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.

A stop codon in xeroderma pigmentosum group C families in Turkey and Italy: molecular genetic evidence for a common ancestor.

Xeroderma pigmentosum family G from Van, Turkey had two severely affected children: a son with multiple skin cancers who died at age 10 (XP67TMA), and an 8 y old daughter who began developing skin cancer before 3 y of age (XP68TMA). XP67TMA and XP68TMA cells were hypersensitive to killing by ultraviolet and the post-ultraviolet DNA repair level was 12-16% of normal. Host cell reactivation of an ultraviolet-treated reporter plasmid cotransfected with a vector expressing wild-type XPC cDNA assigned XP67TMA to xeroderma pigmentosum complementation group C. The XPC mRNA level was markedly reduced. Sequencing of the 3.5 kb XPC cDNA from XP67TMA showed a C-T mutation in XPC exon 8 at base pair 1840. This mutation converts the CGA codon of arginine at amino acid 579 to a UGA stop codon resulting in marked truncation of the 940 amino acid xeroderma pigmentosum C protein. Restriction fragment length polymorphism analysis of XPC exon 8 DNA in XP67TMA and XP68TMA showed that both affected children had a homozygous mutation and that both parents had heterozygous normal and mutated sequences at the same position consistent with a history of consanguinity in the family. The mutated allele also contained two XPC single nucleotide polymorphisms. The same mutated XPC allele was reported in an Italian family. Studies of 19 microsatellite markers flanking the XPC gene on chromosome 3 suggest that the XPC allele passed between Italy and Turkey approximately 300-500 y ago. This XPC allele containing a nonsense mutation is associated with severe clinical disease with multiple skin cancers and early death.

Clinical, cellular, and molecular features of an Israeli xeroderma pigmentosum family with a frameshift mutation in the XPC gene: sun protection prolongs life.

An Ashkenazi Jewish Israeli family with two children affected with severe xeroderma pigmentosum was investigated. A son, XP12TA, developed skin cancer at 2 y and died at 10 y. A daughter, XP25TA, now 24 y old, was sun protected and began developing skin cancers at 10 y. Their cultured skin fibroblasts showed reductions in post-ultraviolet survival (11% of normal), unscheduled DNA synthesis (10% of normal), global genome DNA repair (15% of normal), and plasmid host cell reactivation (5% of normal). Transcription-coupled DNA repair was normal, however. Northern blot analysis revealed greatly reduced xeroderma pigmentosum complementation group C mRNA. A plasmid host cell reactivation assay assigned the cells to xeroderma pigmentosum complementation group C. Cells from both parents and an unaffected child exhibited normal post-ultraviolet-C survival and normal DNA repair. Sequencing the xeroderma pigmentosum complementation group C cDNA of XP12TA and XP25TA revealed a homozygous deletion of two bases (del AT 669-670) in exon 5 with a new termination site 10 codons downstream that is expected to encode a truncated xeroderma pigmentosum complementation group C protein. Sequence analysis of the xeroderma pigmentosum complementation group C cDNA in cells from the parents found identical heterozygous mutations: one allele carries both the exon 5 frameshift and an exon 15 polymorphism and the other allele carries neither alteration. Cells from the unaffected brother had two normal xeroderma pigmentosum complementation group C alleles. This frameshift mutation in the xeroderma pigmentosum complementation group C gene led to reduced DNA repair with multiple skin cancers and early death. Sun protection delayed the onset of skin cancer and prolonged life in a sibling with the same mutation.

Manitoba aboriginal kindred with original cerebro-oculo- facio-skeletal syndrome has a mutation in the Cockayne syndrome group B (CSB) gene.

