Differences in the sites of phosphorylation of the insulin receptor in vivo and in vitro

Cascade of autophosphorylation in the beta-subunit of the insulin receptor

Insulin stimulated autophosphorylation of the beta-subunit of the insulin receptor purified from Fao hepatoma cells or purified from Chinese hamster ovary (CHO/HIRC) or Swiss 3T3 (3T3/HIRC) cells transfected with the wild-type human insulin receptor cDNA. Autophosphorylation of the purified receptor occurred in at least two regions of the beta-subunit: the regulatory region containing Tyr-1146, Tyr-1150, and Tyr-1151, and the C-terminus containing Tyr-1316 and Tyr-1322. In the presence of antiphosphotyrosine antibody (alpha-PY), autophosphorylation of the purified receptor was inhibited nearly 80% during insulin stimulation. Tryptic peptide mapping showed that alpha-PY inhibited autophosphorylation of both tyrosyl residues in the C-terminus and one tyrosyl residue in the regulatory region, either Tyr-1150 or Tyr-1151. Thus, a bis-phosphorylated form of the regulatory region accumulated in the presence of alpha-PY, which contained Tyr(P)-1146 and either Tyr(P)-1150 or 1151. In intact Fao, CHO/HIRC, and 3T3/HIRC cells, insulin stimulated tyrosyl phosphorylation of the beta-subunit of the insulin receptor. Tryptic peptide mapping indicated that the regulatory region of the beta-subunit was mainly (greater than 80%) bis-phosphorylated; however, all three tyrosyl residues of the regulatory region were phosphorylated in about 20% of the receptors. As the phosphotransferase was activated by tris-phosphorylation but not bis-phosphorylation of the regulatory region of the beta-subunit (White et al.: Journal of Biological Chemistry 263:2969-2980, 1988), the extent of autophosphorylation in the regulatory region may play an important regulatory role during signal transmission in the intact cell.

The immunoglobulin class, the subclass and the ratio of kappa:lambda light chain of autoantibodies to human insulin in insulin autoimmune syndrome

The immunoglobulin class, subclass and the k:lambda light chain ratio of insulin autoantibodies were determined in the sera of twenty-four patients with insulin autoimmune syndrome. All sera proved to be of the IgG immunoglobulin class but exhibited various IgG1:IgG2:IgG3:IgG4 ratios. The ratio of k:lambda light chain ranged from 1:0.13 to 1:0.75 with the exceptions of two sera that were characterized as IgG1(k) and IgG1(lambda).

The insulin receptor: structure and function

Promising progress in understanding the molecular basis of insulin action has been achieved by demonstrating that the insulin receptor is an insulin-sensitive tyrosine kinase. Here we discuss the structure of this receptor kinase and compare it with receptors for related growth factors. We review the known modes to regulate the receptor kinase activity, either through its autophosphorylation (on tyrosine residues) or through its phosphorylation by other kinases (on serine and threonine residues). We discuss the role of the receptor kinase activity in hormone signal transduction in light of results indicating a reduced kinase activity in insulin-resistant states. Finally, studies to identify natural substrates for the insulin receptor kinase are presented. The possible physiological role of these phosphorylated substrates in mediating insulin action is evaluated.

Cellular mechanisms of insulin resistance in non-insulin-dependent (type II) diabetes

