Direct estimate of 1:1 stoichiometry of K+-Clminus cotransport in rabbit erythrocytes

Michael L. Jennings and Mark F. Adame

Department of Physiology and Biophysics, University of Arkansas for Medical Sciences, Little Rock, Arkansas 72205


    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

This work was undertaken to obtain a direct measure of the stoichiometry of Na+-independent K+-Cl- cotransport (KCC), with rabbit red blood cells as a model system. To determine whether 86Rb+ can be used quantitatively as a tracer for KCC, 86Rb+ and K+ effluxes were measured in parallel after activation of KCC with N-ethylmaleimide (NEM). The rate constant for NEM-stimulated K+ efflux into isosmotic NaCl was smaller than that for 86Rb+ by a factor of 0.68 ± 0.11 (SD, n = 5). This correction factor was used in all other experiments to calculate the K+ efflux from the measured 86Rb+ efflux. To minimize interference from the anion exchanger, extracellular Cl- was replaced with SO<UP><SUB>4</SUB><SUP>2−</SUP></UP>, and 4,4'-diisothiocyanothiocyanatodihydrostilbene-2,2'-disulfonic acid was present in the flux media. The membrane potential was clamped near 0 mV with the protonophore 2,4-dinitrophenol. The Cl- efflux at 25°C under these conditions is ~100,000-fold smaller than the uninhibited Cl-/Cl- exchange flux and is stimulated ~2-fold by NEM. The NEM-stimulated 36Cl- flux is inhibited by okadaic acid and calyculin A, as expected for KCC. The ratio of the NEM-stimulated K+ to Cl- efflux is 1.12 ± 0.26 (SD, n = 5). We conclude that K+-Cl- cotransport in rabbit red blood cells has a stoichiometry of 1:1.

red blood cells; N-ethylmaleimide; ion regulation


    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

THE COUPLED COTRANSPORT of Cl- with alkali cations serves a variety of cellular functions, including transepithelial fluid absorption and secretion, cell volume regulation, and regulation of intracellular Cl- (21, 41, 47). The first cation-Cl- cotransporter to be described functionally (16) and at the molecular level (51, 59) is known as NKCC and mediates the electroneutral cotransport of 1 Na+, 1 K+, and 2 Cl-. A related family of transporters, the K+-Cl- cotransporters (KCC), mediate the Na+-independent cotransport of K+ and Cl-. KCC was first characterized functionally in erythrocytes (14, 38) and epithelia (37, 53). The cDNA sequences and tissue distributions of several KCC isoforms have been determined (19, 24, 25, 48, 50, 52). The most widely distributed isoform is KCC1, which is activated by cell swelling or N-ethylmaleimide (NEM) (19). Another isoform, KCC2, is expressed specifically in neurons (50) and has a role in determining the intracellular Cl- concentration and the excitatory or inhibitory action of Cl- channels (42, 54).

It is very clear that KCC represents obligatory cotransport rather than interdependent Cl- and K+ channels. For example, in the basolateral membrane of Necturus gall bladder, the effects of K+ gradients on net Cl- fluxes are as expected for cotransport, rather than separate channels, and the Cl- conductance is too low to account for the Cl- flux (53). In red blood cells, net uphill K+ transport can be driven by a Cl- gradient, under conditions in which the membrane potential is clamped with NO<UP><SUB>3</SUB><SUP>−</SUP></UP> (6). A further indication that KCC is not mediated by interdependent channels is that there is very little effect of membrane potential on the swelling-activated K+ flux in human red blood cells (35). The lack of potential dependence does not prove that the overall transport process is electroneutral but does show that the rate-limiting step does not involve net charge movement in the transmembrane electric field.

To understand the functional consequences of K+-Cl- cotransport, it is important to know the stoichiometry of the process. For example, if the stoichiometry is 1:1, then the driving force for net ion flux is zero when [K+]i[Cl-]i = [K+]o[Cl-]o (where [K+]i and [Cl-]i represent intracellular K+ and Cl- concentrations and [K+]o and [Cl-]o represent extracellular K+ and Cl- concentrations) irrespective of the membrane potential.1 For the K+ gradients commonly present in cells {i.e., ([K+]in/[K+]out) ~25}, a 1:1 K+-Cl- cotransporter would be at equilibrium when intracellular Cl- concentration is 4 mM and extracellular Cl- concentration is 100 mM. Therefore, at any intracellular Cl- concentration >4 mM, 1:1 KCC would mediate net efflux. However, if the stoichiometry is actually not equimolar, the driving force for transport and the consequences of KCC for intracellular Cl- would be very different.

There are several kinds of evidence, in addition to the lack of potential dependence of the flux (35), that, in fact, the stoichiometry of KCC is 1:1. Most studies of the K+ and Cl- concentration dependence of KCC show no sign of more than one binding site for each ion (3, 11, 19, 38, 52). Most data on the flux reversal point, i.e., the K+ (or Rb+) and Cl- gradients that result in zero net flux (38, 40), indicate 1:1 cotransport. Finally, the magnitudes of the net K+ and Cl- fluxes in osmotically swollen duck red blood cells (44) and the basolateral membrane of Necturus gall bladder (53) are approximately equal.

Although the above data strongly suggest that KCC1 has 1:1 stoichiometry, there is one missing piece of information: a direct measurement of KCC-mediated net K+ and Cl- fluxes under conditions in which 1) the membrane potential is clamped to remove the requirement that net K+ and Cl- fluxes be equal to preserve global electroneutrality and 2) the KCC-mediated fluxes are clearly distinguished from those through other transport pathways for K+ and Cl-. To obtain a direct estimate of the stoichiometry of KCC, we have used the rabbit erythrocyte as a model system. The rabbit red blood cell has a comparatively large Cl--dependent K+ (or 86Rb+) flux that is stimulated by cell swelling or treatment with NEM (2, 58). This flux is very likely mediated by KCC1, although it is possible that KCC3 is also expressed in red blood cells (52). The KCC-mediated 86Rb+ flux, although large compared with that in red blood cells of other mammalian species, is still at least four orders of magnitude lower than the 36Cl-/Cl- exchange flux mediated by the anion exchanger AE1 (band 3) (4). Nonetheless, we have found that it is possible to inhibit the band 3-mediated flux by a factor of ~105 by a combination of H2DIDS and removal of extracellular Cl- and HCO<UP><SUB>3</SUB><SUP>−</SUP></UP>. With band 3 inhibited, it is possible to measure an NEM-stimulated 36Cl- efflux, which is inhibited by okadaic acid and calyculin A, as expected for KCC (32, 34, 57). The NEM-stimulated K+ (or 86Rb+) and 36Cl- effluxes indicate that the stoichiometry of KCC in rabbit red blood cells is 1:1.


