Isolation and characterization of mutants of human diploid fibroblasts resistant to diphtheria toxin

Toxic, DNA-Damaging and Mutagenic Activity of Epichlorohydrin on Human Cells Cultured in Vitro

Epichlorohydrin (ECHH) highly inhibited the tritiated thymidine uptake by human lymphocytes cultured in vitro, although the corresponding cell viability was unaffected. Furthermore, it elicited unscheduled DNA synthesis, acting as a DNA-damaging agent after its metabolic activation. ECHH also showed a clear toxic and mutagenic activity toward a human epithelial-like cell line, causing a decrease in cell viability and an increase in mutants resistant to 0.05 Lf/ml of diphtheria toxin.

Variable aberrant cDNAs in single diphtheria toxin-resistant human fibroblasts

We treated transformed human fibroblasts with diphtheria toxin (DT) and isolated 40 single cells that were toxin resistant but unable to propagate. In 13 of them toxin resistance was associated with the presence of one or more aberrant transcripts of the structural gene for elongation factor 2 (EF-2). cDNA obtained from these transcripts had 164-447 bp-long deletions. Each of these deletions was associated with 2-8 base pairs-long repeats at its breakpoints. Only 10 out of 16 cDNA deletions were associated with presumed exon junctions. A role is suggested for errors in transcription in producing the aberrant transcripts which gave rise to the deletion-bearing cDNA species.

Genetic analysis of a vital mammalian housekeeping locus using CHO cells that express a transfected mutant allele

We describe a novel approach for the isolation of null mutations in a vital Chinese hamster ovary (CHO) cell housekeeping gene. Our experimental strategy required introduction of an expressible DNA clone encoding a recessive emetine-resistance allele of ribosomal protein S14 into wild-type CHO cells. Transgene heterozygote (TGH) cell lines, which harbor multiple emetine-resistance S14 transgenes, survive mutations that inactivate the CHO RPS14 locus by virtue of the transgenes' biological function. Null mutations in RPS14 yield TGH clones that display the transgene's drug-resistance phenotype. A large collection of emetine-resistant clones was isolated from one TGH cell line and shown to consist of three types of S14 mutations: (1) nonsense null mutations in the RPS14 protein coding sequence; (2) missense null mutations that affect S14 amino acid residues that have been conserved stringently during eukaryotic evolution; and (3) a recurrent missense mutation that results in a new, functional RPS14 emetine-resistance allele.

DNA amplification is rare in normal human cells

Three types of normal human cells were selected in tissue culture with three drugs without observing a single amplification event from a total of 5 x 10(8) cells. No drug-resistant colonies were observed when normal foreskin keratinocytes were selected with N-(phosphonacetyl)-L-aspartate or with hydroxyurea or when normal mammary epithelial cells were selected with methotrexate. Some slightly resistant colonies with limited potential for growth were obtained when normal diploid fibroblast cells derived from fetal lung were selected with methotrexate or hydroxyurea but careful copy-number analysis of the dihydrofolate reductase and ribonucleotide reductase genes revealed no evidence of amplification. The rarity of DNA amplification in normal human cells contrasts strongly with the situation in tumors and in established cell lines, where amplification of oncogenes and of genes mediating drug resistance is frequent. The results suggest that tumors and cell lines have acquired the abnormal ability to amplify DNA with high frequency.

Isolation and characterization of dexamethasone-resistant mutants from human lymphoid cell line CEM-C7