Cerebro-oculo-facio-skeletal (COFS) syndrome is a rapidly progressive neurological disorder leading to brain atrophy with calcification, cataracts, microcornea, optic atrophy, progressive joint contractures, and growth failure. Cockayne syndrome (CS) is a recessively inherited neurodegenerative disorder characterized by low-to-normal birth weight; growth failure; brain dysmyelination with calcium deposits; cutaneous photosensitivity; pigmentary retinopathy, cataracts, or both; and sensorineural hearing loss. CS cells are hypersensitive to UV radiation because of impaired nucleotide excision repair of UV radiation-induced damage in actively transcribed DNA. The abnormalities in CS are associated with mutations in the CSA or CSB genes. In this report, we present evidence that two probands related to the Manitoba Aboriginal population group within which COFS syndrome was originally reported have cellular phenotypes indistinguishable from those in CS cells. The identical mutation was detected in the CSB gene from both children with COFS syndrome and in both parents of one of the patients. This mutation was also detected in three other patients with COFS syndrome from the Manitoba Aboriginal population group. These results suggest that CS and COFS syndrome share a common pathogenesis.

Increased ultraviolet sensitivity and chromosomal instability related to P53 function in the xeroderma pigmentosum variant.

The xeroderma pigmentosum (XP) variant (XPV) is a form of XP that has normal excision repair but shows defective DNA replication after UV irradiation. In developing various transformed fibroblast cell lines from these patients, we have found that there are significant phenotypic changes in transformed cells that seem to correlate with inactivation of p53. After transformation with SV40, XPV cell lines are only slightly UV sensitive, like their primary counterparts, but their sensitization with caffeine and the induction of sister chromatid exchanges (SCEs) by UV irradiation are greatly enhanced. After transformation by HPV16 E7, which targets the retinoblastoma cell cycle regulatory gene, there is no change in the UV sensitivity of XPV cells; but, when transformed by HPV16 E6 or E6 and E7 combined, there is a large increase in UV sensitivity and in the induction of SCEs. These changes are not associated with any detectable changes in the reactivation of an externally irradiated luciferase expression vector, the excision of cyclobutane pyrimidine dimers from bulk DNA, or unscheduled DNA synthesis and, therefore, do not involve excision repair. We suggest that if SCEs represent homologous recombination between sister chromatids, then in the absence of p53 function, the DNA chain arrest typical of UV-damaged XPV cells initiates strand exchange during recovery. In untransformed cells with normal p53, the preferred mode of recovery would then be replication bypass. The symptoms of elevated solar carcinogenesis in XPV patients may, therefore, be associated with increased genomic instability in cells of the skin in which p53 is inactivated by UV-induced mutations.

The human XRCC9 gene corrects chromosomal instability and mutagen sensitivities in CHO UV40 cells.

The Chinese hamster ovary (CHO) mutant UV40 cell line is hypersensitive to UV and ionizing radiation, simple alkylating agents, and DNA cross-linking agents. The mutant cells also have a high level of spontaneous chromosomal aberrations and 3-fold elevated sister chromatid exchange. We cloned and sequenced a human cDNA, designated XRCC9, that partially corrected the hypersensitivity of UV40 to mitomycin C, cisplatin, ethyl methanesulfonate, UV, and gamma-radiation. The spontaneous chromosomal aberrations in XRCC9 cDNA transformants were almost fully corrected whereas sister chromatid exchanges were unchanged. The XRCC9 genomic sequence was cloned and mapped to chromosome 9p13. The translated XRCC9 sequence of 622 amino acids has no similarity with known proteins. The 2.5-kb XRCC9 mRNA seen in the parental cells was undetectable in UV40 cells. The mRNA levels in testis were up to 10-fold higher compared with other human tissues and up to 100-fold higher compared with other baboon tissues. XRCC9 is a candidate tumor suppressor gene that might operate in a postreplication repair or a cell cycle checkpoint function.

Phenotypic heterogeneity in nucleotide excision repair mutants of rodent complementation groups 1 and 4.

