Absence of covalent binding by insulin to erythrocyte and reticulocyte insulin receptors

We investigated whether insulin forms covalent bonds with its receptors on erythrocytes and reticulocytes, as it does in adipocytes (1). Of the [125I]-insulin specifically bound at 37 degrees C to human and rat erythrocytes and rat reticulocytes, only 1.5-2.3% was non-dissociable on extensive washing. When ghosts prepared from the washed cells were solubilized in Triton X-100, only 0.6-1.5% of the specifically bound radioactivity appeared in the void volume of a Sephadex G-50 column. Moreover in contrast to adipocytes, this high molecular weight radioactivity was not immunoprecipitable by antibodies to the insulin receptor and was dissociated during chromatography in sodium dodecyl sulphate. Thus we have been unable to demonstrate the formation of covalent bonds between insulin and its receptors on erythrocytes and reticulocytes. This finding is consistent with the hypothesis that covalent binding of insulin is a necessary receptor modification for insulin's metabolic effects.     

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.     

Decreased binding of insulin to liver plasma membrane receptors in hereditary diabetic mice.

The interaction of insulin with its receptors was studied in liver plasma membranes of the young non-obese hereditary diabetic mouse (KK strain). Under identical conditions of preparation and incubation, the membranes of the KK mouse bind only 55-70% as much insulin per mg of protein as those of the control mouse (Swiss albino). Scatchard analysis suggests that this decrease in binding is due to a decrease in the number of receptor sites in the membrane of the diabetic mouse. However, the membranes of diabetic and control mice do not exhibit significant differences in hexosamine and sialic acid contents, enzyme activities, and protein and glycoprotein analysis. The decrease in insulin receptors in the KK mouse seems to correlate with the insulin resistance which they exhibit.     

Essential metal ions alter the lactoferrin binding to the erythrocyte plasma membrane receptors

The effect of metal ions at a concentration of l0^-8 to l0^-5 M [using their salts: ZnCl₂, CdCl₂, LiCl, CuSO₄, NiSO₄, A1₂(SO₄)₃, (NH₄)₂MoO₄ on the lactoferrin (Lf) binding to the erythrocyte membrane receptors was studied. In the absence of metal ions, Scatchard’s analysis showed the existence of two kinds of binding site: one with high affinity and low capacity, and the another with low affinity and high capacity. All these metals, excluding Zn²⁺ and Cd²⁺, at a concentration 10^-5 M decreased the affinity of Lf binding (Ka₁) to the high-affinity receptors. In the presence of Zn²⁺ and Cd²⁺, only the lowaffinity binding site was found. Significant inhibition on the affinity (Ka₂) of the low-affinity class of receptors showed Zn²⁺, Al³⁺, and Mo⁶⁺. Depending on their concentration (10^-8-10^-5 M), these ions enhanced to a different extent, the binding capacity of the both types receptors, but the effect did not correspond to the applied doses. Several explanations of the mechanism for influence of the metal ions on the Lf-receptor interaction is discussed.     

Effect of hemoperfusion on plasma oxidizing capacity and erythrocyte sensitivity to oxidation in patients with chronic uremia

An effect of haemoperfusion on plasma oxidizing capacity and erythrocyte sensitivity to oxidation was investigated in patients with the chronic uremia. It was found that plasma oxidizing capacity measured with NTB reduction is more pronounced in patients with the chronic uremia than in normal subjects. Oxidizing capacity of plasma is increased at the beginning of haemoperfusion. This effect is clearly seen during single pass of blood through the column with activated carbon. Erythrocyte sensitivity to oxidation following their suspension in the normal saline with phosphate buffer and measured with ascorbic-cyanate test does not differ significantly in patients with the chronic uremia and healthy subjects and does not change markedly during haemoperfusion.     

Stoichiometry for the binding of insulin to insulin receptors in adipocyte membranes

Insulin receptor molecules in rat adipocyte plasma membranes were shown to be monovalent with respect to their capacity to bind insulin. The 1:1 stoichiometry for insulin binding was determined by a "double-probe labeling" procedure, wherein 125I-insulin (probe 1) was affinity cross-linked to its receptor in the presence of an excess saturating concentration of an unlabeled biotinylated insulin derivative (probe 2). If the receptor were competent to bind more than one insulin molecule, any receptor molecule that was cross-linked to probe 1 also should have been cross-linked to probe 2 in the double probe labeling procedure. The monovalent character of the insulin receptor was indicated by the failure of the probe 1-linked receptor to be cross-linked to probe 2. This was indicated by the failure of succinylavidin to increase the molecular weight of the probe 1-linked receptor. Control experiments indicated that succinylavidin increased the molecular weight of receptor that had been cross-linked to probe 2. The 1:1 stoichiometry for insulin binding demonstrated here indicates that if insulin receptors contain more than one insulin binding subunit, the binding of insulin to its receptor must be a highly negatively cooperative process.     

The effect of diffusion on the binding of membrane-bound receptors to coated pits.

