Active transport of Calcium ions in the skin of the salamander Ambystoma tigrinum

We measured Ca²⁺ exchanges across the skin of larval and adult Ambystoma tigrinum using the radio-isotope influx method. We found that the skin of both morphs takes up Ca²⁺ in a manner that is proportional to external [Ca²⁺], saturable and oriented against the electrochemical gradient for Ca²⁺. We conclude that this uptake occurs by active transport. Kinetic analysis yields affinities for calcium ions that are similar to the affinities for both Ca²⁺ and Na⁺ in the skin of other amphibians. The capacity for calcium is similar to Ca²⁺ capacity in other amphibians. The capacity for Ca²⁺ is lower than the capacity for Na⁺. Cutaneous Ca²⁺ deposits are lower in this urodele than found in anurans. Adults tend to have higher levels of Ca in their skin than do larvae. Accepted: 25 June 1999     

Comparative Studies of Leaf Tissue and Isolated Mesophyll Protoplasts: II. ION RELATIONS

Freshly isolated tobacco mesophyll protoplasts had contentsof K^$, Cl^– and Na^$ slightly higher (on a cell basis) thanthe original leaf tissue, and had a high K^$/Na^$ ratio similarto that of the leaf tissue. Influxes of these ions into theprotoplasts were of similar magnitudes to the correspondingfluxes in leaf tissue when compared on the basis of the respectiveplasmalemma surface areas. In both systems the K^$ influx wasstrongly inhibited by CN^– and by DNP. These results suggestthat the ion relations of the freshly isolated mesophyll protoplastswere similar to those of the original leaf tissue and that isolatedmesophyll protoplasts should be a useful system for the studyof ion transport processes in leaf cells.     

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.     

Cutaneous ion exchange,and renal and extrarenal partitioning of acid and ammonia excretion in the larval tiger salamander,Ambystoma tigrinum,following ingestion of ammonium salts

Summary The skin/gills and the kidneys of aquatic amphibians are potential sites of acid-base regulation. The roles of these organs in acid-base balance were examined in larval Ambystoma tigrinum following gastric infusion of ammonium salts. A single dose of 1.75 mEq NH₄Cl·100 g^-1 produced a mixed acidosis by 1 h after gavage. By 8 h after ingestion, pH and HCO ₃ ^– had increased and PCO₂ had decreased as the animals recovered. A prolonged acidosis was developed in a second group by gavage of an initial dose (1.5 mEq·100 g^-1), followed by periodic maintenance doses (0.25 mEq·100 g^-1) to prolong the disturbance for 8 h. The magnitude of the acidosis during this period was similar to that seen at 1 h after ingestion in the time-course study. A third group of larvae were given NaCl as a control for salt loading, which induced a small but significant respiratory acidosis. Unidirectional fluxes of Na⁺ and Cl^- were examined during these serial ingestions. Salt loading inhibited the influx of the ingested ion. Na⁺ influx increased during the NH₄Cl-induced acidosis. A fourth group of larvae were used to partition acid and ammonia excretion between the skin and the kidneys. These animals were given (NH₄)₂SO₄ to allow re-examination of Cl^- flux rates under non-Cl^--loaded conditions. The ensuing acidosis had a reduced respiratory component and, therefore, pH did not decrease as much. Cl^- influx rates did decrease significantly under these conditions. In both control and acidotic conditions, the majority of the acid efflux was as ammonia and the skin was the primary site of acid excretion. However, both the skin and the kidneys increased total acid excretion, although the efflux across the skin showed a much greater increase. This suggests a primary role for the skin in acid-base regulation in aquatic amphibians.Abbreviations GFR glomerular filtration rate - PO₂ partial pressure of oxygen - PCO₂ partial pressure of carbon dioxide - SITS 4-acetamido-4-isothiocynanatostilbene-2,2-disulfonic acid - TA titratible acidity Present address: Department of Organismal Biology and Anatomy, University of Chicago, 1025 E. 57th St., Chicago, IL 60637, USA     

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^–.     

