Ariane Vettorazzi

Ochratoxin A reduces aflatoxin B1 induced DNA damage detected by the comet assay in Hep G2 cells

Mycotoxins aflatoxin B1 (AFB1) and ochratoxin A (OTA) can be present together in food commodities. These food contaminants are considered to be genotoxins, acting by different mechanisms. The aim of this work was to characterize combined genotoxic in vitro effects of both mycotoxins in Hep G2 cells. For this purpose, cytotoxicity was first determined in isolated and combined treatments in order to determine the dose range of genotoxicity studies. Co-exposure of cells to OTA+AFB1 for 24 h resulted in additive effects. Genotoxicity was determined in Hep G2 cells by the modified comet assay with restriction enzymes (endo III and FPG). Significant reactive oxygen species formation was detected in both single and combined treatments. AFB1 was genotoxic after 3 h with external metabolic activation (S9 mix) and after 24 h without metabolic activation. Co-exposure to OTA significantly decreased DNA damage induced by AFB1, not only in breaks and apurinic sites but also in FPG-sensitive sites. The apparent contradiction between additive cytotoxic effects and antagonic genotoxic effects may be explained if AFB1 and OTA compete for the same CYPs, yielding more ROS but less AFB1 adducts.

Gene expression changes induced by ochratoxin A in renal and hepatic tissues of male F344 rat after oral repeated administration.

Ochratoxin A (OTA), a naturally occurring mycotoxin, is nephrotoxic in all animal species tested and is considered a potent renal carcinogen, particularly in male rats. Its mechanism of toxicity is still unknown, although oxidative stress appears to be a plausible mechanism. Therefore, the objective of this study was to identify the biological pathways that are modulated in vivo by OTA in male F344 rats in order to gain further insight into its mechanism of renal toxicity. Rats were gavaged daily with OTA (500 microg/kg bw) and gene expression profiles in target and non-target organs were analyzed after 7 and 21 days administration. As was expected, a time-dependent increase of OTA concentrations was found in plasma, kidney and liver, with the concentrations found in both tissues being quite similar. However, histopathological examinations only revealed changes in kidney; signs of nephrotoxicity involving single cell necrosis and karyomegalic nuclei were observed in the treated rats. The number of differentially expressed genes in kidney was much higher than in liver (541 versus 11 at both time points). Several similarities were observed with other in vivo gene expression data. However, great differences were found with previous in vitro gene expression data, with the exception of DNA damage response which was not observed at mRNA level in any of our study conditions. Down-regulation was the predominant effect. Oxidative stress response pathway and genes involved in metabolism and transport were inhibited at both time points. RGN (regucalcin) - a gene implicated in calcium homeostasis - was strongly inhibited at both time points and genes implicated in cell survival and proliferation were up-regulated at day 21. Moreover, translation factors and annexin genes were up-regulated at both time points. Apart from oxidative stress, alterations of the calcium homeostasis and cytoskeleton structure may be present at the first events of OTA toxicity.

Validation of a UHPLC-FLD analytical method for the simultaneous quantification of aflatoxin B1 and ochratoxin a in rat plasma, liver and kidney.

A rapid and simple method for the simultaneous quantification of AFB1 and OTA in rat plasma, liver and kidney by UHPLC-FLD has been successfully validated according to the following criteria: selectivity, stability, linearity, precision, accuracy, recovery, robustness and limits of quantification and detection. The extraction method, calibration curves and chromatographic conditions are common for the three matrices. Plasma and homogenized tissue samples (100 μL) were extracted with acetonitrile:formic acid mixture (99:1) (300 μL). Chromatographic separation was performed with a mixture of water and acetonitrile:methanol (50:50), both acidified with 0.5% of formic acid using a gradient profile. The method avoids the use of immunoaffinity columns and allows reduction of sample and solvent volumes as well as toxic wastes. The detection is based on a photochemical reaction which enhances the AFB1 response without affecting the OTA signal before reaching the fluorescent detector. The mycotoxin recovery for each matrix was very efficient, between 93% and 96% for AFB1 and between 94% and 96% for OTA. For both mycotoxins the LOQs were 2μg/L in plasma and 8μg/kg in liver and kidney. The method has successfully been applied to rat samples after a single oral administration of a mixture of AFB1 and OTA and it could be a useful tool in toxicokinetic and toxicological studies.

