GDNF and development of the intestinal nervous system

GDNF 与肠道神经系统的发育

• 批准号: 312246-2010
• 负责人: Blennerhassett, Michael
• 金额: $ 2.83万
• 依托单位: Queen's University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2013
• 资助国家: 加拿大
• 起止时间: 2013-01-01 至 2014-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=526452
• 关键词: GDNF; development; intestinal; nervous; system

Animal models show that the intestine is quite short at birth, but reaches several feet in length in the young adult. In the growing intestine, smooth muscle cells increase in number and are responsible for contraction or relaxation that will propel the intestinal contents appropriately for digestion and absorption of nutrients. These cells require the control of the millions of neurons in the intestinal nervous system in order to do this. These neurons are present at birth and do not increase in number at all, but like neurons in the brain or spinal cord, they must extend long thin processes (axons) to act on other cells by the release of chemicals called neurotransmitters. Working with students that are learning valuable skills in scientific methods, I will study how and why do they do this in the growing intestine. Together, we will investigate the factors that keep this population of nerve cells alive, and that cause them to extend their axons to the right places. In the early embryo, long before birth, studies show that the neurons enter the tube that would become the intestine through following factors that it was making. Called neurotrophins, these can influence target cells only when they make the right molecules that can detect them. We will study whether these same factors continue to be made after birth, by cells in the intestinal wall, and whether neurons continue to be able to respond to them. The major neurotrophin is glia cell line derived neurotrophic factor (or GDNF) since it was first found in glial cells, but is now known to be made by other cell types. We will study how and when it is made, and how affects neurons through use of tissue culture, which is simply a way of keeping cells outside the body for observation and manipulation. This could reveal how the growing intestine makes sure that its vitally important nervous system "grows" right along with it - constantly changing its wiring to be able to control the muscle cells that are so important to intestinal function. This project will increase our knowledge of the natural world, and add to Canada's knowledge-based work force, providing technologists for support of research endevours in many areas and training graduate students that may continue in academia or in industry.

动物模型表明，出生时肠道很短，但在年轻的成年人中达到几英尺长。 在生长的肠道中，平滑肌细胞数量增加，负责收缩或舒张，这将推动肠道内容物适当地消化和吸收营养。 这些细胞需要控制肠神经系统中数百万个神经元才能做到这一点。 这些神经元在出生时就存在，数量根本不会增加，但就像大脑或脊髓中的神经元一样，它们必须延伸细长的过程（轴突），通过释放称为神经递质的化学物质来作用于其他细胞。 与正在学习科学方法中有价值的技能的学生一起工作，我将研究他们如何以及为什么在生长的肠道中这样做。 我们将一起研究使这群神经细胞存活的因素，并使它们将轴突延伸到正确的位置。 在出生前很久的早期胚胎中，研究表明，神经元通过以下因素进入将成为肠道的管道。 这些被称为神经营养素的物质只有在它们产生了能够检测到它们的正确分子时才能影响靶细胞。 我们将研究出生后肠壁细胞是否继续产生这些相同的因素，以及神经元是否继续能够对它们做出反应。 主要的神经营养因子是胶质细胞系衍生的神经营养因子（或GDNF），因为它首先在胶质细胞中发现，但现在已知由其他细胞类型产生。 我们将研究它是如何以及何时制造的，以及如何通过使用组织培养来影响神经元，这只是一种将细胞保持在体外以供观察和操作的方法。 这可以揭示生长中的肠道如何确保其至关重要的神经系统与它一起沿着“生长”--不断改变其线路，以便能够控制对肠道功能如此重要的肌肉细胞。 该项目将增加我们对自然世界的了解，增加加拿大以知识为基础的劳动力队伍，为许多领域的研究工作提供技术支持，并培训可能继续在学术界或工业界工作的研究生。