Molecular Dynamics Simulation Studies of the Limiting Conductances of MgCl2 and CaCl2 in Supercritical Water Using SPC/E Model for Water

We report results of molecular dynamics (MD) simulations of the limiting conductances of MgCl² and CaCl² in supercritical water as a function of water density using the SPC/E model for water. The limiting conductances of Mg²⁺, Ca²⁺ and Cl^- over the whole range of water density considered exhibits a linear dependence of the limiting conductance on the water density. In the cases of Mg²⁺ and Ca²⁺, a solventberg picture for the behavior of small divalent cation emerges from our studies. From the view of the solventberg picture, the ion and its shell moving together as an entity interacts with the second hydration shell water molecules, and its mobility is restricted mostly by the number of the second hydration shell water which is proportional to the water density of the whole system. In the case of Cl^-, the range of water density considered in this study belongs to the higher-density region (above 0.45?g/cm³) in which the effect of the number of hydration water molecules around ions dominated. As the water density increases, the water molecules of the first hydration shell restrict the mobility of Cl^- and the limiting conductance of Cl^- decreases nearly linearly. Significant different dependence on the water density is observed between the calculated limiting conductances of MgCl² and CaCl² at 673?K and the experimental results over the water density of 0.60–0.90?g/cm³. Possible limitation of the extended simple point charge (SPC/E) model with regard to this difference should be pointed out and the use of a more precise model like the revised polarizable (RPOL) model is indispensable for a further MD study to gain a complete picture of the chemical circumstance around the ions.     

Molecular Dynamics Simulation of Limiting Conductance for Na2+, Cl2−, Na°, and Cl° in Supercritical Water

Abstract

We report results of molecular dynamics simulations of the limiting conductance of Na²⁺, Cl^2?, Na°, and Cl° in supercritical water using the SPC/E model for water in conjuction with our previous study (Lee et al., Chem. Phys. Lett. 293, 289 (1998)). The behavior of the limiting conductances of Na²⁺ and Cl^2? in the whole range of water density shows almost the same trend as those of Na⁺ and Cl^?, but the deviation from the assumed linear dependence of limiting conductances of Na²⁺ and Cl^2? on the water density is smaller than that of Na⁺ and Cl^?. The ratio of the limiting conductance of the divalentions to that of the corresponding monovalentions over the whole range of water density is almost constant. In the cases of Na²⁺ and Cl^2?, the dominating factor of the number of hydration water molecules around ions in the higher-density region and the dominating factor of the interaction strength between the ions and the hydration water molecules in the lower-density region are also found as was the cases for Na⁺ and Cl^?. These factors, however, are not so strong as for the corresponding monovalent ions because the change in the energetics, structure, and dynamics are very small mainly due to the strong Coulomb interaction of the divalent ions with the hydration water molecules. The diffusion coefficient of Na° and Cl° monotonically increases with decreasing water density over the whole range of water density. The increase of the diffusion coefficient with decreasing water density is attributed only to the dramatic decrease of the hydration number of water in the first solvation shell around the uncharged species. Among the two important competing factors in the limiting conductance of Na⁺ and Cl^?, the effect of the number of hydration water molecules around the uncharged species is the only existing factor over the whole range of water density since the interaction strength between the uncharged species and the hydration water molecules very small through the LJ interaction. This result has confirmed the dominating factor of the number of hydration water molecules around ions in the higher-density region in the explanation of the limiting conductance of Na⁺ and Cl^? in supercritical water at 673 K.     

Electrophoresis in protein crystal: nonequilibrium molecular dynamics simulations

Electrophoresis of a mixture of NaCl and CaCl₂ in a lysozyme crystal is investigated using nonequilibrium molecular dynamics (MD) simulations. Upon exposure to an electric field, the stability of lysozyme is found to decrease slightly. This finding is demonstrated by increases in the root mean-square deviations of the heavy atoms of lysozyme, in the solvent-accessible surface area of hydrophobic residues, and in the number of hydrogen bonds between lysozyme and water. The solvent-accessible surface area of hydrophilic residues changes marginally, and the number of hydrogen bonds between lysozyme molecules decreases. Water molecules tend to align preferentially parallel to the electric field, and the dipole moment along the pore axis increases linearly with increasing field strength. Two pronounced layered structures are observed for Na⁺ and Ca²⁺ in the vicinity of protein surface, but only one enriched layer is observed for Cl⁻. The number distributions of all ions are nearly independent of the electric field. The water coordination numbers of all ions are smaller in the crystal than in aqueous bulk solution; however, the reverse is found for the Cl⁻ coordination numbers of cations. Both the water and the Cl⁻ coordination numbers are insensitive to the electric field. Ion diffusivities in the crystal are ∼2 orders of magnitude smaller than those in aqueous bulk solution. The drift velocities of ions increase proportionally to the electric field, particularly at high strengths, and depend on ionic charge and coordination with oppositely charged ions. Electrical current exhibits a linear relationship with the field strength. The zero-field electrical conductivity is estimated to be 0.56 S/m, which is very close to 0.61 S/m as predicted by the Nernst-Einstein equation.     

