Cox, Spielman, Kahn, Müller-Wieland, Kriauciunas, and Taub. 1988. “Four RFLPs of the Human Insulin Receptor Gene: PstI, KpnI, RsaI (2 RFLPs)”. Nucleic Acids Res 16 (16): 8204.
Publications by Year: 1988
1988
Crettaz, Müller-Wieland, and Kahn. 1988. “Transcriptional and Posttranscriptional Regulation of Tyrosine Aminotransferase by Insulin in Rat Hepatoma Cells”. Biochemistry 27 (1): 495-500.
The molecular mechanisms of induction of tyrosine aminotransferase (TAT) by insulin were studied in the well-differentiated rat hepatoma cell line Fao. Incubation of Fao cells with insulin resulted in a 2-fold increase in TAT activity and TAT mRNA measured by Northern blot analysis with an oligonucleotide probe to the 5' end of the gene. The effect of insulin on TAT activity had a lag period of 30-60 min and was maximal within 4-5 h. The insulin effect on TAT mRNA was rapid, half-maximal after 15 min, and complete within 1-2 h. Insulin dose-response curves for stimulation of TAT activity and TAT mRNA were almost identical. TAT mRNA levels and enzyme activity were also stimulated by anti-insulin receptor antibodies and dexamethasone but not by wheat germ agglutinin, concanavalin A, or phytohemagglutin. The effect of insulin on the TAT gene was further investigated by measuring the relative rate of transcription in isolated nuclei using genomic TAT clones. Insulin produced a 1.5-1.7-fold increase in the production of TAT RNA transcripts. Dexamethasone induced both TAT activity and TAT mRNA to a comparable extent. In the presence of dexamethasone, insulin produced an additional 2-fold stimulation of TAT activity but had no additional effect on the abundance of TAT mRNA. These data provide direct evidence that insulin can increase TAT activity by at least two distinct mechanisms: insulin alone appears to increase TAT activity and TAT mRNA due to a stimulation of the TAT gene transcription rate; while in the presence of glucocorticoids, insulin increases TAT activity but not TAT mRNA, suggesting an insulin effect at the posttranscriptional level.
White, Shoelson, Keutmann, and Kahn. 1988. “A Cascade of Tyrosine Autophosphorylation in the Beta-Subunit Activates the Phosphotransferase of the Insulin Receptor”. J Biol Chem 263 (6): 2969-80.
We identified the major autophosphorylation sites in the insulin receptor and correlated their phosphorylation with the phosphotransferase activity of the receptor on synthetic peptides. The receptor, purified from Fao hepatoma cells on immobilized wheat germ agglutinin, undergoes autophosphorylation at several tyrosine residues in its beta-subunit; however, anti-phosphotyrosine antibody (alpha-PY) inhibited most of the phosphorylation by trapping the initial sites in an inactive complex. Exhaustive trypsin digestion of the inhibited beta-subunit yielded two peptides derived from the Tyr-1150 domain (Ullrich, A, Bell, J. R., Chen, E. Y., Herrera, R., Petruzzelli, L. M., Dull, T. J., Gray, A., Coussens, L., Liao, Y.-C., Tsubokawa, M., Mason, A., Seeburg, P. H., Grunfeld, C., Rosen, O. M., and Ramachandran, J. (1985) Nature 313, 756-761) called pY4 and pY5. Both peptides contained 2 phosphotyrosyl residues (2Tyr(P], one corresponding to Tyr-1146 and the other to Tyr-1150 or Tyr-1151. In the absence of the alpha-PY additional sites were phosphorylated. The C-terminal domain of the beta-subunit contained phosphotyrosine at Tyr-1316 and Tyr-1322. Removal of the C-terminal domain by mild trypsinolysis did not affect the phosphotransferase activity of the beta-subunit suggesting that these sites did not play a regulatory role. Full activation of the insulin receptor during in vitro