The capacity of anaerobically grown bacteria to exchange the 2H+ of the cell for the K+ of the medium and to maintain a high K+ distribution between cell and medium

The N,N'-dicyclohexylcarbodiimide sensitive exchange of 2H+ of a cell for K+ of medium stable to pH, K+ activity and temperature changes has been discovered in anaerobically grown gram-negative Escherichia coli, Salmonella typhimurium. S. enteritidis, Proteus mirabilis, P. vulgaris, anaerobic gram-positive bacteria Streptococcus faecalis, Lactobacillus salivarius, L. lactis in the presence of exogenic energy source. This exchange in gram-negative bacteria is operating only at increase of medium osmolarity. The high K+ distribution between cell and medium has been reached during the exchange of 2H+ for one K+ and the corresponding potassium equilibrium potential is much more than the measured delta psi. In aerobically grown E. coli, S. typhimurium, Brevibacterium flavum and aerobic Micrococcus luteus exchange of 2H+ for K+ does not take place, the K+ distribution is lower and in good conformity with the measured delta psi. It is assumed that exchange of 2H+ for K+ in anaerobic bacteria is carried out by the H+-ATPase complex and the Trk (or Trk-like) system of K+ absorption united into the same membrane supercomplex which functions as the H+-K+-pump and supports the high K+ distribution between cell and medium.     

ATP-driven exchange of Na+ and K+ ions by Streptococcus faecalis

We describe the characterization of KtrII, a novel potassium transport system of Streptococcus faecalis, first discovered by H. Kobayashi [1982) J. Bacteriol. 150, 506-511). KtrII requires sodium ions and mediates the stoichiometric exchange of internal Na+ for external K+. Potassium accumulation is not energized by the electrochemical potentials of either H+ or Na+; the energy source is probably ATP. Two lines of evidence indicate that KtrII is a manifestation of the sodium-stimulated ATPase reported earlier (Heefner, D. L., and Harold, F. M. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 2798-2802). (i) Mutants that lack the ATPase also lack KtrII, and revertants recover both in parallel. (ii) KtrII and the Na+-ATPase are induced in parallel when cells are grown on media rich in sodium, particularly under conditions that limit the generation of a proton potential. KtrII is not induced in response to K+ deprivation. We propose that the Na+-ATPase exchanges Na+ for K+ ions.     

The nature of H+-K+-exchange in anaerobically and aerobically grown S. typhimurium

H+-K+-exchange via the Trk-like system of K+ accumulation takes place in anaerobically grown S. typhimurium LT-2 with stable ratio of DCC-sensitive ionic fluxes, equal to 2H+ of a cell for one K+ of the medium. This exchange is now observed in the mutant S. typhimurium TH-31 with unfunctional H+-ATPase. H+-K+-exchange in aerobically grown S. typhimurium LT-2 has unstable ratio of ionic fluxes. The rate of K+ uptake in anaerobically grown bacteria is higher than that in the aerobically grown ones. Q10 is about 1.8 both for H+ transfer and K+ uptake in anaerobically grown bacteria, but it is 1.7 and 0.9 respectively in the aerobically grown ones. Delta psi is not changed by different temperatures both in anaerobically and aerobically grown bacteria. The distribution of K+ in anaerobically grown bacteria is higher than 10(3) and the potassium equilibrium potential is much higher than the measured delta psi. In aerobically grown bacteria the distribution of K+ is in good conformity with the measured delta psi. H+ and K+ transport in anaerobically grown cells is likely to proceed by the same mechanism, which includes H+-ATPase and the Trk-like system. In aerobically grown bacteria these transport systems work separately, and the Trk-like system as K+-ionophore serving for K+ uptake across the electrical field on the membrane.     

Relation between H2 production and energy-dependent metabolism of H+ and K+ ions in E.coli

Anaerobically grown E. coli escape H2 into the medium during the operation of H(+)-K(+)-pump exchanging 2H+ from a cell for one K+ of the medium. Anaerobic cells grown in the nitrate medium as well as the aerobically grown bacteria possessed neither 2H+/K+ exchange system, nor the ability for H2 production. Introduction of N,N'-dicyclohexylcarbodiimide into the medium, the removal of external K+ or the decrease of external osmotic pressure blocked both the functioning of H(+)-K(+)-pump and H2 production. The substitution of glucose by lactate reduced the activity of bacteria without change in pump operation and H2 production. It is assumed that formate-hydrogen lease and H(+)-K(+)-pump are working in collaboration.     

