Isolation of Enterococcus hirae mutant deficient in low-affinity potassium uptake at alkaline pH

We here isolated an Enterococcus hirae mutant unable to grow well at pH 10. The influx rate calculated from steady-state 42K+/K+ exchange and the intracellular K+ concentration of the mutant were reduced to 53 and 55% of those of the wild-type, respectively. The activities of two high-affinity K+ uptake systems, KtrI and KtrII, were normal in the mutant, but the kinetics of net K+ uptake at pH 10 indicated that a low-affinity K+ uptake with a Km of about 20 mM (Kawano, M, Abuki, R, Igarashi, K, Kakinuma, Y. (2001) Arch. Microbiol. 175: 41-45), which were seen in the wild-type, was deficient in this mutant.     

Potassium uptake with low affinity and high rate in Enterococcus hirae at alkaline pH

Two high-affinity K+ uptake systems, KtrI and KtrII, have been reported in Enterococcus hirae. A mutant, JEMK1, defective in these two systems did not grow at pH 10 in low-K+ medium (less than 1 mM K+), but grew well when supplemented with 10 mM KCl. In this mutant, we found an energy-dependent K+ uptake at pH 10 with a low affinity for K+ (Km of approximately 20 mM) and an extremely high rate [Vmax of 1.6 micromol x min(-1) (mg protein)(-1)]. Rb+ uptake [Km of approximately 40 mM and Vmax of 0.5 micromol x min(-1) (mg protein)(-1)], which was inhibited competitively by K+ and less prominently by Cs+, was also observed. The specificity of this transport is likely to be K+>Rb+>Cs+. This peculiar K+ transport plays a role as a salvage mechanism against defects in high-affinity systems in the K+ homeostasis of this bacterium.     

Sodium ATPase and Sodium/proton Antiporter Are Not Obligatory for Sodium Homeostasis of Enterococcus hirae at Acid pH

Enterococcus hirae grows in a broad pH range from 5 to 11. An E. hirae mutant 7683 lacking the activities of two sodium pumps, Na⁺-ATPase and Na⁺/H⁺ antiporter, does not grow in high Na⁺ medium at pH above 7.5. We found that 7683 grew normally in high Na⁺ medium at pH 5.5. Although an energy-dependent sodium extrusion at pH 5.5 was missing, the intracellular levels of Na⁺ and K⁺ were normal in this mutant. The Na⁺ influx rates of 7683 and two other strains at pH 5.5 were much slower than those at pH 7.5. These results suggest that Na⁺ elimination of this bacterium at acid pH is achieved by a decrease in Na⁺ entry and a normal K⁺ uptake.     

Transport of protons and potassium ions across the membranes of bacteria <Emphasis Type="Italic">Enterococcus hirae</Emphasis> dependent on ATP and nicotinamide adenine dinucleotides

The transport of protons and potassium ions across the membranes of the bacteria Enterococcus hirae growing in an alkaline medium (pH 8.0) or under experimental conditions (pH 7.5) during glucose fermentation accomplished by a KtrI system of absorption of potassium ions, which can interact with F₀F₁-ATPase to form at H⁺-K⁺-pump, has been studied. It was found on cells with a high membrane permeability that the administration of nicotinamide adenine dinucleotides results in the potassium absorption which is insensitive to the inhibitor of F₀F₁-ATPase N,N′-dicyclohexylcarbodiimide. It is assumed that, along with the KtrI system which interacts with F₀F₁-ATPase, a separate KtrI or another K⁺ absorption system operates in these bacteria under particular conditions, which is dependent on NAD⁺ +NADH. Presumably, these interact with this system, changing its conformational state required for the transition to the “active” form.     

