Evaluation of anti-tumour properties of two depsidones - Unguinol and Aspergillusidone D - in triple-negative MDA-MB-231 breast tumour cells.

There is an ongoing search for new compounds to lower the mortality and recurrence of breast cancer, especially triple-negative breast cancer. Naturally occurring depsidones, extracted from the fungus Aspergillus, are known for their wide range of biological activities such as cytotoxicity, aromatase inhibition, radical scavenging, and antioxidant properties. Research showed the potential of depsidones as a treatment option for hormone receptor-positive breast cancer treatment, yet its effects on hormone receptor-negative breast cancer are still unkown. This study, therefore, investigated the potential of two depsidones (Unguinol and Aspergillusidone D) to induce apoptosis, cell cycle arrest and cytotoxicity, and reduce cell proliferation in the triple-negative MDA-MB-231 breast cancer cell line. Results were compared with the effects of the cytostatic drug doxorubicin, antimitotic agent colchicine and endogenous hormones 17ß-estradiol, testosterone and dihydrotestosterone. The cytostatic drugs and hormones affected the MDA-MB-231 cell line comparable to other studies, showing the usefulness of this model to study the effects of depsidones on a triple-negative breast cancer cell line. At sub µM levels, Unguinol and Aspergillusidone D did not influence cell proliferation, while cell viability was reduced at concentrations higher than 50 µM. Both depsidones induced apoptosis, albeit not statistically significantly. In addition, Unguinol induced cell cycle arrest in MDA-MB-231 cells at 100 µM. Our research shows the potential of two depsidones to reduce triple-negative breast cancer cell survival. Therefore, this group of compounds may be promising in the search for new cancer treatments, especially when looking at similar depsidones.

Exposure to benzene in various susceptible populations: co-exposures to 1,3-butadiene and PAHs and implications for carcinogenic risk.

Exposure to benzene in human populations can occur in various work-related settings in which benzene is used or produced, or from traffic emissions resulting from incomplete combustion of fossil fuel, or from other sources. Two scenarios of benzene exposure were studied in 4 susceptible groups in Thailand. The first scenario is work-related exposures primarily to benzene, with the study subjects consisting of petrochemical laboratory workers and gasoline service station attendants, who are exposed at levels of 78.32 and 360.84 microg/m(3), respectively. The second scenario is traffic-related exposure and exposure to incense smoke, where co-exposures to other pollutants occurs, with the study groups consisting of school children attending schools in the city center and exposed to traffic emissions, and temple workers exposed to incense smoke. The individual benzene exposure levels were approximately 19.38 microg/m(3) in city school children and 45.90 microg/m(3) in temple workers. Co-exposures to 1,3-butadiene and polycyclic aromatic hydrocarbons (PAHs) generated from the same sources occurred in the second exposure scenario. 8-OHdG, DNA strand breaks and DNA repair capacity were measured as biomarkers of early effects of carcinogenic compound exposure. Petrochemical laboratory workers and gasoline service stations attendants had significantly higher levels of DNA strand breaks and significantly lower DNA repair capacity compared to controls, while gasoline service station attendants also had significantly higher levels of 8-OHdG than controls. City school children had significantly higher levels of PAH-DNA adducts, 8-OHdG, and DNA strand breaks and significantly lower levels of DNA repair capacity compared to rural children. Temple workers also had significantly higher levels of 8-OHdG and DNA strand breaks and significantly lower levels of DNA repair capacity compared to controls. In all of the study groups, the levels of benzene exposure correlated significantly with 8-OHdG levels, DNA strand breaks, and DNA repair capacity. In school children, PAH levels also correlated significantly with 8-OHdG levels, DNA strand breaks and DNA repair capacity. In temple workers, 1,3-butadiene levels correlated significantly with 8-OHdG and DNA strand breaks, but not with DNA repair capacity, while in the school children they did not correlate significantly with 8-OHdG or DNA strand breaks, and correlated marginally significantly with DNA repair capacity (deletions per metaphase). Multivariate regression analysis identified total PAHs concentrations converted to B[a]P equivalents as the only factor significantly affecting 8-OHdG levels, and total PAHs concentrations converted to B[a]P equivalents, as well as 1,3-butadiene concentrations as the factors significantly affecting DNA repair capacity in the school children. PAHs concentration was identified as the factor most significantly affecting DNA strand breaks in temple workers, followed by benzene concentrations, while DNA repair capacity was also significantly influenced by PAHs concentrations.

