Molecular basis of X-ray-induced mutation at the HPRT locus in human lymphocytes

Human lymphocytes lacking functional HPRT enzyme after a dose of 300 rad X-radiation were cloned and the monoclonal populations expanded so that sufficient genomic DNA was obtained for Southern analysis. A total of 33 mutant clones were analysed. Wild-type clones showed no evidence of changes to the HPRT gene resolvable by Southern banding patterns whereas 17 of 33 mutant clones showed changes. The alterations observed included total gene deletions (3 clones) and partial gene deletions with or without the appearance of novel bands (12 clones). Two clones showed the appearance of novel bands only. There were no changes observed in 16 of the 33 mutant clones. Three clones showed changes inconsistent with deletion of portions of the gene. In these clones inversion seems to have been the most likely cause of the mutation. The spectrum of gene alterations following ionizing radiation appears different to that previously observed for spontaneous mutations. Consequently, ionizing radiation or radiomimetic agents would appear to be aetiologic, at the most, for only a minor proportion of in vivo somatic mutations.     

Molecular characterization of X-ray-induced mutations at the HPRT locus in plateau-phase Chinese hamster ovary cells

CHO-K1 cells were irradiated in plateau phase to determine the effect of dose, dose fractionation, and delayed replating on the type, location and frequency of mutations induced by 250 kVp X-rays at the hypoxanthine-guanine phosphoribosyl transferase (HPRT) locus. Independent HPRT-deficient cell lines were isolated from each group for Southern blot analysis using a hamster HPRT cDNA probe. When compared with irradiation with 4 Gy and immediate replating, dose fractionation (2 Gy + 24 h + 2 Gy) the entire gene. Since an increase in survival was noted under these conditions, these data suggest that repair of sublethal and potentially lethal damage acts equally on all premutagenic lesions, regardless of type or location. Differences in the mutation spectrum were noted when cells were irradiated at 2 Gy and replated immediately. The location of the deletion breakpoints was determined in 15 mutants showing partial loss of the HPRT locus. In 12 of these cell lines one or both of the breakpoints appeared to be located near the center of the gene, indicating a nonrandom distribution of mutations. These results indicate that damage induced by ionizing radiation results in a nonrandom distribution of genetic damage, suggesting that certain regions of the genome may be acutely sensitive to the mutagenic effects of ionizing radiation.     

Cellular and molecular effects for mutation induction in normal human cells irradiated with accelerated neon ions

We investigated the linear energy transfer (LET) dependence of mutation induction on the hypoxanthine-guanine phosphoribosyl transferase (HPRT) locus in normal human fibroblast-like cells irradiated with accelerated neon-ion beams. The cells were irradiated with neon-ion beams at various LETs ranging from 63 to 335 keV/microm. Neon-ion beams were accelerated by the Riken Ring Cyclotron at the Institute of Physical and Chemical Research in Japan. Mutation induction at the HPRT locus was detected to measure 6-thioguanine-resistant clones. The mutation spectrum of the deletion pattern of exons of mutants was analyzed using the multiplex polymerase chain reaction (PCR). The dose-response curves increased steeply up to 0.5 Gy and leveled off or decreased between 0.5 and 1.0 Gy, compared to the response to (137)Cs gamma-rays. The mutation frequency increased up to 105 keV/microm and then there was a downward trend with increasing LET values. The deletion pattern of exons was non-specific. About 75-100% of the mutants produced using LETs ranging from 63 to 335 keV/mum showed all or partial deletions of exons, while among gamma-ray-induced mutants 30% showed no deletions, 30% partial deletions and 40% complete deletions. These results suggested that the dose-response curves of neon-ion-induced mutations were dependent upon LET values, but the deletion pattern of DNA was not.     