    MATERIALS AND METHODS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Materials. Blood was drawn from an ear vein of a healthy New Zealand White rabbit into heparin and stored for <= 4 days at 4°C as whole blood. Radionuclides (86Rb+ as RbCl and 36Cl- as NaCl) were obtained from DuPont NEN (Boston, MA). H2DIDS was synthesized from 4,4' diaminostilbene-2,2'-disulfonic acid (DADS) by a modification of the method used by Cabantchik and Rothstein (8) as described previously (30). Okadaic acid and calyculin A were purchased from Calbiochem. All other buffers, salts, and reagents were obtained from Sigma (St. Louis, MO) or Fisher Scientific (Pittsburgh, PA).

Cell preparation and NEM treatment. Cells were washed three times and incubated for 90 min at 37°C in HEPES-buffered physiological saline (HPS: 150 mM NaCl, 5 mM KCl, 1 mM CaCl2, 1 mM MgCl2, 1 mM sodium phosphate, 10 mM HEPES, pH 7.4) plus 10 mM glucose to try to establish a reproducible steady state. For 86Rb+ efflux measurements, the incubation in HPS included 1 µCi/ml 86RbCl. After the incubation in HPS, cells were washed once in HPS, suspended at 5% hematocrit in HPS, and chilled on ice before treatment with 2 mM NEM as described previously (28). The NEM treatment was at 0°C; treatment at low temperature avoids the inhibitory side reactions that take place during exposure of cells to high concentrations of NEM at 37°C (39). The suspensions were incubated for 15 min on ice and washed once, and the treatment was repeated. Finally, the cells were washed once in HPS, and the pellet was incubated for 20 min at 37°C to activate KCC; the details of the kinetics of activation of KCC after NEM pretreatment are described elsewhere (28). Calyculin A, if present, was added to a final concentration of 50 nM immediately before the 37°C activation incubation. After the 20-min incubation at 37°C, KCC is fully activated. The flux itself was measured at 25°C, because the KCC flux (when fully activated with NEM) has a relatively low temperature dependence at 25-37°C (31); therefore, the KCC flux is larger at 25°C relative to other transport pathways than it is at 37°C.

Comparison of 86Rb+ and K+ efflux. To evaluate 86Rb+ as a quantitative tracer for K+, we measured net 86Rb+ efflux and K+ efflux simultaneously in parallel suspensions of cells from the same preparation. Cells were prepared exactly as described above (with or without NEM treatment) and were suspended in 160 mM NaCl, 10 mM HEPES hemisodium (a 1:1 mixture of HEPES free acid and Na+-HEPES, resulting in a pH equal to the pK of HEPES), pH 7.45, and 10-4 M ouabain at 25°C. The extracellular K+ concentration was measured at various time points by immersion of a K+-selective electrode (Fisher Scientific) in the suspension immediately after calibration of the electrode in 160 mM NaCl, 10 mM HEPES, pH 7.45, and 0.01-10 mM KCl. Total K+ in the suspension was measured by the same method after lysis by repeated freezing and thawing. To allow calculation of the volume of cells per volume of suspension, cells were added to the medium from a loosely packed pellet with a positive displacement pipette, and the hematocrit of an aliquot of the stock packed suspension was measured. The intracellular K+ content determined in this manner was 111 ± 6.4 (SD) meq/l cells (n = 4 preparations), similar to published values (10).

86Rb+ and 36Cl- efflux measurements. To compare NEM-stimulated 86Rb+ and 36Cl- effluxes, cells were pretreated with NEM as described above, and the efflux of 86Rb+ or 36Cl- was measured at 25°C in a medium consisting of 120 mM Na2SO4, 20 mM MOPS, pH 7.1, 20 µM H2DIDS, 40 µM 2,4-dinitrophenol (2,4-DNP), and 100 µM ouabain. All NEM pretreatments and subsequent washes can be performed on 86Rb+-loaded cells with negligible losses of tracer. For 36Cl- efflux measurements, cells were preincubated exactly as described above (but without 86Rb+). After the 20-min incubation at 37°C to activate KCC, cells were loaded with 36Cl- by incubating a 50% suspension in HPS containing 1 µCi/ml Na36Cl for 5 min at 25°C. Cells were then washed twice in chilled 120 mM Na2SO4, 20 mM MOPS hemisodium, pH 7.1, and 10 µM H2DIDS and immediately resuspended in flux medium to start the efflux measurement. The medium had been bubbled with N2 to minimize the HCO<UP><SUB>3</SUB><SUP>−</SUP></UP> concentration. The H2DIDS was present to inhibit AE1-mediated exchange of Cl- for SO<UP><SUB>4</SUB><SUP>2−</SUP></UP> or residual HCO<UP><SUB>3</SUB><SUP>−</SUP></UP>. The 2,4-DNP was added to clamp the membrane potential at the equilibrium potential for H+, which is close to 0 mV in this medium. Ouabain was added as a precaution to prevent any 86Rb+ flux from a reversed mode of the Na+-K+-ATPase, although we do not have any evidence that such a flux is significant under these conditions.

The flux suspensions (2-4% hematocrit) were incubated at 25°C with gentle stirring. Aliquots (0.6 ml) were removed at various intervals and centrifuged for 1 min in a microfuge, and the radioactivity in 0.2 ml of supernatant was determined by liquid scintillation counting (Scintisafe Econo 2, Fisher Scientific). For each efflux measurement, four time points were taken, as well as duplicate samples lysed in 10% trichloroacetic acid for determination of the total counts per minute in the suspension (time point at infinity). The rate constants (h-1) for tracer efflux were determined by fitting the data to a single exponential function using SigmaPlot software (Jandel Scientific).

Cl- contents and flux calculation. Cl- contents were determined by mixing 0.5 ml of stock suspension (80% hematocrit) with 0.3 ml of HPS containing a known amount of 36Cl-. After the cells and medium were allowed to equilibrate for a few minutes at 25°C, cells were centrifuged, and the radioactivity in the supernatant was determined by scintillation counting. The cellular Cl- was calculated from the total 36Cl-, the final extracellular 36Cl-, the total extracellular water, and the volume of cells. In a medium containing 160 mM Cl-, the Donnan ratio ([Cl-]in/[Cl-]out) at 25°C and pH 7.4 was 0.75, which is close to the known value for human red blood cells under these conditions (22). The net Cl- flux (meq · l cells-1 · h-1) was calculated from the rate constant for 36Cl- efflux (h-1) times the cellular Cl- contents (meq/l cells).


