Volume-activated Cl(-)-independent and Cl(-)-dependent K+ pathways in trout red blood cells

Use it or lose it? Sablefish, Anoplopoma fimbria, a species representing a fifth teleostean group where the βNHE associated with the red blood cell adrenergic stress response has been secondarily lost

Like most teleosts, sablefish (Anoplopoma fimbria Pallas 1814) blood exhibits a moderate Root effect (~35% maximal desaturation), where a reduction in blood pH dramatically reduces O2 carrying capacity, a mechanism important for oxygenating the eye and filling the swim bladder (SB) in teleosts. Although sablefish lack a SB, we observed a well-defined choroid rete at the eye. The adrenergically mediated cell swelling typically associated with a functional red blood cell (RBC) β-adrenergic Na+/H+ exchanger (βNHE), which would normally protect RBC pH, and thus O2 transport, during a generalized acidosis, was not observed in sablefish blood. Neither isoproterenol (a β-agonist) nor 8-bromo cAMP could elicit this response. Furthermore, RBC osmotic shrinkage, known to stimulate NHEs in general and βNHE in other teleosts such as trout and flounder, resulted in no significant regulatory volume increase (RVI), further supporting the absence of a functional RBC βNHE. The onset of the Root effect occurs at a much lower RBC pH (6.83–6.92) than in other teleosts, and thus RBC βNHE may not be required to protect O2 transport during a generalized acidosis in vivo. Phylogenetically, sablefish may represent a fifth group of teleosts exhibiting a secondary reduction or loss of βNHE activity. However, sablefish have not lost the choroid rete at the eye (unlike in the other four groups), which may still function with the Root effect to oxygenate the retina, but the low pH onset of the Root effect may ensure haemoglobin (Hb)-O2 binding is not compromised at the respiratory surface during a general acidosis in the absence of RBC βNHE. The sablefish may represent an anomaly within the framework of Root effect evolution, in that they possess a moderate Root effect and a choroid rete at the eye, but lack the RBC βNHE and the SB system.

Characterisation of three pathways for osmolyte efflux in human erythroleukemia cells

Cell volume decrease is a key step during differentiation of erythroid cells. This could arise from membrane transporter activation leading to a loss of cell osmolytes; however, the pathways involved are poorly understood. We have characterised Cl(-)-independent K(+) and (3)H-taurine efflux from the erythroleukemia cell line, K562. K(+) efflux (measured using (86)Rb(+)) from pre-loaded cells subjected to hypo-osmotic challenge demonstrated two phases, a rapid increase in K(+) efflux followed by a smaller slower increase. Swelling-activated taurine efflux only demonstrated a single phase. Both phases of K(+) efflux were significantly (P<0.05) blocked by anion channel inhibitor 5-nitro-2-(3-phenypropylamino)-benzoic acid (NPPB). However the antiestrogen, tamoxifen, only inhibited the slow late phase. The initial rapid phase had a higher IC(50) for NPPB inhibition than the slow phase, and was insensitive to protein kinases inhibitors KN-62, wortmannin and PD98059. For the slow K(+) efflux phase, the IC(50) for NPPB inhibition and the inhibition by KN-62, wortmannin, genistein or PD98059, were very similar to those measured for the hypo-osmotically-activated taurine efflux. With NPPB (100 microM) present, the slow K(+) efflux phase was further significantly decreased by the Ca(2+) chelator BAPTA-AM or by the Ca(2+)-activated K(+) channel blockers clotrimazole and charybdotoxin but not by apamin. Thus, at least 3 Cl(-)-independent pathways are involved: (a) a tamoxifen-sensitive and taurine-permeable anion channel; (b) a tamoxifen-insensitive and taurine-impermeable K(+) efflux pathway; and (c) a subtype of Ca(2+)-activated K(+) channel. Any or all of these could be involved in the cell volume decrease associated with differentiation in K562 cells.