Recent studies have led to an enhanced understanding of cellular alterations that may play an important role in the pathophysiology of non-insulin-dependent diabetes mellitus (NIDDM). The insulin receptor links insulin binding at the cell surface to intracellular activation of insulin's effects. This transducer function involves the tyrosine kinase property of the beta-subunit of the receptor. It was found that adipocytes from subjects with NIDDM had a 50 to 80 percent reduction in insulin-stimulated receptor kinase activity compared with their non-diabetic counterparts. This defect was relatively specific for the diabetic state since no decrease was observed in insulin-resistant non-diabetic obese subjects. The reduction in kinase activity was accounted for by changes in the ratio of two pools of receptors, both of which bind insulin but only one of which is capable of tyrosine autophosphorylation and subsequent kinase activation; 43 percent of the receptors from non-diabetic subjects were capable of autophosphorylation compared with only 14 percent in the NIDDM group. A major component of cellular insulin resistance in NIDDM involves the glucose transport system. Exposure of cells to insulin normally results in enhanced glucose transport mediated by translocation of glucose transporters from a low-density microsomal intracellular pool to the plasma membrane. It was found that cells from NIDDM subjects had a marked depletion of glucose transporters in both plasma membranes and low-density microsomes, relative to obese non-diabetic control participants. Obese non-diabetic persons had a normal number of plasma membrane transporters but a reduced number of low-density microsome transporters in the basal state compared with lean control volunteers; insulin induced the translocation of relatively fewer transporters from the low-density microsome to the plasma membrane in the obese subgroups. In addition to the diminished number of glucose transporters, cells from both NIDDM and obese subjects had impaired functional activity of glucose carriers since decreased whole-cell glucose transport rates could not be entirely explained by the magnitude of the decrement in the number of plasma membrane transporters. Thus, impaired glucose transport is due to both a numerical and functional defect in glucose transporters. The cellular content of high-density microsomal transporters was the same in lean and obese control volunteers and NIDDM subjects, suggesting that transporter synthesis is normal and that cellular depletion results from increased protein turnover once transporters leave the high-density microsomal subfraction.(ABSTRACT TRUNCATED AT 400 WORDS)

Mutation of the insulin receptor at tyrosine 960 inhibits signal transmission but does not affect its tyrosine kinase activity

Tyrosyl phosphorylation is implicated in the mechanism of insulin action. Mutation of the beta-subunit of the insulin receptor by substitution of tyrosyl residue 960 with phenylalanine had no effect on insulin-stimulated autophosphorylation or phosphotransferase activity of the purified receptor. However, unlike the normal receptor, this mutant was not biologically active in Chinese hamster ovary cells. Furthermore, insulin-stimulated tyrosyl phosphorylation of at least one endogenous substrate (pp185) was increased significantly in cells expressing the normal receptor but was barely detected in cells expressing the mutant. Therefore, beta-subunit autophosphorylation was not sufficient for the insulin response, and a region of the insulin receptor around Tyr-960 may facilitate phosphorylation of cellular substrates required for transmission of the insulin signal.

Phosphorylation of hepatic insulin receptor by casein kinase 2

Casein kinase 2 was able to phosphorylate the beta-subunit of hepatic insulin receptor in the presence of either ATP or GTP. Phosphorylation by casein kinase 2 was observed even in the absence of insulin, was inhibited by low heparin concentrations, and led to the incorporation of phosphate on serine and threonine residues. Casein kinase 2 phosphorylation of insulin receptor partially decreased its tyrosine kinase activity.

Phosphorylation of insulin-like growth factor I receptor by insulin receptor tyrosine kinase in intact cultured skeletal muscle cells

The interaction between insulin and insulin-like growth factor I (IGF I) receptors was examined by determining the ability of each receptor type to phosphorylate tyrosine residues on the other receptor in intact L6 skeletal muscle cells. This was made possible through a sequential immunoprecipitation method with two different antibodies that effectively separated the phosphorylated insulin and IGF I receptors. After incubation of intact L6 cells with various concentrations of insulin or IGF I in the presence of [32P]orthophosphate, insulin receptors were precipitated with one of two human polyclonal anti-insulin receptor antibodies (B2 or B9). Phosphorylated IGF I receptors remained in solution and were subsequently precipitated by anti-phosphotyrosine antibodies. The identities of the insulin and IGF I receptor beta-subunits in the two immunoprecipitates were confirmed by binding affinity, by phosphopeptide mapping after trypsin digestion, and by the distinct patterns of expression of the two receptors during differentiation. Stimulated phosphorylation of the beta-subunit of the insulin receptor correlated with occupancy of the beta-subunit of the insulin receptor by either insulin or IGF I as determined by affinity cross-linking. Similarly, stimulation of phosphorylation of the beta-subunit of the IGF I receptor by IGF I correlated with IGF I receptor occupancy. In contrast, insulin stimulated phosphorylation of the beta-subunit of the IGF I receptor at hormone concentrations that were associated with significant occupancy of the insulin receptor but negligible IGF I receptor occupancy. These findings indicate that the IGF I receptor can be a substrate for the hormone-activated insulin receptor tyrosine kinase activity in intact L6 skeletal muscle cells.