    RESULTS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Comparison of NEM-stimulated K+ and Rb+ efflux. These experiments were designed to measure NEM-stimulated net K+ and Cl- effluxes under conditions in which the membrane potential is clamped at ~0 mV to remove electrical constraints on the K+ and Cl- fluxes. In our experience, the most accurate way to measure solute transport is with radioactive tracers, and 86Rb+ is commonly used as a tracer for K+ in the study of KCC (14, 38). To determine whether 86Rb+ is a quantitative tracer for K+ with regard to rabbit red cell KCC, cells were washed and loaded with 86Rb+, and KCC was activated by pretreatment with NEM. Cells were then washed and resuspended in 160 mM NaCl-10 mM HEPES, pH 7.45, at 25°C for measurement of efflux of 86Rb+ and K+ as described in MATERIALS AND METHODS.

As shown in Fig. 1, NEM stimulates both K+ and 86Rb+ fluxes, but the rate constant (h-1) for both control and NEM-stimulated K+ efflux is lower than that for 86Rb+ efflux. In five experiments, the NEM-stimulated K+ efflux rate constant (difference between control and NEM-treated cells) was lower than that for 86Rb+ by a factor of 0.68 (range 0.54-0.76), indicating that 86Rb+ is not a perfect tracer for K+ efflux under these conditions. Nonetheless, the accuracy and convenience of using 86Rb+ make it superior to ion-selective electrodes or the short-lived radionuclide 42K+. Accordingly, the remaining cation efflux measurements in this study (see Fig. 5) were performed with 86Rb+, and the K+ efflux was calculated by assuming that the NEM-stimulated K+ efflux rate constant is 0.68 times that for 86Rb+.


View larger version (17K):
[in this window]
[in a new window]
 
Fig. 1.   Comparison of the time course of 86Rb+ and K+ efflux from control (circles) and N-ethylmaleimide (NEM)-treated (triangles) rabbit red blood cells suspended in a medium consisting of 160 mM NaCl and 10 mM HEPES, pH 7.5, at 25°C. Results are from a single experiment that is representative of 5 experiments. [Rb+]o and [K+]o, extracellular Rb+ and K+ concentrations.

Clamping the membrane potential with 2,4-DNP. The goal of these experiments is to measure NEM-stimulated K+ (or 86Rb+) and Cl- effluxes under conditions of maximum inhibition of other transport pathways for these ions. However, if K+ and Cl- are the main permeant ions, the constraint of electroneutrality would require that net K+ and Cl- effluxes be equal, even if the actual cotransport itself were an electrogenic 1:2 or 2:1 process. To remove the electrical constraint on the K+ and Cl- fluxes, the protonophore 2,4-DNP was added to the flux medium to provide a conductive pathway for H+. Macey et al. (45) showed that protonophores can increase the H+ permeability of the human red cell membrane sufficiently to make the membrane potential close to the Nernst potential for H+. This finding is in agreement with the earlier observation of Harris and Pressman (23) that protonophores increase the rate of valinomycin-mediated K+ efflux in human red blood cells.

We showed several years ago that, in rabbit red blood cells, 2,4-DNP induces the expected H+ influx in the presence of valinomycin and an outward K+ gradient (29). We recently verified that, under the conditions of the present experiments (rabbit red blood cells, 25°C, pH 7.1), 40 µM 2,4-DNP accelerates the valinomycin-mediated 86Rb+ efflux from rabbit red blood cells suspended in a K+-free medium (2 experiments, not shown). Therefore, the conductive proton permeability in the presence of 2,4-DNP is sufficiently high to balance a valinomycin-mediated conductive K+ flux, which is much higher than the K+ fluxes observed in the absence of valinomycin. If there were a charge imbalance in the efflux of K+ and Cl- through KCC in red blood cells, the proton conductance mediated by 2,4-DNP would be high enough to allow the efflux of different amounts of K+ and Cl-. Control experiments also showed that 40 µM 2,4-DNP does not affect the basal or NEM-stimulated 86Rb+ efflux, measured as in Fig. 1. All further experiments were carried out in the presence of 40 µM 2,4-DNP, which has the added benefit of inhibiting band 3-mediated anion transport (49).

Inhibition of Cl- exchange by H2DIDS and removal of extracellular Cl-. It is so difficult to measure a Cl- tracer flux associated with red cell KCC because red blood cells have a very large Cl-/Cl- exchange flux mediated by band 3 (AE1). In a medium containing 150 mM Cl- at pH 7.4, the rate constant for 36Cl-/Cl- exchange in rabbit red blood cells at 0°C is ~3/min (unpublished data), which is similar to that in human red blood cells under comparable conditions (20). With the assumption that the temperature dependence of red cell Cl-/Cl- exchange is the same in rabbits and humans (4), the rate constant for Cl-/Cl- exchange at 25°C in rabbit red blood cells should be ~180/min. The rate constant for NEM-stimulated 86Rb+ efflux in rabbit red blood cells at 25°C is ~0.0015/min (see below), which is a factor of 100,000 slower than the AE1-mediated Cl-/Cl- exchange flux. Accordingly, it is necessary to inhibit the AE1-mediated flux by a very large factor to have a chance of detecting a Cl- flux associated with K+-Cl- cotransport.

The large 36Cl- flux mediated by AE1 would initially appear to preclude the possibility of detecting a 36Cl flux through KCC in red blood cells. Powerful inhibitors of anion exchange such as DIDS, H2DIDS, and related agents are well known (7, 8, 36, 56), but the prospect of using inhibitors to reduce the 36Cl- efflux by a factor of 100,000 is discouraging. The maximum irreversible inhibition of human AE1 by DIDS is a factor of only ~500 (15). Another approach is to include enough inhibitor in the flux medium at 25°C to inhibit the band 3-mediated Cl- efflux reversibly by a factor of >100,000. However, high concentrations of DIDS cause reversible inhibition of KCC (12). Accordingly, it is unrealistic to expect that DIDS, H2DIDS, or any other agent, by itself, can inhibit AE1-mediated Cl-/Cl- exchange sufficiently to allow detection of a KCC-mediated tracer flux.