High affinity k uptake in maize roots: a lack of coupling with h efflux

We report here on the putative coupling between a high affinity K⁺ uptake system which operates at low external K⁺ concentrations (K_m = 10-20 micromolar), and H⁺ efflux in roots of intact, low-salt-grown maize plants. An experimental approach combining electrophysiological measurements, quantification of unidirectional K⁺(⁸⁶Rb⁺) influx, and the simultaneous measurement of net K⁺ and H⁺ fluxes associated with individual cells at the root surface with K⁺- and H⁺-selective microelectrodes was utilized. A microelectrode system described previously (IA Newman, LV Kochian, MA Grusak, and WJ Lucas [1987] Plant Physiol 84: 1177-1184) was used to quantify net ion fluxes from the measurement of electrochemical potential gradients for K⁺ and H⁺ ions within the unstirred layer at the root surface. No evidence for coupling between K⁺ uptake and H⁺ efflux could be found based on: (a) extremely variable K⁺:H⁺ flux stoichiometries, with K⁺ uptake often well in excess of H⁺ efflux; (b) dramatic time-dependent variability in H⁺ extrusion when both fluxes were measured at a particular location along the root over time; and (c) a lack of pH sensitivity by the high affinity K⁺ uptake system (to changes in external pH) when net K⁺ uptake, unidirectional K⁺(⁸⁶Rb⁺) influx, and K⁺-induced depolarizations of the membrane potential were determined in uptake solutions buffered at pH values from pH 4 to 8. Based on the results presented here, we propose that high affinity active K⁺ absorption into maize root cells is not mediated by a K⁺/H⁺ exchange mechanism. Instead, it is either due to the operation of a K⁺-H⁺ cotransport system, as has been hypothesized for Neurospora, or based on the striking lack of sensitivity to changes in extracellular pH, uptake could be mediated by a K⁺-ATPase as reported for Escherichia coli and Saccharomyces.     

Die pH-Abhängigkeit der Aufnahme von H2PO 4 - , SO 4 = , Na+ und K+ und ihre gegenseitige Beeinflussung bei Ankistrodesmus braunii

Summary Ion uptake was studied using ³²P, ³⁵S, ²²Na and ⁴²K as tracers in synchronized cells of Ankistrodesmus, which were slightly starved with respect to the ions to be investigated. In the light and in the dark, phosphate uptake is maximal between pH 5.5 and 6.5. Whereas Na⁺ in comparison to K⁺ enhances phosphate uptake in the light (8 to 9-fold) and in the dark, Ca⁺⁺ exerts only a slightly stimulatory effect. The stimulation of phosphate binding by Na⁺ occurs rapidly, even after less than 5 sec of incubation, and also in the presence of an equimolar concentration of K⁺.The pH-dependence of Na⁺-uptake in the light and in the dark is comparable to a dissociation curve: Na⁺-uptake increases with decreasing extracellular H⁺-concentration and is inversely proportional to phosphate uptake in the absence of Na⁺. The light:dark ratio of Na⁺-uptake at pH 8 amounts to 7:1. Mere adsorption of Na⁺ is similarly dependent on the pH. K⁺ strongly competes with Na⁺-uptake, even at pH 8. K⁺-uptake proceeds in a quite different manner from Na⁺-uptake and has an optimum at pH 7.Sulfate is taken up linearly in a biphasic process as a function of time; the pH-optimum lies between pH 7.5 and 8. K⁺ but not Na⁺ slightly enhances sulfate uptake.The Na⁺-enhancement of phosphate uptake can be related neither to a sodium-potassium exchange pump nor to a photosynthesis-dependent ion-exchange reaction.The results suggest that the uptake of phosphate, Na⁺ and K⁺, and the influence of alkali cations on phosphate uptake, but not sulfate uptake, are strongly dependent on fixed charges of the plasmalemma or even of the cell wall. These fixed charges may even prevent an active ion uptake.     