Interconversion of components of the bacterial proton motive force by electrogenic potassium transport.

The influence of K+ ions on the components of the transmembrane proton motive force (delta mu H+) in intact bacteria was investigated. In K+-depleted cells of the glycolytic bacterium STreptococcus faecalis the addition of K+ ions caused a depolarization of the membrane by about 60 mV. However, since the depolarization was compensated for by an increase in the transmembrane pH gradient (delta pH), the total proton motive force remained almost constant at about 120 mV. Half-maximal changes in the potential were observed at K+ concentrations at which the cells accumulated K+ ions extensively. In EDTA-treated, K+-depleted cells of Escherichia coli K-12, the addition of K+ ions to the medium caused similar, although smaller changes in the components of delta mu H+. Experiments with various E. coli K-12 K+ transport mutants showed that for the observed potential changes the cells required either a functional TrkA or Kdp K+ transport system. These data are interpreted to mean that the inward movement of K+ ions via each of these bacterial transport systems is electrogenic. Consequently, it leads to a depolarization of the membrane, which in its turn allows the cell to pump more protons into the medium.     

Effect of the preparation method on Na+-H+ exchange and ion permeabilities in rat renal brush-border membranes

The delta pH-dependent quenching of Acridine orange was used to characterize Na+-H+ exchange and K+ and H+ conductances in brush-border membrane vesicles isolated by precipitation with either CaCl2 or MgCl2 from rat kidney cortex. A transmembrane pH difference of 2.5 units (inside acidic) was imposed and the initial rate of its dissipation was followed after injecting a puls of tetramethylammonium gluconate (control) or sodium or potassium gluconate. In membranes isolated by CaCl2, the Na+-H+ exchange was partially electroneutral (45% to 77% of the total exchange) and the rest was due to electrically coupled Na+ and H+ movements through conductive pathways in the membranes. In membranes prepared by MgCl2, the rate of total Na+-H+ exchange was about twice as high as that in membranes obtained by CaCl2 precipitation. However, total and electroneutral exchanges were equal indicating negligible electrically coupled Na+ and H+ movements in these membranes. K0.5 for Na+ in all preparations was in the same range, being in average 30 mM. Amiloride was a competitive inhibitor of Na+-H+ exchange in membranes obtained with both preparations; Ki values ranged between 0.1 and 0.58 mM. The rates of delta pH-dissipation with K+ gradients (+/- valinomycin) were by 50% to 150% higher in membranes prepared with CaCl2 than in membranes isolated with MgCl2 indicating much higher H+ and K+ conductances in membranes obtained with CaCl2. Therefore, the rate of Na+-H+ exchange as well as the conductances for various ions in the isolated brush-border membranes depend on membrane preparation.     

Osmotic activity and ionic permeability of membrane vesicles from Streptococcus faecalis and Micrococcus lysodeikticus cells]

Membrane fractions containing osmotically active vesicles with sufficiently low membrane permeability for K+, Na+ and Cl- ions typical for the intact cell membrane were isolated from the cells of the glycolyzing bacterium Streptococcus faecalis. In their osmotic properties and ionic permeability the membrane fractions of S. faecalis were found similar to those of the respiring bacterium Micrococcus lysodeikticus, which are capable of the energy-dependent potassium transport. It may be thus assumed that the S. faecalis fractions obtained may be used to study ionic transport. The removal of proton-dependent ATPase of the S. faecalis membrane preparations did not affect the permeability of membranes for K+ ions which is indicative of different mechanisms of proton and potassium translocation.     

A nonelectrogenic H+ pump in plasma membranes of hog stomach.