Insulin resistance in uremia: insulin receptor kinase activity in liver and muscle from chronic uremic rats

We have studied the structure and function of the partially purified insulin receptors from liver and skeletal muscle in a rat model of severe chronic uremia. 125I-insulin binding was higher in the liver from uremic rats when compared with ad libitum- and pair-fed controls. Furthermore, the ability of insulin to stimulate the autophosphorylation of the beta-subunit and insulin receptor kinase activity using Glu80, Tyr20 as exogenous phosphoacceptor was increased in the liver of the uremic animals. The structural characteristic of the receptors, as determined by electrophoretic mobilities of affinity labeled alpha-subunit and the phosphorylated beta-subunit, were normal in uremia. 125I-insulin binding and insulin receptor kinase activity were similar in the skeletal muscle from uremic and pair- and ad libitum-fed animals. Thus our data are supportive of the hypothesis that in liver and muscle of chronic uremic rats, insulin resistance is due to a defect(s) distal to the insulin receptor kinase.

Purification and characterization of a 22-kDa microsomal protein from rat parotid gland which is phosphorylated following stimulation by agonists involving cAMP as second messenger

Stimulation of secretion in exocrine glands by agonists involving cAMP as second messenger leads to the phosphorylation of the ribosomal protein S6 (protein I) and two other particulate proteins with apparent molecular masses of 24 kDa (protein II) and 22 kDa (protein III) [Jahn, R., Unger, C. & Söling, H. D. (1980) Eur. J. Biochem. 112, 345-352]. This report describes the purification and characterization of protein III. Solubilization studies indicate that protein III is an intrinsic membrane protein. It could be extracted from the endoplasmic reticulum membrane only with Triton X-100, SDS or concentrated formic or acetic acid. The purification of this protein involved extraction of the microsomes with Triton X-100, removal of the detergent by acetone precipitation, extraction of water-soluble proteins, lipids and lipoproteins, and preparative SDS polyacrylamide gel electrophoresis. The protein has a basic pI (greater than 8.7). For determination of the amino acid composition of protein III and for sequencing of its amino-terminal portion, the protein was electroeluted out off the gel, the detergent removed and the protein finally purified by reversed-phase HPLC. Protein III could be phosphorylated in vitro by the catalytic subunit of the cAMP-dependent protein kinase to a degree of approximately 0.14 mol phosphate/mol protein. The only phosphopeptide obtained after in vitro phosphorylation and subsequent tryptic or chymotryptic digestion was identical with the phosphopeptide obtained after stimulation of intact rat parotid gland lobules with isoproterenol. The sequence of this peptide was Lys-Leu-Ser(P)-Glu-Ala-Asp-Asn-Arg. It was confirmed by an analysis of the synthetic peptide following in vitro phosphorylation with cAMP-dependent protein kinase. The first 41 N-terminal residues of protein III were sequenced. So far no sequence homology with other known peptides or proteins could be found.