Induction of <Emphasis Type="Italic">Rhizopus oryzae</Emphasis> Pyruvate Decarboxylase Genes

A thalium chloride-resistant (TlCl^r) mutant strain and a sodium chloride-resistant (NaCl^r) mutant strain of the diazotrophic cyanobacterium Anabaena variabilis have been isolated by spontaneous and chemical mutagenesis by using TlCl, a potassium (K⁺) analog, and nitrosoguanidine (NTG), respectively. The TlCl^r mutant strain was found to be defective in K⁺ transport and showed resistance against 10 μM TlCl. However, it also showed sensitivity against NaCl (LD₅₀, 50 mM). In contrast, neither wild-type A. variabilis nor its NaCl^r mutant strain could survive in the presence of 10 μM TlCl and died even at 1 μM TlCl. The TlCl^r mutant strain exhibited almost negligible K⁺ uptake, indicating the lack of a K⁺ uptake system. High K⁺ uptake was, however, observed in the NaCl^r mutant strain, reflecting the presence of an active K⁺ uptake system in this strain. DCMU, an inhibitor of PS II, inhibited the K⁺ uptake in wild-type A. variabilis and its TlCl^r and NaCl^r mutant strains, suggesting that K⁺ uptake in these strains is an energy-dependent process and that energy is derived from photophosphorylation. This contention is further supported by the inhibition of K⁺ uptake under dark conditions. Furthermore, the inhibition of K⁺ uptake by KCN, DNP, and NaN₃ also suggests the involvement of oxidative phosphorylation in the regulation of an active K⁺ uptake system. The whole-cell protein profile of wild-type A. variabilis and its TlCl^r and NaCl^r mutant strains growing in the presence of 50 mM KCl was made in the presence and absence of NaCl. Lack of transporter proteins in TlCl^r mutant strain suggests that these proteins are essentially required for the active transport and accumulation of K⁺ and make this strain NaCl sensitive. In contrast, strong expression of the transporter proteins in NaCl^r mutant strain and its weak expression in wild-type A. variabilis is responsible for their resistance and sensitivity to NaCl, respectively. Therefore, it appears that the increased salt tolerance of the NaCl^r mutant strain was owing to increased K⁺ uptake and accumulation, whereas the salt sensitivity of the TlCl^r mutant strain was owing to the lack of K⁺ uptake and accumulation. Received: 7 March 2002 / Accepted: 8 April 2002     

The Ktr potassium transport system in Staphylococcus aureus and its role in cell physiology,antimicrobial resistance and pathogenesis

Potassium (K⁺) plays a vital role in bacterial physiology, including regulation of cytoplasmic pH, turgor pressure and transmembrane electrical potential. Here, we examine the Staphylococcus aureus Ktr system uniquely comprised of two ion‐conducting proteins (KtrB and KtrD) and only one regulator (KtrA). Growth of Ktr system mutants was severely inhibited under K⁺ limitation, yet detectable after an extended lag phase, indicating the presence of a secondary K⁺ transporter. Disruption of both ktrA and the Kdp‐ATPase system, important for K⁺ uptake in other organisms, eliminated regrowth in 0.1 mM K⁺, demonstrating a compensatory role for Kdp to the Ktr system. Consistent with K⁺ transport mutations, S. aureus devoid of the Ktr system became sensitive to hyperosmotic conditions, exhibited a hyperpolarized plasma membrane, and increased susceptibility to aminoglycoside antibiotics and cationic antimicrobials. In contrast to other organisms, the S. aureus Ktr system was shown to be important for low‐K⁺ growth under alkaline conditions, but played only a minor role in neutral and acidic conditions. In a mouse competitive index model of bacteraemia, the ktrA mutant was significantly outcompeted by the parental strain. Combined, these results demonstrate a primary mechanism of K⁺ uptake in S. aureus and a role for this system in pathogenesis.     

