Genetic interaction between DNA polymerase beta and DNA-PKcs in embryogenesis and neurogenesis

DNA polymerase beta (Polbeta) has been implicated in base excision repair. Polbeta knockout mice exhibit apoptosis in postmitotic neuronal cells and die at birth. Also, mice deficient in nonhomologous end-joining (NHEJ), a major pathway for DNA double-strand break repair, cause massive neuronal apoptosis. Severe combined immunodeficiency (SCID) mice have a mutation in the gene encoding DNA-dependent protein kinase catalytic subunit (DNA-PKcs), the component of NHEJ, and exhibit defective lymphogenesis. To study the interaction between Polbeta and DNA-PKcs, we generated mice doubly deficient in Polbeta and DNA-PKcs. Polbeta(-/-)DNA-PKcs(scid/scid) embryos displayed greater developmental delay, more extensive neuronal apoptosis, and earlier lethality than Polbeta(-/-) and DNA-PKcs(scid/scid) embryos. Furthermore, to study the involvement of p53 in the phenotype, we generated Polbeta(-/-)DNA-PKcs(scid/scid)p53(-/-) triple-mutant mice. The mutants did not exhibit apoptosis but were lethal with defective neurulation at midgestation. These results suggest a genetic interaction between Polbeta and DNA-PKcs in embryogenesis and neurogenesis.     

Elevated DNA double strand breaks and apoptosis in the CNS of scid mutant mice

Genetic approaches have provided evidence that DNA end-joining problems serve an essential role in neuronal survival during development of mammalian embryos. In the present study, we tested whether the DNA repair enzyme, DNA dependent protein kinase, plays an important role in the survival of cerebral cortical neurons in mice. DNA-PK is comprised of a DNA-binding subunit called Ku and a catalytic subunit called DNA-PKcs. In mice with the scid mutation, DNA-PKcs is truncated near the kinase domain, which causes loss of kinase activity. We compared the spatial and temporal aspects of neuronal cell death in scid versus isogenic wild-type embryos and found a significant increase in dying cells in scid mice, as assessed by nuclear changes, DNA fragmentation and caspase-3 activity. Additional biochemical and immunocytochemical studies indicated that of several DNA repair enzymes investigated, only PARP was increased in scid mice, possibly in response to elevated DNA strand breaks.     

Shortened telomeres in murine scid cells expressing mutant hRAD54 coincide with reduction in recombination at telomeres

Murine severe combined immunodeficiency (scid) cells are characterized by defective Prkdc (DNA-PKcs), one of the key genes involved in the repair of DNA double-strand breaks. Interestingly, scid mice are not null mutants and their cells are likely to show low DNA-PKcs activity. Prkdc is also involved in telomere maintenance and in contrast to mice genetically engineered to lack Prkdc (i.e. null mutants), which show complete absence of DNA-PKcs activity, loss of telomere capping function and normal telomere length, cells from scid mice show not only loss of telomere capping function but also abnormally elongated telomeres. Here we demonstrate that telomere elongation observed in murine scid cells can be reversed by expressing mutant hRAD54, a protein involved in homologous recombination. In addition, we measured recombination rates at telomeres using chromosome orientation fluorescence in situ hybridization (CO-FISH) and found that these are elevated in scid cells in comparison with control cells, or significantly reduced in scid cells expressing mutant hRAD54. Similarly, recombination rates at telomeres are reduced in scid cells following introduction of functional Prkdc. Since expression of mutant hRAD54 and restoration of functional Prkdc in scid cells cause the same effects, i.e. telomere shortening and reduced recombination rates at telomeres, these results argue that telomere elongation in scid cells is a complex trait resulting from interactions between homologous recombination mechanisms and DNA-PKcs.     

