An analysis of the interaction of a platinum complex and radiation with CHO cells using the molecular theory of cell survival.

A mathematical analysis is developed from the concepts of the molecular theory of cell survival to explain the cytotoxic action of a platinum complex on CHO cells and its synergistic interaction with radiation. In the analysis, it is assumed that both inter- and intra-strand cross-links induced by the Pt complex in the DNA contribute to cell killing and that the synergistic effect arises from the interaction between an intra-strand cross-link and a radiation-induced single-strand break on complementary strands of the DNA. The analysis is shown to be compatible with experimental results. Further, a mechanistic model is developed in an attempt to explain in more detail the processes which appear to be involved in the expression of the cytological damage.     

Regulation of endonuclease activity in human nucleotide excision repair

Nucleotide excision repair (NER) is a DNA repair pathway that is responsible for removing a variety of lesions caused by harmful UV light, chemical carcinogens, and environmental mutagens from DNA. NER involves the concerted action of over 30 proteins that sequentially recognize a lesion, excise it in the form of an oligonucleotide, and fill in the resulting gap by repair synthesis. ERCC1-XPF and XPG are structure-specific endonucleases responsible for carrying out the incisions 5' and 3' to the damage respectively, culminating in the release of the damaged oligonucleotide. This review focuses on the recent work that led to a greater understanding of how the activities of ERCC1-XPF and XPG are regulated in NER to prevent unwanted cuts in DNA or the persistence of gaps after incision that could result in harmful, cytotoxic DNA structures.     

Topoisomerase-targeting antitumor drugs

Much has been learned about the unusual type of DNA damage produced by the topoisomerases. The mechanism by which these lesions trigger cell death, however, remains unclear, but it appears that DNA metabolic machinery transforms reversible single-strand cleavable complexes to overt strand breaks which may be an initial event in the cytotoxic pathway. For the topoisomerase I poisons, they produce breaks at replication forks that appear to be the equivalent of a break in duplex DNA. Indicating that this may be an important cytotoxic lesion is the hypersensitivity to camptothecin of the yeast mutant rad52, which is deficient in double-strand-break-repair. The topoisomerase poisons preferentially kill proliferating cells. In the case of the topoisomerase I poison camptothecin, dramatic S-phase-specific cytotoxicity can explain its preferential action on proliferating cells. For the topoisomerase II poisons, high levels of the enzyme in proliferating cells, and very low levels in quiescent cells appear to explain the resistance of quiescent cells to the drug's cytotoxic effects. Thus, the topoisomerase poisons convert essential enzymes into intracellular, proliferating-cell toxins. The identification of both topoisomerase I and II as the specific targets of cancer chemotherapeutic drugs now provides a rational basis for the development of topoisomerase I poisons for possible clinical use. Knowledge of the molecular mechanisms of cell killing may lead to the identification of new therapies for treating cancer. The topoisomerase poisons appear to be a good tool for studying cell killing mechanisms as they produce highly specific and reversible lesions.     

Interplay of DNA repair pathways controls methylation damage toxicity in Saccharomyces cerevisiae

Methylating agents of S(N)1 type are widely used in cancer chemotherapy, but their mode of action is poorly understood. In particular, it is unclear how the primary cytotoxic lesion, O(6)-methylguanine ((Me)G), causes cell death. One hypothesis stipulates that binding of mismatch repair (MMR) proteins to (Me)G/T mispairs arising during DNA replication triggers cell-cycle arrest and cell death. An alternative hypothesis posits that (Me)G cytotoxicity is linked to futile processing of (Me)G-containing base pairs by the MMR system. In this study, we provide compelling genetic evidence in support of the latter hypothesis. Treatment of 4644 deletion mutants of Saccharomyces cerevisiae with the prototypic S(N)1-type methylating agent N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) identified MMR as the only pathway that sensitizes cells to MNNG. In contrast, homologous recombination (HR), postreplicative repair, DNA helicases, and chromatin maintenance factors protect yeast cells against the cytotoxicity of this chemical. Notably, DNA damage signaling proteins played a protective rather than sensitizing role in the MNNG response. Taken together, this evidence demonstrates that (Me)G-containing lesions in yeast must be processed to be cytotoxic.     

Effects of DNA damaging agents on cultured fibroblasts derived from patients with Cockayne syndrome.

