Methanogenesis and the K+ transport system are activated by divalent cations in ammonia-treated cells of Methanospirillum hungatei

We describe a K+ transport system in Methanospirillum hungatei cells depleted of cytoplasmic K+ via an ammonia/K+ exchange reaction (Sprott, G. D., Shaw, K. M., and Jarrell, K. F. (1984) J. Biol. Chem. 259, 12602-12608). Ammonia-treated cells contained low concentrations of ATP and were unable to make CH4 or to transport 86Rb+. All of these properties were restored by CaCl2, MgCl2, or MnCl2, and not by CoCl2 or NiCl2. The Rb+ transport system had a Km of 0.42 and Vmax of 29 nmol/min X mg; K+ inhibited competitively. Both H2 and CO2 were required for appreciable transport, whereas air, valinomycin, or nigericin were potent inhibitors. The influx of Rb+ was electrogenic and associated with proton efflux, producing a delta pH (alkaline inside) in acidic media. In the absence of K+ (or Rb+), the activation of CH4 synthesis by Mg2+ produced little change in the cytoplasmic pH, showing that methanogenesis did not elicit a net efflux of protons. The pH optimum for transport was in the range 6.0-7.3 where the transmembrane pH gradient would contribute minimally to the proton motive force. Protonophores at pH 6.3 caused a partial decline in CH4 synthesis and the ATP content and dramatically collapsed Rb+ transport. These and other inhibitor experiments, coupled with the fact that the Rb+ gradient was too large to be in equilibrium with the proton motive force alone, suggest a role for both ATP and the proton motive force in Rb+ transport. Also, a role for K+ in osmoregulation is indicated.     

Modulation of electroneutral Na transport in sheep rumen epithelium by luminal ammonia

Ammonia is an abundant fermentation product in the forestomachs of ruminants and the intestine of other species. Uptake as NH3 or NH4+ should modulate cytosolic pH and sodium-proton exchange via Na+/H+ exchanger (NHE). Transport rates of Na+, NH4+, and NH3 across the isolated rumen epithelium were studied at various luminal ammonia concentrations and pH values using the Ussing chamber method. The patch-clamp technique was used to identify an uptake route for NH4+. The data show that luminal ammonia inhibits electroneutral Na transport at pH 7.4 and abolishes it at 30 mM (P < 0.05). In contrast, at pH 6.4, ammonia stimulates Na transport (P < 0.05). Flux data reveal that at pH 6.4, approximately 70% of ammonia is absorbed in the form of NH4+, whereas at pH 7.4, uptake of NH3 exceeds that of NH4+ by a factor of approximately four. The patch-clamp data show a quinidine-sensitive permeability for NH4+ and K+ but not Na+. Conductance was 135 +/- 12 pS in symmetrical NH(4)Cl solution (130 mM). Permeability was modulated by the concentration of permeant ions, with P(K) > P(NH4) at high and P(NH4) > P(K) at lower external concentrations. Joint application of both ions led to anomalous mole fraction effects. In conclusion, the luminal pH determines the predominant form of ammonia absorption from the rumen and the effect of ammonia on electroneutral Na transport. Protons that enter the cytosol through potassium channels in the form of NH4+ stimulate and nonionic diffusion of NH3 blocks NHE, thus contributing to sodium transport and regulation of pH.     

Ammonia uptake and its effects on ionoregulation in the freshwater crayfish Pacifastacus leniusculus (Dana)