Irradiation-induced rescue of thymocyte differentiation and V(D)J recombination in mice lacking the catalytic subunit of DNA-dependent protein kinase

Scid mice express a truncated form of the catalytic subunit of the DNA-dependent protein kinase (DNA-PKcs) and are unable to properly rearrange their Ig and TCR genes, resulting in a severe combined immunodeficiency that is characterized by arrested differentiation of B and T lymphocytes. Treatment of scid mice with low doses of gamma irradiation rescues rearrangements at several TCR loci and promotes limited thymocyte differentiation. The machinery responsible for sensing DNA damage and the mechanism by which irradiation compensates for the scid defect in TCR recombination remain unknown. Because DNA-PKcs is present in scid thymocytes, it may mediate some or all of the irradiation effects. To test this hypothesis, we examined the effects of irradiation on DNA-PKcs-deficient (slip) mice. Our data provide the first evidence that DNA-PKcs is not required for limited rescue of thymocyte differentiation or TCR rearrangements.     

Role of DNA-dependent protein kinase in neuronal survival

DNA-dependent protein kinase (DNA-PK) is a DNA repair enzyme composed of a DNA-binding component called Ku70/80 and a catalytic subunit called DNA-PKcs. Many investigators have utilized DNA-PKcs-deficient cells and cell lines derived from severe combined immunodeficiency (scid) mice to study DNA repair and apoptosis. However, little is known about the CNS of these mice. This study was carried out using primary neuronal cultures derived from the cerebral hemispheres of new-born wild-type and scid mice to investigate the effects of loss of DNA-PK function on neuronal maturation and survival. Purified neuronal cultures developed comparably in terms of neurite formation and expression of neuronal markers, but scid cultures showed a significant increase in the percentage of dying cells. Furthermore, when apoptosis was induced by staurosporine, scid neurons died more rapidly and in higher numbers. Apoptotic scid neurons exhibited nuclear condensation, DNA fragmentation and caspase-3 activation, but treatment with the general caspase inhibitor, N-benzyloxycarbonyl-Val-Ala-Asp-(O-methyl) fluoromethyl ketone did not prevent staurosporine-induced apoptosis. We conclude that a DNA-PK deficiency in cultured scid neurons may cause an accumulation of DNA damage and increased susceptibility to caspase-independent forms of programmed cell death.     

Lack of spontaneous and radiation-induced chromosome breakage at interstitial telomeric sites in murine scid cells

Interstitial telomeric sites (ITSs) in chromosomes from DNA repair-proficient mammalian cells are sensitive to both spontaneous and radiation-induced chromosome breakage. Exact mechanisms of this chromosome breakage sensitivity are not known. To investigate factors that predispose ITSs to chromosome breakage we used murine scid cells. These cells lack functional DNA-PKcs, an enzyme involved in the repair of DNA double-strand breaks. Interestingly, our results revealed lack of both spontaneous and radiation-induced chromosome breakage at ITSs found in scid chromosomes. Therefore, it is possible that increased sensitivity of ITSs to chromosome breakage is associated with the functional DNA double-strand break repair machinery. To investigate if this is the case we used scid cells in which DNA-PKcs deficiency was corrected. Our results revealed complete disappearance of ITSs in scid cells with functional DNA-PKcs, presumably through chromosome breakage at ITSs, but their unchanged frequency in positive and negative control cells. Therefore, our results indicate that the functional DNA double-strand break machinery is required for elevated sensitivity of ITSs to chromosome breakage. Interestingly, we observed significant differences in mitotic chromosome condensation between scid cells and their counterparts with restored DNA-PKcs activity suggesting that lack of functional DNA-PKcs may cause a defect in chromatin organization. Increased condensation of mitotic chromosomes in the scid background was also confirmed in vivo. Therefore, our results indicate a previously unanticipated role of DNA-PKcs in chromatin organisation, which could contribute to the lack of ITS sensitivity to chromosome breakage in murine scid cells.     

