Threshold-type dose response for induction of neoplastic transformation by 1 GeV/nucleon iron ions.

Neoplastic transformation of HeLa x skin fibroblast human hybrid cells by doses of 1 GeV/nucleon iron ions in the range 1 cGy to 1 Gy to exposed cultures has been examined. The data indicate a threshold-type dose-response curve with no increase in transformation frequency until doses above 20 cGy. At doses <10 cGy, not all exposed cells receive a direct traversal of an iron-ion track core, but all exposed cells receive up to several mGy of low-LET radiation associated with the delta-ray penumbra. It is proposed that the threshold-type response seen is a consequence of an adaptive response associated with the delta-ray exposure. For comparison purposes, the dose response for (137)Cs gamma rays over the same dose range was examined using the same experimental procedure. As we have shown previously, the dose response for (137)Cs gamma radiation was J-shaped. The iron ions were 1.5 to 1.7 times more biologically effective than the gamma radiation over the dose range examined.

Inactivation of the cystatin E/M tumor suppressor gene in cervical cancer.

We have previously localized a cervical cancer tumor suppressor gene to a 300 kb interval of 11q13. Analysis of candidate genes revealed loss of expression of cystatin E/M, a lysosomal cysteine protease inhibitor, in 6 cervical cancer cell lines and 9 of 11 primary cervical tumors. Examination of the three exons in four cervical cancer cell lines, 19 primary tumors, and 21 normal controls revealed homozygous deletion of exon 1 sequences in one tumor. Point mutations were observed in six other tumors. Two tumors contained mutations at the consensus binding sites for cathepsin L, a lysosomal protease overexpressed in cervical cancer. Introduction of these two point mutations using site directed mutagenesis resulted in reduced binding of mutated cystatin E/M to cathepsin L. Although mutations were not observed in any cell lines, four cell lines and 12 of 18 tumors contained promoter hypermethylation. Reexpression of cystatin E/M was observed after 5'aza 2-deoxycytidiene and/or Trichostatin A treatment of cervical cancer cell lines, HeLa and SiHa, confirming promoter hypermethylation. Ectopic expression of cystatin E/M in these two cell lines resulted in growth suppression. There was also suppression of soft agar colony formation by HeLa cells expressing the cystatin E/M gene. Reexpression of cystatin E/M resulted in decreased intracellular and extracellular expression of cathepsin L. Overexpression of cathepsin L resulted in increased cell growth which was inhibited by the reintroduction of cystatin E/M. We conclude, therefore, that cystatin E/M is a cervical cancer suppressor gene and that the gene is inactivated by somatic mutations and promoter hypermethylation.

Low doses of very low-dose-rate low-LET radiation suppress radiation-induced neoplastic transformation in vitro and induce an adaptive response.

The purpose of this study was to determine whether adaptation against neoplastic transformation could be induced by exposure to very low-dose-rate low-LET radiation. HeLa x skin fibroblast human hybrid cells were irradiated with approximately 30 kVp photons from an array of (125)I seeds. The initial dose rate was 4 mGy/day. Cell samples were taken at four intervals at various times over a period of 88 days and assayed for neoplastic transformation and the presence of reactive oxygen species (ROS). The dose rate at the end of this treatment period was 1.4 mGy/day. Transformation frequencies and ROS levels were compared to those of parallel unirradiated controls. At the end of 3 months and an accumulated dose of 216 mGy, cells treated with very low-dose-rate radiation were exposed to a high-dose-rate 3-Gy challenge dose of (137)Cs gamma rays, and the effects compared with the effect of 3 Gy on a parallel culture of previously unirradiated cells. Cells exposed to very low-dose-rate radiation exhibited a trend toward a reduction in neoplastic transformation frequency compared to the unirradiated controls. This reduction seemed to diminish with time, indicating that the dose rate, rather than accumulated dose, may be the more important factor in eliciting an adaptive response. This pattern was in general paralleled by a reduction of ROS present in the irradiated cultures compared to controls. The very low-dose-rate-treated cells were less sensitive to the high challenge dose than unirradiated controls, suggesting the induction of an adaptive response. Since there was a suggestion of a dose-rate threshold for induction suppression, a second experiment was run with a fresh batch of cells at an initial dose rate of 1 mGy/day. These cells were allowed to accumulate 40 mGy over 46 days (average dose rate=0.87 mGy/day), and there was no evidence for suppression of transformation frequency compared to parallel unirradiated controls. It is concluded that doses of less than 100 mGy delivered at very low dose rates in the range 1 to 4 mGy/day can induce an adaptive response against neoplastic transformation in vitro. When the dose rate drops below approximately 1 mGy/day, this suppression is apparently lost, suggesting a possible dose-rate-dependent threshold for this process.

