Kinetics of unscheduled DNA synthesis in UV-irradiated chicken embryo fibroblasts

Unscheduled DNA synthesis induced by 254-nm UV radiation in chicken embryo fibroblasts was examined for 24 h following irradiation, while cells were kept in the dark. The effect on this repair process of a 2-4 h exposure to photoreactivating light immediately after UV was studied. Initial [3H]thymidine incorporation in the light-treated cells was only slightly different from that in cells not exposed to light, but a distinct difference in rate and cumulative amount of unscheduled DNA synthesis was seen several hours after irradiation. By varying the UV dose and the time allowed for photoreactivation, the amount of dimers (determined as sites sensitive to a M. luteus UV-endonuclease) and non-dimers could be changed. The results of these experiments suggest that excision repair of dimers, rather than non-dimer products, is responsible for the unscheduled DNA synthesis seen after UV irradiation.     

Differential spermatogonial stem-cell survival and mutation frequency

One group of adult C3H×101 hybrid male mice was given 3 injections of 12.5 μCi of [³H]thymidine at 9-h intervals and irradiated 24 h after the last injection with X-ray doses of 100, 300, 500, 600, 1000 R or the first fraction of a split 1000-R dose given as two 500-R exposures 24 h apart. Mice were killed 207 and 414 h after irradiation. A second group of mice was given a single injection of 12.5 μCi of [³H]thymidine 1 h before irradiation with single exposures of 300, 500, 600, 1000 R, or the first fraction of a 1000-R exposure given as two 500-R fractions 24 h apart. Mice were killed 120 and 207 h after irradiation. In both experiments, parallel groups of mice were given X-ray only as a control for the effect of [³H]thymidine. Two sets of slides were prepared for each mouse receiving [³H]thymidine: one set was not autoradiographed and was used for scoring cell survival; the second set was coated with emulsion and used for scoring percentage of labeled cells. The dose-response curves for survival at 120 and 207 h were curvilinear, with no evidence of discontinuity over the 100–1000-R range. After multiple injections of [³H]thymidine and irradiation 24 h later, percentage of labeled cells at 207 h was comparable for controls, 100, 300, and 600 R; significantly lower than controls for 1000 R; and significantly above controls after 500 + 500 R. Thus the surviving stem-cell population was qualitatively the same for that portion of the dose-response curve giving a linear increase in mutation rate but was different for both 1000-R and 500 + 500-R exposures, and the single and fractionated 1000-R exposures differed from each other. This parallelism between survival of labeled cells and mutation frequency in spermatogonial stem cells suggests that a stage in the cell cycle 24–42 h after DNA synthesis is resistant to cell killing but sensitive to mutation induction. The mutation rate after a single 1000-R exposure is low because labeled, mutation-sensitive cells have been selectively killed. Mutation frequency after the 500 + 500-R dose is increased because of synchronization induced by the first dose combined with selective killing of unlabeled cells by the second fraction. Irradiation 1 h after labeling with [³H]-thymidine demonstrated that the S phase of the spermatogonial stem-cell cycle is sensitive to radiation-induced cell killing.     

Pulmonary injury after combined exposures to low-dose low-LET radiation and fungal spores

Exposure to infectious microbes is a likely confounder after a nuclear terrorism event. In combination with radiation, morbidity and mortality from an infection may increase significantly. Pulmonary damage after low-dose low-LET irradiation is characterized by an initial diffuse alveolar inflammation. By contrast, inhaled fungal spores produce localized damage around pulmonary bronchioles. In the present study, we assessed lung injury in C57BL/6 mice after combined exposures to whole-body X radiation and inhaled fungal spores. Either animals were exposed to Aspergillus spores and immediately irradiated with 2 Gy, or the inoculation and irradiation were separated by 8 weeks. Pulmonary injury was assessed at 24 and 48 h and 1, 2, 4, 8, and 24 weeks later using standard H&E-stained sections and compared with sham-treated age-matched controls. Immunohistochemistry for invasive inflammatory cells (macrophages, neutrophils and B and T lymphocytes) was performed. A semi-quantitative assessment of pulmonary injury was made using three distinct parameters: local infiltration of inflammatory cells, diffuse inflammation, and thickening and distortion of alveolar architecture. Radiation-induced changes in lung architecture were most evident during the first 2 weeks postexposure. Fungal changes were seen over the first 4 weeks. Simultaneous combined exposures significantly increased the duration of acute pulmonary damage up to 24 weeks (P < 0.01). In contrast, administration of the fungus 8 weeks after irradiation did not produce enhanced levels of acute pulmonary damage. These data imply that the inhalation of fungal spores at the time of a radiation exposure alters the susceptibility of the lungs to radiation-induced injury.     