Involvement of telomere dysfunction in the induction of genomic instability by radiation in scid mouse cells

To determine the effects of a defect in NHEJ on the induction of genomic instability by radiation, we investigated X-ray-induced delayed chromosomal aberrations such as dicentrics and fragments in scid mouse cells. We found that radiosensitive scid mouse cells are more susceptible than wild-type mouse cells to the induction of delayed chromosomal aberrations when the cells are exposed to an equivalent survival dose of X-rays. Telomere FISH analysis revealed that radiation enhances the induction of telomeric fusions where telomeric sequences remain at the fused position (tel+ end-fusions), suggesting that radiation induces telomere dysfunction. Moreover, formation of the tel+ end-fusions was found to be enhanced in scid mouse cells, suggesting that DNA-dependent protein kinase catalytic subunit (DNA-PKcs) plays a role in telomeric stabilization. Thus, the present study suggests that a cause of genomic instability is telomere dysfunction induced by radiation and that a defect in DNA-PKcs enhances the telomeric destabilization.     

Molecular and biochemical characterisation of DNA-dependent protein kinase-defective rodent mutant irs-20.

The catalytic subunit of the DNA-dependent protein kinase (DNA-PKcs) is a member of a sub-family of phosphatidylinositol (PI) 3-kinases termed PIK-related kinases. A distinguishing feature of this sub-family is the presence of a conserved C-terminal region downstream of a PI 3-kinase domain. Mutants defective in DNA-PKcs are sensitive to ionising radiation and are unable to carry out V(D)J recombination. Irs-20 is a DNA-PKcs-defective cell line with milder gamma-ray sensitivity than two previously characterised mutants, V-3 and mouse scid cells. Here we show that the DNA-PKcs protein from irs-20 cells can bind to DNA but is unable to function as a protein kinase. To verify the defect in irs-20 cells and provide insight into the function and expression of DNA-PKcs in double-strand break repair and V(D)J recombination we introduced YACs encoding human and mouse DNA-PKcs into defective mutants and achieved complementation of the defective phenotypes. Furthermore, in irs-20 we identified a mutation in DNA-PKcs that causes substitution of a lysine for a glutamic acid in the fourth residue from the C-terminus. This represents a strong candidate for the inactivating mutation and provides supportive evidence that the extreme C-terminal motif is important for protein kinase activity.     

Function of DNA-protein kinase catalytic subunit during the early meiotic prophase without Ku70 and Ku86

All components of the double-stranded DNA break (DSB) repair complex DNA-dependent protein kinase (DNA-PK), including Ku70, Ku86, and DNA-PK catalytic subunit (DNA-PKcs), were found in the radiosensitive spermatogonia. Although p53 induction was unaffected, spermatogonial apoptosis occurred faster in the irradiated DNA-PKcs-deficient scid testis. This finding suggests that spermatogonial DNA-PK functions in DNA damage repair rather than p53 induction. Despite the fact that early spermatocytes lack the Ku proteins, spontaneous apoptosis of these cells occurred in the scid testis. The majority of these apoptotic spermatocytes were found at stage IV of the cycle of the seminiferous epithelium where a meiotic checkpoint has been suggested to exist. Meiotic synapsis and recombination during the early meiotic prophase induce DSBs, which are apparently less accurately repaired in scid spermatocytes that then fail to pass the meiotic checkpoint. The role for DNA-PKcs during the meiotic prophase differs from that in mitotic cells; it is not influenced by ionizing radiation and is independent of the Ku heterodimer.     

