Axial flow modulates proximal tubule NHE3 and H-ATPase activities by changing microvillus bending moments.
Academic Article
Overview
abstract
We have previously demonstrated that mouse proximal tubules in vitro respond to changes in luminal flow with proportional changes in Na+ absorption (Du Z, Duan Y, Yan Q, Weinstein AM, Weinbaum S, and Wang T. Proc Natl Acad Sci USA 101: 13068-13073, 2004). It was hypothesized that brush-border microvilli function as a sensor to detect and amplify luminal hydrodynamic forces and transmit them to the actin cytoskeleton. In the present study we examine whether 1) flow-dependent HCO3- transport is proportional to flow-dependent variations in microvillous torque (bending moment); 2) both luminal membrane Na(+)/H+ exchange (NHE3) and H(+)-ATPase activity are modulated by axial flow; and 3) paracellular permeabilities contribute to the flux perturbations. HCO3- absorption is examined by microperfusion of mouse S2 proximal tubules in vitro, with varying perfusion rates, and in the presence of the Na/H-exchange inhibitor EIPA, the H(+)-ATPase inhibitor bafilomycin, and the actin cytoskeleton inhibitor cytochalasin D. Paracellular permeability changes are assessed with measurements of epithelial HCO3- permeability and transepithelial potential difference (PD). It is found that 1) an increase in perfusion rate enhances HCO3- absorption and microvillous torque, and the fractional changes of each are nearly identical; 2) inhibition of NHE3 by EIPA, or H(+)-ATPase by bafilomycin, produced only partial inhibition of flow-stimulated bicarbonate transport; 3) disruption of the actin cytoskeleton by cytochalasin D blocked the increment of HCO3- absorption by high flow; and 4) HCO3- permeability and transepithelial PD are not modulated by flow. We conclude that flow-dependent modulation of proximal tubule HCO3- reabsorption is due to changes in both NHE3 and H(+)-ATPase activity within the luminal cell membrane and this requires an intact actin cytoskeleton. Paracellular permeability changes do not contribute to this flow dependence. Perfusion-absorption balance in the proximal tubule is a direct effect of flow-induced torque on brush-border microvilli to regulate luminal cell membrane transporter activity.