The enhanced radioresistance (adaptive response) in vivo of splenic colony-forming units (CFU-S) following the exposure of mice to 60Co gamma rays at low doses]

An increase of resistance to radiation damage of human lymphocytes previously exposed to low doses of ionizing radiation from incorporated tritiated thymidine was observed by G. Olivieri et al. in 1984. The phenomenon was named adaptive response and its occurrence was reported by others for many animal and plant cells. In this research we studied the adaptive response of spleen colony formation at different time after previous irradiation of mice with low doses of 60Co gamma rays. Our results suggest that the pretreatments protect spleen colony-formatting units (CFU-S) from the second damaging radiation dose of 1.5 Gy during long time (as many as one month).     

Mutations and chromosomal aberrations in hMTH1-transfected and non-transfected TK6 cells after exposure to low dose rates of gamma radiation

The aim of the present study was to analyse the dose rate effect of gamma radiation at the level of mutations, chromosomal aberrations, and cell growth in TK6 cells with normal as well as reduced levels of hMTH1 protein. TK6 cells were exposed to gamma radiation at dose rates ranging from 1.4 to 30.0 mGy/h (chronic exposure) as well as 24 Gy/h (acute exposure). Cell growth, frequency of thymidine kinase mutants, and of chromosomal aberrations in painted chromosomes 2, 8, and 14 were analysed. A decline in cell growth and an increase in unstable-type chromosomal aberrations with increasing dose rate were observed in both cell lines. A dose rate effect was not seen on mutations or stable-type chromosomal aberrations in any of the two cell lines. Reduction in the hMTH1 protein does not influence the sensitivity of TK6 cells to gamma radiation. This result fits well with data of others generated with the same cell line.     

Diverse delayed effects in human lymphoblastoid cells surviving exposure to high-LET (56)Fe particles or low-LET (137)Cs gamma radiation

To obtain information on the origin of radiation-induced genomic instability, we characterized a total of 166 clones that survived exposure to (56)Fe particles or (137)Cs gamma radiation, isolated approximately 36 generations after exposure, along with their respective control clones. Cytogenetic aberrations, growth alterations, responses to a second irradiation, and mutant frequencies at the Na(+)/K(+) ATPase and thymidine kinase loci were determined. A greater percentage of clones that survived exposure to (56)Fe particles exhibited instability (defined as clones showing one or more outlying characteristics) than in the case of those that survived gamma irradiation. The phenotypes of the unstable clones that survived exposure to (56)Fe particles were also qualitatively different from those of the clones that survived gamma irradiation. A greater percentage (20%) of the unstable clones that survived gamma irradiation than those that survived exposure to (56)Fe particles (4%) showed an altered response to the second irradiation, while an increase in the percentage of clones that had an outlying frequency of ouabain-resistant and thymidine kinase mutants was more evident in the clones exposed to (56)Fe particles than in those exposed to gamma rays. Growth alterations and increases in dicentric chromosomes were found only in clones with more than one alteration. These results underscore the complex nature of genomic instability and the likelihood that radiation-induced genomic instability arises from different original events.     

Sorption of bacteria by blood cells as an indicator of the reaction of animals to the action of different doses of gamma rays

In experiments with mice, guinea pigs, and dogs, a study was made of the sorptive capacity of peripheral blood cells after different gamma-radiation doses with reference to living Escherichia coli cells. The sorptive capacity of blood cells was inhibited in exposed animals the inhibition being maximum during the first 3 days following irradiation. Homologous immunoglobulin administered to mice 24 h before irradiation prevented the diminution of the sorptive capacity of cells and stimulated it during the first week following irradiation.     

