Dosimetric advantages of generalised equivalent uniform dose-based optimisation on dose-volume objectives in intensity-modulated radiotherapy planning for bilateral breast cancer.

OBJECTIVE: We compared and evaluated the differences between two models for treating bilateral breast cancer (BBC): (i) dose-volume-based intensity-modulated radiation treatment (DV plan), and (ii) dose-volume-based intensity-modulated radiotherapy with generalised equivalent uniform dose-based optimisation (DV-gEUD plan). METHODS: The quality and performance of the DV plan and DV-gEUD plan using the Pinnacle(3) system (Philips, Fitchburg, WI) were evaluated and compared in 10 patients with stage T2-T4 BBC. The plans were delivered on a Varian 21EX linear accelerator (Varian Medical Systems, Milpitas, CA) equipped with a Millennium 120 leaf multileaf collimator (Varian Medical Systems). The parameters analysed included the conformity index, homogeneity index, tumour control probability of the planning target volume (PTV), the volumes V(20 Gy) and V(30 Gy) of the organs at risk (OAR, including the heart and lungs), mean dose and the normal tissue complication probability. RESULTS: Both plans met the requirements for the coverage of PTV with similar conformity and homogeneity indices. However, the DV-gEUD plan had the advantage of dose sparing for OAR: the mean doses of the heart and lungs, lung V(20) (Gy), and heart V(30) (Gy) in the DV-gEUD plan were lower than those in the DV plan (p<0.05). CONCLUSIONS: A better result can be obtained by starting with a DV-generated plan and then improving it by adding gEUD-based improvements to reduce the number of iterations and to improve the optimum dose distribution. Advances to knowledge The DV-gEUD plan provided superior dosimetric results for treating BBC in terms of PTV coverage and OAR sparing than the DV plan, without sacrificing the homogeneity of dose distribution in the PTV.

Antimutagenicity of WR-1065 in L5178Y cells exposed to accelerated (56)Fe ions.

The ability of the aminothiol WR-1065 [N-(2-mercaptoethyl)-1,3-diaminopropane] to protect L5178Y (LY) cells against the cytotoxic and mutagenic effects of exposure to accelerated (56)Fe ions (1.08 GeV/nucleon) was determined. It was found that while WR-1065 reduced the mutagenicity in both cell lines when it was present during the irradiation, the addition of WR-1065 after the exposure had no effect on the mutagenicity of the radiation in either cell line. No marked protection against the cytotoxic effects of exposure to (56)Fe ions was provided by WR-1065 when added either during or after irradiation in either cell line. We reported previously that WR-1065 protected the LY-S1 and LY-SR1 cell lines against both the cytotoxicity and mutagenicity of X radiation when present during exposure, but that its protection when administered after exposure was limited to the mutagenic effects in the radiation-hypersensitive cell line, LY-S1. The results indicate that the mechanisms involved differ in the protection against cytotoxic compared to mutagenic effects and in the protection against damage caused by accelerated (56)Fe ions compared to X radiation.

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

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

Genotoxic effects of high-energy iron particles in human lymphoblasts differing in radiation sensitivity.

The effects of (56)Fe particles and (137)Cs gamma radiation were compared in TK6 and WTK1 human lymphoblasts, two related cell lines which differ in TP53 status and in the ability to rejoin DNA double-strand breaks. Both cell lines were more sensitive to the cytotoxic and clastogenic effects of (56)Fe particles than to those of gamma rays. However, the mutagenicity of (56)Fe particles and gamma rays at the TK locus was the same per unit dose and was higher for gamma rays than for (56)Fe particles at isotoxic doses. The respective RBEs for TK6 and WTK1 cells were 1.5 and 1.9 for cytotoxicity and 2.5 and 1.9 for clastogenicity, but only 1 for mutagenicity. The results indicate that complex lesions induced by (56)Fe particles are repaired less efficiently than gamma-ray-induced lesions, leading to fewer colony-forming cells, a slightly higher proportion of aberrant cells at the first division, and a lower frequency of viable mutants at isotoxic doses. WTK1 cells (mutant TP53) were more resistant to the cytotoxic effects of both gamma rays and (56)Fe particles, but showed greater cytogenetic and mutagenic damage than TK6 cells (TP53(+)). A deficiency in the number of damaged TK6 cells (a) reaching the first mitosis after exposure and (b) forming viable mutants can explain these results.

