Comparison of the gramicidin a potassium/sodium permeability and single channel conductance ratio

If the ion concentration is low enough that most channels are unoccupied, then the ‘independence relations’ should be satisfied and the permeability ratio should equal the conductance ratio. It has been previously reported that for the gramicidin A channel these ratios for Na⁺ and K⁺ were not equal at concentrations as low as 10 mM. However, these ratios were not measured at the same applied potential, as is required by the theory. Instead, the conductance ratio was measured at 100 mV and corrected using calculated current-voltage relations. In this report the comparison between permeability and conductance ratios is reexamined using data obtained at the correct potential. There is no significant difference in the ratios at 10 mM when they are measured at the same voltage. This implies that most channels are not occupied by sodium or potassium ions at 10 mM.     

Effect of beta-blockers on sodium and potassium content of human erythrocytes.

Recently, hyperpotassemia was reported in patients treated with propranolol, but the mechanism has not yet been delineated. We have investigated the effects of various beta-adrenergic blockers and of D-propranolol on the Na+ and K+ distribution intra- and extracellularly in human erythrocytes. K+ loss and Na+ gain by cells was demonstrated at drug concentrations of 10(-4) M or greater. D-Propranolol was more effective than L-propranolol, whereas pindolol was ineffective. Practolol increased Na+ content but did not influence K+. The results suggest that electrolyte redistribution across cell membranes is not a likely explanation for hyperpotassemia in patients treated with propranolol, or for the local anaesthetic effect of this drug.     

The use of whole-body sodium, potassium and calcium content to identify the nutrient status of first year salmon fry

Samples of fed and unfed hatchery reared Atlantic salmon fry and parr were analysed for body water and whole body Na, K and Ca content. From these body parameters it is possible to estimate the relative proportions of the skeletal mass, and intra- and extracellular spaces. These data can be applied to estimating the nutritional status of parr sampled at random from hatchery, and possibly from wild populations. When fish with a dry weight of about 25 and 70 mg were deprived of artificial food for 27 and 21 days, respectively, the Na/K ratio rose to 0.59 and 0.80 compared with 0.37 in the controls. With fish of about 475 mg in weight, percentage water content was a better indicator of undernourishment. The use of the K⁺: Ca²⁺ ratio to compare the amount of cellular material with the skeletal mass was a good indicator of nutritional depletion, especially in smaller fish.     

Effects of potassium carbonate as an alternative road de-icer to sodium chloride on soil chemical properties

The effect of potassium carbonate on soil chemical characteristics was compared with that of the most common de‐icer, sodium chloride, in a 4‐yr outdoor pot experiment with poplar and lime trees. Soil pH was raised more by K₂CO₃ than by NaCl. Potassium carbonate increased the electrical conductivity mainly in the upper soil layers. When K₂CO₃ was applied at an average annual dose of 154 g m^?2, only the water‐soluble fractions of calcium and magnesium were affected. At an average annual dose of 617 g m^?2, total potassium increased by 33% and calcium was displaced from the exchange sites. Calcium saturation was reduced from 85% of the cation exchange capacity in the untreated control to 69% in the higher dose K₂CO₃ treatment and to 75% in the NaCl treatment. The results show that the negative impact of K₂CO₃ on soil chemical and osmotic properties is as high as that of NaCl. For plants, however, potassium carbonate in contrast to chloride is not toxic and, applied in moderate doses, may even remedy potassium deficiencies in roadside trees.     

Effect of the cations sodium and potassium on the molecular weight of hyaluronate

The molecular weight of Na- and K-hyaluronate has been determined by low angle laser light scattering (LALLS) technique. Two preparations of hyaluronate from rooster comb ($\text{M}{}_{\mathrm{w}}\text{= 0.9 × 10}{}^6\text{and 4 × 10}{}^6$) were investigated. The LALLS was carried out both in a static mode and on the effluent from a column filled with porous gel. In contrast to Sheehan et al.¹, no significant difference was found in the molecular weight of viscosity of Na- and K-hyaluronate in 2.0 M salt solutions     

Salt sensitivity and low discrimination between potassium and sodium in bean plants

Bean plants (Phaseolus vulgaris) were very sensitive to moderate concentrations of NaCl, showing a dramatic decrease in their K⁺ content in the presence of this salt. Increasing the KCl content of the nutrient medium released the inhibitory effect of NaCl by increasing the K⁺ content of the plants. Likewise moderate concentrations of KCl were toxic for bean plants because they produced a large K⁺ loading. NaCl partially released this toxicity by inhibiting the K⁺ loading. When compared to the moderately salt tolerant sunflower plants (Helianthus annuus), bean plants showed a lower capacity to discriminate between K⁺ and Na⁺, at high Na⁺ levels, and an uncontrolled K⁺ uptake at moderate concentrations of K⁺. It is concluded that this low capacity of discrimination of the K⁺ uptake system of bean plants in presence of Na⁺ can account for by the NaCl sensitivity of bean plants.     

