Mutant yields and mutational spectra of the heterocyclic amines MeIQ and PhIP at the S1 locus of human-hamster AL cells with activation by chick embryo liver (CELC) co-cultures.

Cooking meat and fish at high temperature creates heterocyclic amines (HA) including 2-amino-3,4-dimethylimidazo[4,5-f]quinoline (MeIQ) and 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP). Several HA are mutagens in the Ames' S9/Salmonella assay. While PhIP is a substantial Ames' test mutagen, it is 1000-fold less active than the extraordinarily potent MeIQ. In contrast, MeIQ is significantly less mutagenic than PhIP in several mammalian cell assays, especially in repair-deficient Chinese hamster ovary (CHO) cells. HA are suspect human carcinogens on the basis of (i) epidemiological evidence, (ii) induction of tumors in rodents and monkeys, (iii) DNA adduct formation and (iv) mutagenic capacity. In this study, MeIQ and PhIP were significant mutagens at the S1 locus of co-cultivated human/hamster hybrid AL cells following metabolic activation by beta-napthoflavone (betaNF)-induced chick embryonic liver cultures (CELC). MeIQ was more mutagenic than PhIP in the CELC+AL cell assay. The mutant response curves increase with dose and then plateau (PhIP), or decrease (MeIQ). The inflections in these response curves coincide with dose-dependent decreases in cytochrome CYP1A1 activity. Molecular analysis of S1- mutants indicates that a substantial fraction, >65%, of the mutations induced by PhIP are deletions of 4.2 to 133 (Mbp); half are larger than 21 Mbp. Mutations induced by MeIQ were smaller, most (56%) being less than 5.7 Mbp. When appropriate metabolic activation is combined with a target locus, which can detect both small and large chromosomal mutations, both MeIQ and PhIP are significant mutagens and clastogens in repair proficient mammalian cells.

Mutation inhibition by beta-estradiol after low doses of gamma-irradiation of mammalian cells.

The methodology previously described for measuring mutagenesis has been applied to the study of mutation prevention in immortalized G2 phase human lymphocytes exposed to 25 and 50 cGy of gamma-radiation. Caffeine prevents repair of mutations. Two times 10(-4) M beta-estradiol applied for 2.5 h markedly decreases induced mutations and affects male and female cells similarly. Quantitative measurement of mutagenesis in cells of different individuals and the effect of various agents on mutation yield should be important in prevention of cancer and other mutational disease.

Mutation measurement in mammalian cells. IV: Comparison of gamma-ray and chemical mutagenesis.

The interaction of chemical mutagens with mammalian cells is much more complex than that of gamma-irradiation because of the different ways in which chemical agents react with cell and medium components. Nevertheless, the system previously described for analysis of mutagenesis by gamma-radiation appears applicable to chemical mutagenesis. The approach involves measurement of cell survival, use of caffeine to inhibit repair, analysis of mitotic index changes, and quantitation of microscopically visible structural changes in mitotic chromosomes. The behavior of a variety of chemical mutagens and nonmutagens in this system is described and compared with that of gamma-irradiation. The procedure is simple and the results reasonably quantitative though less so than those of gamma-irradiation. The procedure can be used for environmental monitoring, analysis of mutational events, and individual and epidemiological testing. Mutational events should be classified as primary or secondary depending on whether they represent initial genomic insult, or genomic changes resulting from primary mutation followed by structural changes due to metabolic actions. While caffeine has multiple effects on the mammalian genome, when used under the conditions specified here it appears to act principally as an inhibitor of mutation repair, and so affords a measure of the role of repair in the action of different mutagens on cells in the G2 phase of the life cycle.

Br-cAMP induction of apoptosis in synchronized CHO cells.

The proliferation of suspension cultures of malignant CHO cells was inhibited by 0.5 mM Br-cAMP treatment and restored by its removal. This treatment also inhibited histone H1 phosphorylation completely, reduced histones H2A and H4 phosphorylations, induced DNA degradation, and produced cells containing micronuclei. Agarose gel electrophoresis of the degraded DNA fragments produced a "ladder" pattern confirming these cells were undergoing apoptosis. Cell cycle synchrony experiments demonstrated culture growth inhibition was the result of two different cell cycle-specific processes: [1] arrested cell cycle traverse at a restriction point in mid-G1, and [2] rapid apoptosis following cell division. Br-cAMP did not stop cells in late-G1, S, G2, or M from traversing the cell cycle and dividing, but rather, induced apoptosis following mitosis. The restriction point of Br-cAMP arrest was located in the middle of a wider band of G1 arrest induced by isoleucine deprivation. The cells synchronized in G1 before the restriction point were held in G1-arrest by Br-cAMP and spared apoptotic death. These studies support the further study of cAMP derivatives as agents to induce tumor regression by apoptosis and reverse transformation.