It is well known that replacement of external Cl- with slowly permeating anions can strongly reduce the tracer Cl- efflux from red blood cells (18). For example, the half time of 36Cl efflux from human red blood cells in an Na2SO4 medium (treated with N2 to lower HCO<UP><SUB>3</SUB><SUP>−</SUP></UP>) is ~20 min at 23°C (27), which is a factor of ~5,000 slower than Cl-/Cl- exchange (4). We therefore tried to minimize the band 3-mediated Cl- efflux by the combined effects of replacing extracellular Cl- with SO<UP><SUB>4</SUB><SUP>2−</SUP></UP>, adding 20 µM H2DIDS to the flux medium, and pretreating the medium with N2 to lower the CO2/HCO<UP><SUB>3</SUB><SUP>−</SUP></UP>. These conditions lower the rate constant for 36Cl- efflux by a factor of ~100,000, from ~180/min to 0.002/min (see below), which is the same order of magnitude as the NEM-stimulated K+ efflux. Therefore, we attempted to detect a KCC-mediated (NEM stimulated) 36Cl- efflux in a medium consisting of 120 mM Na2SO4, 20 mM MOPS, pH 7.1, 20 µM H2DIDS, and 40 µM 2,4-DNP. The extracellular and intracellular pH are nearly equal in this medium; therefore, the membrane potential is near 0 in the presence of 2,4-DNP. Also, there are no possible KCC-mediated exchanges (Rb+/K+ or Cl-/Cl- exchange), because the medium contains no extracellular K+ or Cl-.

Lack of effect of traces of CO2. To minimize residual Cl-/HCO<UP><SUB>3</SUB><SUP>−</SUP></UP> exchange, media were always bubbled with N2 before the flux experiment. In early experiments, we maintained an N2 atmosphere throughout the flux experiments but found no detectable effect of allowing contact with an air atmosphere during the efflux measurement. Most of the experiments, therefore, were carried out in an air atmosphere with flux solutions that had been pretreated with N2. Apparently, there was sufficient inhibition of Cl-/HCO<UP><SUB>3</SUB><SUP>−</SUP></UP> exchange by H2DIDS, 2,4-DNP, and SO<UP><SUB>4</SUB><SUP>2−</SUP></UP> that traces of HCO<UP><SUB>3</SUB><SUP>−</SUP></UP> entering the solution did not stimulate Cl- efflux significantly.

Lack of effect of 20 µM H2DIDS on NEM-stimulated 86Rb+ efflux. To use H2DIDS as an inhibitor of band 3 in these experiments, it is necessary to determine whether H2DIDS affects KCC under these conditions. In human red blood cells at 0°C, H2DIDS inhibits Cl-/Cl- exchange half-maximally at 0.05 nM (56); 20 µM should therefore produce >99% inhibition of anion exchange. We found that 20 µM H2DIDS in the flux medium does not have a detectable effect on either the basal or the NEM-stimulated 86Rb+ efflux in red blood cells (Fig. 2).


View larger version (15K):
[in this window]
[in a new window]
 
Fig. 2.   Lack of effect of 20 µM H2DIDS in the flux medium on the efflux of 86Rb+ from rabbit red blood cells. Conditions are described in Fig. 1 legend. Cells had been pretreated with or without 2 mM NEM, and the efflux was carried out in 160 mM NaCl-10 mM HEPES, pH 7.5, at 25°C. Error bars represent the range of 2 fluxes, each determined from a single exponential fit of 4 time points.

NEM-stimulated 36Cl- efflux. Figure 3 shows that pretreatment of cells with 2 mM NEM stimulates 36Cl- efflux into an Na2SO4 medium containing 2,4-DNP and H2DIDS. The baseline flux is very consistent among different cell preparations; we do not know the nature of this Cl- transport pathway. We found a clear stimulation of the 36Cl- efflux by NEM in eight of eight experiments. The NEM-stimulated flux is inhibited by the protein phosphatase inhibitors calyculin A (Fig. 4) and okadaic acid (not shown), which are known inhibitors of activation of K+-Cl- cotransport (32, 34). There is no measurable effect of calyculin A on the 36Cl- in the absence of NEM treatment, but a small KCC-mediated Cl- flux could be present and not detected.


View larger version (15K):
[in this window]
[in a new window]
 
Fig. 3.   Stimulation of 36Cl- efflux by NEM pretreatment. Cells were pretreated with (black-triangle) or without () NEM as described in legends of Figs. 1 and 2. Efflux was measured at 25°C in the following medium: 120 mM Na2SO4, 20 mM MOPS, pH 7.1, 20 µM H2DIDS, 40 µM 2,4-dinitrophenol, and 100 µM ouabain. [36Cl-]o, extracellular 36Cl- concentration.



View larger version (15K):
[in this window]
[in a new window]
 
Fig. 4.   Inhibition of NEM-stimulated 36Cl- efflux by calyculin A (Cal). Cells were prepared and treated with NEM as described in legends of Figs. 1-3, and 36Cl- efflux was measured as described in Fig. 3 legend. Calyculin A (final concentration 50 nM) was added from a methanolic 100 µM stock solution after the 0°C NEM treatment and before the incubation at 37°C that activates the cotransporter. Control tubes received 0.05% methanol. Error bars represent the range of 2 fluxes, each determined from a single exponential fit of 4 time points.

Stoichiometry of NEM-stimulated K+ (or 86Rb+) and Cl- efflux. In five cell preparations, the tracer effluxes of 86Rb+ and 36Cl- were measured in parallel in the same flux solution used in Figs. 3 and 4, with or without pretreatment of the cells with NEM. The pretreatments were the same for the 86Rb+ and 36Cl- efflux measurements; the only difference was the radionuclide. The ratio of the NEM-stimulated K+ efflux to Cl- efflux ranged from 0.79 to 1.45 (Fig. 5), with an average of 1.12. The variations among different experiments are considerable, because experiments require measurement of differences. It is clear, however, that the NEM-stimulated effluxes of K+ and Cl- are very nearly equimolar.


