The insulin receptor possesses an insulin-stimulated tyrosine-kinase activity; however, the significance of receptor phosphorylation in terms of the binding and signaling function of the receptor is unclear. To help clarify this problem, we have studied insulin binding and receptor phosphorylation in a Cloudman S91 melanoma cell line and two of its variants: the wild type (1A) in which insulin inhibits cell growth, an insulin-resistant variant (111) in which insulin neither stimulates or inhibits growth, and a variant (46) in which insulin stimulates cell growth. 125I-insulin binding to intact cells was similar for the wild-type 1A and insulin-stimulated variant 46. The insulin-resistant variant 111, in contrast, showed approximately 30% decrease in insulin binding. This was due to a decrease of receptor affinity with no major difference in receptor number. When the melanoma cells were solubilized in 1% Triton X-100 and the insulin receptor was partially purified by chromatography on wheat germ agglutinin-agarose, a similar pattern of binding was observed. Phosphorylation was studied by incubation of the partially purified receptor with insulin and [gamma-32P]ATP, and the receptor was identified by immunoprecipitation and NaDodSO4 PAGE. Insulin stimulated phosphorylation of the 95,000-mol-wt beta-subunit of the receptor in all three cells types with similar kinetics. The amount of 32P incorporated into the beta-subunit in the insulin-resistant cell line 111 was approximately 50% of that observed with the two other cell lines. This difference was reflected throughout the entire dose-response curve (10(-9) M to 10(-6) M). Qualitatively similar results were obtained when phosphorylation was studied in the intact cell. Peptide mapping of the beta-subunit using tryptic digestion and reverse-phase high-performance liquid chromatography column separation indicated three sites of phosphorylation in receptor from the wild type and variant 46, but only two major sites of phosphorylation of variant 111. These data suggest that the insulin-resistant variant melanoma 111 possesses a specific defect in the insulin receptor which alters both its binding and autophosphorylation properties, and also suggests a possible role of receptor phosphorylation in both the binding and the signaling function of the insulin receptor.

Insulin binding and processing was studied in monolayer cultures of bovine aortic endothelial cells. Specific 125I-insulin binding was both time and temperature dependent. Maximum binding at 37 degrees C occurred at 90 min, and was 3.8%/mg protein and, at 15 degrees C, 7%/mg protein at 4 h. 125I-insulin was crosslinked to its receptor using disuccinimidyl suberate (DSS), and the structure of the receptor complex was identified by SDS-polyacrylamide gel electrophoresis and autoradiography; a major band with Mr = 145,000 was identified, which corresponds to the alpha-subunit of the insulin receptor reported in other tissues. Receptor-bound insulin was internalized, and both the rate and the amount of internalization were temperature dependent. The rate of internalization was slowest at 4 degrees C, and fastest at 37 degrees C, and the maximum amount of 125I-insulin internalized in 120 min was 16% at 4 degrees C, 45% at 15 degrees C, and 81% at 37 degrees C. Despite the high rate of internalization, endothelial cells do not appear to degrade insulin significantly, as determined by gel chromatography and TCA solubility (7% at 4 h) of media-associated radioactivity. In addition, the majority of internalized insulin (75%) was released by 60 min, largely as intact insulin. Chloroquine treatment at high concentration did not exert any major effect on insulin binding or degradation within the first 60 min, but thereafter produced a marked increase in cell-associated radioactivity.(ABSTRACT TRUNCATED AT 250 WORDS)

To examine the role of heritable factors in insulin-dependent diabetes mellitus (IDDM), we studied the incidence of IDDM in the offspring of patients with the disease who were identified by the medical records of the Joslin Diabetes Center from 1928 to 1939. We found 187 survivors who, after the diagnosis of IDDM, had produced 419 offspring for whom information about diabetes status was available. By the age of 20, 6.1 per cent of the offspring of the 88 men had diabetes; in contrast, only 1.3 per cent of the offspring of the 99 women had the disease by the age of 20 (P less than 0.05). Daughters and sons of the men with IDDM were affected equally (there were insufficient numbers of affected offspring of diabetic women to permit determination of whether the sexes were equally affected). We conclude that IDDM is transmitted less frequently to the offspring of diabetic women than to those of diabetic men. More study is required to determine whether this difference reflects a genetic mechanism or, instead, selective perinatal loss of the affected offspring of diabetic mothers.