Detrimental and protective bystander effects: a model approach.

This work integrates two important cellular responses to low doses, detrimental bystander effects and apoptosis-mediated protective bystander effects, into a multistage model for chromosome aberrations and in vitro neoplastic transformation: the State-Vector Model. The new models were tested on representative data sets that show supralinear or U-shaped dose responses. The original model without the new low-dose features was also tested for consistency with LNT-shaped dose responses. Reductions of in vitro neoplastic transformation frequencies below the spontaneous level have been reported after exposure of cells to low doses of low-LET radiation. In the current study, this protective effect is explained with bystander-induced apoptosis. An important data set that shows a low-dose detrimental bystander effect for chromosome aberrations was successfully fitted by additional terms within the cell initiation stage. It was found that this approach is equivalent to bystander-induced clonal expansion of initiated cells. This study is an important step toward a comprehensive model that contains all essential biological mechanisms that can influence dose-response curves at low doses.

p53-dependent Chk1 phosphorylation is required for maintenance of prolonged G2 Arrest.

Targeting checkpoint kinases has been shown to have a potential chemosensitizing effect in cancer treatment. However, inhibitors of such kinases preferentially abrogate the DNA damage-induced G2 checkpoint in p53-/- as opposed to p53+/+ cells. The mechanisms by which p53 (TP53) can prevent abrogation of the G2 checkpoint are unclear. Using normal human diploid p53+/+ and p53-/- fibroblasts as model systems, we have compared the effects of three checkpoint inhibitors, caffeine, staurosporine and UCN-01, on gamma-radiation-induced G2 arrest. The G2 arrest in p53+/+ cells was abrogated by caffeine, but not by staurosporine and UCN-01, whereas the G2 arrest in p53-/- cells was sensitive to all three inhibitors. Chk2 (CHEK1) phosphorylation was maintained in the presence of all three inhibitors in both p53+/+ and p53-/- cells. Chk1 phosphorylation was maintained only in the presence of staurosporine and UCN-01 in p53+/+ cells. In the presence of caffeine Chk1 phosphorylation was inhibited regardless of p53 status. The pathway of Chk1 phosphorylation --> Cdc25A degradation --> inhibition of cyclin B1/Cdk1 activity --> G2 arrest is accordingly resistant to staurosporine and UCN-01 in p53+/+ cells. Moreover, sustained phosphorylation of Chk1 in the presence of staurosporine and UCN-01 is strongly related to phosphorylation of p53. The present study suggests the unique role of Chk1 in preventing abrogation of the G2 checkpoint in p53+/+ cells.

The effect of dose rate on radiation-induced neoplastic transformation in vitro by low doses of low-LET radiation.

