Interaction of receptors for prostaglandin E1/prostacyclin and insulin in human erythrocytes and platelets.

Prostaglandin E1/I2 and insulin receptors of human erythrocyte and platelet are capable of modulating each other's activity. This modulation of the receptor activity and number in one system by a second receptor system in human platelet and erythrocyte seems to be beneficial. Insulin increases the PGE1 binding to platelets and thereby enhances the platelet antiaggregatory action of prostaglandin by increasing cyclic AMP levels. Similarly, PGE1 increases insulin binding to human erythrocyte, and thereby reduces the optimum concentration of insulin for a maximal reduction in membrane microviscosity. During ischemia the reduced response of platelets to the inhibitory effect of PGE1 or PGI2 relates to the impaired PGE1/I2 receptor activity. Treatment of these platelets with insulin at physiological concentrations can normalise the PGE1/I2 receptor activity. This review focuses on the relationship between the two receptor systems in human blood cells.     

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.     

Distribution of insulin receptors in human erythrocyte membranes. Insulin binding to sealed right-side-out and inside-out human erythrocyte vesicles

Analyses of insulin binding to human erythrocytes and to resealed right-side-out and inside-out erythrocyte membrane vesicles have revealed that high affinity insulin binding receptors are present on both sides of the erythrocyte membranes. Insulin binding to human erythrocytes was examined with the use of a binding assay designed to minimize the potential errors arising from the low binding capacity of this cell type and from non-specific binding in the assay. Scatchard analysis of equilibrium binding to the cells revealed a class of high affinity sites with a dissociation constant (Kd) of (1.5 +/- 0.5) X 10(-8) M and a maximum binding capacity of 50 +/- 5 sites per cell. Interestingly, both resealed right-side-out and inside-out membrane vesicles exhibited nearly identical specific sites for insulin binding. At the high affinity binding sites, for both right-side-out and inside-out vesicles, the dissociation constant (Kd) was (1.5 +/- 0.5) X 10(-8) M, and the maximum binding capacity was 17 +/- 3 sites per cell equivalent. These findings suggest that insulin receptors are present on both sides of the plasma membrane and are consistent with the participation of the erythrocyte insulin receptors in an endocytic/recycling pathway which mediates receptor-ligand internalization/externalization.     

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.     

The effect of insulin on glucose transport in rabbit erythrocytes and reticulocytes

Insulin binding and 3-0-Methylglucose transport have been studied in erythrocyte- and reticulocyte-enriched fractions of blood cells in order to determine if the increased number of insulin binding sites in reticulocytes is associated with a glucose transport response to insulin. In these experiments rabbit reticulocytes demonstrate an eightfold increase in total insulin receptors when compared to erythrocytes. Glucose transport activity in the erythrocyte has a K_m of 3.2 mM. Reticulocytes demonstrate a saturable glucose transport activity of lower affinity, K_m 18.9 mM. Neither the erythrocyte, nor the reticulocyte glucose transport activity, was capable of an increased response to insulin. The low affinity glucose transport activity in reticulocytes could allow a fourfold increase in facilitated glucose transport at supraphysiological glucose concentrations that might occur in poorly controlled diabetes mellitus.     

Insulin receptors on erythrocytes and hepatocytes from streptozotocin induced diabetic rats

Insulin receptors on hepatocytes and erythrocytes were studied in rats two and eight weeks after the injection of streptozotocin (50 mg/kg) to see if erythrocyte insulin receptors change parallel with hepatocyte insulin receptors in response to hypoinsulinemia. Insulin binding to hepatocytes increased two (14.0 +/- 2.5% v.s. 7.7 +/- 0.7%; P less than 0.025) and eight weeks (15.9 +/- 1.9% v.s. 6.6 +/- 1.1%; P less than 0.005) after the streptozotocin injection. Scatchard analysis revealed that this increase was due to a rise in both the receptor concentration and affinity. The number of receptors was comparable in the two- and eight-week-streptozotocin rats while the increase in the affinity was more pronounced in the latter group. Insulin binding to the erythrocytes was also increased in both two- (5.0 +/- 0.7% v.s. 4.2 +/- 0.6%) and eight-week- (4.3 +/- 0.6% v.s. 2.7 +/- 1.2%) streptozotocin rats. This increase was due to a rise in the receptor concentration rather than the affinity. However, compared to hepatocytes, these changes were inconsistent and statistically not significant. Furthermore, no correlation was obtained between the binding and plasma insulin concentration. These results indicate that insulin receptors on rat erythrocytes are less sensitive to a change in the plasma insulin concentration and do not always reflect accurately the receptor state on hepatocytes.     