Genetic damage induced by in vitro irradiation of human G0 lymphocytes with low-energy protons (28 keV/microm): HPRT mutations and chromosome aberrations

Cell survival, mutations and chromosomal effects were studied in primary human lymphocytes exposed in G0 phase to a proton beam with an incident energy of 0.88 MeV (incident LET of 28 keV/microm) in the dose range 0.125-2 Gy. The curves for survival and mutations at the hypoxanthine-guanine phosphoribosyl transferase locus were obtained by fitting the experimental data to linear and linear-quadratic equations, respectively. In the dose interval 0-1.5 Gy, the alpha parameters of the curves were 0.42/Gy and 3.6 x 10(-6) mutants/Gy, respectively. The mutation types at the HPRT locus were analyzed by multiplex-PCR in 94 irradiated and 41 nonirradiated clones derived from T lymphocytes from five healthy donors. All clones showed a normal multiplex-PCR pattern and were classified as point mutations. Chromosome aberration data were fitted as a linear function of dose (alpha = 0.62 aberrations per cell Gy(-1)). By irradiating G0 lymphocytes from a single subject with 28 keV/microm protons and gamma rays, an RBE of 6.07 was obtained for chromosome aberrations. An overinvolvement of chromosome 9 relative to chromosome 7 was found in chromosome breaks after chromosome painting analysis.     

Dose-rate effect on the induction of HPRT mutants in human G0 lymphocytes exposed in vitro to gamma radiation

The influence of dose rate on expression time, cell survival and mutant frequency at the hypoxanthine-guanine phosphoribosyltransferase (HPRT) locus was evaluated in human G(0) peripheral blood lymphocytes exposed in vitro to gamma rays at low (0.0014 Gy/min) and high (0.85 Gy/min) dose rates. A cloning assay performed on different days of postirradiation incubation indicated an 8-day maximum expression period for the induction of HPRT mutants at both high and low dose rates. Cell survival increased markedly with decreasing dose rate, yielding D(0) values of 3.04 Gy and 1.3 Gy at low and high dose rates, respectively. The D(0) of 3.04 Gy obtained at low dose rate could be attributed to the repair of sublethal DNA damage taking place during prolonged exposure to low-LET radiation. Regression analysis of the mutant frequency yielded slopes of 12.35 x 10(-6) and 3.66 x 10(-6) mutants per gray at high and low dose rate, respectively. A dose and dose-rate effectiveness factor of 3.4 indicated a marked dose-rate effect on the induced HPRT mutant frequency. The results indicate that information obtained from in vitro measurements of dose-rate effects in human G(0) lymphocytes may be a useful parameter for risk estimation in radiation protection.     

Evidence that most radiation-induced HPRT mutants are generated directly by the initial radiation exposure.

Radiation-induced HPRT mutants are generally assumed to arise directly from DNA damage that is misrepaired within a few hours after X-irradiation. However, there is the possibility that mutations result indirectly from radiation-induced genomic instability that may occur several days after the initial radiation exposure. The protocols that commonly employ a 5-7 day expression period to allow for expression of the mutant phenotype prior to replating for selection of mutants would not be able to discriminate between mutants that occurred initially and those that arose during or after the expression period. To address this question, we performed a fluctuation analysis in which synchronous or asynchronous populations of human bladder carcinoma cells were treated with single doses of X-irradiation. For comparison, radiation was delivered during the expression period, either from an initial dose of 1.0 Gy followed by two 1.0 Gy doses separated by 24 h or from disintegrations resulting from I125dU incorporated into DNA. The mutation frequency observed at the time of replating was used to calculate the average number of mutants in the initial irradiated culture by assuming that the mutants were induced directly at the time of irradiation. Then, this average number was used to calculate the fraction of the irradiated cultures that would be predicted by a Poisson distribution to have zero mutants. There was reasonably good agreement between the predicted poisson distribution and the observed distribution for the cultures that received single doses. Moreover, as expected, when cultures were irradiated during the expression period, the fraction of the cultures having zero mutants was significantly less than that predicted by a Poisson distribution. These results indicate that most radiation-induced HPRT mutations are induced directly by the initial DNA damage, and are not the result of radiation-induced instability during the 5-7 day expression period.     

