Isolation of UV-sensitive variants of CHO-K1 by nylon cloth replica plating

Cytotoxicity of cigarette smoke condensate is not due to DNA double strand breaks: Comparative studies using radiosensitive mutant and wild-type CHO cells

PURPOSE

To determine whether cigarette smoke condensate (CSC) without metabolic activation induces direct DNA double strand breaks (DSB) in the G1 phase of various radiosensitive mutants of CHO cells and whether these breaks display collateral hypersensitivity to CSC with respect to cell killing.

MATERIALS & METHODS

We treated the G1-phase cultures of wild-type and DNA repair deficient mutants of CHO cells with various concentrations of CSC and examined the cell survival by colony formation assay and the induction of DNA double strand breaks by constant field gel electrophoresis as well as the phophorylated histone H2-A variant X (gamma-H2AX) assay.

RESULTS

Gel analysis and gamma-H2AX focus assay showed significantly fewer, but still detectable levels of DSB per cell after CSC treatment compared to ionizing radiation (IR) exposures, even when equitoxic radiation exposures were delivered at a low dose rate over the same 8-hour exposure used for CSC treatments. None of the three non-homologous end joining (NHEJ) deficient mutants were remarkably hypersensitive to CSC compared to wild-type cells. In contrast, UV-1 cells that are hypersensitive to several base damage and cross-linking agents showed a higher sensitivity to CSC compared to the other CHO cell lines.

CONCLUSIONS

DNA DSB produced directly by CSC are not principally responsible for its cytotoxicity. Further, the present study does not rule out the possibility that some of these lesions may secondarily result in DSB, such as may occur during impeded DNA replication and whose repair may require systems other than NHEJ.

Radiation Research Society. 1952-2002. Historical and current highlights in radiation biology: has anything important been learned by irradiating cells?

Around 30 years ago, a very prominent molecular biologist confidently proclaimed that nothing of fundamental importance has ever been learned by irradiating cells! The poor man obviously did not know about discoveries such as DNA repair, mutagenesis, connections between mutagenesis and carcinogenesis, genomic instability, transposable genetic elements, cell cycle checkpoints, or lines of evidence historically linking the genetic material with nucleic acids, or origins of the subject of oxidative stress in organisms, to name a few things of fundamental importance learned by irradiating cells that were well known even at that time. Early radiation studies were, quite naturally, phenomenological. They led to the realization that radiations could cause pronounced biological effects. This was followed by an accelerating expansion of investigations of the nature of these radiobiological phenomena, the beginnings of studies aimed toward better understanding the underlying mechanisms, and a better appreciation of the far-reaching implications for biology, and for society in general. Areas of principal importance included acute tissue and tumor responses for applications in medicine, whole-body radiation effects in plants and animals, radiation genetics and cytogenetics, mutagenesis, carcinogenesis, cellular radiation responses including cell reproductive death, cell cycle effects and checkpoint responses, underlying molecular targets leading to biological effects, DNA repair, and the genetic control of radiosensitivity. This review summarizes some of the highlights in these areas, and points to numerous examples where indeed, many things of considerable fundamental importance have been learned by irradiating cells.

Phenotype of FAECB (Facility for Automated Experiments in Cell Biology) Chinese hamster ovary mutants with minimal UV-sensitivity

The Facility for Automated Experiments in Cell Biology (FAECB) collection of over 200 lines of ultraviolet (UV)-sensitive mutant Chinese hamster ovary (CHO) cells has previously been studied for complementation group assignment (CG), with representatives of rodent UV CGs 1-6 (ERCC1-6) and the new rodent XRCC9/FANCG group identified. Ten mutants from the collection, including a further six derived from wildtype AA8, three UV-sensitive double-mutants of CHO ERCC1 cell line UV4, and a UV-sensitive mutant of CHO XRCC1 cell line EM9, had not been assigned or characterized in these previous studies. These 10 mutants include 8 with approximately 1.5-fold the UV-sensitivity of the parental line (AA8, EM9, or UV4), and 2 with about 2-fold the UV-sensitivity of AA8. The present study reports the partial characterization of these 10 mutants in terms of sensitivity to UV (with and without caffeine), ionizing radiation, mitomycin C (MMC) and ethyl methanesulfonate (EMS); proficiency in DNA repair (unscheduled DNA synthesis (UDS)); and UV-mutability. The phenotypes of the 10 cell lines were heterogeneous, a number showed reduced UDS or UV-sensitization by caffeine, whilst others showed marked sensitivity to EMS or MMC, and they may have mutations in different genes involved in nucleotide excision repair, post-replicational repair, base excision repair or recombinational repair. Previous mutants isolated as part of the FAECB collection have proved to be extremely important in characterizing mammalian DNA repair processes and cloning human repair genes and these current mutants, whilst not as hypersensitive to UV, may still have the potential to make further contributions.

