Abstract
How dynamic circadian rhythms arise from a relatively static nuclear architecture remains a fundamental open question. Here, we identify the SWI/SNF chromatin-remodeling complex as a critical interface between the circadian clock and nuclear organization. Using endogenously tagged Moira (MOR), a core component of the Drosophila SWI/SNF complex and homolog of human BAF155, we find that MOR assembles into a small number of discrete foci near the nuclear periphery, in stark contrast to the current model of diffuse nuclear distribution for SWI/SNF-family proteins. We demonstrate that this localization is maintained by the inner nuclear envelope LEM-domain protein Otefin, effectively shifting MOR from a global to a localized regulator of chromatin architecture. DNA-FISH reveals that clock-regulated genes cluster into peripheral "hubs" that co-localize with MOR foci throughout the circadian cycle. ATAC-seq analysis shows that while MOR modulates chromatin accessibility genome-wide, it establishes a constitutive restrictive baseline specifically at clock-regulated loci. As a result, MOR depletion abolishes accessibility rhythms at these loci, rendering them constitutively hyper-accessible. This deregulation disrupts rhythmic gene expression and ultimately drives behavioral arrhythmia. Strikingly, oscillations of the core clock proteins PER and TIM remain intact, indicating that MOR loss uncouples the protein oscillator from its genomic output. Together, these results reveal that MOR-containing SWI/SNF foci form a stable perinuclear scaffold that gates chromatin accessibility, enabling the core clock machinery to convert transient protein oscillations into high-amplitude transcriptional rhythms.