Rodent ultraviolet light (UV)-sensitive mutant cells in complementation groups (CGs) 1 and 4 normally are known for their extraordinary (approximately 80-100 x) sensitivity to mitomycin C (MMC), although some CG1 mutants with reduced MMC sensitivity were previously reported (Stefanini et al. (1987) Cytotechnology 1, 91). We report here new CG1 and CG4 mutants with only 1.6-10 x wild-type MMC sensitivity despite low unscheduled DNA synthesis (UDS) levels. Mutant UV140, in UV CG4, has approximately 3.8 x the UV sensitivity of parental line AA8, approximately 1.6 x wild-type MMC sensitivity, wild-type X-ray and ethyl methanesulfonate (EMS) sensitivity, and is only slightly (approximately 1.4 x) hypermutable to 8-azaadenine resistance by UV light. It has moderately decreased incision of UV-damaged DNA, has moderately decreased removal of (6-4) photoproducts, and is profoundly deficient in UDS after UV. After UV, it shows abnormally decreased DNA synthesis and persistently decreased RNA synthesis. In addition a cell-free extract of this mutant displays strongly reduced nucleotide excision repair synthesis using DNA treated with N-acetoxy-acetyl-amino-fluorene (AAF). The extract selectively fails to complement extracts of group 1 and 4 mutants consistent with the notion that the affected proteins, ERCC1 and ERCC4, are part of the same complex and that mutations in one subunit also affect the other component. Mutant UV212 is a CG1 mutant with approximately 3.3 x wild-type UV and approximately 5-10 x wild-type MMC sensitivity, with profoundly deficient UDS and hypermutability (approximately 5.8 x) by UV. Mutant UV201, probably in CG1, is only slightly (approximately 1.5 x) UV-sensitive and has near wild-type (1.02X) UV mutability. These unusual group 1 and 4 mutants demonstrate that the unique UV and MMC sensitivity phenotypes displayed by these groups can be separated and support the idea that they are the result of distinct repair functions of the corresponding ERCC1 and ERCC4 genes: nucleotide excision repair for UV lesions and a separate repair pathway for removal of interstrand crosslinks.

A CHO mutant, UV40, that is sensitive to diverse mutagens and represents a new complementation group of mitomycin C sensitivity.

A new mitomycin C (MMC)-sensitive rodent line, UV40, has been identified in the collection of ultraviolet light- (UV-) sensitive mutants of Chinese hamster ovary (CHO) cells isolated at the previous Facility for Automated Experiments in Cell Biology (FAECB). It was isolated from an UV mutant hunt using mutagenesis of AA8 cells with the DNA intercalating frameshift mutagen ICR170. It is complemented by CHO-UV-1, irsl, irs3, irslSF, MC5, V-C8 and V-H4 with respect to its MMC sensitivity based on cell survival. Despite having approx. 4 X normal UV sensitivity and increased sensitivity to UV inhibition of DNA replication, it has near-normal incision kinetics of UV irradiated DNA, and normal (6-4) photoproducts removal. It also is not hypermutable by UV, and shows near normal levels of UV inhibition of RNA synthesis. UV40 also has approx. 11 x .10 x .5 x and 2 x AA8 sensitivity to MMC, ethyl methanesulfonate (EMS), methyl methanesulfonate (MMS), and X-rays, respectively. Thus, its defect apparently does not involve nucleotide excision repair but rather another process, possibly in replicating past lesions. The spontaneous chromosomal aberration frequency is elevated to 20% in UV40, and the baseline frequency of sister chromatid exchange is also approximately 4-fold increased. The phenotype of UV40 appears to differ from all other rodent mutants that have so far been described.

Radiation and chemotherapy injury: pathophysiology, diagnosis, and treatment.

The text in general is not meant to represent the participants' entire presentations. The lecture presenters in general are not responsible for the summaries, and cannot necessarily be assumed to agree with all that is stated, but they deserve credit for providing the lecture and handout material on which the summaries are based, and in most cases have contributed far more to the summaries than I have.

Recontacting subjects in mutagen-exposure-monitoring studies: II. Results of a questionnaire study of mutagenesis researchers, with review of the pertinent literature.