We have studied the reversibility of insulin receptor phosphorylation to establish the relation between this autophosphorylation reaction and the initiation of insulin action and between dephosphorylation and the termination of insulin effects in cells. In cultured Fao hepatoma cells labeled with 32PO4(3-), insulin increased 5-fold the phosphorylation of the beta-subunit of the insulin receptor at serine, threonine, and tyrosine residues. Addition of anti-insulin antiserum to cells incubated with insulin caused dissociation of insulin from the receptor and concurrent dephosphorylation of the beta-subunit. 32PO4(3-) associated with the insulin-stimulated receptor could be decreased by the addition of sodium phosphate to the medium but with a slower time course. Insulin stimulated phosphorylation of insulin receptor purified partially on immobilized wheat germ agglutinin. This reaction utilized [gamma-32P] ATP and occurred exclusively on tyrosine residues. Addition of unlabeled ATP caused a decrease in the amount of PO4(3-) associated with the receptor. Insulin-stimulated phosphorylation was also observed if the receptors were further purified by immunoprecipitation with anti-insulin receptor antibody prior to the phosphorylation reaction; however, addition of unlabeled ATP to this system did not chase the labeled 32PO4(3-) from the beta-subunit. These data are consistent with the notion that phosphorylation and dephosphorylation of the insulin receptor parallel the onset and termination of insulin action. Phosphatase activity involved in the dephosphorylation of the insulin receptor appears to be a glycoprotein because it was retained after partial purification of the receptor on wheat germ agglutinin-agarose; however, this phosphatase activity is distinct from the insulin receptor because it was not retained after immunoprecipitation of the receptor with anti-insulin receptor antibodies.

Antibodies to the insulin receptor have provided important experimental probes of receptor structure and function. In the present study, we have characterized the insulin receptor on human lymphoblastoid cell lines using polyclonal and monoclonal anti-receptor antibodies and fluorescence flow cytometry. The cell lines were derived by Epstein-Barr virus transformation of peripheral mononuclear leucocytes from normal subjects or patients with disorders that affect the insulin receptor. Fluorescence analysis revealed a high level of specific fluorescence on lymphoid cell lines from normal individuals (mean peak fluorescence 30-50 units above the control) and was similar to the labelling of the spontaneously transformed lymphoblastoid cell line IM-9. Transformed cells from patients with syndromes of insulin resistance, such as the Rabson Mendenhall syndrome, leprechaunism and the type A syndrome of insulin resistance and acanthosis nigricans, exhibited little or no specific fluorescence. In all cases, there was an unimodal distribution of receptors on cells. In addition, there was a good correlation between specific binding of 125I-insulin and percentage peak fluorescence. The data indicate that fluorescence flow cytometry can be used to study the distribution of insulin receptor on different cell lines and to study cells derived from patients with disease states.