K+/H+ antiporter functions as a regulator of cytoplasmic pH in a marine bacterium,Vibrio alginolyticus

The marine bacterium, Vibrio alginolyticus, regulates the cytoplasmic pH at about 7.8 over the pH range 6.0–9.0. By the addition of diethanolamine (a membrane-permeable amine) at pH 9.0, the internal pH was alkalized and simultaneously the cellular K⁺ was released. Following the K⁺ exit, the internal pH was acidified until 7.8, where the K⁺ exit leveled off. The K⁺ exit was mediated by a K⁺/H⁺ antiporter that is driven by the outwardly directed K⁺ gradient and ceases to function at the internal pH of 7.8 and below. The Na⁺-loaded cells assayed in the absence of KCl generated inside acidic ΔpH at alkaline pH due to the function of an Na⁺/H⁺ antiporter, but the internal pH was not maintained at a constant value. At acidic pH range, the addition of KCl to the external medium was necessary for the alkalization of cell interior. These results suggested that in cooperation with the K⁺ uptake system and H⁺ pumps, the K⁺/H⁺ antiporter functions as a regulator of cytoplasmic pH to maintain a constant value of 7.8 over the pH range 6.0–9.0.     

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.     

Relation of potassium uptake to proton transport and activity of hydrogenases in Escherichia coli grown at low pH

Escherichia coli grown under anaerobic conditions in acidic medium (pH 5.5) upon hyperosmotic stress accumulates potassium ions mainly through the Kup system, the functioning of which is associated with proton efflux decrease. It was shown that H⁺ secretion but not glucose-induced K⁺ uptake was inhibited by N,N′-dicyclohexylcarbodiimide (DCC). The inhibitory effect of DCC on the H⁺ efflux was stronger in the trkA mutant with defective potassium transport. The K⁺ and H⁺ fluxes depended on the extent of hyperosmotic stress in the absence or presence of DCC. The decrease in external oxidation/reduction potential and H₂ liberation insensitive to DCC were recorded. It was found that the atpD mutant with nonfunctional F₀F₁-ATPase produced a substantial amount of H₂, while in the hyc mutant (but not the hyf mutant defective in hydrogenases 3 (Hyd-3) and 4 (Hyd-4)) the H₂ production was significantly suppressed. At the same time, the rate of K⁺ uptake was markedly lower in hyfR and hyfB-R but not in hycE or hyfA-B mutants; H⁺ transport was lowered and sensitive to DCC in hyf but not in hyc mutants. The results point to the relationship of K⁺ uptake with the Hyd-4 activity. Novel options of the expression of some hyf genes in E. coli grown at pH 5.5 are proposed. It is possible that the hyfB-R genes expressed under acidic conditions or their gene products interact with the gene coding for the Kup protein or directly with the Kup system.     

The Influence of Nitrate and Chloride Uptake on Expressed Sap pH, Organic Acid Synthesis, and Potassium Accumulation in Higher Plants

The influence of NO₃⁻ uptake and reduction on ionic balance in barley seedlings (Hordeum vulgare, cv. Compana) was studied. KNO₃ and KCl treatment solutions were used for comparison of cation and anion uptake. The rate of Cl⁻ uptake was more rapid than the rate of NO₃⁻ uptake during the first 2 to 4 hours of treatment. There was an acceleration in rate of NO₃⁻ uptake after 4 hours resulting in a sustained rate of NO₃⁻ uptake which exceeded the rate of Cl⁻ uptake. The initial (2 to 4 hours) rate of K⁺ uptake appeared to be independent of the rate of anion uptake. After 4 hours the rate of K⁺ uptake was greater with the KNO₃ treatment than with the KCl treatment, and the solution pH, cell sap pH, and organic acid levels with KNO₃ increased, relative to those with the KCl treatment. When absorption experiments were conducted in darkness, K⁺ uptake from KNO₃ did not exceed K⁺ uptake from KCl. We suggest that the greater uptake and accumulation of K⁺ in NO₃⁻-treated plants resulted from (a) a more rapid, sustained uptake and transport of NO₃⁻ providing a mobile counteranion for K⁺ transport, and (b) the synthesis of organic acids in response to NO₃⁻ reduction increasing the capacity for K⁺ accumulation by providing a source of nondiffusible organic anions.     

