<p>Since its original formulation, the concept of the central pattern generator (CPG) has provided a foundational framework for understanding vertebrate locomotion. Recent advances in circuit-level neuroscience in zebrafish have redefined the CPG as a dynamic, modular and hybrid sensorimotor system. A central shift has been the replacement of the classical view of the CPG as a unitary rhythm generator with the idea that it is made up of speed-specific modules that are recruited via gear-shifting mechanisms tailored to behavioural demands. Brainstem circuits have emerged as layered controllers that initiate locomotion and modulate episode duration, speed and direction, whereas motor neurons and proprioceptors are now recognized as integral CPG components that shape rhythm and coordination. Here, I use zebrafish as a primary reference point — alongside explicit comparisons to conserved and divergent principles in mammals — to highlight new facets of the vertebrate CPG that redefine it as a highly adaptable, multilayered control system that is&#xa0;continuously tuned by sensory feedback and descending input. This offers a roadmap for decoding the neural logic of adaptive movement across contexts and evolutionary scales and highlights how principles revealed in zebrafish can provide testable hypotheses for terrestrial vertebrates.</p>

错误:搜索内容不能为空,请输入英文关键词
错误:关键词超出字数限制,请精简
高级检索

Redefining the central pattern generator for vertebrate locomotion

  • Abdeljabbar El Manira

摘要

Since its original formulation, the concept of the central pattern generator (CPG) has provided a foundational framework for understanding vertebrate locomotion. Recent advances in circuit-level neuroscience in zebrafish have redefined the CPG as a dynamic, modular and hybrid sensorimotor system. A central shift has been the replacement of the classical view of the CPG as a unitary rhythm generator with the idea that it is made up of speed-specific modules that are recruited via gear-shifting mechanisms tailored to behavioural demands. Brainstem circuits have emerged as layered controllers that initiate locomotion and modulate episode duration, speed and direction, whereas motor neurons and proprioceptors are now recognized as integral CPG components that shape rhythm and coordination. Here, I use zebrafish as a primary reference point — alongside explicit comparisons to conserved and divergent principles in mammals — to highlight new facets of the vertebrate CPG that redefine it as a highly adaptable, multilayered control system that is continuously tuned by sensory feedback and descending input. This offers a roadmap for decoding the neural logic of adaptive movement across contexts and evolutionary scales and highlights how principles revealed in zebrafish can provide testable hypotheses for terrestrial vertebrates.