Heterologous expression of Pharaonis halorhodopsin in Xenopus laevis oocytes and electrophysiological characterization of its light-driven Cl- pump activity

Natronomonas pharaonis halorhodopsin (pHR) is an archaeal rhodopsin functioning as an inward-directed, light-driven Cl- pump. To characterize the electrophysiological features of the Cl- pump activity of pHR, we expressed pHR in Xenopus laevis oocytes and analyzed its photoinduced Cl- pump activity using the two-electrode voltage-clamp technique. Photoinduced outward currents were observed only in the presence of Cl-, Br-, I-, NO3-, and SCN-, but not in control oocytes, indicating that photoinduced anion currents were mediated by pHR. The relationship between photoinduced Cl- current via pHR and the light intensity was linear, demonstrating that transport of Cl- is driven by a single-photon reaction and that the steady-state current is proportional to the excited pHR molecule. The current-voltage relationship for pHR-mediated photoinduced currents was also linear between -150 mV and +50 mV. The slope of the line describing the current-voltage relationship increased as the number of the excited pHR molecules was increased by the light intensity. The reversal potential (VR) for Cl- as the substrate for the anion pump activity of pHR was about -400 mV. The value for VR was independent of light intensity, meaning that the VR reflects the intrinsic value of the excited pHR molecule. The value of VR changed significantly for the R123K mutant of pHR. We also show that the Cl- pump activity of pHR can generate a substantial negative membrane potential, indicating that pHR is a very potent Cl- pump. We have also analyzed the kinetics of voltage-dependent Cl- pump activity as well as that of the photocycle. Based on these data, a kinetic model for voltage-dependent Cl- transport via pHR is presented.     

The Aplysia californica Cl- pump is a P-type ATPase: evidence through inhibition studies

Utilizing a proteoliposomal preparation containing Cl(-)-ATPase from Aplysia californica foregut, it was shown that orthovanodate inhibited Cl(-)-ATPase activity, ATP-dependent Cl- transport, ATP-dependent membrane potential change and ATP-dependent phosphorylation. N-ethylmalemide and p-chloromercurobenzoate also inhibited the Cl- pump biochemical and physiological transport characteristics. However, bafilomycin, azide, N, N'-dicyclohexylcarboiimide (DCCD), and efrapeptin had no effect on the Cl- pump biochemical or physiological characteristics, suggesting that this Cl- pump was a P-type ATPase. It was concluded that this P-type ATPase Cl- pump is the mechanism that is responsible for the net absorptive flux of Cl- in the A. californica foregut.     

Electrogenic Cl- pump in Acetabularia

Measurements of this transmembrane potential difference (V) under various conditions have demonstrated the operation of an electrogenic Cl- pump in the outer plasma membrane (plasmalemma) of the unicellular marine alga Acetabularia. In preparations of partly purified membranes (containing plasmalemma), there is Cl- stimulated, N,N'-dicyclohexylcarbodiimide-insensitive, vanadate-sensitive ATPase activity with a pH optimum around pH 6.5. These properties are consistent with the assumption that the electrogenic Cl- pump is an ATPase. In order to investigate electrical details of the "Mitchellian" type of charge-translocating enzyme, steady-state current-voltage curves of the electrogenic pump (Ip(V)) were measured in vivo under dark and light conditions and analysed by two-state reaction kinetic model. This model with the resulting parameters predicts V-sensitive, undirectional Cl- effluxes through the pump. The predictions of this model agree with the experimental results. Green light causes a fast decrease of V, which is explained as a disturbance of the pump cycle. Relaxation studies on this effect and reaction kinetic analysis of Ip(V) under different external Cl- concentrations are used to develop a consistent three-state model of the pump that includes the order of and absolute rate constants of individual reactions, states of charge, stoichiometry, voltage-sensitivity and density of the pump molecules in the membrane.     

