adult onset of the disease compared with children. In this study, intensive insulin treatment was initiated in newly diagnosed adult patients to determine if it preserved endogenous insulin secretion longer than conventional therapy. Forty-nine patients with newly diagnosed diabetes were carefully categorized as having IDDM according to clinical and serological criteria. They were randomized to an intensive (I group) or conventional (C group) insulin therapy and evaluated for 5 years. Every 6 months, a check-up included glucagon-stimulated C-peptide (GSCP), hyperglycemic glucose clamp with arginine bolus, euglycemic-hyperinsulinemic clamp, and screening for microalbuminuria, retinopathy, and neuropathy. At the end of the study, hemoglobin A1c (HbA1c) was 6.3% +/- 1.9% in the I patients and 8.1% +/- 2.1% in the C patients (P < .001). Blood glucose concentrations less than 3.5 mmol/L were more frequent in the I group than in the C group (P < .05). Insulin sensitivity (M/I) and GSCP were higher in intensively treated patients after 5 years (M/I, I group 40 +/- 10 nmol x kg(-1) x min(-1) x pmol/L1 v C group 21 +/- 11, P < .005; GSCP, I group 0.6 +/- 0.2 nmol/L v C group 0.19 +/- 0.11, P < .005). The prevalence of peripheral neuropathy was significantly lower in the I group at the end of the study. In conclusion, intensive therapy is more effective in the preservation of insulin action and reserve. In our patients, no case of severe hypoglycemia was observed, indicating that intensive therapy was safe in these patients.
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PMID:Intensive therapy in adult insulin-dependent diabetes mellitus is associated with improved insulin sensitivity and reserve: a randomized, controlled, prospective study over 5 years in newly diagnosed patients. 896 84

Persistent humoral autoimmunity to the enzyme glutamic acid decarboxylase (GAD) has been described in a substantial proportion of patients with insulin-dependent diabetes mellitus (IDDM) of long duration. The source of the stimulus for this autoimmune reactivity is still unknown. Because the GAD 65 isoform is mainly expressed in pancreatic beta-cells and in the nervous system we investigated in the present study of the largest number of well characterized patients with longstanding IDDM (n = 105; median duration: 21 years; range: 10-46 years) the presence of autoantibodies to GAD 65 and their relationship to a residual C-peptide response or peripheral and autonomic neuropathy. Additionally we studied the HLA-DR status relative to GAD 65 antibodies in 86 out of the 105 individuals. One hundred healthy control subjects and 100 recent onset IDDM patients were also studied for GAD 65 antibodies. GAD 65 antibodies were detected in a radioligand-binding-assay with recombinant human GAD 65 and were present in 32% of the long-term diabetic patients, 82% of the recent onset IDDM patients and in 3% of the healthy control subjects. A preserved C-peptide response to i.v. glucagon (Hendriksen criteria) was observed in 23% of the long-term IDDM patients. Autonomic neuropathy and peripheral neuropathy was identified using criteria based on both symptoms and formal testing giving a frequency of 67% vs 79%. The HLA specific DR 4/X was observed in 47% and HLA-DR 3/X in 22% of the long-term IDDM patients. Patients who were heterozygous for DR3/DR4 were found in 23% of the cases. GAD 65 antibodies were significantly less frequent in the long-term IDDM patients compared to recent onset IDDM (p < 0.001), and diabetes duration showed a significant negative correlation with GAD 65 antibody index levels (r = 0.22, p < 0.01). Interestingly, GAD 65 antibodies were not significantly correlated either with residual beta-cell function or neuropathy and no particular HLA-DR status was associated with persistent GAD 65 antibodies. In conclusion neither residual beta-cell function nor diabetic neuropathy or a certain HLA-DR specificity are exclusively associated with persistent autoimmunity directed to GAD 65 in longstanding IDDM. The stimulus for the persistent humoral immune response and its significance for the disease process and its complications remain to be established.
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PMID:Persistent GAD 65 antibodies in longstanding IDDM are not associated with residual beta-cell function, neuropathy or HLA-DR status. 940 79

This article examines the role of the autonomic nervous system in mediating the increase of glucagon secretion observed during insulin-induced hypoglycemia (IIH). In the first section, we briefly review the importance of the alpha-cell response in recovery from hypoglycemia under both physiologic conditions and pathophysiologic conditions, such as type 1 diabetes. We outline three possible mechanisms that may contribute to increased glucagon secretion during hypoglycemia but emphasize autonomic mediation. In the second section, we review the critical experimental data in animals, nonhuman primates, and humans suggesting that, in the absence of diabetes, the majority of the glucagon response to IIH is mediated by redundant autonomic stimulation of the islet alpha-cell. Because the glucagon response to hypoglycemia is often impaired in patients with type 1 diabetes, in the third section, we examine the possibility that autonomic impairment contributes to the impairment of the glucagon response in these patients. We review two different types of autonomic impairment. The first is a slow-onset and progressive neuropathy that worsens with duration of diabetes, and the second is a rapid-onset, but reversible, autonomic dysfunction that is acutely induced by antecedent hypoglycemia. We propose that both types of autonomic dysfunction can contribute to the impaired glucagon responses in patients with type 1 diabetes. In the fourth section, we relate restoration of these glucagon responses to restoration of the autonomic responses to hypoglycemia. Finally, in the fifth section, we summarize the concepts underlying the autonomic hypothesis, the evidence for it, and the implications of the autonomic hypothesis for the treatment of type 1 diabetes.
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PMID:Autonomic mediation of glucagon secretion during hypoglycemia: implications for impaired alpha-cell responses in type 1 diabetes. 964 20