Interactions Between Transcutaneous Ion Transfer Processes and Carbon Dioxide Excretion in Amphibians

SYNOPSIS. The amphibian skin possesses a wide variety of physiologicalfunctions in that it constitutes not only the major organ forrespiratory CO₂ exchange but also plays important roles forionic as well as osmotic balance. Apart from the simple transcutaneousdiffusion of CO₂ down its partial pressure gradient, acid-baserelevant ion exchange mechanisms in the skin may also be importantin overall pH regulation in these animals. The skin of somefrogs, for example, contains mechanisms for the exchange ofNa^$/H^$ and HCO₃^–/Cl^– in which NaCl is actively transportedinto the animal in exchange for H^$ and HCO₃^–. While suchexchange mechanisms have often been studied in the context ofosmoregulation in freshwater environments, their potential importancein acid-base regulation have been largely unexplored. The presentpaper reviews the evidence for participation of cutaneous iontransfer mechanisms in the overall regulation of CO₂ excretionand acid-base balance in amphibians.     

Biophysical and Biochemical Regulation of Cytoplasmic pH in Chara corallina during Acid Loads

The contribution of membrane transport to regulation of cytoplasmicpH in Chara corallina has been measured during proton-loadingby uptake of butyric acid. In the short-term (i.e. up to 20min) uptake of butyric acid is not affected by removal of externalK⁺, Na⁺ or Cl^– but over longer periods uptake is decreased(by 20–50% in different experiments) in the absence ofexternal Na⁺ or, sometimes, K⁺. Influxes of both Na⁺ and K⁺increase temporarily after addition of butyrate, Na⁺ immediatelyand K⁺ after a lag. Effects on Cl^– influx are small butCl^– efflux increases enormously after a short lag. Anapproximate comparison of internal butyrate with changes inthe concentration of K⁺, Na⁺, and Cl^– suggests that initially(i.e. for a few min) cytoplasmic pH is determined by bufferingand possibly by some decarboxylation of organic acids (biochemicalpH regulation), and that biophysical pH regulation involvingefflux of H⁺ balanced by influxes of K⁺, Na⁺ and especiallyefflux of Cl^– progressively becomes dominant. When butyric acid is washed out of the cells, cytoplasmic pHis restored completely or partially (depending on the butyrateconcentration used) and this is independent of the presenceor absence of external Cl^–. Where Cl^– is present,its influx is relatively small. It is suggested that cytoplasmicpH is then controlled biochemically, involving the synthesisof an (unidentified) organic acid and the accumulation of acidicanions in place of butyurate lost from the cell. During thesecond application of butyrate, net Cl^– efflux is small:it is suggested that control of cytoplasmic pH then involvesdecarboxylation of the organic acid anions. The questions of the source of Cl^– lost from the cell(cytoplasm or vacuole) and of possible cytoplasmic swellingassociated with the accumulation of butyrate are discussed. Key words: Chara corallina, butyric acid, cytoplasmic pH, membrane transport     

Effect of Exogenous Glycinebetaine on Na+ Transport in Barley Roots

Ahmad, N., Wyn Jones, R. G. and Jeschke, W. D. 1987. Effectof exogenous glycinebetaine on Na⁺ transport in barley roots.—J.exp. Bot. 38: 913–921. A comparison has been made of the kinetics of 22Na⁺ uptake intoexcised barley roots and roots pre-loaded with glycinebetaine.The elevated intracellular glycinebetaine or a metabolic consequencethereof increased the Na⁺ influx, and the effect was relatedto the level of internal glycinebetaine and or Na⁺ [Cl^–].The quasi-steady-state Na⁺ influx at the tonoplast rather thanthe plasmalemma influx was apparently influenced by glycinebetaineloading. The tonoplast fluxes and vacuolar Na⁺ content wereconsistently higher in glycinebetaine-loaded roots than unloadedroots. A membrane-modifying role of glycinebetaine in relationto ion compartmentation is discussed. Key words: Excised roots, glycinebetaine, Na⁺, ion fluxes, barley     

Uptake of Imidazole and its Effects on the Intracellular pH and Ionic Relations of Chara corallina