Genome exposure and regulation in mammalian cells.

A method of measurement of exposed DNA (i.e. hypersensitive to DNase I hydrolysis) as opposed to sequestered (hydrolysis resistant) DNA in isolated nuclei of mammalian cells is described. While cell cultures exhibit some differences in behavior from day to day, the general pattern of exposed and sequestered DNA is satisfactorily reproducible and agrees with results previously obtained by other methods. The general pattern of DNA hydrolysis exhibited by all cells tested consists of a curve which at first rises sharply with increasing DNase I, and then becomes almost horizontal, indicating that roughly about half of the nuclear DNA is highly sequestered. In 4 cases where transformed cells (Raszip6, CHO, HL60 and PC12) were compared, each with its more normal homolog (3T3, and the reverse transformed versions of CHO, HL60 and PC12, achieved by dibutyryl cyclic AMP [DBcAMP], retinoic acid, and nerve growth factor [NGF] respectively), the transformed form displayed less genome exposure than the nontransformed form at every DNase I dose tested. When Ca++ was excluded from the hydrolysis medium in both the Raszip6-3T3 and the CHO-DBcAMP systems, the normal cell forms lost their increased exposure reverting to that of the transformed forms. Therefore Ca++ appears necessary for maintenance of the DNA in the more highly exposed state characteristic of the nontransformed phenotype. LiCl increases the DNA exposure of all transformed cells tested. Dextran sulfate and heparin each can increase the DNA exposure of several different cancers. Colcemid prevents the increase of exposure of CHO by DBcAMP but it must be administered before or simultaneously with the latter compound. Measurements on mouse biopsies reveal large differences in exposure in different normal tissues. Thus, the exposure from adult liver cells was greater than that of adult brain, but both fetal liver and fetal brain had significantly greater exposure than their adult counterparts. Exposure in normal human fibroblasts as revealed by in situ nick translation reveals a nuclear distribution pattern around the periphery, around the nucleoli and in punctate positions in the nuclear interior in parts of both S and G1 phases of the cell cycle. The same exposure pattern is duplicated by the pattern of DNA synthesis in S cells. It would appear that these nuclear regions represent positions of special activity. The previously proposed theory of genome regulation in mammalian cells is supported by these findings. The theory proposes that: a) gene activity requires exposure of the given locus followed by action of transcription factors on the exposed genes; b) the fiber system of the cell (cytoskeleton, nuclear fibers, and extracellular fibers) are required for normal exposure; c) active sites for gene expression and replication consist of the nuclear periphery where differentiation genes particularly are exposed; the nucleoli where at least some housekeeping genes are exposed; and possibly also punctate regions in the interior; d) noncoding sequences play a critical role in genome regulation, possibly including the transport of loci to be activated to appropriate exposure transcriptional and replicating locations. Cancer cells have lost specific differentiation gene activities, at least sometimes because of mutation of appropriate exposure genes; at least some protooncogenes and tumor suppressor genes are responsible for exposure and transport of specific differentiation gene loci to their appropriate exposure sites in the nucleus and for inducing exposure.

A system for mutation measurement in mammalian cells: application to gamma-irradiation.

Monitoring of mutagenesis by environmental agents for the purpose of preventing genetic disease including cancer must include quantitation of cell killing, sensitive measurement of mutation production by appropriate doses of each agent, and assessment of mutation repair effects in mammalian cells. A four-step procedure, in the presence and absence of a repair suppressor, is proposed: (i) determination of the survival curve; (ii) measurement of the mitotic index in cells collected after treatment with colcemid; (iii) construction of a mutagenesis yield curve in the presence and absence of a repair suppressor, like caffeine; and (iv) assessment of the effect of test agents on the repair of mutations produced by other mutagens. The procedure is quantitative, reproducible, and reasonably rapid. It involves measurement of mutations causing visible chromosomal aberrations. Numerical parameters are proposed defining quantitatively mutation, cell killing, and mutation repair capacity. The procedure is applied to gamma-irradiation and can detect the effects of doses as low as 2-5 cGy. Theoretical analysis of the underlying processes is presented, using the concept of D(0)E, the effective dose of mutagen after repair mechanisms and neutralizing agents have acted. Microscopically visible chromosome aberrations are due to mutations that distort the process of mitotic chromosome condensation, with or without actual chromosome breakage.