Signal joint formation is also impaired in DNA-dependent protein kinase catalytic subunit knockout cells

The effort to elucidate the mechanism of V(D)J recombination has given rise to a dispute as to whether DNA-dependent protein kinase catalytic subunit (DNA-PKcs) contributes to signal joint formation (sjf). Observations reported to date are confusing. Analyses using DNA-PKcs-deficient cells could not conclude the requirement of DNA-PKcs for sjf, because sjf can be formed by end-joining activities which are diverse among cells other than those participating in V(D)J recombination. Here, we observed V(D)J recombination in DNA-PKcs knockout cells and showed that both signal and coding joint formation were clearly impaired in the cells. Subsequently, to directly demonstrate the requirement of DNA-PKcs for sjf, we introduced full-length cDNA of DNA-PKcs into the knockout cells. Furthermore, several mutant DNA-PKcs cDNA constructs designed from mutant cell lines (irs-20, V3, murine scid, and SX9) were also introduced into the cells to obtain further evidence indicating the involvement of DNA-PKcs in sjf. We found as a result that the full-length cDNA complemented the aberrant sjf and that the mutant cDNAs constructs also partially complemented it. Lastly, we looked at whether the kinase activity of DNA-PKcs is necessary for sjf and, as a result, demonstrated a close relationship between them. Our observations clearly indicate that the DNA-PKcs controls not only coding joint formation but also the sjf in V(D)J recombination through its kinase activity.     

Double strand break rejoining by the Ku-dependent mechanism of non-homologous end-joining

The DNA-dependent protein kinase functions in the repair of DNA double strand breaks (DSBs) and in V(D)J recombination. To gain insight into the function of DNA-PK in this process we have carried out a mutation analysis of Ku80 and DNA-PKcs. Mutations at multiple sites within the N-terminal two thirds of Ku80 result in loss of Ku70/80 interaction, loss of DNA end-binding activity and inability to complement Ku80 defective cell lines. In contrast, mutations in the carboxy terminal region of the protein do not impair DNA end-binding activity but decrease the ability of Ku to activate DNA-PK. To gain insight into important functional domains within DNA-PKcs, we have analysed defective mutants, including the mouse scid cell line, and the rodent mutants, irs-20 and V-3. Mutational changes in the carboxy terminal region have been identified in all cases. Our results strongly suggest that the C-terminus of DNA-PKcs is required for kinase activity.     

Increased γ-H2A.X Intensity in Response to Chronic Medium-Dose-Rate γ-Ray Irradiation

Background

The molecular mechanisms of DNA repair following chronic medium-dose-rate (MDR) γ-ray-induced damage remain largely unknown.

Methodology/Principal Findings

We used a cell function imager to quantitatively measure the fluorescence intensity of γ-H2A.X foci in MDR (0.015 Gy/h and 0.06 Gy/h) or high-dose-rate (HDR) (54 Gy/h) γ-ray irradiated embryonic fibroblasts derived from DNA-dependent protein kinase mutated mice (scid/scid mouse embryonic fibroblasts (scid/scid MEFs)). The obtained results are as follows: (1) Automatic measurement of the intensity of radiation-induced γ-H2A.X foci by the cell function imager provides more accurate results compared to manual counting of γ-H2A.X foci. (2) In high-dose-rate (HDR) irradiation, γ-H2A.X foci with high fluorescence intensity were observed at 1 h after irradiation in both scid/scid and wild-type MEFs. These foci were gradually reduced through de-phosphorylation at 24 h or 72 h after irradiation. Furthermore, the fluorescence intensity at 24 h increased to a significantly greater extent in scid/scid MEFs than in wild-type MEFs in the G₁ phase, although no significant difference was observed in G₂/M-phase MEFs, suggesting that DNA-PKcs might be associated with non-homologous-end-joining-dependent DNA repair in the G₁ phase following HDR γ-ray irradiation. (3) The intensity of γ-H2A.X foci for continuous MDR (0.06 Gy/h and 0.015 Gy/h) irradiation increased significantly and in a dose-dependent fashion. Furthermore, unlike HDR-irradiated scid/scid MEFs, the intensity of γ-H2A.X foci in MDR-irradiated scid/scid MEFs showed no significant increase in the G₁ phase at 24 h, indicating that DNA repair systems using proteins other than DNA-PKcs might induce cell functioning that are subjected to MDR γ-ray irradiation.