Proton pump-generated electrochemical gradients in rat liver multivesicular bodies. Quantitation and effects of chloride

Endocytic vesicles possess an electrogenic proton pump, and measurements of ATPase activity suggest that Cl- may stimulate proton pump activity. This study was undertaken to measure the steady-state pH, potential (delta psi), and total proton electrochemical gradients established by the rat liver multivesicular body (MVB) proton pump and to examine the effects of Cl- (0.5-140 mM) on these gradients. Radiolabeled [( 14C] methylamine and 36Cl-) and fluorescent (fluorescein isothiocyanate-conjugated low density lipoproteins) probes were used to assess internal pH (pHi) and delta psi. In the absence of ATP, pHi averaged 7.37 +/- 0.05 (extracellular pH 7.31 +/- 0.02), and delta psi ranged from -32 to -71 mV; but neither pHi nor delta psi varied consistently with [Cl-]. In the presence of ATP, pHi decreased progressively with increasing [Cl-] to a plateau value of about 5.89 at greater than or equal to 25 mM Cl-, and MVB exhibited an interior positive delta psi that was maximal at the lowest Cl- concentration (+65.5 mV) and decreased as medium Cl- increased. The total ATP-dependent proton electrochemical gradient (proton-motive force (delta p] averaged 118.0 +/- 4.3 mV and did not change in any consistent manner as [Cl-] varied almost 300-fold. However, initial rates of MVB acidification increased with increasing [Cl-]. These studies indicate that: (a) in the absence of ATP, isolated MVB exhibited a negative delta psi, probably a Donnan potential; (b) in the presence of ATP and at a [Cl-] similar to that in hepatocyte cytoplasm (25 mM), MVB pHi was 5.89, and delta psi was +9.6 mV; and (c) over the range of [Cl-] tested, the magnitudes of delta pH and delta psi were inversely related, apparently related to Cl- availability, but the ATP-dependent delta p did not vary. Therefore, it is concluded that Cl- increases the initial rate of vesicle acidification in MVB and also affects the relative chemical and electrical contributions of the steady-state proton pump-determined delta p. Cl-, however, does not alter steady-state delta p.     

Anion inhibition of the proton pump in rat liver multivesicular bodies

Rat liver multivesicular bodies (MVB), as well as other hepatic subcellular organelles, are acidified by an electrogenic ATP-dependent proton pump that requires Cl- for maximal acidification (Van Dyke, R. W., Hornick, C. A., Belcher, J., Scharschmidt, B. F., and Havel, R.J. (1985) J. Biol. Chem. 260, 11021-11026), suggesting that Cl- serves as a permeable charge-compensating anion. However, we have observed that NO3- is unable to substitute for Cl-. This study was undertaken therefore to examine more closely the effects of Cl- on MVB acidification and to determine whether NO3- and other anions interact with the proton pump. ATP-dependent vesicle acidification and membrane potential (psi) were measured using the fluorescent dyes acridine orange and Oxonol V (bis(3-phenyl-5-oxoisoxasol-4-yl)pentamethine oxonol), respectively. Cl- both stimulated acidification (Km = 23.2 +/- 4.2 mM) and decreased psi (IC50 = 3.4 +/- 0.6 mM) in a concentration-dependent, nonlinear fashion. In the presence of saturating Cl- (100 mM), however, NO3- (shown to be more permeable than Cl-) and the impermeant anions SO4(2-) and PO4(2-), inhibited both ATP-dependent acidification and psi in a concentration-dependent manner. Other anions, including gluconate and HCO3-, had no effect. The inhibitory effect of NO3- was reversible. Neither SO4(2-) nor PO4(2-) appeared to block Cl- movement across the vesicle membrane as assessed by the ability of Cl- to decrease an established psi. In additional experiments, the effects of anions on relaxation of a previously established pH gradient were measured. Compared to Cl- or gluconate, NO3- had no significant effect on pH gradient relaxation, even when MVB were preloaded with NO3-, indicating that rapid cycling of NO3-/HNO3 across the MVB membrane does not occur. The organic nitrate, isosorbide dinitrate, also inhibited both acidification and psi and, similar to NO3-, had no effect on pH gradient relaxation. By contrast, NO2- potently inhibited both MVB acidification and psi but also rapidly relaxed a pre-established pH gradient, suggesting that NO2- increases MVB membrane proton permeability. Finally, MVB exhibited N-ethylmaleimide-sensitive ATPase activity that was inhibited 23.9% by NO3- (100 mM). In conclusion, although MVB are permeable to a variety of anions (Cl-, Br-, NO3-, NO2-), only Cl- and Br- support maximal rates of acidification by the proton pump.(ABSTRACT TRUNCATED AT 400 WORDS)     