DNA exposure and condensation in the X and 21 chromosomes.

Fluorescence in situ hybridization (FISH) whole chromosome painting probe studies have been carried out with X and 21 chromosomes on normal human fibroblasts grown in tissue culture. The majority of the cells were in G1 phase (including G0). The X chromosome, which exhibits differential inactivation, displays an active form which is most commonly in the nuclear periphery, is diffused over a large area with dark regions interspersed with bright regions, and exhibits punctate bright spots at its edges. The inactive X, which contains a small fraction of active genes, is also most often at the nuclear periphery, is highly condensed and also exhibits punctate labeling around its outer edge. Occasional nuclei exhibit X chromosomal material adjacent to a nucleolus. These observations fit the pattern proposed by the genome exposure theory in which inactive gene regions are sequestered by chromosome condensation, and become exposed by decondensation into a condition invisible by the video-imaging technique employed. Such exposed genes can then be activated by appropriate molecular messengers. In accordance with this theory, the total fluorescence observed from the active X is appreciably less than that of the inactive. The FISH pattern from chromosome 21 is very different, displaying two fluorescent bodies usually connected with the nucleoli. Both bodies contain condensed and decondensed regions, and both are much more similar in their degree of decondensation than was the case with the X chromosomes, although a small difference cannot be ruled out. Use of DNase I treatment of nuclei reveals the existence of exposed DNA. The use of FISH as demonstrated here can indicate sequestered DNA. Together the two techniques promise elucidation of gene regions of various chromosomes which are active and inactive in particular tissues and in normal and pathologic conditions.

Gamma-ray mutagenesis measurement in mammalian cells.

Application of conventional in vitro mutagenesis testing has so far failed to result in marked reduction of the total incidence of cancer. At least part of the reason may lie in the frequent use of a cell target too small to yield adequate sensitivity, and in failure to take into account the effects of cell killing in the assessment of mutagenic action. A single theoretical analysis fits the results of experimental data on gamma-irradiation applied to single marker gene testing in bacteria and to cytogenetic analysis of irradiated mammalian cells, and permits determination of the mean mutagenic dose, DoM, without complication due to cell killing. Cytogenetic monitoring of human lymphocytes which can detect mutagenic effects of gamma-radiation down to doses of < 0.1 Gy (10 rad) will also furnish an estimate of repair effectiveness at these low levels and may well be a useful tool in a program for prevention of cancer and other genetic disease.

On the role of lipids in cell regulatory economy.

Prenylated proteins, which contain a lipid tail, may function to enhance the self-assembly of complementary molecular structures by providing a monomolecular film between the two combining regions so that electrostatic forces of attraction are greatly increased over that which would be established with water molecules in the intervening spaces. Such interactions may be important in DNA regulation, RNA processing, and a variety of protein-protein interactions.

Reverse transformation and genome exposure in the C6 glial tumor cell line.

Reexpression of growth control and differentiation in response to physiological inducers can be demonstrated in some malignant cell lines, showing that they are not irreversibly transformed. This switch in phenotype is likely to reflect a changing pattern of gene expression, but it has not been known whether such cellular transitions involve major or only minor modulation of chromatin structure. We have studied growth control and accessibility of chromatin to DNase I in C6 glioma cells subjected to different growth regimens using an in situ nick translation assay to label the most exposed regions of nuclear chromatin. In fibroblasts and primary glia, exposed chromatin was localized mainly at the nuclear lamina. This readily labeled DNA structure was largely lacking in the malignant C6 glioma. When C6 cells were treated with dibutyryl cyclic AMP, exposed chromatin was reestablished around the nuclear periphery. This restoration of a normal genome exposure pattern required cytoskeletal integrity. Thus large-scale nuclear reorganization events proceed in parallel with phenotypic normalization. The changes in cell morphology, growth control, cytoskeletal organization, and chromatin exposure and localization are similar to the reverse transformation reaction in CHO-K1 cells, which is also regulated by the cyclic nucleotide system. Hydrocortisone and dexamethasone also restored genome exposure in C6 but less markedly than cAMP derivatives. Diverse transformed cells can thus respond to growth control stimuli with similar nuclear restructuring events, which presumably underlie changes in gene expression. Reverse transformation and redifferentiation appear to be alternative terms describing essentially the same biological phenomenon.

