Insulin Receptor Binding Research Articles

In vivo insulin signaling through PI3-kinase is impaired in skeletal muscle of adult rat offspring exposed to ethanol in utero

It is now known that prenatal ethanol (EtOH) exposure is associated with impaired glucose tolerance and insulin resistance in rat offspring, but the underlying mechanism(s) is not known. To test the hypothesis that in vivo insulin signaling through phosphatidylinositol 3 (PI3)-kinase is reduced in skeletal muscle of adult rat offspring exposed to EtOH in utero, we gave insulin intravenously to these rats and probed steps in the PI3-kinase insulin signaling pathway. After insulin treatment, EtOH-exposed rats had decreased tyrosine phosphorylation of the insulin receptor beta-subunit and of insulin receptor substrate-1 (IRS-1), as well as reduced IRS-1-associated PI3-kinase in the gastrocnemius muscle compared with control rats. There was no significant difference in basal or insulin-stimulated Akt activity between EtOH-exposed rats and controls. Insulin-stimulated PKC isoform zeta phosphorylation and membrane association were reduced in EtOH-exposed rats compared with controls. Muscle insulin binding and peptide contents of insulin receptor, IRS-1, p85 subunit of PI3-kinase, Akt/PKB, and atypical PKC isoform zeta were not different between EtOH-exposed rats and controls. Thus insulin resistance in rat offspring exposed to EtOH in utero may be explained, at least in part, by impaired insulin signaling through the PI3-kinase pathway in skeletal muscle.

Gender-dependent effect of ageing on peripheral insulin action

The aim of the present study was to investigate the effect of both gender and age on insulin secretion, peripheral insulin effectiveness and insulin-receptor binding. Eighty healthy volunteers, 40 females of mean age 38.47 +/- 11.37 years and mean BMI 21.99 +/- 2.06 kg/m(2) and 40 males of mean age 34.87 +/- 11.22 years and mean BMI 22.65 +/- 2.31 kg/m(2), with normal glucose tolerance participated in the study. Peripheral insulin effectiveness was measured by the artificial endocrine pancreas, using the euglycaemic hyperinsulinaemic clamp technique and insulin-receptor binding on circulating mononuclear blood cells. Peripheral insulin sensitivity was significantly higher in females as compared to males (p < 0.001), while males demonstrated higher total number of insulin receptors (p < 0.0001) and number of high-affinity receptors (p < 0.01). Peripheral insulin sensitivity decreased with ageing in both males and females, the reduction in females being more pronounced (p < 0.05). In the group under 40 years, the females demonstrated significantly higher insulin sensitivity as compared to males (p < 0.001) and lower insulin-receptor binding. Over 40 years, females presented higher peripheral insulin sensitivity and higher insulin-receptor binding. The percentage of specifically bound insulin increased significantly with ageing in females and decreased in males. We consider that probably the higher androgen level in males affects the post-receptor processes in insulin action and despite the higher insulin-receptor binding, males have lower insulin sensitivity. The androgen levels in females increase with ageing, which could probably affect peripheral insulin sensitivity at the post-receptor level. In conclusion, our results demonstrate that when analysing peripheral insulin effectiveness and insulin-receptor binding, one should always consider both gender and age.

Structural, metabolic and endocrine analysis of the diabetes (db/db) hypogonadal syndrome: relationship to hypophyseal hypercytolipidemia