Effects of human growth hormone on erythrocyte insulin binding in growth hormone deficient children

In this paper, the effect of acute human growth hormone (GH) administration on erythrocyte insulin binding in GH deficient children (N = 6) was studied. Following GH (0.25 U/kg) administration, the blood levels of GH peaked within 4 to 8 h and returned to basal levels 24 h later. However, the changes in somatomedin activity, free fatty acid (FFA), urea, blood glucose and 125I-insulin binding to erythrocyte were observed around 24 h following the injection, and there was a converse relationship between maximum percent 125I-insulin binding (IBmax) and FFA (P less than 0.02). By Scatchard analysis it was found that the decrease in IBmax is mainly due to the change in the number of insulin receptors. These results suggest that GH may possibly affect the insulin binding to erythrocyte indirectly through metabolic changes as a result of hormonal changes in GH deficient children.     

Insulin-like growth factor I (IGF-I) and insulin binding to erythrocytes of normal prepubertal children and adults.

Erythrocyte insulin-like growth factor I (IGF-I) and insulin receptors were characterized in 10 normal prepubertal children (5 girls and 5 boys) aged 4-11 yrs and 10 normal adults (4 women and 6 men) aged 32-47 yrs. erythrocytes were purified from 5 ml of blood by Ficoll-Paque gradient centrifugation. Reticulocytes count in the erythrocyte suspensions were lower than 1%. Insulin and IGF-I binding assays were performed simultaneously. Maximal percent binding of [125I] labelled IGF-I was significantly higher in prepubertal children than in adults (8.7 +/- 0.7% versus 6.2 +/- 0.5% at a concentration of 5 x 10(9) erythrocytes/ml). Scatchard analysis revealed the high affinity constant was better in prepubertal children (Ka = 4.6 +/- 1.3 nM-1 versus 1.8 +/- 0.2 nM-1), whereas the binding capacity was similar (5.8 +/- 1.1 versus 7.7 +/- 0.8 high affinity binding sites/cell). In both groups, unlabelled IGF-I inhibited tracer-binding half maximally at about 1 nM. Insulin was 100-fold less potent. In adults, specific binding of [125I] labelled IGF-I was higher in women (7.6 +/- 0.7%) than in men (5.3 +/- 0.4%). No significant difference was observed in maximal specific binding of [125I] labelled insulin between prepubertal children (8.2 +/- 0.5%) and adults (7.2 +/- 0.7%). In both groups, competition by unlabelled insulin for [125I] labelled insulin binding gave 50% displacement for approximately 0.25 nM and IGF-I was about 80-fold less potent. Both IGF-I and insulin binding parameters were not significantly correlated with plasma hormone levels. In prepubertal children, the high-affinity IGF-I receptors number decreased with increasing high-affinity insulin receptors number.(ABSTRACT TRUNCATED AT 250 WORDS)     

Substitution of the insulin receptor transmembrane domain with that of glycophorin A inhibits insulin action.

To study the role of transmembrane (TM) domains interactions in the activation of the insulin receptor, we have replaced the insulin receptor TM domain with that of glycophorin A (GpA), an erythrocyte protein that spontaneously forms detergent-resistant dimers through TM-TM interactions. Insulin receptor cDNA sequences with the TM domain replaced by that of GpA were constructed and stably transfected in CHO cells. Insulin binding to cells and solubilized receptors was not modified. Electrophoresis after partial reduction of disulfide bonds revealed an altered structure for the soluble chimeric receptors, seen as an altered mobility apparently due to increased interactions between the beta subunits of the receptor. Insulin signaling was markedly decreased for cells transfected with chimeric receptors compared with cells transfected with normal receptors. A decrease in insulin-induced receptor kinase activity was observed for solubilized chimeric receptors. In conclusion, substitution by the native GpA TM domain of the insulin receptor results in structurally modified chimeric receptors that are unable to transmit the insulin signal properly. It is hypothesized that this substitution may impose structural constraints that prevent the proper changes in conformation necessary for activation of the receptor kinase. Other mutants modifying the structure or the membrane orientation of the glycophorin A TM domain are required to better understand these constraints.     

