The relationship of DNA and chromosome damage to survival of synchronized X-irradiated L5178Y cells. I. Initial damage

We investigated the role of initial DNA and chromosome damage in determining the radiosensitivity difference between the variant murine leukemic lymphoblast cell lines L5178Y-S (sensitive) and L5178Y-R (resistant) and the difference in cell cycle-dependent variations in radiosensitivity of L5178Y-S cells. We measured initial DNA damage (by the neutral filter elution method) and chromosome damage (by the premature chromosome condensation method) and compared them with survival (measured by cloning) for both cell lines synchronized in G1 or G2 phase of the cell cycle (by centrifugal elutriation) and irradiated with low doses of X rays (up to 10 Gy). The initial yield of DNA and chromosome damage in G2 L5178Y-S cells was almost twice that in G1 L5178Y-S cells and G1 or G2 L5178Y-R cells. In all cases DNA damage expressed as relative elution corresponded with chromosome damage (breaks in G1 chromosomes, breaks and gaps in G2 chromosomes). Also we found that the initial DNA and chromosome damage did not determine cell age-dependent radiosensitivity variations in L5178Y-S cells, as there was less initial damage in the more sensitive G1 phase than in the G2 phase. L5178Y-R cells showed only small changes in survival or initial yield of DNA and chromosome damage throughout the cell cycle. Because survival and initial damage in sensitive and resistant cells irradiated in G2 phase correlated, the difference in radiosensitivity between L5178Y-S and L5178Y-R cells might be determined by initial damage in G2 phase only.     

Damage at two levels of DNA folding measured by fluorescent halo technique in X-irradiated L5178Y-R and L5178Y-S cells. II. Repair

In the preceding paper we described the properties of nucleoids analyzed with the fluorescent halo assay at pH 6.9 and 9, as well as in the presence of reducing and chelating agents and after X-irradiation. We found analogies between the properties of type I and II nucleoids, as examined by Lebkowski and Laemmli (1982), and nucleoids analyzed with the fluorescent halo assay. We concluded that radiation-inflicted damage at two levels of DNA folding is measured at pH 6.9 and 9. In this paper we examined repair of damage to the nucleoid structure as assayed by the fluorescent halo method in X-irradiated L5178Y (LY) sublines; R (radiation resistant,D₀=1.4 Gy) and S (radiation sensitive,D₀=0.5 Gy). Halo diameters were measured after cell lysis in the presence of propidium iodide (PI; 0.5 to 50 µg/ml) at pH 6.9 and 9. The ability of DNA to be rewound at 10–50 µg/ml of PI was impaired by X-irradiation and partly restored during 90-min post-irradiation incubation, indicating damage to the superhelical structure and its partial restoration. The exponential time constants for repair were 10.1 min (LY-S, 6 Gy), 11.2 min (LY-R, 12 Gy), and 20.3 min (LY-s, 12 Gy) when measured at pH 9. In X-irradiated (12 Gy) LY-S cells, slower restoration of DNA supercoiling was observed at pH 9 than at pH 6.9. The presence of labile lesions at pH 9 did not prevent restoration of the higher-order DNA structure, as estimated from DNA rewinding at pH 6.9 in LY-S cells.Work performed at SUNY-Health Science Center at Brooklyn     

Fructose and related phosphate derivatives impose DNA damage and apoptosis in L5178Y mouse lymphoma cells

Glycation between reducing sugars and amino groups of long-lived macromolecules results in an array of chemical modifications that may account for several physiological complications. The consequences of the reaction are directly related to the reactivity of the sugars involved, whether aldoses or ketoses, phosphorylated or non-phosphorylated. So far, most studies have been focused on glucose, while fructose, a faster glycating agent, attracted minor attention. We have recently demonstrated that under in vitro conditions fructose and its phosphate derivatives can modify plasmid DNA faster than glucose and its phosphate metabolites. In the present study we provide further evidences suggesting that fructose and its phosphate metabolites, at the tested conditions, are cytotoxic and inflict deleterious DNA modifications to L5178Y cells in culture. Damage was verified by viable cell counts, MTT assay, colony forming ability, induction of mutation in the thymidine kinase gene, internucleosomal DNA cleavage, and single strand breaks. The intensity of the tested sugars to impose damage increased significantly in the following order: sucrose = glucose 1-phosphate < glucose < glucose 6-phosphate < fructose 1-phosphate = fructose < fructose 6-phosphate. Aminoguanidine, an inhibitor of the glycation reaction, inhibited internucleosomal DNA cleavage. Taken together, these results suggest that fructose triggers deleterious modification in cultured cells through the glycation process, and thus should deserve more attention as an agent that may induce physiological complications.     