Expression of the diabetes (db/db) mutation in C57BL/KsJ mice results in functional suppression of the female pituitary-gonadal axis accompanied by premature utero-ovarian cytolipoatrophy. Cellular gluco- and lipo-metabolic disturbances promoted by the db/db systemic hyperglycemic-hyperinsulinemic state suppress pituitary gonadotropin release in response to gonadotropin-releasing hormone and gonadal steroid stimulation and results in a hypogonadal-infertility syndrome. Adult female C57BL/KsJ control (+/+ and +/? genotypes) and db/db littermates were monitored for associations in systemic and cellular alterations in luteinizing hormone (LH), follicle-stimulating hormone (FSH), gonadal steroid (binding) levels, and pituitary glucometabolic indices associated with db/db-enhanced lipid imbibition and cytostructural disruption. Obesity, hyperglycemia, and hyperinsulinemia characterized all db/db mutants relative to controls. Serum and pituitary progesterone and estradiol concentrations were suppressed in db/db mutants, in association with serum LH and FSH levels, but not with pituitary LH and FSH concentrations, which were comparable between groups. Pituitary insulin receptor binding and glucose utilization rates were suppressed in db/db groups relative to +/? indices. Structural and cytochemical analysis of anterior (AP), intermediate (IL), and neuro-(NP) hypophyseal lobes demonstrated prominent hypercytolipidemia in db/db mutants relative to controls. Prominent cytolipidemia was localized within well-granulated basophilic gonadotrophs and within IL and NP pituicytes. Vasolipidemia and interstitial cytoadiposity were prominent throughout all db/db pituitary lobes. Thus, disturbances associated with pituitary hypercytolipidemia are functional components of the expressed diabetes-associated hypogonadal syndrome in db/db mutants. Progressive alterations in hypophyseal cytoarchitecture are correlated with suppression of pituitary metabolic and endocrine indices, alterations that contribute to functional disruption of the pituitary-hypogonadal axis in C57BL/KsJ-db/db mice.

Molecular evidence supporting the portal theory: a causative link between visceral adiposity and hepatic insulin resistance

The mechanism by which increased central adiposity causes hepatic insulin resistance is unclear. The "portal hypothesis" implicates increased lipolytic activity in the visceral fat and therefore increased delivery of free fatty acids (FFA) to the liver, ultimately leading to liver insulin resistance. To test the portal hypothesis at the transcriptional level, we studied expression of several genes involved in glucose and lipid metabolism in the fat-fed dog model with visceral adiposity vs. controls (n = 6). Tissue samples were obtained from dogs after 12 wk of either moderate fat (42% calories from fat; n = 6) or control diet (35% calories from fat). Northern blot analysis revealed an increase in the ratio of visceral to subcutaneous (v/s ratio) mRNA expression of both lipoprotein lipase (LPL) and peroxisome proliferator-activated receptor-gamma (PPARgamma). In addition, the ratio for sterol regulatory element-binding transcription factor-1 (SREBP-1) tended to be higher in fat-fed dogs, suggesting enhanced lipid accumulation in the visceral fat depot. The v/s ratio of hormone-sensitive lipase (HSL) increased significantly, implicating a higher rate of lipolysis in visceral adipose despite hyperinsulinemia in obese dogs. In fat-fed dogs, liver SREBP-1 expression was increased significantly, with a tendency for increased fatty acid-binding protein (FABP) expression. In addition, glucose-6-phosphatase (G-6-Pase) and phosphoenolpyruvate carboxykinase (PEPCK) increased significantly, consistent with enhanced gluconeogenesis. Liver triglyceride content was elevated 45% in fat-fed animals vs. controls. Moreover, insulin receptor binding was 50% lower in fat-fed dogs. Increased gene expression promoting lipid accumulation and lipolysis in visceral fat, as well as elevated rate-limiting gluconeogenic enzyme expression in the liver, is consistent with the portal theory. Further studies will need to be performed to determine whether FFA are involved directly in this pathway and whether other signals (either humoral and/or neural) may contribute to the development of hepatic insulin resistance observed with visceral obesity.