Differential and density gradient centrifugation were used to prepare a vesicular membrane fraction from hog gastric mucosa enriched 17-fold with respect to cation-activated ATPase and 5'-AMPase. Fractionation of the gradient material by free flow electrophoresis resulted in a fraction 35-fold enriched in cation-activated ATPase and essentially free of 5'-AMPase and Mg2+ATPase. The addition of ATP to either fraction resulted in H+ uptake and Rb+ efflux. The ionophoric and osmotic sensitivity showed that these ion movements were due to transport rather than binding. The cation selectivity sequences, substrate specificities and action of inhibitors indicated that the transport was a function of K+ATPase activity. The characteristics of the ATP-dependent enhancement of SCN- uptake and 8-anilinonapthalene-1-sulfonate fluorescence in the presence of valinomycin and the action of ionophores and lipid-permeable ions suggested that the energy dependent K+:H+ exchange was effectively nonelectrogenic. Thus these vesicles contain a nonelectrogenic (H+ + K+)-ATPase, hence acid secretion by the stomach is probably due to an ATP-dependent H+ + K+ exchange.     

Identification of essential lysines involved in substrate binding of vacuolar H+-pyrophosphatase

H+-translocating pyrophosphatase (H+-PPase; EC 3.6.1.1) drives proton transport against an electrochemical potential gradient by hydrolyzing pyrophosphate (PPi) and is found in various endomembranes of higher plants, bacteria, and some protists. H+-PPase contains seven highly conserved lysines. We examined the functional roles of these lysines, which are, for the most part, found in the cytosolic regions of mung bean H+-PPase by site-directed mutagenesis. Construction of mutants that each had a cytosolic and highly conserved lysine substituted with an alanine resulted in dramatic drops in the PPi hydrolytic activity. The effects caused by ions on the activities of WT and mutant H+-PPases suggest that Lys-730 may be in close proximity to the Mg2+-binding site, and the great resistance of the K694A and K695A mutants to fluoride inhibition suggests that these lysines are present in the active site. The modifier fluorescein 5'-isothiocyanate (FITC) labeled a lysine at the H+-PPase active site but did not inhibit the hydrolytic activities of K250A, K250N, K250T, and K250S, which suggested that Lys-250 is essential for substrate binding and may be involved in proton translocation. Analysis of tryptic digests indicated that Lys-711 and Lys-717 help maintain the conformation of the active site. Proteolytic evidence also demonstrated that Lys-250 is the primary target of trypsin and confirmed its crucial role in H+-PPase hydrolysis.     

Selective permeability of bacterial membranes for monovalent thallium ions]

Transport of monovalent thallium ions in bacterial cells was studied. An energy-dependent transport of T1+ against electrochemical gradient into the cells of S. faecalis and Micrococcus lysodeikticus, according to the Michaelis-Menten kinetics was observed. T1+, being a K+ analog, is involved into active K+ transport. Unlike K+, T1+ readily penetrates bacterial membranes, reaching the level of stationary distribution between the cells and the medium. This permits to use T1+ as a penetrating cation to study the mechanism of potassium transport in bacteria without the use of ionophores, which can destroy the integrity of cell membranes.     

The modulation of rat brain Na(+)-Ca2+ exchange by K+

The involvement of potassium ions in the Na(+)-Ca2+ exchange process was studied in rat brain synaptic plasma membrane (SPM) vesicles. Addition of equimolar [K+] to the intravesicular and the extravesicular medium led to a stimulation of the Na+ gradient-dependent Ca2+ influx; this stimulation was noticeable already at 0.5 mM and reached its maximum at 2 mM K+. The magnitude of the K+ stimulation was between 1.3-2.5-fold in different SPM preparations. K+ ions also stimulated the Na(+)-dependent Ca2+ efflux. K+ stimulation of Na(+)-Ca2+ exchange is of considerable specificity, since it is not mimicked by either Li+ or H+. The following lines of evidence suggest that K+ modulation of Na(+)-Ca2+ exchange involves the catalytic moiety of the transporter itself and not an unrelated K+ channel which modulates the membrane potential. 1) K+ stimulation of the transport process was conserved following reconstitution of the transporter into phospholipid-rich liposomes, an experimental condition which presumably separates the native membrane proteins among different vesicular structures. 2) K+ stimulation of Na+ gradient-dependent Ca2+ influx persists also when the build up of negative inside membrane potential is prevented by addition of carbonyl cyanide p-trifluoromethoxy phenylhydrazone which renders the membrane highly permeable to protons both in the native and the reconstituted preparation. 3) K+ stimulation of Na+ gradient-dependent Ca2+ influx is obtained also when tetraethylammonium chloride, 2,3-diaminopyridine and Cs+ are added to the Ca2+ uptake medium. Reconstituted SPM vesicles take up 86Rb+ in response to activation of Na+ gradient-dependent Ca2+ influx. The ratio of Ca2+ taken up by SPM vesicles in a Na+ gradient-dependent manner to the corresponding amounts of Rb+ taken up varies between 8-5 in different SPM preparations. If the stoichiometry of the process is 1 Rb+/1 Ca2+, then Rb+ cotransport is mediated by 10-20% of the transporters present in the preparation.     