The cytotoxic action of physical and chemical agents on 10 skin fibroblast strains in culture derived from individuals with Cockayne's syndrome was measured in terms of colony-forming ability. As compared to fibroblasts from normal donors, all Cockayne cell strains tested exhibited a significantly increased sensitivity to UV light and a normal sensitivity to X-rays. Cells from two sets of parents of unrelated Cockayne children showed an intermediate level of UV sensitivity. There was no effect of 0.5 mM caffeine on UV survival in normal and two Cockayne strains tested, indicating that postreplicational repair in Cockayne cells as measured by caffeine sensitivity was probably normal. Sensitivity of normal and Cockayne cells to the chemical carcinogens and mutagens 4NQO, N-AcO-AAF, ICR-170 and EMS was also compared. An increased sensitivity of Cockayne cells to 4NQO or N-AcO-AAF, but not the ICR-170 or EMS, was observed. However, unlike the intermediate UV sensitivity, the cell strains from two parents of Cockayne patients showed the same sensitivity to N-AcO-AAF or 4NQO as fibroblasts from normal individuals. Quantiation of damage to the DNA after 20 J . m-2 UV irradiation indicates normal levels of [3H] thymidine incorporation in the Cockayne cells, in contrast to UV-irradiated xeroderma pigmentosum cells (XP 12BE) in which there was a very low level of repari synthesis. Moreover, we have shown previously that excision of UV-induced pyrimidine dimers in 2 of the 10 Cockayne cell strains was normal.     

Model-Based Statistical Procedures for the Analysis of in Vitro Mutagenesis Assays

A number of short-term screening assays for potential chemical carcinogens and mutagens involve the measurement of mutation rates in in vitro cell populations. In this paper, statistical procedures are proposed for the analysis of results from these assays. The procedures, which are based on previously developed stochastic models of cell growth and mutation, include hypothesis tests for the comparison of mutation rates in treated and control cultures, and estimation and hypothesis tests for the parameters of a linear mutagenesis dose-response. Computer simulation is used to validate the methods, and they are illustrated by an analysis of data obtained under the mouse lymphoma mutagenesis protocol.     

Mutagenic action of dimethyl sulfate and N-nitrosoethylurea on the mulberry silkworm

Mutagenic effect of chemical mutagens, dimethalsulphate (DMS) and N-nitrosoethyl urea (NEU), on silkworm is studied. The effect of these mutagens have never been studied on silkworm before. DMS is found to be completely insufficient as mutagen for the silkworm, because its low mutability is accompanied with strong cytotoxic effect. NEU appeared to be of "milder" effect. Injection of male-moth proved to be very efficient. The majority of exuded mutants showed mosaic colouring of the graine.     

Prediction for Target Sites of Small Interfering RNA Duplexes in SARS Coronavirus

High doses of ionizing irradiation and chemical mutagens induce random mutations and chromosome aberrations in cells of affected organisms and cause acute symptoms, delayed increased risk of cancer and accelerated aging. The mechanism of disease development remains unclear and no treatment exists for consequences of the mutagenic damage. We have proposed recently that extracellular genomic DNA from tissue fluids of a healthy organism, innate receptor-mediated nuclear delivery of this DNA, and its homologous recombination with cellular genomic sequences might function concertedly as a natural proofreading mechanism for somatic cell genomes. Here we hypothesize that cells dying from irradiation or chemical mutagens release heavily damaged DNA fragments that propagate mutations and chromosome aberrations to DNA-recipient cells via this mechanism, inducing cell death and release of their mutated DNA again into the bloodstream. The repeated release of the mutated DNA followed by its incorporation into cellular genomes would spread mutational damage in the affected organism, thus making this DNA the etiologic agent of either radiation sickness or post-mutagen exposure syndrome. The hypothesis opens a possibility to inhibit and treat the disease via administration of non-mutated genomic DNA fragments that would compete with the circulating mutant DNA fragments, entering cells in greater numbers, leading to replacement of mutant segments in cellular genomes. Injection of fragmented mouse DNA, but not human DNA, into lethally irradiated mice dramatically increased their survival. Similarly, the mouse DNA was more potent than human and salmon DNA in accelerating recovery of the normal leukocyte level in mice treated with the chemical mutagen cyclophosphamide. The species specificity of the DNA therapy suggests that the genomic sequences are the agent producing the effects.     

