Involvement of protein kinase C-related anti-apoptosis signaling in radiation-induced apoptosis in murine thymic lymphoma(3SBH5) cells

Protein kinase C (PKC; also known as PRKC) is known to be an important participant in radiation-induced apoptosis. However, its role is not fully clarified. Using 3SBH5 cells, which are radiation-sensitive thymic lymphoma cells, the involvement and functions of PKC were assessed in radiation- induced apoptosis. PMA (phorbol 12-myristate 13-acetate), a PKC activator, inhibited the radiation-induced apoptosis in 3SBH5 cells. On the other hand, chelerythrine, a PKC inhibitor, potentiated apoptosis. In addition, G?6976, a classical PKC (cPKC) inhibitor, which specifically inhibits PKC (alpha and betaI), also promoted apoptosis. Interestingly, post-treatment (20 min after irradiation) with G?6976 had no effect on the radiation-induced apoptosis. These results suggest that cPKC is activated early after irradiation for anti-apoptosis signaling and contributes to the balance between cell survival and death. Indeed, an increase of cPKC activity involving PKC (alpha, betaI and betaII) was observed in the cytosolic fraction 3 min after irradiation with 0.5 Gy. However, no translocation of cPKC was observed in the cells after irradiation. Our findings indicate that activation of cPKC (alpha or beta) soon after irradiation is critical to the understanding of the regulation of radiation-induced apoptosis in radiation-sensitive cells.     

Effect of Atm disruption on spontaneously arising and radiation-induced deletion mutations in mouse liver

Deletion mutations were efficiently recovered in mouse liver after total-body irradiation with X rays by using a transgenic mouse "gpt-delta" system that harbored a lambda EG10 shuttle vector with the red and gam genes for Spi- (sensitive to P2 lysogen interference) selection. We incorporated this system into homozygous Atm-knockout mice as a model of the radiosensitive hereditary disease ataxia telangiectasia (AT). Lambda phages recovered from the livers of X-irradiated mice with the Atm+/+ genotype showed a dose-dependent increase in the Spi- mutant frequency up to sixfold at 50 Gy over the unirradiated control of 2.8x10(-6). The livers from Atm-/- mice yielded a virtually identical dose-response curve for X rays with a background fraction of 2.4x10(-6). Structural analyses revealed no significant difference in the proportion of -1 frameshifts and larger deletions between Atm+/+ and Atm-/- mice, although larger deletions prevailed in X-ray-induced Spi- mutants irrespective of Atm status. While a possible defect in DNA repair after irradiation has been strongly indicated in the literature for nondividing cultured cells in vitro from AT patients, the Atm disruption does not significantly affect radiation mutagenesis in the stationary mouse liver in vivo.     

ATM controls c-Myc and DNA synthesis during postnatal thymocyte development through regulation of redox state

The oncoprotein c-Myc is essential for thymocyte development, and its dysregulation causes lymphoid malignancies. We have demonstrated previously that spontaneous DNA synthesis in Atm(-/-) thymocytes is markedly increased over that of Atm(+/+) thymocytes and that glucocorticoid dexamethasone suppresses thymocyte DNA synthesis and prevents the ultimate development of thymic lymphoma in Atm(-/-) mice. Recently, we reported that in Atm(-/-) thymic lymphoma cells c-Myc is overexpressed compared with the levels of c-Myc in primary thymocytes from wild-type or Atm(-/-) mice. In this study, we show that c-Myc expression progressively increases with age in primary thymocytes from Atm(-/-) mice and that the upregulation of c-Myc parallels the elevated DNA synthesis in the cells, suggesting that deregulation of c-Myc may drive the uncontrolled proliferation of thymocytes in Atm(-/-) mice. Here we also demonstrate that Atm(-/-) thymocytes exhibit increased levels of hydrogen peroxide, NF-E2-related factor (Nrf-2), peroxiredoxin-1, and intracellular glutathione relative to thymocytes from Atm(+/+) mice. Importantly, reduction of hydrogen peroxide by administration of the antioxidant N-acetylcysteine to Atm(-/-) mice attenuates the elevation of Nrf-2, c-Myc, and DNA synthesis in their thymocytes, suggesting that ATM may control c-Myc and DNA synthesis during postnatal thymocyte development by preventing accumulation of reactive oxygen species.     