Synthesis of glycoprotein, glycolipid, protein, and lipid in synchronized L5178Y cells

Synthesis of four macromolecular classes found in membranes—glycoprotein, glycolipid, protein, and lipid—was measured as a function of time of the cell cycle in synchronized L5178Y cells. Incorporation of leucine, choline, fucose, glucosamine, or thymidine into the cells, protein, nucleic acid, or lipid was measured by pulse-labeling for ½ hr at ½ hr intervals after release from the mitotic block. The amount of protein, lipid, glycoprotein, or glycolipid released or secreted into the medium by the L5178Y cells was also measured as a function of time of the cell cycle. Cellular protein was found to be synthesized throughout the cell cycle, with the highest synthesis occurring in the S period; synthesis was depressed in the M period. Cellular glycoprotein was synthesized at approximately the same times as protein, except that the rates of glycoprotein synthesis in the S period relative to other periods were much greater than for protein. Secreted protein was synthesized throughout the cell cycle without any general pattern, except that secretion was elevated in the late S and G₂ periods. Secreted glycoprotein was similar to secreted protein. Cellular lipid and cellular glycolipid were synthesized almost exclusively in the G₂ and M periods; there was no synthesis in the G₁ and S periods. Release or secretion of glycolipid and lipid also occurred in the G₂ and M periods.     

Micronucleus, chromosome aberration, and small-colony TK mutant analysis to quantitate chromosomal damage in L5178Y mouse lymphoma cells

In testing the hypothesis that the small-colony thymidine kinase-deficient mutants of L5178Y/TK+/- -3.7.2C mouse lymphoma cells represent an estimate of the clastogenicity of test chemicals, we have been performing gross aberration analysis. The present study was initiated to determine if the cytokinesis block method of micronucleus analysis could be performed in mouse lymphoma cells and to compare 3 different endpoints of clastogenicity: the number of metaphases with aberrations, number of binucleates with micronuclei, and small-colony TK mutant frequency. In this study, 12 compounds having varying clastogenic potencies were evaluated. As would be expected, the 3 endpoints vary in the relative magnitude of the quantitated response. This difference likely results from the types of clastogenic damage detected by each endpoint. Of the 3 endpoints tested, only the small-colony TK mutant frequency measures events compatible with long-term cell survival.     

Amino acid content of L5178Y and L5178Y/L-ASE cells after L-asparaginase treatment

The amino acid contents of tumor cells that are either sensitive or resistant to treatment with L-asparaginase were measured. These amino acid concentrations were measured as a function of incubation time with L-asparaginase or as a function of the L-asparaginase dose. The cell types compared were the mouse leukemia lines L5178Y (sensitive to L-asparaginase treatment) and L5178Y/L-ASE (resistant to L-asparaginase treatment). Upon L-asparaginase treatment both cell lines lost most of their cellular asparagine but, whereas the resistant cells exhibited the ability to rebound to about 50% of initial values, the sensitive cells did not. While previous work had suggested that asparagine-dependent glycine synthesis was essential for sensitive cells (but not in resistant cells), we found no difference in the glycine content of either of the two cell lines as a function of either time or dose that would support this hypothesis. Major differences between the two cell lines were seen in the content of the essential amino acids before treatment with L-asparaginase. After incubation without L-asparaginase the contents of the two cell lines became similar. These results are discussed in terms of possible mechanisms of L-asparaginase sensitivity and resistance.     

The relationship between Y chromosome DNA haplotypes and Y chromosome deletions leading to male infertility

Microdeletions on the short arm of the Y chromosome have defined three non-overlapping regions (AZFa, b, c) recurrently deleted among infertile males. These regions contain several genes or gene families involved in male germ-cell development and maintenance. Even though a meiotic origin for these microdeletions is assumed, the mechanisms and causes leading to microdeletion formation are largely unknown. In order to assess whether some Y chromosome groups (or haplogroups) are predisposed to, or protected against, deletion formation during male meiosis, we have defined and compared Y chromosome haplogroup distribution in a group of infertile/subfertile males harbouring Yq deletions and in a relevant Northwestern European control population. Our analyses suggest that Y chromosome deletion formation is, at least in the study populations, a stochastic event independent of the Y chromosome background on which they arise and may be caused by other genetic and/or environmental factors.     