Chinese hamster cells meet DNA repair: an entirely acceptable affair

This personal account relates the advent of mutant isolation and other developments in somatic cell genetics that were critical steps toward isolating DNA repair mutants in mammalian cells. The isolation of auxotrophic and temperature-sensitive mutants in genetically stable Chinese hamster cell during the late 1960s and early 1970s provided a conceptual framework in which to later isolate mutations conferring hypersensitivity to ultraviolet radiation, ionizing radiation, and various chemical mutagens. Complementation group analysis of ultraviolet-sensitive mutants helped identify multiple genes that overlapped with the groups of cancer-prone xeroderma pigmentosum, as well as Cockayne syndrome. The first mammalian cell mutants defective in strand-break repair were also discovered. Subsequent cloning of human genes that corrected CHO-cell mutations in nucleotide-excision repair groups 1-6 later led to identifying the key enzymes in the incision steps of this pathway, as well as the CSB protein, which is involved in coupling excision repair and transcription.

Expression of human O6-methyl guanine methyl transferase (MGMT) in post replication repair (PRR) deficient CHO-UV-1 cells: compensation for hypersensitivity to methylating and ethylating agents but not to mitomycin C

The cDNA for human MGMT was transfected into and expressed in CHO cells and the post-replication repair deficient mutant CHO-UV-1 cell, both of which are devoid of endogenous MGMT activity. Expression of MGMT activity was demonstrated by measurement of activity and by immunoblot analysis. The mutant phenotype of UV-1 is characterized by extreme hypersensitivity to killing by methylating and ethylating agents as well as the antitumor antibiotic mitomycin C (MMC). MGMT expression conferred equivalent, supra-normal levels of resistance to killing by MNNG (N-methyl-N'-nitro-nitrosoguanidine) or EMS (ethyl methanesulfonate) on CHO and UV-1, but had no effect on the lethality of MMC. So, even though a mutated gene other than MGMT is known to underlie the pleiotropic phenotype of UV-1, expression of MGMT compensates for part of this phenotype. This result indicates that attempts to concordance map and clone the gene(s) responsible for the UV-1 phenotype can be complicated when using MNNG selection due to compensation by the MGMT gene. These results also indicate that the post-replication repair deficient phenotype characterized in CHO-UV-1 cells, will be masked in cells normally expressing MGMT due to MGMT-mediated resistance to methylating and ethylating agents.

Molecular cloning of a mammalian gene involved in the fixation of UV-induced mutations

A mammalian DNA damage tolerance gene has been isolated by DNA transfection and cosmid rescue. Following cotransfection of mouse genomic DNA and pSV2neo into SVM, the UV hypersensitive mutant Indian muntjac cell line, clones with a 1.7 to 2.0-fold greater D37 value for UV killing were isolated. This trait was carried through three rounds of transfection. A neo gene and flanking sequences from a tertiary transfectant were cloned by cosmid rescue. The cosmid clone confers UV resistance to SVM and improves the ability of the cell to replicate UV damaged DNA. This replication appears to be error-prone; UV-induced 6-thioguanine-resistant mutants occur four to fivefold more frequently than in SVM or a wild-type Indian muntjac line. Thus, the gene isolated is not homologous to that defective in SVM. We believe that this is the first mammalian gene to be isolated that is directly involved in mutation fixation.

