Abstract

Dysregulation and enhanced expression of MYC transcription factors (TFs) including MYC and MYCN contribute to the majority of human cancers. For example, MYCN is amplified up to several hundred-fold in high-risk neuroblastoma. The resulting overexpression of N-myc aberrantly activates genes that are not activated at low N-myc levels and drives proliferation and cell survival. Whether increasing N-myc levels simply mediate binding to lower-affinity binding sites in the genome or fundamentally changes the activation process remains unclear. One such activation mechanism that could become important above threshold levels of N-myc is the formation of aberrant transcriptional condensates through phase separation. Phase separation has recently been linked to transcriptional regulation, but how strongly it contributes to gene activation remains unclear. Here we characterized the phase behavior of N-myc and showed that it can form dynamic condensates that bear the hallmarks of transcriptional activity. We tested the contribution of phase separation to N-myc-mediated gene expression by using a chemogenetic tool that allowed us to compare non-phase-separated and phase-separated conditions at identical N-myc levels, which both showed a strong impact on gene expression compared to no N-myc expression. However, we found that only a small fraction of 97% of N-myc-regulated genes are not affected by N-myc phase separation, highlighting that transcription can be activated effectively by diffuse complexes of TFs with the transcriptional machinery.