A.H. de Boer

Arabidopsis thaliana and Saccharomyces cerevisiae NHX1 genes encode amiloride sensitive electroneutral Na+/H+ exchangers

Sodium at high millimolar levels in the cytoplasm is toxic to plant and yeast cells. Sequestration of Na(+) ions into the vacuole is one mechanism to confer Na(+)-tolerance on these organisms. In the present study we provide direct evidence that the Arabidopsis thaliana At-NHX1 gene and the yeast NHX1 gene encode low-affinity electroneutral Na(+)/H(+) exchangers. We took advantage of the ability of heterologously expressed At-NHX1 to functionally complement the yeast nhx1-null mutant. Experiments on vacuolar vesicles isolated from yeast expressing At-NHX1 or NHX1 provided direct evidence for pH-gradient-energized Na(+) accumulation into the vacuole. A major difference between NHX1 and At-NHX1 is the presence of a cleavable N-terminal signal peptide (SP) in the former gene. Fusion of the SP to At-NHX1 resulted in an increase in the magnitude of Na(+)/H(+) exchange, indicating a role for the SP in protein targeting or regulation. Another distinguishing feature between the plant and yeast antiporters is their sensitivity to the diuretic compound amiloride. Whereas At-NHX1 was completely inhibited by amiloride, NHX1 activity was reduced by only 20-40%. These results show that yeast as a heterologous expression system provides a convenient model to analyse structural and regulatory features of plant Na(+)/H(+) antiporters.

Properties of the K+ inward rectifier in the plasma membrane of xylem parenchyma cells from barley roots: Effects of TEA+, Ca2+, Ba2+ and La3+

Xylem parenchyma cells are situated around the (apoplastic) xylem vessels and are involved in the control of the composition of the xylem sap by exporting and resorbing solutes. We investigated properties of the K+ inward rectifier in the plasma membrane of these cells by performing patch clamp experiments on protoplasts in the whole-cell configuration. Inward currents were sensitive to the K+ channel blocker TEA+ at a high concentration (20 mm). Barium, another “classical” K+ channel blocker, inhibited K+ currents with a Ki of about 1.3 mm. In contrast to guard cells, the cytosolic Ca2+ level proved to be ineffective in regulating the K+ conductance at hyperpolarization. External Ca2+ blocked currents weakly in a voltage-dependent manner. From instantaneous current-voltage curves, we identified a binding site in the channel pore with an electrical distance of about 0.2 to 0.5. Lanthanum ions reduced the inward current in a voltage-dependent manner and simultaneously displaced the voltage at which half of the channels are in the open state to more positive values. This finding was interpreted as resulting from a sum of two molecular effects, an interaction with the mouth of the channel that causes a reduction of current, and a binding to the voltage sensor, leading to a shielding of surface charges and, subsequently, a modulation of channel gating.A comparison between the K+ inward rectifier in xylem parenchyma cells, guard cells and KAT1 from Arabidopsis leads to the conclusion that these rectifiers form subtypes within one class of ion channels. The ineffectiveness of Ca2+ to control K+ influx in xylem parenchyma cells is interpreted in physiological terms.

Effects of dormancy-breaking chemicals on ABA levels in barley grain embryos

The endogenous ABA contents of dormant and nondormant barley grains were determined following application of different compounds to break dormancy. The chemicals used for breaking of dormancy in intact dormant grains were weak and strong acids, alcohols,. hydrogen peroxide, cyanide, nitrate, salicylic acid, gibberellic acid and fusicoccin. The dormancy-breaking compounds could be classified into two major groups: compounds that caused a decrease in endogenous ABA (class I) and compounds which did not affect endogenous ABA (class II). Class I compounds included gibberellic acid, ethanol, hydrogen peroxide, nitrate, salicylic acid; class II compounds were fusicoccin, acid (H2SO4), sodium azide, n-caproic acid. in addition, these dormancy-breaking compounds were able to stimulate the germination rate when applied to embryos isolated from dormant grains. The concentrations necessary for stimulation of germination of isolated embryos were much lower than the concentrations for breaking the dormancy of intact grains. After embryos were isolated from dormant grains and incubated in water, ABA was determined in both embryos and in the incubation media. The class I compounds stated above also reduced ABA content in the incubation medium of isolated embryos, while class II compounds had no effect on ABA content of the medium. External application of ABA could overcome the effect of dormancy-breaking compounds of class I but not of class II. The results suggest that in the presence of the agents belonging to class II, ABA responsiveness of isolated embryos from dormant grains is decreased, compared to nontreated embryos.

