Loading of nitrate into the xylem: apoplastic nitrate controls the voltage dependence of X-QUAC, the main anion conductance in xylem-parenchyma cells of barley roots.

We report here that NO(3)(-) in the xylem exerts positive feedback on its loading into the xylem through a change in the voltage dependence of the Quickly Activating Anion Conductance, X-QUAC. Properties of this conductance were investigated on xylem-parenchyma protoplasts prepared from roots of Hordeum vulgare by applying the patch-clamp technique. Chord conductances were minimal around -40 mV and increased with plasma membrane depolarisation as well as with hyperpolarisation. Two gates with opposite voltage dependences were postulated. When 30 mM Cl- in the bath was replaced by NO(3)(-), a shift in the midpoint potential of the depolarisation-activated gate by about -60 mV from 43 to -16 mV occurred (K(m) = 3.4 mM). No such effect was seen when chloride was replaced by malate. Addition of 10 mM NO(3)(-)to the pipette solution and reduction of [Cl-] from 124 to 4 mM (to simulate cytoplasmic concentrations) did not interfere with the voltage dependence of X-QUAC activation, nor was it affected by changes in external [K+]. If only the NO(3)(-) effect on gating was considered, an increase of the NO(3)(-) concentration in the xylem sap to 5 mM would result in an enhancement of NO(3)(-) efflux by about 30%. Although the driving force for NO(3)(-) efflux would be reduced simultaneously, NO(3)(-) efflux into the xylem through X-QUAC would be maintained with high NO(3)(-) concentrations in the xylem sap; a situation which occurs for instance during the night.