Differential antimutagenicity of WR-1065 added after irradiation in L5178Y cell lines.

The purpose of this study was to determine the antimutagenicity of WR-1065 added after irradiation of cells of cell lines differing in their ability to rejoin radiation-induced DNA double-strand breaks (DSBs). The postirradiation antimutagenicity of WR-1065 at the thymidine kinase locus was demonstrated for L5178Y (LY)-S1 cells that are deficient in repair of DNA DSBs. Less postirradiation antimutagenicity of WR-1065 was observed in LY-R16 and LY-SR1 cells, which are relatively efficient in DSB repair. Postirradiation treatment with WR-1065 had only a small stimulatory effect on DSB rejoining. A 3-h incubation of irradiated LY cells with WR-1065 caused slight changes in the distribution of cells in the phases of the cell cycle that differed between LY-S1 and LY-SR1 cells. Both LY-S1 and LY-SR1 cells were protected against the cytotoxic and mutagenic effects of radiation when WR-1065 was present 30 min before and during the irradiation. We conclude that the differential postirradiation effects of WR-1065 in the LY-S1 and LY-SR1 cells are not caused by differences in cellular uptake of the radioprotector or in its radical scavenging activity. Possible mechanisms for the postirradiation antimutagenicity of WR-1065 are discussed.

Variation in photodynamic efficacy during the cellular uptake of two phthalocyanine photosensitizers.

A decrease in the efficacy of photodynamic therapy (PDT) with phthalocyanine photosensitizers was observed for lymphoblastic murine and human cell lines as the time between the addition of the photosensitizer, aluminum phthalocyanine (AIPc), to the culture medium and exposure to light was increased from 4 h to 18 h. The total intracellular concentration of photosensitizer did not decrease significantly during this 18 h interval. For the murine cell lines, the maximum cytotoxic and mutagenic effects were observed when the time between addition of the photosensitizer and irradiation was between 1 and 4 h. The time course of the variations in efficacy did not vary greatly from one murine cell line to another, even though the cell lines differ markedly in the extent of their cytotoxic and mutagenic response. The time course of the variation was similar for cytotoxicity and mutagenicity, as well as for the induction of DNA fragmentation. The human lymphoblastic cell line, WTK1, showed less variation in survival and mutability with time than did the murine cell lines. With Pc 4 (HOSiPcOSi[CH3]2[CH2]3N[CH3]2) as the photosensitizer, the photocytotoxicity for murine L5178Y (LY)-S1 cells did not change significantly as the time between addition of Pc 4 and irradiation was increased from 2 to 18 h. However, the mutagenicity decreased by a factor of three during this interval. The mutagenicity of PDT with Pc 4 was much less in LY-S1 cells than that with AlPc. The results suggest that the variation in the efficacy observed for AlPc-induced photocytotoxicity is caused by changes in the intracellular distribution and/or the aggregation of the photosensitizer with time after its addition.

Mutagenicity of photodynamic therapy as compared to UVC and ionizing radiation in human and murine lymphoblast cell lines.

The mutagenicity of photodynamic therapy (PDT) using red light and either Photofrin (porfimer sodium) (PF) or aluminum phthalocyanine (AlPc) as the photosensitizer was determined at the thymidine kinase (TK) locus in the human lymphoblastic cell lines, TK6 and WTK1, and was compared to the mutagenicity of UVC and X-radiation in these cells as well as the mutagenicity of PDT in murine L5178Y lymphoblastic cell lines. Photodynamic therapy was found not to be mutagenic in TK6 cells, which possess an active p53 gene and which are relatively deficient in recombination and repair of DNA double-strand breaks. In contrast, PDT with either sensitizer was significantly mutagenic in WTK1 cells, which harbor an inactivating mutation in the p53 gene and are relatively efficient in recombination and double-strand break repair as compared to TK6 cells. The induced mutant frequency in WTK1 cells with PF as the photosensitizer was similar to that induced by UVC radiation but lower than that induced by X-radiation at equitoxic fluences/doses. The mutant frequency induced by PDT in WTK1 cells with either photosensitizer was much lower than that induced in murine lymphoblasts at equitoxic fluences. The TK6 and WTK1 cells did not differ in their sensitivity to the cytotoxic effects of PDT, but the level of PDT-induced apoptosis was greater in TK6 than in WTK1 cells. These results indicate that the mutagenicity of PDT varies in different types of cells and may be related to the repair capabilities as well as the p53 status of the cells.