Ataxia-telangiectasia mutated is not required for p53 induction and apoptosis in irradiated epithelial tissues

The ataxia-telangiectasia mutated (Atm) protein kinase is a central regulator of the cellular response to DNA damage. Although Atm can regulate p53, it is not known if this Atm function varies between tissues. Previous studies showed that the induction of p53 and apoptosis by whole-body ionizing radiation varies greatly between tissue and tumor types, so here we asked if Atm also had a tissue-specific role in the ionizing radiation response. Irradiated Atm-null mice showed impaired p53 induction and apoptosis in thymus, spleen, and brain. In contrast, radiation-induced p53, apoptosis, phosphorylation of Chk2, and G(2)-M cell cycle arrest were slightly delayed in Atm(-/-) epithelial cells of the small intestine but reached wild-type levels by 4 h. Radiation-induced p53 and apoptosis in Atm(-/-) hair follicle epithelial cells were not impaired at any of the time points examined. Thus, Atm is essential for radiation-induced apoptosis in lymphoid tissues but is largely dispensable in epithelial cells. This indicates that marked differences in DNA damage signaling pathways exist between tissues, which could explain some of the tissue-specific phenotypes, especially tumor suppression, associated with Atm deficiency.     

Protein kinase Cdelta overexpression enhances radiation sensitivity via extracellular regulated protein kinase 1/2 activation, abolishing the radiation-induced G(2)-M arrest.

Protein kinase C (PKC) has been widely implicated in regulation ofcell growth/cell cycle progression and apoptosis. However,the role of PKCdelta in radiosensitivity and cell cycle regulation remains unclear. Overexpression of PKCdelta increased Ca2+-independent PKC activity without altering other PKC isoforms (PKCalpha, -beta1, -epsilon, and -zeta), and extracellular regulated protein kinase (ERK) 1/2 activity was also increased in PKCdelta-specific manner. A clonogenic survival assay showed that PKCdelta-overexpressed cells had more radiosensitivity and pronounced induction of apoptosis than control cells. Flow cytometric analysis revealed that PKCdelta made the cells escape from radiation-induced G(2)-M arrest. Moreover, p53 and p21(Waf) induction by radiation were higher in PKCdelta-overexpressed cells than control cells, and PKCdelta-mediated apoptosis was reduced, when radiation-induced ERK1/2 activity was inhibited by PD98059. Furthermore, PKCdelta antisense and rottlerin, PKC inhibitor-abrogated PKCdelta-mediated radiosensitivity and reduced ERK1/2 activity to the control vector level. These results demonstrated that PKCdelta overexpression enhanced radiation-induced apoptosis and radiosensitivity via ERK1/2 activation, thereby abolishing the radiation-induced G(2)-M arrest and finally apoptosis.     

Existence of a threshold-like dose for gamma-ray induction of thymic lymphomas and no susceptibility to radiation-induced solid tumors in SCID mice

Severe combined immune deficiency (SCID) mice exhibit limited repair of DNA double-strand breaks and are sensitive to ionizing radiation due to a mutation of the DNA-dependent protein kinase catalytic subunit gene. To elucidate the effects of deficient DNA double-strand break repair on radiation-induced carcinogenesis, the dose-response relationship for the induction of all tumor types was examined in wild-type and SCID mice. In wild-type mice, the incidence of thymic lymphomas at gamma-ray doses up to 1 Gy was almost equal to the background level, increased gradually above 1 Gy, and reached a maximum of 12.5% at 5 Gy, which is indicative of a threshold dose of less than 1 Gy. SCID mice were extremely susceptible to the induction of spontaneous and radiation-induced thymic lymphomas. The incidence of thymic lymphomas in SCID mice irradiated with 0.1 Gy or less was similar to the background level; that is, it increased markedly from 31.7% at 0.1 Gy to 51.4% at 0.25 Gy, and reached a maximum of 80.6% at 2 Gy, suggesting the presence of a threshold-like dose at low gamma-ray doses, even in radiosensitive SCID mice. As the average latency for the induction of thymic lymphomas at 0.1 Gy was significantly shortened, the effect of 0.1 Gy gamma-rays on thymic lymphoma induction was marginal. The high susceptibility of SCID mice to develop thymic lymphomas indicates that thymic lymphomas are induced by a defect in DNA double-strand break repair or V(D)J recombination. Excessive development of tumors other than thymic and nonthymic lymphomas was not observed in SCID mice. Furthermore, our data suggest that the defective double-strand break repair in SCID mice is not a major determinant for the induction of nonlymphoid tumors.     

