Agneta Önfelt

Uptake of analogs of penetratin, Tat(48-60) and oligoarginine in live cells.

Cell-penetrating peptides are regarded as promising vectors for intracellular delivery of large, hydrophilic molecules, but their mechanism of uptake is poorly understood. Since it has now been demonstrated that the use of cell fixation leads to artifacts in microscopy studies on the cellular uptake of such peptides, much of what has been considered as established facts must be reinvestigated using live (unfixed) cells. In this work, the uptake of analogs of penetratin, Tat(48-60), and heptaarginine in two different cell lines was studied by confocal laser scanning microscopy. For penetratin, an apparently endocytotic uptake was observed, in disagreement with previous studies on fixed cells found in the literature. Substitution of the two tryptophan residues, earlier reported to be essential for cellular uptake, did not alter the uptake characteristics. A heptaarginine peptide, with a tryptophan residue added in the C-terminus, was found to be internalized by cells via an energy-independent, non-endocytotic pathway. Finally, a crucial role for arginine residues in penetratin and Tat(48-60) was demonstrated.

The detection and evaluation of aneugenic chemicals.

Although aneuploidy makes a significant contribution to both somatic and inherited disease the mechanisms by which environmental chemicals may induce numerical chromosome aberrations are only poorly defined. The European Union Project was aimed to further our understanding of those chemical interactions with the components of the mitotic and meiotic cell division cycle which may lead to aneuploidy and to characterise the parameters such as cellular metabolism which may influence the activity of aneugenic chemicals. C-mitosis can be induced by the highly lipophilic polychlorinated biphenyl and the completion of mitosis and cleavage can be modified by agents which deplete cellular levels of reduced glutathione. Modifications of the fidelity of chromosome segregation were produced by inhibiting the functioning of topoisomerase II during chromatid separation. In contrast, the modification of centromere integrity resulted in chromosome breakage as opposed to disturbance of segregation. Modifiers of tubulin assembly and centriolar functioning in somatic cells such as acrylamide, vinblastine and diazepam reproduced their activity in rodent bone marrow and male germ cells. The analysis of chromosome malsegregation in Aspergillus nidulans by a structurally related series of halogenated hydrocarbons was used to develop a QSAR model which had high predictive value for the results of fungal tests for previously untested related chemicals. Metabolic studies of potential aneugens in genetically engineered human lymphoblastoid cells demonstrated the detoxification of the aneugenic activity of chloral hydrate and the activation of 2,3-dichlorobutane, 1,1,2-trichloroethane and trichloroethylene by Phase I biotransforming enzymes. Cell transformation studies in Syrian hamster dermal cultures using a panel of 22 reference and or potential aneugens indicated that 15 of the 22 produced positive results following single exposures. Five of the aneugens which were negative following single exposures produced positive results where cultures were continuously exposed for up to 6 weeks to low concentrations following a single non-transforming exposure to the mutagen dimethyl sulphate. The transformation studies indicate that a significant proportion of chemical aneugens are potential complete carcinogens and/or co-carcinogens. To optimise the enumeration of chromosomes following exposure to potential chemical aneugens whole chromosome paints and centromere specific probes suitable for use in fluorescence in situ hybridisation (FISH) were developed for the rat, mouse and Chinese hamster and selected human probes evaluated for their suitability for routine use. Molecular chromosome probes were used to develop protocols for enumerating chromosomes in metaphase cells and centromeres and micronuclei in interphase cells. The analysis of segregation of specific centromeres in binucleate cells following cytochalasin B treatment was shown to be a potentially valuable system for characterising non-disjunction following chemical exposure. Whole chromosome paints and centromere specific probes were used to demonstrate the presence of dose-response thresholds following treatment with a reference panel of spindle inhibiting chemicals. These data indicate that the FISH technology is suitable for evaluating the relative hazards of low-dose exposures to aneugenic chemicals.

Mechanistic aspects on chemical induction of spindle disturbances and abnormal chromosome numbers

Work on the chemical induction of spindle disturbances and abnormal chromosome numbers, and work on the composition and biochemistry of the spindle are reviewed. Some early investigations have shown that there is an unspecific mechanism for chemical induction of spindle disturbances. This mechanism is based on the interaction of compounds with cellular hydrophobic compartments. Some compounds act differently and are more active than predicted from their lipophilic character. Selected compounds of that kind and their possible mechanisms of action are discussed. Changes in sulfhydryl and ATP levels, oxidative damage of membranes and impaired control of cytoplasmic Ca2+ levels are discussed in this context.