Exposure of adult crayfish Pacifastacus leniusculus to Artificial Freshwater (AFW) media containing 1.5 m and 0.15 mmol x l(-1) total ammonia [Tamm; 0.1 x acute lethal concentration (24 h LC50) and 0.01 x 24 h LC50] and adjusted to pH 6.5, pH 8.2 and pH 10.5 resulted in significant increases in haemolymph ammonia over a 24-h period. Ammonia accumulated most rapidly at pH 10.5. These media were chosen to expose animals to a range of different un-ionised ammonia (UIA) [NH3] and ionised ammonia [NH4+] concentrations. From comparisons of measured transepithelial potential differences (PDte) with calculated Nernst potentials (PDNH4+) for the known haemolymph-to-medium gradients of [NH4+], it was deduced that, in pH 8.2 and pH 6.5 AFW, NH4+ was not in thermodynamic equilibrium across the integument (presumably gill epithelium). In pH 10.5 AFW with 1.5 mmol x l(-1) Tamm (predominantly NH3), the accumulation of ammonia in the haemolymph was in the NH4+ form due to haemolymph pH regulation by the crayfish in this alkaline external medium. Measured net fluxes of ammonia (Jamm(net)) were inwardly directed and maximal when [NH3] was the main component externally, but were also significant at pH 8.2 with high [NH4+] ([NH4+]:[NH3] approximately 20:1). Haemolymph Na+ depletion was significant and, over the 24-h exposure period, most rapid in high [NH3] medium but [Cl-] was unaffected. However, paradoxically, sodium uptake (measured JNa(in) on immediate transfer to high Tamm medium) was not significantly inhibited when [NH3] was the predominant ammonia species. In 1.5 mmol x l(-1) Tamm (mainly [NH4+), VNa(in) (the active component of JNa(in)) was significantly inhibited, particularly at low external [Na+]. This inhibition could not be demonstrated as one of competition at an Na+/NH4+ apical gill exchange site. The resultant net efflux of sodium from the animal showed that the ability of the animals to balance sodium losses at low external [Na+] was severely affected. Longer exposure to pH 10.5 AFW with high [NH3] (12 h) resulted in significantly increased JNa(out), while not significantly affecting JNa(in). Analysis of urinary Na+ losses showed that, while urinary flow rate and water reabsorption was most likely unaffected by ammonia exposure, final urine [Na+] was significantly elevated. The resulting urinary Na+ loss accounted for 63% of the increased JNa(out) in high [NH3] medium.     

Cation/proton antiport systems in Escherichia coli. Solubilization and reconstitution of delta pH-driven sodium/proton and calcium/proton antiporters

Uptake of 22Na+ and 45Ca2+ into everted membrane vesicles from Escherichia coli was measured with imposed transmembrane pH gradients, acid interior, as driving force. Vesicles loaded with 0.5 M KCl were diluted into 0.5 M choline chloride to create a potassium gradient. Addition of nigericin to produce K+/H+ exchange resulted in formation of a pH gradient. This imposed gradient was capable of driving 45Ca2+ accumulation. In another method vesicles loaded with 0.5 M NH4Cl were diluted into 0.5 M choline chloride, creating an ammonium diffusion potential. A gradient of H+ was produced by passive efflux of NH3. With an ammonium gradient as driving force, everted vesicles accumulated both 45Ca2+ and 22Na+. The data suggest that 22Na+ uptake was via the sodium/proton antiporter and 45Ca2+ via the calcium/proton antiporter. Uptake of both cations required alkaline pHout. A minimum pH gradient of 0.9 unit was needed for transport of either ion, suggesting gating of the antiporters. Octyl glucoside extracts of inner membrane were reconstituted with E. coli phospholipids in 0.5 M NH4Cl. NH4+-loaded proteoliposomes accumulated both 22Na+ and 45Ca2+, demonstrating that the sodium/proton and calcium/proton antiporters could be solubilized and reconstituted in a functional form.     

Ammonia accumulation in acetate-growing yeast

During growth on acetate, the pH of yeast cultures rises from 5.8 to around 7-8 in the stationary phase. This was found to result from acetic acid uptake and accompanying H+ loss. In addition, acetate-growing yeast were found to accumulate ammonia. The influence of pH on ammonia transport and accumulation was studied with the analogue [14C]methylamine with the following results. (a) Methylamine uptake kinetics from 0.1-50 mM were consistent with a single-component uptake system (NH+4 permease) at pH values more acidic than 6.5, and with a two-component system (NH+4 permease and NH3 diffusion) above pH 7.5. (b) Equilibrium accumulation of methylamine was found to increase with increasing pH. (c) Methylamine efflux from methylamine-loaded cells increased as the external pH decreased. It was concluded from measurements of the internal pH under various culture conditions that the accumulation of ammonia in acetate-growing alkaline cultures resulted from the sum of two processes: (1) an energy-driven NH+4 transport; and (2) NH3 diffusion dependent on the delta pH.     

