The role of Retinoic Acid Induced 1 (Rai1) in neural network stability

视黄酸诱导 1 (Rai1) 在神经网络稳定性中的作用

• 批准号: RGPIN-2020-04094
• 负责人: Huang, WeiHsiang
• 金额: $ 2.99万
• 依托单位: McGill University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=761343
• 关键词: role; Retinoic; Acid; Induced; Rai1

The brain has the remarkable capacity to be flexible and stable at the same time. This allows us to learn new information while maintaining brain excitability within an operating range. At the cellular level, the brain uses several mechanisms to regulate activity homeostasis, including intrinsic membrane excitability, synaptic transmission, and dendritic morphology. At the network level, the brain uses synaptic scaling to globally normalize synaptic strength. Transcriptional programs have recently emerged as an important player in regulating activity homeostasis. However, how the brain simultaneously controls these processes by transcriptional mechanisms is not fully understood. The long-term objective of my research program is to elucidate the transcriptional mechanism by which the brain maintains homeostatic activity on molecular, cellular, and circuit levels. To achieve this goal, our short-term objective will study how a transcription factor, Retinoic acid induced 1 (Rai1), regulates brain network stability. Neural loss of Rai1 increases brain excitability in mice, suggesting that Rai1 regulates activity homeostasis of the brain. Our preliminary data found a group of excitatory neurons in the hippocampus, the dentate gyrus granule cells (dGCs), are hyperactivated in the absence of Rai1. How Rai1 controls dGCs excitability, morphology, synaptic plasticity, and gene expression is unknown. In this Discovery Research Program, we will use the dGCs as a model to study how Rai1, a transcription factor located in the nucleus, regulates the stability of network activity by coupling intrinsic excitability, homeostatic plasticity, neuronal morphology, and activity-dependent gene expression. This grant will create a new level of understanding of transcriptional mechanisms that control network homeostasis within the brain. Moreover, it will provide excellent conceptual and technical opportunities for trainees to use advanced bioinformatics, morphometric analysis, single cell analysis, and electrophysiology tools while discovering fundamental aspects of brain function and homeostasis.

大脑具有同时保持灵活性和稳定性的非凡能力。这使我们能够学习新信息，同时将大脑的兴奋性保持在一个操作范围内。在细胞水平，大脑使用几种机制来调节活动稳态，包括内在膜兴奋性，突触传递和树突形态。在网络层面，大脑使用突触缩放来全局规范化突触强度。转录程序最近已成为一个重要的球员在调节活动的稳态。然而，大脑如何通过转录机制同时控制这些过程尚未完全了解。我的研究计划的长期目标是阐明大脑在分子，细胞和电路水平上维持稳态活动的转录机制。 为了实现这一目标，我们的短期目标将研究转录因子视黄酸诱导1（Rai1）如何调节大脑网络的稳定性。Rai1的神经缺失增加了小鼠的大脑兴奋性，表明Rai1调节大脑的活动稳态。我们的初步数据发现，海马中的一组兴奋性神经元，齿状回颗粒细胞（dGC），在Rai1的情况下被过度激活。Rai1如何控制dGC的兴奋性、形态、突触可塑性和基因表达尚不清楚。 在这项发现研究计划中，我们将使用dGC作为模型来研究位于细胞核中的转录因子Rai1如何通过耦合内在兴奋性，稳态可塑性，神经元形态和活性依赖性基因表达来调节网络活动的稳定性。这项资助将创造一个新的水平的理解转录机制，控制网络内的大脑稳态。此外，它将为学员提供良好的概念和技术机会，使用先进的生物信息学，形态分析，单细胞分析和电生理学工具，同时发现大脑功能和稳态的基本方面。