We have formulated a kinetic model for the primary steps that occur at the cell membrane during receptor-mediated endocytosis. This model includes the diffusion of receptor molecules, the binding of receptors to coated pits, the loss of coated pits by invagination, and random reinsertion of receptors and coated pits. Using the mechanistic statistical theory of nonequilibrium thermodynamics, we employ this mechanism to calculate the two-dimensional radial distribution of receptors around coated pits at steady state. From this we obtain an equation that describes the effect of receptor diffusion on the rate of binding to coated pits. Our equation does not assume that ligand binding is instantaneous and can be used to assess the effect of diffusion on the binding rate. Using experimental data for low density lipoprotein receptors on fibroblast cells, we conclude that the effect of diffusion on the binding of these receptors to coated pits is no more than 84% diffusion controlled. This corresponds to a dissociation rate constant for receptors on coated pits (k-) that is much less than the rate constant for invagination of the pits (lambda = 3.3 X 10(-3)/s) and a correlation length for the radial distribution function of six times the radius of a coated pit. Although the existing experimental data are compatible with any value of k-, we obtain a lower bound for the value of the binding constant (k+) of 2.3 X 10(-2)(micron)2/s. Comparison of the predicted radial distributions with experiment should provide a clear indication of the effect of diffusion on k+.     

The effect of acetoacetate on plasma insulin concentration

1. Sodium acetoacetate was infused into the inferior vena cava of fed rats, 48h-starved rats, and fed streptozotocin-diabetic rats treated with insulin. Arterial blood was obtained from a femoral artery catheter. 2. Acetoacetate infusion caused a fall in blood glucose concentration in fed rats from 6.16 to 5.11mm in 1h, whereas no change occurred in starved or fed-diabetic rats. 3. Plasma free fatty acids decreased within 10min, from 0.82 to 0.64mequiv./l in fed rats, 1.16 to 0.79mequiv./l in starved rats and 0.83 to 0.65mequiv./l in fed-diabetic rats. 4. At 10min the plasma concentration rose from 20 to 49.9muunits/ml in fed unanaesthetized rats and from 6.4 to 18.5muunits/ml in starved rats. There was no change in insulin concentration in the diabetic rats. 5. Nembutal-anaesthetized fed rats had a more marked increase in plasma insulin concentration, from 30 to 101muunits/ml within 10min. 6. A fall in blood glucose concentration in fed rats and a decrease in free fatty acids in both fed and starved rats is to be expected as a consequence of the increase in plasma insulin. 7. The fall in the concentration of free fatty acids in diabetic rats may be due to a direct effect of ketone bodies on adipose tissue. A similar effect on free fatty acids could also be operative in normal fed or starved rats.     

The effect of high-glucose condition on insulin binding to IM-9 lymphocytes

The long-term effect of high-glucose condition on insulin binding to IM-9 cells was studied by incubating the cells in RPMI-1640 medium containing 450 mg/dl of glucose. Insulin binding began to decrease after incubation for 6 days in high-glucose-treated cells, and significantly decreased after 14 days due to the reduction of receptor affinity. The number of binding sites for insulin did not change by the treatment. Thus, high-glucose condition per se does not appear to induce the decrease of the number of insulin receptors on target cells, as observed in diabetic patients.     

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.     

Relation of insulin receptors to insulin resistance.

The status of insulin-receptor interactions in a variety of insulin-resistant states is reviewed. Utilizing large adipocytes from adult rats and small fat cells from young rats, we have conducted a series of in vitro experiments in an attempt to determine the cellular alteration(s) responsible for the insulin resistance associated with obesity. Stimulation of glucose oxidation by insulin is reduced in large cells. Studies using a mimicker of insulin action, spermine, as well as measurements of 125I-insulin binding to large and small cells indicate that receptor number and affinity are not responsible for hormone resistance. Furthermore, when rapid and direct measurements of sugar uptake were made, insulin stimulation was virtually identical in both cell types. These findings indicate that large adipocytes have an efficient insulin-responsive D-glucose transport system and suggest that the apparent hormone resistance may be due to alterations in intracellular glucose metabolism. It has been proposed that altered insulin-receptor interaction underlies the insulin resistance of human obesity. We have investigated this particular aspect of insulin action by 125I-insulin binding studies. Similar numbers of insulin receptors per cell and affinity for insulin were observed in adipocytes obtained from normal weight subjects and morbidly obese patients. Thus, the initial step in insulin action is unaltered in human obesity.     

The nonclassical insulin binding of insulin receptors from rat liver is due to the presence of two interacting alpha-subunits in the receptor complex

The binding characteristics of the insulin receptor tetramer (alpha 2 beta 2) and dimer (alpha beta) were examined. Unlabelled insulin enhanced the dilution-induced dissociation only of the receptor tetramer-bound 125I-insulin. Furthermore, when both the receptor forms had been preincubated with anti-receptor-antibodies (B9-antiserum), insulin binding only to the receptor tetramer but not to the dimer was inhibited. However, both oligomers are not immunologically distinct since more than 80% of the two forms were immunoprecipitated by the antiserum. These results suggest that both insulin and anti-receptor-antibodies induce cooperative interactions between the two linked alpha-subunits of the receptor tetramer leading to a decrease in insulin binding of this receptor form.     

