Cross-sensitivity of gamma-ray-sensitive hamster mutants to cross-linking agents

A range of hamster cell mutants, which have been characterised as sensitive to ionising radiation, were examined for their cross-sensitivity to four DNA-DNA cross-linking agents and the protein-DNA cross-linking agent, camptothecin. The mutants represent 7 distinct complementation groups. Two complementation groups were identified as having a major sensitivity to cross-linking damage, more marked than their sensitivity to ionising radiation (irs1, irs1SF). These two mutants also show sensitivity to UV-irradiation. Two of the remaining complementation groups (xrs and XR-1) have a defect in rejoining DNA double-strand breaks, and these exhibit sensitivity to 3 of the 4 DNA-DNA cross-linking agents. The results with these mutants suggest an involvement of double-strand break rejoining in the repair of certain cross-link damage. Two mutants were also notably sensitive to the topoisomerase I inhibiting anticancer drug, camptothecin. One of these mutants was sensitive to the DNA cross-linking agents examined (irs1SF), but the other was not at all sensitive to this class of drug (EM9).     

Six complementation groups for ionising-radiation sensitivity in Chinese hamster cells

The ionising radiation-sensitive mutants irs 1, irs 2, irs 3, xrs-1 (or xrs-7), EM7 and XR-1 were fused to wild-type cells or to each other in pairs to create hybrid cells. These hybrids were checked chromosomally and their X-ray sensitivity tested. Each mutant was found to be recessive to wild-type and to complement the X-ray sensitivity of the other mutants. Thus there appear to be at least 6 complementation groups for ionising radiation sensitivity in Chinese hamster cells.     

The genetic basis of resistance to ionising radiation damage in cultured mammalian cells

To test the genetic similarity of independently-isolated hamster cell mutants sensitive to ionising radiation, these were fused in pairs and the hybrids exposed to X-rays. Some mutants (irs1, irs3, xrs-1, XR-1, BLM2) were found to complement all others tested for radiosensitivity in hybrids, and are therefore in separate genetic groups. The mutants irs2 and V-E5, both isolated from V79 cells, did not complement and therefore belong to the same group. Another pair, EM7 and irs1SF, formed hybrids with intermediate levels of survival between mutant and wild-type. However, the parental cells fused to irs1SF also showed intermediate sensitivity, suggesting a semi-dominant mutant phenotype rather than a lack of complementation. Crosses of some of these hamster mutants to the radiosensitive mouse mutant M10 showed clear complementation (irs1 x M10, irs2 x M10) but for others the complementation did not greatly exceed the sensitivity of one (irs3 x M10) or both mutants (XR-1 x M10). Taken with our previously-published data, these results show that there are at least 8 genetic groups determining resistance to ionising radiation damage in rodent cells.     

Genetic analysis of X-ray-sensitive mutants of the CHO cell line

The genetic diversity of 6 X-ray-sensitive (xrs) mutants of the CHO cell line has been investigated. Hybrids were constructed by fusing ouabain- and 6-thioguanine-resistant cells to ouabain- and 6-thioguanine-sensitive cells and selecting in HAT and ouabain medium. Hybrids were examined for ploidy and X-ray sensitivity. Crosses between xrs mutants and wild-type showed that each mutant was recessive. Crosses between different xrs mutants showed that all were in the same complementation group. Although all the mutants are primarily sensitive to ionizing radiation and bleomycin, and all have a defect in double-strand break rejoining, their cross-sensitivity to other DNA-damaging agents differed to some degree. One explanation is that this repair gene is involved in a pleiotropic response to DNA damage.     

Genetic analysis of mitomycin-C-sensitive mutants of a Chinese hamster ovary cell line

5 mutants of a Chinese hamster ovary (CHO) cell line, which exhibit similar levels of sensitivity to killing by mitomycin C, have been analysed genetically to determine whether they represent one or more genetic complementation groups. Hybrids were constructed by fusing cells carrying either the neo or the Ecogpt marker and selecting in medium containing G418 and mycophenolic acid. Selectable markers were introduced into the cells by DNA transfection using pSV5-neo or pSV5-gpt, which represents a quick and convenient method for generating resistant derivatives. Hybrids generated by crosses between any one mutant and the parental cell line exhibited near wild-type resistance to mitomycin C, indicating that the mutants are phenotypically recessive. Self-cross hybrids for all 5 mutants had D37 values for killing by mitomycin C of between 20 and 30 ng/ml. The values obtained for crosses between different mutants were 60-105 ng/ml, with the exception of 1 pairing which gave a value of 33 ng/ml. These results indicate that that the mutants represent at least 4 different genetic complementation groups, suggesting that cellular resistance to mitomycin C is mediated via a number of different mechanisms.     

