The mouse lymphoma L5178Y Tk+/- cell line is heterozygous for a codon 170 mutation in the p53 tumor suppressor gene.

The p53 tumor suppressor protein plays an important role in regulating the cellular response to DNA damage, including cell cycle arrest and apoptosis induction. Normal p53 function is critical for the maintenance of genomic stability. The mouse lymphoma L5178Y/TK(+/-)-3.7.2C cell line is widely used in genetic toxicology for mutagenesis and clastogenesis testing. A related line L5178Y-R, has previously been shown to react with antibodies specific for mutant as well as wild-type p53 protein and to exhibit delayed cell death after radiation. For this reason, as well as the mouse lymphoma assay's reputation for high sensitivity of detection for genotoxic agents but low specificity, we examined several clones of L5178Y cells for mutations in the conserved core domain (exons 5-8) of the p53 gene. Using single-strand conformational polymorphism analysis, we found evidence for the same mutation in exon 5 of p53 in L5178Y-R, L5178Y-S and L5178Y/TK(+/+)-3.7.2C cells. The mutation was identified by sequencing of exon 5 as a TGC (Cys) to CGC (Arg) transition in codon 170 (= codon 176 in humans). Sequencing showed approximately equivalent signals for the mutant and normal alleles for all 3 lines. The mutation in codon 170 is adjacent to a mutation hotspot of the human p53 gene (codon 175) and eliminates a critical zinc-coordinating cysteine residue such that the mutant protein is likely to be denatured and have a dominant negative effect on normal p53 function. Western blots showed approximately 100-fold higher levels of p53 protein in unirradiated L5178Y cells as compared to induced levels of p53 in normal mouse splenocytes 4 h after 5 Gy of gamma radiation. The high levels of p53 protein in L5178Y cells were not further inducible by radiation, whereas an 11-fold induction was seen in the irradiated splenocytes. These results indicate that p53 protein in L5178Y cells is dysfunctional and suggest that this line may therefore be abnormally susceptible to the induction of genetic alterations.

Revalidation of the in vitro alkaline elution/rat hepatocyte assay for DNA damage: improved criteria for assessment of cytotoxicity and genotoxicity and results for 81 compounds.

The in vitro alkaline elution/rat hepatocyte assay is a sensitive assay for genotoxicity, measured as DNA strand breaks induced in primary cultures of rat hepatocytes after 3-h treatments with test compounds. Since DNA degradation can be rapid and extensive in dead and/or dying cells, the original criteria for a positive result in the assay were that a compound induce a 3.0-fold or greater increase in the elution slope (for the terminal phase of alkaline elution from 3 to 9 h) in the absence of significant cytotoxicity (defined as relative cell viability of less than 70% by trypan blue dye exclusion; TBDE). Recently we have shown that false-positive results can still be obtained due to cytotoxicity when loss of membrane integrity is a late event in toxic cell death relative to the induction of endonucleolytic DNA degradation. To improve the ability of the assay to discriminate between genotoxic vs. cytotoxic effects of chemicals, we have evaluated additional assays of cytotoxicity including cell adenosine triphosphate (ATP) and potassium (K+) content, tetrazolium dye reduction (MTT), TBDE after a further 3-h recovery incubation without test chemicals (delayed toxicity), cell blebbing and endonucleolytic DNA degradation (double-strand breaks; DSBs) assessed by pulsed-field gel electrophoresis (PFGE). We have also evaluated 2 parameters derived from the elution data which can indicate extensive, cytotoxicity-induced DNA degradation: the fraction of the DNA recovered in the neutral lysis/rinse fraction and the gamma-intercept of the extrapolation of the 3-9-h segment of the elution curve. Twenty-eight rodent non-carcinogens that are negative (or inconclusive) in the Ames assay with no, or limited, other evidence of genotoxicity, and 33 genotoxins, most of which are also carcinogens, were evaluated. The results showed that DNA degradation as measured by a 1-h PACE (Programmed Autonomously Controlled Electrodes)/PFGE assay was a sensitive indicator of cytotoxicity which correlated well with results of the other cytotoxicity indicators. The delayed TBDE (after a 3-h recovery), intracellular potassium and ATP assays as well as the gamma-intercept parameter were also shown to be sensitive and in some cases complementary measures of cytotoxicity. Using new criteria based on these data of an induced slope (treatment slope-negative control slope) of 0.020 for the 3- to 9-h elution period and cytotoxicity limits of 70% relative viability for the delayed TBDE assay and 50% for intracellular ATP content, the assay scores the genotoxicity of these 61 reference compounds with an overall accuracy of 92%. Test results using these new criteria are provided for an additional 20 compounds (5 non-genotoxic carcinogens and 15 compounds whose genotoxic and carcinogenic potential are unknown or equivocal).