THE UPTAKE OF INORGANIC ELECTROLYTES BY THE CRAYFISH

1. Reasons are given for believing that the uptake of Na⁺, Cl^-, and NaCl by the crayfish occurs through the gills. 2. A crayfish in fresh water, with a Cl concentration of about 0.2 mEq./l., can) by active Cl absorption, compensate entirely for Cl lost in the urine. 3. The carbonic anhydrase activity of the gills is markedly higher than that of other tissues of the crayfish, but the equivalent CO₂ output of the crayfish is far in excess of the equivalent Cl absorption per unit time and weight and thus fails to warrant the supposition that Cl absorption is of respiratory importance. 4. The carbonic anhydrase activity of the soft integument of the lobster, before and after molting, and of the hypodermis of the hard-cuticled animal is almost identical and of the same order as that of other tissues of the lobster. 5. The concentration of the electrolytes was about 7.5 mEq./l.; i.e., considerably lower than in the blood of the crayfish. Cl^- can be taken up independently of the complementary cation. Na₊ can be taken up independently of the complementary anion. K⁺ and SO₄ ⁼ are not taken up at all. In pure NaCl, the Na⁺ and Cl^- are absorbed evidently largely together. Ca⁺⁺ is absorbed only in newly molted animals and in animals preparing to molt but is not absorbed by hard-cuticled animals not preparing to molt. Ca⁺⁺ is taken up independently of Cl^- in pure CaCl₂. 6. Newly molted animals absorb Ca⁺⁺ at a rate exceeding that of the absorption of other absorbable ions (Na⁺ and Cl_-) in the same equivalent concentration. 7. A crayfish utilizes the Ca⁺⁺ in fresh water in the calcification of its cuticle. Since the animal does not swallow water, the Ca⁺⁺ must enter through the exterior. Reasons are given for believing that, unlike Na⁺ and Cl^-, Ca⁺⁺ is absorbed directly from the exterior by the integument and does not enter the body through the gills. 8. During molting, only about 4 per cent of the raw ash and 2.3 per cent of the organic material of the old cuticle is resorbed.     

Cation Effects on Chloride Fluxes and Accumulation Levels in Barley Roots

Accumulation of Cl^- by excised barley roots, as of K⁺, approaches a maximum level at which the ion influx and efflux rates become equal. The rate of Cl^- influx at this equilibrium is close to the initial rate while the efflux rate increases with time from zero to equality with influx. The Cl^- fluxes are independent of simultaneous exchange flux of the cations, but depend on the nature and concentration of the salt solutions from which they originate. The Cl^- content at equilibrium, however, is largely independent of the external concentrations. The approach to equilibrium reflects the presence of the cation. Cl^- flux equilibrium is attained more rapidly in KCl than in CsCl or CaCl₂. This is presumably an effect of much slower distribution of Cs⁺ and Ca⁺⁺ than of K⁺ within the roots. Accumulated Cs⁺ appears to form a barrier to ion movement primarily within the outermost cells, thereby reducing influx and ultimately efflux rates of both Cl^- and cations. Slow internal mixing and considerable self-exchange of the incoming ions suggest internal transport over a series of steps which can become rate-limiting to the accumulation of ions in roots.     