The cross sensitivity to radiations, chemical mutagens and heat treatment of X-ray sensitive mutants of yeast

Summary A number of radiation sensitive mutants of yeast were examined for their sensitivity to the inactivating agents, ultraviolet light (UV), gamma irradiation, ethyl methane sulphonate (EMS) and heat treatment (52° and 37°).A mutant of the gene rad-3, isolated on the basis of its primary sensitivity to UV showed sensitivity only to UV. In contrast the five X-ray sensitive mutants were sensitive to all four inactivating treatments. Considerable variation was observed in the response of the mutants to liquid holding treatment in non-nutrient solution.The data concerning the heat sensitivity of the X-ray sensitive mutants confirms the correlation between heat and X-ray sensitivity observed in bacteria by Bridges (1969).The results indicate that at least two separable pathways of cellular repair exist in yeast, one effective in the repair of UV damage and the other effective in the repair of ionising radiation, alkylating agents, heat and a fraction of UV damage.     

Isolation and characterization of mitomycin-C-sensitive mouse lymphoma cell mutants

26 mutants with increased sensitivity to the lethal effects of mitomycin C (MMC) were isolated from mouse lymphoma L5178Y cells by a replica-plating technique. Most of them were about 5-10 times more sensitive in terms of D37 values to MMC than were parental cells. 5 of the MMC-sensitive mutants isolated from independently mutagenized cell populations were further analyzed. They were highly sensitive to the killing by decarbamoyl (DC) MMC, a monofunctional derivative of MMC, but were not sensitive to ultraviolet radiation, X-rays, 4-nitroquinoline-1-oxide or methyl methanesulfonate. These 5 mutants were classified into at least 2 genetic complementation groups. The implication of these mutations in cross-link and mono-adduct repair of DNA damage induced by MMC and DCMMC is discussed.     

Lack of sensitivity of primary Fanconi's anemia fibroblasts to UV and ionizing radiation

Clinical observations and theoretical considerations suggest some degree of radiosensitivity in Fanconi's anemia (FA), but experimental evidence remains controversial. We tested the sensitivity of primary skin fibroblast cultures from all known FA complementation groups to ionizing radiation and ultraviolet light using conventional cell growth and colony formation assays. In contrast to previous studies, and because FA fibroblasts grow and clone poorly at ambient oxygen, we performed our sensitivity tests under hypoxic cell culture conditions. Fibroblast strains from healthy donors served as negative controls and those from patients with ataxia telangiectasia (AT) and Cockayne syndrome (CS) as positive controls. We observed interstrain variation but no systematic difference in the response of FA and non-FA control fibroblasts to ionizing radiation. After exposure to UV radiation, only complementation group A, G and D2 strains displayed values for colony formation EC50 that were intermediate between those for the negative and positive controls. Because of considerable interstrain variation, minor alterations of the response of individual FA strains to ionizing and UV radiation should be interpreted with caution and should not be taken as evidence for genotype-specific sensitivities of primary FA fibroblasts. All together, our data indicate neither systematic nor major sensitivities of primary FA fibroblast cultures of any complementation group grown under hypoxic cell culture conditions to ionizing or UV radiation.     

Telomere dysfunction: a new player in radiation sensitivity

Human individuals often exhibit important differences in their sensitivity to ionising radiation. Extensive literature links radiation sensitivity with impaired DNA repair which is due to a lack of correct functioning in many proteins involved in DNA-repair pathways and/or in DNA-damage checkpoint responses. Given that ionising radiation is an important and widespread diagnostic and therapeutic tool, it is important to investigate further those factors and mechanisms that underlie individual radiosensitivity. Recently, evidence is accumulating that telomere function may well be involved in cellular and organism responses to ionising radiation, broadening still further the currently complex and challenging scenario.     