Induction of multilocus mutations at the Tk1 locus after X irradiation of L5178Y cells at different times in the mitotic cycle.

TK1+/- L5178Y-R16 cells were separated into G1, S and G2/M-phase populations by centrifugal elutriation and were treated with 1.5 Gy X radiation. Cells irradiated in the G1 and G2/M phases were most sensitive to the cytotoxic effects of radiation, while cells irradiated in the G2/M phase showed the highest mutant frequency at the thymidine kinase (Tk1) locus. DNA isolated from independent TK1-/- mutants was analyzed for loss of heterozygosity (LOH) at the Tk1 locus and two microsatellites, D11Mit48 and D11Nds7. Homogenates of each mutant were assayed for activity of galactokinase (GLK), the product of the galactokinase (Glk) gene neighboring the Tk1 gene on chromosome 11. Irradiated G1-phase cells had the highest percentage of mutants showing no LOH. The frequency of mutants with LOH at both Tk1 and D11Nds7 with no loss of GLK activity was high in all cell populations: There was no significant difference in the observed frequency of these mutants between the populations. The frequency of mutants losing GLK activity was low, particularly in cells irradiated in the S or G2/M phases. The possibility that the loss of GLK activity is not indicative of LOH at the Glk gene under the conditions of the present experiments is discussed.

Characterization of multilocus lesions in human cells exposed to X radiation and radon.

Human TK6 lymphoblasts were exposed to X radiation or radon, and thymidine kinase negative (TK-/-) mutants were selected, isolated and harvested for analysis of structural changes in the TK gene. A large majority (82%) of the radon-induced mutants, 74% of the X-radiation-induced mutants and 45% of the spontaneous mutants lost the entire active TK allele. To analyze these mutants further we measured the loss of heterozygosity at several loci neighboring the TK locus on chromosome 17q. A greater proportion (61%) of the radon-induced mutants than X-radiation-induced or spontaneous mutants harbored the smaller lesions involving the TK allele alone or extending from the TK locus to one or both of the closest neighboring sequences tested. Further, 21% of the X-radiation-induced mutants but only 5% of the radon-induced mutants lost heterozygosity at the col1A1 locus, 31 Mb from the TK gene. These results are in agreement with a recent analysis of radon- and X-radiation-induced lesions inactivating the HPRT gene of TK6 cells, in which we reported that a lower percentage of radon- than X-radiation-induced mutants showed lesions extending to markers 800 kb or more from the HPRT gene on the X chromosome (Bao et al., Mutat. Res. 326, 1-13, 1995). In the present study, we observed that the percentage of slowly growing and very slowly growing TK-/- mutants was greater after treatment with radon than after treatment with X radiation, regardless of the type of lesion present. It is possible, therefore, that the radon-induced lesions are complex and/or less easily repaired, leading to slow growth in a large proportion of the surviving mutant cells.

Molecular analysis of hypoxanthine phosphoribosyltransferase gene deletions induced by alpha- and X-radiation in human lymphoblastoid cells.

Mutations caused by exposure to X-radiation and to radon and its decay products were compared in the hprt gene of a human lymphoblastoid cell line. Thirty-one X-radiation-induced, 29 radon-induced, and 24 spontaneous mutants were recovered from cell cultures under identical conditions except for the exposure to radiation. Seven spontaneous point mutations were recovered and DNA sequenced. These mutations included three C:G-->T:A transitions. These spontaneous point mutations were located in the exon or splice donor regions of five of the nine hprt exons. Four X-radiation-induced and three radon-induced point mutations were also analyzed by DNA sequencing. The frequency of induced mutants at the D0 doses for radon and X-radiation respectively were 5 x 10(-6) and 4.5 x 10(-6). Deletions were the predominant mutations recovered from both radon- and X-irradiated cells. Eighty-one percent of the mutants from X-radiation-treated cultures, 86% of the radon-treated cultures, and 63% of the spontaneous mutants involved deletions. Deletions involving exon and intron DNA, as well as intron DNA alone, were found to inactivate the hprt gene and result in a selectable HPRT- phenotype. Among the deletion mutants, however, only 21% of the spontaneous mutants versus 55% of both the X-radiation- and radon-induced mutants exhibited loss of the entire hprt gene. More X-radiation-induced deletions than radon-induced deletions extended further than 800 bp in the telomeric direction from the hprt gene (six of 17 versus two of 17). The results show that at the human hprt locus of TK-6 cells the predominant kind of mutation indicative of exposure to both high LET alpha-radiation and low LET X-radiation is a large deletion, spanning the entire hemizygous hprt gene and extending into flanking sequences.

