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Insulin Signaling in a Cell-Free System

无细胞系统中的胰岛素信号传导

基本信息

批准号：
6919073
负责人：
MIKE M MUECKLER
金额：
$ 28.23万
依托单位：
WASHINGTON UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2005
资助国家：
美国
起止时间：
2005-03-01 至 2009-02-28
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/6919073
关键词：
adipocytes cell free system cytoskeleton enzyme mechanism enzyme structure hormone regulation /control mechanism insulin insulin receptor matrix assisted laser desorption ionization phosphatidylinositol 3 kinase phosphorylation protein isoforms protein localization serine threonine protein kinase

项目摘要

Insulin action has been the subject of intense investigation for several decades. Interest in this field has been stimulated by an appreciation of the role of aberrant insulin signaling in several common metabolic disorders, including non-insulin-dependent diabetes mellitus and obesity. Although much progress has been made in understanding insulin signaling at the molecular level, many details remain unknown because of the unusual complexity of the effects of this hormone. Rather than corresponding to a simple series of linear pathways, insulin signaling can more accurately be characterized as a four-dimensional web of interacting molecules, involving coordinates in both space and time. Because of this complexity, it has been suggested that many important aspects of insulin signaling may only be unraveled via the use of cell-free systems that accurately reproduce various segments of the in vivo signaling cascades. The long-term goal of this proposal is to elucidate the molecular signaling cascades involved in the major metabolic effects of insulin in adipocytes. In order to facilitate the accomplishment of this goal, we have recently developed a novel cell-free system from 3T3L1 adipocytes to investigate insulin signaling. This system faithfully reconstitutes the PI 3-kinase signaling cascade from receptor autophosphorylation to events downstream of Akt activation, including the phosphorylation of GSK-3. We propose to further refine this cell-free system and to utilize it to pursue the following specific aims: 1) Akt is a serine kinase that plays a pivotal role in the PI3-kinase-dependent signaling pathway. It is activated by dual phosphorylations at a threonine and a serine residue. The threonine phoshorylation is catalyzed by PDK1, a well-characterized serine/threonine kinase, however, the serine kinase has not yet been identified. We have isolated a novel cytoskeletal subcellular fraction associated with adipocyte plasma membranes that is enriched approximately 1000-fold in PDK2 activity relative to total cellular homogenates. We propose to further enrich PDK2 activity from this fraction, identify the kinase using MALDI-TOF mass spectrometry, and then to clone and characterize the enzyme. 2) IRS-1 and IRS-2 are the major docking molecules that link the activated insulin receptor to the PI3-kinase signaling pathway. Current evidence suggests that IRS-1 and IRS-2 play distinct roles in the metabolic effects of insulin, but little is known about the mechanism by which these two IRS isoforms might mediate divergent signaling events. One hypothesis suggests that IRS-1 and IRS-2 promulgate distinct signaling outcomes by means of differential subcellular localization. Consistent with this hypothesis, we have observed that IRS-2, but not IRS-1, is highly enriched in the same plasma membrane-associated cytoskeletal fraction that contains the bulk of cellular PDK2 activity. Additionally, data obtained using our cell-free signaling assay indicate that Akt activation is dependent on plasma embrane-associated IRS-1, and that IRS-2 and cytosolic IRS-1 do not play a role in this process. Our second aim is to further characterize the novel PDK2/IRS-2-containing subcellular fraction and to determine the molecular basis and functional significance of IRS-2 targeting to the corresponding cellular compartment.

几十年来，胰岛素作用一直是深入研究的主题。人们对异常胰岛素信号在几种常见代谢性疾病（包括非胰岛素依赖性糖尿病和肥胖症）中的作用的认识激发了人们对这一领域的兴趣。尽管在分子水平上理解胰岛素信号传导方面已经取得了很大进展，但由于这种激素的作用异常复杂，许多细节仍然未知。胰岛素信号传导不是对应于一系列简单的线性途径，而是可以更准确地描述为相互作用分子的四维网络，涉及空间和时间的坐标。由于这种复杂性，有人认为胰岛素信号传导的许多重要方面可能只能通过使用无细胞准确再现体内信号级联的各个部分的系统。该提案的长期目标是阐明脂肪细胞中胰岛素主要代谢效应所涉及的分子信号级联。为了促进这一目标的实现，我们最近开发了一种新型的无细胞系统，从 3T3L1 脂肪细胞到研究胰岛素信号传导。该系统忠实地重建了从受体自身磷酸化到 Akt 激活下游事件（包括 GSK-3 磷酸化）的 PI 3 激酶信号级联。我们建议进一步完善这个无细胞系统，并利用它来实现以下具体目标： 1) Akt 是一种丝氨酸激酶，在 PI3 激酶依赖性信号通路中发挥关键作用。它通过苏氨酸和丝氨酸残基的双重磷酸化而被激活。苏氨酸磷酸化由 PDK1 催化，PDK1 是一种已充分表征的丝氨酸/苏氨酸激酶，然而，丝氨酸激酶尚未被鉴定。我们分离出一种与脂肪细胞质膜相关的新型细胞骨架亚细胞部分，其 PDK2 活性相对于总细胞匀浆富集约 1000 倍。我们建议进一步富集该组分中的 PDK2 活性，使用 MALDI-TOF 质谱法鉴定激酶，然后克隆和表征该酶。 2) IRS-1和IRS-2是将激活的胰岛素受体与PI3激酶信号通路连接起来的主要对接分子。目前的证据表明，IRS-1 和 IRS-2 在胰岛素的代谢作用中发挥着不同的作用，但人们对这两种 IRS 亚型可能介导不同信号事件的机制知之甚少。一种假设表明，IRS-1 和 IRS-2 通过差异亚细胞定位来传达不同的信号结果。与这一假设一致，我们观察到 IRS-2（而非 IRS-1）在含有大量细胞 PDK2 活性的相同质膜相关细胞骨架部分中高度富集。此外，使用我们的无细胞信号转导测定获得的数据表明 Akt 激活依赖于血浆膜相关的 IRS-1，并且 IRS-2 和胞质 IRS-1 在此过程中不起作用。我们的第二个目标是进一步表征含有 PDK2/IRS-2 的新型亚细胞部分，并确定 IRS-2 靶向相应细胞区室的分子基础和功能意义。