Effects of potassium deficiency on tomato growth and mineral nutrition at the early production stage

The effects of potassium deficiency on hydroponically grown tomato were investigated at the early production stage (23 leaves, 3 trusses). Two types of potassium deficiency were applied : the permanent deficiency lasted for 23 days whereas the 10-day temporary deficiency was followed by a 7-day period of potassium supply resumption.Growth was assessed through non-destructive measurements. Permanent potassium deficiency resulted in growth slow-down before visual symptoms appeared on the adult leaves (leaves 12 to 17), but the older leaves (next to the first truss) were not affected. Temporary potassium deficiency reduced the growth rate, but, after potassium supply resumption, the plants recovered a growth pattern which was similar to that of the control plants. The potassium of the older leaves appeared to be less mobilizable than that present in the adult leaves where the visual deficiency symptoms appeared.Potassium uptake kinetics during the potassium supply resumption period were investigated on the plants submitted to temporary deficiency. In tomato plants which had been temporarily deprived of potassium before being transferred onto a standard nutrient solution, potassium uptake was faster than in the control plants. This result is to be related to the plant ability to recover a normal growth pattern.As a result of the occurrence of K-Mg and K-Na antagonisms, the sum of the cations was maintained at a constant value in some plant organs.     

Transport,signaling, and homeostasis of potassium and sodium in plants

Potassium(Kt) is an essential macronutrient in plants and a lack of Ktsignificantly reduces the potential for plant growth and development. By contrast, sodium(Nat),while beneficial to some extent, at high concentrations it disturbs and inhibits various physiological processes and plant growth. Due to their chemical similarities, some functions of Kt can be undertaken by Natbut Kthomeostasis is severely affected by salt stress, on the other hand. Recent advances have highlighted the fascinating regulatory mechanisms of Kt and Nattransport and signaling in plants. This review summarizes three major topics:(i) the transport mechanisms of Ktand Natfrom the soil to the shoot and to the cellular compartments;(ii) the mechanisms through which plants sense and respond to Ktand Natavailability; and(iii) the components involved in maintenance of Kt/Nathomeostasis in plants under salt stress.     

Transport,signaling, and homeostasis of potassium and sodium in plants

Potassium （K＋） is an essential macronutrient in plants and a lack of K＋ significantly reduces the potential for plant growth and development. By contrast, sodium （Na＋）, while beneficial to some extent, at high concentrations it disturbs and inhibits various physiological processes and plant growth. Due to their chemical similarities, some functions of K＋ can be undertaken by Na＋ but K＋ homeostasis is severely affected by salt stress, on the other hand. Recent advances have highlighted the fascinating regulatory mechanisms of K＋ and Na＋ transport and signaling in plants. This review summarizes three major topics： （i） the transport mechanisms of K＋ and Na＋ from the soil to the shoot and to the cellular - compartments; （ii） the mechanisms through which plants sense and respond to K＋ and Na＋ availability; and （iii） the components involved in maintenance of K＋/Na＋ homeostasis in plants under salt stress.     

Effects of calcium on the gramicidin A single channel in phosphatidylserine membranes

In phosphatidylserine membranes the decrease in the conductance of the gramicidin A single channel caused by calcium is attributed to a reduction of surface potential and to a direct blocking of the pore (Apell et al. 1979).The aim of this paper is to make a, quantitative evaluation of these two effects. We recorded the conductance of gramicidin single channels in 100 mM KCl in the presence of different amounts of CaCl₂, MgCl₂ or TEACl.The ionic activities at the channel mouth were calculated using the Gouy-Chapman-Stern theory. Our experiments showed that even when the K⁺ activity at the channel mouth was estimated to be the same, the single channel conductance was lower if divalent cations were present. This effect is attributed to a blocking action of these ions.Abbreviations PS phosphatidylserine - TEA tetraethylammonium     

Furosemide-sensitive sodium and potassium fluxes in human neonatal erythrocytes

During the course of incubation, in vitro, in a saline medium, we found an increase of cell volume and Na+ content in human neonatal erythrocytes (NNE), from the umbilical cord. The increased cell volume was dependent on the major anion in the medium in that replacement of Cl- by NO-3 abolished the cell volume increase. In erythrocytes from adults neither the cell volume nor the sodium content were altered under similar incubation conditions. Furosemide-sensitive Na+ and K+ fluxes were at variance from those reported from adult erythrocytes. The differences here presented between both cell types would be another instance of changes observed to occur in erythrocytes during the postnatal period.     

The effects of sodium and potassium on ouabain binding by human erythrocytes

Ouabain binding by the human erythrocyte membrane is reversible, exhibits a high degree of chemical specificity, and can be detected at ouabain concentrations as low as 1 x 10^-10 M. The relation between ouabain binding and ouabain concentration can be described by a rectangular hyperbola permitting determination of the maximal binding (B _max) and the ouabain concentration at which ouabain binding is half-maximal (K_B). Reducing the external sodium concentration increased K_B, while reducing the external potassium concentration decreased K_B. Neither cation altered B _max The reciprocal of K_B was a linear function of the sodium concentration at sodium concentrations ranging from 0 to 150 mM. Conversely, the relation between the reciprocal of K_B and the external potassium concentration was nonlinear, and raising the potassium concentration above 4 mM produced no further increase in K_B. These results are compatible with a model which postulates that the erythrocyte membrane contains a finite number of receptors each composed of a glycoside-binding site and a cation-binding site. When sodium occupies the cation-binding site, the affinity of the glycoside site for ouabain is increased; when potassium occupies the cation-binding site the affinity of the glycoside site for ouabain is decreased.     