We have studied the effects of chronic exposure to insulin on the binding and the biologic activity of the hormone using a well-differentiated cell line (Fao) derived from the Reuber H35 rat hepatoma. Prolonged incubation (24 h) with 10(-6) M insulin produced a 20-25% decrease in binding of tracer concentrations (2 X 10(-11) M) of 125I-insulin, and a leftward shift of the curve for inhibition by unlabeled insulin. Scatchard analysis of the binding data revealed that a 75-80% decrease in the number of binding sites had occurred in the insulin-treated cells, but was accompanied by an increase in apparent receptor affinity. Kinetic studies suggested negative cooperativity in insulin binding and indicated that the change in affinity was accounted for by a decrease in the rate of dissociation. Both the decrease in receptor number and the increase in affinity were dependent on time, temperature, and the insulin concentration during the treatment period. Both effects were also blocked by cycloheximide, suggesting that they required new protein synthesis. Plasma membranes isolated from downregulated cells retained both the change in receptor number and affinity. Anti-receptor antibodies present in two human sera (B-2 and B-9) inhibited 125I-insulin binding in downregulated cells with equal or slightly greater sensitivity than in control cells. The changes in insulin binding were accompanied by changes in insulin's biologic effects in these cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Imaging and quantitative analysis of insulin-receptor interaction was studied in vivo in lean and obese Zucker rats, using a recently developed technique in which purified Tyr A14 123I-monoiodoinsulin is intravenously injected and the tracer followed by scintillation scanning. The obese rats were 72% overweight, had near normal blood glucose concentrations and an 11-fold increase in plasma insulin concentration. In both groups of rats, the tracer was rapidly taken up by the liver (by a receptor mediated mechanism) and the kidneys (by a non-receptor mediated process). Past this maximum, radioactivity decreased in both organs as 123I-insulin was degraded and free 123I-iodide was released into the plasma compartment. Heart radioactivity (i.e. blood pool) mirrored that of the liver and kidneys. The rapid initial decrease of blood radioactivity was concomitant with liver and kidney uptake of 123I-insulin. Release of free iodide from these organs induced a slow secondary rise of blood radioactivity followed by a final decline corresponding to clearance of plasma iodide, mainly by urinary excretion. Liver radioactivity profiles of lean and obese rats were parallel. When expressed per g weight, liver radioactivity was significantly decreased in obese rats. However, due to hepatomegaly in obese rats, total liver radioactivity was significantly higher in homozygous fa/fa rats than in lean littermates. Furthermore, if the marked hyperinsulinaemia of the obese rats is taken into account, total bound insulin was enhanced in the liver of fa/fa rats whatever reference is used, either g weight or total liver.(ABSTRACT TRUNCATED AT 250 WORDS)

Autophosphorylation of the insulin receptor was studied using a glycoprotein fraction solubilized and purified partially from the rat hepatoma cell line, Fao. Incubation of this receptor preparation with [gamma-32P] ATP, Mn2+, and insulin yielded a single insulin-stimulated phosphoprotein of Mr = 95,000 which corresponds to the beta-subunit of the insulin receptor. At 22 degrees C, incorporation of 32P was half-maximal at 30 s and about 90% complete after 2 min. At steady state, about 200 pmol of 32P were incorporated per mg of protein; this value corresponded to about 2 molecules of phosphate per insulin binding site estimated from Scatchard plots. Insulin increased the Vmax for autophosphorylation of the insulin receptor kinase nearly 20-fold with no effect on the Km for ATP. Mn2+ stimulated autophosphorylation by decreasing the Km of the kinase for ATP, whereas Mg2+ had no effect. Dilution of the insulin receptor over a 10-fold concentration range did not decrease the rate of autophosphorylation suggesting that it may occur by an intramolecular mechanism. When the phosphorylated beta-subunit of the insulin receptor was digested with trypsin, at least 5 phosphopeptides could be separated by high performance liquid chromatography on a mu Bondapak C18 reverse-phase column. Insulin stimulated the phosphorylation of all sites. These phosphate acceptor sites varied in their rate and degree of phosphorylation. Phosphopeptides pp4 and pp5 were phosphorylated very rapidly and reached steady state within 20 s, whereas phosphorylation of pp1 and pp2 required several minutes to reach steady state.

Both the insulin receptor and the gene product of the Rous sarcoma virus, pp60src, are protein kinases which phosphorylate themselves and other proteins on tyrosine residues. Addition of the solubilized insulin receptor to purified pp60src increased the phosphorylation of the beta-subunit of the insulin receptor. Phosphorylation of the insulin receptor by pp60src occurred both in the absence and presence of insulin but did not alter the insulin dose response for autophosphorylation of the receptor. Increasing concentrations of pp60src increased the phosphorylation of the receptor and at high concentrations equaled the maximal effect produced by insulin. Our observations suggest a possible mechanism by which the metabolically regulated insulin receptor tyrosine kinase could be altered by other tyrosine kinases such as that associated with pp60src. Further studies will be required to determine if the insulin receptor is phosphorylated by pp60src in Rous sarcoma virus-infected cells.