Conclusions

Our results indicate that the mechanism of phosphorylation or de-phosphorylation of γ-H2A.X foci induced by chronic MDR γ-ray irradiation might be different from those induced by HDR γ-ray irradiation.     

Synthetic lethality between mutation in Atm and DNA-PK(cs) during murine embryogenesis

The gene product mutated in ataxia telangiectasia, ATM, is a ubiquitously expressed 370 kDa protein kinase that is a key mediator of the cellular response to DNA damage [1]. ATM-deficient cells are radiosensitive and show impaired cell cycle arrest and increased chromosome breaks in response to ionizing radiation. ATM is a member of the phosphatidylinositol-3-kinase (PI3K)-related protein kinase superfamily, which includes the catalytic subunit of DNA-dependent protein kinase (DNA-PK(cs)) and ATR [2]. DNA-PK is a 470 kDa protein kinase that is required for proper end-to-end rejoining of DNA double-strand breaks [3]. Prkdc(scid/scid) mice have a homozygous mutation in the gene encoding DNA-PK(cs) and, like Atm(-/-) mice, are viable and radiosensitive [4-8]. To determine if Atm and DNA-PK(cs) show genetic interaction, we attempted to generate mice deficient in both gene products. However, no scid/scid Atm(-/-) pups were recovered from scid/scid Atm(+/-) intercrosses. Developmental arrest of scid/scid Atm(-/-) embryos occurred around E7.5, a developmental stage when embryonic cells are hypersensitive to DNA damage [9]. This reveals synthetic lethality between mutations in Atm and DNA-PK and suggests that Atm and DNA-PK have complementary functions that are essential for development.     

UV sensitivity and impaired nucleotide excision repair in DNA-dependent protein kinase mutant cells.

DNA-dependent protein kinase (DNA-PK), a member of the phosphatidyl-inositol (PI)3-kinase family, is involved in the repair of DNA double-strand breaks. Its regulatory subunit, Ku, binds to DNA and recruits the kinase catalytic subunit (DNA-PKcs). We show here a new role of DNA-PK in the modulation of the process of nucleotide excision repair (NER) in vivo since, as compared with their respective parental cell lines, DNA-PK mutants (scid , V-3 and xrs 6 cells) exhibit sensitivity to UV-C irradiation (2.0- to 2.5-fold) and cisplatin ( approximately 3- to 4-fold) associated with a decreased activity (40-55%) of unscheduled DNA synthesis after UV-C irradiation. Moreover, we observed that wortmannin sensitized parental cells in vivo when combined with either cisplatin or UV-C light, but had no effect on the DNA-PKcs deficient scid cells. Despite a lower repair synthesis activity (approximately 2-fold) measured in vitro with nuclear cell extracts from DNA-PK mutants, a direct involvement of DNA-PK in the NER reaction in vitro has not been observed. This study establishes a regulatory function of DNA-PK in the NER process in vivo but rules out a physical role of the complex in the repair machinery at the site of the DNA lesion.     

DNA-dependent protein kinase catalytic subunit: a target for an ICE-like protease in apoptosis.

Radiosensitive cell lines derived from X-ray cross complementing group 5 (XRCC5), SCID mice and a human glioma cell line lack components of the DNA-dependent protein kinase, DNA-PK, suggesting that DNA-PK plays an important role in DNA double-strand break repair. Another enzyme implicated in DNA repair, poly(ADP-ribose) polymerase, is cleaved and inactivated during apoptosis, suggesting that some DNA repair proteins may be selectively targeted for destruction during apoptosis. Here we demonstrate that DNA-PKcs, the catalytic subunit of DNA-PK, is preferentially degraded after the exposure of different cell types to a variety of agents known to cause apoptosis. However, Ku, the DNA-binding component of the enzyme, remains intact. Degradation of DNA-PKcs was accompanied by loss of DNA-PK activity. One cell line resistant to etoposide-induced apoptosis failed to show degradation of DNA-PKcs. Protease inhibitor data implicated an ICE-like protease in the cleavage of DNA-PKcs, and it was subsequently shown that the cysteine protease CPP32, but not Mch2alpha, ICE or TX, cleaved purified DNA-PKcs into three fragments of comparable size with those observed in cells undergoing apoptosis. Cleavage sites in DNA-PKcs, determined by antibody mapping and microsequencing, were shown to be the same for CPP32 cleavage and for cleavage catalyzed by extracts from cells undergoing apoptosis. These observations suggest that DNA-PKcs is a critical target for proteolysis by an ICE-like protease during apoptosis.     

