[Effect of inorganic fluorine on living organisms of different phylogenetic level].

The presented review summarizes literature data on pathways of the inorganic fluoride intake into the plant, animal, and human organisms, on its metabolism, distribution, and accumulation in the organism, forms of fluoride in biological tissues, toxic effects of fluoride on physiological and reproductive functions of living organisms of various phylogenetic groups, as well as clinical symptoms of deficient and excessive fluoride intake into the human organism.

Effects of phorbol 12-myristate 13-acetate on potassium transport in the red blood cells of frog Rana temporaria.

Phorbol 12-myristate 13-acetate (PMA), a stimulator of PKC, was examined for its influence on K(+) ((86)Rb) influx in the frog erythrocyte. PMA, 0.1 microM, was found to accelerate ouabain-sensitive K(+) influx, which was suppressed by 73% with 1 mM amiloride, indicating secondary activation of the Na(+)-K(+)-pump due to stimulation of Na(+ )/H(+) exchange. PMA-induced stimulation of the sodium pump was completely inhibited with 1 microM staurosporine and by approximately 50% with 20 microM chelerythrine. In contrast to Na(+)-K(+)-pump, an activity of Cl(-)-dependent K(+) transport (K-Cl cotransport, KCC), calculated as the difference between K(+) influxes in Cl(-) and NO(3) (-)-media, was substantially decreased under the influence of PMA. Staurosporine fully restored the PMA-induced inhibition of KCC, whereas chelerythrine did not exert any influence. Osmotic swelling of the frog erythrocytes was accompanied by approximately twofold stimulation of KCC. Swelling-activated KCC was inhibited by approximately 50 and approximately 83% in the presence of PMA and genistein, respectively, but not chelerythrine. Exposure of the frog erythrocytes to 5 mM fluoride (F(-)) also reduced the KCC activity in isotonic and hypotonic media, with maximal suppression of K(+) influx in both media being observed upon simultaneous addition of PMA and F(-). Furosemide and [(dihydronindenyl)oxy] alkanoic acid inhibited the K(+) influx in both the media by approximately 50-60%. The results obtained show both the direct and indirect effects of PMA on the K(+) transport in frog erythrocytes and a complicated picture of KCC regulation in frog erythrocytes with involvement of PKC, tyrosine kinase and protein phosphatase.

[Kinetic properties of sodium transport pathways in the river lamprey Lampetra fluviatilis erythrocytes].

To activate Na+/H+ exchange, intracellular pH (pHi) of erythrocytes of the river lamprey Lampetra fluviatilis were changed from 6 to 8 using nigericin. The Na+/H+ exchanger activity was estimated from the values of amiloride-sensitive components of Na+ (22Na) inflow or of H+ outflow from erythrocytes. Kinetic parameters of the carrier functioning were determined by using Hill equation. Dependence of Na+ and H+ transport on pHi value is described by hyperbolic function with the Hill coefficient value (n) close to 1. Maximal rate of ion transport was within the limits of 9-10 mmol/l cells/min, and the H+ concentration producing the exchanger 50% activation amounted to 0.6-1.0 microM. Stimulation of H+ outcome from acidified erythrocytes (pHi 5.9) with increase of H+ concentration in the incubation medium is described by Hill equation with n value of 1.6. Concentration of Na+: for the semimaximal stimulation of H+ outcome amounted to 19 mM. The obtained results indicate the presence in lamprey erythrocytes of only one binding site for H+ from the cytoplasm side and the presence of positive cooperativity in Na+ binding from the extracellular side of the Na+/H+ exchanger. Its efflux from cells in the Na+ -free medium did not change at a 10-fold increase of H+ concentration in the incubation medium. The presented data indicate differences of kinetic properties of the lamprey erythrocyte Na+/H+ exchanger and of this carrier isoforms in mammalian cells. In intact erythrocytes the dependence of the amiloride-sensitive Na+ inflow on its concentration in the medium is described by Hill equation with n 1.5. The Na+ concentration producing the 50% transport activation amounted to 39 mM and was essentially higher as compared with that in acidified erythrocytes. These data confirm the concept of the presence of two amiloride-sensitive pathways of Na+ transport in lamprey erythrocytes.