A different kinetic profile of ochratoxin A in mature male rats.

Ochratoxin A (OTA) is a mycotoxin that causes renal tumors in rodents, particularly in male rats. The present work explored the impact of gender and age on OTA toxicokinetics in F344 rats after a single oral dose (0.5mg/kg b.w.). OTA plasma concentrations were analysed with a validated HPLC-FLD method and a population approach (NONMEM VI) was used to perform the kinetic analysis and the one year exposure simulation (0.21 mg/kg daily). Maximum observed OTA concentration (CMAX(obs)) was at 2h in all groups except in mature females (6h). Mature females reached higher CMAX(obs) than males of the same age. Apparent volume of distribution, but not apparent total plasma clearance, increased significantly with body weight (P<0.01) resulting in the following values for the terminal plasma half life (h) in males: 219 (young), 264 (matures) and females: 191 (young), 205 (matures). In addition mature males showed a significant lower relative bioavailability. The simulation showed similar plasma concentrations in males and females after two-months. Thus, toxicokinetic does not seem to explain sex-differences in toxicity in long-term studies. However, the age and weight should be taken into account in short-term toxicological studies if sex-differences are studied.

Genotoxicity of Aflatoxin B1 and Ochratoxin A after simultaneous application of the in vivo micronucleus and comet assay

Aflatoxin B1 (AFB1) and Ochratoxin A (OTA) are genotoxic mycotoxins that can contaminate a variety of foodstuffs, the liver and the kidney being their target organs, respectively. The micronucleus (MN) assay (bone marrow) and the comet assay (liver and kidney) were performed simultaneously in F344 rats, treated with AFB1 (0.25 mg/kg b.w.), OTA (0.5 mg/kg b.w.) or both mycotoxins. After AFB1 treatment, histopathology and biochemistry analysis showed liver necrosis, focal inflammation and an increase in Alanine Aminotransferase and Aspartate Aminotransferase. OTA alone did not cause any alteration. The acute hepatotoxic effects caused by AFB1 were less pronounced in animals treated with both mycotoxins. With regard to the MN assay, after 24 h, positive results were obtained for AFB1 and negative results were obtained for OTA, although both toxins caused bone marrow toxicity. In the combined treatment, OTA reduced the toxicity and the number of MN produced by AFB1. In the comet assay, after 3 h, positive results were obtained for AFB1 in the liver and for OTA in the kidney. The combined treatment reduced DNA damage in the liver and had no influence in the kidney. Altogether, these results may be indicative of an antagonistic relationship regarding the genotoxicity of both mycotoxins.

A review on ochratoxin A transcriptomic studies.

The mycotoxin Ochratoxin A (OTA) is a potent renal carcinogen in male rats. Transcriptomic studies on OTA (4 in vitro, 6 in vivo, 2 in vitro/in vivo) have been reviewed. The aim of 6 of them was mainly mechanistic whereas the rest had mostly predictive (1) or evaluation (5) purposes. An overall tendency towards gene expression downregulation was observed, probably as a result of protein synthesis inhibition. DNA damage response genes were not deregulated in most of the studies. Genes involved in acute renal injury, cell survival and cell proliferation were upregulated in several in vivo studies. Apoptosis genes were deregulated in vitro but less affected in vivo; activation of several MAPKs has been observed. Many genes related to oxidative stress or involved in cell-to-cell interaction pathways (Wnt) or cytoskeleton structure appeared to be deregulated either in vitro or in vivo. Regucalcin was highly downregulated in vivo and other calcium homeostasis genes were significantly deregulated in vitro. Genes related to OTA transport (OATs) and metabolism (CYPs) appeared downregulated in vivo. Overall, the mechanism of action of OTA remains unclear, however transcriptomic data have contributed to new mechanistic hypothesis generation and to in vitro-in vivo comparison.

Simple high-performance liquid chromatography-fluorescence detection method for plasma, kidney and liver of rat as a tool for toxicology studies.