Insulin secretion, peripheral insulin sensitivity and insulin-receptor binding in subjects with different degrees of obesity

The aim of the present study was to investigate insulin secretion, insulin-receptor binding and peripheral insulin sensitivity in subjects with different degrees of obesity. 36 obese subjects with normal glucose tolerance and different degrees of obesity and 40 healthy normal-weight subjects participated in the study. Peripheral insulin sensitivity was measured by using the euglycaemic hyperinsulinaemic clamp technique, and insulin-receptor binding-on circulating mononuclear blood cells. Insulin secretion was studied during intravenous tolbutamide test. The subjects with I degree of obesity demonstrated a significant decrease in the number of total (p<0.0001) and high-affinity (p<0.01) insulin receptors per cell, as well as significantly higher insulin receptor affinity (p<0.01) as compared to the normal-weight subjects. The subjects with II degree of obesity also demonstrated a significant decrease in the number of total (p<0.0001) and high-affinity receptors (p<0.001) per cell as well as an increase (p<0.001) in insulin-receptor affinity as compared to the controls. The significantly decreased receptor number in the subjects with I and II degree of obesity was accompanied by an increase in insulin receptor affinity; thus their insulin-receptor binding being maintained similar to the controls. The subjects with III degree obesity presented a significant decrease (p<0.0001) in the number of both the total and high-affinity insulin receptors as well as a reduction in insulin receptor affinity as compared to the controls. Therefore the percentage of specifically bound insulin was significantly lower (p<0.01) as compared to that of the control group. Insulin resistance in the obese subjects is associated with secondary hyperinsulinaemia, which is present in subjects with I and II degree of obesity; while in severely obese subjects exhaustion of beta-cell secretory capacity is observed. We consider that III degree of obesity appears to be a risk factor for type 2 diabetes mellitus as the alterations in insulin sensitivity, insulin-receptor binding and beta-cell secretion are quite similar to the reported in diabetic patients.

Insulin resistance in thermally-injured rats is associated with post-receptor alterations in skeletal muscle, liver and adipose tissue.

Several of the possible molecular mechanisms that contribute to the insulin resistance associated with burn injury were examined in a rat model of thermal injury. Rats were subjected to full thickness scald injury (25% total body surface area, 10 sec burn) and resuscitated with saline. After 1, 2 and 3 weeks, urinary C-peptide excretion was measured in burned and sham-treated control animals. At 3 weeks after injury, glucose production by the liver and utilization by skeletal muscle was measured under insulin clamp conditions, insulin receptor binding was measured in skeletal muscle, liver and adipose tissue membranes and IRS-1 expression was measured by Western blot methods. Urinary C-peptide excretion was significantly elevated at 1, 2 and 3 weeks after injury. At 3 weeks after injury, several key metabolic processes were blunted, including the ability of insulin infusion to stimulate glucose uptake by skeletal muscle, the potency of insulin infusion for inhibiting hepatic glucose production, and the ability of a bolus injection of insulin to simulate phosphorylation of IRS-1 in liver, skeletal muscle or adipose tissue. In contrast, there were no apparent alterations in the binding of insulin to membranes from liver, skeletal muscle or adipose tissue. These findings support the concept that the burn injury stimulates insulin production 3 weeks after burn injury, and produces insulin resistance in skeletal muscle, adipose tissue and liver by processes that are associated with post-receptor alterations in the absence of changes in insulin receptor binding.

Effect of thyroid hormone binding proteins on insulin receptor binding of B1-thyronine-insulin analogues.

Certain thyronine-insulin analogues, which form non-covalent complexes with plasma proteins, have been shown to act preferentially in the liver. We hypothesized that this property may be dependent on the ability of the analogue to bind to the insulin receptor without prior dissociation from the binding protein. NaB1-L-thyroxyl-insulin, NaB1-3,3',5'-triiodothyronine-insulin, NaB1-D-thyroxyl-insulin and NaB1-L-thyroxyl-aminolauroyl-insulin were compared with insulin for their capacity to inhibit the binding of [125I]TyrA14-insulin to rat liver plasma membrane in albumin-free buffer. Effective doses at 50% maximum inhibition of binding (ED50) were calculated with and without addition of the thyroid hormone binding proteins transthyretin, thyroxine binding globulin and human serum albumin. The binding of thyronine-insulin analogues to insulin receptors was inhibited in a dose-dependent manner by the addition of thyroid hormone binding proteins at concentrations in the physiological range. Complexes of thyronine-insulin analogues with thyroid hormone binding proteins exhibit impaired insulin receptor binding affinities compared with those of the analogues in their free form. Hepatoselectivity in vivo may not depend on binding of the intact complexes to hepatocytes. These results have implications for the physiological role of hormone binding proteins and the in vivo properties of other insulin analogues which bind to plasma proteins.