The genetic toxicology of ethylenethiourea: a case study concerning the evaluation of a chemical's genotoxic potential.

Ethylenethiourea (ETU) is a metabolite, environmental degradation product and minor technical impurity of the ethylenebisdithiocarbamate (EBDC) class of fungicides. The genetic toxicology of ETU is important given that ETU causes thyroid tumors in rodents and liver tumors in mice. Although it is clear that ETU induces thyroid tumors via a non-genotoxic, threshold mechanism, the role ETU plays in inducing mouse liver tumors remains to be fully elucidated. Recently, Dearfield (Mutation Res., 317, 111-132, 1994) reviewed the genetic toxicology of ETU, and concluded that, although ETU is not a potent genotoxic agent, it is weakly genotoxic. This view stands in contrast to reports from several independent authorities that have generally concurred that ETU is not a mammalian genotoxin (IARC, 1987; MAFF, 1990; NTP, 1992; FAO/WHO, 1994). These conflicting reports highlight a generic problem in genotoxicity safety assessment: although individual test results typically yield either a positive or negative response, the overall evaluation of an extensive battery of tests for a particular chemical rarely yields an unambiguous conclusion. Recently, Mendelsohn et al. (Mutation Res., 266, 43-60, 1992) showed that the response of a chemical to a battery of genotoxicity tests is not a dichotomous (i.e., either positive or negative) property, but rather, appears to be a continuous property that ranges from strongly negative to strongly positive. We have used these data, together with a four-step weight of the evidence procedure, to evaluate ETU. Our analysis indicates that ETU is not genotoxic in mammalian systems and suggests that ETU likely induces mouse liver tumors by a non-genotoxic mechanism.

Rapid DNA degradation in primary rat hepatocytes treated with diverse cytotoxic chemicals: analysis by pulsed field gel electrophoresis and implications for alkaline elution assays.

The use of genetic toxicology tests for hazard identification is complicated by the fact that some in vitro tests using cultured mammalian cells are subject to potential artifacts that can make it difficult to distinguish between direct, chemically-induced genotoxicity, and DNA damage that occurs secondary to chemically-induced cytotoxicity (e.g., mediated by endogenous nucleases). Recently, we demonstrated that cytotoxicity-induced DNA double strand breaks (dsb) can produce artifacts in the in vitro alkaline elution/rat hepatocyte assay [Elia et al., 1993]. To explore this further, we used pulsed field gel/DNA dsb assays to characterize the relationship between chemically-induced cytotoxicity and the degradation of genomic DNA to high molecular weight fragments. Two sets of compounds were tested: 17 cytotoxic agents judged to be neither genotoxic nor carcinogenic, and 10 known genotoxic carcinogens. We found a close correlation between chemically-induced cytotoxicity and the rapid degradation of DNA to high molecular weight, double-stranded fragments. In contrast, the classic genotoxic chemicals tested generally did not trigger DNA dsb fragmentation at doses that were genotoxic but not immediately cytotoxic. These data indicate that pulsed field gel/DNA dsb assays can be used with in vitro genetic toxicology assays to help distinguish between genotoxic and cytotoxic mechanisms of DNA damage.

Cytotoxicity as measured by trypan blue as a potentially confounding variable in the in vitro alkaline elution/rat hepatocyte assay.