The dependence of the incidence of radiation-induced cancer on the dose rate of the radiation exposure is a question of considerable importance to the estimation of risk of cancer induction by low-dose-rate radiation. Currently a dose and dose-rate effectiveness factor (DDREF) is used to convert high-dose-rate risk estimates to low dose rates. In this study, the end point of neoplastic transformation in vitro has been used to explore this question. It has been shown previously that for low doses of low-LET radiation delivered at high dose rates, there is a suppression of neoplastic transformation frequency at doses less than around 100 mGy. In the present study, dose-response curves up to a total dose of 1000 mGy have been generated for photons from (125)I decay (approximately 30 keV) delivered at doses rates of 0.19, 0.47, 0.91 and 1.9 mGy/min. The results indicate that at dose rates of 1.9 and 0.91 mGy/min the slope of the induction curve is about 1.5 times less than that measured at high dose rate in previous studies with a similar quality of radiation (28 kVp mammographic energy X rays). In the dose region of 0 to 100 mGy, the data were equally well fitted by a threshold or linear no-threshold model. At dose rates of 0.19 and 0.47 mGy/min there was no induction of transformation even at doses up to 1000 mGy, and there was evidence for a possible suppressive effect. These results show that for this in vitro end point the DDREF is very dependent on dose rate and at very low doses and dose rates approaches infinity. The relative risks for the in vitro data compare well with those from epidemiological studies of breast cancer induction by low- and high-dose-rate radiation.

Neoplastic transformation in vitro by low doses of ionizing radiation: role of adaptive response and bystander effects.

The shape of the dose-response curve for cancer induction by low doses of ionizing radiation is of critical importance to the assessment of cancer risk at such doses. Epidemiologic analyses are limited by sensitivity to doses typically greater than 50-100 mGy for low LET radiation. Laboratory studies allow for the examination of lower doses using cancer-relevant endpoints. One such endpoint is neoplastic transformation in vitro. It is known that this endpoint is responsive to both adaptive response and bystander effects. The relative balance of these processes is likely to play an important role in determining the shape of the dose-response curve at low doses. A factor that may influence this balance is cell density at time of irradiation. The findings reported in this paper indicate that the transformation suppressive effect of low doses previously seen following irradiation of sub-confluent cultures, and attributed to an adaptive response, is reduced for irradiated confluent cultures. However, even under these conditions designed to optimize the role of bystander effects the data do not fit a linear no-threshold model and are still consistent with the notion of a threshold dose for neoplastic transformation in vitro by low LET radiation.

Health risks of low photon energy imaging.

The major health risk associated with low photon energy imaging is thought to be the induction of cancer as a consequence of the radiation exposure and this is the focus of this paper. Low photon energy imaging typically involves exposure to a low dose (<50 mGy) of low linear energy transfer (LET) radiation delivered at high dose-rate. Since epidemiologic data cannot provide an accurate assessment of risk at the doses used in imaging, risk estimates are currently made by fitting a linear response to intermediate and high dose data for cancer induction in radiation-exposed human populations. This method assumes a linear no-threshold (LNT) response and implies that no dose of radiation is safe. This assumption is not borne out by many laboratory studies of cancer-related endpoints that would suggest that the risk at low doses is much less than would be estimated from linear extrapolation from intermediate to high doses. It is also well recognised that the dose-response from many epidemiologic studies could equally well be fit by threshold models. Through the study of radiation-induced neoplastic transformation in vitro J-shaped dose-response curves for a variety of low LET radiations, including those used in low photon energy imaging, have been demonstrated. The relative risks calculated from this data compare remarkably well with those for breast cancer and leukemia incidence in radiation-exposed populations. From this it is concluded that the LNT hypothesis is likely to overestimate the risk of cancer induction by low photon energy imaging, at least for certain tumors.

Irradiation-induced adduct formation of RNA with carcinogenic arylamine derivatives.

