Abstract
Bisphenol A (BPA) is a major component of the most commonly used plastic products, such as disposable plastics, Tetra Paks, cans, sport protective equipment, or medical devices. Due to the accumulation of excessive amounts of plastic waste and the subsequent release of BPA into the environment, BPA is classified as a pollutant that is undesirable in the environment. To date, the most interesting finding is the ability of BPA to act as an endocrine disrupting compound due to its binding to estrogen receptors (ERs), and adverse physiological effects on living organisms may result from this action. Since evidence of the potential pro-oxidizing effects of BPA has accumulated over the last years, herein, we focus on the detection of oxidative stress and its origin following BPA exposure using pulsed-field gel electrophoresis, flow cytometry, fluorescent microscopy, and Western blot analysis. Saccharomyces cerevisiae cells served as a model system, as these cells lack ERs allowing us to dissect the ER-dependent and -independent effects of BPA. Our data show that high concentrations of BPA affect cell survival and cause increased intracellular oxidation in yeast, which is primarily generated in the mitochondrion. However, an acute BPA exposure does not lead to significant oxidative damage to DNA or proteins.
Highlights
Phenolic compounds are chemically defined as compounds containing hydroxylated aromatic rings, which comprise the hydroxy group attached directly to the phenyl, substituted phenyl, or other aryl groups
Bisphenol A (BPA) Exposure Leads to a Decrease in Growth Rate and Cell Survival in Yeast
We found that BPA, in the concentration range tested, formed virtually no double-strand break (DSB) in S. cerevisiae cells (Figure 2A)
Summary
Phenolic compounds are chemically defined as compounds containing hydroxylated aromatic rings, which comprise the hydroxy group attached directly to the phenyl, substituted phenyl, or other aryl groups. BPA can serve as a heat-activated developer when added as a powder to thermal paper [10,11], and 8.6% of the BPA attached to the paper can penetrate through the skin into the body, as has been shown both in vitro and in vivo. This dermal exposure represents a minimal contribution to the total human body’s exposure to BPA [12,13]
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