Rat hepatocytes treated in vitro with A2RA, an angiotensin II receptor antagonist, displayed an increased level of DNA-strand breaks as determined by alkaline elution, without an appreciable increase in cytotoxicity as determined by a trypan blue dye exclusion assay at harvest. The alkaline elution profile appeared to have two components: a rapidly eluting component detected in the first fraction collected (often associated with DNA from dead or dying cells), followed by a more slowly eluting component detected in the subsequent fractions. Further analysis of hepatocytes treated with A2RA by pulsed-field gel electrophoresis and neutral elution revealed significant levels of DNA double-strand breaks. Electron microscopy (EM) showed pronounced damage to mitochondria; although cell blebbing was seen using both EM and light microscopy, the plasma and nuclear membranes appeared intact when examined by EM. Cellular ATP levels decreased precipitously with increasing doses of A2RA, falling to less than 10% of control values at a dose of 0.213 mM A2RA, a concentration showing 100% relative viability by trypan blue at harvest. Thus, whereas in our experience trypan blue dye exclusion accurately reflects cytotoxicity induced by the majority of test agents, in this rather unusual case, trypan blue did not accurately reflect compound-induced cytotoxicity at harvest since there was no concurrent loss of membrane integrity. However, when hepatocytes treated with A2RA were incubated for either 3 h or 20 h in the absence of compound, a sharp, dose-dependent decline in viability was observed using trypan blue dye exclusion. Together with the initial, dose-dependent drop in the alkaline elution curve, these data suggest that the observed DNA double-strand breaks arose as a consequence of endonucleolytic DNA degradation associated with cytotoxicity, rather than by a direct compound-DNA interaction. Since DNA double-strand breaks behave under alkaline denaturing conditions as two single-strand breaks and can therefore produce increases in the alkaline-elution slope values, a necessary criteria for a valid positive result in this assay is that cytotoxicity by trypan blue dye exclusion will not be greater than 30%. Our data, however, indicate that interpretation of the elution assay as a test for genotoxicity can still be confounded by the failure of the trypan blue dye exclusion assay to reflect cytotoxicity in the unusual instance when there is no concurrent, immediate loss of membrane integrity.

Application of programmable, autonomously controlled electrode (PACE) technology to the development of an improved pulsed field gel electrophoresis assay for DNA double-strand breaks in mammalian cells.

PACE (programmable, autonomously controlled electrodes) pulsed field gel electrophoresis technology was used to develop a DNA double-strand break assay that simultaneously combined (1) resolution across a broad range of DNA sizes, (2) high sensitivity (in terms of detecting dsb at low doses) and (3) speed. A 48 h PACE/dsb assay resolves DNA fragments ranging in size from 0.2 to 6 Mb, and detects damage induced by as little as 2 Gy of gamma-radiation. A different set of electrophoretic conditions resolves DNA between 1.5 and 6 megabases in 23 h, with a detection limit of about 5 Gy. A third electrophoretic protocol, while not resolving DNA fragments greater than 50 kb in length, detects DNA dsb in CHO cells induced by 15 Gy or more of gamma-rays after only a 1 h run. In particular, the 48 h PACE/dsb assay should prove useful in studies aimed at understanding the mechanisms whereby a variety of biological, chemical and physical agents induce DNA dsb in eukaryotes.

Influence of chromatin structure on the induction of DNA double strand breaks by ionizing radiation.

Pulsed field gel electrophoresis was used to examine the influence of chromatin structure on the induction of DNA double strand breaks by gamma-irradiation in CHO-WBL cells, nuclei, and a series of protein-depleted chromatin substrates. We developed a method to isolate intact nuclei in agarose plugs that avoids DNA shearing and nucleolytic degradation during sample preparation, and facilitates nuclear protein extraction. Agarose plug-isolated nuclei are extracted with increasing concentrations of NaCl to selectively strip off: (a) nonhistone chromosomal proteins (NHP); (b) NHP and histone H1; (c) NHP, H1, and histone H2A-H2B dimers; or (d) NHP, H1, and H2A-H2B dimers and histone H3-H4 tetramers. Following treatment with up to 40 Gy of gamma-radiation, DNA from each sample is purified and the relative induction of DNA double strand breaks is assayed by asymmetric field inversion gel electrophoresis. At a dose of 20 Gy, removal of nonhistone proteins from nuclei results in a 3-fold increase in DNA double strand breaks, compared to intact CHO cells. Additional stripping of histone H1 results in an incremental increase in double strand break induction, whereas further removal of H2A-H2B dimers yields a greater than 10-fold increase in DNA double strand breaks compared to intact CHO cells. The dose-response profile for this latter sample is similar to that observed for purified DNA. These data indicate that distinct classes of chromosomal proteins afford the DNA with different levels of protection against gamma-ray-induced DNA double strand breaks. Thus, chromatin domains that differ in tertiary structure and protein composition may also differ in their susceptibility to DNA double strand breaks induced by ionizing radiation and, perhaps, other clastogens.

Electrotransfer of [32P]NAD allows labeling of ADP-ribosylated proteins in intact Chinese hamster ovary cells.