Nigericin-induced death of an acidophilic bacterium.

At an external pH of 3.5, nigericin (which catalyses an electroneutral H+/K+ exchange) abolished the transmembrane proton gradient (delta pH) of Bacillus acidocaldarius, causing a rapid acidification of the cytoplasm from approximately pH 6.0 to pH 3.5. A pronounced loss of viability and fine-structural changes rapidly followed treatment with nigericin. A marked decline in respiration and an even more rapid decrease in cytoplasmic ATP were observed. Activity of at least one cytoplasmic enzyme decreased more slowly. There was no generalized loss in the integrity of the cytoplasmic membrane, as assayed by permeability to inulin or Na+ or by release of ultraviolet light-absorbing compounds. The loss of viability upon treatment with carbonyl cyanide m-chlorophenylhydrazone was similar to what observed with nigericin, so proton influx alone, rather than together with K+ efflux, was probably involved in the death of the organism. Moreover, acidification of the cytoplasm rather than abolition of the delta pH was the lethal event, since no loss of viability was observed when the delta pH was abolished by elevation of the external pH.     

Generation of a proton motive force by the anaerobic oxalate-degrading bacterium Oxalobacter formigenes.

The generation of transmembrane ion gradients by Oxalobacter formigenes cells metabolizing oxalate was studied. The magnitudes of both the transmembrane electrical potential (delta psi) and the pH gradient (internal alkaline) decreased with increasing external pH; quantitatively, the delta psi was the most important component of the proton motive force. As the extracellular pH of metabolizing cells was increased, intracellular pH increased and remained alkaline relative to the external pH, indicating that O. formigenes possesses a limited capacity to regulate internal pH. The generation of a delta psi by concentrated suspensions of O. formigenes cells was inhibited by the K+ ionophore valinomycin and the protonophore carbonyl cyanide-m-chlorophenylhydrazone, but not by the Na+ ionophore monensin. The H+ ATPase inhibitor N,N'-dicyclohexyl-carbodiimide inhibited oxalate catabolism but did not dissipate the delta psi. The results support the concept that energy from oxalate metabolism by O. formigenes is conserved not as a sodium ion gradient but rather, at least partially, as a transmembrane hydrogen ion gradient produced during the electrogenic exchange of substrate (oxalate) and product (formate) and from internal proton consumption during oxalate decarboxylation.     

The use of fluorescamine as a permeant probe to localize phosphatidylethanolamine in intact friend erythroleukaemic cells

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 delta pH 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.     

Potassium extrusion by the moderately halophilic and alkaliphilic methanogen methanolobus taylorii GS-16 and homeostasis of cytosolic pH.

Methanolobus taylorii GS-16, a moderately halophilic and alkaliphilic methanogen, grows over a wide pH range, from 6.8 to 9.0. Cells suspended in medium with a pH above 8.2 reversed their transmembrane pH gradient (delta pH), making their cytosol more acidic than the medium. The decreased energy in the proton motive force due to the reversed delta pH was partly compensated by an increased electric membrane potential (delta psi). The cytosolic acidification by M. taylorii at alkaline pH values was accompanied by K+ extrusion. The cytosolic K+ concentration was 110 mM in cells suspended at pH 8.7, but it was 320 mM in cells suspended at neutral pH values. High external K+ concentrations (210 mM or higher) inhibited the growth of M. taylorii at alkaline pH values, perhaps by preventing K+ extrusion. Cells suspended at pH 8.5 and 300 mM external K+ failed to acidify their cytosol. The key observation indicative of the involvement of K+ transport in cytosolic acidification was that valinomycin (0.8 microM), a K+ uniporter, inhibited the growth of M. taylorii only at alkaline pH values. Experiments with resting cells indicated that at alkaline pH values valinomycin uncoupled catabolic reactions from ATP synthesis. Thus, K+/H+ antiport activity was proposed to account for the K+ extrusion and the uncoupling effect of valinomycin at alkaline pH values. Such antiport activity was demonstrated by the sharp drop in pH of the bulk medium of the cell suspension upon the addition of 0.1 M KCl. The antiporter appeared to be active only at alkaline pH values, which was in accordance with a possible role in pH homeostasis by M. taylorii growing at alkaline pH values.     