Constitutive inactivation of the hKv1.5 mutant channel, H463G, in K+-free solutions at physiological pH

Extracellular acidification and reduction of extracellular K⁺ are known to decrease the currents of some voltage-gated potassium channels. Although the macroscopic conductance of WT hKv1.5 channels is not very sensitive to [K⁺]_o at pH 7.4, it is very sensitive to [K⁺]_o at pH 6.4, and in the mutant, H463G, the removal of K⁺ _o virtually eliminates the current at pH 7.4. We investigated the mechanism of current regulation by K⁺ _o in the Kv1.5 H463G mutant channel at pH 7.4 and the wild-type channel at pH 6.4 by taking advantage of Na⁺ permeation through inactivated channels. Although the H463G currents were abolished in zero [K⁺]_o, robust Na⁺ tail currents through inactivated channels were observed. The appearnnce of H463G Na⁺ currents with a slow rising phase on repolarization after a very brief depolarization (2 ms) suggests that channels could activate directly from closed-inactivated states. In wild-type channels, when intracellular K⁺ was replaced by NMG⁺ and the inward Na⁺ current was recorded, addition of 1 mM K⁺ prevented inactivation, but changing pH from 7.4 to 6.4 reversed this action. The data support the idea that C-type inactivation mediated at R487 in Kv1.5 channels is influenced by H463 in the outer pore. We conclude that both acidification and reduction of [K⁺]_o inhibit Kv1.5 channels through a common mechananism (i.e., by increasing channel inactivation, which occurs in the resting state or develops very rapidly after activation).     

Conditions controlling relative uptake of potassium and rubidium by plants from soils

Earlier studies have demonstrated close inverse relationships between Rb⁺ concentrations in plants and pH or base (including K⁺) saturation of soils. This study aims at elucidating conditions in soils influencing plant uptake of Rb⁺. Growth experiments with Carex pilulifera L. were performed, modifying the acidity and K⁺ supply of acid soils and solutions. We were unable to assess any reduction in Rb⁺ uptake by adding precipitated CaCO₃ to acid soil unless pH was raised to near neutrality. Though not fully compensating the loss of soil solution K⁺and exchangeable K⁺ from uptake by the growing plants, soil treated with 0.5 mM K⁺ (as KCl) reduced the Rb⁺ concentration in the shoots by 40% without measurably changing soil pH. Experiments varying the pH and K⁺ concentration of a nutrient solution (20% Hoagland), spiked with 6 uM Rb⁺, clearly demonstrated that plant uptake of Rb⁺ and K⁺ was unaffected by acidity in the pH range 3.6–5.0 tested, whereas Rb⁺ uptake was reduced by ca. 50%, when K⁺ concentration was increased from 1.2 to 3.6 mM. The sensitivity of this reaction indicates that shortage or low availability of K⁺ controls Rb⁺ uptake from acid soils, being probably more important than soil acidity per se. Secondary effects of high soil acidity, such as leaching losses of K⁺, might also be of importance in accounting for the high uptake of Rb⁺ from such soils. It is suggested that leaf analysis of Rb⁺ may be used as a method to assess early stages of K⁺ deficiency in plants on acid soils.     

