Erythrocyte insulin binding in normal infants, children and adults

To establish normal insulin binding criteria, we studied the binding of insulin to erythrocytes from normal subjects of different ages. Insulin binding to cord erythrocytes and to erythrocytes from infants aged 2-7 days was significantly higher at tracer and physiological insulin concentrations than was binding to cells from children aged 1-15 years and adults. In infants aged 1-12 months the maximum insulin binding to erythrocytes was significantly higher than that to erythrocytes from children, and in addition, it correlated negatively with age. An increase in receptor concentration was found in cord erythrocytes whereas an increased receptor affinity for insulin was found in erythrocytes from infants. Insulin binding characteristics in erythrocytes from prepubertal and pubertal children were basically similar to those in women. Erythrocytes from men bound significantly higher amounts of insulin than did those from women. This difference was associated with changes in receptor affinity for insulin. There was no correlation between the insulin binding characteristics and the circulating concentration of insulin or C-peptide. The increased erythrocyte insulin binding at birth persisted over the neonatal period. There was an overall negative correlation between the maximum insulin binding and age in the subjects studied, but the major decrease in erythrocytes insulin binding occurred during the first year of life past the neonatal period. These observations stress the importance of using age-matched controls in studies on erythrocyte insulin binding in disease states.     

Effect of tetrahydrocurcumin on insulin receptor status in type 2 diabetic rats: studies on insulin binding to erythrocytes

Curcumin is the most active component of turmeric. It is believed that curcumin is a potent antioxidant and anti-inflammatory agent. Tetrahydrocurcumin (THC) is one of the major metabolites of curcumin, and exhibits many of the same physiological and pharmacological activities as curcumin and, in some systems, may exert greater antioxidant activity than curcumin. Using circulating erythrocytes as the cellular mode, the insulin-binding effect of THC and curcumin was investigated. Streptozotocin (STZ)-nicotinamide-induced male Wistar rats were used as the experimental models. THC (80 mg/kg body weight) was administered orally for 45 days. The effect of THC on blood glucose, plasma insulin and insulin binding to its receptor on the cell membrane of erythrocytes were studied. Mean specific binding of insulin was significantly lowered in diabetic rats with a decrease in plasma insulin. This was due to a significant decrease in mean insulin receptors. Erythrocytes from diabetic rats showed a decreased ability for insulin-receptor binding when compared with THC-treated diabetic rats. Scatchard analysis demonstrated that the decrease in insulin binding was accounted for by a decrease in insulin receptor sites per cell, with erythrocytes of diabetic rats having less insulin receptor sites per cell than THC-treated rats. High affinity (K d1), low affinity (K d2) and kinetic analyses revealed an increase in the average receptor affinity of erythrocytes from THC-treated rats compared with those of diabetic rats. These results suggest that acute alteration of the insulin receptor on the membranes of erythrocytes occurred in diabetic rats. Treatment with THC significantly improved specific insulin binding to the receptors, with receptor numbers and affinity binding reaching near-normal levels. Our study suggests the mechanism by which THC increases the number of total cellular insulin binding sites resulting in a significant increase in plasma insulin. The effect of THC is more prominent than that of curcumin.     

Defect in insulin receptor phosphorylation in erythrocytes and fibroblasts associated with severe insulin resistance

The insulin receptor is a tyrosine-specific protein kinase. Upon binding of the hormone, the kinase is activated resulting in autophosphorylation of the receptor. This kinase activity has been postulated to be an early step in the transmembrane signaling produced by insulin. To evaluate the physiologic relevance of receptor phosphorylation, we have studied insulin binding and autophosphorylation properties using cells from an individual with a variant of the Type A syndrome of severe insulin resistance and acanthosis nigricans. Erythrocytes and cultured fibroblasts from this individual exhibited normal or near normal 125I-insulin binding. Receptors extracted from erythrocytes with Triton X-100 also exhibited normal 125I-insulin binding and competition curves. Despite this, receptors extracted from both erythrocytes and fibroblasts showed a 50% decrease in insulin-stimulated autophosphorylation. Partially purified receptors from the patient's fibroblasts also exhibited a 40% decrease in their ability to phosphorylate exogenous substrates. These data suggest that the insulin resistance in this syndrome is due to a genetic abnormality which impairs insulin receptor phosphorylation and kinase activity and further support the possible role of receptor phosphorylation and kinase activity in insulin action.     