Radiosensitization of human T-cell leukemia by thymidine and 41.8 degrees C hyperthermia in vitro

This study tested whether thymidine, a naturally occurring nucleoside metabolite, could increase the sensitivity of human T-cell neoplasms to ionizing irradiation and whether adding 41.8 degrees C hyperthermia (X 1 h) to the combination of thymidine and irradiation would further enhance killing of cells by radiation. The magnitude of cytotoxicity induced directly by thymidine was also evaluated. Finally, the ability of 2'-deoxycytidine to prevent thymidine-induced cytotoxicity and radiosensitization was studied. Using JM and MOLT3, two human T-cell acute lymphoblastic leukemias, it was found that thymidine itself was cytotoxic and the toxicity appeared rapidly upon exposure to the drug (i.e., at 4 h). Thymidine caused significant radiosensitization, and thymidine plus 1 h of 41.8 degrees C hyperthermia enhanced radiation-induced killing significantly more than did thymidine or hyperthermia separately. The addition of 2'-deoxycytidine only partly reversed thymidine-induced killing and did not prevent thymidine-induced radiosensitization. The applicability of these results to the clinical management of T- and null-cell malignancies is discussed, as is the presumed mechanistic basis for these observations relative to deoxyribonucleoside metabolism, NAD metabolism, and inhibition of poly(ADP-ribose) polymerase.     

Radiation adaptive response of glial cells.

There are various types of radiation in space including high energy particles. It is, therefore, becoming to be important to study the low dose and low dose-rate effects in space radiation biology. Radiation adaptive response (RAR) for cell growth and its mechanism were examined using cultured glial cells. The cells from hippocampus of Wistar rats were irradiated with a low dose (0.1 Gy) of X-rays and 3 h after with a high dose (2 Gy). Decrease in the rate of cell growth with 2 Gy was suppressed by the 0.1 Gy preirradiation, when cells were counted 2 days after irradiation. The inhibitors of protein kinase C (PKC) and DNA-dependent protein kinase (DNAPK) or phosphatidylinositol 3-kinase (PI3K) suppressed RAR. The treatment with the activators of PKC instead of 0.1 Gy-preirradiation also caused adaptive response to 2 Gy-irradiation. Moreover, glial cells cultured from severe combined immunodeficiency (scid) mice, which have lost DNAPK activity, and AT-2KY cells, fibroblasts of an ataxia-telangiectasia (AT) patient, showed no RAR. These results indicated that PKC, ATtM, DNAPK and/or PI3K were involved in RAR for growth of cultured glial cells. Proteomics [correction of preteomics] analysis of these cells exposed to low dose irradiation in now underway.     

Inhibition of ATR kinase with the selective inhibitor VE-821 results in radiosensitization of cells of promyelocytic leukaemia (HL-60)

We compared the effects of inhibitors of kinases ATM (KU55933) and ATR (VE-821) (incubated for 30 min before irradiation) on the radiosensitization of human promyelocyte leukaemia cells (HL-60), lacking functional protein p53. VE-821 reduces phosphorylation of check-point kinase 1 at serine 345, and KU55933 reduces phosphorylation of check-point kinase 2 on threonine 68 as assayed 4 h after irradiation by the dose of 6 Gy. Within 24 h after gamma-irradiation with a dose of 3 Gy, the cells accumulated in the G2 phase (67 %) and the number of cells in S phase decreased. KU55933 (10 μM) did not affect the accumulation of cells in G2 phase and did not affect the decrease in the number of cells in S phase after irradiation. VE-821 (2 and 10 μM) reduced the number of irradiated cells in the G2 phase to the level of non-irradiated cells and increased the number of irradiated cells in S phase, compared to irradiated cells not treated with inhibitors. In the 144 h interval after irradiation with 3 Gy, there was a considerable induction of apoptosis in the VE-821 group (10 μM). The repair of the radiation damage, as observed 72 h after irradiation, was more rapid in the group exposed solely to irradiation and in the group treated with KU55933 (80 and 77 % of cells, respectively, were free of DSBs), whereas in the group incubated with 10 μM VE-821, there were only 61 % of cells free of DSBs. The inhibition of kinase ATR with its specific inhibitor VE-821 resulted in a more pronounced radiosensitizing effect in HL-60 cells as compared to the inhibition of kinase ATM with the inhibitor KU55933. In contrast to KU55933, the VE-821 treatment prevented HL-60 cells from undergoing G2 cell cycle arrest. Taken together, we conclude that the ATR kinase inhibition offers a new possibility of radiosensitization of tumour cells lacking functional protein p53.     