PROGRAMMABLE DIELECTROPHORETIC µTAS SAMPLE HANDLING.

We present the concept of a general-purpose sample analysis platform (GSAP) based on dielectrophoretic methods. The platform architecture comprises integrated functional blocks that can be programmed to perform a diverse range of analysis steps, including the on-device preparation of real world samples.

Dielectrophoretic detection of changes in erythrocyte membranes following malarial infection.

The dielectric properties of normal erythrocytes were compared to those of cells infected with the malarial parasite Plasmodium falciparum. Normal cells provided stable electrorotation spectra which, when analyzed by a single-shelled oblate spheroid dielectric model, gave a specific capacitance value of 12 +/- 1.2 mF/m2 for the plasma membrane, a cytoplasmic permittivity of 57 +/- 5.4 and a cytoplasmic conductivity of 0.52 +/- 0.05 S/m. By contrast, parasitized cells exhibited electrorotation spectra with a time-dependency that suggested significant net ion outflux via the plasma membrane and it was not possible to derive reliable cell parameter values in this case. To overcome this problem, cell membrane dielectric properties were instead determined from dielectrophoretic crossover frequency measurements made as a function of the cell suspending medium conductivity. The crossover frequency for normal cells depended linearly on the suspension conductivity above 20 mS/m and analysis according to the single-shelled oblate spheroid dielectric model yielded values of 11.8 mF/m2 and 271 S/m2, respectively, for the specific capacitance and conductance of the plasma membrane. Unexpectedly, the crossover frequency characteristics of parasitized cells at high suspending medium conductivities were non-linear. This effect was analyzed in terms of possible dependencies of the cell membrane capacitance, conductance or shape on the suspension medium conductivity, and we concluded that variations in the membrane conductance were most likely responsible for the observed non-linearity. According to this model, parasitized cells had a specific membrane capacitance of 9 +/- 2 mF/m2 and a specific membrane conductance of 1130 S/m2 that increased with increasing cell suspending medium conductivity. Such conductivity changes in parasitized cells are discussed in terms of previously observed parasite-associated membrane pores. Finally, we conclude that the large differences between the dielectrophoretic crossover characteristics of normal and parasitized cells should allow straightforward sorting of these cell types by dielectrophoretic methods.

Effects of pyridoxine deficiency on the metabolism of N-nitrosodimethylamine in the rat.

The alteration in the metabolic activation of N-nitrosodimethylamine (NDMA) was investigated in the rat during dietary pyridoxine deficiency. The in vitro metabolism of NDMA by demethylase system was measured in both liver and kidney microsomes. The profile of the kidney enzyme appears similar to that of the liver indicating that at least two forms of isozymes with the low and the high Km's are present. Pyridoxine deficiency significantly increased the activity of NDMA-demethylase of both organs. The increase in the activity of NDMA-demethylase induced by dietary pyridoxine deficiency can be reversed by supplementation of pyridoxine (500 micrograms), i.p., daily for two consecutive days. The increase in the NADPH cytochrome c reductase activity was observed after 6 weeks on pyridoxine-deficient diet.

Alterations in dimethylnitrosamine-induced lethality and acute hepatotoxicity in rats during dietary thiamin, riboflavin and pyridoxine deficiencies.

The effects of dietary thiamin, riboflavin and pyridoxine deficiencies on dimethylnitrosamine-induced lethality and hepatotoxicity were investigated in the rat. Development of deficiencies was monitored by growth rate, food intake, ratio of liver weight to body weight and the biochemical parameters (thiamin diphosphate effects for thiamin deficiency, glutathione reductase activity coefficient for riboflavin deficiency and erythrocyte glutamate-oxaloacetate transaminase activity for pyridoxine deficiency). Thiamin deficiency slightly increased the acute toxicity of dimethylnitrosamine as observed by the lowering of the LD50 dose and the greater increase in the serum glutamate-oxaloacetate transaminase and serum glutamate-pyruvate transaminase levels. Riboflavin deficiency, on the other hand, slightly increased the LD50 dose of dimethylnitrosamine and resulted in less dimethylnitrosamine-induced damage to the liver. Pyridoxine deficiency did not affect the lethal dose nor significantly alter the transaminases levels.

