Phosphatidic acid directly binds with rice potassium channel OsAKT2 to inhibit its activity

The plant Shaker K⁺ channel AtAKT2 has been identified as a weakly rectifying channel that can stabilize membrane potentials to promote photoassimilate phloem loading and translocation. Thus, studies on functional characterization and regulatory mechanisms of AtAKT2‐like channels in crops are highly important for improving crop production. Here, we identified the rice OsAKT2 as the ortholog of Arabidopsis AtAKT2, which is primarily expressed in the shoot phloem and localized at the plasma membrane. Using an electrophysiological assay, we found that OsAKT2 operated as a weakly rectifying K⁺ channel, preventing H⁺/sucrose‐symport‐induced membrane depolarization. Three critical amino acid residues (K193, N206, and S326) are essential to the phosphorylation‐mediated gating change of OsAKT2, consistent with the roles of the corresponding sites in AtAKT2. Disruption of OsAKT2 results in delayed growth of rice seedlings under short‐day conditions. Interestingly, the lipid second messenger phosphatidic acid (PA) inhibits OsAKT2‐mediated currents (both instantaneous and time‐dependent components). Lipid dot‐blot assay and liposome‐protein binding analysis revealed that PA directly bound with two adjacent arginine residues in the ANK domain of OsAKT2, which is essential to PA‐mediated inhibition of OsAKT2. Electrophysiological and phenotypic analyses also showed the PA‐mediated inhibition of AtAKT2 and the negative correlation between intrinsic PA level and Arabidopsis growth, suggesting that PA may inhibit AKT2 function to affect plant growth and development. Our results functionally characterize the Shaker K⁺ channel OsAKT2 and reveal a direct link between phospholipid signaling and plant K⁺ channel modulation.     

Studies on Arabidopsis athak5, atakt1 double mutants disclose the range of concentrations at which AtHAK5, AtAKT1 and unknown systems mediate K+ uptake

The high‐affinity K⁺ transporter AtHAK5 and the inward‐rectifier K⁺ channel AtAKT1 have been described to contribute to K⁺ uptake in Arabidopsis thaliana. Studies with T‐DNA insertion lines showed that both systems participate in the high‐affinity range of concentrations and only AtAKT1 in the low‐affinity range. However the contribution of other systems could not be excluded with the information and plant material available. The results presented here with a double knock‐out athak5, atakt1 mutant show that AtHAK5 is the only system mediating K⁺ uptake at concentrations below 0.01 mM. In the range between 0.01 and 0.05 mM K⁺ AtHAK5 and AtAKT1 are the only contributors to K⁺ acquisition. At higher K⁺ concentrations, unknown systems come into operation and participate together with AtAKT1 in low‐affinity K⁺ uptake. These systems can supply sufficient K⁺ to promote plant growth even in the absence of AtAKT1 or in the presence of 10 mM K⁺ where AtAKT1 is not essential.     

The Os-AKT1 Channel Is Critical for K+ Uptake in Rice Roots and Is Modulated by the Rice CBL1-CIPK23 Complex

Potassium (K⁺) is one of the essential nutrient elements for plant growth and development. Plants absorb K⁺ ions from the environment via root cell K⁺ channels and/or transporters. In this study, the Shaker K⁺ channel Os-AKT1 was characterized for its function in K⁺ uptake in rice (Oryza sativa) roots, and its regulation by Os-CBL1 (Calcineurin B-Like protein1) and Os-CIPK23 (CBL-Interacting Protein Kinase23) was investigated. As an inward K⁺ channel, Os-AKT1 could carry out K⁺ uptake and rescue the low-K⁺-sensitive phenotype of Arabidopsis thaliana akt1 mutant plants. Rice Os-akt1 mutant plants showed decreased K⁺ uptake and displayed an obvious low-K⁺-sensitive phenotype. Disruption of Os-AKT1 significantly reduced the K⁺ content, which resulted in inhibition of plant growth and development. Similar to the AKT1 regulation in Arabidopsis, Os-CBL1 and Os-CIPK23 were identified as the upstream regulators of Os-AKT1 in rice. The Os-CBL1-Os-CIPK23 complex could enhance Os-AKT1-mediated K⁺ uptake. A phenotype test confirmed that Os-CIPK23 RNAi lines exhibited similar K⁺-deficient symptoms as the Os-akt1 mutant under low K⁺ conditions. These findings demonstrate that Os-AKT1-mediated K⁺ uptake in rice roots is modulated by the Os-CBL1-Os-CIPK23 complex.     

