Specific stimulation of alpha-amanitin-sensitive RNA synthesis in isolated HeLa nuclei by methyl mercury

Mercury inactivates transcription and the generalized transcription factor TFB in the archaeon Sulfolobus solfataricus

Mercury has a long history as an antimicrobial agent effective against eukaryotic and prokaryotic organisms. Despite its prolonged use, the basis for mercury toxicity in prokaryotes is not well understood. Archaea, like bacteria, are prokaryotes but they use a simplified version of the eukaryotic transcription apparatus. This study examined the mechanism of mercury toxicity to the archaeal prokaryote Sulfolobus solfataricus. In vivo challenge with mercuric chloride instantaneously blocked cell division, eliciting a cytostatic response at submicromolar concentrations and a cytocidal response at micromolar concentrations. The cytostatic response was accompanied by a 70% reduction in bulk RNA synthesis and elevated rates of degradation of several transcripts, including tfb-1, tfb-2, and lacS. Whole-cell extracts prepared from mercuric chloride-treated cells or from cell extracts treated in vitro failed to support in vitro transcription of 16S rRNAp and lacSp promoters. Extract-mixing experiments with treated and untreated extracts excluded the occurrence of negative-acting factors in the mercury-treated cell extracts. Addition of transcription factor B (TFB), a general transcription factor homolog of eukaryotic TFIIB, to mercury-treated cell extracts restored >50% of in vitro transcription activity. Consistent with this finding, mercuric ion treatment of TFB in vitro inactivated its ability to restore the in vitro transcription activity of TFB-immunodepleted cell extracts. These findings indicate that the toxicity of mercuric ion in S. solfataricus is in part the consequence of transcription inhibition due to TFB-1 inactivation.

Inorganics and hormesis

The article is a comprehensive review of the occurrence of hormetic dose-response relationships induced by inorganic agents, including toxic agents, of significant environmental and public health interest (e.g., arsenic, cadmium, lead, mercury, selenium, and zinc). Hormetic responses occurred in a wide range of biological models (i.e., plants, invertebrate and vertebrate animals) for a large and diverse array of endpoints. Particular attention was given to providing an assessment of the quantitative features of the dose-response relationships and underlying mechanisms that could account for the biphasic nature of the hormetic response. These findings indicate that hormetic responses commonly occur in appropriately designed experiments and are highly generalizeable with respect to biological model responses. The hormetic dose response should be seen as a reliable feature of the dose response for inorganic agents and will have an important impact on the estimated effects of such agents on environmental and human receptors.

Specific inhibition of rRNA transcription and dynamic relocation of fibrillarin induced by mercury

Current evidence suggests that the nucleolus is composed of different substructures that are dynamic and form in response to the requirement for new ribosome synthesis. Thus, agents that disrupt nucleolar organization may deregulate basic cellular events and eventually contribute to human disease. Here we report that environmentally relevant concentrations (5 microM) of inorganic mercury induce a redistribution of nucleolar protein fibrillarin from the nucleolus to the nucleoplasm in epithelial cell lines. Since treatment with transcription inhibitors led to a similar relocation of fibrillarin, the effects of mercury on transcription were studied by run-on transcription assays: mercuric ions specifically blocked synthesis of ribosomal RNA, whereas activity of RNA polymerase II remained unchanged and occurred throughout the nucleoplasm. Moreover, we show by double-labeling that inhibition of nucleolar transcription and redistribution of fibrillarin occur simultaneously, underlining that fibrillarin relocation is a consequence of the blockade of ribosomal RNA synthesis by mercury. We also detected redistribution of fibrillarin in vivo, e.g., in splenic cells of mice chronically exposed to HgCl(2). Thus, implications of this alteration of nuclear structure and function for mercury-induced autoimmunity are discussed.

Protein synthesis is not required for the inhibitory effect of selenite on cell colony formation and RNA synthesis

Selenite has been shown to undergo intracellular metabolism that results in its conversion to other low molecular weight Se-containing species and also to its incorporation into a selenocysteine residue in selenoprotein. In order to investigate whether the incorporation into protein is required for the cytotoxic effects of selenite, we have examined whether inhibition of protein synthesis prevents the inhibitory effect of selenite on the ability of cells to form colonies or to synthesize RNA. We have found that treatment of HeLa cells with cycloheximide inhibited protein synthesis by > 90% but had no effect on the inhibitory effect of selenite on cell colony formation or RNA synthesis. Since protein synthesis is not necessary for these cytotoxic effects of selenite they are unlikely to result from an increase in the synthesis of selenoproteins.