Blood sampling techniques and storage duration: Effects on the presence and magnitude of the red blood cell β-adrenergic response in rainbow trout (Oncorhynchus mykiss)

Many teleostean fish, including rainbow trout, regulate red blood cell (RBC) pH (pH(i)) in the presence of a stress-induced acidosis such as hypoxia, hypercapnia, or exhaustive exercise. This is accomplished through activation of RBC Na+/H+ exchange (beta-NHE), ultimately minimizing impairment to oxygen transport. Presence and characterization of the RBC beta-NHE in fish is best tested in blood from cannulated, resting animals; however, several studies have used blood from stressed animals drawn from the caudal vein and stored prior to use. The effects of sampling procedures and storage on the beta-NHE response is not known and is the focus of this study. Whole blood drawn from cannulated, resting rainbow trout was compared with RBCs obtained from the caudal vein rinsed and stored at 4 degrees C for 0, 6, 24, 48, 96 or 144 h. Isoproterenol (10(-5) M), a beta-adrenergic agonist, was added to hypoxia/hypercapnia incubated RBCs in vitro. In all treatments, isoproterenol induced a large beta-NHE response, and storage duration (< or =96 h) had a minimal affect, indicating that rinsing and storing is an easy and viable means by which to obtain RBCs and investigate function. Storage for 144 h still resulted in a significant RBC beta-NHE response; however, viability of RBCs may be compromised.

Functional and molecular characterization of the K-Cl cotransporter of Xenopus laevis oocytes

The K-Cl cotransporters (KCCs) have a broad range of physiological roles, in a number of cells and species. We report here that Xenopus laevis oocytes express a K-Cl cotransporter with significant functional and molecular similarity to mammalian KCCs. Under isotonic conditions, defolliculated oocytes exhibit a Cl(-)-dependent (86)Rb(+) uptake mechanism after activation by the cysteine-reactive compounds N-ethylmaleimide (NEM) and mercuric chloride (HgCl(2)). The activation of this K-Cl cotransporter by cell swelling is prevented by inhibition of protein phosphatase-1 with calyculin A; NEM activation of the transporter was not blocked by phosphatase inhibition. Kinetic characterization reveals apparent values for the Michaelis-Menten constant of 27.7 +/- 3.0 and 15.4 +/- 4.7 mM for Rb(+) and Cl(-), respectively, with an anion selectivity for K(+) transport of Cl(-) = PO(4)(3-) = Br(-) > I(-) > SCN(-) > gluconate. The oocyte K-Cl cotransporter was sensitive to several inhibitors, including loop diuretics, with apparent half-maximal inhibition values of 200 and 500 microM for furosemide and bumetanide, respectively. A partial cDNA encoding the Xenopus K-Cl cotransporter was cloned from oocyte RNA; the corresponding transcript is widely expressed in Xenopus tissues. The predicted COOH-terminal protein fragment exhibited particular homology to the KCC1/KCC3 subgroup of the mammalian KCCs, and the functional characteristics are the most similar to those of KCC1 (Mercado A, Song L, Vazquez N, Mount DB, and Gamba G. J Biol Chem 275: 30326--30334, 2000).

The role of anion and cation channels in volume regulatory responses in trout red blood cells

(1) An outwardly rectifying chloride channel (ORCC) of large conductance has been detected under isotonic conditions (320 mosM 1(-1)) in the plasma membrane of trout red blood cells (RBCs) using the excised inside-out configuration. The channel, with a permeability ratio P(Cl)/Pcation of 12, was inhibited by the Cl- channel blockers 5-nitro-2-(3-phenylpropylamino)-benzoate (NPPB) (50 microM), and 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS) (100 microM) in the bathing solution. (2) In hypotonic conditions (215 mosM 1(-1)), 44% of cell-attached patches showed spontaneous single channel activity identified as nonselective cationic (NSC) channels. A second group, corresponding to 7% of cell-attached patches, showed spontaneous activity corresponding to a channel type presenting outward rectification and anionic selectivity. Finally, 49% of patches displayed a complex spontaneous signal corresponding to the superimposition of inward and outward currents probably due to activation of different channel types. (3) Giga-seals obtained without suction in intact cells under isotonic conditions possessed NSC channels that were quiescent but which could be activated either by mechanical deformation of cell membrane or by hypotonic cell swelling. (4) Hypotonically swollen RBCs exhibited regulatory volume decrease (RVD) over 3 h, which was linked to a fivefold to sixfold increase in unidirectional fluxes of K+, a net loss of intracellular K+ and net gain of extracellular Na+. RVD and the hypotonically activated, unidirectional K+ influx continued after replacement of Cl- by methylsulfonate (MeSF) albeit more slowly. (5) The NSC channel inhibitor, barium, and the Cl- channel inhibitor, NPPB, both inhibited the RVD response by approximately 50% in Cl- containing saline. When Cl- was replaced by MeSF, the inhibition was > 90% suggesting that NSC channels and ORCC play key roles in the chloride-independent component of RVD.