Active potassium extrusion regulated by intracellular pH in Streptococcus faecalis

Potassium extrusion in bacteria is thought to play a role in the regulation of the cytoplasmic pH; in several organisms, it has been ascribed to secondary antiport of K+ for protons. Streptococcus faecalis exhibited a distinctive pattern: potassium extrusion occurred only when the cytoplasmic pH was alkaline and required the generation of ATP. The key observation is that glycolyzing cells suspended in an alkaline medium extruded K+, even against a K+ concentration gradient, provided the medium contained a weak permeant base (e.g. diethanolamine or methylamine). The amines render the cytoplasmic pH alkaline; when conditions were arranged to keep the cytoplasm neutral, no K+ extrusion was seen. Potassium extrusion required the presence of either glucose or arginine and was unaffected by protonophores and by inhibition of the F1Fo-ATPase. When the medium contained [14C]methylamine, the cells accumulated the base to an extent stoichiometrically equivalent to the K+ lost. Concurrently, the cytoplasmic pH fell from 8.8 to 7.6, at which point K+ extrusion ceased. The results suggest that K+ extrusion is due to an ATP-driven transport system that expels K+ by exchange for H+ and is active only at alkaline cytoplasmic pH.     

Responses to reversed NH3 and NH4+ gradients in a teleost (Ictalurus punctatus), an elasmobranch (Raja erinacea), and a crustacean (Callinectes sapidus):evidence for NH4+/H+ exchange in the teleost and the elasmobranch

Ammonia excretion rates of channel catfish, Ictalurus punctatus, little skate (Raja erinacea), and blue crab (Callinectes sapidus) were measured in experimental regimes which permitted simultaneous assessment of the partial pressure gradients for nonionized NH3 and the chemical concentration gradients of NH4+. Under conditions of low external ammonia, the average ammonia excretion was +295 microM kg-1 h-1 for catfish, +149 microM kg-1 h-1 for blue crabs, and +59 microM kg-1 h1 for skates with partial pressure gradients of +72.5 mu Torr, +413 mu Torr, and +24.4 mu Torr, respectively; and [NH4+] gradients of +189 microM l-1, +643 microM l-1, and +107 microM l-1 (positive indicating greater from inside to medium). When the external ammonia was increased to 1.15 mM l-1, both gradients were reversed, and the net ammonia movement was initially from the external water into all three species. In the catfish the inward movement ceased, however, and ammonia excretion eventually resumed in the face of reversed gradients of both NH3 partial pressure and [NH4+]. Unidirectional Na+ influx, indicative of a Na+/NH4+ exchange, did not increase. The ammonia data, changes in titratable acidity, and net apparent H+ efflux were all consistent with a linked extrusion of internal NH4+ for external H+. Incorporation of such an exchange into a computer simulation model of the ammonia equilibrium and exchange system duplicated the experimental data. Other hypotheses failed to match experimental data, or failed to predict internal ammonia levels lower than outside. In the crab, internal ammonia levels rose rapidly to concentrations and partial pressures above the external medium until excretion was reestablished, with no evidence of maintenance of a reversed gradient. In the skate, internal concentrations rose appreciably in the first hour and continued to rise for 6-8 h, with no resumption of ammonia excretion. The interspecies differences appear to be due at least partly to differences in ammonia permeability of the gills.     

Roles of K+ and Na+ in pH homeostasis and growth of the marine bacterium Vibrio alginolyticus.

