Multi-layered proteomics identifies insulin-induced upregulation of the EphA2 receptor via the ERK pathway which is dependent on low IGF1R level
Sarah Hyllekvist JørgensenKristina B. EmdalAnna-Kathrine PedersenLene Nygaard AxelsenHelene Faustrup KildegaardDamien DemozayThomas Åskov PedersenMads GrønborgRita SlaabyPeter Kresten NielsenJesper V. Olsen
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Insulin resistance impairs the cellular insulin response, and often precedes metabolic disorders, like type 2 diabetes, impacting an increasing number of people globally. Understanding the molecular mechanisms in hepatic insulin resistance is essential for early preventive treatments. To elucidate changes in insulin signal transduction associated with hepatocellular resistance, we employed a multi-layered mass spectrometry-based proteomics approach focused on insulin receptor (IR) signaling at the interactome, phosphoproteome, and proteome levels in a long-term hyperinsulinemia-induced insulin-resistant HepG2 cell line with a knockout of the insulin-like growth factor 1 receptor (IGF1R KO). The analysis revealed insulin-stimulated recruitment of the PI3K complex in both insulin-sensitive and -resistant cells. Phosphoproteomics showed attenuated signaling via the metabolic PI3K-AKT pathway but sustained extracellular signal-regulated kinase (ERK) activity in insulin-resistant cells. At the proteome level, the ephrin type-A receptor 2 (EphA2) showed an insulin-induced increase in expression, which occurred through the ERK signaling pathway and was concordantly independent of insulin resistance. Induction of EphA2 by insulin was confirmed in additional cell lines and observed uniquely in cells with high IR-to-IGF1R ratio. The multi-layered proteomics dataset provided insights into insulin signaling, serving as a resource to generate and test hypotheses, leading to an improved understanding of insulin resistance.Keywords:
IRS2
IRS1
Insulin receptor substrate
Binding of insulin receptor substrate proteins 1 and 2 (IRS1/2) to the insulin receptor (IR) is essential for the regulation of insulin sensitivity and energy homeostasis. However, the mechanism of IRS1/2 recruitment to the IR remains elusive. Here, we identify adaptor protein APPL1 as a critical molecule that promotes IRS1/2-IR interaction. APPL1 forms a complex with IRS1/2 under basal conditions, and this complex is then recruited to the IR in response to insulin or adiponectin stimulation. The interaction between APPL1 and IR depends on insulin- or adiponectin-stimulated APPL1 phosphorylation, which is greatly reduced in insulin target tissues in obese mice. appl1 deletion in mice consistently leads to systemic insulin resistance and a significant reduction in insulin-stimulated IRS1/2, but not IR, tyrosine phosphorylation, indicating that APPL1 sensitizes insulin signaling by acting at a site downstream of the IR. Our study uncovers a mechanism regulating insulin signaling and crosstalk between the insulin and adiponectin pathways.
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Insulin receptor substrate
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Insulin receptor substrate
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IRS2
Insulin receptor substrate
IRS1
GRB10
Phosphotyrosine-binding domain
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Insulin receptor substrate
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The receptor-type protein-tyrosine phosphatase LAR (for leukocyte common antigen-related) has been implicated as a physiological regulator of the insulin receptor. To demonstrate a functional interaction between LAR and the insulin receptor, we incubated CHO cells overexpressing the human insulin receptor with an antibody to the extracellular domain of LAR and found a 47% decrease in insulin receptor autophosphorylation and kinase activity. A physical association between LAR and the insulin receptor was then shown by immunoprecipitation of LAR from cell lysates and immunoblotting with antibody to the insulin receptor, or vice versa. Up to 11.8% of the LAR protein in the lysates of CHO cells overexpressing both the insulin receptor and LAR co-immunoprecipitated with the insulin receptor. The LAR/insulin receptor association was related to the level of LAR or insulin receptor overexpression and was increased 6.5-fold by chemical cross-linking and 3.9-fold by treatment with insulin, suggesting that receptor activation influences the affinity of LAR for the insulin receptor. In insulin-stimulated rat liver, LAR was temporally enriched in endosomes with the insulin receptor, and incubation of endosomes with neutralizing LAR antibodies decreased insulin receptor dephosphorylation in situ by 28% (p = 0.01 versus control). These data provide more direct evidence of a role for LAR in the physiological regulation of insulin action at the receptor level.
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The insulin receptor is associated with a protein kinase activity. This has been shown for the receptor of liver, fat, and some other tissues which are not primary targets of insulin action. Here kinase activity is demonstrated for the insulin receptor of rat skeletal and cardiac muscle with similar characteristics. Insulin (10(-7) mol/l) stimulates phosphorylation of the 95-kDa receptor subunit 3- to 18-fold. The effect is detectable at 10(-10) mol/l insulin; the ED50 is approx. 3 X 10(-9) mol/l. The kinase phosphorylates exogenous substrate as well, and it is recovered after immunoprecipitation of the receptor with antireceptor antibody suggesting that kinase activity is intrinsic to the muscle receptor.
