Microfluidic Temperature Steps Robustness of Embryonic Development

微流体温度影响胚胎发育的稳健性

• 批准号: 7077973
• 负责人: RUSTEM F ISMAGILOV
• 金额: $ 17.93万
• 依托单位: UNIVERSITY OF CHICAGO
• 依托单位国家: 美国
• 财政年份: 2006
• 资助国家: 美国
• 起止时间: 2006-04-01 至 2010-03-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7077973
• 关键词: Drosophilidae; fluid flow; invertebrate embryology; microfluidics; microscopy; temperature

DESCRIPTION (provided by applicant): Project summary. This proposal describes a multi-disciplinary research program that aims to develop, validate and disseminate microfluidic technology to allow development of a live Drosophila embryo to be controlled in space and time using temperature steps. The process of Drosophila embryo development is robust - it works precisely even under varying environmental conditions such as temperature. While the function of many individual molecules present in Drosophila development is known, it is unknown how these molecules work together to make developmental network robust. New microfluidic technology that can differentially control temperature around different parts a living embryo could become a powerful tool in determining the mechanisms responsible for this robustness of development. Specific Aim 1 focuses on development of new microfluidic technology that will use laminar flow to create a sharp temperature step around the embryo, where one part of the embryo will develop at the warmer temperature of one laminar stream, and the other part of the embryo will develop at the cooler temperature of the second laminar stream. The temperature profile at the surface of the embryo will be quantitatively characterized using numerical simulations and confocal microscopy. Real-time imaging of an embryo being exposed to temperature step is critical in identifying dynamic processes such as changes in protein concentration as a function of time. Specific Aim 2 adapts technology developed in Specific Aim 1 to DIG and 2-photon microscopy in order to image embryonic development in the temperature step in real time. Proposed research in Specific Aim 3 will validate the microfluidic technology developed in Specific Aim 1 and Specific Aim 2 by answering four important questions concerning the mechanism of robustness, both at the molecular level and at the level of nuclear divisions. Relevance: Understanding development is essential for understanding of human diseases and conditions caused by defects and errors in developmental and differentiation pathways (such as cancer and aging). Studying development in model organisms, in particular, the fruit fly Drosophila melanogaster leads to a better understanding of human development, since many parts of the basic machinery of development are similar among organisms. The microfluidic technology developed in this proposal will enable understanding of the mechanism that provides error-free operation of developmental network in the fruit fly Drosophila melanogaster, and this technology will be extendable to testing and understanding errors in development of other model organisms

描述（由申请人提供）：项目概述。该提案描述了一个多学科的研究项目，旨在开发、验证和传播微流体技术，使果蝇胚胎的发育能够在空间和时间上通过温度步骤进行控制。果蝇胚胎的发育过程是稳健的——即使在温度等不同的环境条件下，它也能精确地工作。虽然已知果蝇发育中存在的许多单个分子的功能，但尚不清楚这些分子如何共同作用以使发育网络强大。新的微流体技术可以对活胚胎不同部位的温度进行差异化控制，这可能成为确定这种健壮性发育机制的有力工具。具体目标1侧重于开发新的微流体技术，该技术将利用层流在胚胎周围创造一个尖锐的温度步骤，其中胚胎的一部分将在一个层流的较热温度下发育，而胚胎的另一部分将在第二个层流的较冷温度下发育。胚胎表面的温度分布将使用数值模拟和共聚焦显微镜进行定量表征。胚胎暴露于温度步骤的实时成像对于识别动态过程（如蛋白质浓度随时间的变化）至关重要。特异性Aim 2将特异性Aim 1中开发的技术应用于DIG和双光子显微镜，以便在温度步骤中实时成像胚胎发育。在Specific Aim 3中提出的研究将通过在分子水平和核分裂水平上回答关于鲁棒性机制的四个重要问题来验证在Specific Aim 1和Specific Aim 2中开发的微流控技术。相关性：理解发育对于理解由发育和分化途径中的缺陷和错误（如癌症和衰老）引起的人类疾病和状况至关重要。研究模式生物的发育，特别是果蝇黑腹果蝇，可以更好地理解人类的发育，因为生物之间发育的基本机制的许多部分是相似的。本课题开发的微流控技术将有助于了解果蝇发育网络无差错运行的机制，该技术将扩展到其他模式生物发育错误的测试和理解