Ionic Relations of Garden Orache, A triplex hortensis L.: Growth and Ion Distribution at Moderate Salinity and the Function of Bladder Hairs

The growth of garden orache, A triplex hortensis was studiedunder conditions of mild NaCl or Na₂SO₄ salinity. Growth, drymatter production and leaf size were substantially stimulatedat 10 mM and 50 mM Na⁺ salts. Increased growth, however, appearedto be due to a K⁺-sparing effect of Na⁺ rather than to salinityper se. The distribution of K⁺ and Na⁺ in the plant revealeda remarkable preference for K+ in the roots and the hypocotyl.In the shoot the K/Na ratio decreased strongly with leaf age.However, the inverse changes in K⁺ and Na⁺ content with leafage were dependent on the presence of bladder hairs, which removedalmost all of the Na⁺ from the young leaf lamina. Measurementsof net fluxes of K⁺ and Na⁺ into roots and shoots of growingAtriplex plants showed a higher K/Na selectivity of the netion flux to the root compared to the shoot. With increasingsalinity the selectivity ratio S_{K, Na}^* of net ion fluxes tothe roots and to the shoots was increased. The data suggestthat recirculation of K⁺ from leaves to roots is an importantlink in establishing the K/Na selectivity in A. hortensis plants.The importance of K⁺ recirculation and phloem transport forsalt tolerance is discussed. Key words: Atriplex hortensis, Salinity, Potassium, Sodium, K⁺ retranslocation, Bladder hairs, Growth stimulation     

Membrane-Bound ATPases in Arthropod Ion-Transporting Tissues

Since Na^$$K^$-activated ATPase was first described, using arthropodtissues, it has become well-recognized as the enzymatic equivalentof the sodium pump. Occurring in the basolateral plasma membranesof epithelial ion-transporting cells, it is responsible forthe transport of Na^$ out of cells in exchange for the cytosol-directedmovement of a counterion (K^$ or NH₄^$). Its kinetic and dynamicproperties suggest that it serves as a major limiting factorin whole-body Na^$ regulation by aquatic arthropods. Its contributionto NH₄^$ excretion awaits isolation of Na^$ $ K^$-ATPase-enrichedmembrane fractions and determination of their transport properties.The role of Na^$$K^$-ATPase in insect epitheha is made uncertainby the apparent inaccessibility of the ATPase to the inhibitorouabain. Two other membrane-bound ATPases, K^$-stimulated ATPaseand anion-dependent ATPase, have been described in arthropodtissues, but their physiological roles are not clear.     

Characterization of inorganic phosphate transport in osteoclast-like cells

Osteoclasts possess inorganic phosphate (P_i) transport systems to take up external P_i during bone resorption. In the present study, we characterized P_i transport in mouse osteoclast-like cells that were obtained by differentiation of macrophage RAW264.7 cells with receptor activator of NF-B ligand (RANKL). In undifferentiated RAW264.7 cells, P_i transport into the cells was Na⁺ dependent, but after treatment with RANKL, Na⁺-independent P_i transport was significantly increased. In addition, compared with neutral pH, the activity of the Na⁺-independent P_i transport system in the osteoclast-like cells was markedly enhanced at pH 5.5. The Na⁺-independent system consisted of two components with K_m of 0.35 mM and 7.5 mM. The inhibitors of P_i transport, phosphonoformic acid, and arsenate substantially decreased P_i transport. The proton ionophores nigericin and carbonyl cyanide p-trifluoromethoxyphenylhydrazone as well as a K⁺ ionophore, valinomycin, significantly suppressed P_i transport activity. Analysis of BCECF fluorescence indicated that P_i transport in osteoclast-like cells is coupled to a proton transport system. In addition, elevation of extracellular K⁺ ion stimulated P_i transport, suggesting that membrane voltage is involved in the regulation of P_i transport activity. Finally, bone particles significantly increased Na⁺-independent P_i transport activity in osteoclast-like cells. Thus, osteoclast-like cells have a P_i transport system with characteristics that are different from those of other Na⁺-dependent P_i transporters. We conclude that stimulation of P_i transport at acidic pH is necessary for bone resorption or for production of the large amounts of energy necessary for acidification of the extracellular environment. Na⁺-dependent phosphate cotransporter; RAW264.7; phosphate uptake     

