The slow and the quick anion conductance in whole guard cells: their voltage-dependent alternation, and the modulation of their activities by abscisic acid and CO2.

We explored the functioning of the slowly activating anion conductance, S-type or SLAC, and of the quickly activating anion conductance, R-type or QUAC, in whole guard cells of Vicia faba L.; details of QUAC activity had not previously been demonstrated in guard cells possessing their walls. The discontinuous single-electrode voltage-clamp method was used to record current responses to voltage pulses and voltage ramps as well as the free-running membrane voltage. At all voltages tested between -200 and 60 mV, SLAC activated with two components, one had a time constant similar to 7 s, the other similar to 40 s. The current-voltage relationship resembled that obtained by patch-clamp experiments. In pulse experiments and 1-s ramps, QUAC activity appeared with half-maximum activation near -50 mV and full activation above -10 mV; it inactivated with a half-time of approximately 10 s. Inactivation of QUAC at -40 mV led to the appearance of SLAC. After deactivation of SLAC at -200 mV, QUAC could be activated again. We concluded that voltage-dependent interchanges between SLAC and QUAC had occurred. Frequently, SLAC and QUAC were active simultaneously in the same cell. Abscisic acid (ABA, 20 microM) activated SLAC as well as QUAC. External Ca2+ was not required, but enhanced the activation of QUAC. Rises in the partial pressure of CO2, in the range between 0 and 700 microbar, caused rapid and reversible increases in the activity of SLAC (and outward currents of K+). QUAC also responded to CO2, however in an unpredictable manner (either by increased or by decreased activity). Oscillations in the free-running membrane voltage arose either spontaneously or after changes in CO2. They were correlated with periodic activations and inactivations of QUAC and required the simultaneous activity of an electrogenic pump.

Alternation of the slow with the quick anion conductance in whole guard cells effected by external malate.

In previous investigations two anion conductances were discovered in guard-cell protoplasts: the quickly activating anion conductance (QUAC, R-type) and the slowly activating anion conductance (SLAC, S-type). In this investigation, effects of malate on the two anion conductances were tested in whole guard cells of Vicia faba L. by the use of the discontinuous single-electrode voltage-clamp method. Application of 1-s voltage ramps proved that QUAC displayed the malate shift of the activation threshold toward hyperpolarization also in complete guard cells. The sensitivity of SLAC to external malate was determined by responses to voltage pulses of 20 s duration at Cl- concentrations of 0.1, 3 or 50 mM. At no voltage were the currents measured at the end of the pulses in the presence and absence of malate significantly different from each other; the current-voltage relationship of SLAC appeared not to be affected by malate. However, in 32% of the cells exposed to malate, current activation in response to voltage steps occurred within 0.1 s, faster than was typical for SLAC, and activation was followed by inactivation with a half-time similar to 10 s: SLAC apparently had changed to QUAC. Simultaneously, the free-running membrane voltage depolarized at 0.1 mM Cl-, did not change at 3 mM Cl- and polarized at 50 mM Cl-, indicating that activation of QUAC increased the membrane conductance for anions and thereby drove the membrane voltage toward the equilibrium voltage of Cl-. The malate-induced changes were fully reversible at Cl- concentrations of 0.1 and 3 mM. These results reinforce the proposition that SLAC and QUAC represented two switching modes of the same anion channel (however, they do not suffice as proof); they also show that this interconvertibility can enable guard cells to control their membrane voltage rapidly.

Metabolite export of isolated guard cell chloroplasts of Vicia faba.

• Stomatal opening is caused by guard cell swelling due to an accumulation of osmotica. We investigated the release of carbon from guard cell chloroplasts as a source for the production of organic osmotica. • Photosynthetically active chloroplasts were isolated from guard cell protoplasts of Vicia faba. Export of metabolites into the surrounding medium was analyzed by silicone oil filtering centrifugation and spectrophotometrically by coupled metabolite assays. Effects of external oxaloacetate and 3-phosphoglycerate on photosynthetic electron transport were examined by recording chlorophyll fluorescence. • In the light, guard cell chloroplasts exported triose phosphates, glucose, maltose and hexose phosphates. The presence of phosphate in the medium was essential for the release of phosphorylated compounds and also strongly enhanced the export of glucose and maltose. Total efflux of carbon from illuminated guard cell chloroplasts was on average 486 µatom C (mg Chl)-1  h-1 , which was significant with respect to the carbon requirement for stomatal opening. • Metabolites released by illuminated guard cell chloroplasts originated predominantly from starch breakdown. Photosynthetic electron transport provided redox power for the reduction of oxaloacetate and 3-phosphoglycerate.

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.