"Modeled microgravity" affects cell response to ionizing radiation and increases genomic damage

The aim of this work was to assess whether "modeled microgravity" affects cell response to ionizing radiation, increasing the risk associated with radiation exposure. Lymphoblastoid TK6 cells were irradiated with various doses of gamma rays and incubated for 24 h in a modeled microgravity environment obtained by the Rotating Wall Vessel bioreactor. Cell survival, induction of apoptosis and cell cycle alteration were compared in cells irradiated and then incubated in 1g or modeled microgravity conditions. Modulation of genomic damage induced by ionizing radiation was evaluated on the basis of HPRT mutant frequency and the micronucleus assay. A significant reduction in apoptotic cells was observed in cells incubated in modeled microgravity after gamma irradiation compared with cells maintained in 1g. Moreover, in irradiated cells, fewer G2-phase cells were found in modeled microgravity than in 1g, whereas more G1-phase cells were observed in modeled microgravity than in 1g. Genomic damage induced by ionizing radiation, i.e. frequency of HPRT mutants and micronucleated cells, increased more in cultures incubated in modeled microgravity than in 1g. Our results indicate that modeled microgravity incubation after irradiation affects cell response to ionizing radiation, reducing the level of radiation-induced apoptosis. As a consequence, modeled microgravity increases the frequency of damaged cells that survive after irradiation.     

用多引物PCR分析γ射线引起人外周血淋巴细胞hprt基因突变

正常人外周血用~（６０）Ｃｏ射线分别进行１～８Ｇｙ照射后,在含６－ＴＧ的培养基上克隆和筛选人淋巴细胞ｈｐｒｔ突变细胞。细胞的突变频率与γ射线的照射剂量呈正相关．获得４２个ｈｐｒｔ突变细胞株,用８对ｈｐｒｔ寡核苷酸引物进行多聚酶链反应（ＰＣＲ）从细胞粗提物中分别扩增ｈｐｒｔ各个外显子,分析突变细胞的ｈｐｒｔ基因突变,约６０％（２５／４２）的ｈｐｒｔ基因突变为基因缺失,其中１３个突变是ｈｐｒｔ基因全部缺失,而１２个是部分ｈｐｒｔ基因外显子缺失,约有４０％（１７／４２）的突变无明显的ＰＣＲ扩增变化．同时显示ｈｐｒｔ基因外显子的缺失突变与辐射剂量有关,实验结果提示,此方法有可能用于估计辐射剂量和进行辐射远后效果观察,进而揭示辐射致突的分子机理．     

Reduction of spontaneous somatic mutation frequency by a low-dose X irradiation of Drosophila larvae and possible involvement of DNA single-strand damage repair

The third instar larvae of Drosophila were irradiated with X rays, and the somatic mutation frequency in their wings was measured after their eclosion. In the flies with normal DNA repair and apoptosis functions, 0.2 Gy irradiation at 0.05 Gy/min reduced the frequency of the so-called small spot (mutant cell clone with reduced reproductive activity) compared with that in the sham-irradiated flies. When apoptosis was suppressed using the baculovirus p35 gene, the small spot frequency increased four times in the sham-irradiated control group, but the reduction by the 0.2-Gy irradiation was still evident. In a non-homologous end joining-deficient mutant, the small spot frequency was also reduced by 0.2 Gy radiation. In a mutant deficient in single-strand break repair, no reduction in the small spot frequency by 0.2 Gy radiation was observed, and the small spot frequency increased with the radiation dose. Large spot (mutant cell clone with normal reproductive activity) frequency was not affected by suppression of apoptosis and increased monotonically with radiation dose in wild-type larvae and in mutants for single- or double-strand break repair. It is hypothesized that some of the small spots resulted from single-strand damage and, in wild-type larvae, 0.2 Gy radiation activated the normal single-strand break repair gene, which reduced the background somatic mutation frequency.     

Induction and decline of HPRT mutants and deletions following a low dose radiation exposure at Chernobyl

