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Genetic Control of Non-Autonomous Survival in Drosophila

果蝇非自主生存的遗传控制

基本信息

批准号：
8367119
负责人：
ANDREAS BERGMANN
金额：
$ 10.98万
依托单位：
UNIV OF MASSACHUSETTS MED SCH WORCESTER
依托单位国家：
美国
项目类别：
财政年份：
2007
资助国家：
美国
起止时间：
2007-09-01 至 2012-07-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8367119
关键词：
Genetic Control Non Autonomous Survival

项目摘要

DESCRIPTION (provided by applicant): Cell/cell communication controls many aspects of cellular physiology including cell proliferation, cell differentiation and cell death/survival. However, the complexity of multi-cellular organisms has made it difficult to obtain a comprehensive understanding of all extracellular signaling mechanisms controlling these aspects. This research project focuses on the control of cell survival by extracellular, or non-autonomous, signaling. We have identified mutants in tumor-suppressor-like genes that control the secretion of extra-cellular factors which promote the survival of neighboring cells. These studies reveal interactions between cells which are very relevant for tissue homeostasis, and abnormalities may be directly linked to the parthenogenesis of human diseases including cancer. For example, animals containing mutant clones of these tumor suppressor-like genes are characterized by tissue overgrowth and tumor-like masses. In some of these mutants, Notch activity is inappropriately activated which stimulates proliferation and survival in a non-autonomous manner. Inappropriate Notch activation has been implicated for the genesis of many human cancers. Our data demonstrate that cell proliferation is not sufficient for generation of the tumor masses; instead increased cell survival is necessary for full development of tumors. Therefore, an understanding of the genetic and molecular mechanisms that control non-autonomous cell survival is crucial for the prevention and treatment of these diseases. It is the main goal of this proposal to further our understanding about the mechanisms that regulate non-autonomous survival. For this purpose, we are using the highly accessible genetic model organism Drosophila melanogaster. Our specific aims are: 1. Identify the genes in the signal-sending cell that control non-autonomous cell survival. 2. Identify the mechanisms which lead to secretion of signaling molecules that control cell survival in neighboring cells. 3. Identify the signals and the mechanisms in the signal-receiving cell that control non-autonomous survival. This project will be the first systematic approach to identify all genes and mechanisms that control non- autonomous survival in any organism. The characterization of these genes may have significant implications for the understanding of human diseases, and may help developing drugs and therapies to treat these diseases.

描述（由申请人提供）：细胞/细胞通讯控制着细胞生理学的许多方面，包括细胞增殖，细胞分化和细胞死亡/存活。然而，多细胞生物的复杂性使得很难全面了解控制这些方面的所有细胞外信号传导机制。本研究项目的重点是通过细胞外或非自主信号传导控制细胞存活。我们已经确定了肿瘤抑制样基因的突变，这些基因控制促进邻近细胞存活的细胞外因子的分泌。这些研究揭示了细胞之间的相互作用与组织稳态非常相关，异常可能与包括癌症在内的人类疾病的孤雌生殖直接相关。例如，含有这些肿瘤抑制样基因的突变克隆的动物的特征是组织过度生长和肿瘤样肿块。在这些突变体中，Notch活性被不适当地激活，以非自主的方式刺激增殖和存活。不适当的Notch激活与许多人类癌症的发生有关。我们的数据表明，细胞增殖不足以产生肿瘤肿块；相反，增加细胞存活率是肿瘤完全发展所必需的。因此，了解控制非自主细胞存活的遗传和分子机制对于预防和治疗这些疾病至关重要。这一建议的主要目标是进一步了解调节非自主生存的机制。为此，我们使用了高度可接近的遗传模式生物黑腹果蝇。我们的具体目标是：1。识别信号发送细胞中控制非自主细胞存活的基因。2. 确定导致邻近细胞分泌控制细胞存活的信号分子的机制。3. 识别信号接收细胞中控制非自主存活的信号和机制。这个项目将是第一个系统的方法来确定所有的基因和机制，控制非自主生存的任何生物体。这些基因的特征可能对理解人类疾病具有重要意义，并可能有助于开发治疗这些疾病的药物和疗法。