Phosphate cycles in energy crop systems with emphasis on the availability of different phosphate fractions in the soil

The growing cells of hydroponic maize roots expand at constant turgor pressure (0.48 MPa) both when grown in low-(0.5 mol m^-3 CaCl₂) or full-nutrient (Hoagland's) solution and also when seedlings are stressed osmotically (0.96 MPa mannitol). Cell osmotic pressure decreases by 0.1–0.2 MPa during expansion. Despite this, total solute influx largely matches the continuously-varying volume expansion-rate of each cell. K⁺ in the non-osmotically stressed roots is a significant exception-its concentration dropping by 50% regardless of the presence or absence of K⁺ in the nutrient medium. This corresponds to the drop in osmotic pressure. Nitrate appears to replace Cl^- in the Hoagland-grown cells.Analogous insensitivity of solute gradients to external solutes is observed in the radial distribution of water and solutes in the cortex 12 mm from the tip. Uniform turgor and osmotic pressures are accompanied by opposite gradients of K⁺ and Cl^-, outwards, and hexoses and amino acids, inwards, for plants grown in either 0.5 mol m^-3 CaCl₂ or Hoagland's solution (with negligible Cl^-). K⁺ and Cl^- levels within both gradients were slightly higher when the ions were available in the medium. The gradients themselves are independent of the direction of solute supply. In CaCl₂ solution all other nutrients must come from the stele, in Hoagland's solution inorganic solutes are available in the medium.24 h after osmotic stress, turgor pressure is recovered at all points in each gradient by osmotic adjustment using organic solutes. Remarkably, K⁺ and Cl^- levels hardly change, despite their ready availability. Hexoses are responsible for some 50% of the adjustment with mannitol for a further 30%. Some 20% of the final osmotic pressure remains to be accounted for. Proline and sucrose are not significantly involved. Under all conditions a standing water potential step of 0.2 MPa between the rhizodermis and its hydroponic medium was found. We suggest that this is due to solute leakage.Abbreviations EDX energy dispersive X-ray microanalysis - water potential - 11-1 cell osmotic pressure - P turgor pressure     

Molecular dynamic simulations study of the effect of salt valency on structure and thermodynamic solvation behaviour of anionic polyacrylate PAA in aqueous solutions

The effect of salt concentration and valency on intermolecular structure and solvation thermodynamic properties of aqueous solution containing polyacrylicacid (PAA) chains and multi-valent salts calcium chloride (CaCl₂) and aluminium chloride (AlCl₃) as a function of charge density was investigated using atomistic molecular dynamic simulations with explicit solvent. Salt-free solution favours the self-association of uncharged (acidic form) PAA chains facilitated by inter-chain hydrogen bonds. The ionised (charged) PAA chains are not associated in salt-free aqueous solutions and undergo self-association in the salt solutions due to bridging effect induced by condensed salt ions in agreement with scattering investigations available in literature. The collapse behaviour of PAA in presence of CaCl₂ and re-expansion behaviour of PAA chains in case of AlCl₃ salt solutions are observed. The rigidity of PAA chains decrease with increase in salt concentration, in agreement with experimental results available in literature. The trivalent salt favours relatively the greater extent of shrinking of PAA chains as well as inter-chain interactions as compared to divalent salts as evident from radius-of-gyration, H-bond and pair-wise solvation enthalpy data. The conformation and hydration behaviour of the acid form of PAA chains are not significantly altered by added salt ions. The hydration behaviour of ionised PAA chains is significantly reduced by added salts due to screening effect of the condensed salt ions. The pair correlation functions of solutions species such as Ca²⁺, Al³⁺, Na⁺ and Cl^? with respect to PAA oxygen show the greater affinity of PAA units with the higher valency Al³⁺ ions over Ca²⁺ and Na⁺ in solution. With increase in concentration of AlCl₃ and CaCl₂ salts, a decrease in effective charge density of ionised PAA chains is observed from the existence of unfavourable PAA–water, PAA–Ca²⁺ and PAA–Al³⁺ interactions.     

渗透胁迫和离子毒害对转Bt基因棉幼苗生长及离子分布的影响

研究了渗透和盐胁迫处理对转Bt基因抗虫棉(Gossypium hirsutum) 99B种子的萌发和幼苗生长的影响,以及幼苗不同器官离子吸收和分配的差异。结果表明:渗透和盐胁迫均对转Bt基因抗虫棉幼苗的生长有抑制作用,其中PEG的抑制作用最强,而3种盐的抑制程度以CaCl₂>NaCl>Na₂SO₄,且在Na⁺含量相同时,Cl^-的毒害大于SO₄^2-。渗透胁迫下使根、茎和叶中的Na⁺和Cl^-含量提高,K⁺、Ca²⁺、SO₄^2-含量和K⁺/Na⁺、Ca²⁺/Na⁺和SO₄^2-/Cl^-比值降低,且地上部的变化幅度大于地下部的,其中以PEG的影响最为显著,其次是CaCl₂,Na₂SO₄处理最弱。这些说明,转Bt基因抗虫棉99B的耐盐性较弱。     

