Point mutations at the thymidine kinase locus in L5178Y mouse lymphoma cells: I. Application to genetic toxicological testing

We have systematically evaluated the mouse lymphoma TK^+/- → TK^-/- mutagenesis assay to determine if this somatic-cell test system would be a useful addition to the routine screening battery already used in our laboratory for the detection of chemical mutagens. During these investigations we observe that, with certain modifications of the basic assay, mutagenicity data could be obtained in as little as 9 days once the relative cytotoxic properties of the test substance were known. By improving the culturing conditions, we were able to reduce the serum requirements by as much as 50–75% without appreciably altering either cell viability or the recovery of chemically-induced mutants. Phenotypic stability of test-derived trifluorothymidine resistant (TFT^R) mutants was confirmed by demonstrating cross-resistance to bromodeoxyuridine and concomitant sensitivity to methotrexate (THMG) in TFT^R cells grown for 20 generations under non-selective conditions. While reduced growth rates resulting from temporary cell-division delay in treated cells is probably not a contributing factor to the observed mutation frequencies, only TFT^R colonies which formed large distinct colonies in the presence of trifluorothymidine were clearly phenotypically stable mutants when spontaneous mutants were isolated and verified. When a non-mutagen, a weak mutagen, and a well-established mutagen were compared at equitoxic doses under these modified conditions, clear quantitative differences were seen in the respective mutation frequencies induced by these 3 types of agents. With these technical modifications, we feel this assay is both reliable and amenable to the screening of diverse chemical compounds for point-mutational activity in a mammalian cell.     

Trifluorothymidine resistance and colony size in L5178Y/TK +/- cells treated with methyl methanesulfonate

L5178Y/TK +/- cells treated with methyl methanesulfonate (MMS) were allowed to recover for 0,48,96,144, or 240 hours, and were then plated in soft-agar medium containing trifluorothymidine (TFT). Dose-dependent and consistent increases in the frequency of TFTR cells were observed after each of the 48-240-hour expression periods through the counting of predominantly large, mutant colonies. Size distributions of soft-agar colonies from either MMS-treated or control cells were bimodal in the presence, and unimodal in the absence, of TFT. An increase of small, presumptive TFTR colonies with either increasing MMS concentration or decreasing recovery time was probably a manifestation of chemical toxicity, for a similar increase in small-colony number was observed in the absence of TFT when cells were cloned immediately after MMS treatment, when no induced mutants were yet detectable. Recloning experiments with 22 small-colony-derived cell lines revealed that, with one exception, small-colony morphology was not a heritable trait. While all large- and some small-colony-derived stocks from MMS-treated cells were of the phenotypically stable TK-/- type; spontaneous small TFTR colonies generally were not, their occurrence being directly correlated with serum concentration. No aneuploidy was evident in MMS-treated cell lines several generations after isolation as small TFTR colonies. These results suggest that delayed MMS cytotoxicity in TK +/- cells can temporarily produce increased physiological resistance to TFT in some cells, giving rise to secondary populations of small-colony TFTR variants.     

Creating auxotrophic mutants in Methylophilus methylotrophus AS1 by combining electroporation and chemical mutagenesis

Stable auxotrophic mutants of the methylotroph Methylophilus methylotrophus AS1 were obtained by a novel mutagenesis technique in which electroporation is used to transport the chemical mutagen N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) across the cell membrane. By combining chemical mutagenesis with electroporation and screening single colonies for auxotrophy in 36 different amino acids and growth factors, 3 auxotrophs per 156 colonies screened were obtained, whereas no auxotrophs were found with chemical mutagenesis alone. MNNG mutagen toxicity was also increased in the methylotroph with this novel mutagenesis technique (death rate 96% compared to 79%). This technique did not increase the mutation rate for strain Escherichia coli BK6 which responds well to simple exposure to the mutagen. Received: 9 December 1996 / Received revision: 31 March 1997 / Accepted: 13 April 1997     

Comparison of a forward and a reverse mutation assay in Salmonella typhimurium measuring L-arabinose resistance and histidine prototrophy

A forward and a reverse mutation assay designed to detect environmental mutagens have been compared in Salmonella typhimurium. The forward mutation assay scored resistance to L-arabinose and the reverse assay, reversion of histidine auxotrophy. Eighteen chemicals of different structural groups, all known to be mutagenic in the histidine reverse assay, were applied to strains carrying the genetic markers needed to perform both mutation assays. The mutagenicity of each chemical was determined by both plate and liquid tests. The plate test counted absolute numbers of surviving mutants and the liquid test separately measured survival and frequency of mutants among the survivors. All the chemicals used were found to be mutagenic in both mutation assays. The response of the L-arabinose assay was equal to or larger than the response of the histidine assay in the case of 16 chemicals. The two other compounds, 2-nitrofluorene and sodium azide, were detected more efficiently by the histidine assay. Sodium azide, a non-carcinogenic compound, is a potent mutagen in the histidine assay, but very weak in the L-arabinose assay.     