Inhibitory effect of crocetin on intracellular nucleic acid and protein synthesis in malignant cells

The possibility that dietary intake of diverse naturally occurring compounds may influence the occurrence of cancer is receiving considerable scientific attention. Previously, it was reported that an extract (Crocus sativus), which contains carotenoids, had an antitumor effect and inhibited colony formation and nucleic acid synthesis by malignant human cells. Epidemiological and experimental research has indicated that carotenoids might act as antitumor agents. We have studied crocetin, a carotenoid isolated from saffron, which has been shown to have biological activity. In our experiments we utilized three malignant human cell lines: HeLa (cervical epitheloid carcinoma), A549 (lung adenocarcinoma) and VA13 (SV-40 transformed fetal lung fibroblast) cells. The effect of crocetin on colony formation and cellular DNA, RNA and protein synthesis in these cells has been examined. Incubation of these cells with crocetin for 3 h caused a dose-dependent inhibition of nucleic acid and protein synthesis. Crocetin also had a dose-dependent inhibitory effect on DNA and RNA synthesis in isolated nuclei and suppressed the activity of purified RNA polymerase II.

Effect of cell density on the inhibition of tumor cell attachment and nucleic acid synthesis by selenite

The effect of cell density on the sensitivity of tumor cells to selenite has been examined. The inhibitory effect of selenite on cellular DNA and RNA synthesis was significantly greater in higher density cultures of HeLa cells and A2780 ovarian tumor cells. High-density cells were also more sensitive to the inhibitory effect of selenite on cell attachment. This difference could not be accounted for by a higher intracellular level of glutathione, since there was no significant difference between the cells at high or low density. The high-density cells were found to take up more selenium per cell during the exposure period; the resulting higher level of intracellular Se could explain their greater sensitivity to selenite. This hypothesis is supported by the observation that DNA synthesis in nuclei isolated from high-density cells did not exhibit higher sensitivity to inhibition by selenite than synthesis in nuclei isolated from low-density cells.

Phorbol ester-induced inhibition of proliferation of Daudi Burkitt's lymphoma cells by impairment of cytokinesis

The phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA) exerts a dose-dependent effect on Daudi cell proliferation. A low concentration has a slight mitogenic effect but higher concentrations inhibit proliferation. The inhibitory effect is associated with increases in cell size, macromolecular content, and incorporation of precursors into RNA and protein. Cell cycle analysis indicates that TPA at 1-10 nM leads to an apparent accumulation of cells in G2/M phase. However, within this population a significant proportion of cells undergo nuclear division but fail to carry out cytokinesis, giving rise to cells with two or more nuclei. Consistent with this, DNA synthesis continues in cells which cease to divide in the presence of TPA. The ability of the phorbol ester to inhibit proliferation can thus be attributed mainly to an inhibition of cytokinesis rather than DNA replication.

RNA elongation by RNA polymerase II is not inhibited by N-ethylmaleimide or iodoacetamide

The elongation of RNA by RNA polymerase II is not inhibited by N-ethylmaleimide or iodoacetamide. Three systems were studied: a soluble chromatin, purified RNA polymerase II with DNA, and a HeLa cell extract with an adenovirus 2 promoter sequence.

Involvement of cellular sulfhydryl compounds in the inhibition of RNA synthesis by selenite

Selenite has been shown previously to inhibit cellular RNA synthesis. Based upon our previous observation that selenite inhibits purified RNA polymerase only in the presence of a sulfhydryl compound (Frenkel et al., Mol Pharmacol 31: 112-116, 1987), we hypothesized that the inhibition of cellular RNA synthesis by selenite involves endogenous sulfhydryl compounds. We found that depletion of cells of endogenous sulfhydryl compounds, by exposure to diethylmaleate (DEM), virtually eliminated the inhibitory effect of a 1-hr exposure of cells to selenite. This inhibition was restored to normal or higher levels when the selenite was reacted with glutathione or cysteamine prior to addition to the DEM-treated cells. RNA synthesis in DEM-treated cells was inhibited after a 4-hr exposure to higher concentrations of selenite. In contrast to the effect of DEM, specific depletion of the cells of glutathione, by exposure to buthionine sulfoximine, had no effect on the inhibition of RNA synthesis by selenite. These results demonstrate the involvement of endogenous cellular sulfhydryl compounds in the inhibition of RNA synthesis by selenite, but indicate that glutathione, in particular, is not involved in this inhibition.