ATP-dependent and DCCD-insensitive Cl- uptake by membrane vesicles from the rat brain plasma membrane fractions

ATP-dependent Cl- uptake by membrane vesicles from the rat brain plasma membrane fractions was not affected by the addition of 40 mM of K+, Na+ or HCO3- to the assay medium. Na+ and K+ did not alter the uptake even in the presence of a K+ ionophore, valinomycin (10 microM), or a H+/K+ exchanger, nigericin (10 microM), whereas in the presence of both of these ionophores, K+, but not Na+, reduced the Cl- uptake. Inhibitors of proton pump activity, N,N'-dicyclohexylcarbodiimide (1 mM) and 5-(N,N-hexamethylene)amiloride (40 microM), however, did not affect the Cl- uptake. These findings suggest the presence of a primary Cl- transport system probably associated with passive H+ flux in the brain plasma membranes.     

Involvement of the cytoskeleton in the effect of PGE2 on ion transport in the rat distal colon

This work aimed at studying the effect of PGE2 on water and chloride absorption from the rat distal colon and at investigating the involvement of the cytoskeleton in the modulation of colonic transporters. PGE2 increased significantly net water and chloride absorption. It increased also the activity of the Na+K+-ATPase and the expression of the Na+K+2Cl- cotransporter. The increase in pump activity was ascribed to its phosphorylation by PKA or PKC when activated upon binding of PGE2 to its receptors, and was deemed responsible for the increase in Cl- absorption. Cytochalasin B (CytoB), a disrupter of microfilaments, decreased net water and chloride absorption in presence or absence of PGE2. Furthermore it down-regulated both pump and cotransporter, and lowered Na+K+-ATPase activity. It was suggested that an intact actin cytoskeleton is required for the basal and the PGE2-elicited trafficking of both transporters. On the other hand, colchicine, an inhibitor of microtubule polymerization, had no effect on the absorption of water and chloride but abrogated the stimulatory effect of PGE2. Colchicine exerted a similar effect to that of cytochlasin on the expression of both pump and cotransporter in presence or absence of PGE2 except for the basal activity of the pump which was not altered by microtubule disruption. It was concluded that both microfilament and microtubular networks are involved in the basal and PGE2-elicited increase in colonic ion absorption.     

Na+, K+, and Cl- transport in resting pancreatic acinar cells

To understand the role of Na+, K+, and Cl- transporters in fluid and electrolyte secretion by pancreatic acinar cells, we studied the relationship between them in resting and stimulated cells. Measurements of [Cl-]i in resting cells showed that in HCO3(-)-buffered medium [Cl- ]i and Cl- fluxes are dominated by the Cl-/HCO3- exchanger. In the absence of HCO3-, [Cl-]i is regulated by NaCl and NaK2Cl cotransport systems. Measurements of [Na+]i showed that the Na(+)-coupled Cl- transporters contributed to the regulation of [Na+]i, but the major Na+ influx pathway in resting pancreatic acinar cells is the Na+/H+ exchanger. 86Rb influx measurements revealed that > 95% of K+ influx is mediated by the Na+ pump and the NaK2Cl cotransporter. In resting cells, the two transporters appear to be coupled through [K+]i in that inhibition of either transporter had small effect on 86Rb uptake, but inhibition of both transporters largely prevented 86Rb uptake. Another form of coupling occurs between the Na+ influx transporters and the Na+ pump. Thus, inhibition of NaK2Cl cotransport increased Na+ influx by the Na+/H+ exchanger to fuel the Na+ pump. Similarly, inhibition of Na+/H+ exchange increased the activity of the NaK2Cl cotransporter. The combined measurements of [Na+]i and 86Rb influx indicate that the Na+/H+ exchanger contributes twice more than the NaK2Cl cotransporter and three times more than the NaCl cotransporter and a tetraethylammonium-sensitive channel to Na+ influx in resting cells. These findings were used to develop a model for the relationship between the transporters in resting pancreatic acinar cells.     

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.     

