Nonstochastic heritable cell lethality in the practice of biotesting of man-made pollutants as inducers of aftereffects

A nonstochastic heritable cell lethality effect was for the first time used in the practice of biotesting in a model of Saccharomyces yeasts for predicting the hazard of low mutagen doses. It was demonstrated that the heritable cell lethality might be induced by multicomponent mutagens of a technogenic nature, for example, sewage waters of gas-transferring plants. The possibility of extrapolation of the results to multicellular organisms is discussed.     

Heritable translocation test on random-bred mice after prolonged triethylenemelamine treatment.

Heritable translocation and dominant lethal tests were conducted with random-bred Swiss albino male mice. The animals were provided drinking water containing triethylenemelamine (TEM) for 4 weeks, and were then mated for 3 successive weeks for analysis of dominant lethality and production of F1 progeny. Potential translocation carriers among F1 males were selected after two breedings and confirmed by cytogenetic analysis. Translocation heterozygotes were obtained in offspring of the TEM-treated groups, but not in the control groups. In F1 males produced from the first week of mating, the frequencies of translocations were 0, 1.78 6.2 and 10.0% for the control group and groups receiving TEM at 0.0125, 0.025 and 0.050 mg/kg/day, respectively, and in those produced from the third week of mating, the values were 0 and 2.1%, respectively, for the control group and the group receiving TEM at 0.050 mg/kg/day. F1 males from the second week of mating were not studied for the induction of heritable translocations. TEM-induced dominant lethality and heritable translocations were most prominent in the first week of mating after 4 weeks of treatment. In addition, heritable translocations appeared to be a more sensitive endpoint than dominant lethal mutations for the measurement of mutagenic effects of TEM.     

Facile induction of apoptosis into plant cells associated with temperature-sensitive lethality shown on interspecific hybrid from the cross Nicotiana suaveolens x N. tabacum

Two lines of suspension culture cells were obtained from a hybrid seedling of Nicotiana suaveolens Lehm. x N. tabacum L. cv. Hicks-2 expressing temperature-sensitive lethality. One of them (LH line) was inducible cell death in accordance with the lethality at 28 degrees C but not under high-temperature conditions (36 degrees C). Another one (SH line) lost the lethality and survived at 28 degrees C. The cells of LH line showed apoptotic changes when they were cultured at 28 degrees C. Fragmentation of nuclei was correlated with the lethality in the cells, as confirmed by fluorimetry of the nuclear DNA using laser scanning cytometry. Agarose gel analysis of DNA extracted from the cells expressing the lethality revealed a specific ladder pattern suggesting nucleosomal fragmentation that is one of the biochemical characteristics of apoptosis. From these facts, we confirmed that the process of cell death leading to hybrid lethality in the cells is certainly apoptosis. Hybrid cells were used in the experiments to estimate the point of no return in temperature-sensitive lethality and to examine the influence of cation in DNA fragmentation during apoptosis. The utility of hybrid cells as an experimental system for studies of hybrid lethality and apoptosis in plants was confirmed.     

Design and synthesis of Pictet-Spengler condensation products that exhibit oncogenic-RAS synthetic lethality and induce non-apoptotic cell death

A series of Pictet-Spengler condensation derivatives (tetrahydro-β-carbolines) was designed, synthesized and evaluated for lethality against a panel of seven cancer cell lines. Seven compounds (2a, 13, 20, 21, 27, 29 and 34) showed lethality in at least five cell lines. Among these, compound 27 showed a unique selectivity towards oncogenic-RAS expressing BJ-TERT/LT/ST/RAS(V12) tumor cells, compared to non-transformed BJ-TERT cells. Further investigation revealed that 27 induces cell death without activation of caspases. This represents a useful new probe of non-apoptotic cell death and oncogenic-RAS synthetic lethality.     

Effect of dihydroxyanthraquinone (DHAQ) and radiation on the survival of cultured Chinese hamster ovary cells

Dihydroxyanthraquinone (DHAQ) is currently being tested as a cancer chemotherapeutic agent because of its structural similarity to Adriamycin (ADR) and other DNA-intercalating antibiotics. The interaction of DHAQ and ionizing radiation on the induction of cell lethality was investigated in Chinese hamster ovary cells in culture. In asynchronous populations of cells, DHAQ produced a slight enhancement of radiation-induced cell lethality as evidenced by changes in both shoulder and slope of the radiation dose-survival curves. However, DHAQ had no effect on either the extent or time course of recovery from sublethal radiation damage. In synchronous populations of cells treated at various times before or after selection in mitosis, the combination of DHAQ and radiation produced greater cell killing than that predicted based on simple additivity of effect, with a decided enhancement for cells treated during S phase. These results indicate that DHAQ is similar to other DNA-intercalating antibiotics in regard to the interaction with ionizing radiation to produce cell lethality.     