A cell line with decreased sensitivity to the methyl mercury-induced stimulation of alpha-amanitin sensitive RNA synthesis in isolated nuclei

1. In nuclei isolated from cells of the B50 rat neuroblastoma line the stimulatory effect of methyl mercury on alpha-amanitin-sensitive RNA synthesis is very much reduced compared to the stimulatory effect in HeLa nuclei (see: Frenkel G. D. and Randles K. (1982) Specific stimulation of alpha-amanitin-sensitive RNA synthesis in isolated HeLa nuclei by methyl mercury. J. biol. Chem. 257, 6275-6279). 2. The stimulatory effect of another mercury compound, p-hydroxymercuribenzoate, was also much less pronounced in the B50 nuclei. 3. Similar results were obtained with nuclei isolated from B50 cells which had been induced to differentiate by exposure to dibutaryl cyclic AMP. 4. Nuclei isolated from cells of another rat neuroblastoma line (B35), and nuclei from cells of a human neuroblastoma line both exhibited levels of stimulation similar to that of HeLa nuclei. 5. The B50 and HeLa cells were also compared as to their sensitivity to other effects of methyl mercury.

The enhanced rate of transcription of methyl mercury-exposed DNA by RNA polymerase is not sufficient to explain the stimulatory effect of methyl mercury on RNA synthesis in isolated nuclei

Previous work demonstrated two stimulatory effects of methyl mercury on nucleic acid synthesis: (1) in isolated nuclei, methyl mercury stimulates RNA synthesis which is catalyzed by RNA polymerase II [Frenkel and Randles, J. Biol. Chem. 257, 6275-6279 (1982)]. (2) Brief exposure of purified DNA to methyl mercury increases the rate of its transcription by purified RNA polymerase II [Frenkel, Cain, and Chao, Biochem. Biophys. Res. Commun. 127, 849-856 (1985)]. The latter effect was considered as a possible mechanism of the former. Two lines of evidence are presented here which demonstrate that the latter effect is not a sufficient explanation for the former. (1) Mercuric perchlorate has been found to increase the rate of DNA transcription by purified polymerase and the template properties of the mercuric perchlorate-exposed DNA have been found to resemble those of methyl mercury-exposed DNA. Nevertheless, mercuric perchlorate has been shown not to stimulate RNA synthesis in isolated HeLa nuclei. (2) In isolated nuclei of the B50 rat neuroblastoma cell line, RNA synthesis has been found to be stimulated only minimally by methyl mercury. Nevertheless, RNA polymerase II purified from the B50 cells has been found to transcribe methyl mercury-exposed DNA at a higher rate than unexposed control DNA.

Comparison of the effects of exogenous native phytochrome and in-vivo irradiation on in-vitro transcription in isolated nuclei from barley (Hordeum vulgare)

In barley seedlings the transcription of genes coding for the light-harvesting chlorophyll a/b protein (LHCP) is stimulated and the transcription of genes coding for the NADPH-protochlorophyllide oxidoreductase (reductase) is repressed by light working via the phytochrome system. This phytochrome-mediated control of gene expression has been studied by monitoring in-vitro transcription in isolated nuclei. Two different experimental approaches have been used to elucidate the function of phytochrome (Pfr) during the transduction of the light signal. Concentrations of phytochrome were varied experimentally either by illuminating intact plants or macerated plant material prior to the isolation of nuclei or by adding purified phytochrome (Pfr) in its native 124-kDa form to the isolated nuclei. Our results indicate that there are at least two different steps involved in the phytochrome control of specific gene expression. (i) There is a rapid and transient change in the transcription rate which is saturated by very low levels of Pfr. (ii) There is a change in the duration and the maximum range of the transient change; this step requires relatively high Pfr concentrations and thus reacts very sensitively and rapidly to changes in Pfr levels as induced by secondary irradiations. This second step, but not the first one, could be triggered by the addition of purified oat phytochrome to a reconstituted nuclear system. This effect of purified phytochrome could only be shown if nuclei isolated from red-light (R)-irradiated seedlings were used. It was thus possible to simulate the effect of an in-vivo-applied second R pulse by the addition of Pfr to nuclei isolated from R-preirradiated plants.