Follow-up analysis of translocation and dicentric frequencies, measured by FISH-chromosome painting in breast cancer patients after partial-body radiotherapy with little bone marrow exposure

Fanconi anemia (FA) is one of several genetic diseases with characteristic cellular hypersensitivity to DNA crosslinking agents which suggest that FA proteins may function as part of DNA repair processes. At the clinical level, FA is characterized by bone marrow failure that affects children at an early age. The clinical phenotype is heterogeneous and includes various congenital malformations as well as cancer predisposition. FA patients are distributed into eight complementation groups suggesting a complex molecular pathway. Three of the eight possible FA genes have been cloned, although their function(s) have not been identified. FA cells are highly sensitive to DNA crosslinking agents (mitomycin C (MMC) and diepoxybutane), with some variability between cell lines. Sensitivity to monofunctional alkylating agents has been reported in some cases, although these studies were performed with genetically unclassified FA cells. To further analyse and characterize the newly identified FA complementation groups, we tested their sensitivity to UV radiation, monofunctional and bifunctional alkylating agents and to the X-ray mimetic drug bleomycin. We found that FA complementation groups D to H show increased sensitivity to the X-ray mimetic drug bleomycin. Furthermore, the single known FA-H cell line shows increased sensitivity to ethylethane sulfonate (EMS), methylmethane sulfonate (MMS) in addition to the characteristic sensitivity to crosslinking agents, suggesting a broader spectrum of drug sensitivities in FA cells.     

A yeast DNA repair gene partially complements defective excision repair in mammalian cells.

The RAD10 gene of Saccharomyces cerevisiae is required for nucleotide excision repair of DNA. Expression of RAD10 mRNA and Rad10 protein was demonstrated in Chinese hamster ovary (CHO) cells containing amplified copies of the gene, and RAD10 mRNA was also detected in stable transfectants without gene amplification. Following transfection with the RAD10 gene, three independently isolated excision repair-defective CHO cell lines from the same genetic complementation group (complementation group 2) showed partial complementation of sensitivity to killing by UV radiation and to the DNA cross-linking agent mitomycin C. These results were not observed when RAD10 was introduced into excision repair-defective CHO cell lines from other genetic complementation groups, nor when the yeast RAD3 gene was expressed in cells from genetic complementation group 2. Enhanced UV resistance in cells carrying the RAD10 gene was accompanied by partial reactivation of the plasmid-borne chloramphenicol acetyltransferase (cat) gene following its inactivation by UV radiation. The phenotype of CHO cells from genetic complementation group 2 is also specifically complemented by the human ERCC1 gene, and the ERCC1 and RAD10 genes have similar amino acid sequences. The present experiments therefore indicate that the structural homology between the yeast Rad10 and human Ercc1 polypeptides is reflected at a functional level, and suggest that nucleotide excision repair proteins are conserved in eukaryotes.     

Regulation of DNA repair in serum-stimulated xeroderma pigmentosum cells

The regulation of DNA repair during serum stimulation of quiescent cells was examined in normal human cells, in fibroblasts from three xeroderma pigmentosum complementation groups (A, C, and D), in xeroderma pigmentosum variant cells, and in ataxia telangiectasia cells. The regulation of nucleotide excision repair was examined by exposing cells to ultraviolet irradiation at discrete intervals after cell stimulation. Similarly, base excision repair was quantitated after exposure to methylmethane sulfonate. WI-38 normal human diploid fibroblasts, xeroderma pigmentosum variant cells, as well as ataxia telangiectasia cells enhanced their capacity for both nucleotide excision repair and for base excision repair prior to their enhancement of DNA synthesis. Further, in each cell strain, the base excision repair enzyme uracil DNA glycosylase was increased prior to the induction of DNA polymerase using the identical cells to quantitate each activity. In contrast, each of the three xeroderma complementation groups that were examined failed to increase their capacity for nucleotide excision repair above basal levels at any interval examined. This result was observed using either unscheduled DNA synthesis in the presence of 10 mM hydroxyurea or using repair replication in the absence of hydroxyurea to quantitate DNA repair. However, each of the three complementation groups normally regulated the enhancement of base excision repair after methylmethane sulfonate exposure and each induced the uracil DNA glycosylase prior to DNA synthesis. These results suggest that there may be a relationship between the sensitivity of xeroderma pigmentosum cells from each complementation group to specific DNA damaging agents and their inability to regulate nucleotide excision repair during cell stimulation.     

Complementation analysis of measles virus mutants isolated from persistently infected lymphoblastoid cell lines.