A single low dose of X-rays induces high frequencies of genetic instability (aneuploidy) and heritable damage (apoptosis), dependent on cell type and p53 status

We harvested and analyzed cells from four different non-transformed cell lines surviving a single X-ray exposure. Evidence of radiation-induced karyotype instability was observed in 100% of C3H 10T1/2 fibroblast clones and 11.3% of V79 fibroblast clones. Heritable damage: predisposition to apoptosis, but not karyotype instability, was induced in TK6 (p53(wt/wt)) and WTK1 (p53(mut/mut)) human B-lymphoblastoid cell clones. The studies indicate: (1) genetic instability and/or heritable damage are induced in cells exposed to radiation at a high frequency, and induction of genetic instability is not limited to morphologically transformed cells [Radiat. Res. 138 (1994) S105; Radiat. Environ. Biophys. 36 (1998) 255]; (2) sensitivity to genetic instability and heritable damage depend on cell type; (3) checkpoint stringency and p53 status significantly influence the frequency of radiation-induced genetic instability and heritable damage; (4) in some cell lines, damage induced by low doses of radiation (below 2 Gy) leads to heritable cytotoxic and genotoxic effects in 100% of cells exposed. The data suggest that mammalian cells misinterpret damage induced by ionizing radiation as if it were a physiological cell signal. This contrasts strongly with the response of mammalian cells to damage induced by other types of DNA-toxic agents where damage-specific repair mechanisms are activated.     

Quantitative Measurement of the Ability of Different Mutagens to Induce an Inherited Change in Phenotype to Allow Maltose Utilization in Suspension Cultures of the Soybean, GLYCINE MAX (L.) Merr

Using a newly developed plating system, we have measured cell survival and the frequencies of variation in an inherited trait after treatment of soybean cell suspensions with different mutagens: ethyl methanesulfonate (EMS), methyl methanesulfonate (MMS), N-Methyl-N'-nitro-N-nitroso-guanidine (MNNG), hycanthone (1-{[2-(diethylamino) ethyl] amino}-4-(hydroxymethyl)-9H-thioxanthen-9-one and ultraviolet light (UV).—The heritable variation selected for displays a phenotype of rapid growth on maltose as carbon source. The marker is stable in the absence of maltose, and prolonged growth of variant cells on sucrose has not shown reversions to slow growth. Doubling time in suspension cultures is decreased from 100 hr to ca. 30 hr by the mutation. Both wild-type and variant cells grow on sucrose with a 24-hr doubling time. Thus, lethality after mutagen treatment can be estimated rapidly by growth on sucrose, whereas variants are scored on maltose medium. The spontaneous frequency of variants was 1.2 x 10^-7; induced frequencies ranged from a low of 3.6 x 10^-5 for EMS to a high of 10^-3 for hycanthone. The high frequency of variants induced by hycanthone, a frame-shift mutagen, and the observation that UV induces variants in haploid cells with much higher frequency than in diploid cells suggests a recessive mutation.     

Embryonic and post-embryonic lethals induced by diethyl sulfate in mature sperm of Drosophila melanogaster.

It has recently been reported that, in Drosophila melanogaster, when sperm treated with diethyl sulfate was stored in the females, II–III translocations were detected as from the 6th day after the treatment, though none was recovered without storage. Chromosome breaks being currently considered the main cause of dominant lethality and the embryonic period lasting about one day at 25°C, it was thought of interest to study the ability of DES to induce this type of damage with and without storage. It was found that the treatment increased embryonic lethality (measured as frequency of unhatched eggs) and post-embryonic lethality (measured as frequency of larval and pupal death) over the control values. The frequency of embryonic lethals after storage in the females for 6 days was similar to that shown by the unstored samples. In contrast with this, the yield of post-embryonic lethality was markedly raised by that storage time. It is suggested that: (1) lesions are induced as “pre-breaks”, and storage and cell divisions are instrumental in their opening; (2) potential breaks can undergo DNA replication and cell division as such and become open in different cell cycles, impairing embryonic and post-embryonic development; (3) chromosome breaks induced by DES seem to behave in a way similar to those induced by other mono- and poly-functional alkylating agents; and (4) when the potential ability of chemical compounds to induce chromosome breaks is assessed, post-embryonic lethality can be used as a simple one-generation preliminary test, to establish delayed effects.     