Interaction of the retinal insulin receptor beta-subunit with the p85 subunit of phosphoinositide 3-kinase.

Recently, we have shown that phosphoinositide 3-kinase (PI3K) in retina is regulated in vivo through light activation of the insulin receptor beta-subunit. In this study, we have cloned the 41 kDa cytoplasmic region of the retinal insulin receptor (IRbeta) and used the two-hybrid assay of protein-protein interaction in the yeast Saccharomyces cerevisiae to demonstrate the interaction between the p85 subunit of PI3K and the cytoplasmic region of IRbeta. Under conditions where IRbeta autophosphorylates, substitution of Y1322F and M1325P in IRbeta resulted in the abolition of p85 binding to the IRbeta, confirming that the p85 subunit of PI3K binds to Y1322. The binding site for p85 on IRbeta was also confirmed in the yeast three-hybrid system. Using the C-terminal region of IRbeta (amino acids 1293-1343 encompassing the YHTM motif) as bait and supplying an exogenous tyrosine kinase gene to yeast cells, we determined that the IRbeta-pYTHM motif interacts with p85. We also used retinal organ cultures to demonstrate insulin activation of the insulin receptor and subsequent binding of p85, measured through GST pull-down assays with p85 fusion proteins. Further, the Y960F mutant insulin receptor, which does not bind IRS-1, is capable of bringing down PI3K activity from retina lysates. On the other hand, in response to insulin, IRS-2 is able to interact with the p85 subunit of PI3K in the retina. These results suggest that multiple signaling pathways could regulate the PI3K activity and subsequent activation of Akt in the retina.

The effect of smoking on peripheral insulin sensitivity and plasma endothelin level

The aim of the present study was to investigate the effect of smoking on peripheral insulin effectiveness. Seven healthy volunteers, nonsmokers, of mean age 39.6 +/- 7.1 Years and mean BMI 22.65 +/- 11.98 kg/m2, without family history of diabetes mellitus, with normal blood pressure participated in the study. All the parameters were studied twice - at baseline as well as after smoking (4 cigarettes per one hour). The study was performed in three days: at the first day we studied peripheral insulin effectiveness (M) in vivo by the artificial endocrine pancreas (Biostator), using the euglycaemic hyperinsulinaemic clamp technique, and insulin-receptor binding on circulating mononuclear blood cells; at the second day - the same parameters after one-hour smoking during the third hour of clamping; at the third day - plasma endothelin level, blood pressure and heart rate at baseline and after one-hour smoking. There was a significant decrease in glucose utilization during the second clamp test, when the volunteers smoked during the third hour as compared to the test at baseline (p=0.04). This was accompanied by a significant decrease in insulin receptor affinity (p=0.04). Systolic blood pressure and heart rate increased significantly after one-hour smoking (p=0.03 and p=0.001, respectively). Plasma endothelin level increased significantly after smoking (from 0.62 +/- 0.15 pg/ml to 2.05 +/- 1.67 pg/ml, p=0.03). Our results demonstrate that smoking decreases peripheral insulin sensitivity reducing insulin receptor affinity. We have confirmed that smoking increases plasma endothelin level, which probably by causing vasoconstriction and consequent tIssue hypoxaemia could decrease peripheral glucose utilization. We consider that smoking could also have a direct effect on insulin receptor affinity, thus leading to decreased peripheral insulin effectiveness.