assay correlated with the appearance of two phosphopeptides in the tryptic digest of the beta-subunit, pY1 and pY1a, that were inhibited by the alpha-PY. Structural analysis suggested that pY1 and pY1a were derived from the Tyr-1150 domain and contained 3 phosphotyrosyl residues (3Tyr(P] corresponding to Tyr-1146, Tyr-1150, and Tyr-1151. The phosphotransferase of the receptor that was phosphorylated in the presence of alpha-PY at 2 tyrosyl residues in the Tyr-1150 domain was not fully activated during kinase assays carried out with saturating substrate concentrations which inhibited further autophosphorylation. During insulin stimulation of the intact cell, the 3Tyr(P) form of the Tyr-1150 domain was barely detected, whereas the 2Tyr(P) form predominated. We conclude that 1) autophosphorylation of the insulin receptor begins by phosphorylation of Tyr-1146 and either Tyr-1150 or Tyr-1151; 2) progression of the cascade to phosphorylation of the third tyrosyl residue fully activates the phosphotransferase during in vitro assay; 3) in vivo, the 2Tyr(P) form predominates, suggesting that progression of the autophosphorylation cascade to the 3Tyr(P) form is regulated during insulin stimulation.(ABSTRACT TRUNCATED AT 400 WORDS)
Takayama, White, and Kahn. 1988. “Phorbol Ester-Induced Serine Phosphorylation of the Insulin Receptor Decreases Its Tyrosine Kinase Activity”. J Biol Chem 263 (7): 3440-7.
The effect of 12-O-tetradecanoylphorbol-13-acetate (TPA) on the function of the insulin receptor was examined in intact hepatoma cells (Fao) and in solubilized extracts purified by wheat germ agglutinin chromatography. Incubation of ortho[32P]phosphate-labeled Fao cells with TPA increased the phosphorylation of the insulin receptor 2-fold after 30 min. Analysis of tryptic phosphopeptides from the beta-subunit of the receptor by reverse-phase high performance liquid chromatography and determination of their phosphoamino acid composition suggested that TPA predominantly stimulated phosphorylation of serine residues in a single tryptic peptide. Incubation of the Fao cells with insulin (100 nM) for 1 min stimulated 4-fold the phosphorylation of the beta-subunit of the insulin receptor. Prior treatment of the cells with TPA inhibited the insulin-stimulated tyrosine phosphorylation by 50%. The receptors extracted with Triton X-100 from TPA-treated Fao cells and purified on immobilized wheat germ agglutinin retained the alteration in kinase activity and exhibited a 50% decrease in insulin-stimulated tyrosine autophosphorylation and phosphotransferase activity toward exogenous substrates. This was due primarily to a decrease in the Vmax for these reactions. TPA treatment also decreased the Km of the insulin receptor for ATP. Incubation of the insulin receptor purified from TPA-treated cells with alkaline phosphatase decreased the phosphate content of the beta-subunit to the control level and reversed the inhibition, suggesting that the serine phosphorylation of the beta-subunit was responsible for the decreased tyrosine kinase activity. Our results support the notion that the insulin receptor is a substrate for protein kinase C in the Fao cell and that the increase in serine phosphorylation of the beta-subunit of the receptor produced by TPA treatment inhibited tyrosine kinase activity in vivo and in vitro. These data suggest that protein kinase C may regulate the function of the insulin receptor.
Okamoto, Kahn, Maron, and White. (1988) 1988. “Decreased Autophosphorylation of EGF Receptor in Insulin-Deficient Diabetic Rats”. Am J Physiol 254 (4 Pt 1): E429-34. https://doi.org/10.1152/ajpendo.1988.254.4.E429.