Whole-cell K+ current activation in response to voltages and carbachol in gastric parietal cells isolated from guinea pig

Summary Patch-clamp studies of whole-cell ionic currents were carried out in parietal cells obtained by collagenase digestion of the gastric fundus of the guinea pig stomach. Applications of positive command pulses induced outward currents. The conductance became progressively augmented with increasing command voltages, exhibiting an outwardly rectifying current-voltage relation. The current displayed a slow time course for activation. In contrast, inward currents were activated upon hyperpolarizing voltage applications at more negative potentials than the equilibrium potential to K⁺ (E _K). The inward currents showed time-dependent inactivation and an inwardly rectifying current-voltage relation. Tail currents elicited by voltage steps which had activated either outward or inward currents reversed at nearE _K, indicating that both time-dependent and voltagegated currents were due to K⁺ conductances. Both outward and inward K⁺ currents were suppressed by extracellular application of Ba²⁺, but little affected by quinine. Tetraethylammonium inhibited the outward current without impairing the inward current, whereas Cs⁺ blocked the inward current but not the outward current. The conductance of inward K⁺ currents, but not outward K⁺ currents, became larger with increasing extracellular K⁺ concentration. A Ca²⁺-mobilizing acid secretagogue, carbachol, and a Ca²⁺ ionophore, ionomycin, brought about activation of another type of outward K⁺ currents and voltage-independent cation currents. Both currents were abolished by cytosolic Ca²⁺ chelation. Quinine preferentially inhibited this K⁺ current. It is concluded that resting parietal cells of the guinea pig have two distinct types of voltage-dependent K⁺ channels, inward rectifier and outward rectifier, and that the cells have Ca²⁺-activated K⁺ channels which might be involved in acid secretion under stimulation by Ca²⁺-mobilizing secretagogues.     

Mechanisms of solute efflux from seed coats: whole-cell K+ currents in transfer cell protoplasts derived from coats of developing seeds of Vicia faba L.

In developing seed ofVicia faba L., solutes imported throughthe phloem of the coats move symplastically from the sieve elementsto a specialized set of cells (the thin-walled parenchyma transfercells) for release to the seed apoplast. Potassium (K⁺) is thepredominant cation released from the seed coats. To elucidatethe mechanisms of K⁺ efflux from seed coat to seed apoplast,whole-cell currents across the plasma membranes of protoplastsof thin-walled parenchyma transfer cells were measured usingthe whole-cell patch-clamp technique. Membrane depolarizationelicited a time-dependent and an instantaneous outward current.The reversal potential (E_R of the time-dependent outward currentwas close to the potassium equilibrium potential (E_K and itshifted in the same direction as E_K upon changing the externalK⁺ concentration, indicating that this current was largely carriedby an efflux of K⁺. The activation of the time-dependent outwardK⁺ current could be well fitted by two exponential componentsplus a constant. The instantaneous outward current could alsobe carried by K⁺ efflux as suggested by ion substitution experiments.These K⁺ outward rectifier currents elicited by membrane depolarizationare probably too small to represent the mechanism for the normalK⁺ efflux from seed coat cells. Membrane hyperpolarization morenegative than –80 mV activated a time-dependent inwardcurrent. K⁺ influx was responsible for the inward current asthe current reversed at membrane voltage close to E_K and shiftedin the same direction as E_K when external [K⁺] was varied. Activationof this K⁺inward rectifier current was well fitted with twoexponential components plus a constant. A regulating functionfor this current is suggested. Key words: Potassium outward rectifier, potassium inward rectifier, transfer cell protoplast, seed coat, Vicia faba L     

Calcineurin B‐like protein CBL10 directly interacts with AKT1 and modulates K+ homeostasis in Arabidopsis