UV-induced photoproducts of 5-methylcytosine in a DNA sequence context.

In order to detect possible m5C photoproducts, highly purified rat liver DNA-cytosine methyltransferase was used to specifically generate m5C with a radioactive methyl group. When these DNAs were subjected to a large dose (10 kJ/m2) of 254 nm or 302 nm ultraviolet light (UVB) to enhance the yield, two labeled photoproducts were detected and isolated by reverse phase HPLC after formic acid hydrolysis. Further studies using acetone as a triplet state sensitizer and UVB irradiation suggested that photoproduct II was activated via a triplet state while the more polar photoproduct I was not. Photoreversion of the purified photoproducts with 10 kJ/m2 254 nm light demonstrated the following reactions: Photoproduct I regenerated m5C, while photoproduct II is split and regenerated m5C and photoproduct I. These results suggest that photoproduct I is monomeric while photoproduct II dimeric, and from the latter's elution position possibly a cyclobutyl type dimer arising from a reaction with an adjacent cytosine. Using d[TTG] and d[Cm5CG] as models of typical sequences, irradiation with 10 kJ/m2 254 nm or 302 nm, respectively, gave rise to a small component having altered mobility in sequencing gels. The altered mobility trinucleotides were resistant to degradation by PI and micrococcal nucleases as expected from photodimerization of the pyrimidine bases. Furthermore, oligonucleotide substrates containing m5C were synthesized and shown to be susceptible to T4 endonuclease v action at locations consistent with d[Cm5C] photodimer formation when irradiated in the UVB range.

Kinetic mechanisms and interaction of rat liver DNA methyltransferase with defined DNA substrates.

DNA substrate analogs were constructed from poly(dC-dG), M13, and XP12 DNA which do not contain a mixture of types of methylation sites. These were used to distinguish different kinetic mechanisms for maintenance and de novo methylation using a highly purified rat liver DNA (cytosine-5) -methyltransferase (DMase+) preparation. De novo methylation on single (ss) and double-stranded (ds) DNA was found to obey Michaelis-Menten kinetics while methylation of hemimethylated sites showed differences depending on size of the hemimethylated region. On long stretches analogous to maintenance methylation of newly replicated DNA, saturation could not be achieved and the kinetics showed non-ideal positive cooperative kinetics, while short stretches showed non-Michaelis-Menten kinetics and rapid saturation. Two types of DMase-DNA complexes could be distinguished by means of affinity chromatography on DNA -agarose matrices and in preincubation assays. The later complex, which is engaged in methyl group turnover, exhibited enhanced stability. The competitiveness of variously configured DNAs was found to parallel the stability of complex formation, e.g., ss, hemi- and ds DNA, respectively. In studies utilizing 5-bromodeoxyuridine, the thymine analog left the basic reaction mechanisms unchanged but increased the km and S0.5 while reducing the velocity of these reactions.

Perturbation of maintenance and de novo DNA methylation in vitro by UVB (280-340 nm)-induced pyrimidine photodimers.

The effect of pyrimidine photodimers on transmethylation reactions catalyzed by a highly purified rat liver DNA (cytosine-5-)-methyltransferase (EC 2.1.1.37) that exhibits maintenance and de novo methylation activities was studied in vitro, using the viral substrates M13 mp9 replicative form (RF) DNA and the hemimethylated analog formed from primed synthesis of phage DNA in the presence of 2'-deoxy-5-methylcytidine 5'-triphosphate. These DNAs were irradiated with UVB (280-340 nm) at 900-3600 J/m2 in the presence of the triplet-state sensitizers acetone or 3-dimethylaminopropiophenone. Under these conditions of irradiation, which approximate solar UV, pyrimidine cyclobutane photodimers were introduced without producing any evidence of single-strand breaks or alkali-sensitive sites [i.e., no (6-4)pyrimidine-pyrimidone photoproducts]. This was confirmed by gel analysis, a T4 UV endonuclease nicking assay specific for cyclobutane-type dimers, and HPLC analysis of the photoproducts. The methylation of irradiated templates by DNA methyltransferase was inhibited in an approximately linear fashion as a function of increasing UVB dose. This inhibition was correlated with the number of lethal photoproducts detected by the simultaneous measurement of the surviving fraction of infectious phage DNA. For approximately the same number of pyrimidine cyclobutane photoproducts introduced, de novo methylation activity was approximately 2-fold more sensitive than the maintenance mode of methylation. The ability of these putatively carcinogenic, pyrimidine photoproducts to inhibit DNA methylation suggests a common mechanism of action with several chemical carcinogens that are known to modify bases.