We have previously reported that despite an increase in receptor concentration, there is a decrease in autophosphorylation and tyrosine kinase activity of the insulin receptor in insulin-deficient diabetic rats. To determine if other tyrosine kinases might be altered, we have studied the epidermal growth factor (EGF) receptor kinase in wheat germ agglutinin-purified, Triton X-100-solubilized liver membranes from streptozotocin (STZ)-induced diabetic rats and the insulin-deficient BB rat. We find that autophosphorylation of EGF receptor is decreased in proportion to the severity of the diabetic state in STZ rats with a maximal decrease of 67% (P less than 0.01). A similar decrease in autophosphorylation was observed in diabetic BB rats that was partially normalized by insulin treatment. Separation of tryptic phosphopeptides by reverse-phase high-performance liquid chromatography revealed a decrease in labeling at all sites of autophosphorylation. A parallel decrease in EGF receptor phosphorylation was also found by immunoblotting with an anti-phosphotyrosine antibody. EGF receptor concentration, determined by Scatchard analysis of 125I-labeled EGF binding, was decreased by 39% in the STZ rat (P less than 0.05) and 27% in the diabetic BB rat (not significant). Thus autophosphorylation of EGF receptor, like that of the insulin receptor, is decreased in insulin-deficient rat liver. In the case of EGF receptor, this is due in part to a decrease in receptor number and in part to a decrease in the specific activity of the kinase.(ABSTRACT TRUNCATED AT 250 WORDS)
Vlachokosta, Piper, Gleason, Kinzel, and Kahn. (1988) 1988. “Dietary Carbohydrate, a Big Mac, and Insulin Requirements in Type I Diabetes”. Diabetes Care 11 (4): 330-6.
Using the artificial beta-cell (Biostator), we determined the insulin requirements in five nonobese type I (insulin-dependent) diabetic subjects who received isocaloric 40 and 60% mixed-carbohydrate diets in a crossover randomized fashion for 4 days, each day consisting of four equal meals. This was followed on day 5 by a "Big Mac Attack" lunch consisting of a Big Mac, french fries, and milk shake. Insulin requirements to maintain normoglycemia were calculated for each 24-h period and for the 2 h after each meal. The mean 24-h insulin requirements to maintain normoglycemia was greater for the 60% carbohydrate diet than the 40% diet. Although the four meals were of equal size, in all patients the insulin required to cover breakfast greater than lunch greater than dinner greater than or equal to snack. Expressed as milliunits per kilocalorie, the amount of insulin to cover breakfast was greater for the 60% (P less than .05) than the 40% carbohydrate diet and greater for breakfast than the other meals (P less than .01). Insulin requirements for the Big Mac (43% carbohydrate) were 58% greater than for the 40% carbohydrate diet, even after correction for caloric differences. In summary, 1) increasing dietary carbohydrate from 40 to 60% results in an increased insulin requirement for meals only; 2) insulin requirements are greater in the morning than in the evening, even when meal size is constant; and 3) very large meals with high fat and carbohydrate content result in a major increase in insulin requirement. These data indicate that diet has an important impact on insulin requirements in diabetes.
Shoelson, White, and Kahn. 1988. “Tryptic Activation of the Insulin Receptor. Proteolytic Truncation of the Alpha-Subunit Releases the Beta-Subunit from Inhibitory Control”. J Biol Chem 263 (10): 4852-60.
Trypsin exerts insulin-like effects in intact cells and on partially purified preparations of insulin receptors. To elucidate the mechanism of these insulinomimetic effects, we compared the structures of insulin- and trypsin-activated receptor species with their functions, including insulin binding, autophosphorylation, and tyrosine kinase activity. In vitro treatment of wheat germ agglutinin-purified receptor preparations with trypsin resulted in proteolysis of both alpha- and beta-subunits. The activated form of the receptor had an apparent molecular mass of 110 kDa under nonreducing conditions, compared to the 400-kDa intact receptor, and was separated following reduction into an 85-kDa beta-subunit related fragment and a 25-kDa alpha-subunit related fragment. Treatment of whole cells with trypsin prior to isolation of the insulin receptor resulted in proteolytic modification of the alpha-subunit only. In this case, the total molecular mass of the activated species was 116 kDa, comprised of an intact 92-kDa beta-subunit and again a 25-kDa alpha-subunit related fragment. Values of Km for peptide substrate phosphorylation and Ki for inhibition of receptor autophosphorylation, and sites of autophosphorylation within the beta-subunits were similar for receptors activated either by insulin or trypsin. Insulin had no additional effect on the rate of autophosphorylation of the truncated receptor, and no binding of insulin by the truncated receptor was detected either by direct assay or cross-linking with bifunctional reagents. Based on the deduced amino acid sequence of the insulin receptor and the structural studies presented here we concluded that this activated form of the receptor resulted from tryptic cleavage at the dibasic site Arg576-Arg577. This was accompanied by loss of the insulin binding site and separation of alpha-beta heterodimers. As truncation of the alpha-subunit results in beta-subunit activation, it appears that the beta-subunit is a constitutively activated kinase and that the function of the alpha-subunit in the intact receptor is to inhibit the beta-subunit.