A Ca2+-activated Cl− current in sheep parotid secretory cells

Previous studies have shown that the whole-cell current-voltage (I-V) relation of unstimulated sheep parotid cells is dominated by two K⁺ conductances, one outwardly and the other inwardly rectifying. We now show that once these K⁺ conductances are blocked by replacement of pipette K⁺ with Na⁺ and by the addition of 5 mmol/liter CsCl to the bath, there remains an outwardly rectifying conductance with a reversal potential of 0 mV. Replacement of 120 mmol/liter NaCl in the pipette solution with an equimolar amount of Na-glutamate shifted the reversal potential of this residual current to -55 mV, indicating that the conductance was Cl^? selective. The Cl^? current was activated by increasing the free Ca²⁺ in the pipette solution from 10 to 100 nmol/liter. When the Ca²⁺ concentration in the pipette solution was 10 nmol/liter, the relaxations observed in response to membrane depolarization could be fitted with a single exponential, whose time constant increased from 81 to 183 ms as the pipette potential was increased from -30 to +60 mV. Relaxation analysis showed that the current was activated by membrane depolarization. Reversal potential measurements in experiments in which external Cl^? was replaced with various anions, gave the following relative permeabilities: SCN^- (1.80) > I^- (1.09) > CI^- (1) > NO ₃ ^- (0.92) > Br^- (0.75). The relative conductances were: SCN^- (2.18) > I^- (1.07) > Cl^? (1.00) > Br^- (0.91) > NO ₃ ^- (0.50). The Cl^? current was blocked by NPPB (ID₅₀ ≈ 10 μm), DIDS (10 or 30 μmol/liter) and furosemide (100 μmol/liter).     

ADH Action on Whole-Cell Currents by Cytosolic Ca2+-dependent Pathways in Aldosterone-treated A6 Cells

We studied the characteristics of the basal and antidiuretic hormone (arginine vasotocin, AVT)-activated whole cell currents of an aldosterone-treated distal nephron cell line (A6) at two different cytosolic Ca²⁺ concentrations ([Ca²⁺] _c , 2 and 30 nm). A6 cells were cultured on a permeable support filter for 10 ∼ 14 days in media with supplemental aldosterone (1 μm). At 30 nm [Ca²⁺] _c , basal conductances mainly consisted of Cl⁻ conductances, which were sensitive to 5-nitro-2-(3-phenylpropylamino)-benzoate. Reduction of [Ca²⁺] _c to 2 nm abolished the basal Cl⁻ conductance. AVT evoked Cl⁻ conductances at 2 as well as 30 nm [Ca²⁺] _c . In addition to Cl⁻ conductances, AVT induced benzamil-insensitive nonselective cation (NSC) conductances. This action on NSC conductances was observed at 30 nm [Ca²⁺] _c but not at 2 nm [Ca²⁺] _c . Thus, cytosolic Ca²⁺ regulates NSC and Cl⁻ conductances in a distal nephron cell line (A6) in response to AVT. Keeping [Ca²⁺] _c at an adequate level seems likely to be an important requirement for AVT regulation of ion conductances in aldosterone-treated A6 cells. Received: 6 May 1996/Revised: 28 June 1996     

Cytoplasmic streaming and ionic regulation inNitella flexilis having artificial cell saps of low ionic strength

The cell sap of the internode ofNitella flexilis was replaced with the isotonic artificial pond water of high Ca²⁺-concentration (0.1 mM KCl, 0.1 mM NaCl, 10 mM CaCl₂ and 275 mM mannitol) and changes in osmotic value and concentrations of K⁺, Na⁺ and Cl⁻ of the cells were followed. When the operated cells were incubated in the artificial pond water containing 0.1 mM each of KCl, NaCl, CaCl₂, they survived for only a short period of time (<10 hr). The cells did not absorb ions from the artificial pond water and showed a conspicuous decrease in the rate of cytoplasmic streaming. In such cell the concentration of K⁺ in the protoplasm decreased significantly. In order to reverse normal concentration gradients of K⁺ and Na⁺ across the protoplasmic layer, the cells of low vacuolar ionic concentrations were incubated in the artificial cell sap (90 mM KCl, 40 mM NaCl, 15 mM CaCl₂, 10 mM MgCl₂). It was found that the cells rapidly absorbed much K⁺, Na⁺ and Cl⁻ and survived for a longer period (1–2 days). During this period the rate of cytoplasmic streaming was nearly normal. Furthermore, the cell lost much mannitol, indicating an enormous increase in permeability to it. Since both absorption of ions and leakage of mannitol at 1 C occurred at nearly the same rates as at 22 C, the processes are assumed to be passive.     