SCID in Jack Russell terriers: a new animal model of DNA-PKcs deficiency

We recently described the incidence of a SCID disease in a litter of Jack Russell terriers. In this study, we show that the molecular defect in these animals is faulty V(D)J recombination. Furthermore, we document a complete deficit in DNA-dependent protein kinase activity that can be explained by a marked diminution in the expression of the catalytic subunit DNA-dependent protein kinase catalytic subunit (DNA-PKcs). We conclude that as is the case in C.B-17 SCID mice and in Arabian SCID foals, the defective factor in these SCID puppies is DNA-PKcs. In mice, it has been clearly established that DNA-PKcs deficiency produces an incomplete block in V(D)J recombination, resulting in "leaky" coding joint formation and only a modest defect in signal end ligation. In contrast, DNA-PKcs deficiency in horses profoundly blocks both coding and signal end joining. Here, we show that although DNA-PKcs deficiency in canine lymphocytes results in a block in both coding and signal end joining, the deficit in both is intermediate between that seen in SCID mice and SCID foals. These data demonstrate significant species variation in the absolute necessity for DNA-PKcs during V(D)J recombination. Furthermore, the severity of the V(D)J recombination deficits in these three examples of genetic DNA-PKcs deficiency inversely correlates with the relative DNA-PK enzymatic activity expressed in normal fibroblasts derived from these three species.     

Mutational analysis of all conserved basic amino acids in RAG-1 reveals catalytic, step arrest, and joining-deficient mutants in the V(D)J recombinase

Although both RAG-1 and RAG-2 are required for all steps of V(D)J recombination, little is known about the specific contribution of either protein to these steps. RAG-1 contains three acidic active-site amino acids that are thought to coordinate catalytic metal ions. To search for additional catalytic amino acids and to better define the functional anatomy of RAG-1, we mutated all 86 conserved basic amino acids to alanine and evaluated the mutant proteins for DNA binding, nicking, hairpin formation, and joining. We found several amino acids outside of the canonical nonamer-binding domain that are critical for DNA binding, several step arrest mutants with defects in nicking or hairpin formation, and four RAG-1 mutants defective specifically for joining. Analysis of coding joints formed by some of these mutants revealed excessive deletions, frequent use of short sequence homologies, and unusually long palindromic junctional inserts, known as P nucleotides, that result from aberrant hairpin opening. These features characterize junctions found in scid mice, which are deficient for the catalytic subunit of DNA-dependent protein kinase (DNA-PKcs), suggesting that the RAG proteins and DNA-PKcs perform overlapping functions in coding joint formation. Interestingly, the amino acids that are altered in 12 of our mutants are also mutated in human inherited immunodeficiency syndromes. Our analysis of these mutants provides insights into the molecular mechanisms underlying these disorders.     

