ABSTRACT: Background Genetic variation drives phenotypic diversity and disease susceptibility. Trans-acting genetic variation coordinates genome-wide chromatin changes, yet the molecular mechanisms underlying this regulation remain largely unknown. Here, we use the power of mouse genetics to investigate how genetic variation at trans-acting loci regulates 3D chromatin interactions. Results Genetically variable 3D interactions were identified using HiChIP to map H3K27ac-associated regulatory elements in C57BL/6J (B6) and DBA/2J (D2) embryonic stem cells (ESCs). We identified 4,962 strain-differential interactions (~5% of total interactions), 71% of which overlapped chromatin accessibility quantitative trait loci (caQTL), establishing that chromatin interaction variation is predominantly heritable. These differential interactions showed coordinated changes in chromatin state and gene expression, with stronger interactions associated with increased accessibility and transcription. Notably, loci regulated in trans exhibited a unique chromatin signature where weaker interactions were enriched for H3K9me3-marked heterochromatin. This pattern was 20-fold more enriched at trans-regulated targets compared to cis, implicating heterochromatin in trans-regulation of 3D genome structure. Analysis of F1 hybrids revealed dominant repressive effects, consistent with heterochromatin-mediated trans-regulation. To causally test this mechanism, we generated reciprocal congenic mouse strains carrying a Chr13 trans-QTL region on otherwise inbred genetic backgrounds. Integrated multiomic profiling of congenic ESC lines demonstrated that this single locus coordinates changes in H3K9me3, H3K27ac, chromatin accessibility, and 3D contact frequency at hundreds of distal genomic regions. Remarkably, 73-83% of differential interactions at Chr13 trans-QTL targets changed in the predicted direction, demonstrating that heterochromatin-mediated trans-regulation coordinately regulates hundreds of regulatory loci. Conclusions This work establishes heterochromatin formation as a mechanism by which genetic variation at trans-acting loci coordinates changes across chromatin accessibility, histone modifications, and 3D genome organization, providing a framework for understanding how early developmental chromatin states could generate phenotypic variation while preserving essential developmental programs.