STEROL SENSING AND TRANSPORT IN A MODEL EUKARYOTE

真核生物模型中的甾醇传感和运输

• 批准号: 6635108
• 负责人: STEPHEN Laurence STURLEY
• 金额: $ 26.52万
• 依托单位: COLUMBIA UNIVERSITY HEALTH SCIENCES
• 依托单位国家: 美国
• 财政年份: 1999
• 资助国家: 美国
• 起止时间: 1999-05-01 至 2004-04-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6635108
• 关键词: Niemann Pick disease; Saccharomyces cerevisiae; biological signal transduction; gene expression; gene mutation; intracellular transport; molecular pathology; protein localization; protein protein interaction; site directed mutagenesis; sterols; yeast two hybrid system

The concentration of intracellular free sterol is strictly regulated to optimize the fluidity and function of all eukaryotic membranes. This homeostasis is imparted by several mechanisms, the crux of which is sensing of sterol and transport of this molecule from sites of synthesis or uptake to intracellular organelles where it can be metabolized or utilized. Aberrations in these processes lead to multiple disease pathologies, including atherosclerosis and Niemann Pick C (NPC) disease. In this project, genetic strategies in yeast will be applied to study sterol transport and sensing as it pertains to human NPC disease. Using a candidate gene approach based on sequence conservation between humans and yeast, we have identified an excellent yeast homolog to the gene defective in Niemann Pick type C disease (NPC1). There are two principle aims to this project. Aim 1 will define the role of the Niemann-Pick C type 1 gene family in intracellular sterol transport. This will test the hypothesis that NPC1 and its yeast homolog, Ncr1, mediate vesicle fusion events and/or act as sterol responsive signal transducers. Molecular, genetic and biochemical approaches including site-directed mutagenesis and sub-cellular protein localization, will be applied. Aim 2 has two components that target pathways that interact in NPC disease to mediate sterol transport and sensing. Firstly, to characterize components of sterol transport pathways by virtue of interactions with the NCR1 gene product that effect normal cell viability. The second component will isolate constituents of the NPC/Ncr-complex to test the hypothesis that key steps in sterol transport and its regulation involve protein-protein interactions. Factors that complex with NCR1 and NPC1 will be identified using the yeast two-hybrid system. The NPC2 gene may arise from this screen. These studies will likely elucidate NPC disease in particular and intracellular sterol transport in general.

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