Functional interaction between DNA-PKcs and telomerase in telomere length maintenance

DNA-PKcs is the catalytic subunit of the DNA-dependent protein kinase (DNA-PK) complex that functions in the non-homologous end-joining of double-strand breaks, and it has been shown previously to have a role in telomere capping. In particular, DNA-PKcs deficiency leads to chromosome fusions involving telomeres produced by leading-strand synthesis. Here, by generating mice doubly deficient in DNA-PKcs and telomerase (Terc(-/-)/DNA-PKcs(-/-)), we demonstrate that DNA-PKcs also has a fundamental role in telomere length maintenance. In particular, Terc(-/-)/DNA-PKcs(-/-) mice displayed an accelerated rate of telomere shortening when compared with Terc(-/-) controls, suggesting a functional interaction between both activities in maintaining telomere length. In addition, we also provide direct demonstration that DNA-PKcs is essential for both end-to-end fusions and apoptosis triggered by critically short telomeres. Our data predict that, in telomerase-deficient cells, i.e. human somatic cells, DNA-PKcs abrogation may lead to a faster rate of telomere degradation and cell cycle arrest in the absence of increased apoptosis and/or fusion of telomere-exhausted chromosomes. These results suggest a critical role of DNA-PKcs in both cancer and aging.     

Accessibility of chromosomal recombination breaks in nuclei of wild-type and DNA-PKcs-deficient cells

V(D)J recombination is a highly regulated process, proceeding from a site-specific cleavage to an imprecise end joining. After the DNA excision catalyzed by the recombinase encoded by recombination activating genes 1 and 2 (RAG1/2), newly generated recombination ends are believed held by a post-cleavage complex (PC) consisting of RAG1/2 proteins, and are subsequently resolved by non-homologous end joining (NHEJ) machinery. The relay of these ends from PC to NHEJ remains elusive. It has been speculated that NHEJ factors modify the RAG1/2-PC to gain access to the ends or act on free ends after the disassembly of the PC. Thus, recombination ends may either be retained in a complex throughout the recombination process or left as unprotected free ends after cleavage, a condition that may permit an alternative, non-classical NHEJ end joining pathway. To directly test these scenarios on recombination induced chromosomal breaks, we have developed a recombination end protection assay to monitor the accessibility of recombination ends to exonuclease-V in intact nuclei. We demonstrate that these ends are well protected in the nuclei of wild-type cells, suggesting a seamless cleavage-joining reaction. However, divergent end protection of coding versus signal ends was found in cells derived from severe combined immunodeficient (scid) mice that are defective in the catalytic subunit of DNA-dependent protein kinase (DNA-PKcs). While signal ends are resistant, opened coding ends are susceptible to enzymatic modification. Our data suggests a role of DNA-PKcs in protecting chromosomal coding ends. Furthermore, using recombination inducible scid cell lines, we demonstrate that conditional protection of coding ends is inversely correlated with the level of their resolution, i.e., the greater the accessibility of the coding ends, the higher level of coding joints formed. Taken together, our findings provide important insights into the resolution of recombination ends by error-prone alternative NHEJ pathways.     

The ability of p53 to activate downstream genes p21(WAF1/cip1) and MDM2, and cell cycle arrest following DNA damage is delayed and attenuated in scid cells deficient in the DNA-dependent protein kinase

scid mouse embryonic fibroblasts are deficient in DNA-dependent protein kinase activity due to a mutation in the C-terminal domain of the catalytic subunit (DNA-PKcs). When exposed to ionizing radiation, the increase in levels of p53 was the same as in normal mouse embryonic fibroblasts. However, the rise in p21(WAF1/cip1) and mdm2 was found to be delayed and attenuated, which correlated in time with delayed onset of G1/S arrest by flow cytometric analysis. The p53-dependent G1 checkpoint was not eliminated: inactivation of p53 by the E6 protein in scid cells resulted in the complete loss of detectable G1/S arrest after DNA damage. Immunofluorescence analysis of normal cells revealed p53 to be localized predominantly within the cytoplasm prior to irradiation and then translocate to the nucleus after irradiation. In contrast, scid cells show abnormal accumulation of p53 in the nucleus independent of irradiation, which was confirmed by immunoblot analysis of nuclear lysates. Taken together, these data suggest that loss of DNA-PK activity appears to attenuate the kinetics of p53 to activate downstream genes, implying that DNA-PK plays a role in post-translational modification of p53, without affecting the increase in levels of p53 in response to DNA damage.