The long term goal of this proposal is to understand the molecular mechanisms of action of insulin. A key question is how the insulin receptor alters the activities and phosphorylation states of protein kinases to exert its ultimate physiological regulatory functions. During the past granting period, we have begun to discover the complex network of protein kinases that are regulated by the insulin receptor to cause its diverse actions. We have used and will continue to use the phosphorylation of ribosomal protein S6 as the probe for pathways, because its extensive phosphorylation is a convenient marker of insulin action. We have traced this pathway backwards two steps from S6 to an insulin-sensitive S6 protein kinase and from it to an insulin-sensitive kinase, ERK1, that phosphorylates and activates the S6 kinase. Recently, we have isolated cDNAs that encode ERK1 and a closely related kinase, ERK2. From Southern analysis and sequencing of other clones, there are may be at least two additional members of this family. To understand the control of this signal transduction pathway, we propose to define each step in the cascade that regulates the S6 kinase as follows. 1. We will identify kinases that activate ERK1. To link ERK1 to the insulin receptor we will determine whether or not the insulin receptor activates it directly or if there are additional intermediates. We have evidence indicating that a soluble kinase activates ERK1, suggesting that the soluble kinase is an intermediate in the pathway for regulation of ERK1. 2. We will identify the sites of phosphorylation on ERK1 and ERK2, because mapping the phosphorylation sites is one means of determining which protein kinase activate ERKs. This information will enable us to correlate the phosphorylation of specific sites on ERK1 and ERK2 with changes in their activities and with the kinases that phosphorylate these sites. 3. We will determine the specificity of the ERKs by testing which of other ERKs activate S6 kinase and what sites on S6 kinase are phosphorylated. 4. We will determine if one or all of the ERKs are insulin-stimulated enzymes and if they are regulated by the same or different mechanisms. These studies will provide important information about early steps in protein kinase cascades triggered by insulin.
Thorne, Curtis A; Chen, Ina W; Sanman, Laura E et al. (2018) Enteroid Monolayers Reveal an Autonomous WNT and BMP Circuit Controlling Intestinal Epithelial Growth and Organization. Dev Cell 44:624-633.e4 |
Guerra, Marcy L; Kalwat, Michael A; McGlynn, Kathleen et al. (2017) Sucralose activates an ERK1/2-ribosomal protein S6 signaling axis. FEBS Open Bio 7:174-186 |
Kalwat, Michael A; Cobb, Melanie H (2017) Mechanisms of the amplifying pathway of insulin secretion in the ? cell. Pharmacol Ther 179:17-30 |
Dyachok, Julia; Earnest, Svetlana; Iturraran, Erica N et al. (2016) Amino Acids Regulate mTORC1 by an Obligate Two-step Mechanism. J Biol Chem 291:22414-22426 |
McReynolds, Andrea C; Karra, Aroon S; Li, Yan et al. (2016) Phosphorylation or Mutation of the ERK2 Activation Loop Alters Oligonucleotide Binding. Biochemistry 55:1909-17 |
Jivan, Arif; Ranganathan, Aarati; Cobb, Melanie H (2010) Reconstitution of the nuclear transport of the MAP kinase ERK2. Methods Mol Biol 661:273-85 |
Duan, Lingling; Cobb, Melanie H (2010) Calcineurin increases glucose activation of ERK1/2 by reversing negative feedback. Proc Natl Acad Sci U S A 107:22314-9 |
Lidke, Diane S; Huang, Fang; Post, Janine N et al. (2010) ERK nuclear translocation is dimerization-independent but controlled by the rate of phosphorylation. J Biol Chem 285:3092-102 |
Lawrence, Michael C; Shao, Chunli; McGlynn, Kathleen et al. (2009) Multiple chromatin-bound protein kinases assemble factors that regulate insulin gene transcription. Proc Natl Acad Sci U S A 106:22181-6 |
Lawrence, Michael C; McGlynn, Kathleen; Shao, Chunli et al. (2008) Chromatin-bound mitogen-activated protein kinases transmit dynamic signals in transcription complexes in beta-cells. Proc Natl Acad Sci U S A 105:13315-20 |
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