The evolution of high-order genome architecture revealed from 1,000 species
Summary
Spatial genome organization plays a crucial regulatory role, but its evolutionary development remains unclear. Leveraging Hi-C data from 1,025 species, we trace the evolutionary trajectories of genome organization through 2 higher-order architectures, "global folding" (spatial organization of the karyotype) and "checkerboard" (spatial organization of chromatin compartments). Earlier unicellular life forms mostly displayed random genome configurations. Throughout the evolution of plants, gl
Content
# The evolution of high-order genome architecture revealed from 1,000 species
*Published: 2026 Apr 21*
Spatial genome organization plays a crucial regulatory role, but its
evolutionary development remains unclear. Leveraging Hi-C data from 1,025
species, we trace the evolutionary trajectories of genome organization through 2
higher-order architectures, "global folding" (spatial organization of the
karyotype) and "checkerboard" (spatial organization of chromatin compartments).
Earlier unicellular life forms mostly displayed random genome configurations.
Throughout the evolution of plants, global folding became and remained the
prominent architecture. However, animals progressively developed more pronounced
checkerboard architectures; these are also apparent during early embryogenesis,
which suggests that they act as a conserved mechanism of gene regulation. In
contrast, plants exhibit comparatively weaker checkerboard patterns and instead
preferentially organize co-regulated genes into linear genomic clusters. Both
strategies of gene arrangement reinforce the biological principle that
"structure determines function": divergent evolutionary paths converge on
architectural solutions that reflect gene regulatory requirements over time.
DOI: 10.1016/j.cell.2026.03.042