Ion Regulation in Crayfish: Freshwater Adaptations and the Problem of Molting

SYNOPSIS. Crayfish have a long evolutionary history in temperatefresh water (FW). Ion regulation is challenged by low externalconcentrations of Na, Cl, and Ca (<1 mM). In intermolt theprimary concern is Na and Cl balance; around ecdysis the emphasisswitches to Ca regulation as the cuticle is decalcified/calcified.Compared with marine crustaceans, intermolt crayfish maintaina reduced extracellular (EC) osmolality and have lower permeabilityto both ions and water. Hyperregulation involves active branchialuptake of Na and Cl and the unique ability to produce a hypotonicurine. Ion uptake involves apical electroneutral ion exchange(Na^$ for H^$; Cl^– for HCO₃–; counterions providedfrom CO₂ via carbonic anhydrase) followed by active basolateraltransport of Na via the Na pump, with Cl following passively.Reabsorption of 95% of filtered electrolytes at the antennalgland (kidney) involves similar subcellular mechanisms in amorphologically differentiated region of the distal tubule.Intermolt crayfish exhibit negative Ca balance (passive effluxunopposed by uptake) tolerable in view of the large cuticularCaCO₃ reserve. In premolt, cuticular Ca is reabsorbed. A smallamount is stored as gastroliths, the remainder is lost via branchialexcretion and in the discarded exuviae. At ecdysis, FW uptakegenerates the physical force for shedding, leaving the crayfishwith dilute hemolymph and a Ca deficiency. Levels of EC Na andCl are restored by intensive postmolt branchial uptake. Mineralizationof the soft exoskeleton involves remobilization of stored Caand branchial uptake of Ca and HCO₃. Transepithelial Ca transportinvolves Ca^2$ ATPase and Ca^2$/Na^$ exchange. The importance ofexternal electrolytes and pH in postmolt ion regulation is explored,as are some allometric considerations.     

K+-Na+ Exchange and Selectivity in Barley Root Cells: Effect of Na+ on the Na+ Fluxes

Using the compartmental analysis the unidirectional Na⁺ fluxesin cortical cells of barley roots, the cytoplasmic and vacuolarNa⁺ contents Q_c and Q_v, and the trans-root Na⁺ transport R'have been studied as a function of the external Na⁺ concentration.Using the re-elution technique the effect of low K⁺ concentrationson the plasmalemma efflux _co of Na⁺ (K+-Na+ exchange) and onR' was investigated at different Na+ concentrations and correspondinglydifferent values of the cytoplasmic sodium content Qc. The relationof the K+-dependent Na+ efflux coK+-dep to Qc or to the cytoplasmicNa+ concentration obeyed Michaelis-Menten kinetics. This isconsistent with a linkage of co, K+-dep to K+ influx by a K⁺-Na⁺exchange system. The apparent Km corresponded to a cytoplasmicNa⁺ concentration of 28 mM at 0·2 mM K⁺ and about 0·2mM Na⁺ in the external solution. 0·2 mM K⁺ stimulatedthe plasma-lemma efflux of Na⁺ and inhibited Na⁺ transport selectivelyeven in the presence of 10 mM Na⁺ in the external medium showingthe high efficiency of the K⁺-Na⁺ exchange system. However,_co, K⁺-dep was inhibited at 10 mM Na¹ compared to lower Na¹concentrations suggesting some competition of Na¹ with K¹ atthe external site of the exchange system. The effect of theNa+ concentration on Na¹ influx _oc is discussed with respectto kinetic models of uuptake.     