Relative frequencies of homologous recombination between plasmids introduced into DNA repair-deficient and other mammalian somatic cell lines

Twelve mammalian somatic cell lines, some of them DNA damage-sensitive mutants paired with their respective wild-type parental lines, were assayed for their ability to catalyze extrachromosomal, intermolecular homologous recombination between pSV2neo plasmid recombination substrates. All of the somatic cell lines analyzed are capable of catalyzing homologous recombination; however, there is a wide range of efficiencies with which they do so. Five human cell lines display a fourfold range of recombination frequencies, and six hamster cell lines vary almost 20-fold. Linearizing one of the recombination substrates stimulates recombination in all but one of the cell lines. Two of the three paired mutant cell lines display a threefold reduction in their ability to catalyze homologous recombination when compared to their respective parental cell lines, indicating that the mutations that render them sensitive to DNA damaging agents might also play a role in homologous recombination.

The molecular genetics of the incision step in the DNA excision repair process

This review describes the evolution of research into the genetic basis of how different organisms use the process of excision repair to recognize and remove lesions from their cellular DNA. One particular aspect of excision repair, DNA incision, and how it is controlled at the genetic level in bacteriophage, bacteria, S. cerevisae, D. melanogaster, rodent cells and humans is examined. In phage T4, DNA is incised by a DNA glycosylase-AP endonuclease that is coded for by the denV gene. In E. coli, the products of three genes, uvrA, uvrB and uvrC, are required to form the UVRABC excinuclease that cleaves DNA and releases a fragment 12-13 nucleotides long containing the site of damage. In S. cerevisiae, genes complementing five mutants of the RAD3 epistasis group, rad1, rad2, rad3, rad4 and rad10 have been cloned and analyzed. Rodent cells sensitive to a variety of mutagenic agents and deficient in excision repair are being used in molecular studies to identify and clone human repair genes (e.g. ERCC1) capable of complementing mammalian repair defects. Most studies of the human system, however, have been done with cells isolated from patients suffering from the repair defective, cancer-prone disorder, xeroderma pigmentosum, and these cells are now beginning to be characterized at the molecular level. Studies such as these that provide a greater understanding of the genetic basis of DNA repair should also offer new insights into other cellular processes, including genetic recombination, differentiation, mutagenesis, carcinogenesis and aging.

Phenotypic heterogeneity within the first complementation group of UV-sensitive mutants of Chinese hamster cell lines

A DNA-repair mutant was characterized that has the extraordinary and interesting properties of extreme sensitivity to UV killing combined with a high level of nucleotide excision repair. The mutant V-H1 isolated from the V79 Chinese hamster cell line appeared very stable, with a reversion frequency of about 3.5 X 10(-7). Genetic complementation analysis indicates that V-H1 belongs to the first complementation group of UV-sensitive Chinese hamster ovary (CHO) mutants described by Thompson et al. (1981). This corresponds with data on cross-sensitivity and mutation induction after UV irradiation published by this group. Surprisingly, the mutant V-H1 shows only slightly reduced (to approximately 70%) unscheduled DNA synthesis (UDS) after UV exposure, while the other two mutants of this complementation group are deficient in UDS after UV. In agreement with the high residual UDS, in V-H1 also the amount of repair replication in response to UV treatment is relatively high (approximately 50%). It has also been shown that the incision step of the nucleotide excision pathway takes place in V-H1 (with a lower rate than observed in wild-type cells), whereas another mutant (UV5) of the same complementation group is deficient in incision. This heterogeneity within the first complementation group indicates that the repair gene of this complementation group may have more than one functionally important domain or that the gene is not involved in the incision per se but is involved in e.g. preferential repair of active genes.

Excessive chromosome fragility and abundance of sister-chromatid exchanges induced by UV in an Indian muntjac cell line defective in postreplication (daughter strand) repair

Two UV-hypersensitive animal cell mutants defective in postreplication recovery (daughter strand synthesis) display quite different patterns of induced sister-chromatid exchange (SCE). One, an SV40-transformed Indian muntjac cell (SVM), shows extremely high frequencies of SCE after UV; induced exchanges can be measured after UV doses as low as 0.01 J/m2. This cell also displays exaggerated levels of induced and spontaneous chromosome aberrations. By contrast SCE rates in the Chinese hamster cell mutant, UV-1, are essentially normal. In both SVM and UV-1, however, there is a clear correlation between the cell density and spontaneous frequencies of SCE, a feature which could be related to the observed density-dependent rate of DNA maturation.