Involvement of a 65 kDa phosphoprotein in the regulation of membrane fusion during exocytosis in Paramecium cells

Antisera were raised against a phosphoprotein of 65 kDa (PP65) from Paramecium cells (shown before to be selectively dephosphorylated during synchronous exocytosis) and specified by immunoblotting. By immunofluorescence PP65 has been localized within the cortex, beneath the cell membrane. This corresponds to data obtained by cell fractionation, applying SDS-PAGE autoradiography to cortices prepared from 32P-prelabeled cells. Antisera against PP65 inhibit exocytosis in vivo (microinjection). Applying anti-PP65 antisera in vitro to cortices we could demonstrate inhibition not only of exocytosis, but also of PP65 dephosphorylation. We conclude that PP65 is involved in the regulation of membrane fusion during exocytosis.

The glucose transporter in human fibroblasts is phosphorylated in response to phorbol ester but not in response to growth factors

The possibility that the stimulation of hexose transport in human fibroblasts by phorbol myristate acetate (PMA), insulin, platelet-derived growth factor (PDGF) or epidermal growth factor (EGF) is associated with phosphorylation of the glucose transporter has been investigated. The time and concentration dependencies of the stimulation of transport by these agents under conditions identical to those used for phosphorylation were determined. Each agent, when used at the concentration that resulted in the maximal increase in transport rate, elicited this effect within 30 min of exposure. The extent of stimulation ranged from 15 to 70%. For determination of phosphorylation of the glucose transporter, fibroblasts were incubated for 16 h with [32P]Pi and exposed to the agonist for 30 min; the transporter was then isolated from a detergent lysate of the cells by immunoprecipitation with a monoclonal antibody. Under these conditions, there was no phosphorylation of transporter in basal cells and only PMA caused detectable incorporation of phosphate into the transporter. Thus, it is unlikely that the stimulation of glucose transport by insulin, PDGF and EGF involve transporter phosphorylation.

Regulation of transmembrane signaling by receptor phosphorylation

At least two major effects of receptor phosphorylation have been identified--regulation of receptor function, and regulation of receptor distribution. In many cases where phosphorylation directly alters the functions of receptors, this appears to be in a negative direction. Such decreases in receptor activity may reflect reduced ability to interact with biochemical effectors (e.g., the beta-adrenergic receptor, rhodopsin), reduced affinity for binding agonist ligands (EGF,IGF-I, insulin receptors) or reduced enzymatic activity (e.g., tyrosine kinase activity of the insulin or EGF receptor). In all instances, these negative modulations are associated with phosphorylation of serine and/or threonine residues of the receptor proteins. In contrast, the tyrosine kinase receptors also appear to be susceptible to positive modulation by phosphorylation. With these receptors, autophosphorylation of tyrosine residues may lead to enhanced protein-tyrosine kinase activity of the receptors and increased receptor function. In addition, the subcellular distribution of a receptor may be regulated by its phosphorylation status (e.g., the beta-adrenergic receptor, receptors for insulin, EGF, IGF-II, and transferrin). The emerging paradigm is that receptor phosphorylation may in some way promote receptor internalization into sequestered compartments where dephosphorylation occurs. The molecular and cellular mechanisms involved in translating changes in receptor phosphorylation into changes in receptor distribution remain to be elucidated. Moreover, the biological role of receptor internalization may be quite varied. Thus, in the case of the beta-adrenergic receptor, it may serve primarily as a mechanism for bringing the phosphorylated receptors into contact with intracellular phosphatases that dephosphorylate and resensitize it. By contrast, for the transferrin receptor and other receptors involved in receptor-mediated endocytosis, the internalization presumably functions to carry some specific ligand or metabolite into the cell. The role of phosphorylation in regulating receptor function dramatically extends the range of regulatory control of this important covalent modification.