Time-dependent stimulation by aldosterone of blocker-sensitive ENaCs in A6 epithelia

To study and define the early time-dependent response (6 h) ofblocker-sensitive epithelial Na⁺channels (ENaCs) to stimulation ofNa⁺ transport by aldosterone, weused a new modified method of blocker-induced noise analysis todetermine the changes of single-channel current (i_Na) channel open probability(P_o), andchannel density(N_T) undertransient conditions of transport as measured by macroscopic short-circuit currents(I_sc). In threegroups of experiments in which spontaneous baseline rates of transportaveraged 1.06, 5.40, and 15.14 µA/cm², stimulation of transportoccurred due to increase of blocker-sensitive channels.N_T variedlinearly over a 70-fold range of transport (0.5-35µA/cm²). Relatively small andslow time-dependent but aldosterone-independent decreases ofP_o occurredduring control (10-20% over 2 h) and aldosterone experimentalperiods (10-30% over 6 h). When theP_o of control andaldosterone-treated tissues was examined over the 70-fold extendedrange of Na⁺ transport,P_o was observedto vary inversely withI_sc, falling from~0.5 to ~0.15 at the highest rates ofNa⁺ transport or ~25% per3-fold increase of transport. Because decreases ofP_o from anysource cannot explain stimulation of transport by aldosterone, it isconcluded that the early time-dependent stimulation ofNa⁺ transport in A6 epithelia isdue exclusively to increase of apical membraneN_T.

     

Response of Wheat Seedlings to Low O2 Concentrations in Nutrient Solution: II. K +/Na+ SELECTIVITY OF ROOT TISSUES9

This paper reports the effects of low O₂ concentration (0–01,0–055, and 0.115mol m^–3) in nutrient solutions onK⁺/Na⁺ selectivity of growing and mature root tissues of 6-to 8-d-old, intact, wheat (Triticum aestivum cv. Gamenya) seedlings. Increases in anaerobic catabolism and decreases in O₂ uptake,K⁺ uptake and K⁺/Na⁺ selectivity were all more pronounced and/oroccurred at higher external O₂ concentrations in the apex (0–2mm) than in the expanding tissues (2–4 mm); these growingtissues were, in turn, more affected than the expanded tissuesof the roots (4–12 mm). Selectivity for K⁺ over Na⁺ in roots and shoots was particularlysensitive to O₂ deficiency. For example, in apical tissues (0–2mm) K ⁺ /Na⁺ selectivity was already reduced at 0.115 mol m^–3O₂, yet at this O₂ concentration there was no effect on eithergrowth or (K⁺/Na⁺) uptake. Upon transfer from 0.01 to 0.26 mol m^–3 O₂, a detailedstudy of the 12 mm root tips showed that 70% of these tips regainedhigh (K⁺ + Na⁺) concentrations and K⁺/^Na+ ratios. In contrast,there was no recovery in the remaining 30% of the 12 mm roottips. Net K⁺ transport to the shoots during the period afterre-aeration was negative for the population as a whole. Theseverity of these effects supports the view that the root tipsand the stele were more susceptible to O2 deficiency than wasthe cortex of the fully-developed root tissues. Key words: Hypoxia, K⁺/Na⁺ selectivity, expanded and expanding tissues     

Membrane cholesterol extraction decreases Na+ transport in A6 renal epithelia

In this study, we have investigated the dependence of Na⁺ transport regulation on membrane cholesterol content in A6 renal epithelia. We continuously monitored short-circuit current (I_sc), transepithelial conductance (G_T), and transepithelial capacitance (C_T) to evaluate the effects of cholesterol extraction from the apical and basolateral membranes in steady-state conditions and during activation with hyposmotic shock, oxytocin, and adenosine. Cholesterol extraction was achieved by perfusing the epithelia with methyl--cyclodextrin (mCD) for 1 h. In steady-state conditions, apical membrane cholesterol extraction did not significantly affect the electrophysiological parameters; in contrast, marked reductions were observed during basolateral mCD treatment. However, apical mCD application hampered the responses of I_sc and G_T to hypotonicity, oxytocin, and adenosine. Analysis of the blocker-induced fluctuation in I_sc demonstrated that apical mCD treatment decreased the epithelial Na⁺ channel (ENaC) open probability (P_o) in the steady state as well as after activation of Na⁺ transport by adenosine, whereas the density of conducting channels was not significantly changed as confirmed by C_T measurements. Na⁺ transport activation by hypotonicity was abolished during basolateral mCD treatment as a result of reduced Na⁺/K⁺ pump activity. On the basis of the findings in this study, we conclude that basolateral membrane cholesterol extraction reduces Na⁺/K⁺ pump activity, whereas the reduced cholesterol content of the apical membranes affects the activation of Na⁺ transport by reducing ENaC P_o. epithelial Na⁺ channel; Na⁺-K⁺-ATPase activity; short-circuit current; methyl--cyclodextrin; channel open probability     