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.

Interspecies complementation analysis of xeroderma pigmentosum and UV-sensitive Chinese hamster cells

Complementation analysis was performed 24 h after fusion of UV-sensitive CHO cells (CHO 12 RO) with XP cells of complementation groups A, B, C, D, F and G. The parental cells are characterized by low levels of unscheduled DNA synthesis (UDS). In all combinations, the UDS levels observed in heterokaryons were higher than those in parental mutant cells, clearly indicating cooperation of human and Chinese hamster repair functions. In heterokaryons of CHO 12 RO with XP-A and XP-C cells, the UDS values reached about the normal human level, whereas in heterokaryons with XP-B, XP-D and XP-F, UDS was restored at a level approaching that in wild-type CHO cells. The results obtained after fusion of CHO cells with two representative cell strains from the XP-G group, XP 2 BI and XP 3 BR, were inconsistent. Fusion with XP 3 BR cells yielded UDS levels ranging from wild-type Chinese hamster to normal human, whereas fusion with XP 2 BI cells resulted in a slight increase in UDS which even after 48 h remained below the level found in wild-type CHO cells. The occurrence of complementation in these interspecies heterokaryons indicates that the genetic defect in the CHO 12 RO cells is different from the defects in the XP complementation groups tested.

Different genetic alterations underlie dual hypersensitivity of CHO mutant UV-1 to DNA methylating and cross-linking agents

CHO mutant UV-1, isolated on the basis of hypersensitivity to UV radiation (254 nm), was further characterized with respect to sensitivity to classes of DNA damaging agents in a differential cytotoxicity (DC) assay. Compared to its parental strain, Gly- A, UV-1 was dramatically (10- to 100-fold) hypersensitive to both DNA methylating and cross-linking agents. In addition, UV-1 was moderately (two- to fourfold) hypersensitive to several other classes of mutagens. DNA isolated from UV-1 or Gly- A after exposure to 14C-labeled methylnitrosourea (MNU) contained similar amounts of label, thus ruling out differences in uptake or binding. Three phenotypic revertants of UV-1 were resistant to N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) and other methylating agents but retained hypersensitivity to cross-linking agents. Moreover, fusion of UV-1 with two different UV-sensitive CHO mutants also having hypersensitivity to cross-link and methylation damage produced hybrids resistant to mitomycin C (MMC) but not to methyl methane sulfonate (MMS). Since the methylation and cross-link sensitivities were uncoupled in both genetic tests, the complex phenotype of UV-1 is likely due to more than one genetic alteration.

Isolation of a mutant cell line derived from ICR 2A frog cells hypersensitive to the induction of non-dimer DNA damage by solar ultraviolet radiation

A mutant cell line DRP 36, hypersensitive to nondimer DNA damage induced by exposure of cells to the Mylar-filtered solar ultraviolet (UV) radiation produced by a fluorescent sunlamp plus photoreactivating light (PRL) was isolated from the haploid ICR 2A frog cell line. The DO for mutant cells exposed to this solar UV source was 3.3 kJ/m2 compared with a DO of 7.3 kJ/m2 for the parental ICR 2A cells. In contrast, DRP 36 and ICR 2A cells exhibited similar levels of survival following 254-nm irradiation which causes the induction primarily of pyrimidine dimers. The cross-sensitivity to additional DNA damaging agents was examined, and it was determined that the DRP 36 cells are also hypersensitive to treatment with gamma-rays, ethyl methane sulfonate (EMS), cis-dichlorodiammine platinum (II) (DDP), and 4-nitroquinoline oxide (4-NQO) while exhibiting normal sensitivity to L-phenylalanine mustard (L-PAM), 1,3-bis-(2-chloroethyl)-1-nitrosourea (BCNU) and mitomycin C (MMC).