Relationship between LET and RBE values for Escherichia coli determined using carbon ion beams from the TIARA cyclotron and HIMAC synchrotron

Researchers studied the effects of ion beams on cell lethality in two strains of Escherichia coli. Experiments were conducted on the wild-type strain and a DNA repair-deficient mutant strain that lacks the ability to repair DNA damage. A final aspect of the study was to examine the relationship between the linear energy transfer and relative biological effectiveness values for E. coli cell lethality and dose-response for decreasing the survival fraction to 10 percent.     

A novel Arabidopsis gene causes Bax-like lethality in Saccharomyces cerevisiae

Overexpression of the mammalian proapoptotic protein Bax induces cell death in plant and yeast cells. The Bax inihibitor-1 (BI-1) gene rescues yeast and plant from Bax-mediated lethality. Using the Arabidopsis BI-1 (AtBI-1) gene controlled by the GAL1 promoter as a cell death suppressor in yeast, Cdf1 (cell growth defect factor-1) was isolated from Arabidopsis cDNA library. Overexpression of Cdf1 caused cell death in yeast, whereas such an effect was suppressed by co-expression of AtBI-1. The Cdf1 protein fused with a green fluorescent protein was localized in the mitochondria and resulted in the loss of mitochondrial membrane potential in yeast. The Bax-resistant mutant BRM1 demonstrated tolerance against Cdf1-mediated lethality, whereas the Deltaatp4 strain was sensitive to Cdf1. Our results suggest that Cdf1 and Bax cause mitochondria-mediated yeast lethality through partially overlapped pathways.     

Heritable Epigenetic Changes Alter Transgenerational Waveforms Maintained by Cycling Stores of Information

Our view of heredity can potentially be distorted by the ease of introducing heritable changes in the replicating gene sequences but not in the cycling assembly of regulators around gene sequences. Here, key experiments that have informed the understanding of heredity are reinterpreted to highlight this distortion and the possible variety of heritable changes are considered. Unlike heritable genetic changes, which are always associated with mutations in gene sequence, heritable epigenetic changes can be associated with physical or chemical changes in molecules or only changes in the system. The transmission of cycling stores along the continuous lineage of cells that connects successive generations creates waves of activity and localization of the molecules that together form the cell code for development in each generation. As a result, heritable epigenetic changes can include any that can alter a wave such as changes in form, midline, frequency, amplitude, or phase. Testing this integrated view of all heritable information will require the concerted application of multiple experimental approaches across generations.     

Possible involvement of auxin-induced ethylene in an apoptotic cell death during temperature-sensitive lethality expressed by hybrid between Nicotiana glutinosa and N. repanda

Interspecific hybrids of Nicotiana glutinosa L. x N. repanda Willd. express temperature-sensitive lethality induced by apoptotic cell death. Hybrid seedlings cultured at 28 degrees C began to exhibit lethal symptoms during early growth stages, and then they showed a high level of endogenous auxin compared with those of parental seedlings. Meanwhile, the level of auxin in hybrid seedlings cultured at 32 degrees C, which is a condition suppressing the lethality of this cross combination, was equal to or lower than those of parental seedlings. Administration of 2,3,5-triiodobenzoic acid (TIBA) as an auxin transport inhibitor into the hybrid seedlings suppressed lethal symptoms and had a life-extending effect. Additionally, TIBA has an effect to suppress DNA fragmentation, which is one of characteristics of apoptosis and has been detected in the hybrid seedlings expressing the lethality. Administration of aminooxyacetic acid (AOA) as an ethylene synthesis inhibitor, which could inhibit ethylene production, also showed the same effects as TIBA for the lethality. From these results, we suggested that auxin and ethylene were involved in an apoptotic cell death during the lethality, and the abnormal increase of endogenous auxin may lead to the ethylene production in hybrid seedlings during early growth stages.     