Human lymphoblastoid cell lines persistently infected with measles virus release a heterogeneous population of virions. At least 80% of the infectious particles were temperature sensitive for plaque formation at 39 degrees C. Plaque-purified temperature-sensitive mutants from four persistently infected human lymphoblastoid cell lines were shown to be heterogeneous with respect to efficiency of plating at 31 and 39 degrees C, as well as to antigen and RNA production at 39 degrees C. The heterogeneity was confirmed by complementation analysis in which 21 temperature-sensitive isolates were found to represent at least four of the five previously described complementation groups of measles virus. Two isolates complemented four reference temperature-sensitive mutants. These isolates either represent new complementation groups or are members of the fifth complementation group, group E. The majority of isolates were found to have multiple mutations, and group B mutants (RNA-) predominated. Two temperature-sensitive isolates were able to interfere with production of parental measles virus at both permissive and nonpermissive temperatures.     

The repair of large DNA adducts in mammalian cells.

This paper describes experiments involving the measurement of DNA damage and repair after treatment with 4-nitroquinoline 1-oxide (4NQO) or aflatoxin B1 (AFB1) epoxide in a number of mammalian cell cultures primarily associated with defects in the excision repair of UV-induced DNA damage. The results with transformed derivatives of XP cells belonging to different complementation groups showed that the extent of repair of 4NQO adducts at the N2 or C8 of guanosine did not correlate to the extent of repair reported by others after UV-irradiation. An examination of 4NQO repair in rodent UV-sensitive cell lines from different ERCC groups indicated that again there was little correlation between the extent of 4NQO and UV repair. However, regardless of complementation group those mutants that were defective in the repair of pyrimidine dimers and 6,4-photoproducts did exhibit a reduced ability to repair the 4NQO N2 guanosine adduct, whereas those mutants defective in pyrimidine dimer repair alone were able to repair this lesion as normal. In all of these cell lines there was a normal capacity to repair the 4NQO C8 guanosine adduct. Less extensive experiments involving AFB1 epoxide showed an XPC-transformed cell line was able to repair 40% of lesions after 6 h, whereas only 20% of repair is seen after UV. The rodent mutant V-C4 which belongs to the same ionising radiation group as irs2, was partially defective in repairing AFB1-induced damage. These experiments highlight the fact that although there are many commonalities between the repair of UV damages and lesions classed as large DNA adducts differences clearly exist, the most striking example here being the repair of the C8 guanosine 4NQO adduct which rarely correlates with a defect in UV repair.     

Genetic Mapping Using Microcell-Mediated Chromosome Transfer Suggests a Locus for Nijmegen Breakage Syndrome at Chromosome 8q21-24

Nijmegen breakage syndrome (NBS) is an autosomal recessive disorder characterized by microcephaly, short stature, immunodeficiency, and a high incidence of cancer. Cultured cells from NBS show chromosome instability, an increased sensitivity to radiation-induced cell killing, and an abnormal cell-cycle regulation after irradiation. Hitherto, patients with NBS have been divided into the two complementation groups V1 and V2, on the basis of restoration of radioresistant DNA synthesis, suggesting that each group arises from a different gene. However, the presence of genetic heterogeneity in NBS has been considered to be controversial. To localize the NBS gene, we have performed functional complementation assays using somatic cell fusion between NBS-V1 and NBS-V2 cells, on the basis of hyper-radiosensitivity, and then have performed a genomewide search for the NBS locus, using microcell-mediated chromosome transfer followed by complementation assays based on radiosensitivity. We found that radiation resistance was not restored in the fused NBS-V1 and NBS-V2 cells and that only human chromosome 8 complements the sensitivity to ionizing radiation, in NBS cell lines. In complementation assays performed after the transfer of a reduced chromosome, merely the long arm of chromosome 8 was sufficient for restoring the defect. Our results strongly suggest that NBS is a homogeneous disorder and that the gene for NBS is located at 8q21-24.     

Inactivation of p53 is associated with decreased levels of radiation-induced apoptosis in medulloblastoma cell lines

Radiation is the primary therapeutic modality for children with medulloblastoma, a pediatric brain tumour. We examined the response of four medulloblastoma cell lines to ionising radiation. Our evaluation utilising flow cytometry, morphological analysis and terminal deoxynucleotidyl transferase assays demonstrated that medulloblastoma cells undergo radiation-induced apoptosis. p53 mediates radiation-induced apoptosis in many cell types, and p53 mutations have been associated with increased resistance to ionising radiation. p53 mutations are rare in medulloblastoma. We found that wildtype p53 is required for high levels of apoptosis in medulloblastoma, and cell lines in which p53 had been inactivated by mutation had very low levels of apoptosis. Inactivation of endogenous wildtype p53 in medulloblastoma cells by introduction of a dominant negative mutant of p53 decreased the level of radiation-induced apoptosis. Our results suggest that the sensitivity of medulloblastoma to irradiation involves p53-mediated apoptosis and that p53 gene status may be a predictor of response to radiation therapy.     

