Radiosensitization of X chromosome of Chinese hamster cells related to incorporation of 5-bromodeoxyuridine.

Selective incorporation of 5-bromodeoxyuridine into the late replicating arm of the X chromosome of Chinese hamister cells cultured in vitro caused a selective radiosensization of the arm to ionizing radiation. Radiation damage was observed as chromosomal aberrations, and incorporation was studied by using tritiated 5-bromodeoxyuridine.

Effects of divalent metal cations on composition and neoplasia-specific antigenicity of chromatins.

The antigenicity and composition of chromatins differ markedly in chromatin preparations obtained by different procedures. Rat Novikoff hepatoma chromatin (NC) obtained by the "salt precipitation" and the micrococcal nuclease digestion procedures using significant levels of EDTA and NaCl each shows a common complement fixation (CF) capacity, exceeding chromatin preparations obtained from normal rat liver when tested with rabbit antisera raised to dehistonized NC. In contrast, "structured" NC preparations, which have been postulated to retain a native physical conformation, show minimal CF capacity when tested with the same antiserum but show high CF following elution of histones. While further progressive elution of non-histone proteins (NHPs) did not alter the CF capacity per unit DNA, the completely separated DNA and NHP fractions each showed minimal CF. The data suggest that the antigens detected in the CF assay predominantly represent an artifactual but specific complex of DNA and NHP arising from a denaturation of the native chromatin following elution of metal ions or histones. A qualitatively similar profile of NHPs in salt-precipitated NCs shows a range of total protein/DNA ratios, suggesting that the NHPs found in chromatin preparations may not be intrinsic to the native chromatin structure.

Evidence that hydrogen peroxide generated by 365-nm UVA radiation is not important in mammalian cell killing.

We compared measurements of cell survival and DNA single-strand breaks (SSBs) caused by hydrogen peroxide (H2O2) and UVA radiation (365-nm) in both a parental and a H2O2-resistant variant of the Chinese hamster ovary HA1 line derived by culturing cells in progressively higher concentrations of H2O2. Both RNA slot blot analysis and enzyme analysis confirmed that the variant possesses high levels of both catalase activity and mRNA. The variant was completely resistant to the lethal effects of H2O2 over the concentration range tested (up to 480 microM), whereas the parental strain showed less than 1% survival at this concentration. Similarly, the H2O2-resistant strain exhibited far fewer SSBs after exposure to H2O2 than the parental strain. Addition of o-phenanthroline to the parental cells during H2O2 exposure almost completely inhibited SSB induction, evidence that these SSBs are produced via the Fenton pathway of Haber-Weiss reactions. Very little difference was found between the variant and the parent after exposure to 365-nm radiation: only a minor difference in survival kinetics and no difference is SSB induction were observed between the two cell lines. These results are consistent with a hypothesis that most lethal events caused in cells by UVA occur by pathways that do not involve the H2O2 that is produced by sensitized reactions within the cells.

Chromosome terminal deletion formation in Chinese hamster ovary cells.

To investigate the fate of unrejoined DNA double-strand breaks, the frequency of 60Co gamma-ray- and restriction-enzyme-induced terminal chromosome deletions, a marker of unrejoined breaks, was determined in CHO-K1 and in xrs-5 cells. The xrs-5 cell is a DNA double-strand break repair-deficient derivative of CHO-K1. Terminal deletion frequency was small in both CHO-K1 and xrs-5 cells when cells were irradiated or treated with restriction enzyme while in the G1 phase of the cell cycle. In contrast, previous studies have shown that treatment of cells in G2 leads to large deletion frequencies, especially in xrs-5 cells. Cell cycle analyses show large G2 blocks in irradiated xrs-5 cells with only partial recovery over a 24-96-h period. These results suggest that most CHO cells with unrejoined breaks are blocked in G2 and, therefore, do not contribute to chromosome mutation frequencies. The small frequencies of terminal deletions that are found in these cells may reflect either an inefficiency in the G2 checkpoint mechanism or, perhaps, a modification of broken ends that allows passage through G2.