Modification of DNA repair by human interferons

We have found a new biological function of interferons, namely, their capacity to protect human cells from the action of some physical and chemical mutagens. To evaluate the protective effect of interferons the following criteria were applied: formation of sister chromatid exchanges (SCE) and chromosomal aberrations (CA), as well as viability of cells and intensity of DNA repair synthesis. Pretreatment of cells with natural interferon decreased the number of sister chromatid exchanges and chromosomal aberrations, induced by different mutagens, and increased the intensity of DNA repair synthesis. This is attributed to the ability of interferon to enhance certain phases of DNA repair. In the case of photomutagenic action of 8-methoxypsoralen (8-MOP) on the lymphocytes, when monoadducts (MA) only, or both monoadducts and interstrand cross-links (ICL) are formed, the antimutagenic effect of interferon is exhibited only with respect to ICL. Unlike the natural interferon, the recombinant alpha 2-interferon failed to have any effect on the lymphocytes of clinically healthy donors exposed to gamma-radiation. In the repair- deficient cells (Marfan's syndrome) the protection of natural interferon against the action of 4-nitroquinoline-1'-oxide and gamma- radiation was found to be reduced significantly and that of alpha 2-interferon was not manifested at all. Thus, the capacity of interferons to alter the DNA repair, conceivably, depends on the type of interferon and on the cell genotype.     

The nature of unbalanced cell growth caused by cytotoxic agents

The volume of cells grown in tissue culture following exposure to a wide variety of cytotoxic drugs or x-rays increases at a rate of 1 to 10% of cell mass per hour. The same phenomenon is seen in animal neoplasias and human leukemias. This increase in cell volume is the result of unbalanced cell growth with a resulting disproportionate synthesis of proteins and possibly other macromolecules in the cytoplasm and nucleus. The dose response curve for a decrease in cell survival as measured by cloning efficiency in tissue culture is quantitatively correlated with the dose response curve for inducing an increase in cell volume. This quantitative relationship makes feasible the use of the phenomenon of unbalanced cell growth as a measure of cell death in screening for cytotoxic drugs or in monitoring response to therapy. An hypothesis to explain this increase in cell volume following chemotherapy is that cells are by the action of these drugs induced into an abortive or unbalanced pseudo-cycle which is characterized by synthesis of substantial amounts of protein without other preparative steps for cell division.     

DNA damage and repair in human lymphocytes under the activation of molecular oxygen

It was shown that activation of molecular oxygen by Fe2+ in the presence of ascorbate is a caise of human lymphocyte DNA damage. The level of DNA damage caused by activation of oxygen is comparable with the effect of high doses of chemical mutagens. DNA damage is linked with action of activated oxygen but not with generation of lipid radicals. Vitamin E (alpha-tocopherol) added to lymphocytes prevents partly the damaging action of activated oxygen on DNA.     

Unmasking a killer: DNA O(6)-methylguanine and the cytotoxicity of methylating agents

Methylating agents are potent carcinogens that are mutagenic and cytotoxic towards bacteria and mammalian cells. Their effects can be ascribed to an ability to modify DNA covalently. Pioneering studies of the chemical reactivity of methylating agents towards DNA components and their effectiveness as animal carcinogens identified O(6)-methylguanine (O(6)meG) as a potentially important DNA lesion. Subsequent analysis of the effects of methylating carcinogens in bacteria and cultured mammalian cells - including the discovery of the inducible adaptive response to alkylating agents in Escherichia coli - have defined the contributions of O(6)meG and other methylated DNA bases to the biological effects of these chemicals. More recently, the role of O(6)meG in killing mammalian cells has been revealed by the lethal interaction between persistent DNA O(6)meG and the mismatch repair pathway. Here, we briefly review the results which led to the identification of the biological consequences of persistent DNA O(6)meG. We consider the possible consequences for a human cell of chronic exposure to low levels of a methylating agent. Such exposure may increase the probability that the cell's mismatch repair pathway becomes inactive. Loss of mismatch repair predisposes the cell to mutation induction, not only through uncorrected replication errors but also by methylating agents and other mutagens.     

Antibody-dependent harmful effect of non-immune spleen cells in acute experimental tick-borne encephalitis in mice

The injection of nonprotective dilutions of immune serum and nonimmune spleen cells into mice infected with tick-borne encephalitis virus induced a sharply pronounced immunopathological effect: the mean survival time of the recipients decreased by 3.6 days in comparison with the control animals. This effect was not linked with the increased replication of the virus in the brain. The antibody-dependent damaging action of spleen cells could be reproduced by using the cells of both syngeneic and allogeneic donors. This phenomenon developed only in those cases when antibodies to the infective agent under study were used. The combination of immune serum to Japanese encephalitis virus and nonimmune spleen cells produced no damaging effect. The hypothesis stating that the antibody-dependent damaging action of nonimmune spleen cells arises from the antibody-dependent cytotoxic action of immunocompetent cells on the infected cells of the central nervous system is discussed.     