Genetic analysis of metabolic cooperation in mammalian cell lines

Metabolites can be exchanged between cells in culture by direct transfer from the cytoplasm of one cell to that of another in a process known as metabolic cooperation. Most mammalian cell lines are able to transfer small molecules directly between adjacent cells in this way and are consequently mec+; however, a small number are defective in this ability (mec-). Results obtained from somatic cell hybrids formed between combinations of these cells have shown that the four different cell lines examined in this study can be divided into at least two different complementation groups on the basis of their ability to transfer 3H-labeled nucleotides to adjacent cells. Two of the cell lines clearly fall into a single complementation group.     

Non-targeted effects of ionising radiation—Implications for low dose risk

Non-DNA targeted effects of ionising radiation, which include genomic instability, and a variety of bystander effects including abscopal effects and bystander mediated adaptive response, have raised concerns about the magnitude of low-dose radiation risk. Genomic instability, bystander effects and adaptive responses are powered by fundamental, but not clearly understood systems that maintain tissue homeostasis. Despite excellent research in this field by various groups, there are still gaps in our understanding of the likely mechanisms associated with non-DNA targeted effects, particularly with respect to systemic (human health) consequences at low and intermediate doses of ionising radiation. Other outstanding questions include links between the different non-targeted responses and the variations in response observed between individuals and cell lines, possibly a function of genetic background. Furthermore, it is still not known what the initial target and early interactions in cells are that give rise to non-targeted responses in neighbouring or descendant cells. This paper provides a commentary on the current state of the field as a result of the non-targeted effects of ionising radiation (NOTE) Integrated Project funded by the European Union. Here we critically examine the evidence for non-targeted effects, discuss apparently contradictory results and consider implications for low-dose radiation health effects.     

Evidence for at least eight Fanconi anemia genes.

Fanconi anemia (FA) is an autosomal recessive chromosomal breakage disorder with diverse clinical symptoms including progressive bone marrow failure and increased cancer risk. FA cells are hypersensitive to crosslinking agents, which has been exploited to assess genetic heterogeneity through complementation analysis. Five complementation groups (FA-A through FA-E) have so far been distinguished among the first 20 FA patients analyzed. Complementation groups in FA are likely to represent distinct disease genes, two of which (FAC and FAA) have been cloned. Following the identification of the first FA-E patient, additional patients were identified whose cell lines complemented groups A-D. To assess their possible assignment to the E group, we introduced selection markers into the original FA-E cell line and analyzed fusion hybrids with three cell lines classified as non-ABCD. All hybrids were complemented for cross-linker sensitivity, indicating nonidentity with group E. We then marked the three non-ABCDE cell lines and examined all possible hybrid combinations for complementation, which indicated that each individual cell line represented a separate complementation group. These results thus define three new groups, FA-F, FA-G, and FA-H, providing evidence for a minimum of eight distinct FA genes.     

Molecular and biochemical characterisation of DNA-dependent protein kinase-defective rodent mutant irs-20.

The catalytic subunit of the DNA-dependent protein kinase (DNA-PKcs) is a member of a sub-family of phosphatidylinositol (PI) 3-kinases termed PIK-related kinases. A distinguishing feature of this sub-family is the presence of a conserved C-terminal region downstream of a PI 3-kinase domain. Mutants defective in DNA-PKcs are sensitive to ionising radiation and are unable to carry out V(D)J recombination. Irs-20 is a DNA-PKcs-defective cell line with milder gamma-ray sensitivity than two previously characterised mutants, V-3 and mouse scid cells. Here we show that the DNA-PKcs protein from irs-20 cells can bind to DNA but is unable to function as a protein kinase. To verify the defect in irs-20 cells and provide insight into the function and expression of DNA-PKcs in double-strand break repair and V(D)J recombination we introduced YACs encoding human and mouse DNA-PKcs into defective mutants and achieved complementation of the defective phenotypes. Furthermore, in irs-20 we identified a mutation in DNA-PKcs that causes substitution of a lysine for a glutamic acid in the fourth residue from the C-terminus. This represents a strong candidate for the inactivating mutation and provides supportive evidence that the extreme C-terminal motif is important for protein kinase activity.