Forward mutation assay for screening carcinogens by alkaline phosphatase constitutive mutations in Escherichia coli K-12

A new forward mutation assay was developed with Escherichia coli using alkaline phosphatase (APase) constitutive mutations as a genetic marker. Mutation in any one of the three regulator genes (phoR, T and S) is known to make the cell constitutive for APase synthesis and enable the mutants to form larger colonies on beta-glycerophosphate plate under the condition of excess inorganic phosphate. This property was used for qualitative and quantitative assay of chemical mutagens. Attempts were made to construct suitable strains for this assay by introduction of various genetic traits that might increase the sensitivity of mutation. Three known chemical mutagens (N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), methyl methanesulfonate (MMS), and 4-nitroquinoline-1-oxide (NQNO)) were employed as reference compounds in the quantitative assay. Among the strains constructed, a tester strain with genetic markers tif-1, uvrA and pKM101 was the most sensitive to these compounds, judging from tests on concentration-dependent mutagenic activity. The merits and limitations of the present system are discussed.     

Activity of the plant flavanol quercetin in the mouse lymphoma L5178Y TK+/− mutation,DNA single-strand break,and Balb/c 3T3 chemical transformation assays

The activity of quercetin was investigated in (a) the L5178Y TK^+/− mutation assay system, using trifluorothymidine (TFT) as the selection agent; (b) the DNA single-strand break assay in L5178Y cells after the same treatment used for the mutation assay; and (c) the Balb/c 3T3 chemical transformation assay (foci method). Quercetin was active in the TK^+/− mutation assay, increasing the frequency of TFT-resistant colonies from a control value of 37 per 10⁶ viable cells to 355 per 10⁶ viable cells at 20 μg/ml. When S9 was present, the activity was decreased at each concentration tested. As the S9 concentration employed (mg/ml protein) was decreased, the induced mutant frequency increased. DNA single-strand breakage was observed without S9 at 10 μg/ml, using the alkaline elution technique; a maximal rate of elution was reached at 20 μg/ml. In the chemical transformation experiments, transformation just at the level of 0.05% significance (if both intermediate and typical transformed colonies were combined) was observed. The evidence is sufficiently strong that additional attention should be given to its role as a dietary caused of human cancer.     

Bromouracil mutagenesis and mismatch repair in mutator strains of Escherichia coli.

A screening procedure based on the formation of papillae on individual bacterial colonies was used to isolate mutants of Escherichia coli with high mutation rates in the presence of bromouracil. Most of the mutants obtained had high spontaneous mutation rates and mapped close to the previously known mutators mutT, mutS, mutR, uvrE and mutL. Except for mutants of mutT type, these mutators also showed high mutability by bromouracil. Transfection experiments were performed with heteroduplex lambda DNA to test for mismatch repair. The results suggest a reduced efficiency of repair of mismatched bases in mutators mutS, mutR, uvrE and mutL, whereas mutants mapping as mutT appear normal. The results support a connection between spontaneous and bromouracil-induced mutability and repair of mismatched bases in DNA.     