Cytotoxic and mutagenic effects of radon and radon daughters on murine L5178Y lines differing in DNA repair.

The effects of 222Rn were measured in mouse L5178Y (LY) lymphoblasts that differ in repair capabilities. Line LY-S1 is deficient in the repair of X-radiation-induced DNA doublestrand breaks, while lines LY-R16 and LY-R83 are presumed to be deficient in the excision of UV-radiation-induced pyrimidine dimers. Line LY-R83 is hemizygous while the other two lines are heterozygous at the thymidine kinase (tk) locus. After exposure to radon the D0's were found to be very similar for the three lines (0.30-0.31 Gy), whereas for X radiation the D0 for line LY-S1 is lower (0.7 Gy) than that for the two LY-R lines (1.3 Gy). Mutant frequencies at the tk locus were higher per gray after treatment with radon than X radiation, but at equitoxic doses the mutant frequencies were similar for X and alpha-particle radiation. A low radon-induced mutant frequency was observed for the hemizygous line, in agreement with the hypothesis that multilocus lesions were induced by the alpha-particle radiation and that mutants bearing intergenic lesions were not recovered in the TK+/- line. The entire active tk allele was lost by 81% of the TK-/- mutants of line LY-R16. In lines LY-S1 and LY-R16, 39-43% of the TK-/- mutants exhibited loss of galactokinase activity, indicating that the mutational lesion inactivating the tk gene frequently extended to the neighboring galactokinase gene.

DNA double-strand break rejoining deficiency in TK6 and other human B-lymphoblast cell lines.

TK6, WI-L2, SB and three other B-lymphoblast lines were deficient in the rejoining of DNA double-strand breaks (DSBs) induced by ionizing radiation. Cells of these cell lines rejoin less than 50% of the breaks in 60 min after exposure, as assayed by filter elution at pH 9.6. The deficiency in TK6 cells was confirmed using the comet assay. IN TK6 cells the percentage of DSB rejoining did not vary markedly with dose and was similar for G1, S, and G2 + M-phase cells. Two B-lymphocyte lines (Raji and GM0606), three T-lymphoblast lines (MOLT-4, Jurkat, and CCRF-HSB-2), HL-60 promyelocytes, and GM3440 human skin fibroblasts rejoined more than 50% of the DSBs in this period after exposure. Radiation sensitivity in terms of cell survival was measured in those cells forming colonies. Of the cell lines tested, those that were deficient in DSB rejoining were radiation-sensitive (TK6 and WI-L2: D0 = 0.64 Gy). However, not all lines that were proficient in DSB rejoining were radiation-resistant, since Jurkat and GM0606 cells were relatively radiation-sensitive (D0 = 0.63-0.73 Gy). TK6 and WI-L2 cells were more sensitive to bleomycin (D0 = 8-9 micrograms/ml) than were HL-60 and Raji cells (D0 = 40-54 micrograms/ml). No relationship of DSB rejoining to V(D)J recombinase activity was observed, since no mRNA hybridizing to the cDNA probes for RAG-1 or RAG-2 was detected in any of the cell lines tested.

Induction of multilocus lesions by UVC-radiation in mouse L5178Y lymphoblasts.

