Self-clustering of three CBX2 molecules drives PRC2 to promote facultative heterochromatinization of Polycomb target genes [Hi-C]

Phase separation is increasingly recognized in facultative heterochromatinization of Polycomb target genes; however, the underlying mechanisms remain obscure. Using single-molecule imaging and tracking, we show that individual condensates in mESCs contain approximately 3 CBX2 molecules and numerous PRC1 and PRC2 subunits and indicate that the composition and dynamics of condensates are developmentally regulated. We reveal that CBX2 clusters PRC2 and controls the spatial distribution of both PRC2 and H3K27me3. Using genomic approaches, we demonstrate that CBX2 binds condensate initiation sites enriched for PRC2 nucleation sites. CBX2 deletion causes PRC2 and H3K27me3 to redistribute from their regular targets. By developing a separate-of-function variant, we determine that CBX2 relies on its self-clustering ability to function. These findings collectively support a novel phase-separation model driven by nucleation and bridging, in which low-abundance proteins self-cluster to initiate condensate assembly, a process tightly coupled to function. Overall design: CUT&RUN of tagged CBX2 and EZH2 in CBX2fl/fl-HaloTag EZH2-Venus-dTag, CUT&RUN of tagged CBX2-PSM-HT in CBX2fl/fl-HaloTag & Parental Cells, CUT&Tag of H3K27me3 in mESCs (CBX2 WT, CBX2 KO, CBX2 PSM, and PGK12.1) in two biological replicates.