Amiloride-sensitive sodium transport in lamprey red blood cells: evidence for two distinct transport pathways.

To determine Na+/H+ exchange in lamprey erythrocyte membranes, the cells were acidified to pH(i) 6.0 using the K+/H+ ionophore nigericin. Incubation of acidified erythrocytes in a NaCl medium at pH 8.0 caused a considerable rise in 22Na+ influx and H+ efflux during the first 1 min of exposure. In addition, exposure of acidified red cells to NaCl medium was associated with rapid elevation of intracellular Na+ content. The acid-induced changes in Na+ influx and H+ efflux were almost completely inhibited by amiloride and dimethylamiloride. In native lamprey erythrocytes, amiloride-sensitive Na+ influx progressively increased as the osmolality of incubation medium was increased by addition of 100, 200, or 300 mmol/l sucrose. Unexpectedly, the hypertonic stress induced a small, yet statistically significant decrease in intracellular Na+ content in these cells. The reduction in the cellular Na+ content increased with hypertonicity of the medium. The acid- and shrinkage-induced Na+ influxes were inhibited by both amiloride and 5-(N-ethyl-N-isopropyl)-amiloride (EIPA) in a dose-dependent manner. For both blockers, the half-maximal inhibitory values (IC50) were much greater for the shrinkage-induced (44 and 15 micromol/l for amiloride and EIPA, respectively) than for the acid-induced Na+ influx (5.1 and 3.3 micromol/l, respectively). The data obtained are the first demonstration of the presence of a Na+/H+ exchanger with high activity in acidified (pH(i) 6.0) lamprey red blood cells (on average, 512 +/- 56 mmol/l cells/h, n = 13). The amiloride-sensitive Na+ influxes produced by hypertonic cell shrinkage and acid load are likely to be mediated by distinct ion transporters in these cells.

Activation of Na+/H+ exchange by protein phosphatase inhibitors in red blood cells of the frog Rana ridibunda.

The present study was designed to evaluate the role of protein phosphatases in regulation of sodium transport in the marsh frog erythrocytes using 22Na as a tracer. For this purpose the cells were treated with several known inhibitors of protein phosphatases. In standard isotonic medium, exposure of the cells to 10 mmol l(-1) NaF, 20 nmol l(-1) calyculin A or 0.1 mmol l(-1) cantharidin resulted in a significant (1.7-fold) increase in unidirectional ouabain-insensitive Na+ influx. The Na+ influx in frog red cells was progressively activated as the medium osmolality was increased by addition of 100, 200 or 300 mmol l(-1) sucrose to standard isotonic medium. The stimulatory effect of protein phosphatase blockers on Na+ influx was much higher in hypertonic medium containing 100 or 200 mmol l(-1) sucrose than that in isotonic medium. Stimulation of Na+ transport enhanced with increasing concentrations of calyculin A, and half-maximal activation (EC50) was obtained at 16 nmol l(-1). However, Na+ influx induced by strong hypertonic treatment (+300 mmol l(-1) sucrose) was not altered further in the presence of protein phosphatase inhibitors. The changes in Na+ influx evoked by protein phosphatase inhibitors and hypertonic treatment were associated with a rise in the intracellular Na+, but not K+, content. Enhancement in Na+ influx after addition of protein phosphatase blockers to cell suspension in isotonic or hypertonic media was almost completely inhibited by Na+/H+ exchange inhibitors, amiloride and ethyl-isopropyl-amiloride. The basal Na+ influx in frog erythrocytes in isotonic medium was relatively low (1.7 mmol/l cells/h) and not affected by 1 mmol l(-1) amiloride. Thus, the data obtained clearly indicate that Na+/H+ exchanger in the marsh frog red blood cells is under tight regulatory control, in all likelihood via protein phosphatases of types PP-1 and PP-2A.