The marine bacterium Vibrio alginolyticus, containing 470 mM-K+ and 70 mM-Na+ inside its cells, was able to regulate the cytoplasmic pH (pH(in)) in the narrow range 7.6-7.8 over the external pH (pH(out)) range 6.0-9.0 in the presence of 400 mM-Na+ and 10 mM-K+. In the absence of external K+, however, pHin was regulated only at alkaline pH(out) values above 7.6. When the cells were incubated in the presence of unusually high K+ (400 mM) and 4 mM Na+, the pH(in) was regulated only at acidic pH(out) values below 7.6. These results could be explained by postulating a K+/H+ antiporter as the regulator of pH(in) over the pH(out) range 6.0-9.0. When Na(+)-loaded/K(+)-depleted cells were incubated in 400 mM-Na+ in the absence of K+, an inside acidic delta pH was generated at pH(out) values above 7.0. After addition of diethanolamine the inside acidic delta pH collapsed transiently and then returned to the original value concomitant with the extrusion of Na+, suggesting the participation of a Na+/H+ antiporter for the generation of an inside acidic delta pH. In the presence of 400 mM-K+, at least 5 mM-Na+ was required to support cell growth at pH(out) below 7.5. An increase in Na+ concentration allowed the cells to grow at a more alkaline pH(out). Furthermore, cells containing more Na+ inside could more easily adapt to grow at alkaline pH(out). These results indicated the importance of Na+ in acidification of the cell interior via a Na+/H+ antiporter in order to support cell growth at alkaline pH(out) under conditions where the activity of a K+/H+ antiporter is marginal.     

Microbial volatile organic compound emissions from Stachybotrys chartarumgrowing on gypsum wallboard and ceiling tile

In neutralophilic bacteria, monovalent metal cation/H+ antiporters play a key role in pH homeostasis. In Escherichia coli, only four antiporters (NhaA, NhaB, MdfA and ChaA) are identified to function in maintenance of a stable cytoplasmic pH under conditions of alkaline stress. We hypothesised that the multidrug resistance protein MdtM, a recently characterised homologue of MdfA and a member of the major facilitator superfamily, also functions in alkaline pH homeostasis. Assays that compared the growth of an E. coli ΔmdtM deletion mutant transformed with a plasmid encoding wild-type MdtM or the dysfunctional MdtM D22A mutant at different external alkaline pH values (ranging from pH 8.5 to 10) revealed a potential contribution by MdtM to alkaline pH tolerance, but only when millimolar concentrations of sodium or potassium was present in the growth medium. Fluorescence-based activity assays using inverted vesicles generated from transformants of antiporter-deficient (ΔnhaA, ΔnhaB, ΔchaA) E. coli TO114 cells defined MdtM as a low-affinity antiporter that catalysed electrogenic exchange of Na+, K+, Rb+ or Li+ for H+. The K+/H+ antiport reaction had a pH optimum at 9.0, whereas the Na+/H+ exchange activity was optimum at pH 9.25. Measurement of internal cellular pH confirmed MdtM as contributing to maintenance of a stable cytoplasmic pH, acid relative to the external pH, under conditions of alkaline stress. Taken together, the results support a role for MdtM in alkaline pH tolerance. MdtM can therefore be added to the currently limited list of antiporters known to function in pH homeostasis in the model organism E. coli.     

The Na+-dependent regulation of the internal pH in chick skeletal muscle cells. The role of the Na+/H+ exchange system and its dependence on internal pH.

The internal pH (pHi) of chick muscle cells is determined by the transmembrane Na+ gradient. Li+, but not K+, Rb+ or Cs+, can substitute for Na+ for regulating the internal pH of chick muscle cells. Pharmacological evidence using amiloride and amiloride analogs has shown that the Na+/H+ exchange system is the membrane mechanism that couples the pHi to the transmembrane Na+ gradient. The pHi dependence of the amiloride-sensitive Na+/H+ exchange mechanism was defined. Internal H+ interacts cooperatively with the Na+/H+ exchange system, in contrast with external H+, thus indicating an asymmetrical behaviour of this exchanger. The half-maximum effect for the activation by the internal H+ of the Na+ transporting activity of the amiloride-sensitive Na+/H+ exchange was observed at pH 7.4. The Hill coefficient of the H+ concentration dependence is higher than 3. Insulin was shown to have no effect on the pHi of chick muscle cells.     