Fasting and refeeding alter the insulin receptor tyrosine kinase in chicken liver but fail to affect brain insulin receptors

Insulin receptors from chicken liver and brain were studied following alterations in the nutritional state. Chickens were either fasted for 48 h, fasted for 48 h and then refed for 24 h, or fed a regular diet ad libitum. 125I-Porcine insulin binding was significantly elevated in liver membranes from the fasted animals and lowered in refed chickens when compared to preparations from ad libitum fed chickens. These changes in 125I-insulin binding were inversely related to the levels of plasma insulin and since receptor affinities for insulin were similar in each group, they probably represent alterations in receptor number. Apparent Mr of alpha subunits of the insulin receptors was unaffected by alterations in the nutritional states. The presence of ATPase-like activities that co-eluted with liver insulin receptors from wheat germ agglutinin lectin columns but not from pea lectin columns necessitated the use of both pea and wheat germ agglutinin for liver insulin receptor purification. The insulin receptors purified from both lectin columns were recognized by anti-insulin receptor antiserum and had similar affinities for insulin which were unaltered by the nutritional state. Insulin-stimulatable autophosphorylation of the beta subunit of the insulin receptor was lower in livers from fasted chickens and intermediate in refed chickens. Furthermore, basal and insulin-induced phosphorylation of the artificial substrate poly(Glu,Tyr) 4:1 was significantly less in the fasting state and intermediate in the refed state compared to the ad libitum fed state. Insulin sensitivity (measured as the dose of insulin required for 50% maximal stimulation of kinase activity) was similar in all three states suggesting that the differences in insulin-induced phosphorylation are due to a change in maximal stimulation and not a change in insulin sensitivity. In contrast to the alterations seen with liver receptors, brain insulin receptors were unaffected by these alterations in nutritional state. These findings suggest that: liver insulin receptors are affected by altering the nutritional state; insulin binding to liver membranes is inversely related to plasma insulin levels; and tyrosine kinase is decreased both in fasted and refed animals suggesting an uncoupling of the normal interaction between alpha subunit and beta subunit in liver insulin receptors.     

In Situ Characterization of Renal Insulin Receptrors in the Rat

Abstract

Insulin regulates carbohydrate metabolism, and water, sodium, potassium, and phosphate reabsorption in the kidney by binding to specific receptors. Insulin receptors have been identified in the kidney using membrane preparations obtained from both glomeruli and tubules. In this study, an autoradiographic technique was used to characterize insulin receptors in the rat kidney. Frozen tissue sections were preincubated to remove endogenously bound insulin, incubated in a buffer containing 200 pM 12sl-Tyr-insulin, washed, and dried before exposure on Ultrofilm. Binding density was assessed by computerized microdensitometry. In the cortex, binding density was comparable in glomeruli and tubules. In the medulla, bound radioligand was found primarily in longitudinal structures traversing the outer portion, presumably corresponding to vascular bundles, and in the inner portion. Scatchard analysis of competition binding data resulted in curvilinear profiles, indicating either two classes of receptors with different affinity or the presence of a single class of receptors with a negative cooperative hormone-receptor interaction. Data analyzed for a two-site model showed one receptor site with Kd of 0.39f0.14 nmol/l and Bmax of 3. M. O × 1010 receptordmma and another site with Kd of 0.30fl.1 pmoVl and a Bmax of 3.2 × 1013 receptordmms. Thus, in situ autoradiography can be used to determine distribution and binding characteristics of insulin receptors in rat kidney and might be employed in receptor studies on rat models of human disease.     

Interferon-alpha down-regulates insulin receptors in lymphoblastoid (Daudi) cells. Relationship to inhibition of cell proliferation