Cell volume regulation: the role of taurine loss in maintaining membrane potential and cell pH

1. In response to a hypo-osmotic stress cells undergo a regulatory volume decrease (RVD) by losing osmotically active solutes and obliged water. During RVD, trout red cells lost taurine, K+ and Cl- but gained Na+ and Cl-. Over the full time course of RVD the chloride concentration in the cell water remained remarkably constant. Thus membrane potential and cell pH, which depends on the ratio of internal to external chloride concentration ([Cl-]i:[Cl-]o), remained fixed. 2. When cell volume decreases it is only possible to keep the chloride concentration in the cell water constant if an equal percentage of the cell chloride pool and of the cell water pool are lost simultaneously. Quantitative analysis of our data showed that this requirement was fulfilled because, over the full time course of RVD, cells lost osmotically active solutes with a constant stoichiometry: 1 Cl-:1 positive charge:2.35 taurine. Any change in taurine permeability, by modifying the stoichiometric relationship, would affect the amount of water lost and consequently cell chloride concentration. 3. Experiments carried out with different cations as substitutes for external Na+ suggest that the constancy of the chloride concentration is not finely tuned by some mechanism able to modulate the channel transport capacity, but results in part from the fact that the swelling-dependent channel constitutively possesses an adequately fixed relative permeability for cations and taurine. However, as a significant fraction of K+ and Cl- loss occurs via a KCl cotransporter, the contribution of the cotransport to the stoichiometric relationship remains to be defined. 4. The large amount of taurine released during RVD (50 % of all solutes) was shown to be transported as an electroneutral zwitterion and not as an anion. How the channel can accommodate the zwitterionic form of taurine, which possesses a high electrical dipole, is considered.

Role of polyamine structure in inhibition of K+-Cl- cotransport in human red cell ghosts

1. K+-Cl- cotransport in human red cell ghosts is inhibited by divalent inorganic cations, soluble polycations and amphipathic organic cations. These findings suggest a common mechanism of inhibition, namely, binding of the cations to negative charges at the surface of a hydrophobic structure. 2. We have characterized the inhibitory capacity of a number of polyamines in order to obtain information about the nature of the charges with which they interact. Neomycin inhibited swelling-stimulated cotransport. The diquaternary amines dimethonium and decamethonium were relatively ineffective inhibitors. These compounds are thought to shield negative charges, but not bind to them. 3. Comparison of a homologous series of polyamines indicated that primary amines were better inhibitors than secondary amines, that inhibition increased with the charge of the polyamine, and that inhibition increased as the distance separating the amines increased. 4. The results indicate that the negative charges to which polycations bind are multiple and mobile. Since they must be associated with a hydrophobic environment, it is likely that they are negatively charged phospholipids located in the inner leaflet of the bilayer membrane. 5. Heating red cells or ghosts to 49 C denatures spectrin. Heating markedly increased K+ uptake in swollen ghosts but not in shrunken ghosts. The increase in uptake was reversed when swollen ghosts were shrunk even though denaturation of spectrin was not reversed. Polyamines, which inhibited swelling-activated K+ uptake in control ghosts, similarly inhibited the increased uptake in heated ghosts. 6. We speculate that spectrin, which is closely associated with the inner bilayer leaflet, shields negative charges in a volume-dependent manner and so regulates volume-sensitive K+ transport.