Expression of bak in S. pombe results in a lethality mediated through interaction with the calnexin homologue Cnx1

Expression studies in the yeast S. pombe have been utilised to establish the basis for a genetic analysis designed to identify the lethal partners of the pro-apoptotic proteins bak and bax. Bak expression in S. pombe is lethal and this lethality is rescued by co-expression of bcl-2 or bcl-x(L). S. pombe cells expressing bak have a terminal phenotype in which the majority of cells are blocked in the G1 phase of the cell cycle while the remainder of cells, unable to complete M-phase, mis-coordinate the timing of subsequent events in the cell cycle. Although bax expression in S. pombe gives rise to a slow growth phenotype, not a lethality, bax expressing cells display the same cell cycle phenotypes described for bak. Electron microscopy of cells expressing bak reveals a dramatic accumulation of large vesicular structures. A two-hybrid screen designed to identify S. pombe proteins which interact with bak, isolated the S. pombe calnexin homologue cnx1. Genetic analysis demonstrates that the Cnx1 domain which binds to bak in two-hybrid experiments, is necessary for bak lethality in S. pombe. This report identifies a lethal interacting partner for bak and the observations suggest a model for bak mediated lethality which can be tested in higher cells.     

Effect of diet on hyperthermia-induced cell lethality and prostaglandin release.

Hyperthermia-induced cell lethality is thought to be mediated through injury to the cell membrane. Membrane perturbation results in the release of prostaglandins (PG) and leukotrienes (LT). These compounds are potent biological mediators and may modify the tumor microenvironment and therapeutic efficacy. Membrane composition and PG/LT release are influenced by the dietary fatty acids. The relationship between these variables and response to hyperthermia was examined in vitro using murine P388 leukemia cells grown as an ascites in mice provided either saturated fatty acid diet (SFA; 16% beef tallow) or unsaturated fatty acid diet (UFA; 16% safflower oil). Cells were harvested and exposed in vitro to either 37 degrees C or 43.5 degrees C for periods up to 2 hours. Hyperthermic exposure for 2 hours resulted in 40% cell lethality in SFA cells and 55% in UFA cells. The phospholipid and total cholesterol content was higher (33% and 50% respectively) in the UFA versus the SFA cells. Hyperthermia produced a six-fold increase in prostaglandin E2 PGE2 release by SFA cells and a 4.5-fold increase by UFA cells. No LTC4 was detected. Alteration of dietary fat affects cell lethality and PG release following hyperthermic treatment. The increase in phospholipid and cholesterol content of UFA cells may be a response to reduced membrane fluidity.     

Male germline control of transposable elements

Repetitive sequences, especially transposon-derived interspersed repetitive elements, account for a large fraction of the genome in most eukaryotes. Despite the repetitive nature, these transposable elements display quantitative and qualitative differences even among species of the same lineage. Although transposable elements contribute greatly as a driving force to the biological diversity during evolution, they can induce embryonic lethality and genetic disorders as a result of insertional mutagenesis and genomic rearrangement. Temporary relaxation of the epigenetic control of retrotransposons during early germline development opens a risky window that can allow retrotransposons to escape from host constraints and to propagate abundantly in the host genome. Because germline mutations caused by retrotransposon activation are heritable and thus can be deleterious to the offspring, an adaptive strategy has evolved in host cells, especially in the germline. In this review, we will attempt to summarize general defense mechanisms deployed by the eukaryotic genome, with an emphasis on pathways utilized by the male germline to confer retrotransposon silencing.     

Dependence of HL-60 myeloid cell differentiation on continuous and split retinoic acid exposures: Precommitment memory associated with altered nuclear structure

The cell differentiation of HL-60 human leukemic promyelocytes along the myeloid pathway due to various continuous and distributed exposures to retinoic acid was studied. HL-60 myeloid differentiation was a continuously driven process; significant terminal cell differentiation occurred only after a minimum exposure to inducer of two division cycles. Cells so committed to differentiation retained a heritable, finite memory of differentiation commitment over a further division cycle. Prior to becoming committed, cells acquired precommitment memory of exposure to inducer. Precommitment memory abbreviated the subsequent exposure to inducer needed for commitment to differentiation. Precommitment memory was semistable. It was heritable, but was lost after four division cycles. The acquisition and loss of precommitment memory correlated with alterations in nuclear architecture detected by narrow angle light scatter using flow cytometry. The altered nuclear architecture first occurred before any overt cell differentiation or growth arrest. It was thus an early event in the induced program of terminal cell differentiation. Alterations in relative abundances of cytoplasmic proteins also occurred prior to overt cell differentiation or growth arrest. One of these was a 17 kdalton, anionic, probably Ca²⁺ binding, protein. Retinoic acid thus induced early cellular changes, including cytoplasmic and nuclear alterations, within one cell cycle when cell differentiation was not yet apparent.