Adaptation of mouse leukemic cells (L5178Y) to anisotonic media : II. Cell growth

Mouse lymphoma cells (L5178Y) exposed to hypertonic media for 1 h behave as osmometers, but in hypotonic media, after initial swelling, they shrink back to normal volume and maintain it for long periods of time. The lower limit of osmolarity at which this “volume adaptation” will occur lies between 140 and 185 mosM. The “volume adaptation” is associated with a loss of cellular K⁺ probably due to a transient increase in K⁺ permeability and to loss of associated anions and osmotically obliged water. Partial dissipation of the large gradient of K⁺ between cells and medium by pre-exposure to ouabain or to K⁺-free medium results in a diminished capacity to adapt. After the shrinking phase is completed, a new steady state is established with a reduced cellular K⁺ content, normal Na⁺, normal K⁺-permeability, and a reduced activity of the Na⁺ − K⁺ transport system. When adapted cells are returned to normal medium, an initial shrinking is followed by a re-swelling to normal size, associated with a gain in K⁺ content, presumably due to the return to normal activity of the Na⁺ − K⁺ transport system.     

Studies on three mutagen-sensitive mutants of mouse L5178Y cells. I. Characterization of the hybrids between L5178Y and mutagen-sensitive mutants

Three mutagen-sensitive mutants, MS-1, M10 and Q31, have been isolated from mouse L5178Y cells. MS-1 cells are sensitive to methyl methanesulfonate (MMS), M10 cells are cross-sensitive to X-rays, MMS and 4-nitroquinoline 1-oxide (4NQO), and Q31 cells are cross-sensitive to UV and 4NQO. Lines resistant to 6-thioguanine (TGr) and 5-bromo-2'-deoxyuridine (BUr) were isolated from L5178Y and these three mutagen -sensitive mutants. All the TGr lines were sensitive to 5-bromo-2'-deoxyuridine and HAT medium and all the BUr lines were sensitive to 6-thioguanine and HAT medium. The hybrids homozygous for the mutagen-sensitive markers showed nearly the same sensitivity to UV, 4NQO, X-rays and MMS as their parental TGr and BUr lines. The hybrids constructed by fusing L5178Y BUr and TGr lines from each of MS-1, M10 and Q31 displayed the normal UV, X-ray and MMS resistancy of L5178Y cells. Thus the UV-, X-ray- and MMS-sensitive markers in MS-1, M10 and Q31 were recessive in somatic cell hybrids. The 4NQO-sensitive phenotype, however, behaved codominantly in somatic cell hybrids.     

The repair of bleomycin-induced DNA damage and its relationship to chromosome aberration repair.

Previous studies using the technique of premature chromosome condensation indicated that nearly one-half of the bleomycin-induced chromatid breaks and gaps in CHO cells could be repaired within 1 h (repair starting at 30 min) after treatment. Cycloheximide and streptovitacin A (but not hydroxyurea or hycanthone) inhibited chromosome repair. The purpose of this study was to measure the kinetics of DNA repair after bleomycin treatment using the alkaline elution technique and to determine whether various inhibitors could block this repair. After bleomycin treatment, the major proportion of the repair of DNA damage occurred within 15 min, with significant repair evident by 2 min. This fast repair component was inhibited by 0.2% EDTA. A slower repair component was observed to occur up to 60 min after bleomycin treatment. None of the inhibitors tested were found to have a significant effect on the repair of bleomycin damage at the DNA level. Since chromosome breaks were observed not to begin repair until after 30 min while over 50% of the DNA was repaired by 15 min, these results suggest that the DNA lesions that are repaired quickly are not important in the formation of chromosome aberrations. Further, since cycloheximide and streptovitacin A blocked chromosome repair but had little measurable effect on DNA repair, these results suggest that the DNA lesions responsible for chromosome damage represent only a small proportion of the total DNA lesions produced by bleomycin.     

Methyl methanesulphonate mutagenesis in L5178Y mouse lymphoma cells.

The alkylating agent MMS was toxic to mouse lymphoma L5178Y cells and decreased their growth rate. A dose-dependent induction of thioguanine- and thymidine- but not ouabain-resistant variants was observed. The prolonged period for expression of thioguanine-resistant variants observed with other mutagens was also found in these studies. A comparison of MMS and EMS showed that MMS on a molar basis was approximately 10 times more toxic than EMS. With mutation, however, when evaluated at equal levels of cell killing MMS and EMS induced the same number of thymidine-resistant variants. For thioguanine-resistant variants MMS was approximately 10-fold less efficient than EMS, while for ouabain-resistance MMS, unlike EMBS, produced no variants at all. The ouabain results were further compared with positive results obtained using a modified Luria--Delbrück fluctuation test.     

