Preferential formation of NUP98-KDM5A condensates at specific H3K4me3-rich loci drives leukemogenic gene expression.

Chromosomal translocations involving NUP98 generate fusion proteins that alter gene expression programs, yet the fundamental principles governing their gene targeting and condensate behavior remain poorly understood. Using NUP98-KDM5A as a model, we integrate cellular imaging, reconstitution, and genomic analyses to dissect how chromatin engagement shapes condensate formation. We find that NUP98-KDM5A forms sub-diffraction-limited, gel-like condensates whose assembly is potentiated by binding to H3K4me3. This interaction creates a quantitative targeting mechanism in which, at the native expression level, condensates preferentially form at genomic loci with high local H3K4me3 density. Such local density-dependent recruitment explains selective enrichment at the leukemogenic HOX gene clusters, despite widespread presence of H3K4me3 across the genome. Analysis of single-cell sequencing data from patients further supports a correlation between local H3K4me3 density and transcriptional activation in NUP98-KDM5A-driven leukemia. Together, our findings reveal how activating chromatin marks and condensate-forming proteins synergize to generate specificity within euchromatin, offering a generalizable framework for understanding how chromatin-associated condensates interpret epigenetic landscapes.