The survival, the mutant frequency and the nature of the DNA alteration responsible for the inactivation of the thymidine kinase (tk) locus were investigated in 5 strains of mouse L5178Y lymphoblasts exposed to UVC radiation. The nature of the DNA alteration was investigated in independent TK-/- mutants using Southern blot analysis. The concomitant loss of galactokinase (GK) activity in homogenates of individual TK-/- mutants was taken as an indication that the lesion inactivating the tk allele extended to the neighboring galactokinase (gk) allele. The survival of strains LY-R16 and LY-R83 was decreased to a greater extent than that of strains LY-S1, LY-SR1, and LY-3.7.2C, reflecting a deficiency in excision repair in strains derived from LY-R cells. The TK-/- mutant frequency of strain LY-R83, which is monosomic for chromosome 11 and thus hemizygous for the tk and gk genes, was only 50% of the mutant frequency of strain LY-R16 which is heterozygous for the tk gene. Moreover, a greatly reduced percentage of individual spontaneous and UVC-induced TK-/- mutants of strain LY-R83 showed loss of GK activity in comparison to the other strains. This result indicates that UVC irradiation induces intergenic mutations and that such mutants are poorly recovered in the hemizygous strain. Strain LY-3.7.2C appears to have only one active galactokinase (gk) allele, and very few TK-/- mutants of this strain showed loss of GK activity, possibly because this strain, although heterozyogous for the tk gene, is hemizygous in the region of the gk gene. Strains LY-R16 and LY-S1 are deficient in the repair of UVC- and X-radiation-induced damage, respectively, and the percentage of TK-/- mutants with intergenic mutations was higher for strain LY-R16 after UVC-radiation and for strain LY-S1 after X-radiation. These results indicate that unrepaired DNA lesions lead to an increase in intergenic mutations.

The effect of dose rate on X-radiation-induced mutant frequency and the nature of DNA lesions in mouse lymphoma L5178Y cells.

The induction of mutants at the heterozygous tk locus by X radiation was found to be dose-rate dependent in L5178Y-R16 (LY-R16) cells, but very little dose-rate dependence was observed in the case of strain L5178Y-S1 (LY-S1), which is deficient in the repair of DNA double-strand breaks. Induction of mutants by X radiation at the hemizygous hprt locus was dose-rate independent for both strains. These results are in agreement with the hypothesis that the majority of X-radiation-induced TK-/- mutants harbor multilocus deletions caused by the interaction of damaged DNA sites. Repair of DNA lesions during low-dose-rate X irradiation would be expected to reduce the probability of lesion interaction. The results suggest that in contrast to the TK-/- mutants, the majority of mutations at the hprt locus in these strains of L5178Y cells are caused by single lesions subject to dose-rate-independent repair. The vast majority of the TK-/- mutants of strain LY-R16 showed loss of the entire active tk allele, whether the mutants arose spontaneously or were induced by high-dose-rate or low-dose-rate X irradiation. The proportion of TK-/- mutants with multilocus deletions (in which the products of both the tk gene and the closely linked gk gene were inactivated) was higher in the repair-deficient strain LY-S1 than in strain LY-R16. However, even though the mutant frequency decreased with dose rate, the proportion of mutants showing inactivation of both the tk and gk genes increased with a decrease in dose rate. The reason for these apparently conflicting results concerning the effect of DNA repair on the induction of extended lesions is under investigation.

DNA lesions and DNA degradation in mouse lymphoma L5178Y cells after photodynamic treatment sensitized by chloroaluminum phthalocyanine.

Two closely related strains of mouse lymphoma L5178Y cells, LY-R and LY-S, have been found to differ in their sensitivity to the cytotoxic effects of photodynamic treatment (PDT) with chloroaluminum phthalocyanine (CAPC) and red light. Strain LY-R is more sensitive to photodynamic cell killing than strain LY-S. Differences in uptake of CAPC could not account for the differences in cytotoxic effects. There was no marked difference between the two strains in the induction of single-strand breaks (which includes frank single-strand breaks and alkali-labile lesions), but substantially more DNA-protein cross-links were formed in strain LY-R by CAPC and light. Repair of single-strand breaks proceeded with similar kinetics in both strains for the first 30 min post-irradiation, suggesting that these lesions are not responsible for the differential sensitivity of the two strains to the lethal effects of photodynamic treatment. Thereafter, alkaline elution revealed the presence of increasing DNA strand breakage in strain LY-R. DNA degradation, as measured by the conversion of prelabeled [14C] DNA to acid-soluble radioactivity, was more rapid and extensive in strain LY-R.

Relationship between topoisomerase II and radiosensitivity in mouse L5178Y lymphoma strains.