Radiolysis of N2O-saturated solutions of transfer RNA (tRNA) and the arylacethydroxamic acids, N-hydroxy-N-2-acetylaminofluorene and N-hydroxy-N-4-acetylaminobiphenyl; their corresponding acetamides, 2-acetylaminofluorene and 4-acetylaminofluorene; or the O-glucuronide of N-hydroxy-N-2-acetylaminofluorene resulted in adduct formation of the nucleic acid with these carcinogenic arylamine derivatives. The yield of adducts on irradiation of the arylacethdroxamic acids with tRNA was greater than that for their corresponding acetamides or the O-glucuronide. The fluorenylacethydroxamic acid and acetamide were also more reactive than the biphenyl analogs. Adduct formation resulting from radiolysis of tRNA and the arylacethydroxamic acids or the O-glucuronide proceeded with retention of both the aromatic nucleus and the N-acetyl group. The yields of adducts were much greater for irradiated mixtures than for irradiation of either component alone followed by mixing. Evaluation of the data shows that initial modification of the tRNA or the carcinogen can lead to adduct formation. In the case of primary radical attack of the nucleic acid, it has been shown that short-lived reactive RNA intermediates are responsible for a major fraction of the observed yield of adducts in the irradiated mixtures. Comparative studies showed that irradiation under conditions that favor reaction of oxidizing radicals enhanced formation of the adducts. Oxygen was shown to protect RNA from irradiation-induced binding of the arylacethydroxamine acids due to competition of O2 with the carcinogen for the reactive RNA intermediates.

Suppression of radiation-induced neoplastic transformation of human cell hybrids by long term incubation at low extracellular pH.

We have previously reported that, when 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid buffer was used in the growth medium to control pH fluctuations during the 21-day expression period of our human cell hybrid (HeLa x skin fibroblast) transformation assay, the yield of radiation-induced neoplastically transformed foci after 7 Gy of gamma-irradiation was suppressed. We now demonstrate that the observed suppression is not related to the presence of the 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid buffer per se but rather is a function of the growth medium pH. Detailed studies reveal that incubation of the irradiated cells during the entire 21-day expression period at pH 6.7-6.8 versus pH 7.0-7.2 significantly suppressed the transformation frequency after 7 Gy, from 4.4 x 10(-4) to 4.6 x 10(-5) (accumulated data). The endpoint fraction of flasks containing foci was also significantly reduced at the lower pH. Suppression was evident whether the growth medium pH was lowered from pH 7.0-7.2 to pH 6.7-6.8 by medium exchange on day 0, 1, or 9 or even up to 15 days post-irradiation. Growth curves revealed that the population doubling time of the cells is extended and the unirradiated and irradiated plating efficiencies are lowered by long term low pH exposure. We discuss possible mechanisms for the observed suppression, in terms of the influence of low extracellular pH on cell turnover, repair of radiation damage, cell toxicity, and activity of cellular proteases.

Characterization of intestinal alkaline phosphatase expression and the tumorigenic potential of gamma-irradiated HeLa x fibroblast cell hybrids.

Fusion of tumorigenic HeLa cells with human skin fibroblasts results in genetically stable hybrids which are nontumorigenic and no longer express the HeLa tumor-associated antigen, intestinal alkaline phosphatase (IAP). Previous analysis of spontaneous segregants of the nontumorigenic hybrid have implicated the loss of one copy of human fibroblast chromosome 11 with reexpression of IAP and tumorigenicity. This observation suggests that a putative HeLa tumor suppressor gene(s) is located on chromosome 11 and that this gene may be a negative regulator of the IAP gene. We have isolated several gamma-ray-induced mutants (GIMs) of the nontumorigenic HeLa x skin fibroblast hybrid CGL1 that were specifically selected for reexpression of IAP to further investigate the potential linkage between IAP regulation and the putative tumor suppressor locus. The GIMs have a wide range of cell morphology and level of IAP expression (nearly a factor of 40). The tumorigenicity of the GIMs was examined by s.c. injection into nude mice and all were found to be tumorigenic. The tumor volume-doubling time is in the range of 4 to 8 days for all the cell lines; however, the lag time to reach 500 mm3 tumor volume was significantly longer when the GIM IAP activity was low (less than 20% relative activity), suggesting perhaps that there is a threshold level of IAP expression required for tumor formation and selection for high IAP expression in vivo. However, studies with tumor reconstitutes of the GIMs and transfection studies with an IAP complementary DNA expression vector indicate that high IAP expression alone is not sufficient to confer rapid tumor growth. Therefore, while the data lend strong support to the continued tight correlation between IAP reexpression and tumorigenicity and to our proposal that the tumor suppressor may negatively regulate the IAP gene, it suggests that selection for other gene activities may be responsible for aggressive tumor growth in this cell hybrid system.