(Na+-K+)-stimulated ATPase in Leaves of C4 Plants: Possible Involvement in Active Transport of C4 Acids

Leaves of three C₄ plants, Setaria italica, Pennisetum typhoides,and Amaranthus paniculatus possessed five- to ten-fold higheractivities of a (Na⁺-K⁺)-dependent ATPase than those of twoC₃ plants, Oryza sativa and Rumex vesicarius. Na⁺-K⁺ ATPasefrom leaves of Amarathus exhibited an optimal pH of 7?5 andan optimal temperature of 35 ?C. It required 40 mM K⁺ and 80mM Na⁺ for maximal activity. Ouabain partially inhibited (Na⁺-K⁺)-dependentATPase activity in leaves of C₄ plants. Ouabain also blockedthe movement of label from initially formed C₄ acids into endproducts in leaves of only C₄ plants, Setaria and Amaranthusbut not in a C₃ plant, Rumex. We propose that Na⁺-K⁺ ATPasemay mediate transfer of energy during active transport of C₄acids from mesophyll into the bundle sheath.     

External Potassium Supply is not Required for Root Growth in Saline Conditions: Experiments with Ricinus communis L. Grown in a Reciprocal Split-Root System

Ricinus communis L. (castor bean) plants were grown in the absence(control) and in the presence of 100molm^–3NaCl with areciprocal split-root system, in which K⁺ was supplied to oneand NO₃^– to the other part of the root system. In theseplants shoot and, to a lesser extent, total root growth wereinhibited compared to plants with non-split roots. Without andwith NaCl, growth of roots receiving NO₃^– but noK⁺ (‘minusK/plus N-roots’) was substantially more vigorous thanunder the reverse conditions (‘plus K/minus N-roots¹).100mol m^–3 NaCl inhibited growth of minus K/plus N-roots¹to the same extent as that of non-split roots, indicating thatexternally supplied K⁺ was not required for root growth undersaline conditions. In growth media without added K⁺ the rootdepleted the external low K ⁺ levels resulting from chemicalsdown to a minimum value C_mln (1.0 to 1.4 mmol m^–3); inthe presence of 100 mol m^–3 NaCl, C_min, was higher (10–18mmol m^–3) and resulted from an initial net loss of K ⁺.C_min, was pH-dependent The distribution of K⁺, Na⁺ and Mg²⁺along the root was measured. In meristematic root tissues, K⁺ concentrations were scarcely affected by external K⁺ or byNaCl, where Na ⁺ concentrations were low, but somewhat elevatedat low external K+ and/or high NaCl. In differentiated, vacuolatedtissues K ⁺ concentrations were low and Na⁺ concentrations high,if K ⁺ was not supplied externally and/or NaCl was present.The longitudinal distribution of ions within the root was usedto estimate cytoplasmic and vacuolar ion concentrations. Thesedata showed a narrow homoeostasis of cytoplasmic K+ concentrations(100–140 mol m^–3) independent of external K ⁺ supplyeven in the presence of 100 mol m ^–3 NaCl. CytoplasmicNa ⁺ concentrations were maintained at remarkably low levels.Hence, external K⁺ concentrations above C_min, were not requiredfor maintaining K/Na selectivity, i.e. for controlling Na⁺ entry.The results are discussed with regard to mechanisms of K/Naselectivity and to the importance of phloem import of K⁺ forsalt tolerance of roots and for cytoplasmic K⁺ homoeostasis. Key words: Ricinus communis, nitrate, potassium, root (split-root), salt tolerance, phloem transport     

Effects of Ammonia and Methylamine on Cl- Transport and on the pH Changes and Circulating Electric Currents Associated with HCO3- Assimilation in Chara corallina