Caffeine enhanced measurement of mutagenesis by low levels of gamma-irradiation in human lymphocytes.

The well-known action of caffeine in synergizing mutagenesis (including chromosome aberrations) of agents like ionizing radiation by inhibition of cellular repair processes has been incorporated into a rapid procedure for detection of mutagenicity with high sensitivity. Effects of 5-10 rads of gamma-irradiation, which approximate the human lifetime dose accumulation from background radiation, can be detected in a two-day procedure using an immortalized human WBC culture. Chromosomally visible lesions are scored on cells incubated for 2 h after irradiation in the presence and absence of 1.0 mg/ml of caffeine. An eightfold amplification of scorable lesions is achieved over the action of radiation alone. This approach provides a closer approximation to absolute mutagenicity unmitigated by repair processes, which can vary in different situations. It is proposed that mutagenesis testing of this kind, using caffeine or other repair-inhibitory agents, be employed to identify mutagens in their effective concentrations to which human populations may be exposed; to detect agents such as caffeine that may synergize mutagenic actions and pose epidemiologic threats; and to discover effective anti-mutagens. Information derived from the use of such procedures may help prevent cancer and newly acquired genetic disease.

Reverse transformation, genome exposure, and cancer.

The reverse transformation reaction whereby malignant cells are restored to a more normal phenotype has been reviewed. The primary causative action is ascribed to the genome exposure reaction in which a peripheral nuclear DNA region is restored to high sensitivity to DNase I, like that in normal cells. Various aspects of genome exposure around the nucleoli and the nuclear periphery are considered. The special role of the cytoskeleton in regulating exposure resulting in normal differentiation on the one hand and malignant transformation on the other is discussed. The action of the two-level system for regulation of the mammalian genome previously proposed is reviewed in relation to normal differentiation and malignancy with brief indication of roles played by various metabolites, transcription factors, protooncogenes, cell organelles, and processes like specific phosphorylation and dephosphorylation. Possible implications for cancer therapy and prevention and for the fields of genetic disease and toxicology are indicated.

Confocal microscopy of genome exposure in normal, cancer, and reverse-transformed cells.

Genome exposure studies were carried out on malignant CHO-K1 and C6 rat glioma cells and their respective, phenotypically normal counterparts (reverse-transformed CHO-K1, and both reverse-transformed C6 glioma and normal rat fibroblasts). Cells were subjected to the nick-translation technique previously developed to make visible the exposed (i.e., DNase I-sensitive) nuclear DNA, and examined by both epifluorescence and confocal microscopy. The confocal microscopy, by permitting examination of sections throughout the nucleus, made possible clearer identification of the regions of exposed and sequestered DNA in the cells studied. A peripheral shell of exposed DNA with some discontinuities was displayed in the great majority of the cells with normal phenotype, but in none of the cancer cells. Both types of cells displayed regions of exposed DNA in the nuclear interior, particularly surrounding the nucleoli. In accordance with previous theoretical proposals we postulate: the peripheral nuclear shell of exposed DNA contains differentiation-specific genes that include the specific growth-control genes and that are functional in normal cells but not in cancer; the exposed genes surrounding the nucleoli may represent housekeeping genes active in both normal and cancer cells; and the DNase I-resistant DNA in the interior of the nucleus we postulate to consist for the most part of genes specific to alternative differentiation states and to be sequestered and inactive. Previous differences in evaluation of roles of peripheral and internal DNA sensitivity to DNAse I hydrolysis appear to be reconciled by this formulation. Identification of exposed DNA may be useful in cancer diagnosis.

Detection of direct mutagenicity of cigarette smoke condensate in mammalian cells.

Mutagenicity of cigarette smoke condensate (CSC) and the acidic, basic and neutral fractions of CSC was examined in the AL hybrid cell, a Chinese hamster ovary cell containing one human chromosome 11. Since the human chromosome 11 is not necessary for survival of the AL cells, mutations involving large deletions and chromosomal loss by non-dysjunction are non-lethal events that are detectable by loss of human cell surface antigens (a1, a2 and a3) encoded by genes on chromosome 11p (a1 and a3) and 11q (a2) through an antibody-complement lysis assay. Exposure of AL cells to CSC without exogenous metabolic activation caused a dose-dependent cytotoxicity and mutagenicity. Mutagenicity also increased with time of incubation up to 3 h with a maximum of 300 a1- mutants/10(5) survivors (250% above background; P less than 0.0005) after incubation with 100 micrograms/ml CSC. Cytotoxicity and mutagenicity of CSC were inversely proportional to cell density. Fifty percent lethal doses for the acidic, basic and neutral fractions of CSC after 3 h of incubation were 30, 100 and 240 micrograms/ml respectively, and the acidic fraction at a concentration of 25 micrograms/ml induced 350 a1- mutants/10(5) survivors (230% above background; P less than 0.0005); the basic and neutral fractions were less mutagenic. These results indicate that CSC and fractions of CSC can directly produce a spectrum of mutations, through both deletional and non-dysjunctional mechanisms of a kind known to lead to inactivation of tumor suppressor genes.

