Retracted: At diabetes‐like concentration, glucose down‐regulates the placental serotonin transport system in a cell‐cycle‐dependent manner

Serotonin [5‐hydroxytryptamine (5HT)] is a vasoconstrictor that also acts as a developmental signal early in embryogenesis. The 5HT transporter (SERT) on the membranes of the placental trophoblast cells controls 5HT levels in the maternal bloodstream to maintain stable transplacental blood flow and simultaneously provide 5HT to the embryo. The 5HT uptake rate of placental SERT is important for both the mother and the developing embryo. The impact of glucose on the placental SERT system during diabetic pregnancy is not known. The present in vitro study investigated this important issue in human placental choriocarcinoma (JAR) cells that were cultured for 24–96 h in a medium containing either 5.5 (physiologic concentration) or 25 mmol/L d ‐glucose (diabetic‐like concentration). The 5HT uptake rates of the cultured cells were not altered at exogenous d ‐glucose concentrations in the range of 5.5–15 mmol/L, but were decreased significantly at a diabetic‐like concentration (≥25 mmol/L). To understand better the role of glucose on the placental 5HT system, we first characterized SERT in JAR cells at different cell‐cycle phases and then determined the expression levels of SERT on the plasma membrane and in the intracellular pools of JAR cells at the late‐S and G2 phases, where the uptake rates were decreased 73% under diabetic‐like glucose concentrations. Finally, the importance of self‐association of SERT molecules was examined. In JAR cells co‐expressing Flag‐ and myc‐tagged SERT, myc‐antibody precipitated 70% of Flag‐SERT, indicating that a large percentage of SERT proteins exist as oligomers in situ . Under diabetic conditions, myc‐antibody no longer precipitated Flag‐SERT, suggesting a disruption in the aggregation of SERT molecules. Therefore, we propose that under uncontrolled diabetic conditions, glucose down‐regulates 5HT uptake rates of placental SERT by interfering with its functional expression in a cell‐cycle‐dependent manner.