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Hedgehog-mediated regulation of cell adhesion

Hedgehog 介导的细胞粘附调节

基本信息

批准号：
8601943
负责人：
Xiaoyan Zheng
金额：
$ 24.2万
依托单位：
GEORGE WASHINGTON UNIVERSITY
依托单位国家：
美国
项目类别：
财政年份：
2013
资助国家：
美国
起止时间：
2013-01-01 至 2015-12-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8601943
关键词：
Adhesions Adhesiveness Adhesives Affect Affinity Animals Anterior Binding Biochemical Biological Brothers Cell Adhesion Cell Adhesion Molecules Cell Aggregation Cell Separation Cell surface Cells Cultured Cells Development Drosophila genus Enhancers Erinaceidae Fibronectins Genes Genetic Genetic Models Genetic Screening Goals Growth Homologous Gene Human Immunoglobulins Lead Light Malignant - descriptor Malignant Neoplasms Mediating Methods Molecular Molecular Profiling Neoplasm Metastasis Oncogenes Pattern Population Positioning Attribute Process Property Protein Family Proteins Refractory Regulation Shapes Signal Transduction System Techniques Time Tissues To specify Wing base cancer cell gain of function imaginal disc in vivo morphogens new therapeutic target paracrine promoter receptor receptor internalization research study response segregation smoothened signaling pathway tumor growth tumor progression

项目摘要

Tissue patterning in animal development requires adhesive mechanisms that promote and maintain physical segregation of different cell populations. Many paracrine morphogen signals have been proposed to specify the differences in cell affinity and the formation of sharp and stable boundaries which, in turn, serve to maintain the position and shape of morphogen organizers during the growth of a tissue. The long-term goal of this project is to understand the cellular and molecular mechanisms by which the Hedgehog (Hh) signal defines specific cell affinities and lead to the segregation of Hh-secreting (non-responding) cells and Hh-responding (non-secreting) cells. Increasing evidence indicates that Hh secreted by certain human cancer cells may signal to surrounding tissue and promote tumor growth and metastasis. Furthermore, malignant invasion might be considered a normal process of cell segregation in reverse, in which there is cross-adhesion between cancer cells and tissue cells. Therefore, this study will not only contribute significantly to our knowledge of the molecular and cellular bases of tissue patterning and further understanding of the Hh signal pathway, per se, but will also shed light on the mechanisms of cancer progression, perhaps leading to the discovery of new therapeutic targets in cancers. The Drosophila wing imaginal disc is subdivided into an anterior (A) and a posterior (P) compartment. P cells secrete Hh and, at the same time, are refractory to the Hh signal. In contrast, A cells can receive and respond to Hh, but do not express Hh by themselves. The cells of the two compartments do not intermingle during development. However, A cells unable to respond to the Hh signal no longer segregate from P cells. The current view is that the response to the Hh signal induces a change in the adhesiveness and that this difference leads to the segregation of A cells from P cell. Combining this model genetic system with broad experimental approaches that incorporate powerful biochemical, molecular and cellular techniques, I propose: 1) To investigate how the Hh signal directly alters the affinity differences between Hh-secreting P cells and Hh- responding A cells by modulating cell surface levels of the Ihog family proteins. 2) To identify additional cell adhesion molecules involved in regulating A/P cell segregation. 3) To investigate whether and how the Shh signal alters cell affinity by regulating expression levels of the vertebrate Ihog homologues.

动物发育中的组织模式化需要粘附机制来促进和维持不同细胞群体的物理分离。许多旁分泌形态发生信号已被提出，指定细胞亲和力的差异以及尖锐和稳定边界的形成，反过来，在组织生长过程中保持形态原组织者的位置和形状。的长期目标本项目旨在了解Hedgehog（Hh）信号定义的细胞和分子机制特定的细胞亲和力，并导致分离的Hh分泌（非响应）细胞和Hh响应（非分泌）细胞。越来越多的证据表明，某些人类癌细胞分泌的Hh可能发出信号，并促进肿瘤生长和转移。此外，恶性侵袭可能是被认为是一个正常的细胞分离过程，在反向，其中有交叉粘附之间的癌症细胞和组织细胞。因此，这项研究不仅将大大有助于我们了解组织模式的分子和细胞基础以及对Hh信号通路本身的进一步理解，而且还将揭示癌症进展的机制，也许会导致新的发现癌症的治疗靶点。果蝇翅的成虫盘分为前室（A）和后室（P）。P 细胞分泌Hh，同时对Hh信号不敏感。相反，A细胞可以接收和对Hh有反应，但自己不表达Hh。两个隔室的细胞不混合在发展过程中。然而，不能对Hh信号作出反应的A细胞不再与P细胞分离。目前的观点是，对Hh信号的响应引起了α的变化，这差异导致A细胞与P细胞分离。将该模型遗传系统与广泛的结合强大的生物化学，分子和细胞技术的实验方法，我建议： 1)为了研究Hh信号如何直接改变分泌Hh的P细胞和分泌Hh的P细胞之间的亲和力差异，通过调节Ihog家族蛋白的细胞表面水平来应答A细胞。2)识别其他单元格粘附分子参与调节A/P细胞分离。3)为了调查是否以及如何嘘信号通过调节脊椎动物Ihog同源物的表达水平来改变细胞亲和力。