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Sec61 and ER Stress in Beta-cell Function and Type 2 Diabetes

β 细胞功能和 2 型糖尿病中的 Sec61 和 ER 应激

基本信息

批准号：
8059732
负责人：
Nicholas Gekakis
金额：
$ 32.57万
依托单位：
SCRIPPS RESEARCH INSTITUTE, THE
依托单位国家：
美国
项目类别：
财政年份：
2009
资助国家：
美国
起止时间：
2009-07-01 至 2013-04-30
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8059732
关键词：
Affect Age Animals Apoptosis Autopsy Beta Cell Candidate Disease Gene Cell Death Cell physiology Cells Data Defect Development Diabetes Mellitus Diabetic mouse Electron Microscopy Endoplasmic Reticulum Failure Family Functional disorder Genes Genetic Genetic Predisposition to Disease Genetic Screening Health Human Human Genetics Insulin Resistance Lead Literature Maps Molecular Chaperones Mus Mutant Strains Mice Mutation Nature Non-Insulin-Dependent Diabetes Mellitus Oxidative Stress Pancreas Peripheral Pharmaceutical Preparations Phenotype Play Process Prospective Studies Protein Import Protein translocation Proteins Relative (related person)Role Stress Syndrome Testing Tissues Up-Regulation Yeasts cell type cytokine design diabetic endoplasmic reticulum stress genome wide association study insulin secretion mouse model mutant neonatal diabetes mellitus novel protein folding research study response transcription factor

项目摘要

DESCRIPTION (provided by applicant): In a phenotype-driven, genetic screen to identify novel genes that affect ¿-cell function, we found a mutation in Sec61a1 in a family of mice with diabetes. Sec61a1 encodes the protein conducting subunit of the endoplasmic reticulum (ER) translocation channel, which is responsible for protein import into the ER. Diabetes in Sec61a1 mutant mice is correlated with ¿-cell apoptosis and massively distended ER. The distended ER is consistent with ER stress, an accumulation of unfolded proteins within the ER. The cell mounts a response to ER stress, the unfolded protein response, which includes up regulation of protein folding chaperones (e.g. Bip), and, in the case that ER stress cannot be relieved, up regulation of the proapoptotic transcription factor Chop. Bip and Chop are both up regulated in diabetic Sec61a1 mutant animals. Thus, our hypothesis is that Sec61a1 mutation leads to ER stress, ¿-cell apoptosis, and diabetes. The experiments in this proposal are designed to test this hypothesis, to understand the mechanism by which Sec61a1 mutation leads to ER stress, and to ask if ER stress plays a role in the ¿-cell dysfunction that is part of type 2 diabetes. PUBLIC HEALTH RELEVANCE: The development of type 2 diabetes (T2D) is a two-hit process involving insulin resistance in peripheral tissues and a failure of pancreatic ¿-cells to compensate for insulin resistance by increased insulin secretion. Prospective studies in humans have established the causative role of both insulin resistance and ¿-cell dysfunction in T2D. What is the nature of the ¿-cell failure that accompanies T2D? Autopsy studies have shown that T2D is associated with a relative decrease in ¿-cell mass due to apoptosis, a finding that has been supported in mouse models. There is evidence in the literature to support any of several mechanisms of ¿-cell loss, including oxidative stress, glucotoxicity, lipotoxicity, and cytokine-induced cell death. In these studies we will examine the role of endoplasmic reticulum (ER) stress and ER stress-induced apoptosis in ¿- cell dysfunction. Evidence for a role of ER stress in ¿-cell death comes from human genetic syndromes marked by neonatal diabetes, and various mouse models including a novel mouse model of diabetes from our own lab. Via a forward genetic approach in the mouse, we have identified a family of diabetic mice with a mutation in the ER translocation channel protein Sec61a1. Preliminary data indicate that the mice become diabetic because they lose ¿-cells beginning at about four weeks of age. This loss correlates with an increase in ER stress. The mechanism of ER stress likely relates to a defect in protein processing or degradation due to the Sec6a1 mutation. The studies described herein seek to exploit this and other mouse models of diabetes to answer some fundamental questions about the nature of ¿-cell dysfunction in T2D. How does this mutation in Sec61a1 lead to ER stress, ¿-cell apoptosis, and diabetes and does ER stress play a role in the ¿- cell dysfunction normally seen in T2D? It is hoped that an increased understanding of ¿-cell dysfunction will lead to more effective drugs against T2D.

描述（由申请人提供）：在一个表型驱动的遗传筛选中，我们发现了一个糖尿病小鼠家族的Sec61a1突变，以识别影响细胞功能的新基因。Sec61a1编码内质网（ER）转运通道的蛋白传导亚基，其负责蛋白质输入到ER中。Sec61a1突变小鼠的糖尿病与细胞凋亡和大量扩张的ER相关。膨胀的ER与ER应激一致，ER内未折叠蛋白质的积累。细胞对ER应激产生应答，即未折叠蛋白应答，其包括蛋白折叠伴侣（例如Bip）的上调，以及在ER应激不能被缓解的情况下，促凋亡转录因子Chop的上调。Bip和Chop在糖尿病Sec61a1突变动物中均上调。因此，我们的假设是Sec61a1突变导致ER应激、细胞凋亡和糖尿病。该提案中的实验旨在验证这一假设，了解Sec61a1突变导致ER应激的机制，并询问ER应激是否在2型糖尿病的一部分细胞功能障碍中发挥作用。公共卫生相关性：2型糖尿病（T2D）的发展是一个双重打击的过程，涉及外周组织中的胰岛素抵抗和胰腺细胞无法通过增加胰岛素分泌来补偿胰岛素抵抗。在人类中的前瞻性研究已经确定了胰岛素抵抗和胰岛细胞功能障碍在T2D中的致病作用。T2D伴随的细胞衰竭的性质是什么？尸检研究表明，T2D与细胞凋亡导致的细胞质量相对减少有关，这一发现在小鼠模型中得到了支持。文献中有证据支持任何一种细胞损失机制，包括氧化应激、葡萄糖毒性、脂毒性和精氨酸诱导的细胞死亡。在这些研究中，我们将研究内质网（ER）应激和ER应激诱导的细胞凋亡在细胞功能障碍中的作用。ER应激在细胞死亡中作用的证据来自以新生儿糖尿病为标志的人类遗传综合征，以及各种小鼠模型，包括我们自己实验室的新型糖尿病小鼠模型。通过在小鼠中的正向遗传方法，我们已经确定了一个糖尿病小鼠家族，该家族在ER易位通道蛋白Sec61a1中具有突变。初步数据表明，小鼠患糖尿病是因为它们在大约四周大的时候开始失去细胞。这种损失与ER应力的增加相关。ER应激的机制可能与Sec6a1突变引起的蛋白质加工或降解缺陷有关。本文描述的研究试图利用这种和其他糖尿病小鼠模型来回答关于T2D中细胞功能障碍的性质的一些基本问题。Sec61a1中的这种突变如何导致ER应激、细胞凋亡和糖尿病，ER应激是否在T2D中常见的细胞功能障碍中发挥作用？人们希望，对细胞功能障碍的更多了解将导致更有效的药物对抗T2D。