Ammonia (pK_a 9.25) and methylamine (pK_a, 10.65) increase cytoplasmicpH and stimulate Cl^– influx in Chara corallina, theseeffects being associated with influx of the amine cations ona specific porter. The weak base imidazole (pK_a 6.96) has similareffects but diffuses passively into the cell both as an unionizedbase and as a cation. When the external pH is greater than 6.0influx of the unionized species predominates. Imidazole accumulates to high concentrations in the vacuole,where it is protonated. Cytoplasmic pH and vacuolar pH riseby only 0.2–0.3 units, suggesting a large balancing protoninflux across the plasma membrane. Balance of electric chargeis partially maintained by net efflux of K⁺ and net influx ofCl^–. Calculation of vacuolar concentrations of imidazole(from (¹⁴C] imidazole uptake, assuming that there is no metabolism)plus K⁺ and Na⁺ indicates an excess of cations over inorganicanions (Cl^–). However, although the osmotic potentialof the cells increases, also indicating increased solute concentrations,the increase is less than that predicted by the calculated ionicconcentrations. This discrepancy remains to be resolved. Becausethe osmotic potential also increases when imidazole is absorbedfrom Cl^–-free solutions it is likely that maintenanceof charge-balance can also involve synthesis and vacuolar storageof organic or amino acids. Key words: Imidazole, potassium, intracellular pH, membrane transport, Chara     

NaCl Uptake in Roots of Zea mays Seedlings: Comparison of Root Pressure Probe and EDX Data

The extent by which salinity affects plant growth depends partlyon the ability of the plant to exclude NaCl. To study the uptakeof NaCl into excised roots of Zea mays L. cv. ‘Tanker’,two different techniques were applied. A root pressure probewas used to record steady state as well as transient valuesof root (xylem) pressure upon exposure of the root to mediacontaining NaCl and KCl as osmotic solutes. In treatments withNaCl, pressure/time responses of the root indicated a significantuptake of NaCl into the xylem. NaCl induced kinetics were completelyreversible when the NaCl solution was replaced by an isosmoticKCl solution. This indicated a passive movement of Na⁺-saltsacross the root cylinder. Root samples were taken at differenttimes of exposure to NaCl and prepared for X-ray microanalysis(EDX analysis). Radial profiles of ion concentrations (Na⁺,K⁺, Cl^–) were measured in cell vacuoles and xylem vesselsalong the root axis. Na⁺ appeared rapidly in mature xylem (earlymetaxylem) and living xylem (late metaxylem) before it was detectablein vacuoles of the root cortex. EDX results confirmed that thekinetics observed by the pressure probe technique correspondedmainly to an influx of Na⁺-salts into early metaxylem. In latemetaxylem, the uptake of Na⁺ was associated with a decline ofK⁺. The Na⁺/K⁺ exchange indicated a mechanism to reduce sodiumfrom the transpiration stream. Ion localization, ion transport, maize, root pressure, salinity, water relations, X-ray microanalysis, Zea mays     

Na+ influx and Na+-K+ pump activation during short-term exposure of cardiac myocytes to aldosterone

To examine the effect of aldosterone on sarcolemmalNa⁺ transport, we measuredouabain-sensitive electrogenicNa⁺-K⁺pump current(I_p) involtage-clamped ventricular myocytes and intracellularNa⁺ activity(aⁱ_Na) in right ventricularpapillary muscles. Aldosterone (10 nM) induced an increase in bothI_p and the rateof rise of aⁱ_Na duringNa⁺-K⁺pump blockade with the fast-acting cardiac steroid dihydroouabain. Thealdosterone-induced increase inI_p and rate ofrise of aⁱ_Na was eliminated bybumetanide, suggesting that aldosterone activates Na⁺ influx through theNa⁺-K⁺-2Clcotransporter. To obtain independent support for this, theNa⁺,K⁺, andCl concentrations in thesuperfusate and solution of pipettes used to voltage clamp myocyteswere set at levels designed to abolish the inward electrochemicaldriving force for theNa⁺-K⁺-2Clcotransporter. This eliminated the aldosterone-induced increase inI_p. We concludethat in vitro exposure of cardiac myocytes to aldosterone activates theNa⁺-K⁺-2Clcotransporter to enhance Na⁺influx and stimulate theNa⁺-K⁺pump.