Insulin receptor binding and protein kinase activity in muscles of trained rats

Exercise has been shown to increase insulin sensitivity, and muscle is quantitatively the most important tissue of insulin action. Since the first step in insulin action is the binding to a membrane receptor, we postulated that exercise training would change insulin receptors in muscle and in this study we have investigated this hypothesis. Female rats initially weighing approximately 100 g were trained by treadmill running for 2 h/day, 6 days/wk for 4 wk at 25 m/min (0 grade). Insulin receptors from vastus intermedius muscles were solubilized by homogenizing in a buffer containing 1% Triton X-100 and then partially purified by passing the soluble extract over a wheat germ agglutinin column. The 4 wk training regimen resulted in a 65% increase in citrate synthase activity in red vastus lateralis muscle, indicating an adaptation to exercise. Insulin binding by the partially purified receptor preparation s was approximately doubled in muscle of trained rats at all insulin concentrations, suggesting an increase in the number of receptors. Training did not alter insulin receptor structure as evidenced by electrophoretic mobility under reducing and nonreducing conditions. Basal insulin receptor protein kinase activity was higher in trained than untrained animals and this was likely due to the greater number of receptors. However, insulin stimulation of the protein kinase activity was depressed by training. These results demonstrate that endurance training does alter receptor number and function in muscle and these changes may be important in increasing insulin sensitivity after exercise training.

Regulation of the protein kinase activity of the human insulin receptor

The insulin receptor is a hormone-dependent protein tyrosine kinase that belongs to the family of tyrosine kinases associated with growth factor receptors and oncogene products. The activity of the insulin receptor kinase is regulated by the phosphorylation state of specific domains of the protein. Phosphorylation of the receptor on tyrosine residues activates its kinase activity whereas phosphorylation on serine and/or threonine residues inhibits it. In this review, we discuss the evidence that supports a role of the kinase activity of the receptor in the molecular mechanism of insulin action.

The human insulin receptor cDNA: a new tool to study the function of this receptor

The human insulin receptor (hIR) is an integral transmembrane glycoprotein comprised of two alpha and two beta subunits. An immediate consequence of insulin binding to the extracellular alpha subunit is the autophosphorylation of tyrosine residues on the intracellular domain of the beta subunit. The placental hIR cDNA has been cloned and sequenced, providing the primary structural features of the protein. In order to investigate the functions of the beta subunit and particularly the role of autophosphorylation and tyrosine phosphokinase (TPK) activity (a feature shared by other receptors and oncogene proteins) in transmembrane signalling, we designed an expression system of the hIR cDNA in eucaryotic cells. Superexpressing CHO cell lines that contain about 10(6) functional hIR/cell have been developed. In these cells half maximum stimulation of glucose uptake occurs at 5 X 10(-10)M insulin, whereas normal CHO cells require 5 X 10(-12)M insulin. In this expression system we have carried out site-directed mutagenesis experiments in which domains of the molecule have been deleted or particular amino acids have been replaced by others. The replacement of either or both the tyrosine residues 1162 and 1163 compromise an autophosphorylated site that is important for kinase function and the insulin response. Expression of an isolated membrane-bound form of the beta-subunit produces a 6 fold increase in glucose uptake. This insulin-independent effect disappears if the twin tyrosines are mutated or if the beta subunit is expressed in the cytoplasm. These studies also show that the C terminal 112 amino acid portion of the beta subunit is important for the stability of this protein.

Insulin resistance in uremia: in vitro model in the rat liver using human serum to study mechanisms

We have previously demonstrated in a rat model of chronic uremia that the liver is resistant to insulin. To further investigate the mechanism(s) of insulin resistance in uremia, primary cultures of normal rat hepatocytes were incubated with varying dilutions (1/10 to 1/10,000) of sera from undialyzed end stage uremic and normal humans for 20 hours. We then studied insulin action, binding, and postbinding events. Dilutions of uremic sera as low as 1/1,000 rendered the hepatocytes resistant to maximal concentrations of insulin with regard to [14C]acetate incorporation into lipids. The dose response curve for insulin-stimulated [14C]aminoisobutyric acid uptake demonstrated a shift to the right in hepatocytes incubated with uremic sera when compared with those incubated with normal sera. The 125I-insulin binding sites and affinity, 125I-insulin internalization and degradation, insulin receptor structure, autophosphorylation of the insulin receptor, and its tyrosine-specific kinase activity were normal in the hepatocytes rendered resistant to insulin by uremic sera. However, these cells failed to generate the chemical mediator or second messenger of insulin action, as assessed by its ability to stimulate pyruvate dehydrogenase (PDH) in liver mitochondria from normal rats. We concluded that uremic sera renders normal rat hepatocytes resistant to insulin. Insulin resistance is a postinsulin receptor kinase defect possibly due to lack of the generation of the chemical mediator of insulin action. This in vitro cell model may be useful to further define the mechanism(s) and the serum factor(s) responsible for insulin resistance in uremia in the absence of complicating hormonal and substrate changes that occur in vivo.