TNF-alpha down-regulates the Na+-K+ ATPase and the Na+-K+-2Cl-cotransporter in the rat colon via PGE2

TNF-alpha is believed to play a pivotal role in the pathogenesis of inflammatory bowel diseases which have diarrhea as one of their symptoms. This work studies the effect of the cytokine on electrolyte and water movements in the rat distal colon using an intestinal perfusion technique and attempts to determine its underlying mechanism of action. TNF-alpha inhibited net water and chloride absorption, down-regulated in both surface and crypt colonocytes the Na+-K+-2Cl- cotransporter, and reduced the protein expression and activity of the Na+-K+ ATPase. Indomethacin up-regulated the pump and the cotransporter in surface cells but not in crypt cells, and in its presence, TNF-alpha could not exert its effect, suggesting an involvement of PGE2 in the cytokine action. The effect of TNF-alpha on the pump and symporter was studied also in cultured Caco-2 cells in isolation of the effect of other cells and tissues, to test whether the cytokine acts directly on intestinal cells. In these cells, TNF-alpha and PGE2 had a similar effect on the pump expression and activity as that observed in crypt cells but were without any effect on the Na+-K+-2Cl- cotransporter. It was concluded that the effect of the cytokine on colonocytes is mediated via PGE2. By inhibiting the Na+-K+ ATPase, it reduces the Na+ gradient needed for NaCl absorption, and by down-regulating the expression of the Na+-K+-2Cl- symporter, it reduces basolateral Cl- entry and luminal Cl- secretion. The inhibitory effect on absorption is more significant than the inhibitory effect on secretion resulting in a decrease in net electrolyte uptake and consequently in more water retention in the lumen.     

Phosphatidylinositol and PI-4-monophosphate recover amyloid beta protein-induced inhibition of Cl- -ATPase activity

The neuronal Cl- -ATPase/pump is a candidate for an outwardly directed active Cl- transport system, which requires phosphatidylinositol-4-monophosphate (PI4P) for its optimal activity. We previously reported that low concentrations (1-10 nM) of amyloid beta proteins (Abetas, Abeta1-42, Abeta25-35), the neurotoxic peptides in Alzheimer's disease, reduced Cl- -ATPase activity in cultured rat hippocampal neurons without any changes in the activities of Na+/K+-ATPase or anion-insensitive Mg(2+)-ATPase, and decreased PI, PIP, and PIP2 levels in neuronal plasma membranes (Journal of Neurochemistry 2001, 78, 569-579). In this study, we examined the effects of exogenously applied PI and PI4P on the Abeta25-35-induced changes in Cl- -ATPase activity, the intracellular concentration of Cl- ([Cl- ]i), and glutamate neurotoxicity using primary cultured rat hippocampal neurons. The Abeta decreased Cl- -ATPase activity to 47% of control and increased [Cl- ]i in hippocampal pyramidal cell-like neurons to a level 3 times higher than the control. The addition of PI (50-750 nM) or PI4P (50-150 nM) dose-dependently blocked the inhibitory effects of Abeta on Cl- -ATPase activity. High doses of PI (750 nM) and PI4P (100-150 nM) reduced Na+/K+-ATPase activity to 41% and 35% of control, respectively, but this inhibition was attenuated by the co-application of phosphatidylserine (PS, 1 micro M). PI or PI4P (75 nM each) reversed the Abeta-induced increase in [Cl-]i. In the Abeta-exposed culture, stimulation by glutamate (10 micro M, 10 min) resulted in an increase in DNA fragmentation and decreases in cell viability. Addition of PI or PI4P prevented the Abeta-induced aggravation of glutamate neurotoxicity. Thus, PI and PI4P were demonstrated to prevent Abeta-induced decreases in Cl- -ATPase activity and increases in neuronal [Cl- ]i in parallel with the attenuation of Abeta-induced aggravation of glutamate neurotoxicity.     

Tumor necrosis factor alpha down-regulates the Na+-K+ ATPase and the Na+-K+2Cl- cotransporter in the kidney cortex and medulla