Insulin receptors and renal sodium handling in hypertensive fructose-fed rats

Insulin resistance and hypertension are present in Sprague-Dawley rats fed a fructose-enriched diet. In these rats, insulin might elevate blood pressure via an antinatriuretic action. To investigate the sodium-insulin interaction in fructose-fed rats, we compared insulin sensitivity, insulin receptor binding, and insulin receptor mRNA levels in the kidney and skeletal muscle of rats that were fed standard rat chow or a fructose-enriched diet (66%) with either low (0.07%), normal (0.3%), or high (7.5%) NaCl concentrations for 3 weeks. Systolic blood pressure increased in the fructose-fed rats receiving the normal and high-salt diet, but not the low-salt diet. When the rats were fed the low-salt diet, the rate of glucose infusion required to maintain euglycemia during a hyperinsulinemic clamp and insulin receptor number and mRNA levels in skeletal muscle were lower in fructose-fed than control rats. High-salt diet decreased significantly the rate of glucose disposal during the clamp and muscular insulin receptor number and mRNA levels in control, but not fructose-fed rats. During the low-salt diet, renal insulin receptor number and mRNA levels were comparable in fructose-fed and control rats and hyperinsulinemia had comparable acute antinatriuretic effects in the two groups; when the rats were maintained on the high-salt diet, the expected decrease in renal insulin receptor number and mRNA levels occurred in control but not fructose-fed rats and, consistent with this finding, the antinatriuretic response to hyperinsulinemia was blunted only in controls. An inverse relationship between dietary NaCl content and renal insulin receptor mRNA levels was observed in control but not fructose-fed rats. Fructose-fed rats appear to have lost the feedback mechanism that limits insulin-induced sodium retention through a down-regulation of the renal insulin receptor when the dietary NaCl content is increased. This abnormality might possibly contribute to the elevation of blood pressure in these rats.

Cellular mechanisms of insulin resistance in rats with Fructose-Induced hypertension

Background Feeding a high-fructose diet induces hypertension and insulin-resistance in Sprague-Dawley rats. Methods To investigate whether insulin receptors contribute to abnormal glucose metabolism and whether their regulation is differentially regulated in different tissues, we evaluated the glycemic and insulinemic response to an oral glucose load, insulin receptor binding, and insulin receptor messengerRNA (mRNA) levels in tissues of rats that were fed either standard rat chow or a diet containing 66% fructose for 2 weeks. Results Blood pressure and plasma triglycerides increased significantly in the fructose-fed rats, whereas body weight, fasting plasma glucose, and plasma insulin did not differ significantly from controls. Plasma glucose and insulin responses to oral glucose were significantly greater in fructose-fed than in control rats. Insulin receptor-binding characteristics were determined by an in situ autoradiographic technique associated with computerized microdensitometry. The insulin receptor number was significantly lower in both skeletal muscle and liver of fructose-fed rats as compared to controls, whereas no difference was observed in the kidney. No significant differences were found in binding affinity. Insulin receptor mRNA levels were determined by slot-blot hybridization with a cRNA probe encoding the 5′ end of the rat insulin receptor cDNA. Consistent with binding data, mRNA levels were significantly lower in skeletal muscle and liver of fructose-fed rats as compared to controls, but not in the kidney. Conclusions Decreased number of insulin receptors occurring at the level of gene expression is present in skeletal muscle and liver of fructose-fed rats and might contribute to insulin resistance in this model.

Hydrogen peroxide inhibits insulin signaling in vascular smooth muscle cells.