Fifty-four independent dexamethasone-resistant clones were isolated from the clonal, glucocorticoid-sensitive human leukemic T-cell line CEM-C7. Resistance to 1 microM dexamethasone was acquired spontaneously at a rate of 2.6 X 10(-5) per cell per generation as determined by fluctuation analysis. After mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), the phenotypic expression time for dexamethasone resistance was determined to be 3 days. Spontaneous acquisition of resistance to 0.1 mM 6-thioguanine appeared to occur at a much slower rate, 1.6 X 10(-6) per cell per generation. However, the expression time after MNNG mutagenesis for this resistant phenotype was greater than 11 days, suggesting that the different rates of acquisition for the two phenotypes measured by fluctuation analysis were the results of the disparate expression times. The mutagens ICR 191 and MNNG were effective in increasing the dexamethasone-resistant fraction of cells in mutagenized cultures; ICR 191 produced a 35.6-fold increase, and MNNG produced an 8.5-fold increase. All the spontaneous dexamethasone-resistant clones contained glucocorticoid receptors, usually less than half of the amount found in the parental clone. They are therefore strikingly different from dexamethasone-resistant clones derived from the mouse cell lines S49 and W7. Dexamethasone-resistant clones isolated after mutagenesis of CEM-C7 contained, on the average, lower concentrations of receptor than did those isolated spontaneously, and one clone contained no detectable receptor. These results are consistent with a mutational origin for dexamethasone resistance in these human cells at a haploid or functionally hemizygous locus. They also suggest that this is a useful system for mutation assay.

Spread of SHV-1 beta-lactamase in Escherichia coli isolated from fecal samples in Africa

Ninety-seven (42%) Escherichia coli strains isolated in Senegal from fecal samples produced beta-lactamases. Among them, 29 (30%) isolates produced SHV-1 beta-lactamase that was plasmid mediated. The plasmids belonged to four incompatibility groups. Various degrees of TEM-1 expression in the presence of SHV-1 were observed.

Determination of DNA sequence changes induced by ethyl methanesulfonate in human cells, using a shuttle vector system

The DNA sequence changes for 54 mutations induced in human cells by the alkylating agent ethyl methanesulfonate are reported. The mutations were obtained by using a shuttle vector system with the bacterial lacI gene as the target. Of the 54 mutations obtained, 53 were G:C to A:T transitions.

Diphtheria toxin-resistant mutants of Saccharomyces cerevisiae

We developed a selection procedure based on the observation that diphtheria toxin kills spheroplasts of Saccharomyces cerevisiae (Murakami et al., Mol. Cell. Biol. 2:588-592, 1982); this procedure yielded mutants resistant to the in vitro action of the toxin. Spheroplasts of mutagenized S. cerevisiae were transformed in the presence of diphtheria toxin, and the transformed survivors were screened in vitro for toxin-resistant elongation factor 2. Thirty-one haploid ADP ribosylation-negative mutants comprising five complementation groups were obtained by this procedure. The mutants grew normally and were stable to prolonged storage. Heterozygous diploids produced by mating wild-type sensitive cells with the mutants revealed that in each case the resistant phenotype was recessive to the sensitive phenotype. Sporulation of these diploids yielded tetrads in which the resistant phenotype segregated as a single Mendelian character. From these observations, we concluded that these mutants are defective in the enzymatic steps responsible for the posttranslational modification of elongation factor 2 which is necessary for recognition by diphtheria toxin.

Determination of DNA sequence changes induced by ethyl methanesulfonate in human cells, using a shuttle vector system

The DNA sequence changes for 54 mutations induced in human cells by the alkylating agent ethyl methanesulfonate are reported. The mutations were obtained by using a shuttle vector system with the bacterial lacI gene as the target. Of the 54 mutations obtained, 53 were G:C to A:T transitions.

Diphtheria toxin-resistant mutants of Saccharomyces cerevisiae

We developed a selection procedure based on the observation that diphtheria toxin kills spheroplasts of Saccharomyces cerevisiae (Murakami et al., Mol. Cell. Biol. 2:588-592, 1982); this procedure yielded mutants resistant to the in vitro action of the toxin. Spheroplasts of mutagenized S. cerevisiae were transformed in the presence of diphtheria toxin, and the transformed survivors were screened in vitro for toxin-resistant elongation factor 2. Thirty-one haploid ADP ribosylation-negative mutants comprising five complementation groups were obtained by this procedure. The mutants grew normally and were stable to prolonged storage. Heterozygous diploids produced by mating wild-type sensitive cells with the mutants revealed that in each case the resistant phenotype was recessive to the sensitive phenotype. Sporulation of these diploids yielded tetrads in which the resistant phenotype segregated as a single Mendelian character. From these observations, we concluded that these mutants are defective in the enzymatic steps responsible for the posttranslational modification of elongation factor 2 which is necessary for recognition by diphtheria toxin.