The effect of TNF-alpha on the renal Na+-K+ pump and the Na+-K+2Cl- cotransporter was investigated in the rat. Animals were injected with the cytokine, and 4h later, a homogenate from the cortical and medullary tissues was prepared and used to assay the activity of the Na+-K+ ATPase and the protein expression of the pump and symporter. TNF-alpha reduced the activity and expression of the pump in both cortex and medulla, and its effect disappeared when animals were pre-treated with indomethacin, suggesting that TNF-alpha acts via PGE2. Higher levels of PGE2 were detected by enzyme immunoassay, in kidney tissues isolated from rats treated with PGE2, thus confirming this hypothesis. The cytokine also down-regulated the Na+-K+2Cl- cotransporter but this effect was not abrogated by indomethacin. PGE2, injected into animals, exerted a dose-dependent effect. Low doses did not have any effect on the two transporters in the cortex while high doses inhibited and down-regulated the pump and up-regulated the cotransporter. In the medulla low doses increased the activity and expression of the pump but down-regulated the cotransporter while high doses exerted an exactly opposite effect on the two transporters. It was concluded that the effect of TNF-alpha on the pump is mediated via PGE2 which is released at relatively high doses. The effect of the cytokine on the cotransporter is, however, independent of PGE2.     

An analytical model of ionic movements in airway epithelial cells.

A new mathematical model of ion movements in airway epithelia is presented, which allows predictions of ion fluxes, membrane potentials and ion concentrations. The model includes sodium and chloride channels in the apical membrane, a Na/K pump and a cotransport system for Cl- with stoichiometry Na+:K+:2Cl- in the basolateral membrane. Potassium channels in the basolateral membrane are used to regulate cell volume. Membrane potentials, ion fluxes and intracellular ion concentration are calculated as functions of apical ion permeabilities, the maximum pump current and the cotransport parameters. The major predictions of the model are: (1) Cl- concentration in the cell is determined entirely by the intracellular concentration of negatively charged impermeable ions and the osmotic conditions; (2) changes in intracellular Na+ and K+ concentrations are inversely related; (3) cotransport provides the major driving force for Cl- flux, increases intracellular Na+ concentration, decreases intracellular K+ concentration and hyperpolarizes the cell interior; (4) the maximum rate of the Na/K pump, by contrast, has little effect on Na+ or Cl- transepithelial fluxes and a much less pronounced effect on cell membrane polarization; (5) an increase in apical Na+ permeability causes an increase in intracellular Na+ concentration and a significant increase in Na+ flux; (6) an increase in apical Cl- permeability decreases intracellular Na+ concentration and Na+ flux; (7) assuming Na+ and Cl- permeabilities equal to those measured in human nasal epithelia, the model predicts that under short circuit conditions, Na+ absorption is much higher than Cl- secretion, in agreement with experimental measurements.     

PGE2 exerts dose-dependent opposite effects on net water and chloride absorption from the rat colon

This work investigated the effect of different doses of PGE2 on net water and Cl- absorption from the rat colon, using an in situ perfusion technique. PGE2 exerted opposite effects at different concentrations. Net water and Cl- absorption was significantly reduced at low doses with a minimum at 0.4 microg/100g BW, and significantly elevated at high doses with an observed maximal effect at 21 microg/100g BW. At low doses, PGE2 increased in superficial cells, the activity of the Na+-K+ ATPase and the protein expression of the Na+K+2Cl- cotransporter, but reduced them in crypt cells. Thus, the reduction in net water and Cl- absorption was ascribed to an increase in secretion by surface cells that masked absorptive processes. At high doses, PGE2 increased significantly the activity of the Na+-K+ ATPase in superficial cells only, and was without any effect on the protein expression of the cotransporter and the pump in both surface and crypt cells. The observed increase in net water and Cl- absorption was attributed in this case to an increase in absorptive processes with no effect on secretion.     

Na+,K+ pump and Na+-coupled ion carriers in isolated mammalian kidney epithelial cells: regulation by protein kinase C.

