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Abstract
Induction of oxidative stress by drugs and other xenobiotics is an important mechanism of cytotoxicity. However, in vitro studies on the relationship between oxidative stress and cytotoxicity in cultured cells is frequently complicated by the fact that cell culture medium components affect reactive oxygen species (ROS) exposures in ways that vary with the mode of ROS production. The objectives of this study were to first determine the mode of ROS induction by certain model compounds when they are applied to cultured cells, and then to determine how ROS induction and cytotoxicity were affected by the ROS-quenching medium component pyruvate. Three compounds, eseroline, benserazide, and pyrogallol induced H2O2 in cell culture media independent of cells. However, another compound, menadione, induced H2O2 in a manner largely dependent on the MDA-MB-231 breast cancer cells used in this study, which is consistent with its known mechanism of inducing ROS through intracellular redox cycling. 1 mM pyruvate, as well as catalase, reduced the H2O2 in culture wells with each ROS inducer tested but it only reduced the cytotoxicity of cell-independent inducers. It reduced the cytotoxicity of benserazide and pyrogallol >10-fold and of eseroline about 2.5-fold, but had no effect on menadione cytotoxicity. From this data, it was concluded that depending on the mechanism of ROS induction, whether intra- or extracellular, a ROS-quenching medium component such as pyruvate will differentially affect the net ROS-induction and cytotoxicity of a test compound.
Highlights
Modern toxicity testing places a strong emphasis on in vitro systems that employ cultured cells and various assay chemistries to deliver data that predicts in vivo outcomes (Niles et al 2008)
We showed dramatic effects of the common medium component sodium pyruvate on the cytotoxicity of cellindependent reactive oxygen species (ROS) inducers and its relative lack of effect on the toxicity of a largely cell-dependent ROS inducer
Menadione (Vitamin K3) is a cell-dependent ROS inducer that undergoes redox cycling in the cell, causing the accumulation of excess superoxide that is in turn converted to H2O2 by superoxide dismutase (Fukui et al 2012; Buckman et al 1993; Thor et al 1982)
Summary
Modern toxicity testing places a strong emphasis on in vitro systems that employ cultured cells and various assay chemistries to deliver data that predicts in vivo outcomes (Niles et al 2008). Certain polyphenolic and other food derived antioxidants added to cell culture medium undergo redox cycling that produces H2O2 independent of cells (Halliwell 2008; Babich et al 2009; Long and Halliwell 2009). In this case, H2O2-dependent cytotoxicity is from the outside in. Cells have a significant capacity to eliminate ROS (e.g. superoxide dismutase eliminates superoxide, catalase and glutathione peroxidase eliminate H2O2), so lower ROS levels may be observed with cells compared to a cell free control
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