     

An Examination, by Compartmental Flux Analysis, of the Development of Sodium and Chloride Absorption Capacities in Beetroot Disks

Using beetroot, Beta vulgaris L. var. Avon Early, grown in radioactivelylabelled nutrient solutions, concentrations and fluxes of Na⁺and Cl^– were estimated for cells of freshly cut storageroot disks, by compartmental analysis of radioisotope elutionmeasurements. These values were compared with results obtainedin a similar manner from beetroot grown in non-labelled nutrientsolution and loaded instead during an aging period in ²²Na-or ³⁶Cl- labelled 1 mM NaCl solution. In accord with the generallyaccepted, but never properly tested, view, it was found thatnet Na⁺ influx followed from a reduction in efflux with agingand net Cl^– uptake depended on a marked increase in influx.However, both these important changes took place at the tonoplast,and, although aging led to a reduction of plasmalemma fluxes,at no time was entry of Cl^– into the cytoplasm, or lossof Na⁺ from the cytoplasm, significantly restricted.     

Comparison of the Effects of Ammonia and Methylamine on Chloride Transport and Intracellular pH in Chara corallina

Ammonium and methylammonium ions greatly increase the rate ofCl^– transport in Chara corallian. This effect is dependenton the pH of the bathing solution. The amine-stimulated Cl^–influx is small at pH 5·5, increases to a maximum atpH 6·5–7·5, and decreases again as the pHis raised to 8·5. Increased Cl^– influx is accompaniedby an increase in cytoplasmic pH, as calculated from the distributionof DMO. When the external pH lies between 5·5 and 7·3,cytoplasmic pH in the absence of amine is 7·65–7·70,with an increase of 0·15–0·25 in the presenceof amine. As external pH is increased above 7·3, cytoplasmicpH also increases, with progessively less effect of amine. Although the relationship between Cl^– influx and cytoplasmicpH is not simple, the results provide evidence in accord withthe hypothesis that Cl^– transport in Chara involves H⁺—Cl^–symport, or the equivalent OH^–—Cl^– antiport.The possible role of cytoplasmic pH as a factor involved inthe regulation of membrane transport in Chara is discussed.     

Inhibition of Sugar and Salt Elimination by Glands with the Amino Acid Analog p-Fluorophenylalanine

The amino acid analog p-fluorophenylalanine (FPA) inhibitedsugar and K⁺ secretion by nectary glands. FPA specifically reducedthe net excretion of Na⁺ and Cl^– by the salt glands ofthe halophyte Limonium vulgare and ³⁶Cl^–excretion by theglands of the pitcher walls of the carnivorous plant Nepenthes.Net uptake and net accumulation of Na⁺ and Cl^– by Limoniumleaf tissue and ³⁶Cl^– accumulation in Nepenthes pitchertissue were much less inhibited than excretion. The resultsare discussed in relation to literature reporting similar specificeffects of FPA on transport of ions from the symplast of barleyroots into the dead xylem elements. Limonium vulgare, Nepenthes hookeriana, salt-glands, excretion, p-fluorophenylalanine     

Thyroid Thermogenesis: Regulation of (Na$$K$)-Adenosine Triphosphatase and Active Na,K Transport

SYNOPSIS. Evidence in support of the hypothesis that T₃-inducedenhancement of O₂ consumption in mammalian target tissues isattributable to a stimulation of energy utilization for activetransmembrane Na^$ and K^$ transport is reviewed. The stimulationof target-tissue Na, K transport-dependent respiration followingT₃ treatment is associated with enhanced rates of active Na^$efflux and K^$ influx as well as with an increase in Na, KATPaseenzymaticactivity. The enhancement of Na, K-ATPase activity and enzymeabundance is secondary to a T₃-induced stimulation of Na, K-ATPasea and rß subunit biosynthesis and is probably mediatedby increased abundance of specific messenger RNAs coding forthe subunits of the enzyme. It is proposed that a coordinateaugmentation of Na, KATPase enzymatic activity and enhancementof passive membrane permeability to Na^$ and K^$ are necessaryto maintain the increased rates of active Na, K transport andenergy consumption associated with thyroid thermogenesis.     