Autoradiographic detection of diphtheria toxin resistant mutants in human diploid fibroblasts

An autoradiographic procedure for the detection of diphtheria toxin (DT) resistant (DipR) mutants in human diploid fibroblast (HDF) cells has been developed. The assay is based on the observation that when HDFs from confluent cultures are seeded in medium containing 0.01 flocculating units/ml or higher concentration of DT, protein synthesis in sensitive cells is severely inhibited by 4-6 hr. If at this or later time, a radiolabeled protein precursor (eg, 3H-leucine) is added to the culture, it is almost exclusively incorporated into the resistant cells, which are then readily identified by autoradiography. The DipR cells can also be identified by labeling in the presence of 3H-thymidine, although a higher background is observed in these experiments. Reconstruction experiments using DipS and DipR HDFs show that the frequency of heavily labeled cells that are detected by autoradiography show an excellent correlation with the number of DipR cells added and to the number of DipR cells as detected by conventional colony forming assay. These studies provide strong evidence that the labeled cells identified by autoradiography are bona fide DipR mutants. The detection of DipR cells by autoradiography is apparently not affected by the presence of the sensitive cells in the mixtures. The spontaneous frequency of DipR cells in HDFs has been found to be in the range of 1-5 X 10(-6), and this increases in a dose dependent manner upon treatment with the mutagen ethyl methanesulfonate. These results indicate that the autoradiographic assay could be used for quantitative mutagenesis. Since the autoradiographic assay does not depend on cell division, it may prove useful in estimating the incidence of pre-existing mutations in cell populations that either do not divide or have very limited growth potential (eg, lymphocytes, muscle cells, neurons, senescent fibroblasts, etc).

Diphtheria toxin resistance in human lymphocytes and lymphoblasts in the in vivo somatic cell mutation test

It has been shown that circulating peripheral blood lymphocytes can be used for the enumeration of 6-thioguanine-resistant cells that presumably arise by mutation in vivo. This somatic cell mutation test has been studied in lymphocytes from human populations exposed to known mutagens and/or carcinogens. The sensitivity of the test could be further enhanced by including other gene markers, since there is evidence for locus-specific differences in response to mutagens. Resistance to diphtheria toxin (Dipr) seemed like a potential marker to incorporate into the test because the mutation acts codominantly, can readily be selected in human diploid fibroblasts and Chinese hamster cells with no evidence for cell density or cross-feeding effects, and can be assayed for in nondividing cells by measuring protein synthesis inhibition. Blood samples were collected from seven individuals, and fresh, cryopreserved, or Epstein-Barr virus (EBV)-transformed lymphocytes were tested for continued DNA synthesis (3H-thymidine, autoradiography) or protein synthesis (35S-methionine, scintillation counting). Both fresh and cryopreserved lymphocytes, stimulated to divide with phytohemagglutinin (PHA), continued to synthesize DNA in the presence of high doses of diphtheria toxin (DT). Similarly, both dividing (PHA-stimulated) and nondividing fresh lymphocytes carried on significant levels of protein synthesis even 68 hr after exposure to 100 flocculating units (LF)/ml DT. The findings were confirmed in cord blood lymphocytes, ruling out the possibility that diphtheria immunization could have led to a selection of Dipr lymphocytes. One lymphoblast line (EBV-transformed lymphocytes) showed a reduction in protein synthesis to 0.2% of controls only at 192 hr after exposure to 100 LF/ml. The results suggest that human T and B lymphocytes may not be as sensitive to DT protein synthesis inhibition as human fibroblast and Chinese hamster cells. For this reason, Dipr may not be a suitable marker for the somatic cell mutation test.