Low concentrations of ammonia and methylamine greatly increaseCl^– influx into Chara corallina. Both amines have theirmaximum effect at pH 6.5–7.5. The amine stimulation ofCl^– influx is small below about pH 5.5. Above pH 8.5 theremay be inhibition of influx by amines. Concentrations of 10–25µM ammonia are sufficient to cause the maximum stimulationof Cl^– influx; the corresponding methylamine concentrationsare 0.1–0.2 mM. It is concluded that entry of amine cations(NH₄^$ and CH₃NH₃^$), rather than unionized bases (NH₃ and CH₃NH₂),causes Cl^– transport to be increased. Increases in rates of Cl^– transport are not necessarilyaccompanied by effects on HCO₃^$ assimilation and OH^– efflux.Measurements of localized pH differences at the cell surfaceand of circulating electric currents in the bathing solutionshow that these phenomena are only significantly affected byammonia at or above 50 µM and by methylamine at or above1.0 mM. The significance of the effects of amines is assessedin relation to current ideas about transport of Cl^–, HCO₃^–,and OH^–.     

The Role of the Stem in the Partitioning of Na+ and K+ in Salt-Treated Barley

Hordeum vulgare cv. California Mariout was grown for 50 d insand culture at 100 mol m^–3 NaCl. Xylem sap was collectedthrough incisions at the base of individual leaves along thestem axis by applying pressure to the root system. K⁺ concentrationsin the xylem sap reaching individual leaves increased towardsthe apex, while concentrations of Na⁺, NO₃^–, and Cl^–declined. Phloem exudate was obtained by collecting into Li₂EDTAfrom the base of excised leaves. K/Na ratios of phloem exudatesincreased from older to younger leaves. K/Na ratios in xylem sap and phloem exudate were combined withchanges in ion content between two harvests (38 and 45 d aftergermination) and the direction of phloem export from individualleaves, to construct an empirical model of K⁺ and Na⁺ net flowswithin the xylem and phloem of the whole plant. This model indicatesthat in old leaves, phloem export of K⁺ greatly exceeded xylemimport. In contrast, Na⁺ export was small compared to importand Na⁺ once imported was retained within the leaf. The direction of export strongly depended on leaf age. Old,basal leaves preferentially supplied the root, and most of theK⁺ retranslocated to the roots was transferred to the xylemand subsequently became available to the shoot. Upper leavesexported to the apex. Young organs were supplied by xylem andphloem, with the xylem preferentially delivering Na⁺ , and thephloem most of the K⁺ . For the young ear, which was still coveredby the sheath of the flag leaf, our calculation predicts phloemimport of ions to such an extent that the surplus must havebeen removed by an outward flow in the xylem. Within the culm,indications for specific transfers of K⁺ and Na⁺ between xylemand phloem and release or absorption of these ions by the tissuewere obtained. The sum of these processes in stem internodes and leaves ledto a non-uniform distribution of Na⁺ and K⁺ within the shoot,Na⁺ being retained in old leaves and basal stem internodes,and K⁺ being available for growth and expansion of young tissues. Key words: Hordeum vulgare L., K⁺, Na⁺, stem, salt stress     

Glucose 6-phosphate dehydrogenase from sweet potato: Effect of various ions and their ionic strength on enzyme activity

Activity of glucose 6-phosphate dehydrogenase (D-glucose 6-phosphate:NADP oxidoreductase, EC 1.1.1.49 [EC] ) preparation from sweet potatoroot tissue was markedly altered in the presence of variousions. Cations or anions were effective in the following order:Na^$, K^$>Tris^$>NH₄^$>Mg^2$>Ca^2$, or Cl^–>NO₃^–,HPO₄^2–>SO₄^2–>HCO₃^–. Activity was inhibitedat high concentrations of Ca^2$, and HCO₃^–,. In an investigationon the dependence of the activity on pH, two activity peakswere clearly observed at low ionic strength. Ionic strength altered both the Km and Vmax for glucose 6-phosphate(G6P). A Lineweaver-Burk plot for the enzyme, with respect toG6P, showed a bimodal nature at low ionic strength; suggestingnegative cooperativity. Deviation from linearity of the plotwas less with an increase in the ionic strength. ¹ Present address: Institute of Applied Microbiology, Universityof Tokyo, Bunkyo-ku, Tokyo 113. (Received September 18, 1971; )     

