| 描述信息 |
DNA G-quadruplexes (G4s) are secondary structures with significant roles in regulating genome function and stability. Dysregulation of the dynamic formation of G4s is linked to genomic instability and disease, but the underlying mechanisms are not fully understood. In this study, we conducted a screen of chromatin-modifying enzymes and identified nine potential inhibitors of G4 formation, including seven that were not previously characterized. Among these, we highlight the role of BAZ2 chromatin remodelers as key suppressors of G4 DNA and G4-related genome instability. Depletion of BAZ2 subunits led to increased G4 formation, especially at transcriptional regulatory elements. BAZ2B was found to associate with G4 loci, suggesting that it plays a direct role in suppressing G4s. While BAZ2-deficient cells exhibited modest genomic instability, treatment with the G4-stabilizing ligand BRACO19 exacerbated double-strand breaks (DSBs), highlighting its utility as a tool to study G4-dependent genome instability. DSB profiling using INDUCE-seq uncovered distinct breakage patterns around G4s, further underscoring the impact of G4s on genome integrity. Notably, we found that within G4s, G repeats were more susceptible to DSBs than loops. These results establish BAZ2 chromatin remodeling complexes as direct regulators of G4 dynamics and provide new insights into G4-dependent genome instability.
Overall design: CUT&Tag performed for endogenously HA tagged BAZ2B using an HA antibody as well as H3K4me3 CUT&Tag controls. |
