Publications

1999

Wojtaszewski, Higaki, Hirshman, Michael, Dufresne, Kahn, and Goodyear. (1999) 1999. “Exercise Modulates Postreceptor Insulin Signaling and Glucose Transport in Muscle-Specific Insulin Receptor Knockout Mice”. J Clin Invest 104 (9): 1257-64. https://doi.org/10.1172/JCI7961.
Physical exercise promotes glucose uptake into skeletal muscle and makes the working muscles more sensitive to insulin. To understand the role of insulin receptor (IR) signaling in these responses, we studied the effects of exercise and insulin on skeletal muscle glucose metabolism and insulin signaling in mice lacking insulin receptors specifically in muscle. Muscle-specific insulin receptor knockout (MIRKO) mice had normal resting 2-deoxy-glucose (2DG) uptake in soleus muscles but had no significant response to insulin. Despite this, MIRKO mice displayed normal exercise-stimulated 2DG uptake and a normal synergistic activation of muscle 2DG uptake with the combination of exercise plus insulin. Glycogen content and glycogen synthase activity in resting muscle were normal in MIRKO mice, and exercise, but not insulin, increased glycogen synthase activity. Insulin, exercise, and the combination of exercise plus insulin did not increase IR tyrosine phosphorylation or phosphatidylinositol 3-kinase activity in MIRKO muscle. In contrast, insulin alone produced a small activation of Akt and glycogen synthase kinase-3 in MIRKO mice, and prior exercise markedly enhanced this insulin effect. In conclusion, normal expression of muscle insulin receptors is not needed for the exercise-mediated increase in glucose uptake and glycogen synthase activity in vivo. The synergistic activation of glucose transport with exercise plus insulin is retained in MIRKO mice, suggesting a phenomenon mediated by nonmuscle cells or by downstream signaling events.
Immortalized fetal brown adipocyte cell lines have been generated from homozygous (-/-) and heterozygous (+/-) insulin receptor substrate (IRS)-1-deficient mice, as well as from wild-type mice (+/+). Under growing conditions, these cell lines maintained the expression of the adipogenic marker fatty acid synthase and uncoupling protein-1, a tissue-specific thermogenic marker. The IRS-1 (-/-) brown adipocytes lacked IRS-1 protein expression and had a significant increase in IRS-2 protein expression. Insulin-induced tyrosine phosphorylation of IRS-1 was reduced by 50% in heterozygous IRS-1-deficient cells and was totally absent in homozygous cells, while tyrosine phosphorylation of IRS-2 showed a gradual increase. Insulin receptor alpha-subunit protein content and beta-subunit tyrosine kinase activity remained unchanged upon insulin stimulation, regardless of the lack of IRS-1. Brown adipocytes from homozygous IRS-1-deficient mice showed no IRS-1-associated p85alpha subunit of phosphatidylinositol 3-kinase (PI 3-kinase) or IRS-1-associated PI 3-kinase activity in response to insulin, but exhibited enhanced IRS-2-associated p85alpha subunit and IRS-2-associated PI 3-kinase activity. Overall insulin-induced PI 3-kinase activity associated to antiphosphotyrosine immune complexes was decreased by 30% in the homozygous IRS-1-deficient brown adipocytes. Downstream PI 3-kinase, activated Akt (protein kinase B) was decreased by 92% in an insulin-stimulated homozygous IRS-1-deficient brown adipocyte cell line, whereas the expression of Akt was similar in the three cell lines. However, activated p70 S6 kinase (p70s6k) remained unchanged. Although brown adipocyte cell lines showed similar cytosolic lipid content in the presence of 10% fetal calf serum, cytosolic lipid content was reduced in both serum-deprived heterozygous and homozygous IRS-1-deficient cells. Insulin treatment for 24 h doubled the cytosolic lipid content in wild-type and heterozygous IRS-1-deficient brown adipocyte cell lines but failed to increase the cytosolic lipid content in homozygous IRS-1-deficient cells. Our results strongly suggest that IRS-1/PI 3-kinase/Akt activation is an essential requirement for insulin stimulation of lipid synthesis in brown adipocytes.
