Synthetic wastewaters treatment by electrocoagulation to remove silver nanoparticles produced by different routes.

Nanoscience is a field that has stood out in recent years. The accurate long-term health and environmental risks associated with these emerging materials are unknown. Therefore, this work investigated how to eliminate silver nanoparticles (AgNPs) from synthetic effluents by electrocoagulation (EC) due to the widespread use of this type of nanoparticle (NP) in industry and its potential inhibition power over microorganisms responsible for biological treatment in effluent treatment plants. Synthesized AgNPs were studied via four different routes by chemical reduction in aqueous solutions to simulate the chemical variations of a hypothetical industrial effluent, and efficiency conditions of the EC treatment were determined. All routes used silver nitrate as the source of silver ions, and two synthesis routes were studied with sodium citrate as a stabilizer. In route I, sodium citrate functioned simultaneously as the reducing agent and stabilizing agent, whereas route II used sodium borohydride as a reducing agent. Route III used D-glucose as the reducing agent and sodium pyrophosphate as the stabilizer; route IV used sodium pyrophosphate as the stabilizing agent and sodium borohydride as the reducing agent. The efficiency of the EC process of the different synthesized solutions was studied. For route I, after 85 min of treatment, a significant decrease in the plasmon resonance peak of the sample was observed, which reflects the efficiency in the mass reduction of AgNPs in the solution by 98.6%. In route II, after 12 min of EC, the absorbance results reached the detection limit of the measurement instrument, which indicates a minimum reduction of 99.9% of AgNPs in the solution. During the 4 min of treatment in route III, the absorbance intensities again reached the detection limit, which indicates a minimum reduction of 99.8%. In route IV, after 10 min of treatment, a minimum AgNP reduction of 99.9% was observed. Based on these results, it was possible to verify that the solutions containing citrate considerably increased the necessary times required to eliminate AgNPs from the synthesized effluent, whereas solutions free of this reagent showed better results on floc formation and, therefore, are best for the treatment. The elimination of AgNPs from effluents by EC proved effective for the studied routes.

Domoic acid induces direct DNA damage and apoptosis in Caco-2 cells: recent advances.

Domoic acid (DA) is a neurotoxin produced by sea-water phytoplankton. Shellfish feeding on the phytoplankton can bioconcentrate DA, leading to a potentially serious health hazard for people consuming the contaminated shellfish. DA is the principal toxin responsible for amnesic shellfish poisoning (ASP). The toxic mechanism of DA is believed to be mediated at the level of the mitochondria, where uncoupling of oxidative phosphorylation decreases membrane permeability, causing cell swelling and ultimately lysis. Literature is poor concerning data on the possible genotoxicity and cytotoxicity of DA. In the present study, we have evaluated the cytotoxicity and genotoxicity of DA on a human colorectal adenocarcinoma cell line (Caco-2). Our results clearly demonstrate that DA decreased cell viability (IC(50) about 70 ng/mL), induced direct DNA damage from 15 ng/mL, and apoptosis in Caco-2 cells at 100 ng/mL. This apoptosis is likely bax-dependent and occurred only at high concentrations of DA, while lower concentrations upregulated both bax and bcl-2 at an apparent constant ratio until a sudden decrease of bcl-2 at 100 ng/mL and increase of bax.

Micronucleus induction in mussels exposed to okadaic acid.

Some toxins present in the marine environment are capable of inducing mutagenicity and/or carcinogenicity. Among these toxins, okadaic acid (OA) is gaining considerable interest since it induces DNA based modifications at low concentrations and accumulates in filter-feeding marine animals, including those used for human consumption. This study aims to evaluate the genotoxicity of OA in the haemocytes of the mussel Perna perna, using the micronucleus assay. Fifty-four mussels were separated into three groups of 18 animals. One group received 0.3 microg of OA diluted in 10 microl of ethanol and ultrapure water while the other groups were considered as controls and were exposed to a solvent plus seawater mixture. A significantly higher frequency of micronuclei was observed in haemocytes from the OA-exposed group. There were no statistical differences between the two control groups.

Transplacental passage of [3H]-okadaic acid in pregnant mice measured by radioactivity and high-performance liquid chromatography.

Okadaic acid (OA) is the main toxin produced by dinoflagellates, which can accumulate in the hepatopancreas of mussels and cause diarrhoetic shellfish poisoning in consumers. This toxin is also a tumour promoter and a specific potent inhibitor of protein phosphatases 1 and 2A. The results in this study show for the first time that this marine toxin is able to cross the transplacental barrier. Foetal tissue contains more okadaic acid than the liver or kidney: 5.60% compared to 1.90 and 2.55% respectively as measured by HPLC and fluorescent detection after derivatization with 9-Anthryldiazomethane (ADAM). In view of its adverse effects, okadaic acid might impair foetal development and promote tumours in neonates.

Variations in the distribution of okadaic acid in organs and biological fluids of mice related to diarrhoeic syndrome.