X-ray-sensitive mutants of Chinese hamster ovary cell line. Isolation and cross-sensitivity to other DNA-damaging agents

A standard technique of microbial genetics, which involves the transfer of cells from single colonies by means of sterile toothpicks, has been adapted to somatic cell genetics. Its use has been demonstrated in the isolation of X-ray-sensitive mutants of CHO cells. 9000 colonies have been tested and 6 appreciably X-ray-sensitive mutants were isolated. (D10 values 5-10-fold of wild-type D10 value.) A further 6 mutants were obtained which showed a slight level of sensitivity (D10 values less than 2-fold of wild-type D10 value). The 6 more sensitive mutants were also sensitive to bleomycin, a chemotherapeutic agent inducing X-ray-like damage. Cross-sensitivity to UV-irradiation and treatment with the alkylating agents, MMS, EMS and MNNG, was investigated for these mutants. Some sensitivity to these other agents was observed, but in all cases it was less severe than the level of sensitivity to X-irradiation. Each mutant showed a different overall response to the spectrum of agents examined and these appear to represent new mutant phenotypes derived from cultured mammalian cell lines. One mutant strain, xrs-7, was cross-sensitive to all the DNA-damaging agents, but was proficient in the repair of single-strand breaks.

Isolation of cell cycle-dependent gamma ray-sensitive Chinese hamster ovary cell

A technique for the isolation of gamma ray-sensitive Chinese hamster ovary (CHO) cell mutants is described, which uses nylon cloth replica plating and photography with dark-field illumination to directly monitor colonies for growth after gamma irradiation. Two gamma ray-sensitive mutants were isolated using this method. One of these cells (XR-1) had a two-slope survival curve: an initial steep slope and then a flattening of the curve at about 10% survival. Subsequently, it was found that this cell is sensitive to gamma irradiation in G1, early S, and late G2 phases of the cell cycle, whereas in the resistant phase (late S phase) its survival approaches that of the parental cells. The D37 in the sensitive G1 period is approximately 30 rads, compared with 300 rads of the parental cell. This mutant cell is also sensitive to killing by the DNA breaking agent, bleomycin, but is relatively insensitive to UV light and ethyl methane sulfonate, suggesting that the defect is specific for agents that produce DNA strand breakage.

Radiation-induced lethality and mutation in a repair-deficient CHO cell line

A U.V.-sensitive, DNA repair-deficient mutant of Chinese hamster ovary cells was tested for its response to the lethal effects of X-irradiation and simulated solar light, and to the mutagenic actions of X-rays. A slight sensitivity to killing by X-rays and a greater sensitivity to solar light was observed relative to the wild-type CHO cells. More mutations were induced at a given dose of X-rays in the sensitive cell line than in the wild-type. These results are interpreted in terms of overlap in the repair processes which take place after U.V. damage in mammalian cells with those that take place after other types of radiation damage.

Characteristics of gamma-ray-induced chromosomal aberrations in mutagen-sensitive mutants of L5178Y cells

We have examined the chromosomal radiosensitivities of an ionizing-radiation-and MMS-sensitive mutant (M10), and a UV- and 4NQO-sensitive mutant (Q31), isolated from mouse lymphoma L5178Y cells, with regard to killing effects. In the first mitoses after 100 R gamma-irradiations, it was found that M10 cells were highly radiosensitive in terms of chromosomal aberrations accompanying longer mitotic delay (3 h); the frequencies of both chromatid-type and chromosome-type aberrations were, respectively, about 7 and 4 times higher than that of wild-type L5178Y cells. Furthermore, chromatid exchanges, particularly triradials, isochromatid breaks with sister union, and chromatid gaps and breaks were markedly enhanced at G1 phase of M10 cells. In contrast, the chromosomal radiosensitivity of Q31 cells after 100 R irradiation was similar to that of L5178Y cells. On the other hand, spontaneous aberration frequencies (overall breaks per cell) of M10 and Q31 cells were, respectively, 5.1 and 2.2 times higher than that of wild-type L5178Y cells. The chromosomal hypersensitivity to gamma-rays in M10 cells is discussed in the light of knowledge obtained from ataxia telangiectasia cells.

Isolation of Chinese hamster ovary cells with reduced unscheduled DNA synthesis after UV irradiation

A simple procedure has been worked out to obtain UV-sensitive mutants of Chinese hamster ovary (CHO) cells. In this procedure, conventional mutagenesis is followed by BrdU--light treatment to enrich the population for UV-sensitive cells. Colonies that are allowed to form subsequently are duplicated by replica plating and screened on the master plate for their UV sensitivity and their capacity to carry out UV-induced DNA repair synthesis. Putative mutants are isolated from the replica. With this combination of methods, we succeeded in isolating CHO mutants with an 85-95% reduced level of UV-induced DNA synthesis in combination with an increased UV sensitivity.

