Multiple-level organizational logic of the locus coeruleus-norepinephrine system in structure and function
The locus coeruleus (LC) regulates various neural processes through a limited number of norepinephrine (NE)-releasing neurons with widespread axon projections. However, how the LC is organized to exert brain-wide regulatory functions remain elusive. Utilizing larval zebrafish as a whole-brain-scale model, we reveal that morphologically heterogenous but physiologically comparable LC-NE neurons assemble complementarily to implement region-specific regulation of brain-wide neural dynamics. Individual LC-NE neurons exhibit diverse axon projections with ipsilateral bias and region preference, but share comparable electrophysiological properties, sensory responses and neural function-related genes expression. Moreover, population LC-NE neurons display bilaterally symmetrical yet regionally different axon projections and fire synchronously, causing regionally patterned NE release. Along with the regional comparability of NE receptor expression, these enable the LC to tune brain-wide neural dynamics in an inverted-U manner with region difference. Thus, our study provides a comprehensive understanding of the organizational logic of the LC system.