Role of DSCAM in the development of motor circuits

DSCAM 在运动电路开发中的作用

• 批准号: RGPIN-2018-06218
• 负责人: Bretzner, Frederic
• 金额: $ 2.11万
• 依托单位: Université Laval
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=712133
• 关键词: Role; DSCAM; development; motor; circuits

Motor control results from the interplay between the brain and the spinal cord. The brain initiates, selects, and plans the appropriate motor program to match environmental constraints, while the spinal cord translates this descending command into motor actions. Critical to motor functions is the formation of neuronal networks in the brain and spinal cord, which depends highly on signaling pathways. Some of these signaling molecules are thought to guide growing axons to their proper targets, while others contribute to the cell positioning across the central nervous system. Using mouse genetics, it is now possible to alter gene expression by genetic deletion or overexpression in the mouse, thus allowing us to broaden and deepen our understanding of signaling molecules crucial to the development of motor circuits. My research program focuses on some of these signaling pathways, such as DSCAM (a cell adherence molecule associated to Down Syndrome). Recently, using mutant mice lacking DSCAM, we have shown that DSCAM is important to locomotor control and postural adjustments, it contributes to the normal development of the spinal locomotor and sensorimotor circuits, as well as the establishment of the motor cortex. My short-term objectives in the current program are to identify and characterize how DSCAM contributes to the formation of cortical, spinal, and sensory circuits important to motor control and locomotion. Using the CRE-LOX technology, we will manipulate DSCAM expression by overexpression or mutation in specific neuronal populations in order to investigate how DSCAM contributes anatomically, physiologically, and functionally to the establishment of supraspinal, spinal, and sensory circuits in the mouse. We will address the following aims: Aim 1: To study the contribution of DSCAM in the development of the motor cortex. Aim 2: To identify and characterize the role of DSCAM in the spinal locomotor circuit. Aim 3: To evaluate the role of DSCAM in the establishment of the spinal sensorimotor circuit. By the completion of the 5-year term of this research, we will have a better understanding of the role of cortical, spinal and sensory DSCAM, and their functional contribution to motor control and locomotion.

运动控制是大脑和脊髓之间相互作用的结果。大脑启动、选择和计划适当的运动程序以匹配环境限制，而脊髓将这种下行命令转化为运动动作。运动功能的关键是大脑和脊髓中神经元网络的形成，这高度依赖于信号通路。其中一些信号分子被认为可以引导生长的轴突到达适当的目标，而另一些则有助于中枢神经系统中的细胞定位。利用小鼠遗传学，现在可以通过小鼠中的基因删除或过度表达来改变基因表达，从而使我们能够扩大和加深对对运动回路发育至关重要的信号分子的理解。 我的研究项目重点关注其中一些信号通路，例如 DSCAM（一种与唐氏综合症相关的细胞粘附分子）。最近，使用缺乏 DSCAM 的突变小鼠，我们发现 DSCAM 对于运动控制和姿势调整很重要，它有助于脊髓运动和感觉运动回路的正常发育，以及运动皮层的建立。 我当前项目的短期目标是确定和描述 DSCAM 如何促进对运动控制和运动很重要的皮质、脊髓和感觉回路的形成。使用 CRE-LOX 技术，我们将通过在特定神经元群体中过度表达或突变来操纵 DSCAM 表达，以研究 DSCAM 如何在解剖学、生理学和功能上对小鼠脊髓上、脊髓和感觉回路的建立做出贡献。我们将实现以下目标： 目标 1：研究 DSCAM 在运动皮层发育中的贡献。 目标 2：识别和表征 DSCAM 在脊髓运动回路中的作用。 目标 3：评估 DSCAM 在建立脊髓感觉运动回路中的作用。 完成这项为期 5 年的研究后，我们将更好地了解皮质、脊髓和感觉 DSCAM 的作用，以及它们对运动控制和运动的功能贡献。