Effects of lead acetate on DNA and RNA synthesis by intact HeLa cells, isolated nuclei and purified polymerases

The effects of lead acetate on DNA and RNA synthesis have been investigated with intact HeLa cells, isolated nuclei, and purified DNA and RNA polymerases. No inhibition of DNA or RNA synthesis in intact cells was found even after exposure to 0.5 mM lead acetate for 18 hr. In contrast, both DNA and RNA synthesis in isolated nuclei were inhibited by lead (with 50% inhibition at approximately 150 and 80 microM respectively). Similarly, both HeLa DNA polymerase alpha and RNA polymerase II were inhibited, with 50% inhibition obtained at approximately 150 and 20 microM lead acetate respectively. The inhibition of nucleic acid synthesis in isolated nuclei can thus be accounted for by inhibition of the polymerases. The sensitivity of Escherichia coli DNA polymerase I to lead acetate was found to be significantly greater than the HeLa DNA polymerase alpha (50% inhibition at only 10 microM), but the sensitivity of the E. coli RNA polymerase was the same as that of the HeLa enzyme.

Effect of alpha-amanitin on liver non-histone chromatin proteins of starved hens

A diminution of RNA content in hen liver nuclei was observed after either prolonged starvation or short-term exposure to alpha-amanitin. Using polyacrylamide gel electrophoresis, it has been revealed a limited number of altered polypeptide bands in the gel patterns of 0.35 M NaCl- and 5 M urea-soluble non-histone proteins from liver chromatin of starved or alpha-amanitin-treated birds. The low-molecular-weight polypeptides were found to increase in the protein fractions from liver chromatin of alpha-amanitin-injected hens. Only two protein bands (48 and 79 kDa) in the gel patterns of 5 M urea-soluble chromatin fraction altered in similar manner both in starved and alpha-amanitin-treated animals. The amount of the 48-kDa protein decreased and that of the 79-kDa protein increased under these conditions. alpha-Amanitin seems to affect differently the non-histone chromatin proteins from starved and fed animals. The level of the 48-kDa urea-soluble protein was lower and that of the 64-kDa protein was higher in liver chromatin of starved animals receiving alpha-amanitin in comparison with the corresponding proteins from fed animals treated with this drug.

Mechanism of apparent transcription inhibition by methyl mercury in cerebellar neurons

We have investigated the mechanism of inhibition of RNA synthesis by methyl mercury (MeHg) in isolated neonatal rat cerebellar cells. Each of the three component steps involved in the incorporation of exogenous [3H]uridine into cellular RNA was examined separately in whole-cell and/or subcellular preparations. Nuclear RNA polymerase activity was measured in preparations containing both free nuclei and whole cells. Incorporation of [3H]UTP into nuclear RNA was found to be unimpaired at concentrations of MeHg that inhibited whole-cell incorporation of [3H]uridine by greater than 75%. Cellular uptake of [3H]uridine was assayed in cerebellar cells treated with KCN to deplete ATP levels and block subsequent phosphorylation reactions of transported uridine. Uptake activity under these conditions was unaffected by MeHg. Measurement of intracellular phosphorylation of [3H]uridine indicated that inhibition of this activity closely paralleled that of RNA synthesis. Quantitation of individual uridine nucleotides by polyethyleneimine-cellulose TLC revealed reduced levels of UTP and UDP whereas levels of UMP were elevated, suggesting that impairment of phosphorylation was not the result of cellular ATP depletion but, more likely, a direct effect on phosphouridine kinase enzymes. This mechanism of MeHg-induced inhibition of RNA synthesis was confirmed by assays of uridine phosphorylation using cell-free extracts in which exogenous ATP was supplied.

Effects of sodium selenite and selenate on DNA and RNA synthesis in vitro

The effects of sodium selenite and sodium selenate on DNA and RNA synthesis have been examined using intact HeLa cells, isolated nuclei and extracted polymerases. Selenate had no effect on any of the systems examined. Selenite inhibited DNA synthesis in intact cells and in isolated nuclei, and to a limited extent also inhibited DNA polymerase alpha. Selenite also inhibited RNA synthesis in intact cells and alpha-amanitin resistant RNA synthesis in isolated nuclei (i.e., synthesis catalyzed by RNA polymerase I and III). It had no effect on alpha-amanitin sensitive synthesis (catalyzed by RNA polymerase II) at concentrations up to 500 microM. However, transcription of exogenous DNA by extracted RNA polymerase II (as well as by polymerase I and III) was inhibited by selenite.