基于典范对应分析的滨海湿地土壤季节性盐渍化特征

为了更好地开发利用黄河三角洲湿地土壤资源和生态环境建设,运用单因素方差分析(One-way ANOVA)和典范对应分析方法(CCA),对黄河口湿地0—10 cm土壤全盐量(TS)、盐分离子组成、pH、钠吸附比(SAR)、电导率(EC)的季节性变化特征及数量关系进行了分析。结果表明:该区土壤属于盐土类型,春季(5月)、夏季(8月)、秋季(10月)全盐含量均高于17.9 g/kg,且春季、秋季的含盐量高于夏季,造成春、秋季积盐,夏季脱盐。盐分阳离子以Na~+为主,阴离子以Cl~-为主,除Mg~(2+)在夏季、秋季和Cl~-在秋季表现出强烈的变异性外,其余离子在不同季节均表现出中等强度的变异性。春季,Cl~-与Na~+、Mg~(2+),SO■与K~+;夏季,Cl~-与HCO~-_3,SO■与Mg~(2+)、Ca~(2+),Ca~(2+)与Mg~(2+);秋季,Cl~-与SO■,SO■与Mg~(2+),Ca~(2+)与Mg~(2+),均有很好的关联性。pH值均介于7.7—8.1之间,各个季节受盐分离子的影响较小,分布较为均匀。SAR介于3.08—5.29之间,春季受控于HCO~-_3;夏季受控于K~+;秋季受各离子的影响均较小,分布较为均匀。EC介于7.16—13.04 mS/cm,春季受各离子的影响均较小,其空间分布较为均匀;夏季受控于SO■、Ca~(2+)、Mg~(2+);秋季受控于Na~+。TS与Cl~-、Na~+、Mg~(2+)在季节变化上的差异性一致,且各个季节均受控于Cl~-。故通过合理的措施控制或减少Cl~-来源是一条减轻黄河口湿地土壤盐渍化的合适途径。     

Anion conductance of frog muscle membranes: one channel, two kinds of pH dependence

Anion conductance and permeability sequences were obtained for frog skeletal muscle membranes from the changes in characteristic resistance and transmembrane potential after the replacement of one anion by another in the bathing solution. Permeability and conductance sequences are the same. The conductance sequence at pH = 7.4 is Cl^- Br^- > NO₃ ^- > I^- > trichloroacetate ≥ benzoate > valerate > butyrate > proprionate > formate > acetate ≥ lactate > benzenesulfonate ≥ isethionate > methylsulfonate > glutamate ≥ cysteate. The anions are divided into two classes: (a) Chloride-like anions (Cl^- through trichloroacetate) have membrane conductances that decrease as pH decreases. The last six members of the complete sequence are also chloride like. (b) Benzoate-like anions (benzoate through acetate) have conductances that increase as pH decreases. At pH = 6.7 zinc ions block Cl^- and benzoate conductances with inhibitory dissociation constants of 0.12 and 0.16 mM, respectively. Chloride-like and benzoate-like anions probably use the same channels. The minimum size of the channel aperture is estimated as 5.5 x 6.5 Å from the dimensions of the largest permeating anions. A simple model of the channel qualitatively explains chloride-like and benzoate-like conductance sequences and their dependence on pH.     

Effects of calcium on growth and leaf ion concentrations of Gossypium hirsutum grown in saline hydroponic culture

The optimum Ca²⁺ concentration for growth of cotton (Gossypium hirsutum cv. Acala SJ-2) was in the range 1 to 15 mol m^–3 for plants growing in hydroponic culture with 100–150 mol m^–3 NaCl. Most saline (but not sodic) soils contain higher Ca²⁺ concentrations. CaCl₂ was inhibitory to the growth of cotton above 20–50 mol m^–3. Increasing concentrations of Ca²⁺ in the range 0–2 mol m^–2 drastically reduced Na⁺ accumulation in the leaves. As CaCl₂ concentrations were increased above the optimum for growth there was a further reduction in leaf Na⁺ accumulation, but this was more than offset by increased leaf Ca²⁺ and Cl^– concentrations. Leaf K⁺ concentrations were not much affected by changes in external CaCl₂ concentrations. The response of Mg²⁺ varied from an increase to a decrease with increasing external CaCl₂ and was influenced by nutritional status. There was no evidence that high Ca²⁺ caused a deficiency of Mg²⁺ in cotton. Except for Cl^–, whose concentrations tended to decrease initially and then increase as the CaCl₂ concentration increased, the anions were largely unaffected by changes in external CaCl₂.     