A questionnaire on the attitudes of mutagenesis researchers regarding the health significance of and the use of data from tests of human mutagen exposure or genetic damage was completed by 71 of 312 (23%) individuals who had been participants in meetings or organizations concerned with mutagenesis research. On a point scale of 0 to 10, with 0 indicating strong disagreement, 5 indicating uncertainty, and 10 indicating strong agreement, the average respondent felt (8.31 +/- 2.27) that data indicating a probable health hazard should be shared automatically with the subjects, but was also moderately concerned about psychological distress of subjects learning of study results indicating abnormally high mutagen exposure (6.14 +/- 2.57) or genetic damage (6.94 +/- 2.48). The average respondent felt that follow-up of subjects could improve the quality of mutagen-exposure-monitoring studies (8.33 +/- 1.49), disagreed that subjects whose laboratory data suggested unusually severe exposure or damage should not be asked about possible sources of exposure (1.15 +/- 1.32), and disagreed that it was ethical to follow up but not discuss results with subjects having laboratory evidence of abnormal mutagen exposure (3.78 +/- 3.43) or genetic damage (3.06 +/- 3.17) to see how many developed cancer relative to a control group. Fifteen specific tests for measuring mutagen exposure or genetic damage were rated on a scale of 0 to 10, with 0 being "totally experimental" and 10 being "absolutely diagnostic of degree of exposure or genetic damage." Values ranged from 6.13 +/- 2.67 for karyotyping leukocytes to 3.43 +/- 2.43 for quantifying frequency of rare red cells with mutant protein. This study may help in decision making regarding follow-up of mutagen-exposed subjects.

Drowning of a Friedreich's ataxia patient.

We here report an unusual, apparently accidental death, in which weakness associated with a progressive neuromuscular disease, Friedreich's ataxia, apparently resulted in the drowning of the deceased. The possibility of neuromuscular disease as a rare cause of drownings should not be overlooked.

Recent progress with the DNA repair mutants of Chinese hamster ovary cells.

Repair-deficient mutants of Chinese hamster ovary (CHO) cells are being used to identify human genes that correct the repair defects and to study mechanisms of DNA repair and mutagenesis. Five independent tertiary DNA transformants were obtained from the EM9 mutant, which is noted for its very high sister-chromatid exchange frequencies. In these clones a human DNA sequence was identified that correlated with the resistance of the cells to chlorodeoxyuridine (CldUrd). After EcoRI digestion, Southern transfer, and hybridization of transformant DNAs with the BLUR-8 Alu family sequence, a common fragment of 25-30 kilobases (kb) was present. Since the DNA molecules used to produce these transformants were sheared to less than 50 kb in size, the correcting gene should be small enough to clone in a cosmid vector. Using drug-resistance markers to select for hybrids after fusion, we have done complementation experiments with ultraviolet light (u.v.)-sensitive mutants and have identified a sixth complementation group, line UV61. Additionally, CHO mutants UV27-1 and MMC-2, isolated in other laboratories, were found to belong to UV group 3, which is represented by line UV24. To study the behaviour of transfected DNA molecules in repair-deficient cells, we treated plasmid pSV2gpt with either u.v. radiation or cis-diamminedichloroplatinum(II) (cis-DDP) and introduced the damaged DNA into normal CHO cells (AA8) and mutants UV4 and UV5. Unrepaired damage to the plasmid was indicated by loss of colony-forming ability of the transfected cells in selective medium containing mycophenolic acid. With u.v. damage, the differential survival of the cell lines was similar to that seen when whole cells are treated with u.v. However, with cis-DDP damage, mutant UV4 did not exhibit the extreme hypersensitivity (50-fold) that occurs when cells are treated. This result suggests that UV4 cells may be able to repair cross-links in transfected DNA.

Presence and measurement of sample histidine in the Ames test: quantification and possible elimination of a source of false-positive mutagenicity test results.

Both histidine and dipeptides that can be converted to histidine can potentially interfere with the Ames test by increasing the number of spontaneous revertants. Such interference might be especially evident when urine and other biological samples are studied in this assay. We have developed a turbidimetric bioassay that utilizes a nonrevertible Salmonella typhimurium histidine auxotroph, NS1135. The assay is linear with histidine over at least a 300-fold range (0.015-5 micrograms/ml of L-histidine.HCl.H2O). Data indicate that several histidine-containing dipeptides can be utilized as efficiently as free histidine. Our data suggest that this assay may be used to measure biological samples accurately for their histidine content and thereby permit an adjustment for sample histidine during the setup of Ames assays, thus eliminating increased reversion caused by sample histidine.

