Neural control of respiration

呼吸的神经控制

• 批准号: RGPIN-2018-06190
• 负责人: Dubuc, Réjean
• 金额: $ 2.4万
• 依托单位: Université du Québec à Montréal
• 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=757690
• 关键词: Neural; control; respiration

Respiration is a basic rhythmic motor activity maintained throughout life. In vertebrates, it results from rhythmic activity of brainstem neurons, collectively known as “respiratory rhythm generator”. Both synaptic connectivity and membrane properties play a crucial role in generating respiration. Advances have been made in understanding the basic mechanisms underlying respiration using in vitro preparations of mammalian brainstem tissue. Because most of these in vitro preparations consist of slices of neural tissue, they do not include the entire neural circuitry responsible for respiration and its modulation. These limitations have prevented the detailed identification of the synaptic interactions between the neurons involved. We are using the lamprey, a basal vertebrate, as a powerful model to gain insight into these questions. In lampreys, respiratory activity is maintained for hours under in vitro conditions in the isolated intact brainstem and can even be maintained in semi-intact preparations that include the peripheral respiratory apparatus. The long-term objective of our research program is to characterize in detail the neural mechanisms underlying the generation and modulation of respiration. There are two distinct respiratory rhythms in lampreys: a fast (1.5 Hz) and a slow rhythm (0.02 Hz). During this next granting term, we will focus on 3 specific research themes: Theme 1 will focus on the fast respiratory rhythm. Using anatomical techniques we will define the synaptic connectivity of neurons involved in generating the fast rhythm. Whole cell patch recordings will be used to examine the contribution of excitatory and inhibitory inputs as well as the membrane properties of the neurons. Theme 2 will focus on the mechanisms responsible for generating the slow rhythm. We will use whole cell patch recordings to define the connectivity and properties of generator neurons. Because of their anatomical location in the lamprey brainstem, the groups of neurons generating the slow rhythm are excellent candidates for being the evolutionary ancestors of the neurons generating breathing in mammals. Theme 3 will focus on the mechanisms underlying the increase in respiratory activity during movement. We have discovered in lampreys a central neural substrate responsible for adapting the respiratory output to energy demands during locomotion. It consists of a feed forward mechanism from a locomotor control center to the fast respiratory rhythm generator. The lamprey model is ideal to examine such a behaviourally relevant modulation of the respiratory rhythm. We will now identify the neural mechanisms involved, focusing on the role of acetylcholine and Substance P. Altogether, we are proposing a comprehensive long-term research program to identify the mechanisms responsible for generating and modulating respiration in a basal vertebrate.

呼吸是一种基本的有节奏的运动活动，在整个生命过程中维持。在脊椎动物中，它是由脑干神经元的节律性活动引起的，统称为“呼吸节律发生器”。突触连接和膜特性在产生呼吸中起着至关重要的作用。利用哺乳动物脑干组织的体外制备，在理解呼吸的基本机制方面取得了进展。因为这些体外制备物大多由神经组织切片组成，它们不包括负责呼吸及其调节的整个神经回路。这些局限性阻碍了对所涉及的神经元之间的突触相互作用的详细识别。我们正在使用七鳃鳗，一种基础脊椎动物，作为一个强大的模型来深入了解这些问题。在七鳃鳗中，呼吸活动在体外条件下在分离的完整脑干中维持数小时，甚至可以在包括外周呼吸器官的半完整制剂中维持。我们研究计划的长期目标是详细描述呼吸产生和调节的神经机制。七鳃鳗有两种不同的呼吸节奏：快节奏（1.5 Hz）和慢节奏（0.02 Hz）。在下一个资助学期，我们将专注于3个具体的研究主题：主题1将专注于快速呼吸节律。使用解剖学技术，我们将定义参与产生快节奏的神经元的突触连接。全细胞斑片记录将用于检查兴奋性和抑制性输入的贡献以及神经元的膜特性。主题2将集中讨论产生慢节奏的机制。我们将使用全细胞补丁记录来定义生成神经元的连接和属性。由于它们在七鳃鳗脑干中的解剖位置，产生慢节奏的神经元群是哺乳动物产生呼吸的神经元进化祖先的绝佳候选者。主题3将集中在运动过程中呼吸活动增加的机制。我们在七鳃鳗中发现了一种中枢神经基质，负责使呼吸输出适应运动过程中的能量需求。它包括一个前馈机制，从运动控制中心的快速呼吸节律发生器。七鳃鳗模型是理想的检查这样一个行为相关的呼吸节律的调制。我们现在将确定所涉及的神经机制，重点是乙酰胆碱和P物质的作用。总之，我们提出了一个全面的长期研究计划，以确定负责在基础脊椎动物中产生和调节呼吸的机制。