The Daudi line of human lymphoblastoid cells requires insulin and transferrin for growth in serum-free medium and is highly sensitive to the inhibitory effect of human leukocyte interferon (IFN-alpha) on cell proliferation. A variant subline of Daudi cells, which is resistant to the antiproliferative action of IFN-alpha, also has been grown in serum-free medium containing insulin and transferrin. The proliferation of IFN-sensitive and -resistant Daudi cells is dependent on the occupancy of insulin receptors, with optimal cell proliferation observed at high receptor occupancy (nearly 100%). No evidence was found for receptors for insulin-like growth factor I on Daudi cells. IFN treatment of IFN-sensitive cells decreased the capacity of the cells to bind 125I-insulin. The altered binding capacity was due to diminished specific, lower affinity insulin binding, as detected at high 125I-insulin concentrations. Higher affinity insulin binding was not altered by IFN. Insulin binding was also reduced in detergent-solubilized extracts from IFN-treated sensitive Daudi cells and the magnitude of the effect was comparable to that observed in intact cells. This indicates that the total number of insulin binding sites (surface + internal) is decreased in IFN-treated sensitive cells. Insulin binding to IFN-sensitive cells decreased linearly with time between 6 and 48 h from the addition of IFN. The effect on lower affinity insulin binding developed more rapidly than the inhibitory effect of IFN on cell proliferation. The insulin-binding capacity of Daudi cells resistant to the antiproliferative effect of IFN was unaffected by IFN, despite the fact that these cells contain as many cell surface IFN receptors as sensitive cells. These observations raise the possibility that lower affinity insulin binding is important in the growth-promoting actions of insulin.     

Decreased binding of insulin to its receptors in rats with hormone induced insulin resistance

Insulin and glucagon receptor binding was studied in purified liver membranes from rats made insulin resistant by implantation of an MtT pituitary tumor which secretes growth hormone, prolactin, and ACTH. Insulin binding to its receptors was decreased and correlated with the degree of insulin resistance. In contrast, binding of glucagon to its receptors was unchanged.     

Effects of dietary fats on red blood cell membrane insulin receptor in normo- and hypercholesterolemic miniature swine

It has been demonstrated that the type of dietary fat affects insulin receptors in various tissues in normal humans and animals by altering membrane fluidity. This study compares the effects of n-3 fatty acids from fish oil and n-6 fatty acids from corn oil on red blood cell membrane insulin receptors in normal and hypercholesterolemic minipigs. A group of minipigs were made hypercholesterolemic by feeding cholesterol and lard for 2 months; the other group served as controls and was fed stock diet. Both groups were then fed experimental diets containing either corn oil or menhaden oil or a mixture of the two for 23 additional weeks. Blood was collected at 0, 2, 12 and 23 weeks after the start of the experimental diets and membranes were prepared from the red blood cells. Insulin binding to red blood cell membranes was measured by radioreceptor assay. Plasma insulin was measured by radioimmunoassay. Insulin binding to red blood cell membrane was compared with the fluidity of the membrane measured and reported earlier. There was no significant effect of cholesterol feeding on plasma insulin concentrations. After 23 weeks on experimental diet plasma insulin was significantly higher in minipigs fed menhaden oil compared to those fed corn oil. No such effect was observed in hypercholesterolemic minipigs. No significant effect of either hypercholesterolemia or fish oil was observed on red blood cell insulin binding. A significant negative relationship was observed between insulin binding and anisotropy at 4°C for all probes but at 37°C significant negative relationship was observed only with polar probes. The data suggest that n-3 fatty acids from fish oil significantly increases plasma insulin in minipigs compared to n-6 fatty acids from corn oil. However, the unsaturation has no significant effect on insulin receptors on erythrocytes. Similarly, prior hypercholesterolemic state also has no effect on plasma insulin levels or the insulin binding to red blood cell membranes.     

Amyloid insulin interaction with erythrocytes.

Erythrocyte membrane interactions with insulin fibrils (amyloid) have been investigated using centrifugation, fluorescence spectroscopy, light scattering, and flow cytometric techniques. The results indicate that insulin fibrils are having moderate affinity to erythrocyte membrane. However, analysis of the apparent dissociation constants of human erythrocyte membranes (leaky and resealed vesicles) with amyloid insulin reveal that the insulin binding is drastically reduced on attaining the fibrillar state compared with native insulin. To understand the role of insulin receptors on erythrocytes binding to amyloid, we have studied the interaction of biotinylated forms of denatured and amyloidic insulin with erythrocytes. FITC-streptavidin was used as a counter staining in flow cytometry measurements. We found that insulin fibrils bind 10 times more with erythrocyte membranes than with amylin and denatured insulin.     

Characterization of insulin receptors in human promyelocytic leukemia cell HL60

Highly specific insulin receptors have been identified on human promyelocytic leukemia cells HL60. Insulin binding increased progressively with time to reach a maximum at 2 h at 22° and was proportional to the number of cells in the incubation mixture. Insulin degradation as assessed by TCA precipitation and reincubation studies was negligible. Scatchard analysis of the binding data was curvilinear and the total number of insulin receptor sites per cell was around 45,000. The average affinity profile gave an “unoccupied site” affinity constant of 3.5 × 10⁸ M^?1. The promyelocytic cells HL60, thus, have specific binding sites and binding characteristics similar to more mature human myeloid cells.     