Caspase activation and disruption of mitochondrial membrane potential during UV radiation-induced apoptosis of human keratinocytes requires activation of protein kinase C.

The induction of apoptosis in human keratinocytes by UV radiation involves caspase-mediated cleavage and activation of protein kinase C delta (PKCdelta). Here we examined the role of PKC activation in caspase activation and disruption of mitochondria function by UV radiation. Inhibition of PKC partially blocked UV radiation-induced cleavage of PKCdelta, pro-caspase-3, and pro-caspase-8, and the activation of these caspases. PKC inhibition also blocked the UV-induced loss of mitochondria membrane potential, but did not block the release of cytochrome c from mitochondria. Expression of the active catalytic domain of PKCdelta was sufficient to induce apoptosis and disrupt mitochondrial membrane potential, however a kinase inactive PKCdelta catalytic domain did not. Furthermore, the PKCdelta catalytic fragment generated following UV radiation localized to the mitochondria fraction, as did ectopically expressed PKCdelta catalytic domain. These results identify a functional role for PKC activation in potentiating caspase activation and disrupting mitochondrial function during UV-induced apoptosis.     

Thymic hormones in radiation-induced immunodeficiency. I. Induction of mature interleukin 1 responsive cell in the thymus by thymosin fraction 5

The restorative effect of thymosin fraction 5 (TF5) on the thymus of gamma-irradiated mice was examined. Four different mouse strains were used in this study since earlier work determined that the degree of response to TF5 is strain dependent. The responsiveness to comitogenic effect of interleukin 1 (IL-1) was used to measure the rate of recovery of immunocompetent cells in the thymus, since only more mature PNA-, Lyt-1+-2- medullary cells respond to this monokine. Contrary to several earlier reports that radioresistant cells repopulating the thymus within the first 10 days after irradiation are mature, corticosteroid resistant, immunocompetent cells, the thymic cells from irradiated mice in all strains used had greatly reduced responses to IL-1. Daily intraperitoneal injections of TF5 increased significantly the responses of thymic cells to IL-1 in 10- to 13-weeks-old C57Bl/KsJ, C57Bl/6, C3H/HeJ, and DBA/1 mice. Older mice, 5 months or more in age, of DBA/1 strain did not respond to treatment with TF5. However, C3H/HeJ mice of the same age were highly responsive. In conclusion, (1) cells repopulating the thymus within 12 days after irradiation contain lower than normal fraction of mature IL-1 responsive cells, (2) thymic hormones increase the rate of recovery of immunocompetent cells in the thymus, and (3) the effect of thymic hormones is strain and age dependent.     