Mutants of Chinese hamster cells deficient in thymidylate synthetase

Stable mutants of Chinese hamster V79 cells deficient in thymidylate synthetase (TS; E.C. 2.1.1.45) have been selected from cultures grown in medium supplemented with folinic acid, aminopterin, and thymidine (FAT). After chemical mutagenesis, the frequency of colonies resistant to the "FAT" medium increased more than 100-fold over the spontaneous frequency. The optimal expression time of the mutant phenotype was 5-7 days after mutagen treatment. The recovery of FAT-resistant colonies in the selective medium was not affected by the presence of wild-type cells at a density below 9,000 cells per cm2. All 21 mutants tested exhibited thymidine auxotrophy; neither folinic acid nor deoxyuridine could support mutant cell growth. There was no detectable TS activity in all 11 mutants so far examined and only about 50% of wild-type activity in three prototrophic revertants, as measured by whole-cell and cell-free enzyme assays. The apparent Michaelis-Menten constant (Km) for deoxyuridine-5'-monophosphate and inhibition constant (Ki) for 5-fluoro-deoxyuridine-5'-monophosphate, measured by whole-cell enzyme assay, appear to be similar for the wild-type and revertant cell lines. Using 5-fluoro-[6-3H]-2'-deoxyuridine 5'-monophosphate as active site titrant, the relative amounts of TS in crude cell extract from the parental, revertant, and mutant cells were shown to exist in a 1:0.5:0 ratio. Furthermore, the enzymes from two revertants were more heat labile than that of V79 cells. These properties, taken together, suggest that the FAT-resistant, thymidine auxotrophic phenotype may be the result of a structural gene mutation at the TS locus. The availability of such a mutant facilitates studies on thymidylate stress in relation to DNA metabolism, cell growth, and mutagenesis.     

Somatic genetic analysis of cyclic AMP action: selection of unresponsive mutants.

Dibutyryl cyclic AMP and theophylline kill S49.1 mouse lymphoma tissue culture cells. When cells are grown in soft agar with these drugs, the few clones that survive are resistant to cytolysis. The rate of mutation to resistance is 1-3 times 10-7/cell/generation in both diploid and tetraploid cells. The incidence of mutants is increased by treatment with a chemical mutagen, ICR 191. The mutation is consistently associated with greatly reduced or absent cytoplasmic cyclic AMP binding protein. These results suggest that a somatic mutation leads to a defect of the protein kinase regulatory subunit and that activity of this kinase is required for induction of cell death by cyclic AMP.     

A Pseudomonas aeruginosa mutant non-derepressible for orthophosphate-regulated proteins.

Using a rapid screening assay based on the hydrolysis of p-nitrophenylphosphorylcholine, we isolated several mutants of Pseudomonas aeruginosa deficient in the production of phospholipase C. One, designated strain A50N, was also markedly deficient in the synthesis of alkaline phosphatase and several unidentified extracellular proteins. Because strain A50N produces these proteins under conditions of derepression at levels equal to those produced by the parental strain PAO1 grown in medium containing excess phosphate, it appears to have a mutation in a genetic element involved in the derepression of phosphate-repressible proteins.     

Spontaneous Mutation Rates in Mammalian Cells: Effect of Differential Growth Rates and Phenotypic Lag

We calculated a spontaneous rate of 26-37 x 10(-6) mutations per cell division for L5178Y MOLY (mouse lymphoma) cells at the thymidine kinase locus (tk+/(-)----tk-/-) using a procedure that isolated and segregated cells during expression. This rate was 50 times higher than when cells expressed the mutant phenotype in suspension. The higher mutation rates obtained with the in situ procedure suggest that many of the mutants, whether expressed or unexpressed, grew more slowly than wild-type cells prior to selection with trifluorothymidine (TFT), implying that the slow growth phenotype is expressed earlier than the TFTr (TFT-resistant) phenotype. The loss of mutants was not restricted to cells forming small colonies; the mutation rate for cells forming large colonies was more than ten times higher using the in situ procedure. In this new procedure, the cells expressed spontaneous mutations while growing in semisolid medium for up to 3 days without TFT. Mutants were then selected in situ by adding an overlay of TFT and the visible colonies were analyzed after 11 days. Cells with spontaneous mutations at the tk locus required approximately 30 hr for the more rapidly expressing cells with new mutations to be detected. Most of the TFTr colonies selected after 60 hr of growth in semisolid medium represented independent mutations that had accumulated during the first 30 hr.(ABSTRACT TRUNCATED AT 250 WORDS)     

The Ames Salmonella/microsome mutagenicity assay

The Ames Salmonella/microsome mutagenicity assay (Salmonella test; Ames test) is a short-term bacterial reverse mutation assay specifically designed to detect a wide range of chemical substances that can produce genetic damage that leads to gene mutations. The test employs several histidine dependent Salmonella strains each carrying different mutations in various genes in the histidine operon. These mutations act as hot spots for mutagens that cause DNA damage via different mechanisms. When the Salmonella tester strains are grown on a minimal media agar plate containing a trace of histidine, only those bacteria that revert to histidine independence (his(+)) are able to form colonies. The number of spontaneously induced revertant colonies per plate is relatively constant. However, when a mutagen is added to the plate, the number of revertant colonies per plate is increased, usually in a dose-related manner. The Ames test is used world-wide as an initial screen to determine the mutagenic potential of new chemicals and drugs. The test is also used for submission of data to regulatory agencies for registration or acceptance of many chemicals, including drugs and biocides. International guidelines have been developed for use by corporations and testing laboratories to ensure uniformity of testing procedures. This review provides historical aspects of how the Ames was developed and detailed procedures for performing the test, including the design and interpretation of results.     

