Hydrogen-Deuterium Exchange Effects on β-Endorphin Release from AtT20 Murine Pituitary Tumor Cells

Abundant evidences demonstrate that deuterium oxide (D₂O) modulates various secretory activities, but specific mechanisms remain unclear. Using AtT20 cells, we examined effects of D₂O on physiological processes underlying β-endorphin release. Immunofluorescent confocal microscopy demonstrated that 90% D₂O buffer increased the amount of actin filament in cell somas and decreased it in cell processes, whereas β-tubulin was not affected. Ca²⁺ imaging demonstrated that high-K⁺-induced Ca²⁺ influx was not affected during D ₂O treatment, but was completely inhibited upon D₂O washout. The H₂O/D₂O replacement in internal solutions of patch electrodes reduced Ca²⁺ currents evoked by depolarizing voltage steps, whereas additional extracellular H₂O/D₂O replacement recovered the currents, suggesting that D₂O gradient across plasma membrane is critical for Ca²⁺ channel kinetics. Radioimmunoassay of high-K⁺-induced β-endorphin release demonstrated an increase during D₂O treatment and a decrease upon D₂O washout. These results demonstrate that the H ₂O-to-D₂O-induced increase in β-endorphin release corresponded with the redistribution of actin, and the D₂O-to-H ₂O-induced decrease in β-endorphin release corresponded with the inhibition of voltage-sensitive Ca²⁺ channels. The computer modeling suggests that the differences in the zero-point vibrational energy between protonated and deuterated amino acids produce an asymmetric distribution of these amino acids upon D₂O washout and this causes the dysfunction of Ca²⁺ channels.