Whole body hyperthermia of rats decreases insulin binding to erythrocytes

125I-insulin binding to rat erythrocytes was studied to investigate the effect of whole body hyperthermia on the insulin receptor. Heat treatment of rats at 42 degrees C for 15 min caused a significant decrease (48.7% of control) in 125I-insulin binding to rat erythrocytes. Scatchard analysis showed that the decreased binding resulted from a decrease in the number of the insulin receptors rather than from a decrease in receptor affinity. The decreased receptor number for insulin showed no evidence of recovery, 2 h and 8 h after the hyperthermia. Plasma insulin levels remained lower than the control, up to 8 h after the hyperthermia, whereas plasma glucose, which decreased immediately after the hyperthermia, increased higher than the control, 8 h after the hyperthermia. The low plasma insulin level and decreased number of insulin receptor are believed to be possible factors for the elevation of plasma glucose.     

Nitric oxide: the "second messenger" of insulin

Incubation of various tissues, including heart, liver, kidney, muscle, and intestine from mice and erythrocytes or their membrane fractions from humans, with physiologic concentration of insulin resulted in the activation of a membrane-bound nitric oxide synthase (NOS). Activation of NOS and synthesis of NO were stimulated by the binding of insulin to specific receptors on the cell surface. A Lineweaver-Burk plot of the enzymatic activity demonstrated that the stimulation of NOS by insulin was related to the decrease in the Km for L-arginine, the substrate for NOS, with a simultaneous increase of Vmax. Addition of NG-nitro-L-arginine methyl ester (LNAME), a competitive inhibitor of NOS, to the reaction mixture completely inhibited the hormone-stimulated NO synthesis in all tissues. Furthermore, NO had an insulin-like effect in stimulating glucose transport and glucose oxidation in muscle, a major site for insulin action. Addition of NAME to the reaction mixture completely blocked the stimulatory effect of insulin by inhibiting both NO production and glucose metabolism, without affecting the hormone-stimulated tyrosine or phosphatidyl-inositol 3-kinases of the membrane preparation. Injection of NO in alloxan-induced diabetic mice mimicked the effect of insulin in the control of hyperglycemia (i.e., lowered the glucose content in plasma). However, injection of NAME before the administration of insulin to diabetic-induced and nondiabetic mice inhibited not only the insulin-stimulated increase of NO in plasma but also the glucose-lowering effect of insulin.     

Influence of neonatal insulin imprinting on the insulin binding capacity of rat erythrocytes in adulthood

A single neonatal insulin treatment decreased considerably the insulin binding capacity of erythrocytes in adult rats, by analogy of the behaviour of the hepatic insulin receptors in response to insulin exposure during the perinatal period, or during liver regeneration in adulthood. These observations substantitate earlier conclusions on the mechanism of imprinting and strongly suggest the universality of perinatal imprinting in living organisms. In vitro insulin exposure of the erythrocytes of adult rats depressed 48 h later the erythrocytic insulin binding capacity to a similar degree in individuals treated and not treated with insulin when newborn, from which it follows that neonatal exposure had no influence on erythrocytic response to later in vitro treatment. In the light of the present study the use of erythrocytes as model cells for imprinting studies deserves consideration.     

Oxygen-transport function and carbohydrate metabolism in rat erythrocytes during hypoxic hypoxia and treatment with insulin

Hemoglobin affinity to oxygen, enzyme activity and metabolite concentration of carbohydrate metabolism were determined in erythrocytes of rats which were administered insulin solution. A valid decrease of the hemoglobin value P50 (pressure of hemoglobin half-saturation with oxygen), as well as a decrease of the enzyme activity of 2,3-diphosphoglycerate shunt and increase of the activity of regulatory glycolysis enzymes--hexokinase and pyruvate kinase in erythrocytes with multiple introduction of hormones to animals have been established. Such changes in rat erythrocytes were registered with the simultaneous effect of insulin and hypoxic hypoxia evoked by the "lift" of rats in the altitude chamber to the conditional altitude of 9000 m. It is found out that preliminary injection of insulin considerably increases survivability of rats under hypoxic hypoxia at great altitudes.     