Autoradiographic assay of mutants resistant to diphtheria toxin in mammalian cells in vitro

Diphtheria toxin kills mammalian cells by ribosylating elongation factor 2, a protein factor necessary for protein synthesis. The frequency of cells able to form colonies in the presence of the toxin can be used as an assay for mutation to diphtheria toxin resistance. We report here that resistance to diphtheria toxin can also be detected autoradiographically in cells exposed to [3H]leucine after treatment with the toxin. In cultures of Chinese hamster ovary cells, the frequency of such resistant cells is increased by exposure of the cells to gamma-rays, ultraviolet light, ethylnitrosourea, mitomycin c, ethidium bromide, and 5-bromo-2'-deoxyuridine in a dose- and time-dependent manner. The resistant cells form discrete microcolonies if they are allowed to divide several times before intoxication, which indicates that they are genuine mutants. The assay is potentially adaptable to any cell population that can be intoxicated with diphtheria toxin and labeled with [3H]leucine, whether or not the cells can form colonies. It may be useful, therefore, for measuring mutation rates in slowly growing or nondividing cell populations such as breast, brain, and liver, as well as in cells that do divide but cannot be readily cloned, such as the colonic epithelium.

Induction of diphtheria toxin-resistant mutants in human cells by halogenated compounds

The mutagenic power of 1,2-dichloroethane, 1,2-dibromoethane, 1,2-diiodoethane was tested in the human cell line, EUE. In our mutagenic system, based on selection against diphtheria toxin, the halogenated compounds, 1,2-dichloroethane and 1,2-dibromoethane revealed a strong mutagenic effect, whereas 1,2-diiodoethane was not mutagenic at a concentration allowing survival of 41%.

Saccharomyces cerevisiae spheroplasts are sensitive to the action of diphtheria toxin

Diphtheria toxin kills spheroplasts of Saccharomyces cerevisiae but not the intact yeast cells. After 2 h of exposure to ca. 10(-7) M toxin, less than 1% of spheroplasts were able to regenerate into intact cells. The same high levels of toxin inhibited the rate of protein synthesis by more than 90% within 1 h, whereas RNA and DNA synthesis were not inhibited until 4 h or exposure. Both killing and protein synthesis inhibition were dependent on toxin concentration. The nature of the toxin-cell interaction was also studied by using fragments of intact toxin and mutant toxin proteins. Neither toxin fragment A nor CRM45 nor CRM197 affected spheroplasts, but CRM197 and ATP prevented the inhibitory action of intact toxin. These results suggest that toxin acts on S. cerevisiae spheroplasts in much the same manner as it acts on sensitive mammalian cells.

Species specific differences in the toxicity of mithramycin, chromomycin A3, and olivomycin towards cultured mammalian cells

Three structurally related anticancer drugs, mithramycin, chromomycin A3, and olivomycin, showed large unexpected differences (up to more than 1000 fold) in their toxicity towards cultured cells from various species (human, Chinese hamster, Syrian hamster, and mouse). Among the cell types examined, human cells (both a diploid fibroblast cell strain and HeLa cells) were maximally sensitive to all these drugs, followed by the Syrian hamster kidney cells (BHK 21). The mouse (LMTK- cells) and Chinese hamster (CHO) cells, which were more resistant, showed interesting differences in their sensitivity towards these drugs. For example, whereas the mouse cells were more resistant to mithramycin than CHO cells, the sensitivity pattern was reversed for both chromomycin A3 and olivomycin. In cell extracts derived from human, mouse, and Chinese hamster cells RNA synthesis, which is the cellular target of these drugs, showed identical sensitivity to both mithramycin and chromomycin A3, indicating that the species specific differences in the toxicity to these drugs are at the level of cellular entry of these compounds. Based on the structures of these glycosidic antibiotics and their patterns of toxicity, it is suggested that the intracellular transport of these drugs involves specific interactions between the sugar residues on these compounds and some type of cell surface receptor(s), which differ among different cell types. Some implications of these results for toxicity studies are discussed.