Suppression of apoptosis in the protein kinase Cdelta null mouse in vivo

Protein kinase C (PKC) delta is an essential regulator of mitochondrial dependent apoptosis in epithelial cells. We have used the PKCdelta(-/-) mouse to ask if loss of PKCdelta protects salivary glands against gamma-irradiation-induced apoptosis in vivo and to explore the mechanism underlying protection from apoptosis. We show that gamma-irradiation in vivo results in a robust induction of apoptosis in the parotid glands of wild type mice, whereas apoptosis is suppressed by greater than 60% in the parotid glands of PKCdelta(-/-) mice. Primary parotid cells from PKCdelta(-/-) mice are defective in mitochondrial dependent apoptosis as indicated by suppression of etoposide-induced cytochrome c release, poly(ADP-ribose) polymerase cleavage, and caspase-3 activation. Notably, apoptotic responsiveness can be restored by re-introduction of PKCdelta by adenoviral transduction. Etoposide and gamma-irradiation-induced activation of p53 is similar in primary parotid cells and parotid glands from PKCdelta(+/+) and PKCdelta(-/-) mice, indicating that PKCdelta functions downstream of the DNA damage response. In contrast, activation of the c-Jun amino-terminal kinase is reduced in primary parotid cells from PKCdelta(-/-) cells and in parotid C5 cells, which express a dominant inhibitory mutant of PKCdelta. Similarly, c-Jun amino-terminal kinase activation is suppressed in vivo in gamma-irradiated parotid glands from PKCdelta(-/-) mice. These studies indicate an essential role for PKCdelta downstream of the p53 response and upstream of the c-Jun amino-terminal kinase activation in DNA damage-induced apoptosis in vivo and in vitro.     

Correlation between unirradiated cell TP53 protein levels and radiosensitivity in MOLT-4 cells.

MOLT-4 cells undergo apoptosis after X irradiation. A radiosensitive variant, MOLT-4N1, and a radioresistant variant, MOLT-4N2, have been studied with respect to their radiosensitivity and its relationship to the levels of TP53 protein (formerly known as p53). X irradiation induces apoptosis in both cell lines with the following difference: The induction of apoptosis in MOLT-4N2 cells occurred later than in MOLT-4N1 cells as determined by the morphological changes and DNA fragmentation. The levels of cell death measured by the dye exclusion test coincided with the levels of apoptosis in both cell lines, suggesting that radiation-induced cell killing is determined by the induction of apoptosis. Unirradiated MOLT-4N1 cells contained a significantly higher intracellular level of TP53 protein and a much higher level of TP53 mRNA compared to MOLT-4N2 cells. X irradiation led to an accumulation of TP53 protein in both cell lines that was greater in MOLT-4N1 cells. This accumulation of TP53 protein preceded changes in DNA degradation and ladder formation and in nuclear morphology. These results strongly suggest that the radiosensitivity of MOLT-4 cells correlates well with the unirradiated control levels of TP53 mRNA and TP53 protein, and that the quantitative levels of TP53 protein must reach a threshold for the cells to undergo apoptosis.     

Acquisition of functional MHC class II/peptide complexes by T cells during thymic development and CNS-directed pathogenesis

This study provides evidence that both rat and mouse thymic and splenic T cells express significant levels of MHC class II glycoproteins (MHCII) in vivo. Derivation of rat and mouse chimeras revealed that a major source of MHCII on thymic T cells was acquired from radioresistant host APC. Expression of MHC on thymic T cells appeared physiologically relevant because presentation of rat myelin basic protein (RMBP) by nonadherent, radiosensitive thymic T cells was associated with the adoptive transfer of tolerance. Mature MBP-specific effector T cells isolated from the CNS in both rat and mouse models of EAE also expressed significant levels of MHCII. Adoptive transfer of activated B10.PL MBP/I-A(u)-restricted TCR transgenic T cells into F1(C57BL/6 x B10.PL) mice revealed acquisition of allogeneic I-A(b) on encephalitogenic CNS-derived T cells. Overall, this study indicates that immature and mature T cells in rats and mice acquire functional MHCII in vivo during thymic development and pathogenic inflammation.     

MiR-467a is Upregulated in Radiation-Induced Mouse Thymic Lymphomas and Regulates Apoptosis by Targeting Fas and Bax

