An opposing molecular gradient axis underlies primate cortical organization
Summary
The principles organizing cellular diversity and connectivity in primate brains remain elusive. By integrating spatial transcriptomics, magnetic resonance imaging, and retrograde labeling in marmosets, we identified two opposing molecular gradients that undergo postnatal refinement, emanating from allocortices and primary sensory cortices, respectively. These gradients reconcile conflicting hypotheses on cortical expansion and characterize distinct cortical areas. Cortical gradients align
Content
# An opposing molecular gradient axis underlies primate cortical organization
*Published: 2026 Apr 16*
The principles organizing cellular diversity and connectivity in primate brains
remain elusive. By integrating spatial transcriptomics, magnetic resonance
imaging, and retrograde labeling in marmosets, we identified two opposing
molecular gradients that undergo postnatal refinement, emanating from
allocortices and primary sensory cortices, respectively. These gradients
reconcile conflicting hypotheses on cortical expansion and characterize distinct
cortical areas. Cortical gradients align with thalamic gene expression and
thalamocortical projection patterns. At gradient intersections, the default mode
network and frontal pole exhibited similar molecular features in humans and
marmosets, despite species-specific differences in functional connectivity.
Comparative analysis of gradient-related genes showed that marmoset and human
auditory cortices are highly similar but differ from those of macaques,
potentially reflecting complex vocalization. Together, these opposing gradients
represent a fundamental organizing principle of the primate cortex.
DOI: 10.1126/science.aea2673