Saccharomyces cerevisiae spheroplasts are sensitive to the action of diphtheria toxin

Diphtheria toxin kills spheroplasts of Saccharomyces cerevisiae but not the intact yeast cells. After 2 h of exposure to ca. 10(-7) M toxin, less than 1% of spheroplasts were able to regenerate into intact cells. The same high levels of toxin inhibited the rate of protein synthesis by more than 90% within 1 h, whereas RNA and DNA synthesis were not inhibited until 4 h or exposure. Both killing and protein synthesis inhibition were dependent on toxin concentration. The nature of the toxin-cell interaction was also studied by using fragments of intact toxin and mutant toxin proteins. Neither toxin fragment A nor CRM45 nor CRM197 affected spheroplasts, but CRM197 and ATP prevented the inhibitory action of intact toxin. These results suggest that toxin acts on S. cerevisiae spheroplasts in much the same manner as it acts on sensitive mammalian cells.

Mutations causing deficiency of APRT in fibroblasts cultured from human heterozygous for mutant APRT alleles

Frequent mutation to adenine analog resistance in diploid human cells reflected heterozygosity for recessive alleles affecting expression of the adenine phosphoribosyltransferase (APRT) locus. Cells from both parents of APRT-deficient sibs were heterozygous and had rates of spontaneous mutation to 2,6-diaminopurine (DAP) resistance of 6.0 x 10(-5) and 16 x 10(-5) per cell generation. Spontaneous DAP-resistant mutants were not observed in cultures of homozygous cells. Almost all mutants of proven heterozygous cultures were APRT deficient and could not use adenine for growth. Frequent DAP-resistant mutations identified heterozygous strain 438, which carried an allele encoding a partially defective form of APRT. All DAP-resistant mutants of strain 438 were partially APRT deficient and could use adenine for growth. The frequency of MNNG-induced DAP-resistant mutants in homozygous strains was approximately the square of the induced frequency in heterozygous strains.

Isolation and characterization of dexamethasone-resistant mutants from human lymphoid cell line CEM-C7

Fifty-four independent dexamethasone-resistant clones were isolated from the clonal, glucocorticoid-sensitive human leukemic T-cell line CEM-C7. Resistance to 1 microM dexamethasone was acquired spontaneously at a rate of 2.6 X 10(-5) per cell per generation as determined by fluctuation analysis. After mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), the phenotypic expression time for dexamethasone resistance was determined to be 3 days. Spontaneous acquisition of resistance to 0.1 mM 6-thioguanine appeared to occur at a much slower rate, 1.6 X 10(-6) per cell per generation. However, the expression time after MNNG mutagenesis for this resistant phenotype was greater than 11 days, suggesting that the different rates of acquisition for the two phenotypes measured by fluctuation analysis were the results of the disparate expression times. The mutagens ICR 191 and MNNG were effective in increasing the dexamethasone-resistant fraction of cells in mutagenized cultures; ICR 191 produced a 35.6-fold increase, and MNNG produced an 8.5-fold increase. All the spontaneous dexamethasone-resistant clones contained glucocorticoid receptors, usually less than half of the amount found in the parental clone. They are therefore strikingly different from dexamethasone-resistant clones derived from the mouse cell lines S49 and W7. Dexamethasone-resistant clones isolated after mutagenesis of CEM-C7 contained, on the average, lower concentrations of receptor than did those isolated spontaneously, and one clone contained no detectable receptor. These results are consistent with a mutational origin for dexamethasone resistance in these human cells at a haploid or functionally hemizygous locus. They also suggest that this is a useful system for mutation assay.