H fluxes in excised samanea motor tissue : I. Promotion by light

Previous investigators revealed that white light-promoted leaflet opening in Samanea saman (Jacq) Merrill depends upon K⁺ uptake by extensor cells and efflux from flexor cells of the pulvinus, while dark-promoted closure depends upon K⁺ fluxes in the opposite directions. We now monitored H⁺ fluxes during pulvinar movement to test a model proposing coupled H⁺/K⁺ fluxes. H⁺ fluxes were monitored by measuring changes in the pH of a weakly buffered solution (initial pH = 5.5) bathing excised strips of extensor or flexor tissue. White light at hour 3 of the usual dark period promoted pulvinar opening, H⁺ efflux from extensor cells and uptake by flexor cells, while darkness at hours 2 to 4 of the usual light period promoted pulvinar closure, H⁺ uptake by extensor cells and efflux from flexor cells. The following conditions altered H⁺ fluxes during dark-promoted closure. (a) Light reversed the directions of the fluxes in both extensor and flexor cells. (b) Anoxia increased the rate of H⁺ uptake by extensor cells and promoted H⁺ uptake (rather than efflux) by flexor cells, consistent with an outwardly directed H⁺ pump. KCN showed similar effects initially, but they were transient. (c) Increase in external pH from 5.5 to 6.7 promoted H⁺ efflux (rather than uptake) by extensor cells and increased the rate of H⁺ efflux from flexor cells, presumably by decreasing the rate of inward diffusion. (d) Change in external K⁺ did not alter H⁺ fluxes by extensor cells, but removal of external K⁺ decreased the rate of H⁺ efflux from flexor cells by 70%. These observations support a model for coupled H⁺/K⁺ fluxes in pulvinar cells during light-and dark-promoted leaflet movements.     

K+ Uptake by Fermenting Escherichia coli Cells: pH Dependent Mode of the TrkA System Operating

Escherichia coli accumulates K⁺ by means of multiple transportsystems, of which TrkA is the most prominent at neutral and alkalinepH while Kup is major at acidic pH. In the present study, K⁺ uptakewas observed with cells grown under fermentative conditions at an initialpH of 9.0 and 7.3 (the medium pH decreased to 8.4 and 6.8, respectively,during the mid-logarithmic growth phase), washed with distilled water andresuspended in a K⁺ containing medium at pH 7.5 in the presence ofglucose. The kinetics for this K⁺ uptake and the amount of K⁺accumulated by the wild type and mutants having a functional TrkA orKup could confirm that K⁺ uptake by E. coli grown either at pH 9.0or pH 7.3 occurs mainly through TrkA. The following results distinguishpH dependent mode of TrkA operating: (1) K⁺ uptake was inhibited byDCCD in cells grown either at pH 9.0 or pH 7.3, although the stoichiometryof K⁺ influx to DCCD-inhibited H⁺ efflux for bacteria grownat pH 9.0 varied with external K⁺ concentration, but remained constantfor cells grown at pH 7.3; (2) K⁺ uptake was observed with an atpDmutant grown at pH 9.0 but not at pH 7.3; (3) The DCCD-inhibited H⁺efflux was increased 8-fold less by 5 mM K⁺ added into a K⁺ freemedium for bacteria grown at pH 9.0 than that for cells grown at pH 7.3;(4) the DCCD-inhibited ATPase activity of membrane vesicles from bacteriagrown at pH 9.0 was reduced a little in the presence of 100 mM K⁺,but stimulated more than 2.4-fold at pH 7.3.     

Stimulation of Weak Acid Uptake and Increase in Cell Sap pH as Evidence for Fusicoccin- and K-Induced Cytosol Alkalinization

In maize root segments fusicoccin induced a consistent increase in cell sap pH (taken as representative of vacuolar pH). This effect was markedly enhanced by the presence of K⁺ in the medium, whereas in the absence of fusicoccin K⁺ did not significantly influence cell sap pH. Treatment with a weak acid at 2 mm concentration inhibited the uptake of a different (¹⁴C-labeled) weak acid fed at a lower concentration, thus suggesting that acidification of the cytoplasm inhibits weak acid uptake. Fusicoccin and K⁺ increased the rate of uptake of 5,5-dimethyloxazolidine-2,4-dione, butyric acid, or isobutyric acid slightly when fed separately, strongly when fed in combination. The synergism between fusicoccin and K⁺ in stimulating weak acid uptake was parallel to that observed for the stimulation of H⁺ extrusion. Application of the weak acid distribution method to a condition of `quasi-equilibrium' indicated that fusicoccin induces a cytosolic pH increase of about 0.14 unit. These results are interpreted as providing circumstantial evidence that fusicoccin- and K⁺- induced stimulation of H⁺ extrusion led to an alkalinization of the cytosol, and that other early metabolic responses, such as an increase in malate level, are a consequence of the increase in cytosolic pH.     