Conditions necessary for quantifying ethyl methanesulfonate-induced mutations to purine-analogue resistance in Chinese hamster V79 cells.

We have investigated conditions necessary to quantify the relationship between exposure to a mutagen, ethyl methanesulfonate (EMS), and the frequency of mutation induction at the hypoxanthine-guanine phosphoribosyl transferase locus in V79 cells. Maximal expression of potential mutants has been achieved by either subculturing at fewer than 5 X 10(5) cells/100-mm dish at 2-day intervals or by daily feeding of cultures. An expression period of 5 days (measure from 1 day after the initiation of treatment with the chemical mutagen) should be allowed, since at least 4 days of expression is required to reach to steady maximum of mutation frequency. It appears that there is no concentration dependence of expression time necessary to reach a plateau of mutation frequency with increasing concentrations of EMS up to 1.6 mg/ml. About 1.25 X 10(5) cells/100-mm dish or fewer should be plated for selection to avoid the loss of mutants which occurs at 1.5 X 10(5) cells/dish, presumably through cross-feeding (metabolic cooperation). The use of 6-thioguanine in hypoxanthine-free medium (supplemented with dialyzed fetal calf serum) appears to be a very stringent condition for selection. Mutation induction by EMS as a function of EMS exposure (EMS concentration X treatment time) increases linearly with concentration up to 12 h. For these treatment periods, the observed mutation frequencies for EMS are directly proportional to mutagen exposure regardless of the duration of the treatment.     

Fluctuation analysis: the effect of plating efficiency

This paper supplements an earlier paper which explained how to calculate the probability distribution of the number of mutants that would be observed in a fluctuation test experiment. The formulas in that work give the distributions to be expected under a wide variety of experimental conditions, but the method it uses when only a fraction of the mutants will produce visible colonies are clumsy and inefficient. Here I describe efficient procedures for dealing with that case, provided that the mutation rate per cell division remains constant during the experiment.     

Escherichia coli strains with modified RNase II activity: Isolation and properties

Summary In a search for Escherichia coli strains defective in ribonuclease activity, a uracil requiring strain lacking RNase I activity was fed yeast RNA as the sole source of uracil and mutants that failed to utilize yeast RNA as the sole source of uracil were isolated. Among thirty colonies thus isolated and tested three were found to contain a heat labile RNase activity in cell free extracts. (Assays were performed under conditions for RNase II.) Since no strain completely lacking this RNase activity was found, and since these three strains have reduced growth rates that seem to be caused by the same mutation that altered the RNase activity, we concluded that RNase II activity is indispensible during cell growth.     

Cytogenetic analysis of the L5178Y/TK+/− → TK−/− mouse lymphoma mutagenesis assay system

The L5178Y/TK^+/? → TK^?/? mouse lymphona mutagen assay, which allows selection of forward mutations at the autosomal thymidine kinase (TK) locus, uses a TK^+/? heterozygous cell line, TK^+/? 3.7.2C. Quantitation of colonies of mutant TK^?/? cells in the assay forms the basis for calculations of mutagenic potential of test compounds. We have evaluated the banded karyotypes of the parent TK^+/? heterozygous cell line, as well as homozygous TK^?/? mutants, in order to relate the genetic and morphological properties of mutant colonies. The parent cell line displays karyotype homogeneity, all cells containing normal mouse chromosomes, readily identifiable chromosome rearrangements, and cell line specific marker chromosomes. Mutant TK^?/? colonies of the TK^+/? 3.7.2C cell line form a bimodal frequency distribution of colony sizes for most mutagenic or carcinogenic test substances. Large-colony (λ) TK^?/? mutants with normal growth kinetics appear karyotypically identical within and among clones and with the TK^+/? parental cell line. In contrast, most slow-growing small-colony (σ) TK^?/? mutants have readily recognizable chromosome rearrangements involving chromosome 11, which contains the thymidine kinase gene locus. It is possible that the heritable differences in growth kinetics and resultant colony morphology in λ and σ mutants are related to the type of chromosomal damage sustained. Large-colony mutants receive minimal damage, possibly in the form of point mutations at the TK locus, while small-colony mutants receive damage to other genetic functions coordinately with loss of TK activity, implying gross insult to chromosomal material. It seems likely that λ and σ mutants result from 2 different mutational mechanisms that may be distinguished on the basis of mutant colony morphology.     