The mutation studies of mutagen-sensitive and DNA repair mutants of Chinese hamster fibroblasts

We have previously reported the isolation and partial characterization of DNA repair and/or mutagen-sensitive mutant Chinese hamster cell strains. Here we present the results of a detailed study of the ultraviolet light (UV)-induced mutability of one of these strains, UVs-7, and provide preliminary mutability data on two additional lines, UVr-23 and UVs-40. UVs-7 in extremely deficient in unscheduled DNA synthesis (UDS) but only slightly more sensitive to UV than the parental line. When examined for the UV-inducibility of mutants resistant to ouabain, 6-thioguanine, or diphtheria toxin, UVs-7 was found to be hypermutable at all three loci as compared to the parental line. The degree of hypermutability was not the same for any two loci. UVs-40, a highly UV-sensitive strain, was also found to be hypermutable at the ouabain-resistant (ouar) locus. UVr-23, which is UV-resistant and more proficient at UDS than the parental line, appeared to exhibit a tendency toward hypomutability at both the ouabain(ouar) and 6-thioguanine--resistant (6TGr) loci. Further characterization of all these lines should aid in delineating mammalian mechanisms of DNA repair and mutagenesis.

A novel synergistic effect of alanosine and guanine on adenine nucleotide synthesis in mammalian cells. Alanosine as a useful probe for investigating purine nucleotide metabolism

A novel synergistic effect of the antitumor agent alanosine (2-amino-3-(hydroxynitrosoamino) propionic acid), which specifically inhibits the enzyme adenylosuccinate synthetase (ASS) and guanine on the growth of Chinese hamster ovary (CHO) cells and human diploid fibroblasts (HDF) has been observed. In the presence of subinhibitory concentrations of alanosine, both CHO cells and the HDF show excessive sensitivity to exogenous guanine--a phenotype which closely resembles that seen with some of the mutants containing reduced enzymatic activity of ASS. The growth inhibitory effects of alanosine, or alanosine and guanine, on CHO cells are completely reverted by the addition of adenine to the culture medium, and the synergistic effect of guanine is not observed in mutants which lack the enzyme hypoxanthine-guanine phosphoribosyl transferase. These resuls suggest that guanine nucleotides exert a regulatory effect on the activity of the enzyme adenylosuccinate synthetase. The ability to confer the guanine-sensitive phenotype and its modulation by subinhibitory concentrations of alanosine in different cell types indicates that alanosine provides a useful probe for investigating the regulation of purine nucleotide metabolism in mammalian cells.

Diphtheria toxin resistance in Chinese hamster cells: genetic and biochemical characteristics of the mutants affected in protein synthesis

Diphtheria toxin (DT) resistant mutants (Dipr) have been isolated from a number of different Chinese hamster lines. Among mutants affected in protein synthesis (DiprII class), two distinct phenotypes have been identified. In one class, the entire elongation factor-2 (EF-2) activity becomes resistant to DT-catalyzed ADP-ribosylation (DiprIIa class); these mutants behave recessively upon hybridization with sensitive cells. The second kind of protein synthesis mutants contain nearly normal levels of the ADP-ribosylatable EF-2 activity (DiprIIb class). The hybrids the two types of protein synthesis mutants complement each other indicating that mutations in different genes are responsible for them. While the DiprIIa class of mutants are presumably affected in the EF-2, the lesion in DiprIIb mutants seems to have occurred in a yet unidentified protein synthesis factor. Interesting differences are also observed in the characteristics of mutants that presumably are defective in the entry of toxin into cells (DiprI class).

Senescence of cultured human diploid fibroblasts. Are mutations responsible?

Two predictions of the error/mutation hypothesis of cellular senescence (Orgel, '73) namely,a) exponential accumulation of somatic mutations during the replicative lifespan and b) shortening of culture lifespan upon treatment with mutagens have been examined experimentally in a strain of cultured human diploid fibroblasts. Our studies show that as cells traverse the replicative lifespan (from 10 to 75 mean population doublings (MPD); total lifespan congruent to 95 MPD), no rapid and exponential increase occurs in the accumulation of mutations measured by the frequencies of Thgr(thioguanine resistance) and Dipr (diphtheria toxin resistance) mutants. Furthermore, repeated cycles of treatment (from 1- to 14-times) of human fibroblasts with two mutagens, ethyl methane sulfonate (EMS) and N-methyl-N' nitro-nitrosoguanidine, which led to a marked increase in the mutation frequency for the Dipr marker (congruent to 100-fold), failed to shorten the lifespan of cultured fibroblasts. On the contrary, repeated mutagen treatment (12 times with EMS) prolonged the lifespan of one replicative culture (110 MPD versus 94--98 MPD). These results strongly indicate that mutations are unlikely to be the primary event in cellular senescence and suggest instead that senescence is probably controlled by one or more (specific) gene(s) whose expression can be modified by mutations.

