BMAL1 regulates circadian rhythms via phase separation-mediated transcriptional hub formation
Summary
The mechanisms by which core clock components are spatially organized to ensure robust oscillations in mammals remain unclear. Here, we identify the positive limb factor BMAL1 as a phase-separating protein that forms dynamic biomolecular condensates essential for circadian transcription and behavior. Endogenous BMAL1 forms nuclear puncta that oscillate in sync with the circadian cycle. Deletion analysis and optogenetic clustering identify an N-terminal 90-amino acid intrinsically disordere
Content
# BMAL1 regulates circadian rhythms via phase separation-mediated transcriptional hub formation
*Published: 2026 May 1*
The mechanisms by which core clock components are spatially organized to ensure
robust oscillations in mammals remain unclear. Here, we identify the positive
limb factor BMAL1 as a phase-separating protein that forms dynamic biomolecular
condensates essential for circadian transcription and behavior. Endogenous BMAL1
forms nuclear puncta that oscillate in sync with the circadian cycle. Deletion
analysis and optogenetic clustering identify an N-terminal 90-amino acid
intrinsically disordered region whose phosphorylation state tunes BMAL1 phase
separation. Besides, BMAL1 condensates behave as multi-molecular assemblies that
selectively recruit CLOCK, p300, MED1, and are specifically promoted by E-box
DNA. Functionally, an IDR-deleted BMAL1 mutant fails to rescue rhythmic
transcription in Bmal1-KO cells and cannot restore locomotor rhythms when
reintroduced into SCN-specific Bmal1‑KO mice. These findings establish BMAL1
condensates as dynamic transcriptional hubs that couple phase separation to
circadian rhythm in cells and in vivo.
DOI: 10.1038/s41392-026-02711-7