The spatial distribution of exposed nuclear DNA in normal, cancer, and reverse-transformed cells.

The malignant CHO-K1 cell is reverse-transformed by cAMP, regaining the phenotype of a normal fibroblast. During this reaction, much of its DNA re-acquires sensitivity to hydrolysis by DNase I in a way characteristic of the normal fibroblast. Exposed DNA forms a rim about the nucleus in both the normal and reverse-transformed cell but not in the malignant CHO-K1. Reacquisition of the nuclear rim requires an organized cytoskeleton. Sequestered DNA forms families of different degrees of sequestration. In accordance with previous theoretical developments it is proposed that (i) genes specific to a given differentiation state are stored in the nuclear rim, whereas genes specific to other states are sequestered within the nucleus; (ii) only exposed genes are active, and their activity is modulated by regulatory molecules in the fluid medium; (iii) exposure and sequestration are regulated by cytoskeletal and nuclear protein structures; (iv) in at least several types of cancer the regulatory defect lies in the genome exposure process so that the specific DNA sequences and their associated growth regulatory loci have been transferred from the exposed to the sequestered condition with consequent loss of the nuclear rim of exposed DNA. The methodology described should be generally applicable to examining the accessibility state of subsets of DNA during various physiological modulations of cell function.

Genome regulation in mammalian cells.

A theory is presented proposing that genetic regulation in mammalian cells is at least a two-tiered effect; that one level of regulation involves the transition between gene exposure and sequestration; that normal differentiation requires a different spectrum of genes to be exposed in each separate state of differentiation; that the fiber systems of the cell cytoskeleton and the nuclear matrix together control the degree of gene exposure; that specific phosphorylation of these elements causes them to assume a different organizational network and to impose a different pattern of sequestration and exposure on the elements of the genome; that the varied gene phosphorylation mechanisms in the cell are integrated in this function; that attachment of this network system to specific parts of the chromosomes brings about sequestration or exposure of the genes in their neighborhood in a fashion similar to that observed when microtubule elements attach through the kinetochore to the centromeric DNA; that one function of repetitive sequences is to serve as elements for the final attachment of this fibrous network to the specific chromosomal loci; and that at least an important part of the calcium manifestation as a metabolic trigger of different differentiation states involves its acting as a binding agent to centers of electronegativity, in particular proteins and especially phosphorylated groups, so as to change the conformation of the fiber network that ultimately controls gene exposure in the mammalian cell. It would appear essential to determine what abnormal gene exposures and sequestrations are characteristic of each type of cancer; which agonists, if any, will bring about reverse transformation; and whether these considerations can be used in therapy.

Neuropeptide stimulation of calcium flux in human lung cancer cells: delineation of alternative pathways.

Calcium ion flux following the administration of a series of neuropeptides, N6,O2'-dibutyryladenosine 3',5'-cyclic monophosphate, and serum was monitored by flow cytometry in selected lung and breast cancer cell lines and Chinese hamster ovary cell line CHO-K1. Calcium ion flux was monitored in individual cells by flow cytometry using the indicator indo-1 AM. Five groups of neuropeptides produced calcium flux changes in lung cancer cell lines and CHO-K1 cells but not in breast cancer cells. The peak increase in free calcium was reached within 10 sec of peptide administration and declined to resting levels in 70-120 sec. When two or more members of the same group were administered simultaneously, calcium flux changes were identical to that produced by each single peptide. When two or more members of different groups were administered simultaneously, an increased calcium release occurred. When identical peptides or peptides from the same group were administered sequentially after the return of calcium concentrations to resting values, no calcium flux resulted from the second peptide. When peptides from different active groups were administered sequentially, a new calcium flux occurred after each peptide. These data are interpreted to mean that members of each active group of peptides trigger a different calcium flux pathway. Thus, many such pathways and different metabolic states exist within the cell. Elucidation of calcium flux pathways in normal and cancer cells may lead to greater understanding of the nature of the malignant defect.