Chloride and non-selective cation channels in unstimulated trout red blood cells

1. The cell-attached and excised inside-out configurations of the patch-clamp technique were used to demonstrate the presence of two different types of ion channels in the membrane of trout red blood cells under isotonic and normoxic conditions, in the absence of hormonal stimulation. The large majority (93%) of successful membrane seals allowed observation of at least one channel type. 2. In the cell-attached mode with Ringer solution in the bath and Ringer solution, 145 mM KCl or 145 NaCl in the pipette, a channel of intermediate conductance (15-25 pS at clamped voltage, Vp = 0 mV) was present in 85% of cells. The single channel activity reversed between 5 and 7 mV positive to the spontaneous membrane potential. A small conductance channel of 5-6 pS and +5 mV reversal potential was also present in 62% of cells. 3. After excision into the inside-out configuration (with 145 mM KCl or NaCl, pCa 8 in the bath, 145 mM KCl or NaCl, pCa 3 in the pipette) the intermediate conductance channel was present in 439 out of 452 successful seals. This channel was spontaneously active in 90% of patches and in the other 10% of patches the channel was activated by suction. The current-voltage relationship showed slight inward rectification. The channel conductance was in the range 15-20 pS between -60 and 0 mV and increased to 25-30 pS between 0 and 60 mV, with a reversal potential close to zero. Substitution of K+ for Na+ in the pipette or in the bath did not significantly change the single channel conductance. Dilution of the bathing solution KCl concentration shifted the reversal potential towards the Nernst equilibrium for cations. Substitution of N-methyl-D-glucamine (NMDG) for K+ or Na+ in the bath almost abolished the outward current whilst the divalent cation Ca2+ permeated the channel with a higher permeability than K+ and Na+. Inhibition of channel openings was obtained with flufenamic acid, quinine, gadolinium or barium. Taken together these data demonstrate that the intermediate conductance channel belongs to a class of non-selective cation (NSC) channels. 4. In excised patches, under the same control conditions, the conductance of the small conductance non-rectifying channel was 8.6 +/- 0.8 pS (n = 12) between -60 and +60 mV and the reversal potential was close to 0 mV. This channel could be blocked by 5-nitro-2-(3-phenylpropylamino)-benzoate (NPPB) but not by flufenamic acid, DIDS, barium or gadolinium. Selectivity and substitution experiments made it possible to identify this channel as a non-rectifying small conductance chloride (SCC) channel.

Fish red blood cells: characteristics and physiological role of the membrane ion transporters

Several membrane ion transporters playing a role in gas transport and exchanges, cell volume regulation and intracellular acid-base regulation have been identified in fish red blood cells (RBCs). This short review focuses on Na+/K+ATPase and its role in establishing the ionic gradients across the membrane, on the Cl-/HCO3- exchanger and its key role in respiration and possibly in inducing a chloride conductance, on the Na+/H+ exchanger and the recent advances on its molecular mechanisms of activation and regulation, on the different types of K-Cl cotransports, the different hypotheses and suggested models and their role in cell volume regulation. There is no evidence in the literature for ionic channels in fish RBCs. We present original data obtained with the patch-clamp technique that shows for the first time the existence of a DIDS-sensitive chloride anionic conductance measured in whole cell configuration and the presence of a stretch-activated nonselective cationic channel recorded in cell-attached and excised inside-out configuration. The part played by these ionic conductances is discussed in relation with their possible involvement in volume regulation.

Volume-activated DIDS-sensitive whole-cell chloride currents in trout red blood cells

1. The nystatin-perforated whole-cell recording mode of the patch-clamp technique was used to investigate the membrane conductance of trout (Oncorhynchus mykiss) red blood cells in the steady state, 5 min after exposure to hyposmotic medium and 10 min after return to normal isosmotic medium. 2. Whole-cell I-V relations showed outward rectification when red blood cells were bathed in isosmotic (320 mosmol l-1) saline solution and the patch pipette was filled with 117 mM KCl. The membrane conductance was 2.58 +/- 0.59 nS (number of experiments, n = 18) between 0 and 100 mV and 1.32 +/- 0.19 nS (n = 18) between 0 and -100 mV. Removal of Cl- from the extracellular side or incubation with the Cl- channel blocker DIDS caused a reduction in whole-cell membrane conductance by more than 50%, indicating that the membrane current was generated by Cl- ions. The remaining conductance was voltage independent and probably due to non-selective cation conductance. 3. The membrane conductance increased approximately 2-fold after cell swelling induced by exposure to hyposmotic saline solution (215 mosmol l-1). This effect was abolished in Cl(-)-free hyposmotic medium or in the presence of DIDS. 4. The return to isosmotic solution produced a fall in membrane conductance to, or below, control values. 5. We conclude that trout red blood cells possess a significant Cl- conductance in the steady state which is reversibly activated during cell swelling and contributes to volume recovery.

