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SWI/SNF-related complex in osteoblast differentiation

成骨细胞分化中 SWI/SNF 相关复合物

基本信息

批准号：
7668391
负责人：
Elizabeth Moran
金额：
$ 28.8万
依托单位：
UNIV OF MED/DENT OF NJ-NJ MEDICAL SCHOOL
依托单位国家：
美国
项目类别：
财政年份：
2006
资助国家：
美国
起止时间：
2006-03-01 至 2012-08-31
项目状态：
已结题

项目摘要

DESCRIPTION (provided by applicant): Mammalian SWI/SNF-related complexes are required for tissue specific gene expression. The components of these complexes are evolutionarily conserved, and were first identified in yeast, where they are required for the changes in gene expression that mediate the mating type switch (SWI) and the ability to switch to sucrose utilization in the absence of glucose (Sucrose-Non-Fermentors). The complexes contain a DNA-dependent ATPase activity that powers a nucleosome remodeling function, which in turn allows transcription factor access to promoter sites. The yeast complexes have been the target of extensive genetic analysis, and considerable work has been done to address the mechanisms of nucleosome remodeling by yeast and mammalian complexes, but surprisingly little is known about the biological role of the complex and its individual components in the differentiation of mammalian cells. What is known is that abrogation of the ATPase activity of the complex blocks normal differentiation function in a range of tissue types. The ATPase is the molecular motor of the complex and is, of course essential to its function, but the complexes contain seven or more other components that are believed to modulate the activity of the complex in response to specific signals, particularly in response to hormones. Very limited information is available on the biological role of these modulatory, non-catalytic, subunits. Elucidation of their roles would give much-needed insight into how the complexes achieve specificity of function in precisely regulated metabolic processes. This project therefore proposes the development of differentiation models in which specific complex components will be depleted individually within a single biological system. The resulting phenotypes will indicate the biological roles of the individual subunits. The differentiation models will be developed in a pre-osteoblast line because these cells are responsive to multiple extracellular signals and have a highly regulated and sequential differentiation program that is well-characterized and includes cell cycle regulation. The proposed systems will provide important clinical data, relevant to broad public health problems, such as osteoporosis and inflammatory diseases, as well as to cancer.

描述（由申请人提供）：哺乳动物SWI/ snf相关复合物需要用于组织特异性基因表达。这些复合物的组成部分在进化上是保守的，它们首先在酵母中被发现，在酵母中，它们是介导交配类型转换（SWI）和在缺乏葡萄糖的情况下切换到蔗糖利用能力的基因表达变化所必需的（蔗糖非发酵）。该复合物含有dna依赖的atp酶活性，该活性为核小体重塑功能提供动力，从而允许转录因子进入启动子位点。酵母复合体一直是广泛的遗传分析的目标，并且已经做了大量的工作来解决酵母和哺乳动物复合体的核小体重塑机制，但令人惊讶的是，关于复合体及其单个成分在哺乳动物细胞分化中的生物学作用知之甚少。我们所知道的是，atp酶活性的取消阻碍了一系列组织类型的正常分化功能。atp酶是复合体的分子马达，当然对复合体的功能至关重要，但复合体含有七种或更多的其他成分，这些成分被认为可以调节复合体的活性，以响应特定的信号，特别是对激素的反应。关于这些调节的、非催化的亚基的生物学作用的信息非常有限。阐明它们的作用将为了解这些复合物如何在精确调节的代谢过程中实现功能特异性提供急需的见解。因此，该项目提出了分化模型的发展，其中特定的复杂成分将在单个生物系统中单独耗尽。由此产生的表型将表明单个亚基的生物学作用。分化模型将在成骨前细胞系中发展，因为这些细胞对多种细胞外信号有反应，并且具有高度调控的顺序分化程序，该程序具有良好的特征，包括细胞周期调节。拟议的系统将提供重要的临床数据，涉及广泛的公共卫生问题，如骨质疏松症和炎症性疾病，以及癌症。