View larger version (18K):
[in this window]
[in a new window]
 
Fig. 5.   Comparison of NEM-stimulated K+ and Cl- fluxes. Cells were prepared and treated with NEM as described in legends of Figs. 1-3. Effluxes of 86Rb+ and 36Cl- were measured on parallel aliquots of the same cell preparation in the flux medium described in Fig. 3 legend. Results of 5 separate experiments are shown; in each experiment, for each ion, 2 pairs of effluxes (4 time points) were performed: 1 pair with and 1 pair without NEM. NEM-sensitive flux is defined as that in NEM-treated cells minus that in control cells. Each error bar represents the sum of the ranges of the duplicate flux determinations in control and NEM-treated cells in that experiment. K+ flux was calculated from the 86Rb+ efflux using the correction factor derived from the experiments represented by Fig. 1.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The experiments described above have provided the most direct evidence to date that the red blood cell K+-Cl- cotransporter (most likely KCC1) mediates a Cl- flux and that the cotransport has a 1:1 stoichiometry of K+-Cl- cotransport. The evidence for 1:1 stoichiometry is that NEM stimulates a 36Cl- efflux that is very nearly the same as the NEM-stimulated K+ efflux (Fig. 5). The fact that K+ and Cl- effluxes are equal is not a consequence of the requirement for global electroneutrality, because the protonophore 2,4-DNP was present to allow H+ flux to neutralize any charge imbalance associated with KCC. These results are discussed below in the context of previous work related to the stoichiometry of KCC.

In most studies (3, 11, 19, 38, 52), the KCC-mediated flux of K+ (or Rb+) has a simple hyperbolic (Michaelis-Menten) dependence on the K+ and Cl- concentrations. Some data suggest a sigmoidal Cl- dependence of the KCC-mediated K+ or Rb+ flux (5, 14, 46), but the apparent sigmoidicity could be a consequence of the fact that the fluxes are more difficult to measure at low Cl- concentration, and the relative errors are larger. The apparent sigmoidicity in the Cl- dependence of KCC in these studies is less pronounced than that exhibited by the Na+-K+-2Cl- cotransporter (26), which clearly transports two Cl- ions. Certainly the bulk of the kinetic data on KCC is consistent with a 1:1 mechanism.

Another experimental approach to determine stoichiometry is to measure the flux reversal point, i.e., the combination of K+ (or Rb+) and Cl- gradients at which the net flux is zero. Lauf (38) originally showed that the flux reversal point in LK sheep red blood cells is very close to that expected for 1:1 K+-Cl- cotransport. Subsequently, Delpire and Lauf (11) found that, at 37°C, LK sheep red blood cells exhibit a net K+ flux under conditions in which a 1:1 mechanism would predict no net flux; this result was not in agreement with a 1:1 stoichiometry. More recently, Lauf and Adragna (40) clarified this issue by determining the flux reversal point of KCC in pH-clamped LK sheep red blood cells in the presence of various Cl- gradients; the results are entirely consistent with 1:1 electroneutral K+-Cl- cotransport. This work also provides evidence against H+ or OH- cotransport associated with KCC, because the flux reversal point is not dependent on extracellular pH over a wide range.

Reuss (53), in one of the early studies defining the existence of KCC, measured net K+ and Cl- fluxes across the basolateral membrane of Necturus gall bladder. The uncertainties in the measurements did not allow calculation of a stoichiometry, but the data are consistent with a 1:1 mechanism. In contrast, Larson and Spring (37) presented evidence that the stoichiometry of K+-Cl- cotransport is 3:2 in Necturus gall bladder, although the authors pointed out that parallel transport processes could affect the calculated stoichiometry. Vascular smooth muscle cells exhibit a K+-Cl- cotransport process (1) that has an apparent stoichiometry of as many as 25 Cl- ions per K+ ion, but this unusual stoichiometry may be related to exchange processes (55).

Zeuthen (60) has estimated the stoichiometry of K+-Cl- cotransport through the ventricular membrane of Necturus choroid plexus; the estimate was based on microelectrode determinations of changes in cytoplasmic K+ and Cl- concentrations after changes in the extracellular ion concentrations. Estimates of the ion fluxes were complicated by the large water fluxes that accompanied the solution changes, but the data are consistent with a 1:1 K+-Cl- cotransport. It would be of interest to know whether red cell K+-Cl- cotransport is associated with an obligatory water flux, as found by Zeuthen in Necturus choroid plexus. However, because of the high water permeability of the mammalian red cell membrane mediated by water channels, we cannot tell whether there is a water flux obligatorily coupled with K+-Cl- cotransport in rabbit red blood cells.

To our knowledge, there has been only one report of a 36Cl- flux associated with KCC in any cell. Lytle and McManus (43) showed that, in duck red blood cells treated with DIDS, there is a 36Cl- efflux that is stimulated by cell swelling and is dependent on intracellular K+. This work provided excellent evidence that KCC does, in fact, mediate a Cl- flux. Lytle and McManus did not report the stoichiometry of K+ (or 86Rb+) and 36Cl- effluxes. In related work, Lytle (44) demonstrated very clearly that the net efflux of K+ and Cl- from swollen duck red blood cells (with band 3 inhibited) has a stoichiometry that is indistinguishable from 1:1, as does the net uptake of Rb+ and Cl- into swollen, K+-free cells. The main differences between the present results and those of Lytle, other than the species difference (rabbit vs. duck), are that KCC was activated by NEM, rather than cell swelling, and a protonophore was included in our experiments. Lytle's work on duck red blood cells is completely consistent with our experiments with rabbit red blood cells.

Possible role of parallel pathways. In these experiments, we have assumed that the NEM-stimulated Rb+ and Cl- fluxes are attributable to KCC. This assumption is based on the fact that no other transporter for K+ or Cl- in red blood cells is known to be stimulated by NEM. Moreover, the NEM-stimulated Cl- flux (Fig. 4) is inhibited by calyculin A, as was previously known for KCC-mediated Rb+ fluxes (32, 34). Nonetheless, it is useful to consider the possibility that stimulation of KCC by NEM also causes stimulation of either a K+ or Cl- flux through a parallel pathway and thereby introduces error in the stoichiometry estimate.

For example, if KCC were actually an electrogenic 1:2 K+-Cl- cotransport mechanism, the charge imbalance would tend to drive the membrane potential in the positive direction and cause an efflux of acid equivalents mediated by 2,4-DNP. If the pH change associated with this 2,4-DNP-mediated proton flux caused a stimulation of K+ efflux through a pathway unrelated to KCC, the observed stoichiometry could be close to 1:1, even though the actual cotransport process is 1:2. Because of the large buffer power of red cell cytoplasm (22), it is unlikely that significant intracellular (or extracellular) pH changes take place during the fluxes measured here. In any case, if the KCC flux somehow produced a progressive pH change that induces a K+ or Cl- flux through a separate pathway, the flux should change progressively with time. We observe no indication of a time-dependent flux; the time courses of the effluxes of both 86Rb+ and 36Cl- are indistinguishable from single exponentials. It is therefore unlikely that the estimate of stoichiometry is distorted by fluxes through parallel transport pathways.