Repair capability and the cellular age response for killing and mutation induction after UV

The cell-cycle response for killing and mutation induction by ultraviolet irradiation was measured in synchronous Chinese hamster ovary cells (CHO wild-type) and in a UV-hypersensitive mutant (43-3B) derived from this line. The CHO 43-3B line shows a greatly enhanced sensitivity to killing (D0 of 0.3 as compared to 3.2 J/m2 for the wild-type), is hypermutable, and deficient in DNA repair. For the wild-type, a characteristic age response is seen for killing by UV, with maximum sensitivity in early-S and resistance increasing through the S-phase. There is also a life-cycle specificity for induction of diphtheria-toxin resistance in late-G1 and early-S. Relatively little variation is seen through the cell cycle for induced 6-thioguanine and ouabain resistance. In contrast, the 43-3B cell line shows a relatively 'flat' response to UV throughout the cell cycle, for both killing and mutation induction. Therefore it appears that the characteristic age responses seen in the wild-type CHO are associated with the function of an essentially error-free repair process. A variation in the ability of this repair process to act in eliminating potentially lethal and mutagenic lesions (either due to a variation in repair enzyme activities through the cell cycle, or in the time available for repair) would account for most of the age response which is seen in the wild-type for killing and mutation induction by ultraviolet light.

Isolation of UV-sensitive mutants of mouse L5178Y cells by a cell suspension spotting method

We have isolated 56 UV-sensitive mutant clones from a mouse L51 T/t line of L5178Y cells by a cell suspension spotting method. Five mutants have also been isolated from L51 T/t and L5178Y cells by the method reported by Thompson and coworkers (22). We divided the mutants into two groups, "highly sensitive" and "moderately sensitive" mutants, according to their sensitivity to UV irradiation. Fifty-eight mutants were highly sensitive and three were moderately sensitive to UV. The reconstruction experiments indicate that more than 90% of highly sensitive mutants were recovered by the cell suspension spotting method. Frequencies of recovered mutants highly sensitive to UV increased with increasing dose of mutagens. Recovered mutant frequency reached 10(-2) after treatment with 1.5 micrograms/ml of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) (survival 0.2%). Eight UV-sensitive mutants were divided into four complementation groups. These mutants were 2-6 times more sensitive to UV than parental L51 T/t cells in terms of D37 (dose required to reduce survival to 37%). Four representative UV-sensitive mutants which are classified into different complementation groups were examined for their sensitivity to killing by UV, 4-nitroquinoline-1-oxide (4NQO), mitomycin C (MMC), X-rays, and MNNG. All four classes of mutants were found to be cross-sensitive to UV, 4NQO, and MMC, but not sensitive to X-rays and MNNG.

DNA repair in a UV-sensitive mutant of a mouse cell line

A UV-sensitive mutant, Q31, isolated from mouse-lymphoma L5178Y cells, was studied for excision and post-replication repairs. A nearly equal number of UV endonuclease-sensitive sites was induced by UV in L5178Y, Q31, and human Raji cells. L5178Y cells irradiated with 10 J/m2 removed 18% of sensitive sites from DNA of detection, whereas Raji cells eliminated about 60% of the sites. These results during incubation for 24 h, and Q31 cells removed 3% of the sites, a fraction less than the limit indicate that mouse-lymphoma cells are capable of excision repair to a limited extend as compared with human cells and that mutant Q31 cells are essentially devoid of dimer excision. The newly synthesized DNA was of smaller size in UV-irradiated and unirradiated Q31 cells than that in the corresponding L5178Y cells, but the DNAs in both cell strains increased to comparable sizes after a 2-h chase.