This study was conducted to evaluate the ability of mutation in the hypoxanthine-phosphoribosyltransferase gene (HPRT) to detect radiation-induced mutation in lymphocytes of Russian Chernobyl Clean-up workers, particularly as a function of time after exposure. It is part of a multi-endpoint study comparing HPRT mutation with chromosome translocation and glycophorin A mutation [Radiat. Res. 148 (1997) 463], and extends an earlier report on HPRT [Mutat. Res. 431 (1999) 233] by including data from all 9 years of our study (versus the first 6 years) and analysis of deletion size. Blood samples were collected from 1991 to 1999. HPRT mutant frequency (MF) as determined by the cloning assay was elevated 16% in Clean-up workers (N=300, the entire group minus one outlier) compared to Russian Controls (N=124) when adjusted for age and smoking status (P=0.028). Since exposures occurred over a short relative to the long sampling period, the year of sampling corresponded roughly to the length of time since exposure (correlation coefficient=0.94). When date of blood sample was considered, Control MF was not time dependent. Clean-up worker MF was estimated to be 47% higher than Control MF in 1991 (P=0.004) and to decline 4.4% per year thereafter (P=0.03). A total of 1123 Control mutants and 2799 Clean-up worker mutants were analyzed for deletion type and size by PCR assay for retention of HPRT exons and flanking markers on the X chromosome. There was little difference between the overall deletion spectra of Clean-up workers and Controls. However, there was a decline in the average size of deletions of Clean-up workers as time after exposure at Chernobyl increased from 6 to 13 years (P< or =0.05). The results illustrate the sensitivity of HPRT somatic mutation as a biomarker for populations with low dose radiation exposure, and the dependence of this sensitivity on time elapsed since radiation exposure.     

Elevated in vivo frequencies of mutant T cells with altered functional expression of the T-cell receptor or hypoxanthine phosphoribosyltransferase genes in p53-deficient mice

We have studied the effects of a defect in the p53 gene on spontaneous and radiation-induced somatic mutation frequencies in vivo by measuring T-cell receptor (TCR) and hypoxanthine phosphoribosyltransferase (HPRT) mutant frequencies (MFs) in p53 deficient mice both before and after exposure to X-irradiation. In the absence of irradiation, the TCR and HPRT mutant frequencies were roughly two-fold higher in p53 null (-/-) mice than in wild-type (+/+) mice. Unexpectedly, the TCR and HPRT MFs were slightly lower in heterozygote p53 (+/-) than in wild-type (+/+) mice, however. After 2 weeks 2Gy whole body irradiation the TCR and HPRT MFs were about two-fold higher in the p53 null (-/-) and p53 (+/-) mice than in the wild-type. Taken together, these findings suggest that a defect in the p53 gene may lead to TCR and HPRT mutants being recovered at higher frequencies in both irradiated and unirradiated mice, but it should be emphasized that the effects we have observed are not particularly strong, albeit that they are statistically significant. Interestingly, several of the highest TCR MF values that we observed in the course of our experiments were recorded in p53 (-/-) animals that had developed thymomas and hence appeared to be cancer prone.     

Characterization of HAT- and HAsT-resistant HPRT mutant clones of V79 Chinese hamster cells.

HPRT mutant clones of V79 Chinese hamster cells, isolated after 6-thioguanine (6TG) selection, normally exhibit sensitivity to growth in medium containing the folic acid inhibitor aminopterin or the glutamine analogue L-azaserine (e.g., HAT or HAsT medium). However, it has been shown that some HPRT- clones are resistant to both HAT and HAsT medium. The present study was undertaken to investigate whether any common structural gene alteration exists for such 6TGr-HATr-HAsTr clones. Four clones were studied, 1 of spontaneous origin, 2 induced by a low dose of MNU and 1 EMS-induced. In contrast to wild-type cells and a mutant clone carrying a complete deletion of the HPRT gene, these 4 investigated 6TGr-HATr-HAsTr clones all showed an enhanced incorporation of exogenous 3H-hypoxanthine in the presence of aminopterin and L-azaserine suggesting that these clones carry mutations in the structural part of the HPRT gene. Sequence analysis of PCR-amplified HPRT cDNA from these mutants showed that the spontaneous and the 2 MNU-induced mutant clones lacked exon 4, while the EMS-induced mutant had a GC to AT transition in exon 6. Southern blot analysis of genomic DNA after digestion with BglII, EcoRI and PstI showed no changes in fragment patterns as compared to the wild type. Further sequence analysis of PCR-amplified genomic DNA using exon 4-specific primers showed that all these 3 mutants had an AT to GC or GC to AT transition in exon 4, but had no alterations in the splice sites of exon 4. Based on their characteristics of hypoxanthine incorporation, the present mutant clones fit the model for the proposed functional domains of the HPRT protein.     

