National Centre for Biological Sciences, Tata Institute of Fundamental Research, Bangalore, Karnataka 560065, India; SASTRA Deemed University, School of Chemical and Biotechnology, Thanjavur, Tamil Nadu 613401, India.
National Centre for Biological Sciences, Tata Institute of Fundamental Research, Bangalore, Karnataka 560065, India.
Curr Biol. 2020 Mar 9;30(5):788-801.e3. doi: 10.1016/j.cub.2019.12.064. Epub 2020 Feb 20.
Animals generate locomotion at different speeds to suit their behavioral needs. Spinal circuits generate locomotion at these varying speeds by sequential activation of different spinal interneurons and motor neurons. Larval zebrafish can generate slow swims for prey capture and exploration by activation of secondary motor neurons and much faster and vigorous swims during escape and struggle via additional activation of primary motor neurons. Neuromodulators are known to alter the motor output of spinal circuits, but their precise role in speed regulation is not well understood. Here, in the context of optomotor response (OMR), an innate evoked locomotor behavior, we show that dopamine (DA) provides an additional layer to regulation of swim speed in larval zebrafish. Activation of D1-like receptors increases swim speed during OMR in free-swimming larvae. By analyzing tail bend kinematics in head-restrained larvae, we show that the increase in speed is actuated by larger tail bends. Whole-cell patch-clamp recordings from motor neurons reveal that, during OMR, typically only secondary motor neurons are active, whereas primary motor neurons are quiescent. Activation of D1-like receptors increases intrinsic excitability and excitatory synaptic drive in primary and secondary motor neurons. These actions result in greater recruitment of motor neurons during OMR. Our findings provide an example of neuromodulatory reconfiguration of spinal motor neuron speed modules where members are selectively recruited and motor drive is increased to effect changes in locomotor speed. VIDEO ABSTRACT.
动物以不同的速度产生运动以适应其行为需求。脊髓回路通过顺序激活不同的脊髓中间神经元和运动神经元来以这些不同的速度产生运动。通过激活次级运动神经元,幼鱼可以产生缓慢的游泳来捕食和探索,而通过额外激活初级运动神经元,幼鱼可以在逃避和挣扎时产生更快更有力的游泳。神经调质已知会改变脊髓回路的运动输出,但它们在速度调节中的精确作用尚不清楚。在这里,在光反应(OMR)的背景下,一种先天的诱发运动行为中,我们表明多巴胺(DA)为幼鱼的游泳速度调节提供了额外的一层。在自由游动的幼虫中,激活 D1 样受体可增加 OMR 期间的游泳速度。通过分析头部固定的幼虫的尾巴弯曲运动学,我们表明速度的增加是通过更大的尾巴弯曲来实现的。来自运动神经元的全细胞膜片钳记录显示,在 OMR 期间,通常只有次级运动神经元活跃,而初级运动神经元处于静止状态。激活 D1 样受体可增加初级和次级运动神经元的内在兴奋性和兴奋性突触驱动。这些作用导致在 OMR 期间更多地募集运动神经元。我们的发现提供了一个脊髓运动神经元速度模块的神经调质重新配置的例子,其中成员被选择性募集,并且运动驱动增加以实现运动速度的变化。视频摘要。