Both insulin resistance and reactive oxygen species (ROS) have been reported to play essential pathophysiological roles in cardiovascular diseases, such as hypertension and atherosclerosis. However, the mechanistic link between ROS, such as H2O2 and insulin resistance in the vasculature, remains undetermined. Akt, a Ser/Thr kinase, mediates various biological responses induced by insulin. In this study, we examined the effects of H2O2 on Akt activation in the insulin-signaling pathway in vascular smooth muscle cells (VSMCs). In VSMCs, insulin stimulates Akt phosphorylation at Ser473. Pretreatment with H2O2 concentration- and time-dependently inhibited insulin-induced Akt phosphorylation with significant inhibition observed at 50 microM for 10 min. A ROS inducer, diamide, also inhibited insulin-induced Akt phosphorylation. In addition, H2O2 inhibited insulin receptor binding partially and inhibited insulin receptor autophosphorylation almost completely. However, pretreatment with a protein kinase C inhibitor, GF109203X (2 microM), for 30 min did not block the inhibitory effects of H2O2 on insulin-induced Akt phosphorylation, suggesting that protein kinase C is not involved in the inhibition by H2O2. We conclude that ROS inhibit a critical insulin signal transduction component required for Akt activation in VSMCs, suggesting potential cellular mechanisms of insulin resistance, which would require verification in vivo.

Circulating heavy chain IgG, a pathological mediator for coronary artery disease, recognizes platelet surface receptors of both prostacyclin and insulin

Although an increased incidence of premature cardiovascular disease has been determined to be the major cause of mortality in subjects with chronic spinal cord injury the identity of the pathophysiological mediators of cardiovascular disease in spinal cord injury remains obscure. Because both insulin and prostacyclin could be important in the prevention of thrombosis, the status of insulin-induced nitric oxide production and the prostacyclin high-affinity receptor interaction in platelets in subjects with spinal cord injury was studied. It was established that the insulin-induced nitric oxide synthesis in platelets from spinal cord-injured subjects was markedly impaired (0.053-0.058, P=0.37-0.44) compared to (0.062-0.53 μM/108 platelets, P<0.001) due to the presence of a free heavy chain IgG (Mr 47 kDa) in the circulation of subjects with spinal cord injury. This IgG not only blocked insulin receptor binding sites (without affecting dissociation constant of the hormone binding, Kd1= 2 × 10−9 M) for the synthesis of nitric oxide but also blocked the prostacyclin receptor interaction in normal platelets. Since the presence of circulating heavy chain of IgG could block the antithrombotic effect of both insulin and prostacyclin, the free heavy chain of the IgG molecule was thought to be one of the pathological mediators for the increased incidence of cardiovascular disease in individuals with spinal cord injury. The cross-reactivity of the free heavy chain with two different receptors antigens was thought to be related to the presence of several regions of homology in the amino acid sequence in the insulin and prostacyclin receptor molecules.

A mathematical model of metabolic insulin signaling pathways.

We develop a mathematical model that explicitly represents many of the known signaling components mediating translocation of the insulin-responsive glucose transporter GLUT4 to gain insight into the complexities of metabolic insulin signaling pathways. A novel mechanistic model of postreceptor events including phosphorylation of insulin receptor substrate-1, activation of phosphatidylinositol 3-kinase, and subsequent activation of downstream kinases Akt and protein kinase C-zeta is coupled with previously validated subsystem models of insulin receptor binding, receptor recycling, and GLUT4 translocation. A system of differential equations is defined by the structure of the model. Rate constants and model parameters are constrained by published experimental data. Model simulations of insulin dose-response experiments agree with published experimental data and also generate expected qualitative behaviors such as sequential signal amplification and increased sensitivity of downstream components. We examined the consequences of incorporating feedback pathways as well as representing pathological conditions, such as increased levels of protein tyrosine phosphatases, to illustrate the utility of our model for exploring molecular mechanisms. We conclude that mathematical modeling of signal transduction pathways is a useful approach for gaining insight into the complexities of metabolic insulin signaling.

Leptin secretion and negative autocrine crosstalk with insulin in brown adipocytes.