Activation of Cl− channels by extracellular Ca2+ in freshly isolated rabbit osteoclasts

Ionic channels regulated by extracellular Ca²⁺ concentration ([Ca²⁺]₀) were examined in freshly isolated rabbit osteoclasts. K⁺ current was suppressed by intracellular and extracellular Cs⁺ ions. In this condition, high [Ca²⁺]₀ evoked an outwardly rectifying current with a reversal potential of about −25 mV. When the concentration of extracellular Cl⁻ ions was altered, the reversal potential of the outwardly rectifying current shifted as predicted by the Nernst equation. 4′,4-diisothiocyanostilbene-2′,2-disulphonic acid (DIDS) inhibited the outwardly rectifying current. These results indicated that this current was carried through Cl⁻ channels. Cd²⁺ or Ni²⁺ caused a transient activation of the Cl⁻ current in contrast to the sustained activation elicited by Ca²⁺. Intracellular 20 mM ethylene glycol-bis(β-aminoethyl ether)-N,N,N′,N′-tetraacetic acid (EGTA) inhibited the divalent cation-induced Cl⁻ current. Either when the osmolarity of extracellular medium was increased, or when 100 μM cAMP was dissolved in the patch pipette solution, high [Ca²⁺]₀ still elicited the Cl⁻ current, indicating that the divalent cation-induced Cl⁻ current was carried through Ca²⁺-activated Cl⁻ channels. Under perforated whole cell clamp extracellular divalent cations evoked the Cl⁻ current, indicating that the activation of Cl⁻ current did not arise from possible leakage of divalent cations from the extracellular medium under the whole cell clamp condition. This experiment further excluded a possible activation of volume-sensitive Cl⁻ channels under whole cell clamp. Intracellular application of guanosine 5′-O-(3-thiotriphosphate) (GTPγS) activated the Cl⁻ current and it was inhibited by intracellular 20 mM EGTA, suggesting that the activation of Cl⁻ current was mediated through a G protein, and that an increase in [Ca²⁺]_i was critical for the activation of Cl⁻ channels. A protein phosphatase inhibitor, okadaic acid (100 nM), caused an irreversible activation of the Cl⁻ current, suggesting that protein phosphatase 1 or 2A was involved in the regulation of Ca²⁺-activated Cl⁻ channels. © 1996 Wiley-Liss, Inc.     

Two types of chloride channels in hen colon epithelial cells identified by patch-clamp experiments

Summary Freshly isolated epithelial cells from hen colon were investigated using the patch-clamp technique. The aim of this investigation was to characterise the cellular conducting site for Cl^- secretion. In cell-attached mode two types of Cl^--channels were found. Both showed distinct outward rectification. The channel types differed in single channel conductances and the marked voltage dependence of the open probabilities. A low conductance Cl^--channel was observed with a mean conductance at negative holding potentials of g_-=9 pS, and of g₊=34 pS at positive potentials. This channel was predominantly open at negative potentials, corresponding to cell hyperpolarization. The second channel type observed had conductances of g_-=35 pS and g₊=77 pS, and showed increasing open probabilities with increasing holding potentials (cell depolarisation). Both channel types were blockable by the Cl^--channel blocker NPPB. These data in combination with previously published transepithelial transport data on hen colon indicate that these channels are the Cl^- secretory sites in colon epithelium.Abbreviations DNSO dimethylsulfoxide - EGTA ethyleneglycol triacetic acid - g₊, g_- single channel conductance at positive and negative voltages - HEPES N-(2-hydroxy-ethyl)piperazine-N-(2-ethane-sulfonic acid) - i single channel current - NMDG N-methyl-d-glucosamine - NPPB 5-hitro-2-(3-phenylpropylamino)-benzoate - P_o open probability - V_p holding potential     

