Neural Sequences Underlying Directed Turning in C. elegans

Talya S Kramer, Flossie K Wan, Sarah M Pugliese, Adam A Atanas, Alex W Hiser, Jinyue Luo, Eric Bueno, Steven W Flavell
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Abstract

Complex behaviors like navigation rely on sequenced motor outputs that combine to generate effective movement. The brain-wide organization of the circuits that integrate sensory signals to select and execute appropriate motor sequences is not well understood. Here, we characterize the architecture of neural circuits that control C. elegans olfactory navigation. We identify error-correcting turns during navigation and use whole-brain calcium imaging and cell-specific perturbations to determine their neural underpinnings. These turns occur as motor sequences accompanied by neural sequences, in which defined neurons activate in a stereotyped order during each turn. Distinct neurons in this sequence respond to sensory cues, anticipate upcoming turn directions, and drive movement, linking key features of this sensorimotor behavior across time. The neuromodulator tyramine coordinates these sequential brain dynamics. Our results illustrate how neuromodulation can act on a defined neural architecture to generate sequential patterns of activity that link sensory cues to motor actions.
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草履虫定向转弯的神经序列
复杂的行为(如导航)依赖于有序的运动输出,这些输出结合在一起才能产生有效的运动。目前对整合感觉信号以选择和执行适当运动序列的全脑电路组织尚不十分清楚。在这里,我们描述了控制秀丽隐杆线虫嗅觉导航的神经回路结构。我们确定了导航过程中的纠错转向,并利用全脑钙成像和细胞特异性扰动来确定其神经基础。这些转弯以运动序列的形式出现,并伴有神经序列,其中确定的神经元在每次转弯时都会以刻板的顺序激活。该序列中的不同神经元会对感觉线索做出反应,预测即将到来的转弯方向,并驱动运动,从而将这种感觉运动行为的关键特征在不同时间内联系起来。神经调节剂酪胺能协调这些连续的大脑动态。我们的研究结果说明了神经调节如何作用于一个确定的神经结构,从而产生将感觉线索与运动行为联系起来的连续活动模式。
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