Potassium transporters and channels play crucial roles in K⁺ uptake and translocation in plant cells. These roles are essential for plant growth and development. AKT1 is an important K⁺ channel in Arabidopsis roots that is involved in K⁺ uptake. It is known that AKT1 is activated by a protein kinase CIPK23 interacting with two calcineurin B‐like proteins CBL1/CBL9. The present study showed that another calcineurin B‐like protein (CBL10) may also regulate AKT1 activity. The CBL10‐over‐expressing lines showed a phenotype as sensitive as that of the akt1 mutant under low‐K⁺ conditions. In addition, the K⁺ content of both CBL10‐over‐expressing lines and akt1 mutant plants were significantly reduced compared with wild‐type plants. Moreover, CBL10 directly interacted with AKT1, as verified in yeast two‐hybrid, BiFC and co‐immunoprecipitation experiments. The results of electrophysiological analysis in both Xenopus oocytes and Arabidopsis root cell protoplasts demonstrated that CBL10 impairs AKT1‐mediated inward K⁺ currents. Furthermore, the results from the yeast two‐hybrid competition assay indicated that CBL10 may compete with CIPK23 for binding to AKT1 and negatively modulate AKT1 activity. The present study revealed a CBL‐interacting protein kinase‐independent regulatory mechanism of calcineurin B‐like proteins in which CBL10 directly regulates AKT1 activity and affects ion homeostasis in plant cells.     

Plasmalemmal voltage-activated K + currents in protoplasts from tobacco BY-2 cells: possible regulation by actin microfilaments?

Summary.  Plasmalemmal ionic currents from enzymatically isolated protoplasts of suspension-cultured tobacco ‘Bright Yellow-2’ cells were investigated by whole-cell patch-clamp techniques. In all protoplasts, delayed rectifier outward K⁺ currents having sigmoidal activation kinetics, no inactivation, and very slow deactivation kinetics were activated by step depolarization. Tail current reversal potentials were close to equilibrium potential E_K when external [K⁺] was either 6 or 60 mM. Several channel blockers, including external Ba²⁺, niflumic acid, and 5-nitro-2-(3-phenylpropylamino)-benzoic acid, inhibited this outward K⁺ current. Among the monovalent cations tested (NH₄ ⁺, Rb⁺, Li⁺, Na⁺), only Rb⁺ had appreciable permeation (P_Rb/P_K ⁼ 0.7). In addition, in 60 mM K⁺ solutions, a hyperpolarization-activated, time-dependent, inwardly rectifying K⁺ current was observed in most protoplasts. This inward current activated very slowly, did not inactivate, and deactivated quickly upon repolarization. The tail current reversal potential was very close to E_K, and other monovalent cations (NH₄ ⁺, Rb⁺, Li⁺, Na⁺) were not permeant. The inward current was blocked by external Ba²⁺ and niflumic acid. External Cs⁺ reversibly blocked the inward current without affecting the outward current. The amplitude of the inward rectifier K⁺ current was generally small compared to the amplitude of the outward K⁺ current in the same cell, although this was highly variable. Similar amplitudes for both currents occurred in only 4% of the protoplasts in control conditions. Microfilament-depolymerizing drugs shifted this proportion to about 12%, suggesting that microfilaments participate in the regulation of K⁺ currents in tobacco ‘Bright Yellow-2’ cells. Received December 7, 2001; accepted April 15, 2002; published online July 4, 2002 RID="*" ID="*" Correspondence and reprints: Pharmacologie et Physicochimie, UMR CNRS 7034, Faculté de Pharmacie, Université Louis Pasteur, 74 route du Rhin, BP 24, 67401 Illkirch, France. Abbreviations: TBY-2 Tobacco ‘Bright Yellow-2’; DHCB dihydrocytochalasin B; I_Kin inward rectifier K⁺ current; I_Kout outward K⁺ current; MFs microfilaments; MTs microtubules; NPPB 5-nitro-2-(3-phenylpropylamino)-benzoic acid.     