This review updates our current knowledge on the regulation of Na+/H+ exchanger, Na+,K+,Cl- cotransporter, Na+,Pi cotransporter, and Na+,K+ pump in isolated epithelial cells from mammalian kidney by protein kinase C (PKC). In cells derived from different tubule segments, an activator of PKC, 4beta-phorbol 12-myristate 13-acetate (PMA), inhibits apical Na+/H+ exchanger (NHE3), Na+,Pi cotransport, and basolateral Na+,K+ cotransport (NKCCl) and augments Na+,K+ pump. In PMA-treated proximal tubules, activation of Na+,K+ pump probably plays a major role in increased reabsorption of salt and osmotically obliged water. In Madin-Darby canine kidney (MDCK) cells, which are highly abundant with intercalated cells from the collecting duct, PMA completely blocks Na+,K+,Cl- cotransport and decreases the activity of Na+,Pi cotransport by 30-40%. In these cells, agonists of P2 purinoceptors inhibit Na+,K+,Cl- and Na+,Pi cotransport by 50-70% via a PKC-independent pathway. In contrast with MDCK cells, in epithelial cells derived from proximal and distal tubules of the rabbit kidney, Na+,K+,Cl- cotransport is inhibited by PMA but is insensitive to P2 receptor activation. In proximal tubules, PKC-induced inhibition of NHE3 and Na+,Pi cotransporter can be triggered by parathyroid hormone. Both PKC and cAMP signaling contribute to dopaminergic inhibition of NHE3 and Na+,K+ pump. The receptors triggering PKC-mediated activation of Na+,K+ pump remain unknown. Recent data suggest that the PKC signaling system is involved in abnormalities of dopaminergic regulation of renal ion transport in hypertension and in the development of diabetic complications. The physiological and pathophysiological implications of PKC-independent regulation of renal ion transporters by P2 purinoceptors has not yet been examined.     

K+ and Cl- uptake by cultured oligodendrocytes

Cultured oligodendrocytes take up K+ triggered by an increase in [K+]o. Simultaneously [Cl-]i increases in the majority of the oligodendrocytes. This KCl uptake, which is not furosemide sensitive, can be explained by the following model. The first event is the entry of Cl- into the cell driven by the discrepancy between the membrane and Cl- equilibrium potential. As a consequence of the movement of negative charge across the membrane, K+ is driven into the cell. The prerequisites of this model, a passive Cl- distribution at resting membrane potential and a Cl- conductance of the membrane were found to exist in most cultured oligodendrocytes. The chloride equilibrium potential (-61 mV, SD +/- 10 mV) was slightly more positive than the membrane potential (-64 +/- 8 mV). Since cell input resistance determined with two independent electrodes increased by 11% (SD +/- 0.07) when [Cl-]o was reduced to 10 mM, part of the membrane conductance appears to be mediated by Cl-. Differences between membrane potential and Cl- equilibrium potential therefore will lead to Cl- fluxes across the membrane. In contrast with oligodendrocytes, [Cl-]i in astrocytes is significantly increased (from 20 to 40 mM) above the equilibrium distribution owing to the activity of an inward directed Cl- pump; this suggests a different mechanism of K+ uptake in these cells.     

Evidence for active chloride accumulation in normal and denervated rat lumbrical muscle

Intracellular Cl- activity (aiCl) was measured with Cl(-)-sensitive microelectrodes in normal and denervated rat lumbrical muscle. In normal muscle bathed in normal Krebs solution, aiCl lay close to that predicted by the Nernst equation. The addition of 9-anthracene carboxylic acid, which blocks Cl- conductance, caused aiCl to increase far above that predicted by a passive distribution. Furosemide (10 microM) reversibly blocked this accumulation. After muscle denervation, aiCl progressively increased for 1-2 wk. The rise occurred in two stages. The initial stage (1-3 d after denervation) reflected passive Cl- accumulation owing to membrane depolarization. At later times, aiCl continued to increase, with no further change in membrane potential, which suggests an active uptake mechanism. This rise approximately coincided with the natural reduction in membrane conductance to Cl- that occurs several days after denervation. Na+ replacement, K+ replacement, and furosemide each reversibly blocked the active Cl- accumulation in denervated muscle. Quantitative estimates suggested that there was little difference between Cl- flux rates in normal and denervated muscles. The results can be explained by assuming that, in normal muscle, an active accumulation mechanism operates, but that Cl- lies close to equilibrium owing to the high membrane conductance to Cl-. The rise in aiCl after denervation can be accounted for by the membrane depolarization, the reduction in membrane Cl- conductance, and the nearly unaltered action of an inwardly directed Cl- "pump."     