Spindle disturbances in mammalian cells. III: toxicity, C-mitosis and aneuploidy with 22 different compounds. Specific and unspecific mechanisms

Early investigations have shown that many chemically different compounds can cause disturbances of the spindle function (c-mitosis) in eukaryotic cells and that there is an unspecific (physical) mechanism based on the partitioning of the compound into cellular hydrophobic compartments. This suggests that the approach should be quantitative when testing compounds for this type of activity in vitro; effect/no effect is not the most pertinent question. The present study demonstrates how a set of reference compounds can be used in attempts to identify compounds that act by a more specific (chemical) mechanism to disturb the spindle function. All experiments were performed with an established cell line (V79 Chinese hamster). The results suggest that there is a good qualitative coupling in these cells between c-mitosis and aneuploidy with chemical treatment. Among compounds that are particularly active in relation to their lipophilic character are some chlorophenols, caffeine, diamide, diethyl maleate, 1-chloro-2,4-dinitrobenzene and tertiary butylhydroperoxide. This points to Ca2+-sequestering by mitochondria and/or cellular pH regulation (chlorophenols), Ca2+ release and sequestering by the endoplasmic reticulum (caffeine), enzymatic conjugation to glutathione (diethyl maleate, chlorodinitrobenzene) and hydroperoxide metabolism (t-butylhydroperoxide) as important target functions for specific activity.

Spindle disturbances in mammalian cells. I. changes in the quantity of free sulfhydryl groups in relation to survival and c-mitosis in V79 chinese hamster cells after treatment with colcemid, diamide, carbaryl and methyl mercury

Abstract Asynchronously growing V79 Chinese hamster cells were treated with colcemid, diamide, carbaryl and methyl mercury, which are all known to be spindle disturbing agents. For each compound the dose response for c-mitosis, survival and level of free sulfhydryl groups was investigated under comparable conditions. Diamide, carbaryl and methyl were all found to give a significant increase of c-mitosis at a dose giving a decrease of non-protein sulfhydryl groups (NPSH, mainly glutathione) of 30–40% suggesting that a decrease of this magnitude may have a predictive value for spindle disturbances. Despite this similarity at concentrations close to the respective thresholds it was found that the c-mitotic activity at higher concentrations was not a simple function of average NPSH decrease. Diamide, which rapidly oxidizes glutathione to glutathione disulfide, was a less efficient c-mitotic agent than carbaryl and methyl mercury in relation to average NPSH decrease at higher concentrations. Protein bound sulfhydryl groups (PSH) were not significantly affected with diamide and carbaryl at their lowest c-mitotic concentrations while methyl mercury caused a significant decrease already at concentrations below the lowest c-mitotic concentration. With colcemid a significant decrease of average NPSH (14%) and PSH (12%) was observed only with concentrations giving close to 100% c-mitotic cells. Concentrations giving more than 20% c-mitosis gave a pronounced decrease of survival with carbaryl, diamide and methyl mercury while no toxic effects were obtained with colcemid, not even with concentrations giving close to 100% c-mitosis. Carbaryl, diamide and methyl mercury caused increased glutathione peroxidase activity indicating that these compounds cause increased lipid peroxidation. The possible connection between peroxidative damage of membranes and c-mitosis is discussed.

Spindle disturbances in mammalian cells II. Induction of viable aneuploid/polyploid cells and multiple chromatid exchanges after treatment of V79 Chinese hamster cells with carbaryl modifying effects of glutathione and S9

Treatment of V79 cells with carbaryl increased the frequency of cells with elevated chromosome numbers (greater than 22). This effect of carbaryl was inhibited by simultaneous addition of glutathione or S9. Although selective forces seemed to act against cells with increased chromosome numbers, such cells were still significantly more frequent in treated compared with control cultures 74 h after treatment. In addition, a high adaptive value for these remaining aneuploid/polyploid cells was indicated because they were able to go through 2 successive rounds of replication immediately before fixation to the same extent as cells with chromosome numbers considered normal (21/22) for this cell line. Multiple chromatid exchanges were also observed after carbaryl treatment. The lack of single exchange events indicates that the effect may be systemic. However, additional experiments are required before this hypothesis can be confirmed or discarded. Considering the results obtained and the possible importance of gene dosage for tumor promotion, it is suggested that carbaryl should be tested for tumor promotion in vivo.

Chromosomal effects of newly identified water pollutants PBTA-1 and PBTA-2 and their possible mother compounds (azo dyes) and intermediates (non-ClPBTAs) in two Chinese hamster cell lines.

We performed the in vitro micronucleus (MN) test on 2-[2-(acetylamino)-4-[bis(2-methoxyethyl)amino]-5-methoxyphenyl]-5-amino-7-bromo-4-chloro-2H-benzotriazole (PBTA-1) and 2-[2-(acetylamino)-4-[N-(2-cyanoethyl)-ethylamino]-5-methoxyphenyl]-5-amino-7-bromo-4-chloro-2H-benzotriazole (PBTA-2), which are newly identified water pollutants from the Nishitakase river in Kyoto, Japan, and on their possible mother compounds (AZO DYE) and intermediates (non-ClPBTAs). We tested these compounds in the absence and presence of S9 mix in two Chinese hamster cell lines CHL and V79-MZ and scored MN, polynuclear and karyorrhectic (PN), and mitotic (M) cells. PBTA-2 in the absence of S9 mix induced the strongest responses in both cell lines. It was also a strong inducer of binucleate cells in PN cells in both cell lines, which suggested that it induced polyploidy. PBTA-1 showed clear positive results only in the absence of S9 mix and only in V79-MZ cells, inducing aneuploidy. In CHL cells AZO DYE-1 significantly induced MN cells in the presence of S9 mix, and AZO DYE-2 induced MN and PN cells, including binucleate cells and cells with a multilobed nucleus, in the absence of S9 mix. In V79-MZ cells, AZO DYE-1 and -2 induced primarily M cells in the presence of S9 mix. 9% of the M cells treated with 50 microg/ml AZO DYE-1 showed endoreduplication. AZO DYE-2 at 200 microg/ml condensed the chromatin in 100% of the cells. The non-ClPBTAs were a bit more cytotoxic than the other compounds and induced a slight increase in MN cells in both cell lines. Some of the chemicals tested induced a characteristic karyomorphology that might reflect abnormal cell division. Abnormalities of cell division could be detected in PN and M cells as well as in MN cells. Structure-activity relationships have also been discussed.