SGK1 activates Na+-K+-ATPase in amphibian renal epithelial cells

Serum- and glucocorticoid-induced kinase 1 (SGK1) is thought to be an important regulator of Na⁺ reabsorption in the kidney. It has been proposed that SGK1 mediates the effects of aldosterone on transepithelial Na⁺ transport. Previous studies have shown that SGK1 increases Na⁺ transport and epithelial Na⁺ channel (ENaC) activity in the apical membrane of renal epithelial cells. SGK1 has also been implicated in the modulation of Na⁺-K⁺-ATPase activity, the transporter responsible for basolateral Na⁺ efflux, although this observation has not been confirmed in renal epithelial cells. We examined Na⁺-K⁺-ATPase function in an A6 renal epithelial cell line that expresses SGK1 under the control of a tetracycline-inducible promoter. The results showed that expression of a constitutively active mutant of SGK1 (SGK1^T_S425D) increased the transport activity of Na⁺-K⁺-ATPase 2.5-fold. The increase in activity was a direct consequence of activation of the pump itself. The onset of Na⁺-K⁺-ATPase activation was observed between 6 and 24 h after induction of SGK1 expression, a delay that is significantly longer than that required for activation of ENaC in the same cell line (1 h). SGK1 and aldosterone stimulated the Na⁺ pump synergistically, indicating that the pathways mediated by these molecules operate independently. This observation was confirmed by demonstrating that aldosterone, but not SGK1^T_S425D, induced an 2.5-fold increase in total protein and plasma membrane Na⁺-K⁺-ATPase ₁-subunit abundance. We conclude that aldosterone increases the abundance of Na⁺-K⁺-ATPase, whereas SGK1 may activate existing pumps in the membrane in response to chronic or slowly acting stimuli. sodium transport; serum- and glucocorticoid-induced kinase; A6 cells; sodium pump     

Insulin increases the turnover rate of Na+-K+-ATPase in human fibroblasts

Insulin stimulates K⁺ transport by theNa⁺-K⁺-ATPase in human fibroblasts. In othercell systems, this action represents an automatic response to increasedintracellular [Na⁺] or results from translocation oftransporters from an intracellular site to the plasma membrane. Here weevaluate whether these mechanisms are operative in human fibroblasts.Human fibroblasts expressed the ₁ but not the₂ and ₃ isoforms ofNa⁺-K⁺-ATPase. Insulin increased the influx ofRb⁺, used to trace K⁺ entry, but did not modifythe total intracellular content of K⁺, Rb⁺, andNa⁺ over a 3-h incubation period. Ouabain increasedintracellular Na⁺ more rapidly in cells incubated withinsulin, but this increase followed insulin stimulation ofRb⁺ transport. Bumetanide did not prevent the increasedNa⁺ influx or stimulation ofNa⁺-K⁺-ATPase. Stimulation of theNa⁺-K⁺- ATPase by insulin did not produce anymeasurable change in membrane potential. Insulin did not affect theaffinity of the pump toward internal Na⁺ or the number ofmembrane-bound Na⁺-K⁺-ATPases, as assessed byouabain binding. By contrast, insulin slightly increased the affinityof Na⁺-K⁺-ATPase toward ouabain. Phorbol estersdid not mimic insulin action on Na⁺-K⁺-ATPaseand inhibited, rather than stimulated, Rb⁺ transport. Theseresults indicate that insulin increases the turnover rate ofNa⁺-K⁺-ATPases of human fibroblasts withoutaffecting their number on the plasma membrane or modifying theirdependence on intracellular [Na⁺].

