Essential role of Stasimon in motor circuit development and disease

Stasimon 在运动回路发育和疾病中的重要作用

基本信息

批准号：
10531553
负责人：
Livio Pellizzoni
金额：
$ 58.18万
依托单位：
COLUMBIA UNIVERSITY HEALTH SCIENCES
依托单位国家：
美国
项目类别：
财政年份：
2019
资助国家：
美国
起止时间：
2019-12-01 至 2024-11-30
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/10531553
关键词：
Affect Afferent Neurons Animal Model Behavior Behavioral Biological Assay Breathing Cell model Cells Central Nervous System Cessation of life Data Deafferentation procedure Deglutition Development Disease Event Functional disorder Gene Delivery Gene Mutation Goals Health Homeostasis Human Induced Mutation Inherited Integral Membrane Protein Interneurons Knockout Mice Knowledge Link Lipids Locomotion Mammalian Cell Mediating Mediator Membrane Biology Mitochondria Molecular Morphology Motor Motor Neurons Movement Mus Muscle Mutant Strains Mice Neurobiology Neurodegenerative Disorders Neuromuscular Diseases Neurons Pathogenesis Pathogenicity Pathology Pathway interactions Pattern Peripheral Physiological Process Property Proprioceptor Publishing Regulation Respiration Role SMN deficiency SMN protein (spinal muscular atrophy)Sensory Shapes Site Spinal Spinal Muscular Atrophy Synapses Synaptic Transmission System Systems Development Testing Translating Vertebral column Viral Work brain pathway cell growth regulation cell type cellular targeting conditional knockout design human disease in vivo member mitochondrial membrane motor control motor deficit motor disorder mouse model multidisciplinary neural circuit neuron loss neuronal circuitry neuronal survival novel restoration skeletal muscle wasting spinal reflex synaptic function

项目摘要

Motor circuits control fundamental behaviors such as swallowing, breathing and locomotion. Spinal motor neurons are the key mediators translating motor commands generated within the central nervous system to peripheral muscle targets. Motor neurons are activated by a precisely regulated pattern of synaptic activity from sensory neurons, local spinal interneurons and descending pathways from the brain. Additionally, synaptic activity received by motor neurons during early development shapes their functional properties. In contrast, gene mutations that induce perturbations in either neuronal wiring or synaptic drive received by motor neurons often result in motor system disorders, although the primary cellular targets and the precise molecular events remain largely elusive. Thus, understanding the principles of neural circuit development and function as well as the mechanisms of synaptic dysfunction and selective neuronal death in human disease represent outstanding challenges in neurobiology. A prominent example of this situation is spinal muscular atrophy (SMA)—an inherited neuromuscular disease caused by ubiquitous deficiency in the survival motor neuron (SMN) protein. SMA pathogenesis involves alterations of multiple components of the motor circuit leading to abnormalities in spinal reflexes, motor neuron loss and skeletal muscle atrophy. However, the molecular and cellular mechanisms underlying motor circuit dysfunction in SMA remain poorly understood. In our previous work we have identified Stasimon as a novel transmembrane protein that localizes at contacts sites between ER and mitochondria membranes and contributes to motor dysfunction in animal models of SMA through undefined mechanisms. Furthermore, our preliminary studies revealed that Stasimon’s conditional depletion in neural circuits severely disrupts motor function in mouse models, pointing to an essential requirement for normal motor system development and function. Building on these findings, our goal is to define the neural circuit components and cellular pathway(s) in which Stasimon functions that underlie its essential role in the motor circuit and contribution to human disease. To do so, we will employ newly developed conditional mice for cell type-specific restoration of Stasimon in vivo to study whether Stasimon dysfunction induced by SMN deficiency acts cell autonomously to promote death of SMA motor neurons and non-cell autonomously to alter motor neuron firing through dysfunction of proprioceptive sensory neurons (Aim 1). We will also investigate the temporal and spatial requirement of Stasimon for normal development and function of the sensory-motor circuit using novel conditional knockout mice we have recently developed (Aim 2). Lastly, we will use both cellular and mouse models to characterize the molecular function of Stasimon at the ER-mitochondria contacts and its requirement for motor circuit function in health and disease (Aim 3). The successful accomplishment of the objectives of this proposal will characterize novel aspects of synaptic transmission and motor circuit function as well as the underlying mechanisms of SMA.

运动电路控制吞咽、呼吸和运动等基本行为。神经元是将中枢神经系统内产生的运动命令转化为外周肌肉目标由精确调节的突触活动模式激活。感觉神经元、局部脊髓中间神经元和来自大脑的下行通路、突触。运动神经元在早期发育过程中接受的活动决定了它们的功能特性。相比之下，基因。通常会引起运动神经元接收的神经元接线或突触驱动扰动的突变导致运动系统障碍，尽管主要细胞目标和精确的分子事件仍然存在因此，理解神经回路发育和功能的原理以及人类疾病中突触功能障碍和选择性神经元死亡的机制代表了突出的这种情况的一个突出例子是脊髓性肌萎缩症（SMA）——一种遗传性疾病。由于运动神经元存活蛋白 (SMN) 普遍缺乏而引起的神经肌肉疾病。发病机制涉及运动回路多个组件的改变，导致脊柱异常。然而，反射、运动神经元丧失和骨骼肌萎缩的分子和细胞机制。在我们之前的工作中，我们对 SMA 潜在的运动回路功能障碍仍知之甚少。 Stasimon 作为一种新型跨膜蛋白，定位于内质网和线粒体之间的接触位点。 SMA 动物模型中的膜并通过未定义的机制导致运动功能障碍。此外，我们的初步研究表明，Stasimon 的神经回路条件性损耗严重扰乱小鼠模型的运动功能，表明正常运动系统的基本要求基于这些发现，我们的目标是定义神经回路组件和功能。 Stasimon 发挥作用的细胞通路是其在运动回路中的重要作用和贡献人类疾病。为此，我们将采用新开发的条件小鼠进行细胞类型特异性恢复。研究 SMN 缺陷引起的 Stasimon 功能障碍是否自主作用于细胞促进 SMA 运动神经元和非细胞自主死亡，通过改变运动神经元放电本体感觉神经元功能障碍（目标 1）我们还将研究时间和空间。 Stasimon 使用新颖的感觉运动电路正常发育和功能的要求我们最近开发的条件敲除小鼠（目标 2）最后，我们将使用细胞和小鼠。表征 Stasimon 在内质网-线粒体接触处的分子功能及其要求的模型健康和疾病中的运动回路功能（目标 3）。该提案将描述突触传递和运动电路功能的新颖方面以及 SMA 的潜在机制。