The Ionic Relations of Acetabularia mediterranea

The concentrations of K⁺, Na⁺, and Cl^– in the cytoplasmand the vacuole of Acetabularia mediterranea have been measured,as have the vacuolar concentrations of SO₄^–– andoxalate. The electrical potential difference between externalsolution, and vacuole and cytoplasm has been measured. The resultsindicate that Cl^– and SO₄^–– are probably transportedactively into the cell, and that active transport of Na⁺ isoutwards. The results for K⁺ are equivocal. The fluxes of K⁺,Na⁺, Cl^–, and S0₄^–– into the cell and theeffluxes of Na⁺ and Cl^– have been determined. The Cl^–fluxes are extremely large. In all cases the plasmalemma isthe rate-limiting membrane for ion movement. A technique isdescribed for the preparation of large, completely viable cellfragments containing only cytoplasm, with no vacuole.     

Na+ fluxes in Chara under salt stress

The influx and efflux of Na⁺ across the plasma membrane of Characorallina and Chara longifolia were examined under mild saltstress conditions. Na⁺ influx was found to be rapid in bothspecies with the freely exchangeable cytoplasmic Na⁺ cominginto isotopic equilibrium with external ²²Na⁺ within 1 h ofexposure to isotope. Cytoplasmlc Na⁺ concentration and Na⁺ influxwere greater in C. corallina than in C. longifolla under thesame conditions. Na⁺ influx across the tonoplast was much lowerthan the flux across the plasma membrane. Na⁺ efflux was stimulatedat pH 5 relative to pH 7 by 218% in C. coralllna and 320% inC. longifolia. In both species externally applied Li⁺ inhibitedNa⁺ efflux at pH 5 but not at pH 7. Na⁺ etflux was not significantlyinhibited by amiloride. Key words: Na⁺ influx, Na⁺ efflux, Na⁺/H⁺ antiport, Chara     

Respiration-Dependent Proton and Sodium Pumps in a Psychrophilic Bacterium, Vibrio sp. Strain ABE-1

Respiration-dependent proton and sodium flows in a psychrophilicbacterium, Vibrio sp. strain ABE-1, were examined. At alkalinepH, this bacterium grew without being affected by a proton conductor,carbonylcyanide m-chlorophenylhydrazone (CCCP). O₂-pulse intoanaerobic cell suspensions prepared with Na^$-free buffers inducedtransient alkalization in the presence of CCCP and acidificationat pH 8.5 and 6.5, respectively. However, using cells preparedwith Na^$-containing buffer, the transient pH changes of thecell suspension could be simultanously detected at both pHs.Several inhibitory experiments suggested that the acidificationand alkalization should be attributed to a respiration-dependentprimary H^$ pump and Na^$ pump, respectively, and that the latterwas similar to that first reported in a marine bacterium, Vibrioalginolyticus. This Na^$ pump may have supported the CCCP-resistantgrowth at alkaline pH. The H^$ and Na^$ pumps operated very actively at low temperatures,such as 5?C, and should markedly help sustain bacterial growthat low temperatures. (Received May 30, 1987; Accepted November 13, 1987)     

Fluxes of Sodium and Potassium in Acetabularia mediterranea

Sodium efflux in Acetabularia mediterranea occurs against agradient of electrochemical potential and is a light-stimulated,temperature-sensitive process; it is not sensitive to the uncouplerCCCP. Sodium influx is stimulated in CCCP and at low temperature.Potassium influx is temperature- and uncoupler-sensitive, butis not light-stimulated. Tracer K efflux shows complex kinetics,which cannot be explained by any arrangement of intracellularcompartments; it appears to be stimulated at low temperatureand is insensitive to light and uncouplers. There is no evidencefor any chemical linkage between fluxes of Na⁺, K⁺, or Cl^–.It is concluded that Na^– efflux at the plasmalemma isan active process, but no consistent explanation can be advancedto account for the results of K⁺ flux measurements.     

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.