Severe combined immunodeficient cells expressing mutant hRAD54 exhibit a marked DNA double-strand break repair and error-prone chromosome repair defect.

DNA double-strand breaks (DSBs) can be induced by a number of endogenous and exogenous agents and are lethal events if left unrepaired. DNA DSBs can be repaired by homologous recombination (HR) and nonhomologous end joining (NHEJ). In mammals and higher eukaryotes, NHEJ is thought to be the primary pathway for repair, but the role for each pathway in DNA DSB repair has not been fully elucidated. To define the relative contributions of HR and NHEJ in mammalian DNA DSB repair, cells defective in both pathways were produced. Double-mutant cells were created by expressing a dominant mutant hRAD54 protein in a DNA-dependent protein kinase (DNA-PK)-deficient severe combined immunodeficient cell line. Double-mutant cells demonstrate an increase in ionizing radiation sensitivity and a decrease in DNA DSB repair as compared with either single mutant, whereas single-mutant hRAD54 cells exhibit a wild-type phenotype. Unexpectedly, DNA-PK-null cells were more resistant to mitomycin-C damage than were wild-type cells. Chromosome aberration analysis reveals numerous incomplete chromatid exchange aberrations in the majority of the double-mutant cells after ionizing radiation exposure. Our findings confirm a role for HR in DSB repair in higher eukaryotes, yet indicate that its role is not evident unless the primary repair pathway, NHEJ, is nonfunctional. Mitomycin-C resistance in DNA-PK-null cells compared with wild-type cells suggests that the HR pathway may be more efficient in cross-link repair in the absence of NHEJ. Lastly, the incorrectly repaired chromatid damage observed in double-mutant cells may result from failed recombination or another error-prone repair process that is apparent in the absence of the two primary repair pathways.

The DNA damage response in DNA-dependent protein kinase-deficient SCID mouse cells: replication protein A hyperphosphorylation and p53 induction.

Severe combined immunodeficient (SCID) mice display an increased sensitivity to ionizing radiation compared with the parental, C.B-17, strain due to a deficiency in DNA double-strand break repair. The catalytic subunit of DNA-dependent protein kinase (DNA-PKCS) has previously been identified as a strong candidate for the SCID gene. DNA-PK phosphorylates many proteins in vitro, including p53 and replication protein A (RPA), two proteins involved in the response of cells of DNA damage. To determine whether p53 and RPA are also substrates of DNA-PK in vivo following DNA damage, we compared the response of SCID and MO59J (human DNA-PKcs-deficient glioblastoma) cells with their respective wild-type parents following ionizing radiation. Our findings indicate that (i) p53 levels are increased in SCID cells following ionizing radiation, and (ii) RPA p34 is hyperphosphorylated in both SCID cells and MO59J cells following ionizing radiation. The hyperphosphorylation of RPA p34 in vivo is concordant with a decrease in the binding of RPA to single-stranded DNA in crude extracts derived from both C.B-17 and SCID cells. These results suggest that DNA-PK is not the only kinase capable of phosphorylating RPA. We conclude that the DNA damage response involving p53 and RPA is not associated with the defect in DNA repair in SCID cells and that the physiological substrate(s) for DNA-PK essential for DNA repair has not yet been identified.

DNA-dependent kinase (p350) as a candidate gene for the murine SCID defect.

Severe combined immunodeficient (SCID) mice are deficient in a recombination process utilized in both DNA double-strand break repair and in V(D)J recombination. The phenotype of these mice involves both cellular hypersensitivity to ionizing radiation and a lack of B and T cell immunity. The catalytic subunit of DNA-dependent protein kinase, p350, was identified as a strong candidate for the murine gene SCID. Both p350 and a gene complementing the SCID defect colocalize to human chromosome 8q11. Chromosomal fragments expressing p350 complement the SCID phenotype, and p350 protein levels are greatly reduced in cells derived from SCID mice compared to cells from wild-type mice.