Receptor binding and mitogenic effects of insulin and insulinlike growth factors I and II for human myeloid leukemic cells

Insulin and insulinlike growth factors I and II (IGF-I and IGF-II) influence mesodermal cell proliferation and differentiation. As multiple growth factors are involved in hemopoietic cell proliferation and differentiation, we assessed the receptor binding and mitogenic effects of these peptides on a panel of mesodermally derived human myeloid leukemic cell lines. The promyelocytic cell line HL60 had the highest level of specific binding for these 125I-labeled ligands, with lower binding to the less differentiated myeloblast cell line KG1 and undifferentiated blast variants of these cell lines (HL60blast, KG1a). Insulin binding affinity and receptor numbers were reduced significantly by chemically induced granulocytic differentiation of HL60 cells and was unchanged following induced monocytic differentiation. No substantial alteration in IGF-I or -II binding occurred with induced HL60 cell differentiation. Insulin and IGF-I demonstrated cross competition for receptor binding and down-regulated their homologous receptors without detectable cross modulation of the heterologous receptors on HL60 cells. IGF-I and insulin increased HL60 cell proliferation, as assessed by 3H-thymidine uptake, IGF-I greater than insulin. IGF-I binding and mitogenic effects were blocked by the monoclonal anti-IGF-I receptor antibody IR3, indicating that IGF-I-induced proliferative effects were mediated via its homologous receptor. In contrast, insulin binding and mitogenesis displayed blocking by both anti-IGI-I and anti-insulin receptor antibodies, indicating mediation of its activity through both receptors. These data demonstrate specific binding and mitogenic interactions between insulin, IGFs, and hemopoietic cells which are associated with their state of differentiation.     

Erythrocyte insulin receptor characteristics and erythrocyte membrane lipid composition in healthy men

The cell membrane plays an important role in the mechanism of insulin action. To test whether erythrocyte insulin receptor characteristics are related to the erythrocyte membrane lipid composition, 11 healthy volunteers were studied. The relationship between insulin binding to erythrocytes, the number of receptors per cell and the affinity of receptors to insulin on the one hand and total phospholipid fatty acid (FA) composition and cholesterol/phospholipid molar ratio in the erythrocyte membrane on the other hand were evaluated. 1. We found a significant negative correlation between specific insulin binding and the proportion of n-6 essential FA in erythrocyte membrane phospholipids, especially linoleic acid (r = -0.82, p less than 0.01) and arachidonic acid (r = -0.73, p less than 0.05). On the other hand, a significant positive correlation between insulin binding and the proportion of nonessential FA (r = +0.65, p less than 0.05) was seen. Number of receptors per cell and the affinity of receptors were not significantly related to phospholipid FA composition. 2. There was no significant correlation between insulin receptor characteristics and the cholesterol/phospholipid molar ratio in the erythrocyte membrane. The data presented support the hypothesis that the FA pattern of membrane total phospholipids may modify the properties of insulin receptors.     

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。     

Basal autophosphorylation of insulin receptor occurs preferentially on the receptor conformation exhibiting high affinity for insulin and stabilizes this conformation

Insulin signal transmission through the plasma membrane was studied in terms of relationship between basal autophosphorylation of the β-subunit and the ability by bind insulin by the -subunit of the insulin receptor. In a cell free system, receptors phosphorylated on tyrosine residues in the absence of insulin were separated from non-phosphorylated receptors using antiphosphotyrosine antibodies. Insulin binding assays were then performed on basally autophosphorylated and on non-phosphorylated receptors. We found that the tyrosine phosphorylated receptors, which corresponded to 25% of the total number of receptors, were accountable for 60–80% of insulin binding. Scatchard representation of binding data has shown that the plot corresponding to tyrosine phosphorylated receptors was localized above, and was steeper than the plot corresponding to non-phosphorylated receptors. These data make it likely that the conformation of -subunit which favours ligand binding is connected to the conformation of β-subunit which favours phosphate reception on tyrosine residues. Reciprocally, the high-affinity conformation of insulin receptor seems to become stabilized by basal autophosphorylation.