Insulin binding to circulating erythrocytes in nonobese diabetic mice

Insulin binding to circulating erythrocytes was studied in nonobese diabetic (NOD) mice which develop insulinopenic diabetes mellitus spontaneously. NOD mice with a short duration of diabetes mellitus and mild insulinopenia did not show any change in insulin binding, while those with a long duration of diabetes mellitus and severe insulinopenia showed an increase in insulin binding compared with nondiabetic NOD mice (6.85 +/- 0.38% bound vs. 4.19 +/- 0.24% bound, p less than 0.01). This increase in insulin binding was due to an increase in the number of receptors. Insulin treatment of diabetic NOD mice significantly reduced the insulin binding by 64%, which resulted from a decrease in the number of the receptors. These results indicate that insulin binding to erythrocytes in NOD mice is controlled mostly by up-and-down regulation.     

Characterization of the insulin resistance in liver cirrhosis: a comparison with non-insulin dependent diabetes mellitus.

To characterize the mechanisms of insulin resistance in liver cirrhosis (LC), we estimated the peripheral tissue sensitivity and responsiveness to insulin using the euglycemic clamp technique and determined the insulin binding to erythrocytes in patients with compensated LC as well as in patients with non-insulin dependent diabetes mellitus (NIDDM). The insulin dose-response curves of the glucose metabolic clearance rates (MCR) were shifted to the right and downward both in patients with LC and NIDDM, indicating a reduced sensitivity and responsiveness to insulin. In the cirrhotics, MCR at the maximally effective insulin level, an index of insulin responsiveness, was correlated with fasting insulin levels (r = -0.57, P < 0.01) and sigma BG in 75 gOGTT (r = -0.43, P < 0.05), but no correlations were found between them and the diabetics. Although specific insulin bindings to erythrocytes were significantly lower in patients both with LC and NIDDM, Scatchard analysis revealed a significant decrease in the number of insulin receptors in the cirrhotics, and a decrease in the empty-site affinity in the diabetics. These findings suggest that insulin resistance in LC consists of a combination of binding and postbinding defects. The latter defect may be caused by basal hyperinsulinemia and contribute to the development of glucose intolerance. Although binding and postbinding abnormalities are also found in NIDDM, the mechanisms of insulin resistance in LC and NIDDM may be different.     

Time dependent effects of dexamethasone on serum insulin level and insulin receptors in rat liver and erythrocytes

The effects of glucocorticoid excess on regulation of insulin receptors were investigated in dexamethasone-treated rats. Glucocorticoid excess was produced by administration of dexamethasone (0.5 mg/100 g b.w.) 30 min, 4, 12, 18, 24, 42 or 70 h before experiments. This treatment caused time-dependent changes of glucose and insulin concentration in blood, as well as in amounts of specific insulin binding and insulin receptors of liver cells and erythrocytes. The time intervals in which dexamethasone produced the increase in insulin concentration were accompanied with decrease in insulin binding to receptors in membranes of liver cells, while significant changes in insulin binding to receptors of erythrocytes were not observed under the same experimental conditions. The effect is maximal 18 and 42 h after dexamethasone treatment that increase insulin blood level by about 85% and 60%, respectively. Receptor analysis revealed that changes in specific binding of insulin could be due to significant changes in amount of binding sites on cell surface rather than to mild alteration in receptor affinity. These findings suggest that besides the changes in insulin level, the alterations in insulin receptor number and affinity may play a major role in the states of altered insulin sensitivity which accompany glucocorticoid excess.     