Leptin is an important adipocytokine whose main regulative effects on energy metabolism are exerted via activation of signalling pathways in the central nervous system. Another important regulator of energy homeostasis is insulin. The role of direct autocrine leptin effects on adipose tissue and crosstalk with insulin, in particular in the thermogenically active brown adipose tissue, remains unclear. In the present study, we have investigated leptin secretion and interaction with insulin in highly insulin-responsive immortalised mouse brown adipocytes. Leptin was secreted in a differentiation-dependent manner, and acute leptin treatment of mature adipocytes dose- and time-dependently stimulated phosphorylation of STAT3 and MAP kinase. Interestingly, acute pretreatment of fully differentiated brown adipocytes with leptin (100 nM) significantly diminished insulin-induced glucose uptake by approximately 25%. This inhibitory effect was time-dependent and maximal after 60 min of leptin prestimulation. Furthermore, it correlated with a 35% reduction in insulin-stimulated insulin receptor kinase activity after acute leptin pretreatment. Insulin-induced insulin receptor substrate-1 tyrosine phosphorylation and binding to the regulatory subunit p85 of phosphatidylinositol 3-kinase (PI 3-kinase) were diminished by approximately 60% and 40%, respectively. Taken together, this study has demonstrated strong differentiation-dependent leptin secretion in brown adipocytes and PI 3-kinase-mediated negative autocrine effects of this hormone on insulin action. Direct peripheral leptin-insulin crosstalk may play an important role in the regulation of energy homeostasis.

Effect of disulfide bond on the conformation and anticoagulant activity of an Arg-Gly-Asp motif displayed on a mutant insulin protein framework

Protein engineering techniques were employed to graft the known anticoagulant Arg-Gly-Asp (RGD) motifcontaining sequences onto the surface of a mutant, inactive insulin framework. To probe the effect of a disulfide bond on the resultant anticoagulant activity, a native RGD-containing sequence from disintegrin dendroaspin, CFTPRGDMPGPYC, as well as a modified sequence, SFTPRGDMPGPYS were each examined. The peptide was placed between the C-terminal of the B chain and the N-terminal of the A chain and connected with B27 and A1 residues of the inactive insulin that lacks the characteristic intramolecular A6–11 disulfide bond within the A chain. The two RGD-containing insulin genes were over-expressed inE. coli, and purified and designated as RGD-Cys-Ins and RGD-Ser-Ins, respectively. Their amino acid compositions and mass data were in good agreement with those of expected. The RGD-Cys-Ins showed inhibition of platelet aggregation with an IC50 of 3 μM, while the latter was 3.5-fold less active. Thein vivo assay also indicated that the RGD-Cys-Ins had a higher activity in prolonging the bleeding time in mice than RGD-Ser-Ins. Both RGD-Cys-Ins and RGD-Ser-Ins retained about 25% of the proinsulin immunoactivity and had almost no insulin receptor binding activity. The results indicate the necessity for the RGD motif to be conformationally constrained for it to elicit a greater anticoagulant activity.

Acidic residues on the N-terminus of proinsulin C-Peptide are important for the folding of insulin precursor.

To investigate the role of C-peptide in the folding of insulin precursor, a series of C-peptide mutant proinsulin genes were constructed, overexpressed in Escherichia coli and the proteins purified. Correct disulfide linkages of these proteins were confirmed by both tryptic peptide mapping and insulin receptor binding analyses. In vitro refolding experiments were performed with the purified proteins and showed that mutations on the glycine-rich middle segment of C-peptide, GGGPGAG, and deletion of the C-terminal pentapeptide, EGSLQ, as well as mutations on the two pairs of dibasic residues at the two ends of C-peptide did not significantly affect the refolding yields. However, both alanine replacement mutation and deletion of three highly conserved acidic residues (EAED) at the N-terminus of the C-peptide resulted in serious aggregation during refolding. The results indicate that the highly conserved acidic N-terminal part of C-peptide is very important for insulin precursor folding, and that C-peptide may have some intramolecular chaperone-like function in the folding of insulin precursor.