Localization of deletion to a 300 Kb interval of chromosome 11q13 in cervical cancer.

Previous molecular genetic studies on HeLa cell (a cervical cancer cell line) derived non-tumorigenic and tumorigenic hybrids have localized a tumor suppressor gene to the long arm of chromosome 11. Analysis of cervical cancer cell lines using chromosome 11 specific probes showed deletion and translocation of 11q13 sequences in five out of eight cell lines. Fluorescence in situ hybridization (FISH), using 11q13 specific probes, has shown interstitial deletion of 11q13 sequences in the HeLa cells. In order to determine whether 11q13 deletions occur in primary cervical tumors, we analysed 36 tumors using 20 different microsatellite and RFLP markers. Semi automated fluorescein based allelotyping was performed to identify loss of heterozygosity (LOH) in tumors. The results showed allelic loss in 17 (47%) tumors. Three different regions of loss, one near MEN1, the second near D11S913, and the third near INT2 locus were observed. The smallest region of deletion overlap at the D11S913 locus was localized to a 300 Kb distance between D11S4908 and D11S5023. Fluorescence in situ hybridization (FISH), using 11q13 specific cosmid and BAC (bacterial artificial chromosome) probes, confirmed allelic deletion in the tumors. PCR analysis further identified homozygous deletion of 11q13 sequences in a primary tumor, in HeLa cells and in two HeLa cell derived tumorigenic hybrid cell lines. The homozygous deletion in the cell lines was mapped to a 5.7 kb sequence of 11q13. We hypothesize therefore that a putative cervical cancer tumor suppressor gene exists within the 300 kb of chromosome 11q13.

Paclitaxel exposure time determines the nature of the interaction with radiation in HeLa cells. the role of apoptosis.

The purpose of the present study was to investigate further the mechanisms underlying subadditive and superadditive interactions of radiation and paclitaxel treatments in vitro. The protocol studied was a fixed radiation treatment (7 Gy) followed either immediately or after a 10 h delay by paclitaxel treatment. Paclitaxel treatment was exposure to either a fixed dose of paclitaxel (10 nM) for varying time intervals up to 25 h, or varying doses of paclitaxel up to 20 nM for a fixed exposure time of 24 h. The cells used were HeLa. Cell survival was assessed by colony forming ability and apoptosis was measured by flow cytometry. The results show that when the paclitaxel exposure time was 24 h superadditive interactions were observed at all paclitaxel doses. A reasonable correlation between surviving fraction as measured by colony forming ability and apoptosis in the attached cells at the end of paclitaxel treatment was observed. The nature of the interaction of radiation and subsequent paclitaxel treatment is critically dependent on the duration of the paclitaxel treatment.

Reversion of UVC-induced tumorigenic human hybrid cells to the non-tumorigenic phenotype.

Non-tumorigenic HeLa x skin fibroblast human hybrid cells were UVC-irradiated (10 J/m2) and induced to neoplastic transformation with accompanying morphological change and expression of the HeLa tumour-associated antigen, intestinal alkaline phosphatase (IAP). A single-cell-derived cell line was cloned out of a neoplastically transformed focus and designated as UV-12. In low density culture, this cell line demonstrated the ability to undergo reversion to a morphology similar to that of the non-tumorigenic parent with accompanying, much reduced levels of IAP expression. The frequency of this reversion to low IAP expression increased with passage of low density cultures reaching 10(-2) at 26 passages. A revertant colony was selected and expanded into a cell line which was designated UV-12-RM-1. This cell line had a 67-fold reduction in IAP expression compared to UV-12 and demonstrated a much reduced tumorigenic phenotype. A cell line reconstituted from a tumour derived from this cell line demonstrated a high IAP expression level (3-fold less than UV-12) and was highly tumorigenic. Six single-cell-derived lines were cloned from UV-12-RM-1 and all had low IAP expression. Of these, one demonstrated an aggressive tumorigenicity, four showed the reduced tumorigenic phenotype characteristic of UV-12-RM-1, and one (UV-12-RM-105) was non-tumorigenic. However, with passage in culture, this latter cell line reverted to a weakly tumorigenic phenotype and a much elevated IAP level. It is hypothesised that the phenotypic shifts demonstrated by these UV-induced tumorigenic cells are under epigenetic control, and that they are most likely a consequence of an underlying genetic instability in the survivors of UVC-irradiation.

