Micronucleus induction in V79 cells by the anabolic doping steroids desoxymethyltestosterone (madol) and 19-norandrostenedione.

The abuse of anabolic steroids for doping raises concerns. Many of these compounds have never been examined for their toxicological properties. Aside from hormonal (androgenic) activity, anabolic steroids may also exert genotoxic effects. In the present study, we determined the potencies of the "designer steroid" madol (MAD) and the anabolic prohormone 19-norandrostenedione (NA) to induce micronuclei in V79 cells in vitro. CREST analysis was used to differentiate between aneugenic and clastogenic mechanisms of micronucleus induction. Cytotoxicity of the steroids and their influence on the cell cycle were assessed in parallel. In addition, the ability of MAD and NA to increase production of reactive oxygen species and to induce apoptosis were studied. Both agents caused a concentration-dependent increase in the rates of micronuclei in V79 cells, exceeding a doubling of the background micronucleus rates of untreated controls, which was evident at 27microM and 29microM for MAD and NA, respectively. The steroid-induced micronuclei were predominantly kinetochor (CREST)-negative, pointing to a clastogenic mode of action. As cytotoxicity of both compounds is weak (IC(20) value of 300microM for NA and IC(10) of 100microM for MAD), cytotoxicity was unlikely to contribute to their genotoxicity. The observed genotoxicity of both compounds was due neither to apoptosis induction nor to production of reactive oxygen species. However, the ability of both steroids to induce micronuclei appears related to their lipophilicity. Therefore, a "non-specific" chromosomal genotoxicity of MAD and NA, based on hydrophobic interactions, appears likely. This could well result in biologically relevant increases in chromosomal damage as soon as critical concentrations of the agents are reached in vivo. Regarding the current misuse of the steroids for doping, the uncontrolled administration of very high doses must be considered. Therefore it cannot be ruled out that MAD and NA present genotoxic hazards under current misuse conditions by athletes in sports or in body building.

Hydrophobic interaction of organic chemicals with microtubule assembly in vitro.

A recent concept connecting the lipophilicity of organic chemicals with their genotoxicity on a chromosomal level implies that the lipophilic character of organic chemicals determines a certain background of chromosomal genotoxicity that can be addressed as "non-specific". This is opposed to compounds with more "specific" modes of action. Such mechanisms influence the processes of karyokinesis and cytokinesis. A critical partial process for the chromosomal segregation is the dynamics of assembly and disassembly of microtubules. To broaden the present database for such interactions, chemicals were selected based on their lipophilicity (log P between -1.5 and +1.0) and on hints from the literature pointing to possibilities of interaction with the tubulin-microtubule system. Thus, acetamide, acrylamide, methylmethane sulfonate, acetonitrile, acrylonitrile and cyclohexanone were assessed as to their potencies to influence the dynamic processes of microtubule assembly and disassembly in a cell-free system in vitro. These compounds covered a range of log P between -1.5 and 1.0, complementary to compounds investigated earlier. The entire body of data supports the general concept that hydrophobic interactions are connected with non-specific processes, which contribute to a background genotoxicity on a chromosomal level. It also points to the dynamics of microtubule assembly and disassembly as a decisive partial process involved.

Some molecular descriptors for non-specific chromosomal genotoxicity based on hydrophobic interactions.

A concept relating the lipophilicity of chemicals with their genotoxicity on a chromosomal level had been generated by Schultz and Onfelt (Chem Biol Interact 126:97-123, 2000). It was shown that aneuploidy in Chinese hamster V79 cells was elicited by lipophilic chemicals at concentrations related to their hydrophobicity (log P), whereas toxicants with a specific mode of action acted at concentrations consistently lower than predicted based on log P. We have now combined available data sets on aneuploidy/micronucleus formation with procedures used in QSAR modelling, in order to find new molecular descriptors for modelling non-specific chromosomal genotoxicity, and to optimise combinations thereof. Molecular structures of 26 chemicals, including steroids, were converted into single 3D models using Corina (version 3.20), and 11 descriptors of molecular properties were calculated. The data of 16 compounds assigned to a non-specific mode of action were imported into the QSAR module of the software package Cerius(2) (version 4.10). Applying genetic function approximation (GFA), linear equations were set up relating molecular descriptors with experimental concentrations at which doubling of micronuclei occurred in V79 cells (exp -log C). The number of variables (molecular descriptors) was limited to a maximum of three, and linear and quadratic terms were allowed. Based on the descriptions provided by the GFA procedure, log P was the most suitable single property to describe non-specific genotoxicity [r (2 ) = 0.88], confirming the original concept of Schultz and Onfelt. Using more descriptors (up to three in combination) resulted in an optimization of correlations up to r (2 )= 0.97. Such optimal correlation coefficients were obtained by combinations (a) of the numbers of hydrogen bond acceptors, the polar surface and total surface areas of molecules on one hand, and by (b) the dipole moment, polar surface and total surface descriptors on the other hand. In essence, the relation of polar surface to the total molecular surface appears pivotal to determine the non-specific chromosomal genotoxicity of lipophilic compounds.

Induction of micronuclei in V79 cells by the anabolic doping steroids tetrahydrogestrinone and trenbolone.