Activation of potassium channels in erythrocytes of marine teleost Scorpaena porcus.

To assess the possibility of stimulating Ca2+-activated K+ channels, marine fish erythrocytes were incubated at 20-22 degrees C in saline containing a Ca2+-ATPase inhibitor (orthovanadate), a Ca2+ ionophore (A23187), propranolol or Pb2+. Incubation of the cells for up to 2 h under control conditions or in the presence of 5 mM NH4VO3 and 1 mM Ca2+ did not affect the intracellular K+ and Na+ concentrations. About 50% cellular K+ was lost from erythrocytes incubated in the presence of 0.01 mM A23187, 1 mM EGTA and 0.4-1.0 mM Ca2+. There was a significant loss of cellular K+ after the addition of 0.05-0.2 mM propranolol to the incubation medium. The stimulatory effect of propranolol on the K+ efflux was independent of external Ca2+. Blockers of Ca2+ transport, verapamil and Co2+, caused only a small decrease in the K+ loss induced by propranolol. The treatment of erythrocytes with 1-2 microM Pb2+ led to a minor K+ loss, but at a Pb2+ concentration of 20-50 microM, about 70% cellular K+ was lost. The K+ efflux induced by propranolol or Pb2+ was completely blocked by 1 mM quinine. The induced K+ loss from the erythrocytes was accompanied by a slight increase in the intracellular Na+ concentration. These data indicate the possibility of inducing Ca2+- and Pb2+-activated potassium channels in erythrocytes of S. porcus. A distinctive feature of the cells is a high sensitivity to propranolol, which activates K+ channels in the absence of external Ca2+.

Effects of fluoride and vanadate on K+ transport across the erythrocyte membrane of Rana temporaria.

K-Cl cotransport activity in frog erythrocytes was estimated as a Cl- -dependent component of K+ efflux from cells incubated in Cl- - or NO3- -containing medium at 20 degrees C. Decreasing the osmolality of the medium resulted in an increase in K+ efflux from the cells in a Cl- medium but not in an NO3- medium. Treatment of red cells with 5 mM NaF caused a significant decrease (approximately 50%) in K+ loss from the cells in iso- and hypotonic Cl- media but only a small decrease in K+ loss in isotonic NO3- medium. Addition of 1 mM vanadate to an isotonic Cl- medium also led to a significant reduction in K+ efflux. Similar inhibitory effects of NaF and vanadate on K+ efflux in a Cl- medium, but not in an NO3- medium were observed when the incubation temperature was decreased from 20 to 5 degrees C. Thus, under various experimental conditions, NaF and vanadate inhibited about 50% of Cl- -dependent K+ efflux from frog red cells probably due to inhibition of protein phosphatases. Cl- -dependent K+ (86Rb) influx into frog erythrocytes was nearly completely blocked (approximately 94%) by 5 mM NaF. In a NO3- medium, K+ influx was mainly mediated by the Na+,K+ pump and was unchanged in the presence of 5 mM NaF, 0.03 mM Al3+ or their combination. These data indicate that G proteins or cAMP are not involved in the regulation of Na+,K+ pump activity which is activated by catecholamines and phosphodiesterase blockers in these cells.

Kinetics of K-Cl cotransport in frog erythrocyte membrane: effect of external sodium.