86Rb+ as tracer for K+. Our calculation of the K+ flux from the 86Rb+ tracer flux depends on the assumption that the KCC-mediated (NEM stimulated) K+ efflux rate constant is 0.68 times the 86Rb+ efflux rate constant. This ratio was determined in five experiments at the same temperature and pH as the other experiments (Fig. 1), but the Rb+-to-K+ comparisons were performed in an NaCl, rather than an Na2SO4, medium. The reason for using an NaCl medium is that the K+ efflux measurements with microelectrodes require longer times for reasonable accuracy (~100 min vs. 30 min for tracer efflux); at such long times, the intracellular Cl- concentration would have been lowered significantly in the Na2SO4 medium. The initial intracellular conditions are identical in all experiments (whether in NaCl or Na2SO4), and we do not see any reason to suspect that the ratio of 86Rb+ to K+ efflux rate constants would be any different in Na2SO4 vs. NaCl medium. Nonetheless, our calculation of stoichiometry does depend on the relative K+ and Rb+ efflux rate constants measured in an NaCl medium.

Other comparisons of Rb+ and K+ with regard to KCC have been published. Brugnara (5) measured KCC-mediated Rb+ and K+ efflux from human hemoglobin CC red blood cells and found that K+ and Rb+ effluxes were similar. It is possible that a minor difference could have been overlooked. Lauf (38) found that, in NEM-treated LK sheep red blood cells, K+ and Rb+ influxes through KCC are very similar, although the extrapolated maximal velocity (Vmax) measured with 42K+ was slightly slower (factor of 0.77) than that measured with Rb+; this result is in qualitative agreement with our finding that 86Rb+ efflux is more rapid than K+ efflux. Dunham and Ellory (14), using swollen LK sheep red blood cells, found a larger difference between the Vmax for 86Rb+ and K+ influx: the Vmax for K+ was only ~50% of that for 86Rb+. Part, but not all, of the difference was attributable to the fact that the cells were slightly more swollen in the 86Rb+ experiment. The data of Lauf and Dunham and Ellory are consistent with the idea that the maximal rate of Rb+ transport through KCC is slightly greater than that of K+, as we have found for efflux in the present experiments.

The finding that NEM-stimulated effluxes of 86Rb+ and K+ are slightly different certainly does not negate the value of 86Rb+ (and nonradioactive Rb+) for the study of KCC. The interpretation of most kinetic and regulatory studies of KCC would not be significantly altered by a ~30% difference in the maximal flux of Rb+ vs. K+, because most such studies rely mainly on comparisons of the flux of Rb+ under different conditions (e.g., different ionic media, cell volume, pH, Mg2+). In fact, the present work on K+-Cl- stoichiometry is one of a relatively few examples of an experiment in which it definitely matters whether Rb+ and K+ are kinetically identical. Also, we have shown only that K+ and Rb+ are not identical for efflux from rabbit red blood cells at 25°C; at other temperatures, the kinetic differences could be smaller, and the difference for influx may be smaller than that for efflux. It is worth pointing out that, in some tissues, there are major differences in the characteristics of 86Rb+ and 42K+ transport (13). In red blood cells, however, 86Rb+ is an adequate tracer for K+ for nearly all purposes; the differences we find here for KCC are relatively minor.

Role of O2. In these experiments, the flux media were bubbled with N2 to minimize CO2 and HCO<UP><SUB>3</SUB><SUP>−</SUP></UP>. The N2 bubbling caused deoxygenation of hemoglobin, but the O2 partial pressure in the suspensions was not well controlled. It is known that red cell KCC is influenced by the O2 tension (17, 33). However, the effects of O2 are on the regulation of KCC; after maximal stimulation with NEM, as in the present experiments, there is no longer an effect of O2 on KCC in red blood cells (9). Therefore, even though O2 partial pressure can have important effects on KCC, these effects were not significant under the conditions of our experiments.


    ACKNOWLEDGEMENTS

We are grateful to Carlo Brugnara, Phil Dunham, and Peter Lauf for helpful discussions regarding the issue of whether 86Rb+ is a quantitative tracer for K+ in the study of K+-Cl- cotransport. We are also grateful to Chris Lytle for sending material from his PhD dissertation.


    FOOTNOTES

This work was supported by National Institute of General Medical Sciences Grant R01-GM-26861-21.

1 The membrane potential is not part of the driving force for an electroneutral process, but the rate constants for individual kinetic events in the process could, in principle, be dependent on the membrane potential.

Address for reprint requests and other correspondence: M. L. Jennings, Dept. of Physiology and Biophysics, University of Arkansas for Medical Sciences, 4301 W. Markham St., Little Rock, AR 72205 (E-mail: JenningsMichaelL{at}uams.edu).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Received 1 February 2001; accepted in final form 17 April 2001.


    REFERENCES
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

1.   Adragna, NC, White RE, Orlov SN, and Lauf PK. K-Cl cotransport in vascular smooth muscle and erythrocytes: possible implication in vasodilation. Am J Physiol Cell Physiol 278: C381-C390, 2000[Abstract/Free Full Text].

2.   Al-Rohil, N, and Jennings ML. Volume-dependent K+ transport in rabbit red blood cells: comparison with oxygenated human SS cells. Am J Physiol Cell Physiol 257: C114-C121, 1989[Abstract/Free Full Text].

3.   Bergh, C, Kelley SJ, and Dunham PB. K-Cl cotransport in LK sheep erythrocytes: kinetics of stimulation by cell swelling. J Membr Biol 117: 177-188, 1990[ISI][Medline].

4.   Brahm, J. Temperature-dependent changes of chloride transport kinetics in human red cells. J Gen Physiol 70: 283-306, 1977[Abstract/Free Full Text].

5.   Brugnara, C. Characteristics of the volume- and chloride-dependent K transport in human erythrocytes homozygous for hemoglobin C. J Membr Biol 111: 69-81, 1989[ISI][Medline].

