Antigenotoxic and antimutagenic effects of lignin derivative BP-C2 against dioxidine and cyclophosphamide in vivo in murine cells.

The study investigated antigenotoxic and antimutagenic activity of novel lignin-derived polyphenolic composition (BP-C2) with ammonium molybdate towards cyclophosphamide and dioxidine in the bone marrow, blood and liver cells of BALB/c mice. BP-C2 was given to mice via gavage at 60, 80 and 120 mg/kg once 1 h before single intraperitoneal injection of a genotoxic agent. 1.5 h and 3 h after dioxidine or cyclophosphamide injection, respectively, cellular suspensions were obtained from mice and assessed with the comet test and cytogenetic analysis of bone marrow cells. It was observed that antigenotoxic activity of BP-C2 against DNA damage induced by dioxidine, a prooxidant genotoxic agent, in the bone marrow, liver and blood cells of mice in vivo was more pronounced at 60 and 80 mg/kg than at 120 mg/kg. When cyclophosphamide was used to induce a DNA damage, the genoprotective effect of BP-C2 was observed in bone marrow, liver and blood cells at 60 mg/kg dose but the effect was not significant at 80 mg/kg. When co-administered with 120 mg/kg BP-C2, cyclophosphamide induced a higher level of DNA damage in liver cells, but its genotoxic effect in bone marrow and blood cells was the same as when it was administered alone. When assessing the effect of BP-C2 on chromosomal aberrations induced by cyclophosphamide and dioxidine in bone marrow cells, it was revealed that all three tested doses of BP-C2 significantly decreased the number of cells with chromosome abnormalities. Thus, BP-C2 has a pronounced antimutagenic and genoprotective effects.

Comet assay on one- and two-cell mouse embryos.

DNA damage quantified as the comet tail length was assessed using in vitro and in vivo comet assay on one- and two-cell mouse embryos obtained by natural mating. The use of a protocol with three layers of agarose reduces the embryo loss and makes it possible to study a small number of embryos. A significantly lower level of basal, but not induced DNA damage was found in embryos with cleaved zona pellucida compared to embryos with intact zona pellucida. There were no significant differences in the length of the comet's tail between embryos lysed in different lysis solutions, both in cases of basal and induced DNA damage. A significant increase in the comet tail length was detected in one-cell embryos of mice treated with methyl methanesulfonate and etoposide compared to the control. The data show that DNA damage induced in maternal germ cells persists, which can be detected in embryos using the comet assay.

Genotoxicity of cationic lipopeptide nanoparticles.

The genotoxicity of cationic lipopeptide nanoparticles (cLPNPs) was evaluated in vivo and in vitro comet assay and the in vivo chromosome aberrations test. In vitro comet assay, human blood cells were exposed to cLPNPs at the concentration of 2.5, 5, 10, 20, 40 and 100 µg/mL. Significant DNA damage was observed after 1 h exposure, but no effects were detected after 3 h. In vivo, cLPNPs were administered in single or five daily injection doses at 8, 20 and 40 mg/kg of body weight by subcutaneous injection to male mice. The cLPNPs caused DNA damage in the liver, lung and kidney, but not in the spleen. The kidney was more prone to genotoxic effects that persisted from 24 h to 14d after a single injection of cLPNPs. No statistically significant increase in the percentage of cells with chromosomal aberrations above the vehicle control was observed in mice bone marrow after a single or repeated injection of cLPNPs. In summary, cLPNPs shown to be genotoxic both in vivo and in vitro. The results suggest the importance of the use of highly sensitive methods, such as the comet assay, in order to determine the full genotoxic potential of nanoparticles.

Genotoxicity of two new carbazole derivatives with antifungal activity.

The class of carbazoles includes compounds with high biological activities and broad spectra of action. PLX01107 and PLX01008 are xenomycins, a new subclass of antimicrobial carbazole derivatives demonstrating strong antifungal activity in vitro. We performed three tests, a bacterial reverse mutation assay (Ames test), in vitro cytokinesis-block micronucleus assay, and chromosome aberration test in mouse bone marrow cells, to investigate the possible genotoxicity of these compounds. Despite their structural similarity, the two compounds had different genotoxicity profiles. PLX01008 showed positive effects in all assays. PLX01107 showed no mutagenicity in the Ames test but demonstrated strong cytogenetic activity in vitro and in vivo. PLX01107 was also tested in the in vivo alkaline comet assay, where a weak but statistically significant increase in DNA damage was seen in liver cells 24h after treatment. Significantly increased levels of formamidopyrimidine DNA glycosylase (FPG)-sensitive sites were found in bone marrow cells of PLX01107-treated mice (FPG-modified comet assay), suggesting induction of oxidative or alkylation damage to DNA.

Some causes of inter-laboratory variation in the results of comet assay.

We performed an inter-laboratory study to determine the variation of comet assay results and to identify its possible reasons. An exchange of slides between Labs in different stages of the comet assay protocol was performed. Because identical slides, durations of alkali treatment and electrophoresis, and similar electric field strengths (2.0 V/cm and 2.14 V/cm) were used, we concluded that the observed inter-laboratory difference in the results is directly associated with the electrophoresis step. In Lab 1, mouse bone marrow cells were exposed to methyl methanesulfonate at concentrations of 10, 25 and 50 µM for 3 h at 37 °C. In Lab 2, cells the same as in Lab 1 were immobilized in LMA on slides and exposed to X-rays at doses of 3-8 Gy. We found that the transportation of slides after lysis or electrophoresis step, as well as different dyes used for scoring did not produce any significant effect on the results. No substantial difference in the data was also revealed when various software packages were used for image analysis. The temperature of the alkaline solution was shown to increase during electrophoresis and, besides, the temperature heterogeneity of the solution took place in the area of the platform, with a maximum in the middle of the chamber. The temperature heterogeneity could affect the rate of conversion of alkali labile sites into single stranded breaks. Thus, it was clearly indicated that real temperature variations during the alkali treatment and electrophoresis were an essential factor in the variability of the results between our Labs.