In frog red blood cells, K-Cl cotransport (i.e., the difference between ouabain-resistant K fluxes in Cl and NO(3)) has been shown to mediate a large fraction of the total K(+) transport. In the present study, Cl(-)-dependent and Cl(-)-independent K(+) fluxes via frog erythrocyte membranes were investigated as a function of external and internal K(+) ([K(+)](e) and [K(+)](i)) concentration. The dependence of ouabain-resistant Cl(-)-dependent K(+) ((86)Rb) influx on [K(+)](e) over the range 0-20 mm fitted the Michaelis-Menten equation, with an apparent affinity (K(m)) of 8.2 +/- 1.3 mm and maximal velocity (V(max)) of 10.4 +/- 1.6 mmol/l cells/hr under isotonic conditions. Hypotonic stimulation of the Cl(-)-dependent K(+) influx increased both K(m) (12.8 +/- 1.7 mm, P < 0.05) and V(max) (20.2 +/- 2.9 mmol/l/hr, P < 0.001). Raising [K(+)](e) above 20 mm in isotonic media significantly reduced the Cl(-)-dependent K(+) influx due to a reciprocal decrease of the external Na(+) ([Na(+)](e)) concentration below 50 mm. Replacing [Na(+)](e) by NMDG(+) markedly decreased V(max) (3.2 +/- 0.7 mmol/l/hr, P < 0.001) and increased K(m) (15.7 +/- 2.1 mm, P < 0.03) of Cl(-)-dependent K(+) influx. Moreover, NMDG(+) Cl substitution for NaCl in isotonic and hypotonic media containing 10 mm RbCl significantly reduced both Rb(+) uptake and K(+) loss from red cells. Cell swelling did not affect the Na(+)-dependent changes in Rb(+) uptake and K(+) loss. In a nominally K(+)(Rb(+))-free medium, net K(+) loss was reduced after lowering [Na(+)](e) below 50 mm. These results indicate that over 50 mm [Na(+)](e) is required for complete activation of the K-Cl cotransporter. In nystatin-pretreated cells with various intracellular K(+), Cl(-)-dependent K(+) loss in K(+)-free media was a linear function of [K(+)](i), with a rate constant of 0.11 +/- 0.01 and 0.18 +/- 0.008 hr(-1) (P < 0.001) in isotonic and hypotonic media, respectively. Thus K-Cl cotransport in frog erythrocytes exhibits a strong asymmetry with respect to transported K(+) ions. The residual, ouabain-resistant K(+) fluxes in NO(3) were only 5-10% of the total and were well fitted to linear regressions. The rate constants for the residual influxes were not different from those for K(+) effluxes in isotonic ( approximately 0. 014 hr(-1)) and hypotonic ( approximately 0.022 hr(-1)) media, but cell swelling resulted in a significant increase in the rate constants.

Copper effects on ion transport across lamprey erythrocyte membrane: Cl(-)/OH(-) exchange induced by cuprous ions.

We studied the effects of prelytic copper concentrations on cell volume, intracellular pH, and ion transport in lamprey erythrocytes. Ion fluxes and pH were measured by radioactive tracer technique, patch clamp, and flame photometry. Prelytic CuSO(4) concentration of 100 microM caused anion-dependent intracellular acidification and increase in Cl(-) influx after 2 min lag-phase. In the presence of ascorbate copper effect was amplified and lag-phase was skipped. Pretreatment of the cells with N-phenyl maleimide abolished copper-induced changes completely. Copper treatment caused an increase in Na(+) fluxes in both directions and a net Na(+) uptake. Copper-induced Na(+) transport was partially amiloride(MIA)-sensitive representing Na(+)/H(+) exchange. The nature of the amiloride-insensitive fraction of copper-activated Na(+) influx remains unknown. Cell swelling after 15 min of copper exposure induced regulatory volume decrease response involving KCl extrusion via K(+) and Cl(-) volume-sensitive channels. We suggest that the effects of copper on ion transport fit the following sequence of events: (i) cupric ions are reduced to cuprous state on the membrane surface, (ii) electroneutral pairs CuCl and CuOH mediate chloride/hydroxyl exchange, as shown before for trialkyltin, dissipating transmembrane pH gradient, and (iii) changes in intracellular pH result in the activation of the Na(+)/H(+) exchange and consecutive volume changes cause the RVD response.

Inhibition and stimulation of K+ transport across the frog erythrocyte membrane by furosemide, DIOA, DIDS and quinine.