Karyotypic abnormality of the X chromosome is rare in mutant HPRT-lymphocyte clones

Lymphocyte clones mutated at the hypoxanthine-guanine phosphoribosyl-transferase (HPRT) locus on the X chromosome were studied by synchronization and G banding to determine the proportion of mutant clones having visible karyotypic change. 47 spontaneously mutant clones, 17 mutant clones induced by X-irradiation and 33 wild-type clones were studied. All clones were karyotypically normal except for 1 clone induced by X-irradiation in which an interstitial deletion of the short arm of the X chromosome had been inserted into the long arm of the same chromosome between q23 and q24; this change may have been coincidental or may have resulted in a position effect mutation. It was concluded that the great majority of mutations were not associated with a visible chromosome abnormality. This conclusion complements molecular studies which suggest that gene changes at the HPRT locus in HPRT- mutants generally extend over segments of DNA too small to be resolved by karyotypic analysis.     

Molecular structural analysis of HPRT mutations induced by thermal and epithermal neutrons in Chinese hamster ovary cells

Chinese hamster ovary (CHO) cells were exposed to thermal and epithermal neutrons, and the occurrence of mutations at the HPRT locus was investigated. The Kyoto University Research Reactor (KUR), which has been improved for use in neutron capture therapy, was the neutron source. Neutron energy spectra ranging from nearly pure thermal to epithermal can be chosen using the spectrum shifters and thermal neutron filters. To determine mutant frequency and cell survival, cells were irradiated with thermal and epithermal neutrons under three conditions: thermal neutron mode, mixed mode with thermal and epithermal neutrons, and epithermal neutron mode. The mutagenicity was different among the three irradiation modes, with the epithermal neutrons showing a mutation frequency about 5-fold that of the thermal neutrons and about 1.5-fold that of the mixed mode. In the thermal neutron and mixed mode, boron did not significantly increase the frequency of the mutants at the same dose. Therefore, the effect of boron as used in boron neutron capture therapy (BNCT) is quantitatively minimal in terms of mutation induction. Over 300 independent neutron-induced mutant clones were isolated from 12 experiments. The molecular structure of HPRT mutations was determined by analysis of all nine exons by multiplex polymerase chain reaction. In the thermal neutron and mixed modes, total and partial deletions were dominant and the fraction of total deletions was increased in the presence of boron. In the epithermal neutron mode, more than half of the mutations observed were total deletions. Our results suggest that there are clear differences between thermal and epithermal neutron beams in their mutagenicity and in the structural pattern of the mutants that they induce. Mapping of deletion breakpoints of 173 partial-deletion mutants showed that regions of introns 3-4, 7/8-9 and 9-0 are sensitive to the induction of mutants by neutron irradiation.     

Restriction fragment pattern analysis of HPRT mutations induced in rat-liver epithelial cells by alkylating and arylating agents.

Structural alterations in the hypoxanthine-guanine phosphoribosyl transferase (HPRT) gene in genomic DNA of adult rat-liver (ARL) epithelial cells that were mutated by alkylating and arylating mutagens were studied by restriction enzyme fragment pattern (RFP) analysis. ARL cells were mutated with the direct-acting alkylating agent N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) or the activation-dependent arylating agents 7,12-dimethylbenz[a]anthracene (DMBA) and N-2-acetylaminofluorene (AAF). Alterations in the HPRT gene of at least 10 independent 6-thioguanine-resistant (TGr) clones mutated by each chemical were analyzed using 8 different restriction endonucleases; Hind III, EcoRI, BamHI, XbaI, Hae III, XhoI, MspI and PstI, and a full-length HPRT cDNA as a probe in molecular hybridization. Among the 10 MNNG-induced mutants, the RFPs obtained with most endonucleases displayed no changes, while an altered RFP was found in only one mutant using XbaI. None of the 10 DMBA-induced mutants displayed altered RFPs. Restriction analysis of the 10 AAF-induced mutants showed no abnormality in HPRT gene structure in most restriction digests, while altered RFPs were detected in one mutant using MspI and in two mutants with XbaI digestion. Overall, the studies reveal an absence of major DNA sequence changes in 26 of 30 induced mutants although the mutant phenotype of 4 of the TGr clones can be attributed to gross chromosomal changes or a point mutation at the restriction site. The absence of detectable alterations in the RFPs of the majority of the mutants is strongly suggestive of base substitution as the major molecular alteration underlying the mutant phenotype. The HPRT activity of 14 of 30 mutants was at least 5% of the wild-type level, which is consistent with a structural alteration in the gene product expressed as partial activity of the enzyme. Therefore, the data are interpreted as indicating that in the ARL cells, all 3 mutagens induced primarily localized alterations in base sequences in the HPRT gene together with a few mutations involving large sequence changes.     