Abasic DNA structure, reactivity, and recognition

Loss of a base in DNA, i.e., creation of an abasic site leaving a deoxyribose residue in the strand, is a frequent lesion that may occur spontaneously, or under the action of radiations and alkylating agents, or enzymatically as an intermediate in the repair of modified or abnormal bases. The abasic site lesion is mutagenic or lethal if not repaired. From a chemical point of view,the abasic site is an alkali-labile residue that leads to strand breakage through beta- and delta- elimination. Progress in the understanding of the chemistry and enzymology of abasic DNA largely relies upon the study of synthetic abasic duplexes. Several efficient synthetic methods have thus been developed to introduce the lesion (or a stable analogue) at defined position in the sequence. Physicochemical and spectroscopic examination of such duplexes, including calorimetry, melting temperature, high-field nmr and molecular modeling indicate that the lesion strongly destabilizes the duplex, although remaining in the canonical B-form with structural modifications strictly located at the site of the lesion. Probes have been developed to titrate the damage in DNA in vitro. Series of molecules have been devised to recognize specifically the abasic site, exhibiting a cleavage activity and mimicking the AP nucleases. Others have been prepared that bind strongly to the abasic site and show promise in potentiating the cytotoxic and antitumor activity of the clinically used nitrosourea (bis-chloroethylnitrosurea).     

Fluoride: interaction with chemical mutagens in Drosophila

Simultaneous feeding of sodium fluoride and some chemical mutagens to Drosophila has been reported to reduce the yield of induced mutations compared with feeding the mutagens alone. This observation has been interpreted as a genuine case of antimutagenesis in which fluoride specifically inhibits the induction of chromosome breaks. An alternative hypothesis is that the presence of fluoride inhibits the uptake of the mutagen solutions, producing the same effect as an antimutagen, but for a trivial reason. We have tested this hypothesis using radioactive labelled sucrose to measure the uptake of test solutions. The results show that differential uptake can account for the "antimutagenic" effects reported in Drosophila. Comparison of recessive lethal frequencies induced by Trenimon and PDT do not support the hypothesis that fluoride has any genuine antimutagenic action. Antimutagenic effects of fluoride have been reported in other systems. We cannot exclude the possibility of some genuine effects but we consider that these reports should be critically re-examined in the light of our present findings.     

Cytotoxic activity of 2',2'-difluorodeoxycytidine, 5-aza-2'-deoxycytidine and cytosine arabinoside in cells transduced with deoxycytidine kinase gene

Deoxycytidine nucleoside analogs must be first phosphorylated to become active anticancer drugs. The rate-limiting enzyme in this pathway is deoxycytidine kinase (dCK). Cells deficient in this enzyme are resistant to these analogs. To evaluate the potential of dCK to be used as suicide gene for deoxycytidine nucleoside analogs, we transduced both human A-549 lung carcinoma and murine NIH3T3 fibroblast cell lines with this gene. The dCK-transduced cells showed an increase in cytotoxicity to the analogs, cytosine arabinoside (ARA-C), and 5-aza-2'-deoxycytidine (5-AZA-CdR). Unexpectedly, the related analog, 2',2'-difluorodeoxycytidine (dFdC), was less cytotoxic to the dCK-transduced cells than the wild-type cells. For the A-549-dCK cells, the phosphorylation of dFdC by dCK was much greater than control cells. In accord with the elevated enzyme activity, we observed a 6-fold increased dFdC incorporation into DNA and a more pronounced inhibition of DNA synthesis in the A-549-dCK cells. In an attempt to clarify the mechanism of dFdC, we investigated its action on A549 and 3T3 cells transduced with both cytidine deaminase (CD) and dCK. We reported previously that overexpression of CD confers drug resistance to deoxycytidine analogs. In this study, when the CD-transduced cells were also transduced with dCK they became relatively more sensitive to dFdC. In addition, we observed that dFdU, the deaminated form of dFdC, was cytotoxic to the A-549-dCK cells, but not the wild-type cells. Our working hypothesis to explain these results is that the mitochondrial thymidine kinase (TK2), an enzyme reported to phosphorylate dFdC, acts as an important modulator of dFdC-induced cell toxicity. These findings may further clarify the action of dFdC and the mechanism by which it induces cell death.     