CHO-K1D cells electroporated in buffers containing [32P]NAD incorporated the label in a voltage-dependent manner. Electroporation with 650 V/cm at 1460 microF in Ham's F12 medium supplemented with 10 mM Hepes, pH 7.1, resulted in a greater than 20-fold increase in [32P]NAD uptake, while decreasing relative cellular survival by only 6%. Exposure of cells to gamma irradiation (20 Gy) prior to electroporation increased the steady-state level of poly(ADP-ribosylated) nuclear proteins two- to four-fold over that of unirradiated control cells. These data indicate that electrotransfer of [32P]NAD is a simple and rapid means of labeling the cellular NAD pool and should prove useful in the analysis of the relationship between poly(ADP-ribosylation) of nuclear proteins and DNA repair.

Significance and measurement of DNA double strand breaks in mammalian cells.

Techniques for measuring DNA double strand breaks in mammalian cells are being used increasingly by researchers studying both physiological processes, such as recombination, replication, and apoptosis, as well as pathological processes, such as clastogenesis induced by ionizing radiation, chemotherapeutic drugs, and chemical toxicants. In this review we evaluate commonly used assays for measuring DNA double strand breaks, focusing on neutral filter elution and pulsed field gel electrophoresis, and explore the advantages and limitations of applying these techniques to problems of current interest in carcinogenesis and genetic toxicology.

H2a-specific proteolysis as a unique probe in the analysis of the histone octamer.

We have utilized the H2a-specific protease as a unique probe to investigate the nature of the interactions between the protein subunits which form the core histone octamer. Upon incubation in high ionic strength media this protease, normally found tightly associated with isolated calf thymus chromatin, releases the 15 COOH-terminal amino acids of histone H2a by specifically cleaving the H2a polypeptide between Val114 and Leu115, yielding cleaved H2a (cH2a) and a free pentadecapeptide (Eickbush, T. H., Watson, D. K., and Moudrianakis, E. N. (1976) Cell 9, 785-792). We find that removal of this pentadecapeptide results in a marked dissociation of the octamer into its H2a:H2b dimer and H3:H4 tetramer subunits. Reconstitution experiments indicate that cH2a is capable of forming a dimer with H2b, but this cH2a:H2b dimer has a substantially lower affinity for the H3:H4 tetramer than native H2a:H2b dimer. Kinetic studies of H2a cleavage in high ionic strength solutions demonstrate that H2a molecules in the octamer are relatively resistant to proteolytic attack compared to H2a molecules in the dimer. The extent of this resistance, in response to various experimental parameters, is directly correlated to the strength of interaction between the H2a:H2b dimer and H3:H4 tetramer subunits. These reconstitution and kinetic experiments suggest that the histone domains proximal to the H2a cleavage site have an important function in maintaining the association of the histone octamer subunits.

Regulation of H2a-specific proteolysis by the histone H3:H4 tetramer.

We have studied the limited cleavage of H2a in the H2a:H2b histone dimer by the H2a-specific protease under physiological conditions (neutral pH, 0.1 M NaCl) using a variety of histone-DNA reconstitutes as substrates and/or regulators of the partially purified enzyme. Under these conditions the protease cleaves H2a in "native" dimer-DNA reconstitutes but not in "native" octamer-DNA reconstitutes. Treatment of the enzyme with saturating amounts of H3:H4 tetramer-DNA prior to addition of dimer-DNA substrate results in complete inhibition of H2a-specific proteolysis. Sucrose gradient sedimentation experiments indicate that the protease binds reversibly to tetramer-DNA and that this leads to the reversible inhibition of enzymatic activity. Using three different tetramer-DNA complexes, we found native tetramer-DNA to be a more effective inhibitor than either trypsin-treated tetramer-DNA or acetylated tetramer-DNA. We conclude that under physiological conditions, the H2a-specific protease binds primarily to the highly basic amino-terminal domain of the H3:H4 tetramer, and this binding lowers the effective concentration of enzyme available to cleave H2a. Although no cleaved H2a is produced when protease is mixed with native octamer-DNA, incubation of the enzyme with acetylated octamer-DNA results in H2a-specific proteolysis. This is the first demonstration that the H2a-specific protease activity can be modulated by a physiologically relevant process (e.g. histone acetylation). We propose that the sequestered protease may be functionally regulated in vivo through reversible post-translational modifications to the NH2-terminal domains of the histone H3:H4 tetramer.