Interaction of protein tyrosine phosphatase (PTP) 1B with its substrates is influenced by two distinct binding domains.

We have shown previously that protein tyrosine phosphatase (PTP) 1B interacts with insulin receptor and negatively regulates insulin signalling by an N-terminal binding domain [Dadke, Kusari and Chernoff (2000) J. Biol. Chem. 275, 23642-23647] and it also negatively regulates integrin signalling through a proline-rich region present in the C-terminus [Liu, Hill and Chernoff (1996) J. Biol. Chem. 271, 31290-31295; Liu, Sells and Chernoff (1998) Curr. Biol. 8, 173-176]. Here we show that PTP1B mutants that are defective in Src homology 3 domain binding fully retain the ability to inhibit insulin signalling, whereas mutants defective in insulin-receptor binding fully retain the ability to inhibit integrin signalling. In contrast, both the C-terminal proline-rich region and the tandem tyrosine residues present in the N-terminal region are required for the activation of Src family kinases. These data show that PTP1B can independently regulate insulin and integrin signals, and that Src might represent a convergence point for regulating signal transduction by this phosphatase.

Functional Reconstitution of Insulin Receptor Binding Site from Non-binding Receptor Fragments

We have previously shown that a minimized insulin receptor (IR) consisting of the first 468 amino acids of the insulin receptor fused to 16 amino acids from the C terminus of the alpha-subunit (CT domain) bound insulin with nanomolar affinity (Kristensen, C., Wiberg, F. C., Schäffer, L., and Andersen, A. S. (1998) J. Biol. Chem. 273, 17780-17786). In the present study, we show that a smaller construct that has the first 308 residues fused to the CT domain also binds insulin. Insulin receptor fragments consisting of the first 468 or 308 residues did not bind insulin. However, when these fragments were mixed with a synthetic peptide corresponding to the CT domain, insulin binding was detectable. At concentrations of 10 microm CT peptide, insulin binding was fully reconstituted yielding apparent affinities of 9-11 nm. To further investigate the minimum requirement for the length of the N terminus of IR, we tested smaller receptor fragments for insulin binding in the presence of the CT peptide and found that a fragment consisting of the first 255 amino acids of IR was able to fully reconstitute the insulin binding site, yielding an apparent affinity of 11 +/- 4 nm for insulin.

Decreased erythrocyte insulin binding in hypertensive subjects with hyperinsulinemia

Background This study investigates erythrocyte insulin receptor binding and affinity in subjects with hypertension and hyperinsulinemia. Insulin receptor-binding function has not been extensively studied in hypertensive subjects. Methods Insulin receptor density, binding affinity, and protein tyrosine kinase activity were measured in erythrocytes from 18 hypertensive and 16 normotensive subjects. Insulin sensitivity was measured by the fasting plasma insulin/glucose ratio and the homeostatic assessment model algorithm (HOMA) index. Erythrocyte insulin binding was determined by a competitive binding assay and protein tyrosine kinase activity was measured by an enzyme-linked immunoabsorbent assay technique. Results Fasting plasma insulin/glucose ratio and the insulin resistance index (HOMA) were significantly higher in the hypertensive versus normotensive subjects. Receptor saturation of the high affinity binding sites (Bmax) was reduced in the hypertensive versus control subjects. The Kd values were lower in the erythrocytes from hypertensive than control subjects. Insulin-induced protein tyrosine kinase activity was decreased in erythrocytes from hypertensive versus control subjects. Conclusions A reduced erythrocyte insulin receptor density and tyrosine protein kinase activity may reflect insulin receptor dysfunction in hypertensive individuals who have insulin resistance and hyperinsulinemia. More information is needed examining insulin receptor function in other target tissues such as fat or skeletal muscle cells before defects in the insulin receptor can be firmly proposed as a cause of the metabolic syndrome.