Relative contribution of AtHAK5 and AtAKT1 to K+ uptake in the high‐affinity range of concentrations

The relative contribution of the high‐affinity K⁺ transporter AtHAK5 and the inward rectifier K⁺ channel AtAKT1 to K⁺ uptake in the high‐affinity range of concentrations was studied in Arabidopsis thaliana ecotype Columbia (Col‐0). The results obtained with wild‐type lines, with T‐DNA insertion in both genes and specific uptake inhibitors, show that AtHAK5 and AtAKT1 mediate the ‐sensitive and the Ba²⁺‐sensitive components of uptake, respectively, and that they are the two major contributors to uptake in the high‐affinity range of Rb⁺ concentrations. Using Rb⁺ as a K⁺ analogue, it was shown that AtHAK5 mediates absorption at lower Rb⁺ concentrations than AtAKT1 and depletes external Rb⁺ to values around 1 μM. Factors such as the presence of K⁺ or during plant growth determine the relative contribution of each system. The presence of in the growth solution inhibits the induction of AtHAK5 by K⁺ starvation. In K⁺‐starved plants grown without , both systems are operative, but when is present in the growth solution, AtAKT1 is probably the only system mediating Rb⁺ absorption, and the capacity of the roots to deplete Rb⁺ is reduced.     

K outward rectifying channels as targets of phosphatase inhibitor deltamethrin inVicia faba guard cells

The dominant outward rectifier K⁺ currents were examined in protoplasts from Vicia faba guard cells. In whole-cell patch-clamp recordings, we generally observed that the conductance of the K⁺ inward and the outward rectifier gradually decreases with a half time in the order of 2.3 ± 0.7 min. As a consequence of this rundown, a new steady state was achieved which was 90 ± 5 percnt; lower than that obtained at the beginning of the recording. The rundown of the outward rectifier could be greatly reduced by pre-treating protoplasts either with the membrane permeable drug deltamethrin or by perfusing protoplasts with a pipette solution containing 5 μmol/L cyclosporine A. Furthermore, after the rundown, the conductance of the outward rectifier could be partially restored upon addition of 5 μmol/L deltamethrin to the bath medium. Since deltamethrin and cyclosporine A are established inhibitors of the calcium sensitive phosphatase calcineurin, the data argue for a participation of this type of phosphatase in the control of the activity of K⁺ outward rectifier channels in guard cells.     

Potassium currents in cultured rabbit retinal pigment epithelial cells

Membrane potential and ionic currents were studied in cultured rabbit retinal pigment epithelial (RPE) cells using whole-cell patch clamp and perforated-patch recording techniques. RPE cells exhibited both outward and inward voltage-dependent currents and had a mean membrane capacitance of 26±12 pF (sd, n=92). The resting membrane potential averaged ?31±15 mV (n=37), but it was as high as ?60 mV in some cells. When K⁺ was the principal cation in the recording electrode, depolarization-activated outward currents were apparent in 91% of cells studied. Tail current analysis revealed that the outward currents were primarily K⁺ selective. The most frequently observed outward K⁺ current was a voltage- and time-dependent outward current (I _K) which resembled the delayed rectifier K⁺ current described in other cells. I _K was blocked by tetraethylammonium ions (TEA) and barium (Ba²⁺) and reduced by 4-aminopyridine (4-AP). In a few cells (3–4%), depolarization to ?50 mV or more negative potentials evoked an outwardly rectifying K⁺ current (I _Kt) which showed more rapid inactivation at depolarized potentials. Inwardly rectifying K⁺ current (I _KI) was also present in 41% of cells. I _KI was blocked by extracellular Ba²⁺ or Cs⁺ and exhibited time-dependent decay, due to Na⁺ blockade, at negative potentials. We conclude that cultured rabbit RPE cells exhibit at least three voltage-dependent K⁺ currents. The K⁺ conductances reported here may provide conductive pathways important in maintaining ion and fluid homeostasis in the subretinal space.     

The K+ battery-regulating Arabidopsis K+ channel AKT2 is under the control of multiple post-translational steps