     

The Role of Carbonic Anhydrase in Blood Ion and Acid-Base Regulation

The role of carbonic anhydrase (CA) in ion transport processesof aquatic and terrestrial arthropod species is reviewed. Inboth insects and crustaceans CA is found in a variety of iontransporting tissues. The bulk of CA activity in crustaceansis concentrated in the posterior gills, which are morphologicallyand biochemically adapted for ion transport. The enzyme canbe specifically localized to gill lamellae which contain largepopulations of salt transporting chloride cells. Enzyme activityin the posterior gills of species having the ability to regulateblood ion concentrations increases when these organisms areacclimated to environmental salinities in which they ion regulate.In stenohaline, ion conforming species branchial CA activityis uniformly low, being only 5–10% that in regulatingspecies. Studies on the blue crab, Callinectes sapidus, usingthe specific CA inhibitor acetazolamide have shown that theenzyme is indeed important in blood ion regulation. Blood Na^$and Cl^– concentrations are both severely lowered in drug-treatedanimals acclimated to low salinity, while they remain virtuallyunaffected in animals acclimated to high salinity, in whichthe animal is an ion conformer. High salinity acclimated crabstreated with acetazolamide do not survive transfer to low salinity,and mortality is related to a breakdown in the ion regulatorymechanism. Branchial CA most likely functions in the hydrationof respiratory CO₂ to H^$ and HCO₃^–, which serve as counterionsfor the active uptake of Na^$ and Cl^–, respectively. Interrestrial species the role of CA is unclear and merits furtherinvestigation.     

Na+, K+ and Cl- in Xylem Sap Flowing to Shoots of NaCl-Treated Barley

Munns, R. 1985. Na⁺, K⁺ and Cl^– in xylem sap flowing toshoots of NaCl-treated barley.—J. exp. Bot. 36: 1032–1042. Na⁺, Cl^– and K⁺ concentrations were measured in xylemsap obtained by applying pressure to the roots of decapitatedbarley plants grown at external [NaCl] of 0, 25, 50, 100, 150and 200 mol m^–3. For any given NaCl treatment, ion concentrationsin the xylem sap were hyperbolically related to the flux ofwater. Ion concentrations in sap collected at very low volumefluxes (without applied pressure) were 5–10 times higherthan in sap collected at moderate fluxes (under pressure). Fora given moderate volume flux, Na+ concentration in the xylemsap, [Na⁺]_x, was only 4.0 mol m^–3 at external [NaCl] of25–150 mol m^–3, and increased to 7.0 mol m^–3at 200 mol m^–3. [Cl-]x showed a similar pattern. Thisshows there would be little difference in the rate of uptaketo the shoot of plants at 25–150 mol m^–3 externalNaCl and indicates little change even at 200 mol m^-3 NaCl becausetranspiration rates would be much lower. Thus the reduced growthof the shoot of plants at high NaCl concentrations is not dueto higher uptake rates of Na⁺ or Cl^–. The fluxes of Na⁺, Cl^– and K^– increased non-linearlywith increasing volume flux indicating little movement of saltin the apoplast. The flux of K⁺ increased even when [K⁺]_x wasgreater than external [K⁺], indicating that membrane transportprocesses modify the K⁺ concentration in the transpiration streamas it flows through the root system. Key words: -Xylem sap, Na⁺, K⁺, Cl^– fluxes, salinity, barley     

Hormonal regulation of ENaCs: insulin and aldosterone

Although a variety of hormones and other agents modulate renalNa⁺ transport acting by way of theepithelial Na⁺ channel (ENaC), themode(s), pathways, and their interrelationships in regulation of thechannel remain largely unknown. It is likely that several hormones maybe present concurrently in vivo, and it is, therefore, important tounderstand potential interactions among the various regulatory factorsas they interact with the Na⁺transport pathway to effect modulation ofNa⁺ reabsorption in distal tubulesand other native tissues. This study represents specifically adetermination of the interaction between two hormones, namely,aldosterone and insulin, which stimulate Na⁺ transport by entirelydifferent mechanisms. We have used a noninvasive pulse protocol ofblocker-induced noise analysis to determine changes in single-channelcurrent (i_Na),channel open probability (P_o), andfunctional channel density(N_T) ofamiloride-sensitive ENaCs at various time points following treatmentwith insulin for 3 h of unstimulated control and aldosterone-pretreatedA6 epithelia. Independent of threefold differences of baseline values of transport caused by aldosterone, 20 nM insulin increased by threefold and within 10-30 min the density of the pool of apical membrane ENaCs(N_T) involvedin transport. The very early (10 min) increases of channel density wereaccompanied by relatively small decreases ofi_Na(10-20%) and decreases ofP_o (28%) in the aldosterone-pretreated tissues but not the control unstimulated tissues. The early changes ofi_Na,P_o, andN_T weretransient, returning very slowly over 3 h toward their respectivecontrol values at the time of addition of insulin. We conclude thataldosterone and insulin act independently to stimulate apicalNa⁺ entry into the cells of A6epithelia by increase of channel density.