Frog erythrocytes were incubated in iso- or hypotonic media containing 10 mmol/l Rb+ and 0.1 mmol/l ouabain and both Rb+ uptake and K+ loss were measured simultaneously. Rb+ uptake by frog red cells in iso- and hypotonic media was reduced by 30-60% in the presence of 0.01-0.1 mmol/l [(dihydroindenyl)oxy] alkanoic acid (DIOA) or 0.5-1.0 mmol/l furosemide. Furosemide inhibited K+ loss from frog erythrocytes incubated in hypotonic media but did not affect it in isotonic media. DIOA at a concentration of 0.05 mmol/l inhibited of K+ loss from frog erythrocytes in both iso- and hypotonic media. At the concentrations of 0.01 and 0.02 mmol/l DIOA significantly suppressed K+ loss in a K+-free chloride medium but not in a K+-free nitrate medium. The Cl(-)-dependent K+ loss was completely blocked at a concentration of 0.1 mmol/l DIOA and the concentration required for 50% inhibition of K-Cl cotransport was approximately 0.015 mmol/l. However, the inhibitory effect of DIOA on K-Cl cotransport was masked by an opposite stimulatory effect on K+ transport which was also observed in nitrate medium. Quinine in a concentration of 0.2-1.0 mmol/l was able to inhibit Rb+ uptake and K+ loss only in hypotonic media. In isotonic media, quinine produced a stimulation of Rb+ uptake and K+ loss. A three to five-fold activation of Rb+ uptake and K+ loss was consistently observed in frog erythrocytes treated with 0.05-0.2 mmol/l 4,4'-diisothiocyanatostilbene-2,2'-disulphonic acid (DIDS). In contrast, another stilbene derivative 4-acetamido-4'-isothiocyanatostilbene-2,2'-disulphonic acid (SITS) had no effect on K+ transport in the cells. Thus, of these drugs tested in the present study only DIOA at low concentrations may be considered as a selective blocker of the K-Cl cotransporter in the frog red blood cells.

Chloride transport in red blood cells of lamprey Lampetra fluviatilis: evidence for a novel anion-exchange system.

The existence of a furosemide-sensitive Cl- transport pathway activated by external Ca2+ and Mg2+ has been demonstrated previously in studies of Cl- influx across the lamprey erythrocyte membrane. The aim of the present study was to characterize further specific Cl- transport pathways, especially those involved in Cl- efflux, in the red blood cell membrane of Lampetra fluviatilis. Cl- efflux was inhibited by 0.05 mmol l-1 dihydroindenyloxyalkanoic acid (DIOA) (81%), 1 mmol l-1 furosemide (76%) and 0.1 mmol l-1 niflumic acid (54%). Bumetanide (100 mumol l-1) and DIDS (100 mumol l-1) had no effect effect on Cl- efflux. Substitution of external Cl- by gluconate, but not by NO3-, led to a gradual decline of Cl- efflux. In addition, the removal of external Ca2+ resulted in a significant reduction in the rate of Cl- efflux. Membrane depolarization caused by increasing external K+ concentration or by inhibiting K+ channels with 1 mmol l-1 Ba2+ did not affect Cl- efflux. The furosemide-sensitive component of Cl- influx was a saturable function of external [Cl-] with an apparent K(m) of approximately 92 mmol l-1 and Vmax of approximately 17.8 mmol l-1 cells-1 h-1. Furosemide did not affect intracellular Cl- concentration (57.6 +/- 5.2 mmol l-1 cell water), measured using an ion-selective Cl- electrode, showing that a furosemide-sensitive pathway is not involved in net Cl- movement. A gradual fall (from 28.1 +/- 1.4 to 15.0 +/- 1.3 mmol l-1 cells-1 h-1) in unidirectional Cl- influx with time was observed within 3 h of cell preincubation in the standard physiological medium. These data provide evidence for the existence for an electroneutral furosemide-sensitive anion-exchange pathway in the lamprey erythrocyte membrane that accepts chloride and nitrate, but not bicarbonate or bromide.

