53BP1 exchanges slowly at the sites of DNA damage and appears to require RNA for its association with chromatin
Author:
Pryde Fiona1, Khalili Shirin1, Robertson Kathryn1, Selfridge Jim2, Ritchie Ann-Marie2, Melton David W.2, Jullien Denis1, Adachi Yasuhisa1
Affiliation:
1. The Wellcome Trust Centre for Cell Biology, The Institute of Cell and Molecular Biology, The University of Edinburgh, The King's Buildings, Edinburgh, EH9 3JR, UK 2. Sir Alastair Currie Cancer Research UK Laboratories, Molecular Medicine Centre, The University of Edinburgh, Western General Hospital, Edinburgh, EH4 2XU, UK
Abstract
53BP1 protein is re-localized to the sites of DNA damage after ionizing radiation (IR) and is involved in DNA-damage-checkpoint signal transduction. We examined the dynamics of GFP-53BP1 in living cells. The protein starts to accumulate at the sites of DNA damage 2-3 minutes after damage induction. Fluorescence recovery after photobleaching experiments showed that GFP-53BP1 is highly mobile in non-irradiated cells. Upon binding to the IR-induced nuclear foci, the mobility of 53BP1 reduces greatly. The minimum (M) domain of 53BP1 essential for targeting to IR induced foci consists of residues 1220-1703. GFP-M protein forms foci in mouse embryonic fibroblast cells lacking functional endogenous 53BP1. The M domain contains a tandem repeat of Tudor motifs and an arginine- and glycine-rich domain (RG stretch), which are often found in proteins involved in RNA metabolism, the former being essential for targeting. RNase A treatment dissociates 53BP1 from IR-induced foci. In HeLa cells, dissociation of the M domain without the RG stretch by RNase A treatment can be restored by re-addition of nuclear RNA in the early stages of post-irradiation. 53BP1 immunoprecipitates contain some RNA molecules. Our results suggest a possible involvement of RNA in the binding of 53BP1 to chromatin damaged by IR.
Publisher
The Company of Biologists
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