Takayama, Kahn, Kubo, and Foley. (1988) 1988. “Alterations in Insulin Receptor Autophosphorylation in Insulin Resistance: Correlation With Altered Sensitivity to Glucose Transport and Antilipolysis to Insulin”. J Clin Endocrinol Metab 66 (5): 992-9. https://doi.org/10.1210/jcem-66-5-992.
We studied insulin binding, receptor autophosphorylation, and insulin action in isolated adipocytes from 23 Pima Indians with varying degrees of obesity over a range of glucose tolerance. [125I]Insulin binding varied widely and did not correlate with fasting plasma immunoreactive insulin levels or insulin sensitivity, as assessed by the ED50 values of insulin stimulation of glucose transport or insulin inhibition of lipolysis in isolated abdominal wall adipocytes obtained by biopsy from the patients. In contrast there was a significant correlation between loss of stimulation of autophosphorylation in solubilized receptors and loss of insulin sensitivity for both stimulation of glucose transport (r = -0.59; P less than 0.005) and inhibition of lipolysis (r = -0.54; P less than 0.01). There was also a significant inverse correlation between insulin's ability to stimulate receptor autophosphorylation and in vivo insulin resistance, as assessed by fasting plasma insulin levels (r = -0.46; P less than 0.05). These data indicate a significant correlation between changes in sensitivity of glucose transport and antilipolysis to insulin and receptor kinase activity in those patients and suggest that defective coupling of insulin binding to insulin action at the level of phosphorylation of the insulin receptor may cause the insulin resistance in this group of patients.
Beguinot, Smith, Kahn, Maron, Moses, and White. 1988. “Phosphorylation of Insulin-Like Growth Factor I Receptor by Insulin Receptor Tyrosine Kinase in Intact Cultured Skeletal Muscle Cells”. Biochemistry 27 (9): 3222-8.
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.
Ludwig, Müller-Wieland, Goldstein, and Kahn. (1988) 1988. “The Insulin Receptor Gene and Its Expression in Insulin-Resistant Mice”. Endocrinology 123 (1): 594-600. https://doi.org/10.1210/endo-123-1-594.
Defects of insulin receptor binding and tyrosine kinase activity have been described in genetically diabetic (db/db) and obese (ob/ob) mice. To determine if these changes were related to an abnormality in insulin receptor mRNA expression or structure of the receptor gene, we quantitated receptor mRNA from db/db and ob/ob homozygous, heterozygous (db/x, ob/x) and unaffected [db(x/x), ob(x/x)] mice and also analyzed restriction fragment length patterns of genomic DNA. Northern blot analysis of insulin receptor mRNA in livers from each of the genotypes revealed two major species of 7.5 and 9.5 kilobases. In contrast to known decreased receptor number in various tissues of ob/ob and db/db mice, quantitation of liver insulin receptor mRNA revealed that both homozygous affected strains had 2-fold or more increased levels of both major mRNA species compared to unaffected control groups. (P less than 0.05). Restriction fragment length analysis revealed no major insertion or deletion mutations in either the db/db or ob/ob insulin receptor gene. From the number and size of the fragments generated by this analysis, the minimal size of the mouse insulin receptor gene was calculated to be 97 kilobases, and the minimal number of exons was 16. These data indicate that the insulin receptor gene in ob/ob and db/db mice exhibits no major structural abnormality. Decreases in insulin receptor binding and/or kinase activity in affected mice appear to be due to a defect at the posttranscriptional level and occur despite increased levels of receptor mRNA.