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Grb10 has been proposed to inhibit or activate insulin signaling, depending on cellular context. We have investigated the mechanism by which full-length hGrb10gamma inhibits signaling through the insulin receptor substrate (IRS) proteins. Overexpression of hGrb10gamma in CHO/IR cells and in differentiated adipocytes significantly reduced insulin-stimulated tyrosine phosphorylation of IRS-1 and IRS-2. Inhibition occurred rapidly and was sustained for 60 min during insulin stimulation. In agreement with inhibited signaling through the IRS/PI 3-kinase pathway, we found hGrb10gamma to both delay and reduce phosphorylation of Akt at Thr(308) and Ser(473) in response to insulin stimulation. Decreased phosphorylation of IRS-1/2 may arise from impaired catalytic activity of the receptor, since hGrb10gamma directly associates with the IR kinase regulatory loop. However, yeast tri-hybrid studies indicated that full-length Grb10 blocks association between IRS proteins and IR, and that this requires the SH2 domain of Grb10. In cells, hGrb10gamma inhibited insulin-stimulated IRS-1 tyrosine phosphorylation in a dose-dependent manner, but did not affect IR catalytic activity toward Tyr(972) in the juxtamembrane region and Tyr(1158/1162/1163) in the regulatory domain. We conclude that binding of hGrb10gamma to IR decreases signaling through the IRS/PI 3-kinase/AKT pathway by physically blocking IRS access to IR.
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Insulin receptor substrates (IRS) mediate biological actions of insulin, growth factors, and cytokines. All four mammalian IRS proteins contain pleckstrin homology (PH) and phosphotyrosine binding (PTB) domains at their N termini. However, the molecules diverge in their C-terminal sequences. IRS3 is considerably shorter than IRS1, IRS2, and IRS4, and is predicted to interact with a distinct group of downstream signaling molecules. In the present study, we investigated interactions of IRS3 with various signaling molecules. The PTB domain of mIRS3 is necessary and sufficient for binding to the juxtamembrane NPXpY motif of the insulin receptor in the yeast two-hybrid system. This interaction is stronger if the PH domain or the C-terminal phosphorylation domain is retained in the construct. As determined in a modified yeast two-hybrid system, mIRS3 bound strongly to the p85 subunit of phosphatidylinositol 3-kinase. Although high affinity interaction required the presence of at least two of the four YXXM motifs in mIRS3, there was not a requirement for specific YXXM motifs. mIRS3 also bound to SHP2, Grb2, Nck, and Shc, but less strongly than to p85. Studies in COS-7 cells demonstrated that deletion of either the PH or the PTB domain abolished insulin-stimulated phosphorylation of mIRS3. Insulin stimulation promoted the association of mIRS3 with p85, SHP2, Nck, and Shc. Despite weak association between mIRS3 and Grb2, this interaction was not increased by insulin, and may not be mediated by the SH2 domain of Grb2. Thus, in contrast to other IRS proteins, mIRS3 appears to have greater specificity for activation of the phosphatidylinositol 3-kinase pathway rather than the Grb2/Ras pathway.
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High glucose (HG) has been shown to induce insulin resistance in both type 1 and type 2 diabetes. However, the molecular mechanism behind this phenomenon is unknown. Insulin receptor substrate (IRS) proteins are the key signaling molecules that mediate insulin’s intracellular actions. Genetic and biological studies have shown that reductions in IRS1 and/or IRS2 protein levels are associated with insulin resistance. In this study we have shown that proteasome degradation of IRS1, but not of IRS2, is involved in HG-induced insulin resistance in Chinese hamster ovary (CHO) cells as well as in primary hepatocytes. To further investigate the molecular mechanism by which HG induces insulin resistance, we examined various molecular candidates with respect to their involvement in the reduction in IRS1 protein levels. In contrast to the insulin-induced degradation of
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Abstract ID 99316 Poster Board 359 Prior studies have investigated the impact of palmitate treatment on insulin resistance and posttranslational modification of the key insulin signaling molecules. Exposure to sodium palmitate can lead to the alteration of insulin-stimulated phosphorylation of key insulin signaling molecules like insulin receptor (IR), insulin receptor substrate-1 (IRS1), insulin receptor substrate-2 (IRS2), and Protein kinase B (Akt). Our previous study demonstrated that the global ubiquitin linkage profile is altered upon insulin and glucagon treatment. We hypothesized that ubiquitination of key insulin signaling molecules is a potential mechanism by which palmitate induces insulin resistance, and the inhibition of ubiquitination can be a potential strategy for preventing and treating insulin resistance and diabetes. We investigated the IRS1 and IRS2 upon palmitate treatment in HepG2 cells. We treated HepG2 cells with or without sodium palmitate for 24 hours and probed the cell lysates for the levels of IR, IRS1, IRS2, and Akt, and their respective phosphoprotein levels. In addition, we studied the ubiquitination profile of endogenous and transiently overexpressed proteins. Linkage-specific K63, K48, and total ubiquitin antibodies showed significant alterations in the linkage profile of insulin-signaling proteins. The effect of palmitate on the ubiquitination of IRS1/2 is implicated in the development of insulin resistance; thus, revealing a connection between impaired ubiquitination equilibrium and insulin resistance. Therefore, characterizing the molecular mechanisms of impaired insulin action may reveal new therapeutic targets for diabetes. Keywords: HepG2, insulin resistance, ubiquitination, ubiquitin linkages, IRS Akt, diabetes
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