Chinese hamster ovary mutant UV-1 is hypomutable and defective in a postreplication recovery process

CHO-UV-1 is a mutant of the Chinese hamster cell CHO-K1 hypersensitive to killing by ultraviolet light but with normal resistance to X-ray. It is also hypersensitive to killing by ethyl methane sulfonate. Hybrid clones formed bu fusing UV-1 and Chinese hamster lung cells display the normal ultraviolet resistance of the latter. The sensitive phenotype behaves, therefore, in a genetically recessive manner. Ultraviolet sensitivity of UV-1 is not associated with a deficiency in excision repair. Alkaline sucrose gradient sedimentation analysis of nascent DNA from ultraviolet-irradiated cells reveals that UV-1 is, however, markedly deficient in postreplication recovery. Furthermore, UV-1 has a lower rate of induced mutation to 6-thioguanine resistance than does the parental cell when treated with ultraviolet light or ethyl methane sulfonate. These results suggest that the phenotype of UV-1 is due to a mutation in a form of postreplication recovery which in normal cells is error prone.

Replica plating of cultured mammalian cells

A simple device is described which permits the replica plating of lymphocytes as well as substrate adherent fibroblasts. The replica plating device consists of an 8 X 12 array of cotton-tipped swabs (Q-tips). The principle of the replica plating system involves the use of an array of absorbent cotton-tipped swabs to transfer nonadherent lymphocytes (or conditioned medium) to corresponding wells of 96-well microtiter plates. Replica plating of substrate adherent cells requires one additional step; i.e., dislodgement of adherent cells by rotating the cotton-tipped swabs against the culture surface of each well. Once adherent cells are dislodged, replica plating of adherent cells can be carried out in an identical fashion to the replica plating of nonadherent lymphocytes. Application of the Q-tip replicator in the isolation of monoclonal antibody secreting hybridomas is also presented.

Isolation and partial characterization of mutagen-sensitive and DNA repair mutants of Chinese hamster fibroblasts

Through a new approach, we have sought to isolate ultraviolet light (UV)-sensitive and DNA repair mutant Chinese hamster fibroblasts. The procedure consisted of 1) mutation induction by 5-bromodeoxyuridine (Brd U)-blacklight and UV treatments; 2) incorporation of 3H-thymidine in repair-proficient cells at high temperature (38.5 degrees C) following UV damage; 3) cold holding (4.0 degrees C) of these cells to induce tritium killing; and 4) recovery and testing of repair-deficient and UV-sensitive cells which have survived and formed colonies at low temperature (34.0 degrees C). In our initial attempt at this protocol, we isolated 72 surviving colonies from 2 x 10(7) cells plated for selection. Of the 72 colonies, 20 demonstrated potential interest and four were selected for extensive study. One, identified as UVs-7, is slightly more sensitive to UV, but not sensitive to X rays or N-acetoxy-2-acetylaminofluorene (NAc-AAF). The mutant exhibits a highly reduced level of unscheduled DNA synthesis (UDS), as compared to the parental line. Two additional lines, UVs-40 UVs-44, are sensitive to UV, X ray, N-methyl-N-nitro-N-nitrosoguanidine (MNNG), and NAc-AAF, but exhibit normal UDS. A fourth line, UVr-23, has enhanced UDS, is resistant to UV, but exhibits no difference in sensitivity to x ray or NAc-AAf. These mutants are all stable, and should be useful for the study of mammalians DNA repair processes and mechanisms of mutagenesis.

Large-scale isolation of UV-sensitive clones of CHO cells

We have isolated 54 ultraviolet light (UV) sensitive clones of Chinese hamster ovary (CHO) cells, including two from a parent cell line which is hypersensitive to ethyl methanesulfonate (EMS) and is also sensitive to X rays. A replica plating technique was used for the isolation of two of the clones, and a semiautomated technique was used for the isolation of the other 52 clones. We have observed UV sensitization of up to 5-fold in the mutants relative to the parent in terms of the slopes of the survival curves. Seven of the clones were examined for DNA repair competence using a repair replication assay, and all exhibited a DNA repair defect resembling that seen in human mutant xeroderma pigmentosum cells. We have also demonstrated an approximately 9-fold enhancement in the UV mutagenic response of two of the repair replication-defective clones relative to the parent for resistance to ouabain, 6-thioguanine, and 8-azaadenine.