High and low dose rate irradiation have opposing effects on cytokine gene expression in human glioblastoma cell lines.

Effects of radiation on five cytokine expressing human glioblastoma cell lines were studied. In comparison to unirradiated controls, IL-1 beta and IL-6 mRNAs were generally reduced after low (LDR, 1.0 cGy/min) and very low (VLDR, 0.35 cGy/min) dose rate irradiation. In contrast, high (HDR, 200 cGy/min) and intermediate (IDR, 4.1 cGy/min) dose rates increased steady-state levels of IL-1 beta and IL-6 mRNAs. The surviving fraction was generally inversely proportional to the dose rate; however, these glioma cells were unusually susceptible to LDR. In the two cell lines tested, IDR was less cytotoxic than either HDR or LDR irradiation. Although cytokine gene expression had no clear effect on radiation survival in vitro, autologous cytokines could be important to radiation response in vivo by affecting immune response, tumour stroma, vasculature or surrounding tissues. Adjusting dose rates to account for inverse dose rate effects and altered gene expression may be a useful strategy in optimising radiation therapy of glioblastomas.

Subadditive interaction of radiation and Taxol in vitro.

PURPOSE: To examine the dependency of Taxol-radiation interactions on the scheduling of the two agents. METHODS AND MATERIALS: The human laryngeal squamous cell carcinoma line SCC20 was used for this study. Cells were irradiated as subconfluent cultures using Cs-137 gamma rays at a dose rate of 1.75 Gy/min. Cultures were pretreated with Taxol (7.5 nM for 12 h, S.F. = 0.4) and then irradiated with graded doses followed by either immediate plating or holding for 6 h either in the absence or presence of 7.5 nM Taxol prior to plating for colony-forming ability. Experiments in which cells were irradiated and then exposed to 7.5 nM Taxol for both 12 and 18 h were also performed. Parallel-flow cytometric analyses of cell-cycle distribution of the various treated populations were carried out. RESULTS: The results indicate that pretreatment with Taxol induced a G2 block which was maintained during 6 h postirradiation holding either in the presence or absence of Taxol. No modification of radiosensitivity in the low-dose region was seen for cells treated with Taxol, irradiated, and plated immediately, with the resulting survival being compatible with an additive effect. However, for Taxol-pretreated cells held for 6 h postirradiation, either in the absence or presence of Taxol, the resulting survival reproducibly demonstrated a marked less than additive effect. This was particularly prominent for cells held in the presence of Taxol. Subsequent experiments in which Taxol was added to cells immediately postirradiation again demonstrated a less than additive effect of the two modalities. CONCLUSION: The results of this study are consistent with a dual mechanism of action involving Taxol-induced radiation resistance, possibly as a consequence of postirradiation holding in G2, and radiation-induced Taxol resistance through an as-yet-undefined mechanism.

Induction of cisplatinum sensitivity without alteration in radiation sensitivity by fractionated radiation treatment of a human laryngeal squamous cell carcinoma cell line.