Gazdag, Dumke, Kahn, and Cartee. (1999) 1999. “Calorie Restriction Increases Insulin-Stimulated Glucose Transport in Skeletal Muscle from IRS-1 Knockout Mice”. Diabetes 48 (10): 1930-6.
Calorie restriction (CR), even for brief periods (4-20 days), results in increased whole-body insulin sensitivity, in large part due to enhanced insulin-stimulated glucose transport by skeletal muscle. Evidence suggests that the cellular alterations leading to this effect are postreceptor steps in insulin signaling. To determine whether insulin receptor substrate (IRS)-1 is essential for the insulin-sensitizing effect of CR, we measured in vitro 2-deoxyglucose (2DG) uptake in the presence and absence of insulin by skeletal muscle isolated from wild-type (WT) mice and transgenic mice lacking IRS-1 (knockout [KO]) after either ad libitum (AL) feeding or 20 days of CR (60% of ad libitum intake). Three muscles (soleus, extensor digitorum longus [EDL], and epitrochlearis) from male and female mice (4.5-6 months old) were studied. In each muscle, insulin-stimulated 2DG uptake was not different between genotypes. For EDL and epitrochlearis, insulin-stimulated 2DG uptake was greater in CR compared to AL groups, regardless of sex. Soleus insulin-stimulated 2DG uptake was greater in CR compared with AL in males but not females. The diet effect on 2DG uptake was not different for WT and KO animals. Genotype also did not alter the CR-induced decrease in plasma constituents (glucose, insulin, and leptin) or body composition (body weight, fat pad/body weight ratio). Consistent with previous studies in rats, IRS-1 protein expression in muscle was reduced in WT-CR compared with WT-AL mice, and muscle IRS-2 abundance was unchanged by diet. Skeletal muscle IRS-2 protein expression was significantly lower in WT compared with KO mice. These data demonstrate that IRS-1 is not essential for the CR-induced increase in insulin-stimulated glucose transport in skeletal muscle, and the absence of IRS-1 does not modify any of the characteristic adaptations of CR that were evaluated.

1995

Yamada, Carpentier, Cheatham, Goncalves, Shoelson, and Kahn. 1995. “Role of the Transmembrane Domain and Flanking Amino Acids in Internalization and Down-Regulation of the Insulin Receptor”. J Biol Chem 270 (7): 3115-22.
We have characterized the internalization and down-regulation of the insulin receptor and nine receptors with mutations in the transmembrane (TM) domain and/or flanking charged amino acids to define the role of this domain in receptor cycling. When expressed in Chinese hamster ovary cells, all had normal tetrameric structure and normal insulin-stimulated autophosphorylation/kinase activity. Replacement of the TM domain with that of the platelet-derived growth factor receptor, insertion of 3 amino acids, and substitution of Asp for Val938 or of Ala for either Gly933 or Pro934 had no effect on internalization. Replacement of the TM domain with that of c-neu or conversion of the charged amino acids on the cytoplasmic flank to uncharged amino acids, on the other hand, resulted in a 40-60% decrease in insulin-dependent internalization rate constants. By contrast, substitution of Ala for both Gly933 and Pro934 increases lateral diffusion mobility and accelerates internalization rate. These changes in internalization were due to decreased or increased rates of redistribution of receptors from microvilli to the nonvillous cell surface. In all cases, receptor down-regulation and receptor-mediated insulin degradation paralleled the changes in internalization. Thus, the structure of the transmembrane domain of the insulin receptor and flanking amino acids are major determinants of receptor internalization, insulin degradation, and receptor down-regulation.
Rothman, Magnusson, Cline, Gerard, Kahn, Shulman, and Shulman. 1995. “Decreased Muscle Glucose Transport/Phosphorylation Is an Early Defect in the Pathogenesis of Non-Insulin-Dependent Diabetes Mellitus”. Proc Natl Acad Sci U S A 92 (4): 983-7.