Radioemetic protection at 24 h after 60Co irradiation in both normal and postremectomized cats

The radioemetic dose-response relationships were established in 46 unanesthetized cats for each of two whole-body exposures, 24 h apart, to 60Co radiation at selected doses between 7.5 and 60 Gy. Individual episodes of vomiting were recorded for a period of 48 h as distinctive intrathoracic pressure deflections signaled through a catheter placed in the superior vena cava. Five cats with chronic lesions of the area postrema were included in the group exposed to 45 Gy. The lesioned animals were not detectably different in their radiation response behavior from the intact cats. Initial exposure in the entire cat series produced an increasing incidence of radioemesis from 25 to 80% over the specified dose range for the first observation period of 24 h. By contrast, the second exposure produced an inverse dose-related incidence of emesis varying from 63% to zero with an apparent crossover of radioemetic susceptibility for the two exposures at about 15 Gy. Complete protection during 12 h after the second exposure was obtained at 30, 45, and 60 Gy, and for all of 24 h at 45 and 60 Gy. In a separate group of 11 normal cats, the emetic drug xylazine invariably evoked vomiting when radioemetic protection was otherwise manifest after initial irradiation at 45 Gy. We conclude that the temporary recovery of well-being following acute lethal irradiation results selectively through increased radioemetic resistance, and it does not depend on the integrity of the area postrema.     

Cell cycle changes and cytotoxicity in irradiated cultures of bovine aortic endothelial cells

The purpose of this experiment was to determine the effect of ionizing radiation on cell number, lactate dehydrogenase (LDH) release, cell cycle distribution, [3H]thymidine incorporation, and autoradiographic labeling index in bovine aortic endothelial cells in vitro. Confluent endothelial monolayers were exposed to single doses of 0.5-10 Gy of 60Co gamma rays and were analyzed from 2 to 24 h postirradiation. Irradiated monolayers exhibited a time- and dose-dependent decrease in cell number, increase in LDH release, and redistribution of cells in the cell cycle. Cell cycle redistribution included an increase in the proportion of cells in S phase at 4 h after irradiation and a decrease in S phase at 24 h. The cells also exhibited a decrease in [3H]thymidine incorporation as early as 2 h after 5 Gy. This represented the most rapid radiation response observed in the present study. These data demonstrate that radiation cytotoxicity in confluent, plateau-phase endothelial monolayers is accompanied by changes in the cell cycle distribution of adherent cells, and that reduced [3H]thymidine incorporation is an early marker of radiation injury in this clinically important cell type.     

Effect of UV light on DNA replication and chain elongation in Chinese hamster UV61 cells

Exposure of eukaryotic cells to ultraviolet light results in a temporary inhibition of DNA replication as well as a temporary blockage of DNA fork progression. Recently there has been considerable debate as to whether the (5-6)cyclobutane pyrimidine dimer, the pyrimidine(6-4)pyrimidone lesion or both are responsible for these effects. Using cell lines that repair both of these lesions (CHO AA8), only (6-4) lesions (CHO UV61) or neither (CHO UV5), we have shown that in rodent cells both lesions appear to play a role in both the inhibition of thymidine incorporation and the blockage of DNA fork progression. Specifically, after exposure to 2.5 J/m2, AA8 cells recover normal rates of DNA replication within 5 h after exposure, while UV5 cells exhibit a greater depression in thymidine incorporation for at least 10 h. UV61 cells, on the other hand, show an intermediate response, both with respect to the extent of the initial depression and the rate of recovery of thymidine incorporation. UV61 cells also exhibit an intermediate response with respect to blockage of DNA fork progression. In previous publications we have shown that UV5 cells exhibit extensive blockage of DNA fork progression and only limited recovery of this effect within the first 5 h after exposure to UV. In this report we show that UV61 cells exhibit a more extensive blockage of fork progression than is observed in AA8 cells. These blocks also appear to be removed (or overcome) more slowly than in the AA8 cells, but more rapidly than in UV5 cells. Taken together we conclude that both lesions appear to be involved in the initial depression in thymidine incorporation and the initial blockage of DNA fork progression in rodent cells. These data also indicate that (6-4) lesions may be responsible for the prolonged depression in thymidine incorporation and the prolonged blockage of DNA fork progression observed in UV5 cells.     

