Membrane trafficking factors are involved in the hypotonic activation of the taurine channel in the little skate (Raja erinacea) red blood cell.

In response to volume expansion, red blood cells of the little skate (Raja erinacea) initially swell and then release small organic compounds and osmotically obligated water in what is called a regulatory volume decrease (RVD) to restore cell volume. One of the major intracellular solutes lost during this process is the non-metabolized beta amino acid taurine. This hypoosmotic-induced increase in cell taurine permeability requires the anion exchanger, skAE1. The abundance of this transporter increases on the surface plasma membrane by a process of exocytosis. The second-messenger pathways involved in exocytosis of skAE1 were investigated with the use of inhibitors which affect membrane trafficking. Hypoosmotic-stimulated taurine uptake was significantly decreased by 42% with wortmannin, a phosphatidylinositol 3-kinase (PI3 kinase) inhibitor. Additional evidence for the involvement of PI3K was obtained with a second inhibitor, LY294002, which decreased the hypoosmotic-stimulated taurine uptake by 28%. The state of actin is also involved, as the actin filament depolymerizer latrunculin B decreased hypoosmotic-stimulated taurine uptake by approximately 40%. Although hypoosmotic conditions did not stimulate changes in the distribution of actin between filamentous and globular forms, latrunculin stimulated a decrease in filamentous actin and increase in globular actin in both isoosmotic and hypoosmotic conditions. Disruptors of other potential cytoskeletal factors (myosin, kinesin, dynein, and microtubules) did not affect taurine uptake. The present results suggest that the exocytosis of skAE1 stimulated by hyposmotic-induced cell volume expansion requires activation of PI3 kinase and is regulated by the state of actin filaments.