Electrogenic action of calcium on crayfish gill

When intact crayfish are in an ion-poor medium (KCl, 0.1 mmol·l^-1+KHCO₃, 0.1 mmol·l^-1) there is a large potential difference (transepithelial potential difference),-20 to-40 mV (hemolymph negative), across the gills. Addition of Ca²⁺ to the medium is followed by a rapid change in transepithelial potential difference to near 0 mV. The transepithelial potential difference showed a non-linear dependence on [Ca²⁺]_out with a limiting value of+2 to+10 mV at>1 mmol·l^-1. The concentration generating a half-maximum transepithelial potential difference change (15–20 mV) was 0.1 to 0.2 mmol·l^-1. Three other alkaline earth ions were also electrogenic; Ba²⁺ caused slightly larger transepithelial potential difference changes, Sr²⁺ and Mg²⁺ were a little less effective. It has been suggested that the transepithelial potential difference in ion-poor medium (in fish) is due to the diffusive efflux of NaCl across the gills, with a Cl^-/Na⁺ permeability ratio of <1. Evidence is presented that this might be the case in crayfish. The electrogenic effect of Ca²⁺ might then be due to its effect on gill permeability to Na⁺ and Cl^- such that the permeability ratio increased and approached unity as the transepithelial potential difference approached 0. However, this was shown to be unlikely. An alternative explanation for Ca²⁺ dependence of the transepithelial potential difference is that active inward Ca²⁺ transport is electrogenic.Abbreviations FW fresh water - I _out ion efflux - IP ion-poor solution - P _c Cl-permeability - P _Na Na⁺ permeability - R electrical resistance - SW sea water - TEP transepithelial potential difference     

Effects of trypsin and bivalent cations on P-680+-reduction,fluorescence induction and oxygen evolution in Photosystem II membrane fragments from spinach

Laser-flash-induced absorption changes at 830 nm, fluorescence-induction curves and the average oxygen yield per flash have been measured in spinach Photosystem II membrane fragments as a function of trypsin treatment and its modification by CaCl₂. The following was found. (i) The relative contribution of the nanosecond relaxation to the overall decay kinetics of 830 nm absorption changes reflecting the P-680⁺-reduction decreases as a function of incubation time with trypsin. Simultaneously, mild treatment at pH = 6.0 markedly increases the extent of 200 μs kinetics that highly revert back to nanosecond kinetics by CaCl₂ addition. After harsher trypsin treatment (pH = 7.5) pH-dependent 2–20 μs kinetics appear that cannot be reverted to nanosecond kinetics by CaCl₂. (ii) The CaCl₂-induced restoration of nanosecond kinetics is mainly due to a Ca²⁺-induced effect rather than to a functional role of Cl⁻. Sr²⁺ can substantially substitute for Ca²⁺, whereas Mg²⁺, Mn²⁺ and monovalent ions are almost inefficient. (iii) A quantitative correlation between the extent of the nanosecond kinetics and the average oxygen yield per flash was not observed. (iv) If CaCl₂ is present in the assay medium for trypsin treatment the samples are markedly protected to proteolytic degradation. This effect mainly refers to the reaction pattern of the acceptor side. Other bivalent cations can substitute Ca²⁺ for its protective function. (v) The CaCl₂-induced protection to proteolytic attack is extremely sensitive to a very short trypsin pretreatment that does hardly affect the shape of the fluorescence induction curve. The results are discussed in relation to the functional and structural organization of Photosystem II.     

Effects of salinity on uptake and distribution of Na+, Cl- and K+ in two wheat cultivars

Plants of two wheat (Triticum aestivum L.) cultivars differing in salt tolerance were grown in sand with nutrient solutions. 35-d-old plants were subjected to 5 levels of salinity created by adding NaCl, CaCl₂ and Na₂SO₄. Growth reduction caused by salinity was accompanied by increased Na⁺ and Cl^- concentrations, Na⁺/K⁺ ratio, and decreased concentration of K⁺. The salt tolerant cv. Kharchia 65 showed better ionic regulation. Salinity up to 15.7 dS m^-1 induced increased uptake of Na⁺ and Cl^- but higher levels of salinity were not accompanied by further increase in uptake of these ions. Observed increases in Na⁺ and Cl^- concentrations at higher salinities seemed to be the consequence of reduction in growth. Uptake of K⁺ was decreased; more in salt sensitive cultivar. This was also accompanied by differences in its distribution.