DRB resistance in Chinese hamster and human cells: genetic and biochemical characteristics of the selection system

Stable mutants resistant to the nucleoside analog 5,6-dichloro-1-beta-D-ribofuranosyl benzimidazole (DRB), which interferes with RNA synthesis, have been selected in Chinese hamster ovary (CHO) and human diploid fibroblasts. In CHO cells, upon treatment with the mutagen ethyl-methane sulfonate (EMS), a linear dose--response between the concentration of mutagen and the frequency of DrbR mutants was observed in the range of 20--300 micrograms/ml. The selection system did not show cell density or cross-feeding effects, and the optimal expression time following mutagenesis was found to be 2--3 days for CHO cells and 5--6 days for human fibroblasts. The DrbR mutation behaved codominantly in DrbR x DrbS hybrids. Addition of DRB affected nucleoside uptake to a similar extent in both wild-type and mutant cells, indicating that the drug was able to enter the mutant cells. The failure of DrbR mutants to show any cross-resistance to other toxic nucleoside analogs examined suggests that the action of DRB does not involve the initial phosphorylation step. DRB addition did not cause any marked inhibition of either RNA polymerase I or RNA polymerase II activity from both wild-type and mutant cells in vitro, indicating that its effect on RNA synthesis may be indirect.

Pactamycin resistance in CHO cells: morphological changes induced by the drug in the wild-type and mutant cells

Stable mutants resistant to pactamycin (PacR), a polypeptide chain initiation inhibitor, have been selected in a single step in Chinese hamster ovary (CHO) cells. The sensitivity of protein synthesis in mutant cell extracts to pactamycin indicates that resistance involves an alteration in the permeability of this drug. The failure of PacR mutants to show cross-resistance to other compounds provides further indication that the lesion is presumably specific for pactamycin. Cell hybrids formed between PacR X PacS lines show intermediate sensitivity towards pactamycin, suggesting that the PacR lesion behaves codominantly under these conditions. In the presence of subinhibitory concentrations of pactamycin, CHO cells, which are normally short, polygonal and disoriented, became greatly elongated and aligned themselves in parallel fashion to produce highly oriented colony morphologies, reminiscent of normal diploid fibroblasts. This effect of pactamycin on cellular morphology was seen much more clearly with the PacR mutants, although somewhat higher concentrations of the drug were required to produce this change.

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.

Biochemical and genetic characterization of three hamster cell mutants resistant to diphtheria toxin

We describe here three different hamster cell mutants which are resistant to diphtheria toxin and which provide models for investigating some of the functions required by the toxin inactivates elongation factor 2 (EF-2). Cell-free extracts from mutants Dtx(r)-3 was codominant. The evidence suggests that the codominant phenotype is the result of a mutation in a gene coding for EF-2. The recessive phenotype might arise by alteration of an enzyme which modifies the structure of EF-2 so that it becomes a substrate for reaction with the toxin. Another mutant, Dtx(r)-2, contained EF-2 that was sensitive to the toxin and this phenotype was recessive. Pseudomonas aeruginosa exotoxin is known to inactivate EF-2 as does diphtheria toxin and we tested the mutants for cross-resistance to pseudomonas exotoxin. Dtx(r)-1 and Dtx(r)-3 were cross-resistant while Dtx(r)-2 was not. It is known that diphtheria toxin does not penetrate to the cytoplasm of mouse cells and that these cell have a naturally occurring phenotype of diphtheria toxin resistance. We fused each of the mutants with mouse 3T3 cells and measured the resistance. We fused each of the mutants with mouse 3T3 cells and measured the resistance of the hybrid cells to diphtheria toxin. Intraspecies hybrids containing the genome of mutants Dtx(r)-1 and Dtx(r)-3 had some resistance while those formed with Dtx(r)-2 were as sensitive as hybrids derived from fusions between wild-type hamster cells and mouse 3T3 cells.