Potassium (K⁺) is an important nutrient for plants. It serves as a cofactor of various enzymes and as the major inorganic solute maintaining plant cell turgor. In a recent study, an as yet unknown role of K⁺ in plant homeostasis was shown. It was demonstrated that K⁺ gradients in vascular tissues can serve as an energy source for phloem (re)loading processes and that the voltage-gated K⁺ channels of the AKT2-type play a unique role in this process. The AKT2 channel can be converted by phosphorylation of specific serine residues (S210 and S329) into a non-rectifying channel that allows a rapid efflux of K⁺ from the sieve element/companion cells (SE/CC) complex. The energy of this flux is used by other transporters for phloem (re)loading processes. Nonetheless, the results do indicate that post-translational modifications at S210 and S329 alone cannot explain AKT2 regulation. Here, we discuss the existence of multiple post-translational modification steps that work in concert to convert AKT2 from an inward-rectifying into a non-rectifying K⁺ channel.Key words: potassium, channel, potassium channel, AKT2, phloem (re)loading, post-translational modifications, potassium batteryPotassium (K⁺) is the most abundant mineral element in plants, and together with nitrogen and phosphorous, is limiting for plant production in many natural and agricultural habitats. Voltage-gated K⁺ channels are key players in the acquisition of K⁺ ions from the soil and in its redistribution within the plant.¹ Structurally, these channels result from the assembly of four so-called α-subunits. The subunits are encoded by nine genes in Arabidopsis and both homo- and hetero-tetramers are expressed.^2,3 The K⁺ channel α-subunits can be categorized into four different subfamilies, based on the voltage-gating characteristics of the exogenous K⁺ conductance when expressed in an appropriate heterologous expression system. K_in α-subunits form hyperpolarization-activated channels that mediate K⁺ uptake.^4–7 K_out α-subunits form depolarization-activated channels that mediate K⁺ release from cells.^8–10 K_silent subunits appear unable to yield functional homomeric channels, but can combine with K_in subunits and fine-tune the K⁺-uptake properties of the resulting heteromeric channels.^11–14 Finally, K_weak α-subunits form channels with complex voltage-gating; they allow both K⁺ uptake and release.^15–19 In Arabidopsis, a single member is found in this subfamily, AKT2, and this channel can assemble in heteromeric channels with the K_in subunit KAT2.²⁰To date, only scarce and speculative information has been obtained for the function of K_weak channels. When expressed in heterologous expression systems, two different subpopulations of AKT2 channels differing in their sensitivity to voltage were found.²¹ Channels of the first type showed gating properties and currents analogous to that of K_in channels, while the other sort enabled a non-rectified (leak-like) current; they were open over the entire physiological voltage range.A given channel can be converted from one type to the other by post-translational modifications.²¹ A voltage-dependent phosphorylation was found to be an essential step for this switch,^22,23 although the kinase responsible for this conversion still needs to be uncovered.²⁴ In biophysical studies, mutant versions of the Arabidopsis K_weak channel subunit AKT2 have been created that showed impaired gating mode settings.^22,23 Recently, Gajdanowicz et al. generated transgenic Arabidopsis thaliana plants that express these mutant AKT2 channels in the background of the akt2-1 null-allele plant.²⁵ The major conclusion from analyses of these mutants is that the status switching of AKT2 from an inward-rectifying to a non-rectifying channel is crucial for plants to overcome energy-limiting conditions. This function of AKT2 could be correlated to its expression in phloem tissues. Selective expression of AKT2 under the control of the phloem companion cell-specific AtSUC2 promoter rescued the akt2-1 line, but conversely, selective expression of AKT2 under the control of the guard cell-specific GC1 promoter,²⁶ resulted in further impairment of plant growth (Fig. 1). By combining diverse experimental approaches with mathematical simulation methods, an existing model for phloem (re)loading^18,27 was fundamentally improved. This allowed the uncovering of a novel and interesting role of K⁺ in phloem physiology: K⁺ gradients present between the sieve element/companion cell (SE/CC) complex and the apoplast can serve as an energy source in phloem (re)loading processes. This “potassium battery” can be tapped by means of AKT2 regulation. This clarifies the observation of Deeken et al.²⁸ that in AKT2 loss-of-function mutant plants, assimilates leaking away from the sieve tube were not efficiently reloaded into the main phloem stream.Open in a separate windowFigure 1AKT2 expressed only in guard cells delays plant development. (A–C) Representative wild-type, akt2-1 and akt2-1+pGC1:AKT2 complementation plants grown for 7 weeks (A), 9 weeks (B) and 12 weeks (C) under 12-h day/12-h night conditions at normal light intensity (150 µmol m⁻² s⁻¹). (D) akt2-1+pGC1:AKT2 developed a similar number of leaves as the akt2-1 knock out plants, but bolting-time was delayed. (B and E) After 9 weeks, wild-type plants were at an advanced bolting stage, akt2-1 plants had started bolting, but only initial signs of bolting were visible in akt2-1+pGC1:AKT2 plants. (C and F) At 12 weeks, akt2-1 plants had caught up with the wild-type and akt2-1+pGC1:AKT2 was just starting to bolt, although rosette-leaves were showing clear signs of senescence. For the generation of akt2-1+pGC1:AKT2, the AKT2 cDNA was fused to the guard cell-specific GC1 promoter²⁶ kindly provided by J.I. Schroeder, San Diego. The pGC1:AKT2 construct was cloned into pGreen0229-35S by replacing the 35S promoter and then transformed into the akt2-1 knockout plant. All seeds were cold-treated for 24 h at 4°C. Plants were grown on artificial substrate (type GS-90, Einheitserde). After 2 weeks, seedlings were transferred to single pots. Plants were grown in 60% relative humidity at 21°C during the day and 18°C at night. Phenotypical analyses were done in the middle of the day. Data are shown as means ± SD of n ≥ 9 plants. Statistical analyses using Student''s t test: (D, WT/akt2-1: p < 2e-08; D, WT/pGC-AKT2: p < 2e-08; D, akt2-1/pGC-AKT2: p < 5e-03; E, WT/akt2-1: p < 4e-06; E, WT/pGC-AKT2: p < 1e-10; E, akt2-1/pGC-AKT2: p < 5e-04; F, WT/akt2-1: p = 0.51; F, WT/pGC-AKT2: p < 1e-10; F, akt2-1/pGC-AKT2: p < 1e-10).AKT2 expression is especially abundant in phloem tissues and the root stele, both of which are characterized by a poor availability of oxygen.