Indistinguishable physical and catalytic properties of DNA methyltransferase from normal rat liver and a transplantable rat hepatocellular carcinoma.

DNA methyltransferase (DMase) was purified 700- and 1002-fold from normal rat liver and transplantable hepatocellular carcinoma 252 (THC 252) nuclei, respectively, using a four-step procedure that included chromatography on phosphocellulose, hydroxylapatite, DEAE-Sephacel and gel filtration on AcA 34. The enzymes had identical characteristics: pI = 7.4-7.6; Mr = 280 000 by gel filtration; preference for methylating double-stranded over single-stranded DNA and hemimethylated over unmethylated DNA templates; and apparent km of 10 microM for dinucleotide units in poly(dC-dG) and 0.5 microM for S-adenosylmethionine (SAM). Thermal inactivation profiles and sulfhydryl group alkylation inhibition curves for fraction III produced very similar single-transition curves, suggesting the presence of a single-functional enzyme species that is indistinguishable between normal and tumor tissue. Single-value Michaelis-Menten kinetics were obtained for fraction IV enzymes with respect to the concentration of SAM and dinucleotide units in poly(dC-dG), suggesting the absence of isozymic or multiple forms of DMase in normal and malignant liver tissues.

Mechanism of rat liver DNA methyltransferase interaction with anti-benzo[a]pyrenediol epoxide modified DNA templates.

We investigated the methylation reaction catalyzed by 1500-fold purified rat liver DNA methyltransferase (DMase) on native Micrococcal luteus DNA (ML-DNA) and poly(dC-dG) templates containing covalently bound (+)-7 beta,8 alpha-dihydroxy-9 alpha,10 alpha-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene (anti-BPDE), the strongly carcinogenic, principal metabolite of benzo[a]pyrene. Since eukaryotic DNA methyltransferases recognize the dinucleotide 5'd[CG] in DNA as a substrate for methylation, the model polynucleotide poly(dC-dG) was used to study in more detail the mode of interaction and effect on incorporation. With either of these BPDE-modified templates, a progressive inhibition of methylation was correlated with increasing amount of BPDE substitution. The effect of BPDE-dG adducts did not alter the apparent km with respect to the concentration of d[CG] in either unmodified or BPDE-modified poly(dC-dG) (km = 10 microM) but lowered the relative apparent Vmax. In assays in which perturbation by salt of preformed enzyme-DNA complex is measured, no change in the relative stability to either unsubstituted or the carcinogen-modified template was noted, thus, excluding any change in the ionic component of this interaction. However, in competition-type experiments, BPDE-DNA is an inhibitor of the methylation reaction on native DNA. When BPDE-DNA is allowed to interact with the enzyme before the addition of native competitor DNA, the methylation rate is not stimulated, suggesting very tight hydrophobic binding of the enzyme to BPDE-DNA and an inhibition in the dissociation of DMase from the template following a methylation event.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of riboflavin on the dimethylnitrosamine demethylase system in the rat liver.

The effects of riboflavin on the dimethylnitrosamine [(DMN) CAS: 62-75-9; N-nitrosodimethylamine] demethylase system in inbred F344 rat liver were investigated. Dietary riboflavin deficiency markedly stimulated the activity of DMN demethylase I operating at a low substrate concentration (4 mM), but it caused no change in the activity of DMN demethylase II operating at a high substrate concentration (200 mM). This effect could be reversed by short-term supplementation of the vitamin by a series of three ip injections (0.5 mg/dose/day) to the deficient animals. This dosage regimen of riboflavin did not change the activity of DMN demethylase I in the normal animals. The study in vitro demonstrated that flavins were inhibitory to DMN demethylase I. The enzyme activity in the microsomes of both control and deficient animals was inhibited by preincubation with flavins, suggesting that the interaction between flavins and the enzyme rendered the enzyme inactive. Flavin adenine dinucleotide (FAD) appeared to have a more pronounced effect than riboflavin. In agreement with the earlier observation, DMN demethylase II was unaffected by FAD or riboflavin.