It has been reported dysregulation of certain microRNAs (miRNAs / miRs) is involved in tumorigenesis. However, the miRNAs associated with radiocarcinogenesis remain undefined. In this study, we validated the upregulation of miR-467a in radiation-induced mouse thymic lymphoma tissues. Then, we investigated whether miR-467a functions as an oncogenic miRNA in thymic lymphoma cells. For this purpose, we assessed the biological effect of miR-467a on thymic lymphoma cells. Using miRNA microarray, we found four miRNAs (miR-467a, miR-762, miR-455 and miR-714) were among the most upregulated (>4-fold) miRNAs in tumor tissues. Bioinformatics prediction suggests miR-467a may potentially regulate apoptosis pathway via targeting Fas and Bax. Consistently, in miR-467a-transfected cells, both proliferation and colony formation ability were significantly increased with decrease of apoptosis rate, while, in miR-467a-knockdown cells, proliferation was suppressed with increase of apoptosis rate, indicating that miR-467a may be involved in the regulation of apoptosis. Furthermore, miR-467a-knockdown resulted in smaller tumors and better prognosis in an in vivo tumor-transplanted model. To explain the mechanism of apoptosis suppression by miR-467a, we explore the expression of candidate target genes (Fas and Bax) in miR-467a-transfected relative to negative control transfected cells using flow cytometry and immunoblotting. Fas and Bax were commonly downregulated in miR-467a-transfected EL4 and NIH3T3 cells, and all of the genes harbored miR-467a target sequences in the 3''UTR of their mRNA. Fas and Bax were actually downregulated in radiation-induced thymic lymphoma tissues, and therefore both were identified as possible targets of miR-467a in thymic lymphoma. To ascertain whether downregulation of Fas and / or Bax is involved in apoptosis suppression by miR-467a, we transfected vectors expressing Fas and Bax into miR-467a-upregulated EL4 cells. Then we found that both Fas- and Bax-overexpression decreased cell viability with increase of apoptosis rate, indicating that downregulation of Fas and Bax may be at least partly responsible for apoptosis suppression by miR-467a. These data suggest that miR-467a may have oncogenic functions in radiation-induced thymic lymphoma cells and that its increased expression may confer a growth advantage on tumor cells via aberrant expression of Fas and Bax.     

X-ray-induced telomeric instability in Atm-deficient mouse cells

The gene responsible for ataxia telangiectasia (AT) encodes ATM protein, which plays a major role in the network of a signal transduction initiated by double strand DNA breaks. To determine how radiation-induced genomic instability is modulated by the dysfunction of ATM protein, we examined radiation-induced delayed chromosomal instability in individual cell lines established from wild-type Atm(+/+), heterozygote Atm(+/-), and knock-out Atm(-/-) mouse embryos. The results indicate that Atm(-/-) mouse cells are highly susceptible to the delayed induction of telomeric instability and end-to-end chromosome fusions by radiation in addition to the elevated spontaneous telomeric instability detected by telomere fluorescence in situ hybridization (FISH). The telomeric instability was characterized by abnormal telomere FISH signals, including loss of the signals and the extra-chromosomal signals that were associated and/or not associated with chromosome ends, suggesting that Atm deficiency makes telomeres vulnerable to breakage. Thus, the present study shows that Atm protein plays an essential role in maintaining telomere integrity and prevents chromosomes from end-to-end fusions, indicating that telomeres are a target for the induction of genomic instability by radiation.     

Knocking out peroxisome proliferator-activated receptor (PPAR) alpha inhibits radiation-induced apoptosis in the mouse kidney through activation of NF-kappaB and increased expression of IAPs

Peroxisome proliferator-activated receptor (PPAR) alpha, a member of the ligand-activated nuclear receptor superfamily, plays an important role in lipid metabolism and glucose homeostasis and is highly expressed in the kidney. The present studies were aimed at testing the hypothesis that PPARalpha knockout mice would exhibit decreased radiation-induced apoptosis due to exacerbated activation of NF-kappaB (NFKB) and expression of pro-survival factors. Thirty wild-type mice (29S1/SvImJ) and 30 PPARalpha knockout mice were irradiated with a single total-body dose 10 Gy of (137)Cs gamma rays; controls were sham-irradiated. Tissue samples were collected at 3, 6, 12, 24 and 48 h postirradiation. Apoptosis was quantified using immunohistochemical staining for apoptotic bodies and cleaved caspase 3. Radiation-induced apoptosis was observed in both mouse strains in a time-dependent manner. However, the level of apoptosis was significantly suppressed in PPARalpha knockout mice compared with wild-type mice at 6 h postirradiation (P < 0.05). This inhibition of radiation-induced apoptosis was associated with time-dependent increases in NF-kappaB DNA-binding activity, IkappaBalpha phosphorylation, and expression of other antiapoptosis factors in the PPARalpha knockout mouse kidneys but not in wild-type animals. These data support the hypothesis that the loss of PPARalpha expression leads to the suppression of radiation-induced apoptosis in the mouse kidney, mediated through activation of NF-kappaB and up-regulation of anti-apoptosis factors.     