Reconstitution of the beef heart and rat liver mitochondrial K+/H+ (Na+/H+) antiporter. Quantitation of K+ transport with the novel fluorescent probe, PBFI

New indicators for fluorescent measurement of Na+ and K+ ions should prove particularly useful for studies of reconstituted carriers of these ions. We show that PBFI, a K(+)-specific probe, provides a convenient and sensitive assay for the study of K+ uptake mediated by the reconstituted mitochondrial K+/H+ (Na+/H+) antiporter. Fluorescent measurements have enabled us for the first time to establish reconstitution of the K+/H+ (Na+/H+) antiporter from beef heart as well as from rat liver mitochondria. This technique has also enabled us to establish that dicyclohexylcarbodiimide is capable of complete inhibition of K+/H+ antiport in the reconstituted system, in accord with findings in intact mitochondria. PBFI fluorescence, which measures net K+ uptake, was essential for this corroboration, since dicyclohexylcarbodiimide is not capable of complete inhibition of 42K+/K+ or 86Rb+/Rb+ exchange, presumably because it acts selectively on proton transport within the carrier.     

K+/H+ antiport in heart mitochondria

Heart mitochondria depleted of endogenous divalent cations by treatment with A23187 and EDTA swell in (a) K+ acetate or (b) K+ nitrate when an uncoupler is present. These mitochondria also exchange matrix 42K+ with external K+, Na+, or Li+ in a reaction that does not require respiration and is insensitive to uncouplers. Untreated control mitochondria do not swell in either medium nor do they show the passive cation exchange. Both the swelling and the exchange reactions are inhibited by Mg2+ and by quinine and other lipophilic amines. Swelling and exchange are both strongly activated at alkaline pH, and the exchange reaction is also increased markedly by hypotonic conditions. All of these properties correspond to those reported for a respiration-dependent extrusion of K+ from Mg2+-depleted mitochondria, a reaction attributed to a latent Mg2+- and H+-sensitive K+/H+ antiport. The swelling reactions are strongly inhibited by dicyclohexylcarbodiimide reacted under hypotonic conditions, but the exchange reaction is not sensitive to this reagent. Heart mitochondria depleted of Mg2+ show marked increases in their permeability to H+, to anions, and possibly to cations, and the permeability to each of these components is further increased at alkaline pH. This generalized increase in membrane permeability makes it likely that K+/H+ antiport is not the only pathway available for K+ movement in these mitochondria. It is concluded that the swelling, 42K+ exchange, and K+ extrusion data are all consistent with the presence of the putative K+/H+ antiport but that definitive evidence for the participation of such a component in these reactions is still lacking.     

Proton dissociation from nigericin at the membrane-water interface, the rate-limiting step of K+/H+ exchange on the bilayer lipid membrane.

The rate of K+/H+ exchange through bilayer lipid membranes (BLM) induced by nigericin was measured by the method of pH gradient offset according to Antonenko, Yu.N. and Yaguzhinsky L.S. [(1990) Biochim. Biophys. Acta 1026, 236-240]. It was shown that under the conditions of high potassium ion concentration the rate of nigericin-mediated K+/H+ exchange increased with an increase in the concentrations of such buffer compounds as citric acid and MES. The concentration dependence was different for citrate and MES. The buffer concentration effect was absent at low potassium ion concentrations. Citrate increased the rate of K+/H+ exchange being added to the side of BLM where the K+ concentration was higher and had no effect at the opposite side. At high KCl and citrate concentrations, the rate of K+/H+ exchange was about 6 times lower in D2O when compared to H2O solutions. It is concluded that under certain experimental conditions the overall rate of the K+/H+ exchange induced by nigericin is determined by the rate of proton dissociation from nigericin at the membrane-water interface.     