Interaction of DNA methyltransferase with aminofluorene and N-acetylaminofluorene modified poly(dC-dG).

Poly(dC-dG) was reacted in vitro to yield templates containing similar amounts of aminofluorene (AF) or acetylaminofluorene (AAF) adducts. These modified poly(dC-dG) templates were tested in an in vitro DNA methylation system utilizing 1500-fold purified rat liver methyltransferase (DMase) to compare and quantitate the effects of these adducts on the kinetics of methylation and the interaction of DMase with such templates. Enzymatic methylation is severely impaired by arylamine adducts, with bound AF inhibiting more than AAF (relative Vmax 0.24 for AAF-poly(dC-dG) and 0.066 for AF-poly(dC-dG). The apparent km for the reaction is not appreciably altered by AAF modification: 10 microM for dCdG dinucleotide units, but it is threefold lower (3 microM) for AF-poly(dC-dG). In competition experiments it was demonstrated that a translocational block is imposed by the adducts. From differential salt inhibition assays and preincubation assays, no change in the ionic binding to the altered templates could be detected, which suggests that the enzyme interacts very strongly through hydrophobic interactions with the fluorene ring. Evidence that the fluorene ring is exposed is supported by circular dichroism spectra of the templates under the conditions of the assay, which indicated that the AF adducts do not appreciably change the normal B conformation of the template, while the template with 9.5% modification by AAF adducts adopted a Z form. These results suggest that the inhibitory effects of AAF and, in particular, AF upon DMase-catalyzed methylation reactions are not dependent upon helix conformation. Instead, they appear to depend upon DMase recognition of an altered dG base configuration, which is responsible for altered binding and methylation kinetics.

The protective role of thiol reducing agents in the in vitro inhibition of rat liver DNA methylase by direct acting carcinogens.

The direct-acting carcinogens N-acetoxy-N-acetyl-2-aminofluorene (AcAAF), methyl nitrosourea (MNU), and N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) were tested for their ability to inhibit highly purified, rat liver DNA methylase in vitro. Fifty percent inhibition of DNA methylase activity was achieved with 4.3 mM AcAAF, 47 mM MNU and 2.8 mM MNNG. When the enzyme was reassayed in the presence and absence of dithiothreitol, it was shown that DNA methylase was protected by increasing amounts of the thiol reducing agent. When other thiol reducing agents were tested for their ability to protect DNA methylase from carcinogen damage, a differential protective ability was observed. Dithiothreitol, beta-mercaptoethanol, and reduced glutathione were effective in protecting DNA methylase from carcinogen inhibition, while the effect of cysteine was intermediary and the effect of ergothioneine was minimal. These results may be related to the hypomethylation of DNA observed in several cancers, suggesting that the carcinogens achieve this effect at least in part by inhibiting crucial sulfhydryl group(s) in the methylase molecule. These data also suggest that various intracellular thiols may play an important role in protecting DNA-modifying enzymes from carcinogen damage.

Inhibitory effects of carbon tetrachloride on dimethylnitrosamine metabolism and DNA alkylation.

The effect of CCl4 pretreatment (dose range from 0.5 to 2.0 ml/kg body weight) on the pathways of dimethylnitrosamine (DMN) metabolism was investigated. The oxidative-N-demethylation by the enzymes, DMN-demethylase I and II operating at low (4 mM) and high (200 mM) substrate concentration, respectively, was greatly reduced in a dose-dependent manner. In addition, the generation of an electrophilic intermediate capable of methylating DNA, specifically at the N-7 and O-6 positions of guanine, was completely inhibited by CCl4 (0.5 ml/kg body weight) pretreatment. When indole feeding (1% in the diet for 8 days prior to CCl4 administration) was employed as a means to enhance DMN-demethylase activities, it was found that the reduction of DMN-demethylase activities was more pronounced in these rats than in the controls. In agreement with earlier findings, 7-methylguanine and O6-methylguanine were not detectable in the CCl4 pretreated group. These results suggest that CCl4 exerts a strong inhibitory action on hepatic DMN metabolism, in particular on the pathway leading to alkylation of DNA guanine. This phenomenon may explain the protective role of CCl4 against DMN-induced hepatotoxicity and perhaps, carcinogenicity, believed to be closely associated with the abnormal modifications of DNA.