The placenta exchanges vital factors, including oxygen, carbon dioxide, copper, iron, calcium cations, and glucose, which are essential to fetal growth. Each molecule is transferred by specific receptors that are located at the cell membrane or in the cytoplasm. Copper, iron, calcium cations, and glucose transfer genes are regulated by estrogens, vitamin D, and human placental lactogen. Regulations of these receptors depend on pregnancy time length and maternal and fetal nutrient environment with various pathways. Some synthetic plastics known as endocrine disrupting chemicals (EDC) have a similar structure to reproductive hormones such as estrogens. Thus, these substances have a potential effect on the expression of genes which are regulated by estrogens or progesterone by interfering their pathways. Having an estrogenic property, EDC interact with oestrogen receptors and elevate or decrease the expression of target genes which are responsible for transporting essential molecules such as copper, iron, and calcium. To examine the effects of EDC exposure during pregnancy, we conducted an in vitro model study using the BeWo human trophoblast cell line. The BeWo cell was treated with well-known EDC, octyl-phenol (OP), nonyl-phenol (NP), and bisphenol A (BPA) in a dose-dependent manner (10–7, 10–6, and 10–5 M) for 24 h. The expression of copper (CTR1, ATP7A), iron (IREG1, HEPH), and calcium transporting genes (PMCA1, TRPV6), were measured by real-time RT–PCR and Western blot. The expression of copper, iron, and calcium transporting genes were elevated in a dose-dependent manner by all well-known EDC, including OP, NP, and BPA, as well as E2. To unveil the mechanism of these elevations of ionic transporting genes, an ERE promoter study will be needed. Taken together, essential cation transporting genes in placenta are modulated by EDC.
Screening California surface waters for estrogenic endocrine disrupting chemicals (EEDC) with a juvenile rainbow trout liver vitellogenin mRNA procedure
