A prevalent disease-associated SNP in the human ID3 gene regulates E-protein activity and cellular proliferation.

The helix-loop-helix transcription factor ID3 is a critical regulator of tissue development and homeostasis. Aberrations in ID3 are strongly associated with numerous human disease processes including Burkitt's lymphoma. We previously identified that a single-nucleotide polymorphism (SNP) in ID3 at rs11574 is associated with increased vascular disease burden in three independent cohorts; however, the mechanisms by which this SNP alters ID3 function and impacts vascular cells are unknown. Here, we show that the minor allele of rs11574 specifically disrupts ID3's ability to bind the E-protein E12. Computational analysis and confirmatory biochemical experiments revealed that rs11574's effects on ID3:E12 dimerization are dependent upon a key residue within E12's unique loop domain. Functionally, the disruption of ID3:E12-binding promotes E12 binding to and activation of the p21 promoter. Isogenic human cell lines harboring the rs11574 minor allele exhibited decreased cell proliferation and altered expression of genes involved in proliferation. RNAseq revealed distinct roles for E12 and E47 in transcriptional regulation of vascular smooth muscle cells (VSMCs). Primary human VSMCs from subjects with the rs11574 minor allele exhibited reduced mitogen-stimulated proliferation. Taken together, these results provide the first characterization of altered molecular and cellular functions of this disease-associated SNP in ID3 at rs11574.