Abstract
Bisphenols are important environmental pollutants that are extensively studied due to different detrimental effects, while the molecular mechanisms behind these effects are less well understood. Like other environmental pollutants, bisphenols are being tested in various experimental models, creating large expression datasets found in open access storage. The meta-analysis of such datasets is, however, very complicated for various reasons. Here, we developed an integrating statistical and machine-learning model approach for the meta-analysis of bisphenol A (BPA) exposure datasets from different mouse tissues. We constructed three joint datasets following three different strategies for dataset integration: in particular, using all common genes from the datasets, uncorrelated, and not co-expressed genes, respectively. By applying machine learning methods to these datasets, we identified genes whose expression was significantly affected in all of the BPA microanalysis data tested; those involved in the regulation of cell survival include: Tnfr2, Hgf-Met, Agtr1a, Bdkrb2; signaling through Mapk8 (Jnk1)); DNA repair (Hgf-Met, Mgmt); apoptosis (Tmbim6, Bcl2, Apaf1); and cellular junctions (F11r, Cldnd1, Ctnd1 and Yes1). Our results highlight the benefit of combining existing datasets for the integrated analysis of a specific topic when individual datasets are limited in size.
Highlights
Bisphenols have been in commercial use as plasticizers for over 70 years
By applying machine learning methods to these datasets, we identified genes whose expression was significantly affected in all of the bisphenol A (BPA) microanalysis data tested; those involved in the regulation of cell survival include: Tnfr2, Hepatocyte growth factor (Hgf)-Met, Angiotensin II Receptor Type 1a (Agtr1a), Bradykinin Receptor B2 (Bdkrb2); signaling through Mapk8 (Jnk1)); DNA repair (Hgf-Met, Methylguanine-DNA Methyltransferase (Mgmt)); apoptosis (Tmbim6, Bcl2, Apaf1); and cellular junctions (F11r, Cldnd1, Ctnd1 and Yes1)
We focused on applying machine learning methods in terms of feature selection (FS), revealing key genes influenced by BPA exposure
Summary
Bisphenols have been in commercial use as plasticizers for over 70 years. They are reported to be estrogenic mimics that may interfere with hormonal homeostasis. Mammals are exposed to BPA daily through several routes, such as the consumption of food and drink, drugs, air born inhalation, and contact materials, such as various plastics, medical devices, and store receipts [6,7,8]. It has become increasingly clear that BPA can bioaccumulate in the food chain. In a study in Africa, BPA reached very high concentrations in food (940 ng/g), biological fluids (209 ng/mL), consumer and PCPs (3.6 μg/g), and semisolids (154 μg/g) [19]
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