^29,30 This local internal hypoxia impairs respiratory activity of the vascular tissue and concomitantly, respiratory ATP production is reduced.³¹ As a consequence, phloem transport is very susceptible to decreasing oxygen supply to the plant.^29,32 It is therefore comprehensible that the above mentioned support by the K⁺ driving force for sucrose retrieval is especially relevant in the phloem. Indeed Gajdanowicz et al.²⁵ showed that transgenic plants lacking the AKT2 K⁺ channel were severely impaired in growth when exposed to mild hypoxia (10% v:v), whereas growth of wild-type plants was unaffected by this treatment. These observations illustrate the importance of biochemical flexibility in plant cells to cope with the energetic consequences of the steep oxygen concentration gradients that generally occur in plant stems and roots.In fact, the role of K⁺ gradients in driving sugar, amino acid and organic acid transport across plant cell membranes was first suggested several decades ago.^33,34 Experimental evidence for this concept was provided by various tests in which pieces of plant tissue were incubated in solutions with different K⁺ concentrations and pH levels.^33,34 Unfortunately, at that time the lack of genetic information to support this hypothesis (e.g., identifying transporter proteins that could provide a molecular mechanism to explain the working mechanism of substrate transport driven by a K⁺-motive force) resulted in this idea falling into oblivion. Indeed, the unequivocal experimental observation of this new role of K⁺ gradients in phloem reloading is extremely challenging. Under normal experimental conditions, K⁺ fluxes and sucrose fluxes are coupled during phloem loading in source tissues and unloading in sink tissues. Nonetheless, computational simulations predict that under certain conditions, a local K⁺/Suc antiport is also thermodynamically possible. In this antiport system, the energy from the K⁺ gradient is used to transport Suc into the phloem. This process is only transient; flooding the apoplast with K⁺ will decrease the K⁺ gradient. However, the gradient can be maintained for longer if surrounding cells take up the apoplastic K⁺ for their own use. A K⁺/Suc antiport will not occur in obvious sink or source tissues since the energy balances in such cells are fundamentally different. Consequently, in these tissues only the coupled symport of K⁺ and Suc can be observed. However, the computational predictions allowed the identification of the experimental conditions under which the effect of the K⁺/Suc antiport system is empirically observable at the whole plant level.An essential role in the regulation of AKT2 is played by (de)phosphorylation events of serine residues at positions S210 and S329. The replacement of both serines by asparagine (AKT2-S210N-S329N) resulted in a K⁺-selective leak that is locked in a continuously open mode when the channels are expressed in Xenopus oocytes. Under certain conditions, plants expressing the AKT2-S210N-S329N mutation showed growth benefits over wild-type plants; akt2-1+AKT2-S210N-S329N plants reach the generative state faster, possess an increased number of leaves and increased fresh weight (Fig. 2). Intuitively, one would expect a continuously open channel to cause severe problems for the plant, not a benefit as was observed here. We therefore have to postulate that phosphorylation at residues AKT2-S210 and AKT2-S329 is insufficient for converting AKT2 from an inward-rectifying into a non-rectifying channel; other, as yet unknown mechanisms, must contribute to the switch in the AKT2 gating mode. Such a concept would correspond to results that would otherwise be hard to explain. For instance, when both serine residues were replaced by glutamate, the mutant AKT2-S210E-S329E still showed wild-type characteristics.²² The S to E substitution is expected to mimic the phosphorylated state better than the S to N replacement. Furthermore, position AKT2-K197 has a fundamental influence on the AKT2 gating mode.²³ AKT2 mutants with that particular lysine substituted with a serine are far less sensitive towards (de)phosphorylation; they display the characteristics of a pure inward-rectifying K⁺ channel,²³ and transgenic Arabidopsis plants expressing AKT2 channels with this substitution showed the characteristics of akt2-1 knock-out plants.²⁵ Initially, it was proposed that the positive charge is important for sensitizing AKT2 to phosphorylation. However, the charge-conserving mutant AKT2-K197R is similar to the charge inverting mutant AKT2-K197D,²³ a purely inward-rectifying channel (Fig. 3). We therefore need to take into account that in plants, K197 may also be a target of post-translational modification.³⁵ At present, we can explain the beneficial effect of the AKT2-S210N-S329N mutant on plant growth only by a multiple step regulation of AKT2 (Fig. 4). The double-N mutation would then bypass the phosphorylation step, but AKT2-S210N-S329N could still be deregulated into an inward-rectifying channel. Thus, AKT2 can be considered as a highly specialized K_in channel that can be converted into a leak-like channel by a cascade of post-translational modification steps.Open in a separate windowFigure 2Plants expressing the AKT2-S210N-S329N mutant reach the generative state faster than wild-type plants. The mutant channel AKT2-S210N-S329N was expressed under the control of the native AKT2 promoter in the akt2-1 knock-out background. (A) Photos of representative Arabidopsis thaliana plants grown 7 weeks under short day conditions (12-h day/12-h night, light intensity = 150 µE m⁻²s⁻¹). Seven weeks after sowing, plants expressing only AKT2-S210N-S329N mutant channels (n = 22) differed significantly (Student''s t test, p < 4e-05) from wild-type plants (n = 20) in the height of the main inflorescent stalk (B) and fresh weight (C). At later time points, these differences decrease.²⁵Open in a separate windowFigure 3The mutant AKT2-K197R channel is inward-rectifying. Steady-state current-voltage characteristics measured at the end of activation voltage steps. Currents were normalized to the current values measured at −145 mV in 10 mM K⁺ and are shown as means ± SD (n = 6).Open in a separate windowFigure 4Minimal model for AKT2 gating-mode regulation. To switch AKT2 from an inward-rectifying into a non-rectifying channel, at least two post-translational steps are postulated. (1) Phosphorylation at residues AKT2-S210 and AKT2-S329 (transitions [1]→[2] and [3]→[4]) and (2) a yet unknown modification that most likely involves the residue AKT2-K197 (transitions [1]→[3] and [2]→[4]). Only after both modifications will AKT2 allow the efflux of K⁺ (state [4]).     