Ethyl methanesulfonate mutagenesis in extremely halophilic archaebacteria: Isolation of auxotrophic mutants ofHaloferax mediterranei andHaloferax gibbonsii

The lethality and mutagenicity in ethyl methanesulfonate (EMS)-treated cells of five archaebacterial strains belonging to each of the three described genera of non-alkaliphilic halobacteria were investigated. In order to test the efficiency of the mutagenesis under a variety of experimental conditions, we chose the fast-growing halobacteriumHaloferax mediterranei as a model strain. A strong induced mutagenicity was found, since the spontaneous mutation rate (expressed as the rate of resistance to the antibiotic josamycin) increased up to 500-fold after mutagen exposure. The mutagenesis was also successfully used in obtaining auxotrophic mutants. Although a heterogeneous response to the induced effects caused after EMS exposure was detected for the other halophilic archaebacteria tested, a clear, efficient mutagenicity ofHalobacterium halobium andHaloferax gibbonsii was observed; auxotrophic mutants of this halobacterium were also produced. Optimal experimental conditions for EMS mutagenesis of some halobacteria were determined.     

Clustering of mutant mitochondrial DNA copies suggests stem cells are common in human bronchial epithelium

Tissue maintenance stem cells, as opposed to transition and/or terminal cells in the epithelium, are possible progenitor cells for human tumors, but little is known about their frequency in human tissues. It occurred to us that the colonies of mutants that should be created when a stem cell mutates and transmits the rare mutation to its descendent transition and terminal cells should, given a quantitative mutation assay, define the average number of cells in a maintenance turnover unit and permit calculation of stem cell number. To test this concept we used a combination of high fidelity PCR and constant denaturant capillary electrophoresis to enumerate mitochondrial point mutations and define their number and distribution among multiple small samples of approximately one million cells containing about 400 million copies of mitochondrial DNA. The bulk of the data were best explained by a model in which most stem cells, defined here as long-lived cells, give rise to colonies of approximately 8-128 cells. In addition, we found that about 1.5% of colonies contained hundreds or even thousands of homoplasmic mutant cells. These expanded turnover units suggest the bronchial epithelium may contain large clusters of cells with mutations, and possibly phenotypic alterations as well.     

Synergism of mutant frequencies in the mouse lymphoma cell mutagenicity assay by binary mixtures of methyl methanesulfonate and ethyl methanesulfonate

The effect of mixed mutagen exposures on the rate and type of induced mutants was studied in the L5178Y/TK+/-----TK-/- mouse lymphoma cell mutagenicity assay. In this assay, exposure to ethyl methanesulfonate (EMS) results in more mutants that form large colonies than small colonies. Exposure to methyl methanesulfonate (MMS) results in more mutants that form small colonies than large colonies. Other reports in the literature suggest that large colony TK-/- mutants appear to result from small-scale, perhaps single-gene mutations, and that small-colony TK-/- mutants appear to be associated with chromosomal mutations. Treating cells for 4 h with simple, 2-component mixtures containing 6.45 micrograms/ml MMS and either 261, 392, 560 or 712 micrograms/ml EMS resulted in synergism of mutants at each mixture level. The frequencies of total mutants were synergized 12, 20, 35 and 72%, respectively, in mixed exposures with graded doses of EMS, above the sums of the mixture components. Small colony mutants were synergized to a greater extent than large colony mutants. The frequencies of small colony mutants in mixed exposures were increased 31, 54, 73 and 123%, respectively, while the frequencies of large colony mutants were increased -7, -6, 11 and 39%. Statistical analyses provide strong evidence of synergism (within the limits of the assay) for total and small-colony mutants at all doses of EMS tested, and for large-colony mutants above 400 micrograms/ml EMS. Similar magnitudes of synergism resulted when other constant levels of MMS (4.30 or 8.60 micrograms/ml) were mixed with the same graded doses of EMS. The degree of synergism was dependent on EMS concentration but not on MMS concentration.