Okadaic acid (OA) is the main toxin produced by dinoflagellates which can accumulate in the hepatopancreas of mussels and cause diarrhetic shellfish poisoning in consumers. This toxin is also a tumour promoter and a specific potent inhibitor of protein phosphatases 1 and 2A. No specific target organ is known for this toxin. This study concerns the distribution of [3H]OA in organs and biological fluids of Swiss mice having received a single dose per os of AO (50 microg/kg). The determination of the toxin extracted from mouse organs 24 h after administration of [3H]OA and derivatised with 9-anthryldiazomethane (ADAM) before HPLC and fluorescent detection showed the highest concentration in intestinal tissue and stomach. This distribution was even more pronounced in intestinal tissue, when animal were given per os 90 microg/kg which induced diarrhoea. The high concentrations of [3H]OA in intestinal tissues and contents 24 h after administration demonstrates a slow elimination of OA. When the dose of OA was increased from 50-90 microg/kg, the concentrations of the toxin in the intestinal content and faeces increased proportionally. A good correlation was found between an increase of OA in the intestinal tissue and the diarrhoea in animals given 90 microg/kg orally. Moreover OA was present in liver and bile and in all organs including skin and also fluids. Altogether these results confirmed an enterohepatic circulation of OA as previously shown. These data also revealed that in acute OA intoxication the concentration of the toxin in the intestinal tissues reaches cytotoxic concentrations in accordance with the diarrhoea which is the main symptom of OA poisoning.

Oxygen reactive radicals production in cell culture by okadaic acid and their implication in protein synthesis inhibition.

Okadaic acid (OA), a diarrhetic shellfish toxin is a potent promoter of tumours in mouse skin and a specific inhibitor of protein phosphatases 1 and 2A. Recently it has been shown that OA inhibited protein synthesis in a cell-free system, with 50% inhibitory concentration of 6.3x10(-12) M but the mechanism whereby this inhibition is mediated was still unclear. In the present study, the effect of OA on protein synthesis in Vero cell cultures was investigated. Protein synthesis was inhibited by OA alone in Vero cells in a concentration-dependent manner (IC50=27 ng/ml i.e. 3. 3x10(-8) M). Since OA also induced lipid peroxidation and likely oxygen reactive radicals, it was interesting to know whether these radicals impair the protein synthesis process. Therefore, SOD+catalase known as scavenger of active oxygen radicals were added in the culture medium in the presence of OA and labelled leucine. These enzymes partially prevented the inhibition of protein synthesis induced by OA, indicating that the formation of high reactive oxygen free radicals could be one of the pathways this marine toxin induces its toxicity. Since the prevention by SOD+catalase was only partial (the IC50 increased from 27 ng/ml to 48 ng/ml i.e. 3.3x10(-8) M to 5.9x10(-8) M) it was speculated that the production of oxygen reactive radical scavengered by SOD+catalase is not the main mechanism whereby OA induces its cytotoxicity. Vitamins E and C completely prevent the lipid peroxidation induced by OA in cells, but failed to reduce the inhibition of protein synthesis to the same level, indicating that a more specific mechanism might be responsible for protein synthesis inhibition. That is the hyperphosphorylation of elongation factor EF-2 in the protein synthesis machinery. However our results pointed to lipid peroxidation being a precocious phenomenon following the OA exposure, since a concentration with enhanced MDA production was lower than that inducing significant cellular protein synthesis inhibition.

Micronucleus test in mussels Perna perna fed with the toxic dinoflagellate Prorocentrum lima.

Micronucleus (MN) and other nuclear abnormalities have been measured in the hemocytes of mussels Perna perna to verify whether feeding mussels with different concentrations of Prorocentrum lima results in accumulation of levels of okadaic acid (OA) capable of inducing genotoxic effects at the chromosome level, as evidenced by micronuclei and nuclear abnormalities. Four groups of 12 mussels housed individually in aquaria containing filtered seawater were fed with different concentrations of P. lima. Another group collected directly from the production area served as outdoor control. A significantly higher frequency of MN and nuclear lesions was observed in hemocytes from the groups fed P. lima.

Inhibition of protein synthesis in a cell-free system and Vero cells by okadaic acid, a diarrhetic shellfish toxin.

Okadaic acid, a diarrhetic shellfish toxin, is a potent promoter of tumors in mouse skin and a specific inhibitor of protein phosphatases 1 and 2A. In the present study, we investigated its effects on protein synthesis in Vero cells and rabbit reticulocyte lysate. Protein synthesis was inhibited by okadaic acid in Vero cells in a concentration-dependent manner (IC50 = 3.3 x 10(8) M-1). DNA synthesis was also inhibited by okadaic acid in Vero cells in a concentration-dependent manner (IC50 = 5.3 x 10(8) M-1). DNA synthesis inhibition in Vero cells occurred only after 8 h or longer. RNA synthesis was inhibited with an IC50 of 8.2 x 10(8) M-1. The time lag before DNA and RNA synthesis inhibition occurred was longer than the time lag before protein synthesis inhibition occurred in the same cells (4 h), indicating that protein synthesis is probably the main target and the first of okadaic acid's cytotoxic effects. Moreover, the inhibition of DNA and RNA synthesis is probably a consequence of the inhibition of protein synthesis. Since okadaic acid does not impair the uptake of the precursor of protein synthesis, it is assumed that the inhibition is due to a direct effect on one of the components of the protein synthesis machinery. We then used a cell-free system of rabbit reticulocyte lysate in which specific mRNA is translated into globin to ensure that protein synthesis is a direct target of okadaic acid in vitro. In rabbit reticulocyte lysate, okadaic acid inhibited protein synthesis in a concentration-dependent manner (IC50 = 6.3 x 10(12) M-1) with a correlation coefficient for percent inhibition values of r = .918. The molecular target of okadaic acid inside the cell whereby protein synthesis is inhibited remains to be discovered.