Electroneutral H+-K+ exchange in liver mitochondria. Regulation by membrane potential

The paper analyzes the factors affecting the H+-K+ exchange catalyzed by rat liver mitochondria depleted of endogenous Mg2+ by treatment with the ionophore A23187. The exchange has been monitored as the rate of K+ efflux following addition of A23187 in low-K+ media. (1) The H+-K+ exchange is abolished by uncouplers and respiratory inhibitors. The inhibition is not related to the depression of delta pH, whereas a dependence is found on the magnitude of the transmembrane electrical potential, delta psi. Maximal rate of K+ efflux is observed at 180-190 mV, whereas K+ efflux is inhibited below 140-150 mV. (2) Activation of H+-K+ exchange leads to depression of delta pH but not of delta psi. Respiration is only slightly stimulated by the onset of H+-K+ exchange in the absence of valinomycin. These findings indicate that the exchange is electroneutral, and that the delta psi control presumably involves conformational changes of the carrier. (3) Incubation in hypotonic media at pH 7.4 or in isotonic media at alkaline pH results in a marked activation of the rate of H+-K+ exchange, while leaving unaffected the level of Mg2+ depletion. This type of activation results in partial 'uncoupling' from the delta psi control, suggesting that membrane stretching and alkaline pH induce conformational changes on the exchange carrier equivalent to those induced by high delta psi. (4) The available evidence suggests that the activity of the H+-K+ exchanger is modulated by the electrical field across the inner mitochondrial membrane.     

Na+-K+ Exchange at the Xylem/Symplast Boundary (Its Significance in the Salt Sensitivity of Soybean)

We investigated the mechanism of Na+ reabsorption in exchange for K+ at the xylem/symplast boundary of soybean roots (Glycine max var Hodgson). The xylem vessels of excised roots were perfused with solutions of defined composition to discriminate between entry of ions into or reabsorption from the xylem vessels. In the presence of NaCl, the transport systems released K+ into the xylem sap and reabsorbed Na+. The Na+-K+ exchange was energized by proton-translocating ATPases, enhanced by external K+ concentration, and dependent on the anion permeability. Evidence was presented for the operation of H+/Na+ and H+/K+ antiporters at the xylem/symplast interface.     

Circulation of potassium across the plasma membrane of Blastocladiella emersonii: K+ channel.

A previous paper reported that the water mold Blastocladiella emersonii generates a transcellular electrical current, such that positive charges enter the rhizoid and leave from the thallus (Stump et al., Proc. Natl. Acad. Sci. U.S.A. 77: 6673-6677, 1980). To begin to understand the genesis of this current we investigated ionic relationships in this organism by use of intracellular microelectrodes. In cells suspended in buffered CaCl2, the membrane potential could be accounted for as a K+ diffusion potential; no evidence for an electrogenic pump was obtained. Potassium ions diffuse outward by a pathway that also carries Rb+ and Ba2+, but excludes both smaller and larger ions (Li+, Na+, Cs+, Mg2+, Ca2+, and choline). Chloride and other anions make little contribution to the potential, but the presence of Ca2+ in the external medium is required for successful potential measurements. In growing cells, the internal K+ concentration is generally somewhat higher than would be expected if the K+ distribution were determined entirely by the membrane potential. Under certain conditions, net uptake of K+ against the electrochemical potential gradient was observed. We suggest that K+ is actively accumulated by a primary transport system that may exchange K+ for H+, and that K+ leaks passively outward through the K+ channel. The K+ circulation across the membrane amounts to about 2% of the K+ pool per min, or 4.5 microA/cm2 of surface area. We propose that this K+ circulation is one arm of the transcellular current, carrying positive charge out of the thallus.     