Simulation of exon deletion mutations induced by low-LET radiation at the HPRT locus

Friedland, W., Li, W. B., Jacob, P. and Paretzke, H. G. Simulation of Exon Deletion Mutations Induced by Low-LET Radiation at the HPRT Locus. Radiat. Res. 155, 703-715 (2001). The induction of HPRT mutants with exon deletions after irradiation with photons was simulated using the biophysical radiation track structure model PARTRAC. The exon-intron structure of the human HPRT gene was incorporated into the chromatin fiber model in PARTRAC. After gamma and X irradiation, simulated double-stranded DNA fragments that overlapped with exons were assumed to result in exon deletion mutations with a probability that depended on the genomic or the geometric distance between the breakpoints. The consequences of different assumptions about this probability of deletion formation were evaluated on the basis of the resulting fractions of total, terminal and intragenic deletions. Agreement with corresponding measurements was obtained assuming a constant probability of deletion formation for fragments smaller than about 0.1 Mbp, and a probability of deletion formation decreasing with increasing geometric or genomic distance between the end points for larger fragments. For these two assumptions, yields of mutants with exon deletions, size distributions of deletions, patterns of deleted exons, and patterns of deleted STS marker sites surrounding the gene were calculated and compared with experimental data. The yields, size distributions and exon deletion patterns were grossly consistent, whereas larger deviations were found for the STS marker deletion patterns in this comparison.     

Evaluation of delayed apoptotic response in lethally irradiated human melanoma cell lines

To assess the lethal doses of gamma radiation and corresponding apoptotic response in new established human melanoma cell lines we exposed exponentially growing cultures to 8-100 Gy gamma radiation. The apoptosis and cell survival were determined by trypan blue exclusion, terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling (TUNEL) reaction, agarose gel electrophoresis, colony forming assay, and long-term survival assay. The maximal DNA fragmentation 3 days after irradiation was observed in cultures irradiated with 20 Gy (36.9% TUNEL positive cells). The cultures irradiated with 50 and 100 Gy contained 18.7% and 16.4% TUNEL positive cells, respectively. Cultures exposed to 8 and 20 Gy gamma radiation recovered by week 3-4. Lethally irradiated (50 and 100 Gy) cultures which contained less apoptotic cells by day 3 died by week 5. A detectable increase in melanoma cell pigmentation after irradiation was also observed. The survival of human melanoma cell cultures after exposure to gamma radiation does not correlate with the level of apoptotic cells by day 3. At high radiation doses (> 50 Gy) when the radiation induced cell pigmentation is not inhibited the processes of apoptotic DNA fragmentation might be preferentially inactivated.     

Radiation-induced genomic instability in tandem repeat sequences is not predictive of unique sequence instability

Tandem repeat sequences, classified as minisatellite sequences or partially duplicated genes, are inherently unstable. Radiation exposure can increase the instability of such repeat sequences, but the biological consequences of this elevated instability are not well characterized. To learn more about the characteristics of the instability at different sequences in the genome, we created mutant HT1080 cells bearing 8.4 kb of partially duplicated allele at the HPRT locus by gene targeting. The cells were then tested to determine whether repeat-sequence instability (assessed by elevated reversion rate caused by loss of one duplicated segment) accompanied increased forward mutation rates at the restored wild-type HPRT allele. After a 4-Gy X irradiation, 32 clones were selected (out of 500 clones, 6%) that showed elevated reversion rates even after many cell generations. These clones also showed general increases in the forward mutation rate, whereas the paired individual mutation rates did not correlate with each other. Furthermore, levels of intracellular reactive oxygen species (ROS) and nuclear gamma-H2AX foci, which are hallmarks for DNA damage responses, were also generally elevated, although the levels did not correlate with the individual reversion rates. It was concluded that repeat sequence instability is not predictive of unique sequence instability, probably because the instability is generated by multiple mechanisms after radiation exposure.