A chromosome 15 quantitative trait locus controls levels of radiation-induced jejunal crypt cell apoptosis in mice

Jejunal crypt cells undergo apoptosis in response to ionizing radiation exposure. In mice the number of cells deleted by apoptosis is determined by several factors including the dose of radiation, the time of day the apoptosis level is quantified, and the strain of mouse irradiated. We previously found that the difference in radiation-induced apoptosis levels between C57BL/6J (B6) and C3Hf/Kam (C3H) mice is controlled by multiple genes, and this set of genes is distinct from that controlling thymocyte apoptosis levels in the same strain combination. Here, we report that a new quantitative trait locus on chromosome 15, Rapop5, partly accounts for the murine strain difference in susceptibility to radiation-induced jejunal crypt cell apoptosis. In addition, we show sexual dimorphism in the extent of radiation-induced jejunal crypt cell apoptosis, with female mice having higher levels.     

Protein kinase A inhibitors enhance radiation-induced apoptosis

In addition to a role for de novo protein synthesis in apoptosis we have previously shown that activation of a protein phosphatase or loss of activity of a kinase is also important in radiation-induced apoptosis in human cells [Baxter, and Lavin (1992): J Immunol 148:149–1954]. We show here that some inhibitors of protein kinases exacerbate radiation-induced apoptosis in the human cell line BM13674. The specific protein kinase A inhibitor isoquinoline sulfonamide (20 μM) gave rise to significantly increased levels of apoptosis at 2–6 h postirradiation compared to values after radiation exposure only. The same concentration of isoquinolinesulfonamide, which was effective in increasing apoptosis, reduced activity markedly. A 66% inhibition of cyclic AMP-dependent protein kinase A activity occurred in unirradiated cells at this concentration of H89 and activity was reduced to 58% in irradiated cells. Calphostin C, a specific inhibitor of protein kinase C, at a concentration of 0.1 μM, which caused 68% inhibition of enzyme activity in irradiated cells, failed to enhance the level of radiation-induced apoptosis. Other kinase inhibitors did not lead to an additional increase in apoptosis over and above that observed after irradiation. The results obtained here provide further support for an important role for modification of existing proteins during radiation-induced apoptosis.     

Adaptive response in embryogenesis. III. Relationship to radiation-induced apoptosis and Trp53 gene status

We reported previously that a radiation-induced adaptive response existed in the late period of embryogenesis, and that radiation-induced apoptosis in the predigital regions was responsible for digital defects in embryonic ICR mice. To investigate the possible involvement of the Trp53 gene and radiation-induced apoptosis in radiation-induced adaptive responses in embryogenesis, the present study was conducted using Trp53 wild-type (Trp53(+/+)) and Trp53 heterozygous (Trp53(+/-)) embryonic mice of the C57BL/6 strain. The existence of a radioadaptive response in the Trp53(+/+) embryonic mice was demonstrated by irradiating the embryos with 5 or 30 cGy on embryonic day 11 prior to a challenging irradiation at 3 Gy on embryonic day 12. The two conditioning doses at 5 and 30 cGy significantly suppressed the induction of apoptosis by the challenging dose in the predigital regions of limb buds in the Trp53(+/+) embryonic mice, while no such effect was found in the Trp53(+/-) embryonic mice. These findings indicate that induction of a radioadaptive response in embryogenesis is related to Trp53 gene status and the occurrence of radiation-induced apoptosis.     

