Distinct spatiotemporal dynamics of mammalian checkpoint regulators induced by DNA damage.

Abstract

Cell cycle checkpoints are signal transduction pathways activated after DNA damage to protect genomic integrity. Dynamic spatiotemporal coordination is a vital, but poorly understood aspect, of these checkpoints. Here, we provide evidence for a strikingly different behaviour of Chk2 versus Nbs1, key mediators of the ataxia-telangiecatesia-mutated (ATM)-controlled checkpoint pathways induced by DNA double-strand breaks (DSBs). In live human cells with DSBs restricted to small sub-nuclear areas, Nbs1 was rapidly recruited to the damaged regions and underwent a dynamic exchange in the close vicinity of the DSB sites. In contrast, Chk2 continued to rapidly move throughout the entire nucleus, irrespective of DNA damage and including the DSB-free areas. Although phosphorylation of Chk2 by ATM occurred exclusively at the DSB sites, forced immobilization of Chk2 to spatially restricted, DSB-containing nuclear areas impaired its stimulating effect on p53-dependent transcription. These results unravel a dynamic nature of Nbs1 interaction with DSB lesions and identify Chk2 as a candidate transmitter of the checkpoint signal, allowing for a coordinated pan-nuclear response to focal DNA damage.