The treatment of patients with type 1 diabetes mellitus has to focus on short-term and long-term risks of the disease which means to avoid hyperglycemic or hypoglycemic coma as well as late complications. As we know from the DCCT study metabolic control substantially lowers the risk for retinopathy, nephropathy and neuropathy. We also know, that keeping the blood glucose in a nearly normal range inevitably is connected with a marked increase of severe hypoglycemia, an event which occurs more frequently when normoglycemia has been reached and the further slow decline of blood glucose is not recognized by the patient (autonomous neuropathy, hypoglycemia unawareness of other origin, long duration of diabetes etc.). Furthermore, counterregulatory hormones as glucagon and epinephrine may be lacking due to diminished or even lost alpha cells within the islets and as recently observed due to fibrosis of the adrenal medulla in long-term diabetes. The consequences of severe hypoglycemia are manifold: in the actual situation of unconsciousness the risk of heavy injuries and as long-term consequences irreversible brain damage may occur. Finally, the effort of the patient to reach normoglycemia includes the burden of an intensive blood glucose self-control day by day. This broad scenario of all the achievements and of all the problems connected with an intensified insulin treatment has to be regarded when the indication for an islet transplant will be discussed. From our point of view as clinicians it seems adequate not to give definite recommendations but to express our considerations for islet transplantation in patients with type 1 diabetes mellitus with the following list (table 1). It must be clearly stated, that at present transplantation of isolated islets by no means can serve as a treatment for a larger number of patients and this may hold through also for the foreseeable future. In this context, also the many contraindications should be summarized (table 2). Consequently we have to deal with several questions and problems which can be subdivided into those regarding the possible benefit for the patients from an islet graft (full success = insulin independence, partial success = lower exogenous insulin requirement due to additional endogenous insulin, measured by C-peptide levels, more stable glucose metabolism) and those regarding possible side effects (primary risk of implantation, threat for rejection of the primarily transplanted kidney). Furthermore, one may ask for risks when islets are transplanted alone (ITA). We therefore will address the following areas: 1. Simultaneous islet and kidney transplants 2. Islet transplants after kidney transplantation alone (IAK) 3. Islet transplantation after pancreas transplantation failure (P-failure) 4. Defect hypoglycemia counterregulation--life threatening hypoglycemia unawareness as indication for islet transplantation? 5. Autonomous cardiac neuropathy as indication for islet transplantation? 6. Significant clinical problems with exogenous insulin therapy as indication for islet transplantation?
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PMID:Indications for clinical islet transplantation today and in the forseeable future--the diabetologist's point of view. 993 Sep 51

GLP-1 lowers blood glucose in fasting type 2 diabetic patients. To clarify the relation of the effect of GLP-1 to obesity, blood glucose, beta-cell function, and insulin sensitivity, GLP-1 (1.2 pmol/kg.min) was infused iv for 4-6 h into 50 fasting type 2 diabetic patients with a wide range of age, body mass index, HbA1c, and fasting plasma glucose. The effectiveness of GLP-1 was evaluated by calculation of a glucose disappearance constant for each individual (Kg, linear slope of log-transformed plasma glucose), and by the lowest stable glucose level (Nadir plasma glucose) obtained during the infusion. Grouped according to fasting plasma glucose (<10, 10-15, >15 mmol/liter), Kg values were 0.45 +/- 0.03, 0.38 +/- 0.04, and 0.28 +/- 0.04%/min (P = 0.005), and Nadir plasma glucose values were 4.7 +/- 0.1 (3.9-5.9), 5.8 +/- 0.4 (4.3-8.4), and 8.7 +/- 1.4 (6.2-18.7) mmol/liter (P = 0.0003). Nonresponders were not identified. Multiple regression analysis with Kg or Nadir plasma glucose as the dependent parameter and body mass index, age, gender, diabetes duration, and significantly correlated parameters (in multiple regression for Kg: fasting plasma glucose, fasting nonesterified fatty acid, dipeptidyl peptidase activity, peak insulin, and the logarithm of beta-cell function; and for Nadir plasma glucose: fasting plasma glucose, fasting nonesterified fatty acid, dipeptidyl peptidase activity, delta glucagon decrement, F-GLP-1 total, logarithm of beta-cell function, and Kg) as independent parameters resulted in fasting plasma glucose as the only significant predictor of Kg, and fasting plasma glucose and Kg as predictors of Nadir plasma glucose. Kg and Nadir plasma glucose were neither influenced by treatment nor by neuropathy per se. In conclusion, GLP-1 lowers plasma glucose in type 2 diabetes regardless of severity, but glucose elimination is faster and obtained glycemic level lower in patients with the lower fasting plasma glucose. Not all patients can be expected to reach normoglycemia.
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PMID:Determinants of the effectiveness of glucagon-like peptide-1 in type 2 diabetes. 1150 23