Involvement of 14-3-3 proteins in the osmotic regulation of H+- ATPase in plant plasma membranes.

Abstract. Taking the binding of fusicoccin to plasma membranes as an indicator of complex formation between the 14-3-3 dimer and H+-ATPase, we assessed the effect of osmotic stress on the interaction of these proteins in suspension-cultured cells of sugar beet (Beta vulgaris L.). An increase in osmolarity of the cell incubation medium, accompanied by a decrease in turgor, was found to activate the H+ efflux 5-fold. The same increment was observed in the number of high-affinity fusicoccin-binding sites in isolated plasma membranes; the 14-3-3 content in the membranes increased 2- to 3-fold, while the H+-ATPase activity changed only slightly. The data obtained indicate that osmotic regulation of H+-ATPase in the plant plasma membrane is achieved via modulation of the coupling between H+ transport and ATP hydrolysis, and that such regulation involves 14-3-3 proteins.

Do 14-3-3 proteins and plasma membrane H+-ATPases interact in the barley epidermis in response to the barley powdery mildew fungus?

Abstract14-3-3 proteins form a family of highly conserved proteins with central roles in many eukaryotic signalling networks. In plants, they bind to and activate the plasma membrane H+-ATPase, creating a binding site for the phytotoxin fusicoccin. Barley 14-3-3 transcripts accumulate in the epidermis upon inoculation with the powdery mildew fungus. We have isolated a cDNA encoding a plasma membrane H+-ATPase (HvHA1), which is also induced by powdery mildew attack. The C-terminal domain of this H+-ATPase interacts with 14-3-3 proteins in the yeast two-hybrid system. Inoculation with the powdery mildew fungus, or treatment with fusicoccin, results in an increase in fusicoccin binding ability of barley leaf membranes. Overlay assays show a fungus-induced increase in binding of digoxygenin-labelled 14-3-3 protein to several proteins including a 100 kDa membrane protein, probably the plasma membrane H+-ATPase. These effects are seen specifically in the inoculated epidermis and not in the whole leaf. We propose that 14-3-3 proteins are involved in an epidermis-specific response to the powdery mildew fungus, possibly via an activation of the plasma membrane H+-ATPase.

Regulatory mechanisms of ion channels in xylem parenchyma cells

Xylem parenchyma cells surround the xylem vessels and control the composition of the transpiration stream which flows through the vessels. In the plasma membrane of the xylem parenchyma cells, one inward rectifying channel (denoted KIRC) and two outward rectifying channels (denoted KORC and NORC) have been identified. In the present study it is shown that KIRC was activated by Gpp(NH)p, in contrast to the inward rectifier in guard cells. In the inside-out patch configuration, Gpp(NH)p elicited single channel KIRC activity as well and the conclusion is, therefore, that KIRC is G-protein regulated in a membrane-delimited fashion. NORC gating is affected by the calcium buffering capacity of the pipette solution as determined by the amount of EGTA. KORC conductance is shown to be strongly dependent upon the apoplastic K(+)-concentration. The role of the above-mentioned transporters and their regulation mechanisms are discussed in the light of root:shoot communication and long-distance signalling.