The synthetic steroid tetrahydrogestrinone is a new "designer drug" and was recently detected to be illegally used in sports. It is chemically closely related to trenbolone that is known as an animal growth promoter. The potencies of trenbolone, tetrahydrogestrinone and testosterone to induce micronuclei in V79 cells in vitro were determined. CREST analysis was employed to differentiate between aneugenic or clastogenic mechanisms. Cytotoxicity and an influence on the cell cycle were assessed in parallel. Incubations with testosterone, at concentrations between 3 and 300 microM, failed to induce micronuclei. By contrast, tetrahydrogestrinone and trenbolone increased the rate of micronuclei significantly, up to a doubling of the micronuclei rate of untreated controls. Tetrahydrogestrinone and trenbolone displayed a bell-shaped dose-response curve, with maximal effects observed at 3 and 30 microM, respectively. The micronuclei induced by tetrahydrogestrinone and trenbolone were predominantly kinetochor (CREST) positive, pointing to an aneugenic mode of action. This may be related to the specific structure of both molecules with a system of activated double bonds. As the genotoxic effect of tetrahydrogestrinone at a chromosomal level appears at a low concentration range, it cannot be ruled out that tetrahydrogestrinone presents a genotoxic hazard on a chromosomal level under conditions of its current misuse in sports.

Proposed criteria for specific and non-specific chromosomal genotoxicity based on hydrophobic interactions.

Tests for chromosomal damage are indispensable in the genotoxicity testing battery. Thus, positive results of clastogenicity or aneugenicity tests are of key relevance in safety assessment and product development. Schultz and Onfelt [N. Schultz, A. Onfelt, Sensitivity of cytokinesis to hydrophobic interactions. Chemical induction of bi- and multi-nucleated cells, Chem. Biol. Interact. 126 (2000) 97-123.] have studied the chemical induction of bi- and multi-nucleated cells in Chinese hamster V79 cells and compared non-specific agents with inducers acting through a known specific mechanism. They separated compounds with a specific action from those with a non-specific action based on lipophilicity, following a theory of hydrophobic interactions with processes of cytokinesis. It appeared possible to broaden the original database of this concept to include aneugenic as well as clastogenic compounds studied in the micronucleus (MN) test. The datasets used for this purpose were (A) the original dataset of Schultz and Onfelt [N. Schultz, A. Onfelt, Sensitivity of cytokinesis to hydrophobic interactions. Chemical induction of bi- and multi-nucleated cells, Chem. Biol. Interact. 126 (2000) 97-123.], and two sets (B, C) of our own data from studies in V79 cells in vitro. As the particular endpoints used were different (A: counts of bi- and multi-nucleated cells, B/C: micronucleus counts) the coherence of the experimental data sets was validated by including compounds belonging to both collections. Data set B included compounds with a specific effect on the mitotic spindle (nitrobenzene and benzonitrile) and data set C included the phytoestrogens genistein and daidzein, as well as a number of hormonal steroids with unknown mode of action. Taking all three data sets (A, B, C) together, the 33 compounds investigated covered a total lipophilicity range of logP between -0.51 (diamide) and 5.65 (17alpha-propylmesterolone). In order to separate statistical outliers (with a specific mode of action to be likely) from the large cluster of compounds with non-specific genotoxicity related to hydrophobic interactions, the method of robust regression was applied. It appeared that all compounds with a specific mode of action were in fact outliers of the lipophilicity rule. Genistein, a weak clastogen causing chromosomal aberrations and being discussed to induce topoisomerase-2 mediated DNA breaks, came close to the statistical borderline between compounds with specific and non-specific chromosomal genotoxicity. A general procedure is proposed, applicable in chemical product development, to screen specific and non-specific modes of action.

Genotoxicity and potential carcinogenicity of 2,4,6-TNT trinitrotoluene: structural and toxicological considerations.

Environmental contamination with 2,4,6-TNT (trinitrotoluene) represents a worldwide problem. Concern for carcinogenicity can be derived from chemically related compounds, especially the dinitrotoluenes. In the metabolism of TNT, the reductive routes are preponderant. The main urinary metabolites of TNT are 4-amino-2,6-dinitrotoluene and 2-amino-4,6-dinitrotoluene. In humans exposed to TNT, the formation of hemoglobin adducts of the amino-dinitrotoluenes is in general concordance with the ratio of urinary excretion. The variations in quantities of excreted metabolites among the different occupational cohorts studied are likely explained by the different routes of exposure to TNT, including dermal uptake. Most studies show that urinary excretion of the amino-dinitrotoluenes (4-amino-dinitrotoluene plus 2-amino-dinitrotoluene) in a range of 1 to 10 mg L(-1) (5-50 microM) are not uncommon--for instance in persons employed with the disposal of military waste. Trinitotoluene is mutagenic in Salmonella typhimurium strains TA98 and TA100, with and without exogenous metabolic activation. Mutagenic activity has been found in urine from workers who were occupationally exposed to TNT. An unpublished 2-year study was reported in 1984 by the IIT Research Institute, Chicago, IL. Fischer 344 rats were fed diets containing 0.4, 2.0, 10, or 50 mg/kg TNT per day. In the urinary bladder, hyperplasia (12 of 47 animals p < .01) and carcinoma (11 of 47 animals, p < .05) were observed at significant levels in high-dose (50 mg kg(-1)) females and in one or two females, respectively, at 10 mg kg(-1). Taking all the available evidence together, the appropriate precautions should be taken.