Altered metaphase chromosome structure in xrs-5 cells is not related to its radiation sensitivity or defective DNA break rejoining.

The chinese hamster ovary (CHO) cell line xrs-5 is a radiation-sensitive derivative of CHO-K1 cells. The xrs-5 cells have a defect in DNA double-strand break rejoining and show alterations in chromosome structure and nuclear morphology. The relationship between radiation sensitivity and metaphase chromosome morphology was examined in 12 'revertant' xrs-5 clones isolated following treatment with 5-azacytidine. nine of the clones were radioresistant while the other three retained xrs-5-like radiation sensitivity. Chromosome morphology reverted to CHO-K1-like characteristics in three of the radioresistant clones and one of the radiosensitive clones suggesting that the over-condensed metaphase chromosome morphology of xrs-5 cells does not underlie its radiation sensitivity. Radiation sensitivity did correlate with DNA double-strand break rejoining ability. The radioresistant clones showing the over-condensed xrs-5-like chromosome morphology were also slightly more sensitive to the topoisomerase II inhibitor etoposide (VP-16) than CHO-K1, suggesting that the over-condensed morphology might be due to alterations in the phosphorylation of chromatin proteins.

Cell cycle kinetics and radiation-induced chromosomal aberrations studied with C14 and H3 labels.

Chinese hamster cells in vitro were double labeled with C(14)TdR and H(3)TdR. At the time of irradiation with Co(60) gamma rays (600 rad), the cells in the G(2) phase were labeled only with C(14), whereas cells in the late and middle S phases were labeled with both C(14) and H(3). The cells in early S phase were labeled only with H(3) and the G(1) cells were unlabeled. Samples were fixed at various time intervals following irradiation and the metaphases were analyzed for chromosomal damage. The phase in which the cell was located at the time of irradiation was determined by counting grains in the first and second layers of autoradiographic film. In both control and irradiated cells some G(1) cells divided prior to some of the cells which were in the S phase denoting mixing of the populations. The G(2) phase sustained three times more chromosomal damage than the S phase. Little difference in chromosomal damage was found between the G(1) and S phases or among the different parts of the S phase. Cells in G(2) sustained a mitotic delay of 4 hr, while the other phases sustained a delay of 2 to 3 hr. Chromatid and chromosome (dicentrics) exchanges were induced in G(1) cells but only chromatid exchanges were induced in S and G(2) cells; this is consistent with the hypothesis that the chromosome consists of two subunits which separate either slightly before or immediately as the cell enters the S phase.

Different sensitivity to cell killing and chromosome mutation induction by gamma rays in two human lymphoblastoid cell lines derived from a single donor: possible role of apoptosis.

The gamma-ray sensitivity of two human lymphoblastoid cell lines, TK6 and WI-L2-NS, was studied; both cell lines are derived from the same parent, WI-L2. TK6 was more sensitive to the cytotoxic effects of gamma rays, but showed fewer induced chromosome aberrations. There was no difference between the two cell lines in their capacity to rejoin DNA double-strand breaks or in the kinetics of the rejoining process. The kinetics of cell cycle progression following radiation exposure was also similar in TK6 and WI-L2-NS. However, while TK6 cells were very sensitive to apoptosis induction, showing high levels of apoptotic cells within 24 h of exposure, no evidence for any significant levels of apoptosis was found for WI-L2-NS within 30 h of irradiation, when chromosome aberration frequency was determined. Evidence of apotosis were seen at later times in WI-L2-NS cells, but the levels were significantly lower than comparably treated TK6 cells. The results support a hypothesis that the lower survival and induced aberration frequencies in TK6 cells are due to selective removal of damaged cells by apoptotic processes prior to analysis of chromosome aberration frequencies in mitosis.

Metaphase chromosome and nucleoid differences between CHO-K1 and its radiosensitive derivative xrs-5.

