HP1 binding creates a local barrier against transcription activation and persists during chromatin decondensation

Mouse pericentric repeats form transcriptionally silent and compacted domains known as chromocenters. These prototypic heterochromatin compartments are marked by heterochromatin protein 1 (HP1). However, its contributions to chromocenter structure and function remain debated. We investigated the role of HP1α by recruiting the activators VP16, p65, and VPR to mouse fibroblast chromocenters and analyzed its silencing activity with a transcription reporter. Upon chromocenter decondensation and transcription activation, interactions of HP1α with chromatin and H3K9 trimethylation remained stable, suggesting stoichiometric binding rather than higher-order assembly. HP1α-mediated repression required promoter-proximal binding and effectively suppressed VP16-triggered activation but not the stronger activation by VPR. These observations are explained by a 1D lattice binding model, which conceptualizes chromocenters as arrays of repeat units that can independently switch between silenced and activated states. Our findings provide a quantitative framework that explains how chromocenter organization responds to transcriptional activation while maintaining local heterochromatin features.