POGZ safeguards neuronal gene chromatin architecture and transcription

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Abstract

Disruption of chromatin organization is a common pathogenic mechanism in neurodevelopmental disorders, yet how changes in 3D genome architecture relate to transcriptional dysfunction in the developing brain remains unclear. POGZ, a transposase-derived chromatin regulator mutated in White–Sutton syndrome and autism spectrum disorder (ASD) has been linked to both heterochromatin and accessible regulatory DNA, but its in vivo function in the brain is unresolved. Using immunoprecipitation–mass spectrometry in embryonic day 13.5 (E13.5) mouse cortex, we identify the H3K9 methyltransferases G9a/GLP as principal POGZ interactors, placing POGZ within the core H3K9 methylation machinery in vivo. We find that POGZ loss in embryonic mouse cortex drives bidirectional, megabase-scale redistribution of H3K9me3, with ectopic losses and gains over discrete neuronal gene loci. In developing Pogz -/- cortex, regions with H3K9me3 gains are repositioned to the nuclear lamina and exhibit strengthened B-compartment scores by Micro-C, locus-restricted erosion of TAD architecture, weakened boundary insulation, and reduced CTCF occupancy. Within these domains, nascent RNA synthesis at neuronal genes is markedly diminished. These results identify POGZ as a G9a/GLP-associated chromatin regulator that protects neurodevelopmental gene domains from heterochromatinization and perinuclear sequestering, preserving 3D architecture and transcription during cortical development.

Major Points

  • POGZ interacts with the G9a/GLP H3K9 methyltransferase complex in the developing mouse cortex, identified by IP–mass spectrometry.

  • Loss of POGZ drives megabase-scale redistribution of H3K9me3 and increases compartmentalization and nuclear-lamina association of neurodevelopmental gene loci, shown by ChIP-seq, Micro-C, and DNA FISH.

  • Micro-C reveals disrupted TAD architecture at specific neuronal gene loci in Pogz⁻/⁻.PRO-seq shows POGZ is required to maintain nascent RNA synthesis of neurodevelopmental genes within disrupted chromatin domains.

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