Evidence for a sodium-dependent proline and glycine-betaine uptake in the cyanobacterium <Emphasis Type="Italic">Nostoc muscorum</Emphasis>

The cyanobacterium Nostoc muscorum is able to utilized proline and glycine-betaine as a nitrogen source under unstressed growth conditions. This cyanobacterium when grow in modified Chu No. 10 medium (without Na⁺) unable to utilized proline and glycine-betaine as a nitrogen source. Spontaneously occurring mutant clones defective in Na⁺ transport (Na⁺-R) was isolated and analyzed for proline and glycine-betaine utilization. The mutant phenotype showed normal heterocyst frequency and nitrogenase activity even in the medium containing 1 mM proline or 1 mM glycine-betaine, indicates the role of Na⁺ for proline/glycine-betaine uptake. The Na⁺-R mutant showed 100% survival at pH 11 and was simultaneously able to uptake and utilize proline/glycine-betaine at higher alkaline pH. This indicates that proline and glycinebetaine uptake systems are more efficient at higher alkaline pH. Since, the hypersaline environments are rich in Na⁺ contents and have alkaline pH, therefore it is suggested that the origin and evolution of specific compatible solutes may not depend only on the osmoregulatory role they play, but also on the other ecological factors operating simultaneously in the organism’s niche.     

The Na+-Responsive ntp Operon Is Indispensable for Homeostatis of K+ and Na+ in Enterococcus hirae at Limited Proton Potential

Enterococcus hirae ATCC 9790 grew well in Na⁺-deficient, low-K⁺ medium, but growth was inhibited by carbonylcyanide m-chlorophenylhydrazone (CCCP). Growth inhibition and decrease of cellular K⁺ levels in the presence of CCCP were relieved by the addition of Na⁺ and a high concentration of K⁺. In contrast, in the mutant defective in Na⁺-ATPase or the NtpJ component of the KtrII K⁺ uptake system, CCCP-induced growth inhibition was rescued by a high concentration of K⁺ but not of Na⁺. These transporters are thus indispensable for homeostatis of K⁺ and Na⁺ at low proton potential.     

Suitability of Arabidopsis for studies on intracellular pH regulation: correlation between H+ pump activity, cytosolic pH and malate level in wild-type and in a mutant partially insensitive to fusicoccin

Data are presented on the suitability of Arabidopsis thaliana seedlings for studies on intracellular pH regulation. In this material, grown in the dark in liquid medium, the determination of weak acid distribution at equilibrium provides an adequate method for calculating cytosolic pH values, in spite of the failure of benzylamine as a vacuolar pH probe. The stimulation of the H⁺ pump by K⁺ or K⁺ and fusicoccin (FC) is associated with a marked alkalinization of both cytosol and cell sap, and with a strong increase in malate level, whereas its inhibition by erythrosin B (EB) leads to the opposite effects. A good quantitative correlation is evident between the changes in net H⁺ extrusion and those in intracellular pH and malate content, in particular, with FC+K⁺. Cell sap buffer capacity is strongly influenced by the different treatments, its changes being substantially accounted for by changes in malate level. A comparison between the values of intracellular pH and malate level in wt and in the 5-2 mutant shows that in the mutant the cytosolic pH is always more acidic, and the intracellular alkalinization induced by FC+K⁺ and also by K⁺ alone is significatively lower. These results support the view that the partial insensitivity of 5-2 to FC is due to a reduced functionality of the H⁺-extruding system on which FC acts, and that the depression of the H⁺ pump activity in the mutant does not depend on a possible regulation by constitutively higher cytosolic pH values.