Intravesicular pH changes in submitochondrial particles induced by monovalent cations: relationship to the Na+/H+ and K+/H+ antiporters

The fluorescence of internalized fluorescein isothiocyanate dextran has been used to monitor the intravesicular pH of submitochondrial particles (SMP). Respiring SMP maintain a steady-state delta pH (interior acid) that results from the inwardly directed H+ flux of respiration and an opposing passive H+ leak. Addition of K+, Na+, or Li+ to SMP results in a shift to a more alkaline interior pH (pHi) in both respiring and nonrespiring SMP. The K+-dependent change in pHi, like the K+/H+ antiport in intact mitochondria, is inhibited by quinine and by dicyclohexylcarbodiimide. The Na+-dependent reaction is only partially inhibited by these reagents. Both the Na+- and the K+-dependent pH changes are sensitive to amiloride derivatives. The Km for both Na+ and K+ is near 20 mM whereas that for Li+ is closer to 10 mM. The K+/H+ exchange reaction is only slightly inhibited by added Mg2+, but abolished when A23187 is added with Mg2+. The passive exchange is optimal at pHi 6.5 with either Na+ or K+, and cannot be detected above pHi of 7.2. Both the Na+/H+ and the K+/H+ exchange reactions are optimal at an external pH of 7.8 in respiring SMP (pHi 7.1). Valinomycin stimulates the K+-dependent pH change in nonrespiring SMP, as does nigericin. It is concluded that SMP show K+/H+ antiport activity with properties distinct from those of Na+/H+ antiport. However, the properties of the K+/H+ exchange do not correspond in all respects to those of the antiport in intact mitochondria. Donnan equilibria and parallel uniport pathways for H+ and cations appear to contribute to cation-dependent pH changes in SMP.     

A novel intracellular K+/H+ antiporter related to Na+/H+ antiporters is important for K+ ion homeostasis in plants

In this study we have identified the first plant K+/H+ exchanger, LeNHX2 from tomato (Lycopersicon esculentum Mill. cv. Moneymaker), which is a member of the intracellular NHX exchanger protein family. The LeNHX2 protein, belonging to a subfamily of plant NHX proteins closely related to the yeast NHX1 protein, is abundant in roots and stems and is induced in leaves by short term salt or abscisic acid treatment. LeNHX2 complements the salt- and hygromycin-sensitive phenotype caused by NHX1 gene disruption in yeast, but affects accumulation of K+ and not Na+ in intracellular compartments. The LeNHX2 protein co-localizes with Prevacuolar and Golgi markers in a linear sucrose gradient in both yeast and plants. A histidine-tagged version of this protein could be purified and was shown to catalyze K+/H+ exchange but only minor Na+/H+ exchange in vitro. These data indicate that proper functioning of the endomembrane system relies on the regulation of K+ and H+ homeostasis by K+/H+ exchangers.     

Participation of hyf-encoded hydrogenase 4 in molecular hydrogen release coupled with proton-potassium exchange in Escherichia coli

In a previous work (Trchounian et al., Biol. Membrany 16:416-428 (1999) (in Russian)) we reported the interrelations between production of H2 and H+-K+ exchange in fermenting Escherichia coli grown under anaerobic conditions at pH 7.5. The ion fluxes had stable stoichiometry 2H+/K+ and were N,N'-dicyclohexylcarbodiimide (DCC)-inhibitable at different external pH and K+ activity. In the present study, the H2 production was further studied in fermenting bacteria grown at pH 7.5 or 6.5. The H2 production was inhibited by DCC and did not occur if bacteria were grown at pH 7.5 in a medium containing formate or upon hypoosmotic stress. The H2 production was not sensitive to osmotic stress when bacteria were grown at pH 6.5. Formation of H2 and 2H+/K+ exchange were not observed in mutants with deletions of the hyfoperon genes, encoding membrane-associated hydrogenase 4. K+ influx in these mutants was not sensitive to valinomycin, in contrast to the K+ influx in the parental strain. If grown at pH 6.5, the mutants produced H2 and carried out 2H+/K+ exchange, when subjected to the hyperosmotic stress. The results suggest a participation of hydrogenase 4 in the production of H2 and proton-potassium exchange in fermenting E. coli grown at pH 7.5. In bacteria grown at pH 6.5 or in a medium containing formate, another membrane-bound hydrogenase, namely hydrogenase 3, may be responsible for the H2 production.