Occurrence of lipid receptors inferred from brain and erythrocyte spectrins binding NaOH-extracted and protease-treated neuronal and erythrocyte membranes

It was previously shown in model systems that brain spectrin binds membrane phospholipids. In the present study, we analysed binding of isolated brain spectrin and red blood cell spectrin to red blood or neuronal membranes which had been treated as follows: (1). extracted with low ionic-strength solution, (2). the above membranes extracted with 0.1 M NaOH, and (3). membranes treated as above, followed by protease treatment and re-extraction with 0.1 M NaOH. It was found that isolated, NaOH-extracted, protease-treated neuronal and red blood cell membranes bind brain and red blood cell spectrin with moderate affinities similar to those obtained in model phospholipid membrane-spectrin interaction experiments. Moreover, this binding was competitively inhibited by liposomes prepared from membrane lipids. The presented results indicate the occurrence of receptor sites for spectrins that are extraction- and protease-resistant, therefore most probably of lipidic nature, in native membranes.     

Comparative study of binding of Scorpaena porcus scorpion fish insulin and pig insulin by specific muscle plasma membrane receptors

Insulin from the scorpion-fish and porcine insulin have been compared with respect to their capacity to interact with the specific receptors in plasma membrane of skeletal muscle fibers of rats. Both insulins inhibited membrane binding of insulin-125J; the dose of porcine insulin which inhibited binding by 50% was equal to 3.7 nM, that of fish insulin -- to 100 nM. These figures indicated lower affinity of fish insulin to mammalian receptors (4% of the porcine affinity), being in accordance with lower biological activity of fish insulin in diaphragmal test. Other peculiarity of fish insulin was revealed in studies on dissociation of insulin-125J, which was previously bound to isolated diaphragm muscle of the rat. In contrast to mammalian insulin, it was not capable of increasing the dissociation when being added to a solution in doses from 7.10(-11) to 7.10(-9) M. This fact is analysed in term of the "site--site" interactions concept.     

Impaired binding of low density lipoprotein to hepatic membranes from uremic guinea pigs.

Chronic renal failure is associated with abnormalities in lipoprotein metabolism that may contribute to premature atherosclerosis and early mortality in patients on dialysis. In previous studies, we found that plasma clearance of radiolabelled low density lipoprotein (LDL) was retarded in nephrectomized guinea pigs left with one-sixth of normal functioning renal mass. To elucidate potential mechanisms of delayed LDL clearance, we compared binding of LDL to hepatic membranes from both normal and uremic guinea pigs. One hundred micrograms of the 8000-100,000 X g hepatic microsomal protein was incubated with 125I-labelled normal guinea pig LDL (10-150 micrograms/mL) for 1 h at 37 degrees C, and the membrane washed and pelleted by centrifugation in a Beckman Ti 42.2 rotor. Parallel incubations with excess unlabelled LDL were done to determine specific binding. LDL specific binding to uremic hepatic membranes was significantly impaired compared with normal ones. The major abnormality, as determined by Scatchard transformation of the binding data, was a reduction of the apparent maximal binding of LDL to uremic membranes, with an average Bmax of 4.1 micrograms/mg protein compared with 6.6 micrograms/mg protein for normal hepatic microsomes. The affinity of LDL for uremic liver membranes was only slightly diminished with a mean apparent Kd of 35.2 micrograms/mL in comparison with 21.8 micrograms/mL for normal liver membranes. These results provide a biochemical explanation for the diminished LDL clearance in uremia and may account for the dyslipidemia of renal failure.     

The effect of adlay oil on plasma lipids, insulin and leptin in rat.

This study was designed to investigate the effect of dietary adlay oil on plasma lipids, insulin and lipid peroxidation levels in rats. Twenty-four male Wistar rats fed diet containing adlay oil and cholesterol were studied for 4 weeks. The animals were divided into three groups: (1) 10% lard (control) group; (2) 5% lard + 5% adlay oil (5% adlay oil) group; and (3) 10% adlay oil group. Although there was no significant difference in body weight at the end of the feeding study, rats fed a diet containing adlay oil showed a significant decrease in adipose tissue weight and relative adipose weight. In addition, the rats fed the adlay oil showed significantly decreased low-density lipoprotein cholesterol (LDL-C), insulin, leptin and thiobarbituric acid reactive substance (TBARS) concentrations after 4 weeks of the feeding study. Although a significant decrease in total plasma cholesterol was observed in rats fed the 5% adlay oil diet, no significant difference was observed between the 10% adlay oil and control groups, and neither was a significant difference in liver TBARS concentration found between the dietary groups. Results from this study suggest that dietary adlay oil can reduce leptin, adipose tissue and LDL-C levels in rats.