Differential effects of glycolytic and oxidative metabolism blockers on the Na-K pump in erythrocytes of the frog, Rana temporaria.

This study was undertaken to evaluate the effects of various metabolic blockers on the Na-K-pump activity and ATP content of frog erythrocytes. To eliminate K-Cl cotransport, the frog erythrocytes were incubated in nitrate media at 20 degrees C. Incubation of the red cells in a glucose-free medium for 2 h had no effect on cell ATP content and K+ influx measured as 86Rb uptake for 60 min. The Na(+)-K(+)-pump activity was also unchanged in the frog erythrocytes incubated in a glucose-free medium containing 10 mM 2-deoxy-D-glucose or adenosine. Unexpectedly, the treatment of red cells with 1-2 mM glycolytic blocker iodoacetate produced a 2-fold increase in the ouabain-sensitive K+ influx. The cell ATP content declined by 9.4% after 2 h of cell incubation with iodoacetate. Incubation of the red cells for 90 min in the presence of 2 mM cyanide, 0.01 mM antimycin A or 5 mM azide resulted in a significant reduction in K+ influx by about 50%, 45% and 32%, respectively. The cell ATP content diminished over 60 min and 120 min of cell incubation with 2 mM cyanide by 15.6% and 31.7% of control levels, respectively. In time-course experiments, a 50% reduction in the K+ influx was observed when the frog erythrocytes were incubated for only 30 min in the presence of 2 mM cyanide. In contrast, 0.01-0.10 mM rotenone, a site I inhibitor, and 0.01 mM carbonyl cyanide m-chlorophenylhydrazone, an uncoupler of oxidative phosphorylation were without effect on K+ influx into frog erythrocytes. These results indicate that about one-half of the Na(+)-K(+)-pump activity in frog erythrocytes is tightly functionally coupled to cytochromes via a separate "membrane-associated" ATP pool.

Temperature effects on ion transport across the erythrocyte membrane of the frog Rana temporaria.

Unidirectional K+ and Na+ influxes in the frog erythrocytes incubated in Cl- or NO(3)- media with 2.7 mM K+ were measured using 86Rb and 22Na as tracers. K+ influx was inhibited by 35-55% in the presence of 0.2-1.0 mM furosemide but it was unaffected by 0.1-0.2 mM bumetanide. Furosemide at a concentration of 0.5 mM had no effect on K+ loss from the frog red cells incubated in a nominally K(+)-free medium. Together with our previous studies the data support the existence of K-Cl cotransport and the absence of Na-K-2Cl cotransport in the frog erythrocyte membrane. Cell cooling from 20 to 5 degrees C caused a decrease in K+ influx and K+ efflux via the K-Cl cotransporter (3.2- and 3.7-fold, respectively) giving an apparent energy of activation (EA) of about 60 kJ/mol and Q10 value of 2.5. Only small decline (approximately 30%) in the ouabain-sensitive K+ influx was found as temperature was changed from 20 to 5-10 degrees C. Low values of Q10 (approximately 1.5) and EA (27.3 kJ/mol) were obtained for passive K+ influx in the frog erythrocytes (ouabain-insensitive in NO(3)- medium) at temperature within 5-20 degrees C. However, the temperature coefficients were greater for passive Na+ influx and passive K+ efflux (Q10 approximately 2.4-2.5 and EA approximately 56-58 kJ/mol). The temperature dependence of all ion transport components displayed discontinuities showing no changes at temperature between 5 and 10 degrees C. Thus, cooling of the frog red cells is associated with a greater decrease of Na+ influx and K+ efflux than passive and active K+ influx. These data indicate that the preservation of a relative high activity of the Na,K-pump during cell cooling and also the temperature-induced changes in the K-Cl cotransport activity and ion passive diffusion contribute to maintenance of ion concentration gradients in the frog erythrocytes at decreased temperature.