Ultraviolet light induction of diphtheria toxin-resistant mutants of normal and xeroderma pigmentosum human fibroblasts

The UV induction of diphtheria toxin-resistant (DTr) mutants in normal and xeroderma pigmentosum human fibroblasts has been quantitatively characterized. A concentration of diphtheria toxin at which DTr cells are cross-resistant to Pseudomonas aeruginosa exotoxin A was determined and used in the selection of resistant mutants. Recovery of mutants was not influenced by the presence of wild-type cell densities of 1-8 x 10(5) per 9-cm plate, indicating no metabolic cooperation exists, in contrast to what is seen in the selection of some other variant phenotypes. Expression periods for UV-induced mutations differed with the severity of mutagen treatment and cell strain used. A relatively long (10-15 days after UV treatment) expression period was required for the maximum recovery of DTr mutants. Maximum recovery was followed by a decrease in mutation frequency on subsequent days evaluated. An apparent linear dose response within the dose range used was observed for UV-induced mutations in both normal and xeroderma pigmentosum fibroblasts. Our results indicate that xeroderma pigmentosum fibroblasts have higher UV-induced mutation frequencies per unit UV dose but similar frequencies per unit survival compared to normal cells within the range of UV doses tested.

Characterization of the diphtheria toxin-resistance system in Chinese hamster ovary cells

Variations in two general classes of diphtheria toxin-resistant mutants which may be selected from Chinese hamster ovary (CH0-K1) cells and the conditions for their selection are described. The resistance of class I mutants can be overcome with increasing concentrations of toxin. Their entire complement of EF-2 is susceptible to ADP-ribosylation by toxin. Class I includes those strains in which resistance resides at the level of the plasma membrane. The resistance of class II, translational, mutants cannot be overcome by high concentrations of toxin, as all, or a portion, of their EF-2 is insensitive to the action of diphtheria toxin and Pseudomonas exotoxin A. Adjustment of the concentration of toxin used to select resistant mutants can be used to regulate the class of mutant recovered. Metabolic cooperation between cells does not affect recovery of either class I or class II mutants. Resistance is stable in class I strains, but class IIb strains, which possess 50% resistant and 50% sensitive EF-2, display a transient high level of resistance which is retained for varying lengths of time following exposure to toxin. Class IIa strains, which possess 100% resistant EF-2, grow normally in saturating concentrations of toxin, but class IIb strains grow at a reduced rate. Evidence is presented which suggests that the gene for EF-2 is functionally diploid in CHO-K1 cells.

Diphtheria-toxin-resistant mutants of CHO cells affected in protein synthesis: a novel phenotype

Stable mutants highly resistant to the protein-synthesis-inhibitor diphtheria toxin have been selected in Chinese hamster ovary (CHO) cells. Protein synthesis in extracts of mutant cells is resistant to the inhibitory action of diphtheria toxin, indicating that the lesion has affected the protein-synthesis machinery. However, about 50% of the elongation factor-2 (EF-2) activity in the mutant cells can still be ADP-ribosylated by diphtheria toxin, and this remaining EF-2 activity is similar to that present in the wild-type cells. We suggest that this result is best explained by assuming that our CHO cells contain two functional copies of the EF-2 gene, and that only one of the copies is altered in the mutants. According to this view, the mutated allele produces EF-2 resistant to ADP-ribosylation which is capable of supporting cell growth in the presence of diphtheria toxin. Although the Dipr marker seems to act dominantly in the parental CHO cells, its behavior in Dipr X Dips hybrids (CHO X CHO) is recessive as measured by cell survival in presence of the toxin. This paradoxical behavior may be due to a gene dosage effect. Segregation studies from hybrids show that the Dipr marker segregates independently of the Emtr and Thgr markers indicating that the Dipr locus is not linked to either the Emtr locus or to the X chromosome.