Exposure of DNA to methyl mercury results in an increase in the rate of its transcription by RNA polymerase II

Double-stranded DNA which was exposed to methyl mercury at concentrations of 1 mM and above, and purified by ethanol precipitation and dialysis, was transcribed at a higher rate by RNA polymerase II than was control DNA. The rate of transcription of single-stranded DNA was not affected by similar exposure to methyl mercury. The higher rate of transcription of methyl mercury-treated double-stranded DNA appears to result from a decreased Km of the enzyme for this DNA. This does not appear to result from extensive denaturation, nor from formation of a large number of single-stranded breaks in the DNA.

A comparative study of the effects of mercury compounds on cell viability and nucleic acid synthesis in HeLa cells

The effects of various mercury compounds on HeLa cell viability and DNA and RNA syntheses in intact cells and in isolated nuclei have been studied. The compounds examined were: methylmercuric chloride, ethylmercuric chloride, dimethylmercury, phenylmercuric acetate, p-hydroxymercuribenzoate, p-hydroxymercuribenzenesulfonate, HgCl2, HgSO4 , Hg(ClO4)2 and Hg2(ClO4)2. All of the compounds except dimethylmercury inhibited colony formation as well as DNA synthesis in intact cells and in isolated nuclei. RNA synthesis in intact cells was inhibited by all the compounds except dimethylmercury, p-hydroxymercuribenzoate and Hg(ClO4)2. In isolated nuclei, alpha-amanitin-resistant RNA synthesis was inhibited by all the compounds except dimethylmercury, alpha-Amanitin-sensitive RNA synthesis was stimulated by some compounds, inhibited by some, and unaffected by others. The effects of two non-mercurial sulfhydryl reagents, N-ethylmaleimide and iodoacetic acid, were also examined. These compounds showed a pattern of effects on nucleic acid synthesis which differed considerably from that of the mercury compounds. Neither compound significantly inhibited alpha-amanitin-resistant RNA synthesis in isolated nuclei, although both inhibited RNA synthesis in intact cells. Iodoacetic acid had no inhibitory effect on DNA synthesis in isolated nuclei but strongly inhibited DNA synthesis in intact cells.

In vitro methyl mercury inhibition of protein synthesis in neonatal cerebellar perikarya

In an effort to characterize the principal mechanism(s) underlying the methyl mercury-induced defect in protein synthesis in vivo and in vitro, we examined the dose and time related effects of methyl mercury chloride (MeHg) on a variety of cellular functions using bulk-isolated neonatal cerebellar perikarya. This cell preparation demonstrated a high specific activity for protein synthesis which was optimal between 6 and 12 days of age and declined rapidly thereafter. In vitro MeHg inhibited synthesis with an ID50 of approximately 14 microM without causing significant release of lactate dehydrogenase. The inhibition of protein synthesis occurred independently of mercurial effects on RNA synthesis, mitochondrial function, ATP content or intracellular levels of Na+ and K+. Uptake of [3H]-phenylalanine was not appreciably affected by MeHg. The accumulated evidence suggests that in this in vitro cell model, MeHg inhibition of protein synthesis occurs via a direct interaction with the protein synthetic machinery.

Inhibition of RNA and protein synthesis in isolated cerebellar cells by in vitro and in vivo methyl mercury

Cerebellar perikarya isolated from neonatal rats were exposed to 0-20 microM methyl mercury to simultaneously compare the effect on RNA and protein synthesis. Although 50% inhibition was found at approximately 8 microM for both [3H]uridine and [3H]phenylalanine incorporation, lower concentrations of methyl mercury produced 10-15% greater inhibition of RNA than protein synthesis. In vivo methyl mercury experiments also indicated a greater sensitivity of RNA synthesis in isolated cerebellar perikarya. The observed inhibition of RNA synthesis was not caused by a defect in cellular [3H]uridine uptake or by increased degradation of RNA. Both of these activities were altered by less than 10% at concentrations of methyl mercury that produced greater than 60% inhibition of RNA synthesis. Experiments showing that the specific activity of cerebellar cell RNA synthesis peaks and remains high between 4 and 10 d of age, whereas the specific activity of protein synthesis declines rapidly emphasize the potential importance of transcriptional perturbation in neonatal rats.