Glucagon-like peptide-1 (GLP-1) increases gastric volume in humans possibly through the vagus nerve. Gastric volume response to feeding is preserved after vagal denervation in animals. We evaluated gastric volume responses to GLP-1 and placebo in seven diabetic patients with vagal neuropathy in a crossover study. We also compared gastric volume response to feeding in diabetes with that in healthy controls. We measured gastric volume using SPECT imaging. Data are median (interquartile range). In diabetic patients, GLP-1 did not increase gastric volume during fasting [5 mL (-3; 30)] relative to placebo [4 mL (-14; 50) P = 0.5], or postprandially [Delta postprandial minus fasting volume 469 mL (383; 563) with GLP-1 and 452 mL (400; 493) with placebo P = 0.3]. Change in gastric volume over fasting in diabetic patients on placebo was comparable to that of healthy controls [452 mL (400; 493)], P = 0.5. In contrast to effects in health, GLP-1 did not increase gastric volume in diabetics with vagal neuropathy, suggesting GLP-1's effects on stomach volume are vagally mediated. Normal gastric volume response to feeding in diabetics with vagal neuropathy suggests that other mechanisms compensate for vagal denervation.
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PMID:Effects of glucagon-like peptide-1 and feeding on gastric volumes in diabetes mellitus with cardio-vagal dysfunction. 1284 32

We investigated the functional impact of a recently described islet-specific loss of sympathetic nerves that occurs soon after the autoimmune destruction of beta-cells in the BB diabetic rat (35). We found that the portal venous (PV) glucagon response to sympathetic nerve stimulation (SNS) was markedly impaired in newly diabetic BB rats (BB D). We next found a normal glucagon response to intravenous epinephrine in BB D, eliminating the possibility of a generalized secretory defect of the BB D alpha-cell as the mediator of the impaired glucagon response to SNS. We then sought to determine whether the glucagon impairment to SNS in BB D was due solely to their loss of islet sympathetic nerve terminals or whether other effects of autoimmune diabetes contributed. We therefore reproduced, in nondiabetic Wistar rats, an islet nerve terminal loss similar to that in BB D with systemic administration of the sympathetic neurotoxin 6-hydroxydopamine. The impairment of the glucagon response to SNS in these chemically denervated, nondiabetic rats was similar to that in the spontaneously denervated BB D. We conclude that the early sympathetic islet neuropathy of BB D causes a functional defect of the sympathetic pathway to the alpha-cell that can, by itself, account for the impaired glucagon response to postganglionic SNS.
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PMID:Impaired glucagon response to sympathetic nerve stimulation in the BB diabetic rat: effect of early sympathetic islet neuropathy. 1287 72

In recent years, VIP/PACAP/secretin family has special interest. Family members are vasoactive intestinal peptide (VIP), pituitary adenylate cyclase-activating polypeptide (PACAP), secretin, glucagon, glucagon like peptide-1 (GLP(1)), GLP(2), gastric inhibitory peptide (GIP), growth hormone releasing hormone (GHRH or GRF), and peptide histidine methionine (PHM). Most of the family members present both in central nervous system (CNS) and in various peripheral tissues. The family members that are released into blood from periphery, especially gut, circulate the brain and they can cross the blood brain barrier. On the other hand, some of the members of this family that present in the brain, can cross from brain to blood and reach the peripheral targets. VIP, secretin, GLP(1), and PACAP 27 are transported into the brain by transmembrane diffusion, a non-saturable mechanism. However, uptake of PACAP 38 into the brain is saturable mechanism. While there is no report for the passage of GIP, GLP(2), and PHM, there is only one report that shows, glucagon and GHRH can cross the BBB. The passage of VIP/PACAP/secretin family members opens up new horizon for understanding of CNS effects of peripherally administrated peptides. There is much hope that those peptides may prove to be useful in the treatment of serious neurological diseases such as Alzheimer's disease, amyotropic lateral sclerosis, Parkinson's disease, AIDS related neuropathy, diabetic neuropathy, autism, stroke and nerve injury. Their benefits in various pathophysiologic conditions undoubtly motivate the development of a novel drug design for future therapeutics.
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PMID:Passage of VIP/PACAP/secretin family across the blood-brain barrier: therapeutic effects. 1513 84

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