Modulation of insulin receptors and catecholamines in rat brain in hyperglycemia and hyperinsulinemia

Insulin receptor activity and its relationship with catecholamines and serotonin were investigated in rat whole brain membranes, synaptosomes and choroid plexus in alloxan induced short term and long term hyperglycemia and hyperinsulinemia. Insulin receptor activity was measured by [125I]insulin binding and catecholamines by high performance liquid chromatography with electrochemical detection. While choroid plexus insulin receptors modulate along with norepinephrine, dopamine and serotonin with the changes in insulin and/or plasma glucose levels, insulin receptor activity in synaptosomes and total membranes is not affected to a great extent except in long term hyperglycemia.     

Comparison of insulin receptor binding to monocytes and erythrocytes in newly diagnosed type II diabetes mellitus

Insulin binding to circulating monocytes and erythrocytes was studied in 20 healthy volunteers and in 25 obese hyperinsulinemic newly diagnosed type-II diabetics. In type-II diabetics insulin binding to monocytes as well as to erythrocytes was significantly decreased in comparison with healthy individuals. The lowered insulin binding of the diabetics was mainly caused by a loss of receptor number. Individual analysis of the binding data, however, shows a marked discrepancy between receptor binding to circulating monocytes compared with erythrocytes. Since insulin binding to erythrocytes shows a great variation and seems to be influenced by other factors beside insulin concentrations it is suggested that insulin receptors on monocytes should be preferred for evaluation of peripheral insulin sensitivity.     

Determination of the mean cell age of erythrocytes from diabetic subjects with pyruvate kinase

The pyruvate kinase activity of erythrocytes from normal and diabetic subjects was examined in order to establish this enzyme as a valid indicator of mean cell age in the studies of age-dependent erythrocyte functions. This study reveals that the enzyme activity in the erythrocytes was not affected by the condition of diabetes and suggests that it may provide a simple means for the determination of cell age in erythrocyte insulin binding studies. Present data further indicate that the mean cell age of the erythrocytes from diabetic patients was not significantly different from normal although insulin binding to erythrocytes was markedly reduced when compared with that in the normal subjects.     

不同年龄红细胞(人)的增溶胰岛素受体和胰岛素结合以及依赖于胰岛素的磷酸化反应

1.我们研究了人的不同年龄红细胞的胰岛素受体从膜上增溶后和胰岛素相结合的特征。结果表明,随着红细胞年龄的增加,增溶胰岛素受体和胰岛素的最大结合能力下降;ED_(50)降低,同时受体结合位点数减少。青年红细胞的增溶胰岛素受体数比去年的高一倍,但其亲和性不论在结合平衡状态或动力学状态都基本一致。 2.利用γ-~(32)P-ATP的~(32)P参入量研究了胰岛素对不同年龄红细胞增溶蛋白质及外源蛋白质的磷酸化的影响。在胰岛素存在时,磷酸化分别增加2.3—2.9倍,及3.4—4.4倍。胰岛素刺激青年红细胞的增溶蛋白质的磷酸化的敏感性为老年的2.4倍。 3.研究结果表明,单个人的血样可用来研究胰岛素受体的结合及激酶的性质。     

Effect of gamma irradiation on insulin receptor interaction in rat erythrocytes

An insulin receptor interaction has been studied in rat erythrocytes after whole-body gamma irradiation (1 Gy). Specific binding of insulin was found to increase 30 days following irradiation against the background of a decreased immunoreactive insulin concentration in the blood. A change in the postirradiation activity of insulin receptors is considered as a manifestation of the homeostatic mechanism of "up" regulation in exposed animals.     

Cytoskeletal components enhance the autophosphorylation of retinal insulin receptor

Insulin receptor (IR) signaling provides a trophic signal for transformed retinal neurons in culture, and we recently reported that deletion of IR from rod photoreceptors resulted in stress-induced photoreceptor degeneration. Retinal insulin receptor has a high basal level autophosphorylation compared to liver and the reasons for higher autophosphorylation are not known. In the current study we report a novel finding that cytoplasmic actin associates with and activates the retinal IR in vivo. Similar to insulin, actin also induced autophosphorylation at tyrosines 1158, 1162 and 1163 in the catalytic loop of IR. Our studies also suggest that globular actin activates the retinal IR more effectively than does filamentous actin. Retinal IR kinase activity has been shown to decrease in hyperglycemia and we found a decreased binding of actin to the IR under hyperglycemia. This is the first study which demonstrates that cytoplasmic actin regulates autophosphorylation of the retinal IR.     