Rectal foreign bodies: case reports and a comprehensive review of the world's literature.

The surgical management of two patients presenting with incarcerated, apparently self-inserted foreign bodies is reported. The large volume of prior literature on this subject is reviewed, with tabulation of 182 previous cases by type and number of objects recovered and with a discussion of patients' age distribution, history, complications, and prognosis. Management problems addressed include history, differential diagnosis of reported pruritus ani, and handling of suspected assault. The variety of surgical techniques used to remove rectal foreign bodies transanally or after celiotomy is discussed. Vaginal foreign bodies and large bowel injuries due to fist fornication, colorectal instrumentation, pneumatic rupture, foreign body ingestion, impalement, and abdominal trauma are also discussed.

Urine recovery experiments with quercetin and other mutagens using the Ames test.

Recovery from urine of the mutagenic activity of 2-anthramine, cyclophosphamide, 7,12-dimethylbenz[a]anthracene, 6-chloro-9-((3-(2-chloroethylamino)-propyl)amino)-2-methoxyacridin e dihydrochloride (ICR-191), mitomycin-C, nitrofurantoin, and quercetin was studied with several of the Ames tester strains using acetone-extracted XAD-2 columns with yields ranging from 27% to 79%. Dose responses of the pure chemicals were also studied, and results showed TA 97 to be far more susceptible to quercetin mutagenesis than TA 1537. Reducing pour plate agar volume enhanced mutagenesis.

A protocol for the combined biochemical and serological identification of the Ames mutagen tester strains as Salmonella typhimurium.

Previously published reports have noted biochemical reactions atypical of Salmonella among the Ames tester strains of Salmonella typhimurium, and an inability to assign the strains to a specific Salmonella O (heat-stable cell wall) antigen group. We studied the biochemistry and serology of strains TA97, 98, 100, 102, 104, 1535, 1537, and 1538 in an attempt to develop a protocol to correctly speciate the strains. Biochemical reactions of all eight strains using standard media supplemented with histidine and biotin were consistent with those of the genus Salmonella. Strains TA100, 104, and 1535 were assigned to Salmonella O groups using bacteria treated with hot ethanol (White schema). H (flagellar) antigen assignments were performed successfully with seven of the eight strains. Two H antigen assignments required the use of the Craigie tube test for selection of motile revertants. Combining our biochemical and serological results obtained by this protocol, we were able to correctly speciate TA100, 104, and 1535 as Salmonella typhimurium. Our results demonstrate that representatives of the tester strains can be correctly speciated provided that procedures are followed that allow for the unusual nutrient requirements, the deep rough cell wall mutation, and the variably deficient motility of these organisms.

Genetic diversity of UV-sensitive DNA repair mutants of Chinese hamster ovary cells.

Mutant lines of Chinese hamster ovary cells that show hypersensitivity to killing and mutagenesis by UV light were analyzed by genetic complementation analysis to determine whether defects in different gene loci might underlie a common cellular phenotype,. To facilitate rapid screening of mutant clones, a procedure was devised that allowed presumptive complementation to be assessed on the basis of the frequency of UV-resistant cells after fusion by polyethylene glycol. Four classes were identified among 44 clones tested. By using drug-resistance markers for selection of hybrid cells in crosses between UV mutant and wild type, a mutant from each of the four classes was shown to behave as phenotypically recessive. Hybrids were also isolated from crosses between each of the pair combinations of the four mutants. All such hybrids were relatively resistant to UV killing, providing confirmation of the complementation classes. When mutants representing the four UV-complementation classes were tested with the polyaromatic hydrocarbon 7-bromomethylbenz(a)anthracene, complementation was again seen for all pair combinations. These results suggest that each class of mutants represents a biochemical defect that plays a common role in the repair of both UV-induced and chemically induced lesions in the DNA.

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.