Phototoxicity and photogenotoxicity of nine pyridone derivatives.

Nine structurally related pyridone derivatives were assayed for photogenotoxicity and phototoxicity in the Ames test, the chromosomal aberration test in V79 cells and the neutral red uptake (NRU) test in 3T3 cells. All nine compounds absorb light to a comparable degree at wavelengths between 380 and 430 nm. Seven of the nine compounds were found to produce high quantities of singlet oxygen (1O(2)) upon irradiation in the presence of oxygen. These seven compounds were highly phototoxic in the NRU test, three were clearly and two were marginally photomutagenic in the Ames test, five were assessed as clearly and two as equivocally photoclastogenic in the chromosomal aberration test. Two compounds showed substantially lower 1O(2) yields. The pyridone ring of these two compounds is attached to a non-aromatic ring, while for the seven other compounds the chromophore system including the pyridone ring consists of two or three aromatic rings. One of the two compounds with low 1O(2) yields was distinctly less phototoxic and did not induce photogenotoxic effects. The other, structurally an indolo derivative and not the common thieno derivative, was, however, similarly phototoxic as the seven compounds with high 1O(2) quantum yield and was also clearly photogenotoxic indicating that different action pathways, not involving singlet oxygen, have to be considered at least for this compound.

Mouse lymphoma thymidine kinase locus gene mutation assay: International Workshop on Genotoxicity Test Procedures Workgroup Report.

The Mouse Lymphoma Assay (MLA) Workgroup addressed and reached consensus on a number of issues. Discussion focused on five areas: (1) acceptable assay versions; (2) cytotoxicity measure; (3) 24-hr treatment; (4) microwell colony counting and sizing; and (5) data acceptability/statistical analysis. Although the International Conference on Harmonisation (ICH) indicated a preference for the microwell over the soft agar method, all of the workgroup members agreed that both versions of the MLA are equally acceptable. The workgroup agreed that it is desirable for both assay versions to use the same measure of cytotoxicity to define the acceptable and required concentration range. Currently, laboratories using the microwell version use the relative survival (RS) determined by cloning immediately after the treatment. Laboratories using the soft agar method do not obtain an RS but use the relative total growth (RTG), a combination of the relative suspension growth (RSG) during the expression period and the relative cloning efficiency determined at the time of mutant selection. The workgroup agreed to investigate the RSG, the RS, and the RTG and to develop further guidance. In the interim, the workgroup reached consensus that the RTG be used as the standard measure of cytotoxicity. The ICH recommended a 24-hr treatment in the absence of S9 when negative results are obtained with short (3-4 hr) treatments. The workgroup agreed to retain this requirement but acknowledged that more data are needed prior to making final recommendations concerning the need for and the specific protocol for the 24-hr treatment. Environ. Mol. Mutagen. 35:185-190, 2000 Published 2000 Wiley-Liss, Inc.

Suppression of mutagenic activity of a series of 5HT2c receptor agonists by the incorporation of a gem-dimethyl group: SAR using the Ames test and a DNA unwinding assay.

A positive result in the Ames test is generally taken as a strong indication for a genotoxic (i.e. DNA damaging) property of the test compound, often sufficient to cause termination of its development as a new therapeutic agent. A number of serotonin receptor ligands have been tested for their mutagenic potential in the Ames assay at an early stage of development. For several compounds increases in the number of revertant colonies were observed in strain TA1537. Consequently, structure-activity relationship investigations were undertaken to search for compounds without mutagenic liability. All compounds are three ringed heterocyclic structures consisting of a benzene ring, a central (generally non-aromatic) 5- or 6-membered ring and a pyrrole or pyrazole ring. Using a gel shift assay we provide evidence that the observed genotoxic effects are strongly influenced by the intercalating properties of the compounds. The highest mutagenic response was seen with a compound possessing a central aromatic ring. The mutagenic activity of the naphthaleno derivatives appears to be stronger when compared with the indeno compounds, probably because of the less curved structure. Dimethyl substitution of the indeno substructure reduces the intercalating ability of the compounds and leads to loss of mutagenic activity. Pyrazole analogues of both indeno and naphthaleno structures appear to produce stronger mutagenic responses than the pyrrole derivatives.

The photomutagenicity of fluoroquinolones and other drugs.

Induction of DNA damage as a consequence of exposure to UV light has been established as the major and still increasing cause of skin cancer. Absorption of the photon energy may be either directly by the DNA molecules (for wavelengths < 320 nm) or may be by endogenous or exogenous chemicals (sensitizers) with the potential of energy or electron transfer to DNA. Oxygen-mediated reactions (often called type II reactions) appear to be the most important mechanism since molecular oxygen is a good and abundant substrate for triplet excited sensitizers. Energy transfer to molecular oxygen is possible for wavelengths in the near UV and in the visible part of the solar spectrum since the energy of the excited oxygen molecule ((1)O2*) is comparatively low. A few light-absorbing pharmaceuticals have long been known to cause photo(geno)toxic effects. Notably psoralene and chlorpromazine derivatives have been established as photomutagens and the reaction mechanisms have been identified. The fluoroquinolone antibiotics have more recently been recognized as being photomutagenic. The type of DNA damage and the modulation by antioxidants indicate the involvement of reactive oxygen species (ROS) but other mechanisms are also reported at least for some derivatives. In routine genotoxicity studies we observed a photomutagenic activity of a compound under development as an anxiolytic agent in the Ames tester strain TA102 at 'normal laboratory illumination' conditions. Further investigations showed strong photogenotoxic activity in tests for gene mutations and chromosomal aberrations in mammalian cells. The compound proved to be a potent (1)O2-producer. The finding led to termination of development but in the course of studies several structural analogues have been tested for which structure activity relationships will be described. The relevance of photogenotoxic properties of drugs for predicting adverse effects in man will be discussed.

Genotoxicity of 17 gyrase- and four mammalian topoisomerase II-poisons in prokaryotic and eukaryotic test systems.

The genotoxic potency of certain classes of topoisomerase II poisons is correlated with their affinity to the topoisomerase protein rather than with the presence of 'classical' structural alerts for DNA reactivity: bacterial topoisomerase II poisons (specifically named gyrase inhibitors) are highly genotoxic in prokaryotic systems; mammalian topoisomerase II poisons are potent mutagens/clastogens in eukaryotic systems. Studies with bacterial, lower eukaryotic and mammalian genotoxicity tests were performed to draw structure-activity conclusions and address risk-benefit considerations for the class of quinolone gyrase inhibitors. All 17 gyrase inhibitors investigated in this study showed genotoxic activity in Salmonella typhimurium strain TA102 and the SOS test. The genotoxic and the toxic activities increased in a highly parallel fashion from the parent compounds, nalidixic acid and oxolinic acid, to the new generation fluoroquinolones. Generally, the most potent fluoroquinolones also show clear-cut positive effects in eukaryotic test systems, although at concentrations 100-1000-fold higher than those effective in bacteria and also 100-1000-fold higher than the minimal genotoxic concentrations of antitumour topoisomerase II inhibitors (ellipticine, teniposide, mAMSA) used as reference compounds. However, subtle structural modifications of the quinolones can strongly diminish the preferential genotoxicity in the prokaryotic test systems.