A whole-brain single-cell atlas of circadian neural activity in mice
Summary
The mammalian brain comprises numerous anatomical regions with distinct functions despite their extensive connectivity. How spontaneous neural activity is coordinated across regions over the circadian cycle remains elusive. We used tissue clearing and whole-brain c-Fos immunostaining on 144 mouse brains collected over 2 days under constant darkness. Time-series analysis revealed brainwide circadian rhythmicity at single-cell resolution, with 79% of the 642 anatomically defined regions osci
Content
# A whole-brain single-cell atlas of circadian neural activity in mice
*Published: 2026 Feb 19*
The mammalian brain comprises numerous anatomical regions with distinct
functions despite their extensive connectivity. How spontaneous neural activity
is coordinated across regions over the circadian cycle remains elusive. We used
tissue clearing and whole-brain c-Fos immunostaining on 144 mouse brains
collected over 2 days under constant darkness. Time-series analysis revealed
brainwide circadian rhythmicity at single-cell resolution, with 79% of the 642
anatomically defined regions oscillating in diverse circadian phases that
delineate functional specializations. Voxelwise analyses further highlighted
distinct subregions, suggesting intricate spatiotemporal coordination within
regions. Additionally, brain circadian time could be accurately inferred from
global c-Fos patterns using omics-derived prediction methods. This whole-brain
circadian atlas enhances our understanding of neural coordination and provides a
resource for integrating time-of-day information into functional and
pharmacological research.
DOI: 10.1126/science.aea3381