Defining the volume dependence of multiple K flux pathways of trout red blood cells

The volume sensitivity of different K flux pathways has been determined in trout red blood cells subjected to volume perturbation. Gentle hyposmotic swelling induced a K influx in a Cl-containing saline but not in NO3- or methanesulfonate (MeSF)-containing salines, consistent with the activation of a Cl-dependent flux. Extreme hyposmotic swelling led to larger K fluxes in all salines but with reduced anion discrimination of the Cl-dependent flux. In contrast to these graded responses, isosmotic swelling using ammonium chloride or beta-adrenergic stimulation activated only Cl-dependent fluxes in an all-or-none fashion. The relationship between the hyposmotically and isosmotically induced pathways was studied by coactivation using either ammonium chloride or isoproterenol with anisosmotic treatment. Cells in ammonium chloride-containing hyposmotic salines showed no additive K flux over that induced by hyposmotic treatment alone, indicating that the isosmotically induced Cl-dependent flux was identical to the hyposmotically induced Cl-dependent flux. However, cells coactivated by hyposmotic and beta-adrenergic treatment showed a small Cl-dependent flux in addition to that induced by hyposmotic treatment alone. This small third component was unaffected by anisosmotic treatment. We conclude that the major Cl-dependent and Cl-independent K flux pathways are distinct and separate and that the former has an anion dependence that varies with cell volume and a volume sensitivity that varies with ionic strength.

Role of protein phosphorylation in control of K flux pathways of trout red blood cells

The role of protein phosphatases in the regulation of K flux pathways of the trout red blood cell has been investigated using the phosphatase inhibitors calyculin A and okadaic acid. Both inhibitors completely blocked an oxygenation-activated Cl-dependent K flux with a 50% inhibitory concentration of 17 and 675 nmol/l, respectively, but not the hypotonically activated Cl-independent K uptake. N-ethylmaleimide (NEM) and staurosporine caused an increase in the Cl-dependent flux. In both cases preincubation with calyculin A blocked activation but, when added during activation, it prevented any further increase with NEM but abolished the staurosporine-induced uptake. K uptake that was activated by NEM and "clamped" by calyculin A was volume sensitive, indicating a dual influence on this pathway. Chelerythrine, a protein kinase inhibitor, activated a Cl-independent K uptake that was unaffected by calyculin A. It is concluded that activation and deactivation of both Cl-dependent and Cl-independent pathways require changes in the phosphorylation of an as yet unidentified target protein(s), although with different sets of protein kinase and/or phosphatases. These observations also suggest a complex model of kinase-phosphatase regulation and provide drugs for the pharmacological definition and manipulation of Cl-dependent and Cl-independent K flux pathways.

Evidence for a K(+)-H+ exchange in trout red blood cells

1. Exposure of trout red blood cells to beta-adrenergic agonist isoprenaline activates a cAMP-dependent Na(+)-H+ antiport, the movements of protons being compensated by a Cl(-)-OH- (or HCO3-) exchange mediated by band 3 protein. The absorption of water osmotically linked to sodium and chloride induces cell swelling. 2. In the presence of acetazolamide, anionic exchange is inhibited and activation of cationic exchange resulted in the first 2 min in a strong external acidification and a large internal alkalinization leading to a reversal of the transmembrane pH gradient. Then, for at least 1 h and despite the inhibition of Cl- entry, a net Na+ uptake occurred which was balanced by an equivalent K+ loss, with the result that cell volume and pH gradient remained unchanged. 3. In such conditions, the inactivation of the Na(+)-H+ exchanger by a beta-antagonist, propranolol, blocked Na+ entry while K+ continued to be lost. This volume-independent K+ efflux, which is thus independent of the Na(+)-H+ exchanger, was not accompanied by a Cl- efflux but was associated with large internal and external pH changes consistent with K(+)-H+ exchange. 4. The K+ loss and the related pH changes are inhibited by compounds which are known to inhibit the K(+)-anion co-transporter in trout red cells, i.e. 4,4'-diisothiocyanatostilbene-2,2'-disulphonic acid (Dids) and niflumic acid.