6.   Brugnara, C, Van Ha T, and Tosteson DC. Role of chloride in potassium transport through a K-Cl cotransport system in human red blood cells. Am J Physiol Cell Physiol 256: C994-C1003, 1989[Abstract/Free Full Text].

7.   Cabantchik, ZI, and Greger R. Chemical probes for anion transporters of mammalian cell membranes. Am J Physiol Cell Physiol 262: C803-C827, 1992[Abstract/Free Full Text].

8.   Cabantchik, ZI, and Rothstein A. Membrane proteins related to anion permeability of human red blood cells. I. Localization of disulfonic stilbene binding sites in proteins involved in permeation. J Membr Biol 15: 207-226, 1974[ISI][Medline].

9.   Canessa, M, Fabry ME, and Nagel RL. Deoxygenation inhibits the volume-stimulated, Cl--dependent K+ efflux in SS and young AA cells: a cytosolic Mg2+ modulation. Blood 70: 1861-1866, 1992[Abstract].

10.   Coldman, MF, and Good W. The distribution of sodium, potassium, and glucose in the blood of some mammals. Comp Biochem Physiol A Physiol 21: 201-206, 1967.

11.   Delpire, E, and Lauf PK. Kinetics of Cl-dependent K fluxes in hyposmotically swollen low K sheep erythrocytes. J Gen Physiol 97: 173-193, 1991[Abstract].

12.   Delpire, E, and Lauf PK. Kinetics of DIDS inhibition of swelling-activated K-Cl cotransport in low K sheep erythrocytes. J Membr Biol 126: 89-96, 1992[ISI][Medline].

13.   Dorup, I, and Clausen T. 86Rb is not a reliable tracer for potassium in skeletal muscle. Biochem J 302: 745-751, 1994[ISI][Medline].

14.   Dunham, PB, and Ellory JC. Passive potassium transport in low potassium sheep red cells: dependence upon cell volume and chloride. J Physiol (Lond) 318: 511-530, 1981[Abstract].

15.   Gasbjerg, PK, Funder J, and Brahm J. Kinetics of residual chloride transport in human red blood cells after maximum covalent 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid binding. J Gen Physiol 101: 715-732, 1993[Abstract].

16.   Geck, P, Pietrzyk C, Burckhardt B-C, Pfeiffer B, and Heinz E. Electrically silent cotransport of Na, K, and Cl in Ehrlich cells. Biochim Biophys Acta 600: 432-447, 1980[ISI][Medline].

17.   Gibson, JS, Speake PF, and Ellory JC. Differential oxygen sensitivity of the K+-Cl- cotransporter in normal and sickle human red blood cells. J Physiol (Lond) 511: 225-234, 1998[Abstract/Free Full Text].

18.   Giebel, O, and Passow H. Die Permeabilität der Erythrocytenmembran für organischen Anionen. Zur Frage der Diffusion durch Poren. Pflügers Arch 271: 378-388, 1960.

19.   Gillen, CM, Brill S, Payne JA, and Forbush B, III. Molecular cloning and functional expression of the K-Cl cotransporter from rabbit, rat, and human. J Biol Chem 271: 16237-16244, 1996[Abstract/Free Full Text].

20.   Gunn, RB, Dalmark M, Tosteson DC, and Wieth JO. Characteristics of chloride transport in human red blood cells. J Gen Physiol 61: 185-206, 1973[Abstract/Free Full Text].

21.   Haas, M, and Forbush B, III. The Na-K-Cl cotransporter of secretory epithelia. Annu Rev Physiol 62: 515-534, 2000[ISI][Medline].

22.   Harris, EJ, and Maizels M. Distribution of ions in suspensions of human erythrocytes. J Physiol (Lond) 118: 40-53, 1952[ISI].

23.   Harris, EJ, and Pressman BC. Obligate cation exchanges in red cells. Nature 216: 918-920, 1967[ISI][Medline].

24.   Hiki, K, D'Andrea RJ, Furze J, Crawford J, Woolatt E, Sutherland GR, Vadas MA, and Gamble JR. Cloning, characterization, and chromosomal location of a novel human K+-Cl- cotransporter. J Biol Chem 274: 10661-10667, 1999[Abstract/Free Full Text].

25.   Holtzman, EJ, Kumar S, Faaland CA, Warner F, Logue PJ, Erickson SJ, Ricken G, Waldman J, and Dunham PB. Cloning, characterization, and gene organization of K-Cl cotransporter from pig and human kidney and C. elegans. Am J Physiol Renal Physiol 275: F550-F564, 1998[Abstract/Free Full Text].

26.   Isenring, P, Jacoby SC, Payne JA, and Forbush B, III. Comparison of Na-K-Cl cotransporters NKCC1, NKCC2, and the HEK cell Na-K-Cl cotransporters. J Biol Chem 273: 11295-11301, 1998[Abstract/Free Full Text].

27.   Jennings, ML. Proton fluxes associated with erythrocyte membrane anion exchange. J Membr Biol 28: 187-205, 1976[ISI][Medline].

28.   Jennings, ML. Volume-sensitive K+-Cl- cotransport in rabbit erythrocytes. Analysis of the rate-limiting activation and inactivation events. J Gen Physiol 114: 743-757, 1999[Abstract/Free Full Text].

29.   Jennings, ML, and Adams-Lackey M. A rabbit erythrocyte membrane protein associated with L-lactate transport. J Biol Chem 257: 12866-12871, 1982[Abstract/Free Full Text].

30.   Jennings, ML, Adams-Lackey M, and Denney GH. Peptides of human erythrocyte band 3 protein produced by extracellular papain cleavage. J Biol Chem 259: 4652-4660, 1984[Abstract/Free Full Text].

31.   Jennings, ML, and Al-Rohil N. Kinetics of activation and inactivation of swelling-stimulated K+-Cl- cotransport. Volume-sensitive parameter is the rate constant for inactivation. J Gen Physiol 95: 1021-1040, 1990[Abstract].

32.   Jennings, ML, and Schulz RK. Okadaic acid inhibition of KCl cotransport. Evidence that protein dephosphorylation is necessary for activation of transport by either cell swelling or N-ethylmaleimide. J Gen Physiol 97: 799-817, 1991[Abstract].

33.   Joiner, CH, Jiang M, Fathallah H, Giraud F, and Franco RS. Deoxygenation of sickle red blood cells stimulates KCl cotransport without affecting Na+/H+ exchange. Am J Physiol Cell Physiol 274: C1466-C1475, 1998[Abstract/Free Full Text].