Residual activation events functional after irradiation of mouse splenic lymphocytes

The radioresistance of lymphocytes increases after mitogenic stimulation, suggesting that a radiosensitive activation event contributes to the overall radiosensitivity of lymphocytes. We have sought to identify this activation event by determining the extent of activation of mitogen-stimulated lymphocytes previously exposed to growth-inhibiting doses of radiation. Mouse splenic lymphocytes were exposed to 0-15 Gy 137Cs radiation, and structural and functional damage were assayed. Although damage to cellular thiols and nonprotein thiols was modest, there was a significant loss of viability by 6 h as determined by uptake of propidium iodide (PI). Since cells did not die immediately after irradiation, the activation events which remained were evaluated. Growth-inhibiting doses of radiation left cells partially responsive to mitogen, in that cells were able to exit G0 phase, but they could progress no further into the cell cycle than G1a phase. It is important to note that assessment of viability by uptake of PI indicated substantial cell death after 15 Gy (45%, 6 h; 90%, 24 h); however, cell cycle analysis at 24 h indicated no significant decrease in progression from G0 to G1a phase. The LPS-stimulated response of B cells was more radiosensitive than the Con A-stimulated response of T cells. Further analysis of the Con A response indicated that production of interleukin-2 (IL-2) was unaffected, but expression of the IL-2 receptor was inhibited. Inhibition of poly-ADP-ribosylation and damage to lipids did not prevent the lack of mitogen responsiveness, since neither the ADP-ribose transferase inhibitor 3-aminobenzamide nor lipid radical scavengers had restorative effects on the mitogenic response. Nor was Con A-stimulated incorporation of [3H]thymidine restored with inhibitors of prostaglandin or leukotriene synthesis, suggesting that inhibition was due to direct effects on the Con A responders, and not indirect effects mediated by arachidonate metabolites. These results indicate that growth-inhibiting doses of radiation trigger the process in lymphocytes that culminates in apoptosis, yet leave the cells partially responsive to mitogenic stimuli.     

Fractionated low-level gamma irradiation of Chinese hamster cells: Cellular and biochemical effects

Summary Chinese hamster V79 cells in log-phase were exposed daily to 0.6 Gy of radiation for 3–6 months. After such an exposure the population doubling time increased from 10 to 15 h. When irradiation was discontinued doubling time gradually decreased. Cell survival following acute radiation dose of the low-level irradiated cells remained the same as that of untreated cells. The fractionated irradiation did not affect the capacity of the cells to perform DNA repair synthesis. Likewise, the sensitivity to inhibition by acute radiation exposure of the ability to induce ornithine decarboxylase activity was similar in cells exposed to fractionated irradiation and in untreated cells. It is concluded that there is no apparent effect of sublethal radiation dose received in one generation on the radiation sensitivity of the succeeding generations during the log-phase of growth.     

Investigation of the effects of head irradiation with gamma rays and protons on startle and pre-pulse inhibition behavior in mice

With the increased international emphasis on manned space exploration, there is a growing need to understand the impact of the spaceflight environment on health and behavior. One particularly important aspect of this environment is low-dose radiation. In the present studies, we first characterized the γ- and proton-irradiation dose effect on acoustic startle and pre-pulse inhibition behaviors in mice exposed to 0-5 Gy brain-localized irradiation, and assessed these effects 2 days later. Subsequently, we used 2 Gy to assess the time course of γ- and proton-radiation effects on startle reactivity 0-8 days after exposure. Exposures targeted the brain to minimize the impact of peripheral inflammation-induced sickness behavior. The effects of radiation on startle were subtle and acute. Radiation reduced the startle response at 2 and 5 Gy. Following a 2-Gy exposure, the response reached a minimum at the 2-day point. Proton and γ-ray exposures did not differ in their impact on startle. We found there were no effects of radiation on pre-pulse inhibition of the startle response.     

Effects of 50 Hz magnetic field on cell cycle kinetics and the colony forming ability of budding yeast exposed to ultraviolet radiation.