Laser microsurgery: a versatile tool in plant (electro) physiology

SummaryIn plant cells the cell wall is a formidable obstacle in many physiological studies such as patch-clamp measurements and cell labelling with antibodies. Enzymatic digestion of the cell wall, in order to release a protoplast, has a number of disadvantages; therefore we worked out an alternative method to gain access to the plasma membrane. The wall of specialized cells from three higher plant species and one unicellular alga were perforated using the focussed UV light of a nitrogen laser. In order to enhance the absorption of the UV light by the walls, a dye was used that binds specifically to cell wall components. Extrusion of the protoplast or parts thereof was controlled by a regulated gradual decrease of the osmolarity of the solution surrounding the cells. Cytoplasmic streaming and chloroplast circulation were maintained in the protoplasts, demonstrating their viability after the wall perforation with the laser. Continuous deposition of new cell wall material by the polar tip of pollen tubes after surgical removal of the wall at the tip is another demonstration of the viability of the cells. Formation of high resistance seals between the plasma membrane and a patch pipet was surprisingly difficult. The role of ‘Hechtian strands’ and continuing synthesis of cell wall material in seal formation is further investigated. Other applications for the surgical laser are: fusion of two cells or vacuoles, analysis of the composition of specific parts of the cell wall, and release of the vacuole from an identified cell type for patchclamp studies.

Higher order Arabidopsis 14-3-3 mutants show 14-3-3 involvement in primary root growth both under control and abiotic stress conditions

Summary Our research shows that there is isoform specificity and redundancy among 6 out of 13 14-3-3 members in root growth under control and abiotic stress conditions.

Spatial Coordination of Chloroplast and Plasma Membrane Activities in Chara Cells and Its Disruption through Inactivation of 14-3-3 Proteins

In Chara corallina cells exposed to continuous light, external pH (pHo) and photosystem II (PSII) photochemical yield show correlated banding patterns. Photosynthetic activity is low in cell regions producing alkaline zones and high in the acid regions. We addressed the question whether (and how) photosynthetic activity and plasma membrane (PM) H+-pumping and H+-conductance are coupled in the different bands. First, PM H+-pump activity was stimulated with fusicoccin. This resulted in a more acidic pH in the acid bands without disturbing the correlation of photosynthetic electron transport and H+ fluxes across the PM. Next, H+-pump activity was reduced through microinjection of a phosphorylated peptide matching the canonical 14-3-3 binding motif RSTpSTP in the acid cell region. Microinjection induced a rapid (~5 min) rise in pHo by ca. 1.0 unit near the injection site, whereas the injection of the non-phosphorylated peptide had no effect. This pH rise confirms the supposed inhibition of the H+-pump upon the detachment of 14-3-3 proteins from the H+-ATPase. However, the PSII yield in the cell regions corresponding to the new alkaline peak remained high, which violated the normal inverse relations between the pHo and PSII photochemical yield. We conclude that the injection of the competitive inhibitor of the H+ATPase disrupts the balanced operation of PM H+-transport and photosynthetic electron flow and promotes electron flow through alternative pathways.

The gating kinetics of the slow vacuolar channel. A novel mechanism for SV channel functioning

Although there is consensus that the slow vacuolar or SV channel is a Ca2+ release channel, the underlying mechanism of operation is still controversial. The main reason is that the voltage sensitivity of SV gating seems to exclude activation at hyperpolarized (physiological) membrane potentials. Inspired by a study of Gambale et al. (1993) and supported by simulation studies presented here, we interpreted SV activation and deactivation kinetics in terms of a cyclic state diagram originally applied to animal cation-selective channels. A cyclic state diagram allows two pathways of activation operating in opposite directions. One pathway represents the frequently observed slow activation at moderate depolarization (<130 mV). With the open state (O) next to the closed state initially occupied (C1), direct transitions from C1 to O can account for the fast activation observed at higher depolarized potentials (>130 mV). We hypothesize that similar state transitions directly to O may also occur during hyperpolarization. The implication of this proposed mechanism is that SV accomplishes its physiological role during hyperpolarization-evoked deactivation. Despite their rare occurrence and possibly short duration, these opening events may last long enough to substantially raise the local cytosolic free Ca2+ level at the channel mouth by as much as 600 nM/ms. Because under in vivo conditions the Ca2+ flux is inwardly directed, the mechanism presented here revives the notion that the SV channel can be subject to calcium-induced calcium release.