Recent studies have demonstrated that reduced insulin-stimulated muscle glycogen synthesis is the major cause of insulin resistance in patients with non-insulin-dependent diabetes mellitus (NIDDM). This reduced rate has been assigned to a defect in either glucose transport or hexokinase activity. However it is unknown whether this is a primary or acquired defect in the pathogenesis of NIDDM. To examine this question, we measured the rate of muscle glycogen synthesis and the muscle glucose 6-phosphate (G6P) concentration using 13C and 31P NMR spectroscopy as well as oxidative and nonoxidative glucose metabolism in six lean, normoglycemic offspring of parents with NIDDM and seven age/weight-matched control subjects under hyperglycemic (approximately 11 mM)-hyperinsulinemic (approximately 480 pM) clamp conditions. The offspring of parents with NIDDM had a 50% reduction in total glucose metabolism, primarily due to a decrease in the nonoxidative component. The rate of muscle glycogen synthesis was reduced by 70% (P 0.005) and muscle G6P concentration was reduced by 40% (P 0.003), which suggests impaired muscle glucose transport/hexokinase activity. These changes were similar to those previously observed in subjects with fully developed NIDDM. When the control subjects were studied at similar insulin levels (approximately 440 pM) but euglycemic plasma glucose concentration (approximately 5 mM), both the rate of glycogen synthesis and the G6P concentration were reduced to values similar to the offspring of parents with NIDDM. We conclude that insulin-resistant offspring of parents with NIDDM have reduced nonoxidative glucose metabolism and muscle glycogen synthesis secondary to a defect in muscle glucose transport/hexokinase activity prior to the onset of overt hyperglycemia. The presence of this defect in these subjects suggests that it may be the primary factor in the pathogenesis of NIDDM.
Doria, Caldwell, Ji, Reynet, Rich, Weremowicz, Morton, Warram, Kahn, and Krolewski. (1995) 1995. “Trinucleotide Repeats at the Rad Locus. Allele Distributions in NIDDM and Mapping to a 3-CM Region on Chromosome 16q”. Diabetes 44 (2): 243-7.
A 10-allele polymorphism was identified in rad (ras associated with diabetes), a gene that is overexpressed in non-insulin-dependent diabetes mellitus (NIDDM) muscle. The polymorphism, designated RAD1, consists of a variable number of trinucleotide repeats (GTT and ATT) located in the poly(A) region of an intronic Alu sequence. Based on the number of GTT and ATT repetitions, the alleles can be grouped into four classes (I-IV). RAD1 allele frequencies were determined in 210 NIDDM patients and 133 nondiabetic control subjects, all Caucasians. One allele (number 8, class III) accounted for > 80% of the chromosomes in both groups. However, an excess of minor alleles, all belonging to class I, II, or IV, was observed among NIDDM chromosomes (P 0.025), suggesting a possible association between RAD1 and NIDDM predisposition. To promote further studies to test the hypothesis that genetic variability at the rad locus contributes to NIDDM, we mapped rad on the human genome. Using the fluorescence in situ chromosomal hybridization technique, rad was unequivocally assigned to chromosomal band 16q22. In families that were informative for RAD1, the rad locus was mapped within a 3-cM region defined by the markers D16S265, D16S186, and D16S397 (logarithm of odds scores = 10.08, 10.9, and 10.84 at recombination fractions of 0.024, 0.001, and 0.03, respectively). The high degree of heterozygosity of these markers will allow large-scale family studies to be performed to test the presence of linkage between rad and NIDDM.
Yamada, Goncalves, Carpentier, Kahn, and Shoelson. 1995. “Transmembrane Domain Inversion Blocks ER Release and Insulin Receptor Signaling”. Biochemistry 34 (3): 946-54.