The Extracellular K+ Concentration Dependence of Outward Currents through Kir2.1 Channels Is Regulated by Extracellular Na+ and Ca2+

It has been known for more than three decades that outward Kir currents (I_K1) increase with increasing extracellular K⁺ concentration ([K⁺]_o). Although this increase in I_K1 can have significant impacts under pathophysiological cardiac conditions, where [K⁺]_o can be as high as 18 mm and thus predispose the heart to re-entrant ventricular arrhythmias, the underlying mechanism has remained unclear. Here, we show that the steep [K⁺]_o dependence of Kir2.1-mediated outward I_K1 was due to [K⁺]_o-dependent inhibition of outward I_K1 by extracellular Na⁺ and Ca²⁺. This could be accounted for by Na⁺/Ca²⁺ inhibition of I_K1 through screening of local negative surface charges. Consistent with this, extracellular Na⁺ and Ca²⁺ reduced the outward single-channel current and did not increase open-state noise or decrease the mean open time. In addition, neutralizing negative surface charges with a carboxylate esterifying agent inhibited outward I_K1 in a similar [K⁺]_o-dependent manner as Na⁺/Ca²⁺. Site-directed mutagenesis studies identified Asp¹¹⁴ and Glu¹⁵³ as the source of surface charges. Reducing K⁺ activation and surface electrostatic effects in an R148Y mutant mimicked the action of extracellular Na⁺ and Ca²⁺, suggesting that in addition to exerting a surface electrostatic effect, Na⁺ and Ca²⁺ might inhibit outward I_K1 by inhibiting K⁺ activation. This study identified interactions of K⁺ with Na⁺ and Ca²⁺ that are important for the [K⁺]_o dependence of Kir2.1-mediated outward I_K1.     