Presence of an insulin-stimulated serine kinase in cell extracts from IM-9 cells

Insulin responsive protein kinase activities of wheat germ purified glycoproteins were examined. Glycoproteins were first incubated without or with insulin, and then exposed to a serum containing antibodies to insulin receptor. Thereafter, both immunoprecipitates and supernatants were studied for their kinase activity toward histone. Incubation with anti receptor antibodies promoted insulin receptor beta subunit and histone phosphorylation. More important insulin receptor depleted extract contained a kinase activity toward histone, that was increased by preincubation with insulin. This stimulation was observed only when insulin was added before the immunoprecipitation of insulin receptors. Alkali treatment and phosphoamino acids analysis revealed that the kinase activity remaining in the supernatant is serine specific. These findings suggest, that a serine kinase activity is associated with the insulin receptor, that it can be separated from the insulin receptor with anti receptor antibodies, that the serine kinase is activated by the hormone-receptor complex.

Replacement of insulin receptor tyrosine residues 1162 and 1163 compromises insulin-stimulated kinase activity and uptake of 2-deoxyglucose

Insulin stimulates the autophosphorylation of tyrosine residues of the beta subunit of the insulin receptor (IR); this modified insulin-independent kinase has increased activity toward exogenous substrates in vitro. We show here that replacement of one or both of the twin tyrosines (residues 1162 and 1163) with phenylalanine results in a dramatic reduction in or loss of insulin-activated autophosphorylation and kinase activity in vitro. In vivo, these mutations not only result in a substantial decrease in insulin-stimulated IR autophosphorylation but also in a parallel decrease in the insulin-activated uptake of 2-deoxyglucose. Furthermore, a truncated IR protein (lacking the last 112 amino acids) has an unstable beta subunit; this mutant has no kinase activity in vitro or in vivo and does not mediate insulin-stimulated uptake of 2-deoxyglucose. IR autophosphorylation is thus implicated in the regulation of IR activities, with tyrosines 1162 and 1163 as major sites of this regulation.

Effect of insulin receptor autophosphorylation on insulin receptor binding

Insulin receptor beta-subunit autophosphorylation, the first event occurring after insulin binding, plays a crucial role in modulation of receptor-associated kinase activity towards exogenous substrates and possibly in the transmission of biological signals of insulin. Receptor autophosphorylation strongly depends on insulin receptor occupancy. Till now the effects of receptor phosphorylation on insulin binding itself have not been clarified. In the present report we demonstrate the absence of any feedback mechanism by which insulin receptor activation by phosphorylation affects binding affinity of insulin receptor itself.

Kinetic properties of the insulin receptor tyrosine protein kinase: activation through an insulin-stimulated tyrosine-specific, intramolecular autophosphorylation