Changes in intracellular acidic compartments in sea urchin eggs after activation

Acridine orange (AO) was used as a vital probe for looking at acidic intracellular compartments in sea urchin eggs. This weak base is concentrated by acidic compartments, shifting its fluorescence from green to red due to the formation of dye aggregates. Fertilization or parthenogenetic activation with ionophore A23187 resulted in the appearance of orange fluorescent granules of sizes ranging from 1 to 2 microns at the cortical region of the egg. In one species of sea urchin (Lytechinus pictus), these granules migrate inward before cell division and associate with the forming mitotic apparatus. Treatments that discharge the transmembrane pH gradient (NH4Cl, nigericin, monensin, and acidic external pH) eliminate the orange fluorescence, indicating they are acidic compartments. Spectrofluorimetric measurements showed a decrease in monomer fluorescence accompanying egg activation which is reversible by similar treatments as seen with the fluorescence microscopic observations. Stratified eggs which were subsequently fertilized had acidic granules concentrated at the centripetal pole. This allowed the electron microscopic identification of the granules and showed they are present in the unfertilized egg, although not able to concentrate the AO. Activation of eggs in the absence of Na+ prevented the cytoplasmic alkalinization and also inhibited the appearance of acidic granules. The results indicate that the internal pH rises after egg activation triggers the acidification of these granules. Their possible functions, as in intracellular pH regulation, are discussed.     

NH3 is involved in the NH4+ transport induced by the functional expression of the human Rh C glycoprotein

Renal ammonium (NH3 + NH4+) transport is a key process for body acid-base balance. It is well known that several ionic transport systems allow NH4+ transmembrane translocation without high specificity NH4+, but it is still debated whether NH3, and more generally, gas, may be transported by transmembrane proteins. The human Rh glycoproteins have been proposed to mediate ammonium transport. Transport of NH4+ and/or NH3 by the epithelial Rh C glycoprotein (RhCG) may be of physiological importance in renal ammonium excretion because RhCG is mainly expressed in the distal nephron. However, RhCG function is not yet established. In the present study, we search for ammonium transport by RhCG. RhCG function was investigated by electrophysiological approaches in RhCG-expressing Xenopus laevis oocytes. In the submillimolar concentration range, NH4Cl exposure induced inward currents (IAM) in voltage-clamped RhCG-expressing cells, but not in control cells. At physiological extracellular pH (pHo) = 7.5, the amplitude of IAM increased with NH4Cl concentration and membrane hyperpolarization. The amplitude of IAM was independent of external Na+ or K+ concentrations but was enhanced by alkaline pHo and decreased by acid pHo. The apparent affinity of RhCG for NH4+ was affected by NH3 concentration and by changing pHo, whereas the apparent affinity for NH3 was unchanged by pHo, consistent with direct NH3 involvement in RhCG function. The enhancement of methylammonium-induced current by NH3 further supported this conclusion. Exposure to 500 microm NH4Cl induced a biphasic intracellular pH change in RhCG-expressing oocytes, consistent with both NH3 and NH4+ enhanced influx. Our results support the hypothesis of a specific role for RhCG in NH3 and NH4+ transport.     

Cation exchanges of yeast in the absence of magnesium.

Environmental Mg2+ was found to influence the K+/Na+ exchange rate of metabolizing yeast. Addition of EDTA increased the exchange rate and Mg2+ reversed the effect of EDTA. Yeast starved in the absence of Mg2+ exchanged cellular K+ or Na+ for external H+ when maintained at acidic pH. The exchange rate depended on cellular pH and showed the same kinetics for both K+ and Na+. At acidic pH, the presence of external cations neither inhibited H+ absorption nor changed the cation/H+ 1 : 1 stoichiometry. At neutral pH, external cations inhibited H+ influx but did not change the cation efflux. The K+/Na+ exchange is discussed as electrically coupled and the K+/H+ and Na+/H+ exchanges as electroneutral antiports.     