Spindle disturbances in mammalian cells IV. The action of some glutathione-specific agents in V79 Chinese hamster cells, changes in levels of free sulfhydryls and ATP, c-mitosis and effects on DNA metabolism

Abstract The glutathione-specific agents diamide, diethyl maleate and 1-chloro-2, 4-dinitrobenzene were found to induce a low frequency of c-mitosis (15%) at non-toxic concentrations concomitant with a 30–40% decrease of non-protein sulfhydryls. The frequency of c-mitosis did not increase further with increased concentrations until non-protein sulfhydryl levels were obtained suggesting depletion of reduced glutathione. The observed shape of the concentration-response curve for c-mitosis is particular to these 3 agents and caffeine among 22 different compounds being tested under comparable conditions. This suggests a similar mechanism of action and from what is known about caffeine this mechanism probably involves an impaired control of cytoplasmic free Ca2+. It is speculated that this impairment with the glutathione-specific agents is primarily due to depletion of a particular pool of reduced glutathione. Tertiary butylhydroperoxide which is a substrate for glutathione peroxidase(s) also causes c-mitosis when there is no significant decrease of non-protein sulfhydryls. The c-mitotic response was found to be biphasic with maintained control levels at an intermediate concentration. The humps in the concentration-response curve for c-mitosis appeared coincident with a mitogenic response (G1 → S). Since the latter type of effect most probably is Ca2+ dependent and since the spindle is sensitive to Ca2+ it is tentatively suggested that the c-mitotic effect of tertiary butylhydroperoxide is due to an increase of cytoplasmic Ca2+. Measurements performed imply that an increase of glutathione disulfide (diamide) is more inhibitory to uptake and incorporation of thymidine than a decrease of reduced glutathione per se (diethyl maleate). This difference is probably due to secondary effects on pertinent protein sulfhydryls with diamide, one possible target being the ribonucleotide reductase.

Enhanced mutagenic response of MNU by post-treatment with methylmercury, caffeine or thymidine in V79 Chinese hamster cells

Post-treatment with a non-toxic dose of thymidine, caffeine or methylmercury-hydroxide enhanced the mutagenic response from MNU at high doses, whereas no enhancement was observed with low doses of MNU. No mutagenic effects were found with thymidine, caffeine or methylmercury alone at the doses used. Quantitatively, the modifying effects observed were similar for the 3 agents which indicates the possibility of a similar way of action.

Sensitivity of cytokinesis to hydrophobic interactions. Chemical induction of bi-and multinucleated cells.

We have tested whether cytokinesis is as sensitive to hydrophobic interactions as karyokinesis, and evaluated the usefulness of the frequency of binucleated cells as end-point. Treating cultured cells for 2 or 24 h, with different lipophilic alcohols and chlorinated hydrocarbons made this possible. Colcemid and cytochalasin B were applied as positive controls for inhibition of karyokinesis and cytokinesis, respectively. Several-fold increases of binucleated cells could be seen with cytochalasin B after 2 h of treatment, while there was no increase with colcemid, which instead blocked cells in prometaphase/metaphase. The solvent acted primarily through hydrophobic interactions. For each solvent, the blocking of cells in prometaphase/metaphase and a minor increase in binucleated cells, were seen at approximately the same concentration; the binucleated cells probably emanated from cells in anaphase/telophase at the start of treatment. We conclude that the spindle function and cleavage show similar sensitivity to hydrophobic interactions. After prolonged treatment, allowing escape from the metaphase block, the solvents induced binucleated and multinucleated cells. By forming the quotient between multinucleated (MULTI) and binucleated (BIN) cells one could distinguish between effects primarily on the spindle or cytokinesis, respectively. All solvents, and a combination of colcemid and cytochalasin B, showed quotients intermediate between those observed with colcemid (high MULTI/BIN) and cytochalasin B (low MULTI/BIN), respectively. Both protocols revealed the same relationship between lowest active concentration and lipophilicity for the solvents, implying that concentration, not dose were of prime importance. The specific inhibitors acted at low concentrations in relation to lipophilicity, clearly demonstrating their chemical mechanisms. This approach can be used for rapid screening of potential aneugens, distinguishing between routes, and when lipophilicity is known, also reveal the principal mechanism of action, i.e. physico-chemical or chemical.