The cytotoxic and mutagenic effects of topoisomerase II inhibitors were measured in closely related strains of mouse lymphoma L5178Y cells differing in their sensitivity to ionizing radiation. Strain LY-S is sensitive to ionizing radiation relative to strain LY-R and is deficient in the rejoining of DNA double-strand breaks induced by this agent, whereas 2 radiation-resistant variants of strain LY-S have regained the ability to rejoin these double-strand breaks. We have found that the sensitivity of these cells to m-AMSA, VP-16, and ellipticine is correlated to their sensitivity to ionizing radiation. However, this correlation did not extend to their sensitivities to novobiocin, camptothecin, hydrogen peroxide, methyl nitrosourea and UV radiation. Thus, there appears to be a unique correlation between sensitivity to ionizing radiation and to topoisomerase II inhibitors which stabilize the cleavable complex between the enzyme and DNA. It is possible either that (1) topoisomerase II is altered in strain LY-S and that this enzyme is involved in the repair of DNA double-strand breaks or (2) strain LY-S is deficient in a reaction which is necessary for the repair of DNA double-strand breaks induced by ionizing radiation as well as the repair of DNA damage induced by these topoisomerase II inhibitors. m-AMSA, VP-16, and ellipticine were found to be highly mutagenic at the tk locus in L5178Y strains which are heterozygous for the tk gene but not in a tk hemizygous strain, indicating that these inhibitors induce multilocus lesions in DNA, as does ionizing radiation. The differences in the sensitivity of strains LY-R and LY-S to the topoisomerase II inhibitors were paralleled by differences in the induction of protein-associated DNA double-strand breaks in the 2 strains. This correlation did not extend to the radiation-resistant variants of strain LY-S, however. The variants showed resistance to the cytotoxic effects of the inhibitors relative to strain LY-S, but exhibited DNA double-strand break induction similar to that observed in strain LY-S.

The repair of potentially lethal damage and sublethal damage in strains of mouse L5178Y lymphoma cells differing in radiation sensitivity.

Mouse lymphoma strains L5178Y-R (LY-R) and L5178Y-S (LY-S), which are differentially sensitive to the cytotoxic effects of ionizing radiation, were found to differ in their abilities to repair potentially lethal damage (PLD) and sublethal damage (SLD). The results showed that strain LY-R was more proficient than strain LY-S in the repair of SLD. The split dose recovery observed in strain LY-S could be accounted for by its recovery during postirradiation incubation. In contrast, SLD repair occurred in the absence of PLD repair in strain LY-R. The possibility that the repair of PLD might be completed prior to the postirradiation incubation in strain LY-R was suggested by the decreased survival observed when the cells were irradiated in a hypotonic solution. The repair of PLD and SLD in strain LY-S was temperature sensitive, occurring during postirradiation incubations between 15 and 34 degrees C, but not at 37 or 40 degrees C. This temperature sensitivity is very similar to the temperature sensitivity of the repair of pH 9.6-labile lesions in DNA in strain LY-S, as reported previously. Thus postirradiation cellular recovery processes in strain LY-S may involve the repair of pH 9.6-labile lesions in DNA. Temperature-dependent changes in the postirradiation distribution of cells throughout the cell cycle were observed which could contribute to the temperature sensitivity of the postirradiation recovery of strain LY-S.

Deficiency in DNA repair in mouse lymphoma strain L5178Y-S.

The production and repair of radiation-induced DNA damage were measured by filter elution in strains of mouse lymphoma L5178Y cells differing in their sensitivity to ionizing radiation. The induction of radiation-induced damage, as measured by filter elution at pH 12.1, 9.6, and 7.2, was similar in the resistant strain LY-R and the sensitive strain LY-S. The repair of single-strand breaks and alkali-labile sites, as measured by filter elution at pH 12.1 at various times after irradiation, was somewhat slower in strain LY-S than in strain LY-R, although after a 20-min repair period the extent of repair was equal in the two strains. However, when filter elution was performed at either pH 9.6 or pH 7.2, the repair of x-radiation-induced damage was much less extensive in strain LY-S than in strain LY-R. We have assumed that the extent of filter elution at pH 9.6 is a measure of the occurrence of frank double-strand breaks as well as closely opposing single-strand breaks and pH 9.6-labile sites (and combinations thereof), and that the extent of elution at pH 7.2 is a measure of the occurrence of frank double-strand breaks alone. If these assumptions are correct, the results suggest that the sensitivity of strain LY-S to the cytotoxic effects of ionizing radiation is caused by a deficiency in the ability of this strain to repair frank double-strand breaks and pH 9.6-labile lesions. The repair of pH 9.6-labile lesions was temperature sensitive in strain LY-S, as previously found for cellular recovery processes in this strain. Two independent radiation-resistant variants of strain LY-S, isolated after protracted exposure of LY-S cells to low-dose-rate radiation, showed a deficiency in the repair of pH 9.6-labile lesions similar to that observed in strain LY-S. However, the repair of frank double-strand breaks was more extensive in the radiation-resistant variants than in strain LY-S and was similar in extent to that occurring in strain LY-R after a 60-min postirradiation incubation. The results suggest that there is a difference in the nature of DNA damage measured by filter elution at pH 9.6 vs. pH 7.2 and that a deficiency in the repair of pH 9.6-labile lesions does not contribute to cell lethality in the case of the radiation-resistant variants. The radiation resistance of these variants in comparison to strain LY-S may be due at least in part to recovery of the ability to rejoin frank DNA double-strand breaks.