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.     

Estimation of cytoplasmic nitrate and its electrochemical potential in barley roots using 13NO3 and compartmental analysis

13NO3 was used to determine the intracellular compartmentation of NO3 in barley roots (Hordeum vulgare cv. Klondike), followed by a thermodynamic analysis of nitrate transport.Plants were grown in one-tenth Johnson's medium with 1 mol m3 NO3 (NO3-grown plants) or 1 mol m3 NH4NO3 (NH4NO3-grown plants).The cytoplasmic concentrations of NO3 in roots were only approx. 3-6 mol m3 (half-time for exchange approx. 21 s) in both NO3 and NH4NO3 plants. These pool sizes are consistent with published nitrate microelectrode data, but not with previous compartmental analyses.The electrochemical potential gradient for nitrate across the plasmalemma was +26 +/-1 kJ mol1 in both NO3- and NH4NO3-grown plants, indicating active uptake of nitrate. At an external pH of 6, the plasmalemma electrochemical potential for protons would be approx. -29 +/- 4 kJ mol1. If the cytoplasmic pH was 7.3 +/- 0.2, then 2H+/1NO3 cotransport, or a primary ATP-driven pump (2NO3/1ATP), are both thermodynamically possible. NO3 is also actively transported across the tonoplast (approx. +6 to 7 kJ mol1).     

Alkaline environmental pH has no effect on ammonia excretion in the mudskipper Periophthalmodon schlosseri but inhibits ammonia excretion in the related species Boleophthalmus boddaerti

Experiments were performed to evaluate the effects of alkaline environmental pH on urea and ammonia excretion rates and on tissue urea, ammonia, and free amino acid concentrations in two mudskippers, Periophthalmodon schlosseri and Boleophthalmus boddaerti. Periophthalomodon schlosseri is known to be capable of actively excreting ammonia. The rate of ammonia excretion in B. boddaerti exposed to 50% seawater (brackish water, BW) at pH 9 decreased significantly during the first 2 d of exposure when compared with that of specimens exposed to pH 7 or 8. This suggested that B. boddaerti was dependent on NH(3) diffusion for ammonia excretion, as in most fishes. It was incapable of detoxifying the accumulating endogenous ammonia to urea but could store and tolerate high concentrations of ammonia in the muscle, liver, and plasma. It did not undergo reductions in proteolysis and/or amino acid catabolism in alkaline water, probably because the buildup of endogenous ammonia was essential for the recovery of the normal rate of ammonia excretion by the third day of exposure to a pH 9 medium. Unlike B. boddaerti, P. schlosseri did not accumulate ammonia in the body at an alkaline pH (i.e., pH 9) because it was capable of actively excreting ammonia. Periophthalmodon schlosseri did not undergo partial amino acid catabolism (no accumulation of alanine) either, although there might be a slight reduction in amino acid catabolism in general. The significant decrease in blood pCO(2) in B. boddaerti at pH 9 might lead to respiratory alkalosis in the blood. In contrast, P. schlosseri was able to maintain its blood pH in BW at pH 9 despite a decrease in pCO(2) in the blood. With 8 mM NH(4)Cl in BW at pH 7, both mudskippers could actively excrete ammonia, although not to the same extent. Only P. schlosseri could sustain ammonia excretion against 8 mM NH(4)Cl in BW at pH 8. In BW containing 8 mM NH(4)Cl at pH 9, both mudskippers died within a short period of time. Boleophthalmus boddaerti consistently died faster than did P. schlosseri. This indicates that the body surfaces of these mudskippers were permeable to NH(3), but the skin of P. schlosseri might be less permeable to NH(3) than that of B. boddaerti. Both mudskippers excreted acid (H(+)) to alter the pH of the alkaline external medium. Such a capability, together with modifications in gill morphology and morphometry as in P. schlosseri, might be essential to the development of an effective mechanism for the active excretion of NH+4.