     

Cytosolic potassium controls CFTR deactivation in human sweat duct

Absorptive epithelial cells must admit large quantities of salt (NaCl) during the transport process. How these cells avoid swelling to protect functional integrity in the face of massive salt influx is a fundamental, unresolved problem. A special preparation of the human sweat duct provides critical insights into this crucial issue. We now show that negative feedback control of apical salt influx by regulating the cystic fibrosis transmembrane conductance regulator (CFTR) Cl^– channel activity is key to this protection. As part of this control process, we report a new physiological role of K⁺ in intracellular signaling and provide the first direct evidence of acute in vivo regulation of CFTR dephosphorylation activity. We show that cytosolic K⁺ concentration ([K⁺]_c) declines as a function of increasing cellular NaCl content at the onset of absorptive activity. Declining [K⁺]_c cause parallel deactivation of CFTR by dephosphorylation, thereby limiting apical influx of Cl^– (and its co-ion Na⁺) until [K⁺]_c is stabilized. We surmise that [K⁺]_c stabilizes when Na⁺ influx decreases to a level equal to its efflux through the basolateral Na⁺-K⁺ pump thereby preventing disruptive changes in cell volume. electrolytes; phosphatases; protein kinase A; cystic fibrosis transmembrane conductance regulator; epithelial Na⁺ channel     

Glucose activates H(+)-ATPase in kidney epithelial cells

The vacuolar H⁺-ATPase (V-ATPase) acidifies compartments of the vacuolar system of eukaryotic cells. In renal epithelial cells, it resides on the plasma membrane and is essential for bicarbonate transport and acid-base homeostasis. The factors that regulate the H⁺-ATPase remain largely unknown. The present study examines the effect of glucose on H⁺-ATPase activity in the pig kidney epithelial cell line LLC-PK₁. Cellular pH was measured by performing ratiometric fluorescence microscopy using the pH-sensitive indicator BCECF-AM. Intracellular acidification was induced with NH₃/NH₄⁺ prepulse, and rates of intracellular pH (pH_i) recovery (after in situ calibration) were determined by the slopes of linear regression lines during the first 3 min of recovery. The solutions contained 1 µM ethylisopropylamiloride and were K⁺ free to eliminate Na⁺/H⁺ exchange and H⁺-K⁺-ATPase activity. After NH₃/NH₄⁺-induced acidification, LLC-PK₁ cells had a significant pH_i recovery rate that was inhibited entirely by 100 nM of the V-ATPase inhibitor concanamycin A. Acute removal of glucose from medium markedly reduced V-ATPase-dependent pH_i recovery activity. Readdition of glucose induced concentration-dependent reactivation of V-ATPase pH_i recovery activity within 2 min. Glucose replacement produced no significant change in cell ATP or ADP content. H⁺-ATPase activity was completely inhibited by the glycolytic inhibitor 2-deoxy-D-glucose (20 mM) but only partially inhibited by the mitochondrial electron transport inhibitor antimycin A (20 µM). The phosphatidylinositol 3-kinase (PI3K) inhibitor wortmannin (500 nM) abolished glucose activation of V-ATPase, and activity was restored after wortmannin removal. Glucose activates V-ATPase activity in kidney epithelial cells through the glycolytic pathway by a signaling pathway that requires PI3K activity. These findings represent an entirely new physiological effect of glucose, linking it to cellular proton secretion and vacuolar acidification. proton secretion; glycolysis; intracellular pH; concanamycin A