Activation of the insulin receptor, like other tyrosine kinase receptors, appears to require dimerization. We have shown previously that, even in the absence of insulin, full receptor activation can be induced by changes in the receptor transmembrane domain (TMD), suggesting that TMD dimerization is sufficient for receptor activation. To further understand the importance of the TMD in insulin receptor activation, we have inverted the entire TMD sequence including flanking basic amino acids, residue-for-residue. This mutation was predicted to alter the ability of a TMD alpha-helix to form homodimers and higher level aggregates. Despite apparently normal protein folding on either side of the membrane, this mutation caused ER retention and, for those receptors that reached the cell surface, blockade of insulin-stimulated kinase signal transmission. However, the signaling blockade could be overcome by proteolytic activation with trypsin. In contrast, shifting only the basic cytoplasmic residues to the opposite side of the TMD or mutation to neutral residues had no detectable effect on assembly, biosynthesis, topology, or signaling. These findings extend our previous observations to suggest that TMD interactions within the membrane are not only sufficient for receptor activation, but may be required. TMD interactions also appear to be necessary for oligomeric assembly and biosynthetic maturation of the insulin receptor.

1994

The activation of p21ras by receptor tyrosine kinases involves the translocation of the growth factor receptor bound protein 2-mammalian son of sevenless protein (Grb2-SOS) complex to the plasma membrane where p21ras is localized. Insulin receptors induce p21ras-GTP formation by two possible mechanisms: tyrosine phosphorylation of insulin receptor substrate 1 (IRS1) and its subsequent association with Grb2, or Shc phosphorylation and its subsequent association with Grb2. We investigated the contribution of the major tyrosine autophosphorylation sites Tyr1158, Tyr1162, and Tyr1163 of the insulin receptor to IRS1.Grb2 and Shc.Grb2 association and the formation of p21ras-GTP. Chinese hamster ovary-derived cell lines were used overexpressing mutant insulin receptors in which the major tyrosine autophosphorylation sites were stepwise replaced by phenylalanines. In cell lines expressing wild type or mutant Y1158F,Y1162,Y1163 (FYY) receptors, insulin stimulated tyrosine phosphorylation of IRS1 and Shc and the formation of IRS1.Grb2 and Shc.Grb2 protein complexes, together with an increase in p21ras-GTP. Cell lines expressing mutant Y1158,Y1162F,Y1163F (YFF) receptors showed insulin-induced tyrosine phosphorylation of Shc, Shc.Grb2 complex formation, and p21ras-GTP formation, whereas tyrosine phosphorylation of IRS1 was strongly decreased and formation of IRS1.Grb2 complexes was undetectable. The activity of FYY and YFF receptors to mediate p21ras-GTP formation correlated with their activity to induce Shc phosphorylation and Shc.Grb2 association. The mutant insulin receptors Y1158F,Y1162F,Y1163 and Y1158F,Y1162F,Y1163F were inactive in inducing any of these responses. We conclude that phosphorylation of Tyr1158 and Tyr1162 of the insulin receptor is linked to distinct post-receptor processes and that YFF receptors generate p21ras-GTP via the Shc.Grb2 pathway rather than one involving IRS1.Grb2 interaction.
Araki, Lipes, Patti, Brüning, Haag, Johnson, and Kahn. 1994. “Alternative Pathway of Insulin Signalling in Mice With Targeted Disruption of the IRS-1 Gene”. Nature 372 (6502): 186-90. https://doi.org/10.1038/372186a0.
The principal substrate for the insulin and insulin-like growth factor-1 (IGF-1) receptors is the cytoplasmic protein insulin-receptor substrate-1 (IRS-1/pp185). After tyrosine phosphorylation at several sites, IRS-1 binds to and activates phosphatidylinositol-3'-OH kinase (PI(3)K) and several other proteins containing SH2 (Src-homology 2) domains. To elucidate the role of IRS-1 in insulin/IGF-1 action, we created IRS-1-deficient mice by targeted gene mutation. These mice had no IRS-1 and showed no evidence of IRS-1 phosphorylation or IRS-1-associated PI(3)K activity. They also had a 50 per cent reduction in intrauterine growth, impaired glucose tolerance, and a decrease in insulin/IGF-1-stimulated glucose uptake in vivo and in vitro. The residual insulin/IGF-1 action correlated with the appearance of a new tyrosine-phosphorylated protein (IRS-2) which binds to PI(3)K, but is slightly larger than and immunologically distinct from IRS-1. Our results provide evidence for IRS-1-dependent and IRS-1-independent pathways of insulin/IGF-1 signalling and for the existence of an alternative substrate of these receptor kinases.