Conformational studies on the gramicidin A transmembrane channel in lipid micelles and liposomes

The interaction of gramicidin A with lysolecithin micelles and with lecithin liposomes is demonstrated by circular dichroism to result in several metastable conformational states. A stable state can be obtained after extensive heating when the gramicidin A was added dry or in ethanol solution to the phospholipid dispersion but the stable state is readily obtained when gramicidin A is added in a trifluoroethanol solution. The circular dichroism of the stable conformational state is characterized by negative ellipticity below 205 nm and principally by a positive 220 nm band on which is superposed a weak 230 nm band (the latter likely arising from tryptophan side chains). The stable conformational state is considered to be that of the functional transmembrane channel primarily on the basis of extensive studies on its interaction with sodium ions.     

Effects of anesthetic alcohols on membrane transport processes in human erythrocytes

1. 1. Anesthetic alcohols (pentanol, hexanol and heptanol) were found to increase the fluidity of red cell membrane lipids as monitored by the fluorescence depolarization of diphenylhexatriene. The relative potency of the alcohols was found to be parallel to their relative membrane/water partition coefficients.

2. 2. Hexanol had biphasic effect on erythritol uptake by simple diffusion by red cells. At concentrations less than 9 mM, hexanol had no significant effect. At concentrations greater than 9 mM, there was an approximately linear increase in erythritol permeability with increasing alcohol concentration.

3. 3. The facilitated transport of uridine was markedly inhibited by hexanol. Hexanol at 6 mM produced a 65% inhibition of uridine (4 mM) uptake. Hexanol decreased both the apparent K_m and V values for the equilibrium exchange of uridine.

4. 4. The facilitated transport of galactose was only slightly inhibited by hexanol.

5. 5. Hexanol was without effect on the passive and active fluxes of Na⁺ and K⁺ in red cells with altered cation contents. Cells that were slightly depleted of K⁺ and cells that were highly K⁺-depleted were both insensitive to hexanol.

Effects of some antibiotics on glutathione reductase activities from human erythrocytes in vitro and from rat erythrocytes in vivo

The effects of streptomycin sulfate, gentamicin sulfate, thiamphenicol, penicillin G, teicoplanin, ampicillin, cefotaxime, and cefodizime on the enzyme activity of glutathione reductase (GR) were studied using human and rat erythrocyte GR enzymes in in vitro and in vivo studies, respectively. The enzyme was purified 5,342-fold from human erythrocytes in a yield of 29% with 50.75?U/mg. The purification procedure involved the preparation of hemolysate, ammonium sulfate precipitation, 2′,5′-ADP Sepharose 4B affinity chromatography and Sephadex G-200 gel filtration chromatography. Purified enzyme was used in the in vitro studies, and rat erythrocyte hemolysate was used in the in vivo studies. In the in vitro studies, I₅₀ and K_i values were 12.179?mM and 6.5123±4.1139?mM for cefotaxime, and 1.682?mM and 0.7446±0.2216?mM for cefodizime, respectively, showing the inhibition effects on the purified enzyme. Inhibition types were noncompetitive for cefotaxime and competitive for cefodizime. In the in vivo studies, 300?mg/kg cefotaxime and 1000?mg/kg cefodizime when administered to rats inhibited enzyme activity during the first 2?h (p<0.01). Cefotaxime led to increased enzyme activity at 4?h (p<0.05), but neither cefotaxime nor cefodizime had any significant inhibition or activation effects over 6?h (p>0.05).     

Effects of long-chain acyl carnitine on membrane fluidity of human erythrocytes

Amphiphilic compounds such as long-chain acyl carnitines accumulate in ischemic myocardium and potentially contribute to the myocardial damage. To characterize alterations in membrane molecular dynamics produced by palmitoylcarnitine, human erythrocytes were spin-labeled with 5-doxylstearic acid, and membrane fluidity was quantified by measuring the changes in the order parameter derived from ESR spectra. Palmitoylcarnitine induced triphasic alterations in membrane fluidity of human erythrocytes. The membrane fluidity increased for 5 min, then decreased in a concentration-dependent manner. At higher concentrations (100 and 150 μM) of palmitoylcarnitine, membrane fluidity increased again after 30 and 20 min of the incubation, respectively. Addition of 2.8 mM CaCl₂ resulted in a significant decrease in membrane fluidity and enhanced the alterations in membrane fluidity caused by palmitoylcarnitine. The results suggest that alterations in molecular dynamics are one mechanism through which long-chain acyl carnitine could play an important role in ischemic injury.