The repair of double-strand DNA breaks correlates with radiosensitivity of L5178Y-S and L5178Y-R cells

To better understand the basis for the difference in radiosensitivity between the variant murine leukemic lymphoblast cell lines L5178Y-R (resistant) and L5178Y-S (sensitive), the production and repair of DNA damage after X irradiation were measured by the DNA alkaline and neutral elution techniques. The initial yield of single-strand DNA breaks and the rates of their repair were found to be the same in both cell lines by the DNA alkaline elution technique. Using the technique of neutral DNA elution, L5178Y-S cells exhibited slightly increased double-strand breakage immediately after irradiation, most significantly at lower doses (i.e., less than 10 Gy). Nevertheless, even at doses that yielded equal initial double-strand breakage of both cell lines, the survival of L5178Y-S cells was significantly less than that of L5178Y-R cells. When the technique of neutral DNA elution was employed to measure the kinetics of DNA double-strand break repair, both cell lines exhibited biphasic fast and slow components of repair. However, the double-strand repair rate was much lower in the radiosensitive L5178Y-S cells than in the L5178Y-R cells (T1/2 of 60 vs 16 min). This difference was more pronounced in the fast-repair component. These results suggest that the repair of double-strand DNA breaks is an important factor determining the radiosensitivity of L5178Y cells.     

Relationship of DNA repair to chromosome aberrations, sister-chromatid exchanges and survival during liquid-holding recovery in X-irradiated mammalian cells

The repair of X-ray induced DNA single strand breaks and DNA—protein cross-links was investigated in stationary phase, contact-inhibited mouse cells by the alkaline-elution technique. Approx. 90% of X-ray induced single strand breaks were rejoined during the first hour of repair, whereas most of the remaining breaks were rejoined more slowly during the next 5 h. At early repair times, the number of residual non-rejoined sungle strand breaks was approx. proportional to the X-ray dose. DNA—protein cross-links were removed at a slower rate (T1/2 approx. 10–12 h). Cells were held in stationary growth for various periods of time after irradiation before subculture at low density to score for colony survival (potentially lethal damage repair), chromosome aberrations in the first mitosis, and sister-chromatid exchanges in the second mitosis. Both cell killing and the frequency of chromosome aberrations decreased during the first several hours of recovery, reaching a minimum level by 6 h; this decrease correlated temporally with the repair of the slowly rejoining DNA-strand breaks. Relatively few sister-chromatid exchanges were observed when the cells were subcultured immediately after X-ray. The exchange frequency rose to maximum levels after a 4-h recovery interval, and returned to control levels after 12 h of recovery. The possible relationship of DNA repair to these changes in survival, chromosome aberrations, and sister-chromatid exchanges during liquid-holding recovery is discussed.     

Mutagenicity of rat-liver S9 to L5178Y mouse lymphoma cells

Rat-liver S9 preparations became highly mutagenic to cultured L5178Y mouse lymphoma cells when the exposure period was increased to 18-24 h or when S9 mix was preincubated in Fischer's medium at 37 degrees C for 19 h and then used to treat the cells for 4 h. Five different S9 preparations (from untreated and Aroclor 1254-treated Fischer 344 or Sprague-Dawley male rats) behaved similarly. S9 mix, which contained 1 mM NADP and 5 mM isocitrate as cofactors, was more mutagenic than S9 alone. Heat treatment of S9 did not destroy its mutagenic activity, but the addition of cofactors no longer stimulated an increase in mutagenicity, as observed with native S9. Treatment with cofactors was not mutagenic. These results implied the involvement of both energy-independent and NADPH-dependent enzymatic changes in S9 mix in producing mutagenic substances. The mutagenic treatments with S9 or S9 mix induced predominantly small TFT-resistant mutant colonies, which suggested that these treatments should be clastogenic to cultured mammalian cells. A warning was given that test chemicals evaluated as mutagenic only in the presence of S9 mix may instead be accelerating the decomposition of S9 mix into mutagens, and it may become necessary to experimentally distinguish between these two mechanisms before a chemical can be regarded as mutagenic.