Lethal and mutagenic effects of radiation and alkylating agents on two strains of mouse L5178Y cells.

In previous studies, the two closely related strains of L5178Y (LY) mouse lymphoma cells, LY-R and LY-S, have been shown to differ in their sensitivity to UV and ionizing radiation. Thus, in comparison to strain LY-R, strain LY-S has been found to be more sensitive to the lethal effects of ionizing radiation, more resistant to the lethal effects of UV radiation, but less mutable at the hypoxanthine-guanine phosphoribosyl transferase (HGPRT) locus by both UV and X-radiation. In the present work, the lethal and mutagenic effects of ethyl methanesulfonate (EMS), methyl nitrosourea (MNU) and UV radiation (254 nm) were compared in the two strains. Mutability at the Na+/K+-ATPase locus as well as the HGPRT locus was determined. As previously reported, we found strain LY-S to be more resistant than strain LY-R to the lethal effects of UV radiation. In contrast, strain LY-S was more sensitive to the cytotoxic effects of the two alkylating agents. In spite of these differences in sensitivity, we found strain LY-S to be less mutable than strain LY-R by all 3 agents at the HGPRT locus. At the Na+/K+-ATPase locus, strain LY-S was also less mutable than strain LY-R by equal concentrations of EMS and UV radiation and by equitoxic concentrations of MNU. However, the difference between the strains was much more pronounced at the HGPRT locus than at the Na+/K+-ATPase locus. We have suggested that the interaction of unrepaired lesions in strain LY-S tends to cause an excess of deletions and multilocus effects, which in turn result in a locus-dependent decrease in the recovery of viable LY-S mutant cells.

Locus specificity in the mutability of L5178Y mouse lymphoma cells: the role of multilocus lesions.

Mouse L5178Y strain LY-S and its parental strain LY-R differ in their comparative sensitivities to the cytotoxic effects of various mutagenic agents--i.e., strain LY-S has been found to be more sensitive, less sensitive, or similarly sensitive to individual agents in comparison to strain LY-R. Nevertheless, strain LY-S has been found to be uniformly less mutable than strain LY-R at the hypoxanthine (guanine) phosphoribosyltransferase (Hprt) locus following treatment with x-radiation, UV radiation, or alkylating agents. In the present work we have isolated subclones of strains LY-R and LY-S that are heterozygous at the thymidine kinase (Tk) locus (chromosome 11). We have found that a heterozygous LY-S Tk+/Tk- strain shows as high or higher mutability at the Tk locus than do heterozygous LY-R strains following treatment with x-radiation, UV radiation, or ethyl methanesulfonate. Mutability of all heterozygous strains at the Tk locus is much higher than at the Hprt locus following treatment with these mutagenic agents, with the exception of one heterozygous LY-R strain that possesses only one chromosome 11 and that is poorly mutable at the Tk locus by x-radiation. On the basis of these results, we have suggested that because of a repair deficiency, multilocus lesions are formed in the DNA of LY-S strains following treatment with radiation or alkylating agents; multilocus lesions lead to poor recovery of viable mutants when the target locus is closely linked to essential genes and situated on a hemizygous chromosomal region (e.g., the Hprt locus on the X chromosome or the Tk locus in strains monosomic for chromosome 11); and x-radiation is a relatively poor mutagen at loci situated on hemizygous chromosomal regions, in repair-efficient and repair-deficient cells, because of its tendency to form multilocus lesions.