The insulin receptor is an insulin-activated, tyrosine-specific protein kinase. Previous studies have shown that autophosphorylation of tyrosine residues on the Mr 95,000 is associated with an activation of the protein kinase activity toward exogenous protein substrates. We have employed the highly purified insulin receptor, immobilized on insulin-Sepharose or eluted in an active form, to define the metal/ATP requirements for kinase activation, the relationship of receptor autophosphorylation to activation, and the kinetic properties of the autophosphorylated, activated receptor kinase. Prior incubation of the immobilized receptor with 2 mM ATP, 10 mM Mg (or 10 mM Mn), followed by removal of these reactants, served to abolish the upward curvilinearity in the rate of histone 2b (tyrosine) phosphorylation measured subsequently. This treatment also markedly increased the rate of histone 2b phosphorylation as compared to that observed with the unmodified, immobilized receptor, as estimated under conditions that per se minimized further activation. The extents of maximal activation of receptor histone 2b (tyrosine) kinase obtained on preincubation with MgATP or MnATP are identical; however, the affinity of the receptor for MnATP is approximately 10-fold higher than that for MgATP. The higher affinity of the receptor for MnATP is observed for both autophosphorylation/autoactivation and histone 2b tyrosine kinase activity (Km MnATP approximately 0.01 mM; Km MgATP approximately 0.1 mM). Autophosphorylation/autoactivation per se does not significantly alter the apparent affinity for MeATP (or protein substrate, as previously reported) but increases Vmax. Activation of receptor histone 2b (tyrosine) kinase is due to tyrosine-specific autophosphorylation of the Mr 95,000 (beta) subunit; thus the extent of total 32P incorporation into the beta subunit correlates precisely with the extent of kinase activation, both over time and at a wide variety of Me2+ ATP concentrations. Sequential treatment of the autophosphorylated receptor with elastase and trypsin yields a single, basically charged 32P-peptide, Mr less than 2000. The functional properties of the unphosphorylated and fully phosphorylated receptor were compared after elution from insulin-Sepharose. The insulin binding characteristics of the two forms of the receptor were indistinguishable; the kinase properties differed greatly; whereas the histone 2b activity of the unphosphorylated receptor was low in the basal state, and activated 10-fold by insulin, the fully autophosphorylated receptor exhibits maximal histone 2b kinase in the basal state and is unaffected by insulin addition.(ABSTRACT TRUNCATED AT 400 WORDS)

Insulin rapidly stimulates tyrosine phosphorylation of a Mr-185,000 protein in intact cells

Phosphotyrosine-containing proteins are minor components of normal cells which appear to be associated primarily with the regulation of cellular metabolism and growth. The insulin receptor is a tyrosine-specific protein kinase, and one of the earliest detectable responses to insulin binding is activation of this kinase and autophosphorylation of its beta-subunit. Tyrosine autophosphorylation activates the phosphotransferase in the beta-subunit and increases its reactivity toward tyrosine phosphorylation of other substrates. When incubated in vitro with [gamma-32P]ATP and insulin, the purified insulin receptor phosphorylates various proteins on their tyrosine residues. However, so far no proteins other than the insulin receptor have been identified as undergoing tyrosine phosphorylation in response to insulin in an intact cell. Here, using anti-phosphotyrosine antibodies, we have identified a novel phosphotyrosine-containing protein of relative molecular mass (Mr) 185,000 (pp185) which appears during the initial response of hepatoma cells to insulin binding. In contrast to the insulin receptor, pp185 does not adhere to wheat-germ agglutininagarose or bind to anti-insulin receptor antibodies. Phosphorylation of pp185 is maximal within seconds after exposure of the cells to insulin and exhibits a dose-response curve similar to that of receptor autophosphorylation, suggesting that this protein represents the endogenous substrate for the insulin receptor kinase.

A novel glycosyl-amino acid linkage: rabbit-muscle glycogen is covalently linked to a protein via tyrosine

A recent review summarizes our identification in rabbit-muscle glycogen of a protein that resists all attempts at removal by means that should displace non-covalently bound protein [Kennedy et al. (1985) In Membranes and Muscle (Berman, M.C., Gevers, W. and Opie, L.H. eds.) pp. 65-84, ICSU Press/IRL Press, Oxford]. Here we confirm that the glycogen is covalently bonded to the protein and report that the attachment is via a novel glycosidic linkage involving the hydroxyl group of tyrosine.