Characterization of Vacuolar Malate and K Channels under Physiological Conditions

Patch-clamp techniques were employed to study the electrical properties of vacuoles from sugar beet (Beta vulgaris) cell suspensions at physiological concentrations of cytoplasmic Ca²⁺. Vacuoles exposed to K⁺ malate revealed the activation of instantaneous and time-dependent outward currents by positive membrane potentials. Negative potentials induced only instantaneous inward currents. The time-dependent outward currents were 10 times more selective for malate than for K⁺ and were completely blocked by zinc. Vacuoles exposed to KCl developed instantaneous currents when polarized to positive or negative membrane potentials. The time-dependent outward channels could serve as the route for the movement of malate into the vacuole, whereas K⁺ could move through the time-independent inward and outward channels.     

A calcium-dependent potassium current is increased by a single-gene mutation inParamecium

Summary The membrane currents of wild typeParamecium tetraurelia and the behavioral mutantteaA were analyzed under voltage clamp. TheteaA mutant was shown to have a greatly increased outward current which was blocked completely by the combined use of internally delivered Cs⁺ and external TEA⁺. This, along with previous work (Satow, Y., Kung, C., 1976,J. Exp. Biol. 65:51–63) identified this as a K⁺ current. It was further found to be a calcium-activated K⁺ current since this increased outward K⁺ current cannot be elicited when the internal calcium is buffered with injected EGTA. The mutationpwB, which blocks the inward calcium current, also blocks this increased outward K⁺ current inteaA. This shows that this mutant current is activated by calcium through the normal depolarization-sensitive calcium channel. While tail current decay kinetic analysis showed that the apparent inactivation rates for this calcium-dependent K⁺ current are the same for mutant and wild type, theteaA current activates extremely rapidly. It is fully activated within 2 msec. This early activation of such a large outward current causes a characteristic reduction in the amplitude of the action potential of theteaA mutant. TheteaA mutation had no effect on any of the other electrophysiological parameters examined. The phenotype of theteaA mutant is therefore a general decrease in responsiveness to depolarizing stimuli because of a rapidly activating calcium-dependent K⁺ current which prematurely repolarizes the action potential.     

Potassium Uptake Through the TOK1 K+ Channel in the Budding Yeast

The current through TOK1 (YKC1), the outward-rectifying K⁺ channel in Saccharomyces cerevisiae, was amplified by expressing TOK1 from a plasmid driven by a strong constitutive promoter. TOK1 so hyper-expressed could overcome the K⁺ auxotrophy of a mutant missing the two K⁺ transporters, TRK1 and TRK2. This trk1Δtrk2Δ double mutant hyperexpressing the TOK1 transgene had a higher internal K⁺ content than one expressing the empty plasmid. We examined protoplasts of these TOK1-hyperexpressing cells under a patch clamp. Besides the expected K⁺ outward current activating at membrane potential (V _m ) above the K⁺ equilibrium potential (E _K+ ), a small inward current was consistently observed when the V _m was slightly below E _K+ . The inward and the outward currents are similar in their activation rates, deactivation rates, ion specificities and Ba²⁺ inhibition, indicating that they flow through the same channel. Thus, the yeast outwardly rectifying K⁺ channel can take up K⁺ into yeast cells, at least under certain conditions. Received: 1 October 1998/Revised: 9 December 1998