The Chinese hamster ovary (CHO) cell line xrs-5 is a radiation-sensitive mutant isolated from CHO-K1 cells. The radiation sensitivity is associated with a defect in DNA double-strand break rejoining. Chromatin structure also appears altered in xrs-5 cells compared with the parental CHO-K1 cells. Metaphase chromosomes from xrs-5 are more condensed in appearance than CHO-K1 chromosomes. The overcondensed look is not the result of colcemid sensitivity. Electron microscopy studies suggest that xrs-5 metaphase chromosomes have larger loops of chromatin extending out from the chromosome core. There are also differences between CHO-K1 and xrs-5 cells in the size and fluorescence pattern of ethidium bromide-stained nucleoid preparations. These results suggest that there is a fundamental difference between CHO-K1 and xrs-5 in either the organization of the supercoiled loops of DNA attached to the nuclear matrix or in the nature of the proteins that attach the DNA to the matrix. These alterations in chromosome structure may underlie, in part, the radiation sensitivity of xrs-5 cells.

Differential locus sensitivity to mutation induction by ionizing radiations of different LETs in Chinese hamster ovary K1 cells.

Mutation induction after exposures to 250 kVp X-rays, alpha-particles from the radon daughter 212Bi, and fission-spectrum neutrons from the JANUS reactor was studied in Chinese hamster ovary (CHO) K1 cells and in CHO-10T5, a K1 derivative containing the bacterial gene xanthine-guanine phosphoribosyl transferase (gpt). Mutation induction was analyzed at three genetic loci: the gpt locus, the hypoxanthine-guanine phosphoribosyl transferase (hprt) locus, and the thymidine kinase (tk) locus. After X-irradiation, mutants were induced at the tk loci at approximately 8-9 times the rate of mutant induction at the hprt locus, and the rate of mutant induction at the gpt locus was 8-10 times greater than that at the hprt locus. Neutron and alpha-radiation were more effective mutagenic agents. Mutant frequencies were approximately 4- to 6-fold higher than for X-rays at the hprt and gpt loci and greater than 12-fold greater than X-rays at the tk locus. The greater sensitivity of the tk locus to mutation induction by ionizing radiation (especially neutron and alpha-particle radiation) compared to the hprt locus is likely to be due to the recovery of an additional class of mutants, possibly ones containing larger-sized mutational events. Approximately half of the X-ray-induced tk-1- mutants were small-colony mutants, and 75% of the alpha- and neutron-induced tk-1- mutants were small-colony mutants. The increase in the proportion of small-colony mutants seen with increasing radiation linear energy transfer (LET) suggests that the radiation quality influenced the type of mutation recovered at this locus. There is probably a different reason for the hypersensitivity of the gpt locus because the frequency of gpt mutants, compared to the hprt locus, was independent of radiation quality. Therefore, the LET dependence of mutant induction is gene specific and not necessarily related to the size of deletion recoverable.

An interlaboratory comparison of transformation in Syrian hamster embryo cells with model and coded chemicals.

Three independent laboratories tested eight "model" and five coded chemicals in the Syrian hamster embryo clonal transformation assay system to establish the intra- and interlaboratory reproducibility of the system and to identify sources of variability. When a common cell pool and the same lot of fetal calf serum were used, the three laboratories obtained consensus on the activity of eight model chemicals: five chemicals (benzo(a)pyrene, 7,12-dimethylbenz(a)anthracene, N-methyl-N'-nitro-N-nitrosoguanidine, nitroquinoline-N-oxide, and lead chromate) induced morphological transformation without exogenous metabolic activation and three (N-2-fluorenylacetamide, pyrene, and anthracene) produced no transformation response. Five coded chemicals (2,6-dichloro p-phenylenediamine, 4,4'-oxydianiline, cinnamyl anthranilate, dichlorvos, and reserpine), representative of environmental chemical classes, but not necessarily strong carcinogens, produced more equivocal responses in this interlaboratory study. Thus, while the assay can be used to distinguish between transforming and nontransforming chemicals in some cases, the intrinsic limitations in low transformation frequency and in achieving any dose-response results are major constraints to the use of this system in a routine testing program at the present time. Efforts to increase the transformation frequency or to amplify the expression of the transformed phenotype constitute some of the approaches which should be explored in order to overcome these limitations.