Antioxidant activity of diphenyl diselenide prevents the genotoxicity of several mutagens in Chinese hamster V79 cells

Diphenyl diselenide (DPDS) is an electrophilic reagent used in the synthesis of a variety of pharmacologically active organic selenium compounds. Studies have shown its antioxidant, hepatoprotective, neuroprotective, anti-inflammatory, and antinociceptive effects. We recently showed the antioxidant effect of DPDS in V79 cells, and established the beneficial and toxic doses of this compound in this cell line. Here, we report the antigenotoxic and antimutagenic properties of DPDS, investigated by using a permanent lung fibroblast cell line derived from Chinese hamsters. We determined the cytotoxicity by clonal survival assay, and evaluated DNA damage in response to several mutagens by comet assay and micronucleus test in binucleated cells. In the clonal survival assay, at concentrations ranging from 1.62 to 12.5microM, DPDS was not cytotoxic, while at concentrations up to 25microM, it significantly decreased survival. The treatment with this organoselenium compound at non-cytotoxic dose range increased cell survival after challenge with hydrogen peroxide, methyl-methanesulphonate, and UVC radiation, but did not protect against 8-methoxypsoralen plus UVA-induced cytotoxicity. In addition, the treatment prevented induced DNA damage, as verified in the comet assay. The mutagenic effect of these genotoxins, as measured by the micronucleus test, similarly attenuated or prevented cytotoxicity and DNA damage. Treatment with DPDS also decreased lipid peroxidation levels after exposure to hydrogen peroxide MMS, and UVC radiation, and increased glutathione peroxidase activity in the extracts. Our results clearly demonstrate that DPDS at low concentrations presents antimutagenic properties, which are most probably due to its antioxidant properties.     

Establishment of epithelial cell lines from adult mouse regenerating liver

A simple technique for developing epithelial cell lines from regenerating mouse liver has been described. Twenty-one epithelial cell lines have been developed and can be divided into four groups according to their morphology. All these near diploid cell lines have the capacity to metabolize diverse classes of chemical carcinogens (3-methylcholanthrene, 2-acetylaminofluorene, dimethylnitrosamine and aflatoxin B1) to cytotoxic metabolites. It is not yet possible to determine which ones of these cell lines originated from hepatocytes. Studies are in progress to further characterize and to use these cell lines as lethally irradiated feeder layers for cell-mediated activation of various classes of chemical carcinogens and mutagens with C3H/10T1/2 mouse embryo fibroblasts as indicator cells.     

DNA single-strand breaks,double-strand breaks,and crosslinks in rat testicular germ cells: Measurements of their formation and repair by alkaline and neutral filter elution

This work describes a neutral and alkaline elution method for measuring DNA single-strand breaks (SSBs), DNA double-strand breaks (DSBs), and DNA-DNA crosslinks in rat testicular germ cells after treatments in vivo or in vitro with both chemical mutagens and gamma-irradiation. The methods depend upon the isolation of testicular germ cells by collagenase and trypsin digestion, followed by filtration and centrifugation. ¹³⁷Cs irradiation induced both DNA SSBs and DSBs in germ cells held on ice in vitro. Irradiation of the whole animal indicated that both types of DNA breaks are induced in vivo and can be repaired. A number of germ cell mutagens induced either DNA SSBs, DSBs, or cross-links after in vivo and in vitro dosing. These chemicals included methyl methane sulfonate, ethyl methane sulfonate, ethyl nitrosurea, dibromochlorpropane, ethylene dibromide, triethylene melamine, and mitomycin C. These results suggest that the blood-testes barrier is relatively ineffective for these mutagens, which may explain in part their in vivo mutagenic potency.This assay should be a useful screen for detecting chemical attack upon male germ-cell DNA and thus, it should help in the assessment of the mutagenic risk of chemicals. In addition, this approach can be used to study the processes of SSB, DSB, and crosslink repair in DNA of male germ cells, either from all stages or specific stages of development.Abbreviations DBCP dibromochlorpropane - DSB(s) DNA double-strand break(s) - EDB ethylene dibromide - EMS ethyl methane sulfonate - ENU ethyl nitrosurea - MC mitomycin C - MMS methyl methane sulfonate - SDS sodium dodecyl sulfate - SSB (s) DNA single-strand break(s) - TEM triethylene melamine - UDS unscheduled DNA synthesis