A screening method for isolating DNA repair-deficient mutants of CHO cells

A simple procedure for isolating mutagen-sensitive clones of CHO cells was developed and applied in mutant hunts in which colonies were screened for hypersensitivity to killing by ultraviolet radiation (UV, ethyl methanesulfonate (EMS), or mitomycin C (MMC). Each of two UV-sensitive clones studied in detail had a D37 dose of 1.0 J/m2 compared to 7.0 J/m2 for the wild-type cells, and each was shown to have no detectable repair replication following exposure to UV doses of up to 26 J/m2. Although these mutants resemble xeroderma pigmentosum human mutants with respect to their repair defect and cross-sensitivity to the carcinogen 4-nitroquinoline-1-oxide, one of two clones (UV-20) is characterized by extreme hypersensitivity to MMC (80-fold as compared to the wild type). Clones having hypersensitivity to alkylating agents, but not UV, were obtained using MMC and EMS. In the latter case the two clones had significantly increased sensitivity to the killing action of 60Co gamma-rays.

Mutation induction in a radiation-sensitive variant of mammalian cells

Ultraviolet light (UV)-induced mutations were compared between a UV-sensitive variant and its parental mouse lymphoma cell line. The variant was originally isolated for its sensitivity to 4-nitro-quinoline-1-oxide by employing a replica plating method and proved to be sensitive to the killing by UV as well. Caffeine potentiation of UV killing was observed to a similar extent in the variant and the parental cells, indicating that the caffeine-insensitive process is responsible for UV sensitivity in the variant. The induced mutation frequency as determined by resistance to 6-thioguanine was higher in the variant than in the parental cells per unit dose of UV as well as at the comparable survival level.

Ultraviolet light induction of diphtheria toxin-resistant mutations in normal and DNA repair-deficient human and Chinese hamster fibroblasts

The role of unrepaired DNA lesions in the production of mutations is suspected of contributing to the initiation phase of carcinogenesis. Since the molecular basis of mutagenesis is not understood in eukaryotic cells, development of new genetic markers for quantitative in vitro measurement of mutations for mammalian cells is needed. Furthermore, mammalian cells, genetically deficient for various DNA repair enzymes, will be needed to study the role of unrepaired DNA lesions in mutagenesis. The results in this report relate to preliminary attempts (1) to characterize the diphtheria toxin resistance marker as a useful quantitative genetic marker in human cells and (2) to isolate and characterize various DNA repair-deficient Chinese hamster cells.

Isolation of UV-sensitive variants of human FL cells by a viral suicide method

A new method (viral suicide method) for the isolation of UV-sensitive mutants is described. Colonies of mutagenized human FL cells were infected with UV-irradiated Herpes simplex viruses and surviving ones which seemed to be deficient in host cell reactivation (HCR) were examined for their UV sensitivity. Nineteen of 238 clones examined were sensitive to UV irradiation at the time of the isolation. After recloning, four of these clones have been studied and two (UVS-1 and UVS-2) of them are stable in their UV sensitivity for 4 months in culture. UV sensitivity of UVS-1, UVS-2, and the parental FL cells are as follows: the extrapolation numbers (n) are 2.2, 2.1, and 1.8 and mean lethal doses (D0) are 2.9, 3.7, and 7.8 J/m2 for UVS-1, UVS-2, and the parental FL cells, respectively- They are no more sensitive than FL cells to X-irradiation. The ability of HCR in UVS-2 cells is apparently lower than that in FL cells, whereas UVS-1 cells are the same as FL cells in the ability.

Isolation of UV-sensitive clones from a haploid frog cell line

An isolation procedure has been developed which yielded five clones of haploid frog cells which are sensitive to ultraviolet light. This procedure employed a conventional mutagenesis, followed by time for phenotypic expression and then an enrichment for UV-sensitive mutants. The enrichment relies upon the uptake of bromodeoxyuridine (BrdU) by repairing cells following UV-induced damage, rendering repair-proficient cells differentially sensitive to photolysis by black light. The photolysis is potentiated by use of the bisbenzimidazole dye Hoechst 33258. The enriched population was screened for radiation-sensitive isolates resulting in 5 sensitives from 96 tested. No mutants were obtained from 300 isolates tested from a population which had not undergone enrichment.