34.   Kaji, D, and Tsukitani Y. Role of protein phosphatase in activation of KCl cotransport in human erythrocytes. Am J Physiol Cell Physiol 260: C178-C182, 1991.

35.   Kaji, DM. Effect of membrane potential on K-Cl transport in human erythrocytes. Am J Physiol Cell Physiol 264: C376-C382, 1993[Abstract/Free Full Text].

36.   Knauf, PA. Erythrocyte anion exchange and the band 3 protein: transport kinetics and molecular structure. Curr Top Membr Transp 12: 249-363, 1979.

37.   Larson, M, and Spring KR. Volume regulation by Necturus gallbladder: basolateral KCl exit. J Membr Biol 81: 219-232, 1984[ISI][Medline].

38.   Lauf, PK. Thiol-dependent passive K-Cl transport in sheep red cells. I. Dependence on chloride and external K+ (or Rb+) ions. J Membr Biol 73: 237-246, 1983[ISI][Medline].

39.   Lauf, PK, and Adragna NC. Temperature-induced functional deocclusion of thiols inhibitory for sheep erythrocyte K-Cl cotransport. Am J Physiol Cell Physiol 269: C1167-C1175, 1995[Abstract/Free Full Text].

40.   Lauf, PK, and Adragna NC. A thermodynamic study of electroneutral K-Cl cotransport in pH- and volume-clamped low K sheep erythrocytes with normal and low internal magnesium. J Gen Physiol 108: 341-350, 1996[Abstract].

41.   Lauf, PK, Bauer J, Adragna NC, Fujise H, Zade-Oppen AM, Ryu KH, and Delpire E. Erythrocyte K-Cl cotransport: properties and regulation. Am J Physiol Cell Physiol 263: C917-C932, 1992[Abstract/Free Full Text].

42.   Lu, J, Karadsheh M, and Delpire E. Developmental regulation of the neuronal-specific isoform of K-Cl cotransporter KCC2 in postnatal rat brains. J Neurobiol 39: 558-568, 1999[ISI][Medline].

43.   Lytle, C, and McManus TJ. Effect of loop diuretics and stilbene derivatives on swelling-induced K-Cl cotransport (Abstract). J Gen Physiol 90: 28A-29A, 1987.

44.   Lytle, CY. [Na-K-2Cl] and [K-Cl] Co-Transport in Duck Red Cells (Ph.D. dissertation). Durham, NC: Duke University, 1988.

45.   Macey, RI, Adorante JS, and Orme FW. Erythrocyte membrane potentials determined by hydrogen ion distributions. Biochim Biophys Acta 512: 284-295, 1978[ISI][Medline].

46.   Mercado, A, Song L, Vazquez N, Mount DB, and Gamba G. Functional comparison of the K+-Cl- cotransporters KCC1 and KCC4. J Biol Chem 275: 30326-30334, 2000[Abstract/Free Full Text].

47.   Mount, DB, Hoover RS, and Hebert SC. The molecular physiology of electroneutral cation-chloride cotransport. J Membr Biol 158: 177-186, 1997[ISI][Medline].

48.   Mount, DB, Mercado A, Song L, Xu J, George AL, Jr, Delpire E, and Gamba G. Cloning and characterization of KCC3 and KCC4, new members of the cation-chloride cotransporter gene family. J Biol Chem 274: 16355-16362, 1999[Abstract/Free Full Text].

49.   Omachi, A, Scott CB, and Glader BE. 2,4-Dinitrophenol inhibition of P32 release from human red cells. Experientia 24: 244-245, 1968[ISI][Medline].

50.   Payne, JA, Stevenson TJ, and Donaldson LF. Molecular characterization of a putative K-Cl cotransporter in rat brain. J Biol Chem 271: 16245-16252, 1996[Abstract/Free Full Text].

51.   Payne, JA, Xu J-C, Haas M, Lytle CY, Ward D, and Forbush B, III. Primary structure, functional expression, and chromosomal localization of the bumetanide-sensitive Na-K-Cl cotransporter in human colon. J Biol Chem 27: 17977-17985, 1995.

52.   Race, J, Makhlouf F, Logue P, Wilson F, Dunham P, and Holtzman E. Molecular cloning and functional characterization of KCC3, a new K-Cl cotransporter. Am J Physiol Cell Physiol 277: C1210-C1219, 1999[Abstract/Free Full Text].

53.   Reuss, L. Basolateral KCl co-transport in a NaCl-absorbing epithelium. Nature 305: 723-726, 1983[ISI][Medline].

54.   Rivera, C, Voipio J, Payne JA, Ruusuvuori E, Lahtinen H, Lamsa K, Pirvola U, Saarma M, and Kaila K. The K+-Cl- co-transporter KCC2 renders GABA hyperpolarizing during neuronal maturation. Nature 397: 251-255, 1999[ISI][Medline].

55.   Saitta, M, Cavalier S, Garay R, Cragoe EJ, and Hannaert PA. Evidence for a DIOA-sensitive (K+,Cl-) cotransport system in cultured vascular smooth muscle cells. Am J Hypertens 3: 939-942, 1990[ISI][Medline].

56.   Shami, Y, Rothstein A, and Knauf PA. Identification of the Cl- transport site of human red blood cells by a kinetic analysis of the inhibitory effects of a chemical probe. Biochim Biophys Acta 508: 357-363, 1978[ISI][Medline].

57.   Starke, LC, and Jennings ML. K-Cl cotransport in rabbit red cells: further evidence for regulation by protein phosphatase type 1. Am J Physiol Cell Physiol 264: C118-C124, 1993[Abstract/Free Full Text].

58.   Stewart, GW, and Blackstock EJ. Potassium transport in rabbit erythrocytes. Exp Biol 48: 161-165, 1989[ISI][Medline].

59.   Xu, J-C, Lytle C, Zhu TT, Payne JA, Benz E, Jr, and Forbush B, III. Molecular cloning and functional expression of the bumetanide-sensitive Na-K-Cl cotransporter. Proc Natl Acad Sci USA 91: 2201-2205, 1994[Abstract].

60.   Zeuthen, T. Cotransport of K+, Cl-, and H2O by membrane proteins from choroid plexus epithelium of Necturus maculosus. J Physiol (Lond) 478: 203-219, 1994[Abstract].


Am J Physiol Cell Physiol 281(3):C825-C832
0363-6143/01 $5.00 Copyright © 2001 the American Physiological Society