To investigate the effects of extremely low frequency magnetic fields on ultraviolet radiation (UV) exposed budding yeast, haploid yeast (Saccharomyces cerevisiae) cells of the strain SEy2101a were exposed to 50 Hz sine wave magnetic field (MF) of 120 microT with simultaneous exposure to UV radiation. Most of the UV energy was in the UVB range (280-320 nm). The biologically weighted (CIE action spectrum) dose level for the UV radiation was 175 J/m2. We examined whether 50 Hz MF affected the ability of UV irradiated yeast cells to form colonies (Colony Forming Units, CFUs). In addition, the effect of coexposure on cell cycle kinetics was investigated. Although the significant effect of MF on the cell cycle phases of UV exposed yeast cells was seen only at one time point, the overall results showed that MF exposure may influence the cell cycle kinetics at the first cycle after UV irradiation. The effect of our particular MF exposure on the colony forming ability of the UV irradiated yeast cells was statistically significant 420 min after UV irradiation. Moreover, at 240, 360, and 420 min after UV irradiation, there were fewer CFUs in every experiment in (UV+MF) exposed populations than in only UV exposed yeast populations. These results could indicate that MF exposure in conjunction with UV may have some effects on yeast cell survival or growth.     

Intracellular thymidylate synthase inhibition by trifluorothymidine in FM3A cells

Trifluorothymidine (TFT) can be phosphorylated by thymidine kinase (TK) to TFTMP which can inhibit thymidylate synthase (TS), resulting in depletion of thymidine nucleotides. TFT can be degraded by thymidine phosphorylase (TP) which can be inhibited by thymidine phosphorylase inhibitor (TPI). Using the TS in situ Inhibition Assay (TSIA) FM3A breast cancer cells were exposed 4 h or 24 h to TFT and 5-Fluorouracil (5FU). TS activity reduced to 9% (0.1 microM TFT) and 58% (1 microM 5FU) after 4 h exposure and to 6% (TFT) and 21% (5FU) after 24 h exposure. TPI did not affect TS inhibition by TFT. FM3A cells lacking TK or TS activity (FM3A/TK-) were far less sensitive to TFT compared to FM3A cells. Conclusion: TFT can be taken up and activated very rapidly by FM3A cancer cells, probably due to favourable TK enzyme properties, and TPI did not influence this.     

Some cell kinetic effects of combined injury with ionizing radiation and cyclophosphamide on mouse bladder urothelium

Cyclophosphamide was given intraperitoneally to groups of eight female mice 48 h after local electron irradiation to the bladder with 0, 10 and 20 Gy respectively. The reactions in the urothelium were monitored by histology, incorporation of tritiated thymidine and flow cytometry. A wave of increased thymidine incorporation combined with an increase in the proportion of diploid S-phase cells was seen in the unirradiated bladders 24 h after the drug treatment, followed by normalization after 1 week. This response was significantly less pronounced in the irradiated animals. In the unirradiated animals a similar wave characterized by an increased proportion of octaploid cells was also seen, but this wave occurred later in the irradiated animals. Severe injury was observed in the rectum of the 20 Gy-irradiated animals. Irradiation prior to drug treatment led to only small effects, but a decreased ability for regenerative DNA synthesis after drug injury seems to persist. This affects both proliferation and the building up of polyploidy.     

Inhibition of p38 MAPK attenuates ionizing radiation-induced hematopoietic cell senescence and residual bone marrow injury

Exposure to a moderate or high total-body dose of radiation induces not only acute bone marrow suppression but also residual (or long-term) bone marrow injury. The induction of residual bone marrow injury is primarily attributed to the induction of hematopoietic cell senescence by ionizing radiation. However, the mechanisms underlying radiation-induced hematopoietic cell senescence are not known and thus were investigated in the present study. Using a well-established long-term bone marrow cell culture system, we found that radiation induced hematopoietic cell senescence at least in part via activation of p38 mitogen-activated protein kinase (p38). This suggestion is supported by the finding that exposure to radiation selectively activated p38 in bone marrow hematopoietic cells. The activation was associated with a significant reduction in hematopoietic cell clonogenic function, an increased expression of p16(INK4a) (p16), and an elevated senescence-associated β-galactosidase (SA-β-gal) activity. All these changes were attenuated by p38 inhibition with a specific p38 inhibitor, SB203580 (SB). Selective activation of p38 was also observed in bone marrow hematopoietic stem cells (HSCs) after mice were exposed to a sublethal total-body dose (6.5 Gy) of radiation. Treatment of the irradiated mice with SB after total-body irradiation (TBI) increased the frequencies of HSCs and hematopoietic progenitor cells (HPCs) in their bone marrow and the clonogenic functions of the irradiated HSCs and HPCs. These findings suggest that activation of p38 plays a role in mediating radiation-induced hematopoietic cell senescence and residual bone marrow suppression.