Insulin receptor changes in type 2 diabetes after short term insulin treatment

We have studied erythrocyte insulin receptor changes before and after 8 days of continuous subcutaneous insulin infusion by a pump in 11 uncontrolled obese non-insulin-dependent diabetics (type 2), diet and drug resistant for at least three months previously. All the patients were hospitalized. On day 1 of the study, their oral hypoglycemic agents were stopped and hypocaloric diet (1000 Kcal/day) was maintained (strictly reinforced). This period of reinforced treatment was not accompanied by correction of hyperglycemia. On day 9 patients were placed for 12 hours on artificial pancreas in order to bring their fasting blood glucose levels down to normal values. Then they were submitted to a continuous subcutaneous insulin infusion (CSII) for the following 8 days. There was a significant decrease in mean fasting plasma glucose (P less than 0.001) and a rise in insulin (P less than 0.05) levels after insulin treatment. Mean specific insulin binding was also significantly increased (P less than 0.01). The increase in binding (with insulin therapy) correlated with the fall in fasting hyperglycemia (r = 0.786, P less than 0.01). In addition, the increase in binding correlated negatively with changes in fasting plasma insulin levels (r = -0.867, P less than 0.01), under treatment, on one hand and with the dose of exogenous insulin administered (r = -0.681, P less than 0.05) on the other hand. There was no correlation between binding and fasting plasma insulin levels (before and after insulin therapy), or between diabetes duration and any of the previous parameters.(ABSTRACT TRUNCATED AT 250 WORDS)     

The Male Obese Wistar Diabetic Fatty Rat Is a New Model of Extreme Insulin Resistance

The male obese Wistar Diabetic Fatty (WDF) rat is a genetic model of obesity and non-insulin dependent diabetes (NIDDM). The obese Zucker rat shares the same gene for obesity on a different genetic background but is not diabetic. This study evaluated the degree of insulin resistance in both obese strains by examining the binding and post binding effects of muscle insulin receptors in obese, rats exhibiting hyperinsulinemia and/or hyperglycemia. Insulin receptor binding and affinity and tyrosine kinase activity were measured in skeletal muscle from male WDF fa/fa (obese) and Fa/? (lean) and Zucker fa/fa (obese) and Fa/Fa (homozygous lean) rats. Rats were fed a high sucrose (68% of total Kcal) or Purina stock diet for 14 weeks. At 27 weeks of age, adipose depots were removed for adipose cellularity analysis and the biceps femoris muscle was removed for measurement of insulin binding and insulin-stimulated receptor kinase activity. Plasma glucose (13.9 vs. 8.4 mM) and insulin levels (14,754 vs. 7440 pmoI/L) were significantly higher in WDF obese than in Zucker obese rats. Insulin receptor number and affinity and TK activity were unaffected by diet. Insulin receptor number was significantly reduced in obese WDF rats (2.778 ± 0.617 pmol/mg protein), compared to obese Zucker rats (4.441 ± 0.913 pmol/mg potein). Both obese strains exhibited down regulation of the insulin receptor compared to their lean controls. Maximal tyrosine kinase (TK) activity was significantly reduced in obese WDF rats (505 ± 82 fmol/min/mg protein) compared to obese Zucker rats (1907 ± 610 fmol/min/mg protein). Only obese WDF rats displayed a decrease in TK activity per receptor. These observations establish the obese WDF rat as an excellent model for exploring mechanisms of extreme insulin resistance, particularly post-receptor tyrosine kinase-associated defects, in non-insulin dependent diabetes.     

Insulin receptor down regulation in human erythrocytes

Insulin receptor processing in human erythrocytes was investigated. Insulin binding to the cell surface was found to decrease by 70% in cells which had first been incubated with insulin for 3 h, then washed for 3 h. After an additional 16-h incubation without insulin, the level of cell surface insulin binding was restored to control values, even in the presence of cyclohexamide. Our results suggest that erythrocyte insulin receptors are internalized in response to insulin and that receptors are subsequently recycled to the surface of the cell.