Abstract The V(D)J recombinase, composed of the recombination activating gene (RAG) proteins, RAG1 and RAG2, generate functional antigen receptor genes through the repeated generation of DNA double strand breaks and DNA repair. However, this process can lead to increased genomic instability particularly in the presence of excess DNA breaks. Previously, we showed in pre-B cells that full length RAG2, a nuclear protein, will export to the cytoplasm with DNA damage in an ATM-dependent manner with eventual recovery back into the nucleus following DNA repair. We propose that re-localization of RAG2 prevents RAG-mediated DNA cleavage in the presence of excess DNA ends. Here, by using fluorescently tagged RAG proteins, we show that DNA damage-induced export of the V(D)J recombinase can be recapitulated in non-lymphoid cells. Further, we determined that mutations in the intrinsically-disordered region of RAG2 have distinct effects on this process. Specifically, a basic region mutant of RAG2 (K/R 518–524 A) alters the localization pattern of the V(D)J recombinase, and yet its pre-DNA damage localization pattern is re-established upon DNA repair. Conversely, a T490A mutant blocks relocalization of RAG2 following genotoxic stress for both the single T490A mutant and the combined T490A/basic region mutant. Together, these results demonstrate the role of the intrinsically-disordered region in RAG2 in regulating the mobility and subcellular localization of the V(D)J recombinase upon cellular conditions that may be deemed too risky for continued DNA rearrangements. Supported by NIA T32AG052363, NIH AI128137, OCAST