Autophagy for cancer therapy through inhibition of pro-apoptotic proteins and mammalian target of rapamycin signaling

Autophagy is an alternative cell death pathway that is induced by mammalian target of rapamycin (mTOR) inhibitors and up-regulated when apoptosis is defective. We investigated radiation-induced autophagy in the presence or absence of Bax/Bak with or without an mTOR inhibitor, Rad001. Two isogenic cell lines, wild type (WT) and Bak/Bak(-/-) mouse embryonic fibroblasts and tumor cell lines were used for this study. Irradiated Bak/Bak(-/-) cells had a decrease of Akt/mTOR signaling and a significant increase of pro-autophagic proteins ATG5-ATG12 COMPLEX and Beclin-1. These molecular events resulted in an up-regulation of autophagy. Bax/Bak(-/-) cells were defective in undergoing apoptosis but were more radiosensitive than the WT cells in autophagy. Both autophagy and sensitization of Bak/Bax(-/-) cells were further enhanced in the presence of Rad001. In contrast, inhibitors of autophagy rendered the Bak/Bax(-/-) cells radioresistant, whereas overexpression of ATG5 and Beclin-1 made the WT cells radiosensitive. When this novel concept of radiosensitization was tested in cancer models, small interfering RNAs against Bak/Bax also led to increased autophagy and sensitization of human breast and lung cancer cells to gamma radiation, which was further enhanced by Rad001. This is the first report to demonstrate that inhibition of pro-apoptotic proteins and induction of autophagy sensitizes cancer cells to therapy. Therapeutically targeting this novel pathway may yield significant benefits for cancer patients.     

Dose-effect relationship for X-ray-induced reciprocal translocations in mouse spermatogonia following pretreatment with 3-aminobenzamide

The influence of 3-aminobenzamide (3-AB) pretreatment on the dose-response relationship for radiation-induced reciprocal translocations in mouse spermatogonial stem cells was studied. The results show that at doses of 3-10 Gy of X-rays the frequencies of translocations were higher in 3-AB-pretreated animals as compared to animals that received X-rays only. The 3-AB pretreatment was not effective at dose levels of 1 and 2 Gy. The shape of the dose-effect curve was similar to that obtained without 3-AB pretreatment, i.e., a humped curve, but the initial slope was clearly steeper and the position of the peak was shifted from 7 to 9 Gy. The effects observed can be explained by a 3-AB-mediated sensitization of normally radioresistant stem cells that are at the stage of stimulation to enter the mitotic cycle, thus increasing the population of radiosensitive spermatogonial stem cells.     

Tumor suppression by p53 in the absence of Atm

Oncogenes can induce p53 through a signaling pathway involving p19/Arf. It was recently proposed that oncogenes can also induce DNA damage, and this can induce p53 through the Atm DNA damage pathway. To assess the relative roles of Atm, Arf, and p53 in the suppression of Ras-driven tumors, we examined susceptibility to skin carcinogenesis in 7,12-dimethylbenz(a)anthracene/12-O-tetradecanoylphorbol-13-acetate (TPA)-treated Atm- and p53-deficient mice and compared these results to previous studies on Arf-deficient mice. Mice with epidermal-specific deletion of p53 showed increased papilloma number and progression to malignant invasive carcinomas compared with wild-type littermates. In contrast, Atm-deficient mice showed no increase in papilloma number, growth, or malignant progression. gamma-H2AX and p53 levels were increased in both Atm(+/+) and Atm(-/-) papillomas, whereas Arf(-/-) papillomas showed much lower p53 expression. Thus, although there is evidence of DNA damage, signaling through Arf seems to regulate p53 in these Ras-driven tumors. In spontaneous and radiation-induced lymphoma models, tumor latency was accelerated in Atm(-/-)p53(-/-) compound mutant mice compared with the single mutant Atm(-/-) or p53(-/-) mice, indicating cooperation between loss of Atm and loss of p53. Although p53-mediated apoptosis was impaired in irradiated Atm(-/-) lymphocytes, p53 loss was still selected for during lymphomagenesis in Atm(-/-) mice. In conclusion, in these models of oncogene- or DNA damage-induced tumors, p53 retains tumor suppressor activity in the absence of Atm.