PURPOSE: To determine if fractionated radiation treatment can alter cisplatinum sensitivity of a human laryngeal squamous carcinoma cell line. METHODS AND MATERIALS: Human squamous carcinoma cells, both previously untreated, as well as survivors of fractionated radiation therapy, were tested in vitro for their sensitivity to gamma radiation and cisplatinum. Fractionated gamma radiation was delivered in 14 or 10 daily fractions of 2 Gy. The cell line, cSCC-20, was derived from an untreated primary human laryngeal carcinoma. RESULTS: The human laryngeal squamous cell carcinoma cell line, cSCC-20, was demonstrated to have heterogeneous subpopulations with respect to cisplatinum sensitivity. No variation in radiation sensitivity was seen among subpopulations of varying cisplatinum sensitivity. The cells were relatively radioresistant (Do = 2.5 Gy). Fractionated radiation treatments of the parent cell line (14 fractions, 14 days, 2 Gy/fraction) or a cisplatinum sensitive subline (10 fractions, 12 days, 2 Gy/fraction) induced cisplatinum sensitivity (factor of 1.3 to 1.4) in the surviving cells. CONCLUSION: Fractionated radiation treatment of human squamous carcinoma cells in vitro induced sensitivity to cisplatinum without concomitant alteration in radiation sensitivity.

Modification of the radiation response of mouse lung by actinomycin D: dependence on interval between radiation and drug treatments.

Actinomycin D (0.6 mg/kg, i.p.) enhances the radiation response of mouse lung. The degree of enhancement varies inversely with the interval between radiation and drug treatments. The kinetics of the loss of interaction of the drug with radiation damage is similar to that observed for "slow repair" of radiation injury to the lung.

Repopulation in irradiated pig skin: late versus early effects.

In the first 16 weeks after irradiation, two distinct waves of reaction can be observed in pig skin, the first wave (3-9 weeks) represents the expression of damage to the epithelium while the second is indicative of primary damage to the dermis, mediated through vascular injury. Following beta-irradiation with a strontium-90 applicator, a severe epithelial reaction was seen with little subsequent dermal effects. X-rays (250 kV), on the other hand, produced a minimal epithelial response at doses which led to the development of dermal necrosis after 10-16 weeks. Comparison of single doses with two equal doses separated by 28 days produced a D2-D1 value of 14.0 Gy at the doses which produced moist desquamation in 50% of fields (ED50) after strontium-90 irradiation. After X-irradiation, comparison of ED50 doses for the later dermal reaction suggested a D2-D1 value of 4.2 Gy. These values of D2-D1 for epithelial and dermal reactions in pig skin were compared with earlier data from this laboratory for similar split-dose experiments with a one-day interval. Such a comparison allowed for the estimation of the component of recovery in the present 28-day interval experiments due to repopulation. This component was found to be 6.5 Gy for the early epithelial damage, but was zero for the later dermal damage.

Reduced temperature (22 degrees C) results in enhancement of cell killing and neoplastic transformation in noncycling HeLa x skin fibroblast human hybrid cells irradiated with low-dose-rate gamma radiation.

The effect of reduced temperature (22 degrees C) or serum deprivation during low-dose-rate (0.66 cGy/min) gamma irradiation on cell killing and neoplastic transformation has been examined using the HeLa x skin fibroblast human hybrid cell system. The reduced temperature stops progression of these cells through the cell cycle while serum deprivation slows down cell turnover markedly. The data demonstrate an enhancement in both of the end points when cells are held at 22 degrees C compared to parallel experiments done at 37 degrees C. In operational terms, the decreased survival and increased neoplastic transformation are consistent with our earlier hypothesis of a higher probability of misrepair at reduced temperature (Redpath et al., Radiat. Res. 137, 323-329, 1994). The interpretation that this damage enhancement was associated with the reduced temperature, and not the fact that the cells were noncycling, was supported by the results of experiments performed with cells cultured at 37 degrees C in serum-free medium for 35 h prior to and then during the 12.24 h low-dose-rate radiation exposure. Under these conditions, cell cycle progression, as shown by reduction in growth rate and dual-parameter flow cytometric analysis, was considerably inhibited (cell cycle time increased from 20 h to 40 h), and there was no significant enhancement of cell killing or neoplastic transformation.