A fast and simple HPLC-FLD (high-performance liquid chromatography-fluorescence detection) analytical method has been developed and validated for the determination of ochratoxin A in rat plasma, kidney and liver. The extraction method, calibration curves and chromatographic conditions are common for the three matrices. Plasma and homogenized tissue samples (250 microL) were extracted with ethanol (400 microL) and trichloroacetic acid 20% (w/v) (50 microL). Supernatants were directly injected into the HPLC system, analyzed on a 5-microm (25 cm x 0.4 cm) Tracer Extrasil ODS2 column using FLD (excitation wavelength=225 nm, emission wavelength=461 nm). The mobile phase was 29:29:42 (v/v) methanol-acetonitrile-sodium acetate. The small volume of sample needed which allows the obtaining of ochratoxin A levels in individual tissue samples from small animals and the wide range of concentrations that could be analyzed make this method easy to apply in toxicology and toxicokinetic studies of this mycotoxin, even in low dose carcinogenic studies. This method was linear and selective for all the matrices. Precision and accuracy were always <10% and recovery was very efficient in each case. Limits of detection and quantification were also calculated in plasma (1 and 8.4 microg/L), kidney (14.3 and 55.8 microg/kg) and liver (4.1 and 52.8 microg/kg). Stability of the tissue homogenates was assured for at least 10 months at -80 degrees C. The method has been successfully applied to the analysis of rat samples after 7 days of ochratoxin A (0.5mg/kg b.w. dissolved in an aqueous NaHCO(3) solution) administration by oral gavage.

Kidney and liver distribution of ochratoxin A in male and female F344 rats.

The impact of age and gender on Ochratoxin A (OTA) distribution in kidney and liver were studied. OTA was quantified in kidney and liver of young and mature rats of both sexes. Data was fit simultaneously using the population approach with NONMEM program. Fed and fasted mature males showed a 30% decrease and an 11% increase in relative bioavailability, respectively, in comparison with the rest of the groups. The OTA concentrations reached in kidney and liver were very similar between both organs. The models that best fit to data were the ones that considered that distribution of OTA to kidney and liver occurs from the central compartment and that elimination occurs mainly from the liver compartment. The kinetic analysis revealed that both, the apparent volume of distribution of the central compartment (V/F) and the apparent volume of distribution of the liver and kidney compartments (V(L,K)/F) increased significantly with body weight. Thus, the sex differences observed in organs distribution are a reflection of the differences in relative bioavailability observed in adult males, as a consequence of the fed and fasted conditions and to the significant higher body weight of mature males which directly affected the V/F and V(L,K)/F.

Effects of fasting and gender on ochratoxin A toxicokinetics in F344 rats

Ochratoxin A (OTA) is a mycotoxin that causes renal tumors in rats, particularly in males. In previous kinetic studies performed in fed conditions (Vettorazzi et al., 2008), mature F344 male rats presented a significantly lower OTA bioavailability than females and young animals. The objective of the present study was to evaluate two factors which could explain this different kinetic profile: the presence of food and the male-specific protein alpha-2u-globulin. Therefore, a 24h kinetic study has been performed in rats under fasting conditions. Food ingestion has been controlled in both sexes during two months. The presence of alpha-2u-globulin in the urine has been analyzed with SDS-gradient mini-gel electrophoresis. Fasting tends to increase the maximum OTA plasma concentrations and the rate of absorption. The relative bioavailability is significantly increased under fasting conditions only in males. Mature males consumed a higher amount of food but, as the OTA dose administered, it was proportional to body weight. The reason why the OTA bioavailability is more affected in presence of food only in males is unclear. Several possibilities, such as differences in gastric emptying, OTA-food interactions and the involvement of alpha-2u-globulin are discussed.

Ochratoxin A kinetics: a review of analytical methods and studies in rat model.

Ochratoxin A (OTA) is a thermostable mycotoxin that contaminates a great variety of foodstuffs. It is nephrotoxic in all of the mammalian species tested, the pig being the most sensitive one; among rodents, rats are the most susceptible to OTA carcinogenicity. Kinetics, by studying the absorption, distribution, metabolism and excretion of xenobiotics, is an important tool in the extrapolation of animal toxicity data for human risk assessment. The most important kinetic studies performed with OTA in rats are reviewed, together with the different methods used for OTA quantification in biological matrices. Twelve studies in Wistar, Sprague-Dawley or F344 rats, using radiolabeled OTA or TLC, HPLC-FLD or LC/MS have been summarized. Very often methods validated for food have been directly applied to tissues. Strain, sex and age differences have been detected but the interpretation is difficult due to the different experimental conditions, and the connection of the several factors that may account for these differences.