Relationships between membrane lipids and ion transport in red blood cells of Dahl rats

Distinct changes of membrane lipid content could contribute to the abnormalities of ion transport that take part in the development of salt hypertension in Dahl rats. The relationships between lipid content and particular ion transport systems were studied in red blood cells (RBC) of Dahl rats kept on low- and high-salt diets for 5 weeks since weaning. Dahl salt-sensitive (SS/Jr) rats on high-salt diet had increased blood pressure, levels of plasma triacylglycerols and total plasma cholesterol compared to salt-resistant (SR/Jr) rats. Furthermore, RBC of SS/Jr rats differed from SR/Jr ones by increased content of total membrane phospholipids, but membrane cholesterol was not changed significantly. SS/Jr rats had higher RBC intracellular Na+ (Na(i)+) content and enhanced bumetanide-sensitive Rb+ uptake. RBC membrane content of cholesterol and phospholipids correlated positively with RBC Na(i)+ content, with the activity of Na+-K+ pump and Na+-K+-2Cl- cotransport and also with Rb+ leak. The content of phosphatidylserines plus phosphatidylinositols was positively associated with RBC Na(i)+ content, with the activity of Na+-K+ pump and Na+-K+-2Cl- cotransport and with Rb+ leak. The content of sphingomyelins was positively related to Na+-K+-2Cl- cotransport activity and negatively to ouabain-sensitive Rb+-K+ exchange. We can conclude that observed relationships between ion transport and the membrane content of cholesterol and/or sphingomyelins, which are known to regulate membrane fluidity, might participate in the pathogenesis of salt hypertension in Dahl rats.     

Subcellular localization of prostaglandin E2 binding sites in bovine adrenal medulla

Effect of changing [K+], [Na+] and [Cl-] in nutrient solution on potential difference (PD) and resistance was studied in bullfrog antrum with and without nutrient HCO3(-) but with 95% O2/5% CO2 in both cases. In both cases, changing from 4 to 40 mM K+ gave about the same initial PD maximum (anomalous response) which was followed by a decrease below control level. Latter effect was much less with zero than with 25 mM HCO3(-). Changing from 102 to 8 mM Na+ gave initial normal PD response about the same in both cases. However, 10 min later the change in PD with zero HCO3(-) was insignificant but with 25 mM HCO3(-) the PD decreased (anomalous response of electrogenic NaCl symport). PD maxima due to K+ and Na+ were largely related to (Na+ + K+)-ATPase pump. Changes in nutrient Cl- from 81 to 8.1 mM gave only a decrease in PD (normal response). Initial PD increases are explained by relative increases in resistance of simple conductance pathways and of parallel pathways of (Na+ + K+)-ATPase pump and Na+/Cl- symport. Removal of HCO3(-) and concurrent reduction of pH modify resistance of these pathways.     

Role of separate K+ and Cl- channels and of Na+/Cl- cotransport in volume regulation in Ehrlich cells

Cells resuspended in hypotonic medium initially swell as nearly perfect osmometers, but later recover their volume with an associated KCl loss. This regulatory volume decrease (RVD) is unaffected when nitrate is substituted for Cl- or if bumetanide or 4,4'-diisothiocyanostilbene-2,2'-disulfonate (DIDS) is added. It is inhibited by quinine, Ba2+, low pH, anticalmodulin drugs, and depletion of intracellular Ca2+. It is accelerated by the Ca2+ ionophore A23187, or by a sudden increase in external Ca2+ and at high pH. A net KCl loss is also seen after addition of ionophore A23187 in isotonic medium. Similarities are demonstrated between the KCl loss seen after addition of A23187 and the KCl loss seen during RVD. It is proposed that separate conductive K+ and Cl- channels are activated during RVD by release of Ca2+ from internal stores, and that the effect is mediated by calmodulin. After restoration of tonicity the cells shrink initially, but recover their volume with an associated KCl uptake. This regulatory volume increase (RVI) is inhibited when NO3- is substituted for Cl-, and is also inhibited by furosemide or bumetanide, but it is unaffected by DIDS. The unidirectional Cl-flux ratio is compatible with either a coupled uptake of Na+ and Cl-, or an uptake via a K+/Na+/2Cl- cotransport system. No K+ uptake was found, however, in ouabain-poisoned cells where a bumetanide-sensitive uptake of Na+ and Cl- in nearly equimolar amounts was demonstrated. Therefore, it is proposed that the primary process during RVI is an activation of an otherwise quiescent Na+/Cl- cotransport system with subsequent replacement of Na+ by K+ via the Na+/K+ pump. There is a marked increase in the rate of pump activity in the absence of a detectable increase in intracellular Na+ concentration.