Thiol-dependent K∶Cl transport in sheep red cells: VIII. Activation through metabolically and chemically reversible oxidation by diamide

Summary The sulfhydryl (SH) oxidant diamide activated in a concentration-dependent manner ouabain-resistant (OR), Cl-dependent K flux in both low potassium (LK) and high potassium (HK) sheep red cells as determined from the rate of zero-trans K efflux into media with Cl or Cl replaced by NO₃ or methane sulfonate (CH₃SO₃). Diamide did not alter the OR Na efflux into choline Cl. The diamide effect on K efflux appeared after 80% of cellular glutathione (GSH) was oxidized to GSSG, its disulfide. The stimulation of K efflux was completely reversed during metabolic restitution of GSH, a process that depended on the length of exposure to and the concentration of diamide. The action of diamide on both the KCl transporter and GSH was also fully reversed by the reducing agent dithiothreitol (DTT). Diamide apparently oxidized the same SH groups alkylated by N-ethylmaleimide (NEM) (Lauf, P.K. 1983.J. Membrane Biol..73:237–246). Like NEM, diamide activated KCl transport several-fold more in LK cells than in HK cells, and the effect on LK cells was partially inhibited by anti-L₁, the allo-antibody known to inhibit OR K fluxes.     

Kinetic comparison of ouabain-resistant K:CI fluxes (K:Cl [Co]-transport) stimulated in sheep erythrocytes by membrane thiol oxidation and alkylation

Summary The stimulatory effects of two thiol (SH) group oxidants, methylmethane thiosulfonate (MMTS) and diazene dicarboxylic acid bis [N,N-dimethylamide] (diamide), on the kinetics of ouabain-resistant (OR) K:Cl [co]-transport in low K (LK) sheep red blood cells were compared with the effects of alkylating agents, notably N-ethylmaleimide (NEM). At low concentrations, both MMTS and diamide stimulated K:CI [co]-transportv and with a latency period, as measured by OR zero-trans K efflux and OR uptake of external Rb, Rb_o, as K congener in Cl and NO₃ media. At high concentrations the effect of diamide saturated, and that of MMTS disappeared. The stimulatory effect of MMTS was partially reversed by the reducing agent dithiothreitol (DTT) known to fully restore the diamide-activated K flux (Lauf, J. Memb. Biol. 101:179–188, 1988). In diamide pre-equilibrated LK sheep red cells, the K_m of K:Cl [co]-transport for external Cl, Cl_o, was 84.3 mM, and 18.7 mM for Rb_o, with nearly identical V_max values around 4 mmol Rb/L cells × h for K (Rb) fluxes in Cl and after correction for the small Cl-independent component. Zero net K (Rb) flux existed at K_c (cell K)/Rb_o concentration ratios, [K]_c/[Rb]_c, of 0.8 i.e. when the electrochemical driving forces across the membrane were about equal. The measured K efflux/Rb influx ratios were almost twice those predicted from [K]_c/[Rb]_o and the Cl equilibrium potential suggesting that the diamide-stimulated K (Rb) flux may occur through non-diffusional, carrier-mediated transport. The effects of NEM and of A23187 plus/minus Ca or chelators on K: [co]Cl-transport (Lauf, Am. J. Physiol. 249:C271–278, 1985) consisted primarily of V_max changes. Thus, all chemical interventions resulted in an increase of the number of actively transporting K:Cl [co]-transport units or an augmented turnover number per existing site.     

Evidence for inhibitory SH groups in the thiol activated K:Cl cotransporter of low K sheep red blood cells

The monofunctional thiol reagents N-ethylmaleimide (NEM) and methyl methanethiosulfonate (MMTS) stimulate ouabain resistant (OR) electroneutral K:Cl cotransport in LK sheep red blood cells at low, but not at high concentrations. Diamide (DM), on the other hand, only stimulates OR K:Cl flux (Lauf, P.K., J. Memb. Biol. 101: 179–188, 1988). The DM stimulated K:Cl cotransport was decreased toward the control value prior to DM stimulation when NEM or MMTS were added, subsequently. The inhibitory effect was dependent on the compound's concentration and exposure time and, in the case of MMTS, was reversed upon addition of dithiothreitol (DTT). The inhibition was more prominent when NEM treatment was performed at pH 8.0 and disappeared at pH 6.0. In contrast the NEM stimulatory effect was most effective when the pH of NEM treatment was 6.0 (Bauer, J. & Lauf, P.K., J. Memb. Biol. 73: 257–261, 1983). The results suggest the existence of additional, however, inhibitory thiol groups in the already thiol-activated K:Cl cotransporter, with a different pKa value and a lower affinity for NEM or MMTS as compared to the stimulatory thiol groups. Like the activating thiols, the inhibitory sulfhydryls appeared to be inaccessible to non-penetrating thiol reagents and hence, must be located deeper within the red cell membrane.     

Incorporation of 3H-N-ethylmaleimide into sheep red cell membrane thiol groups following protection by diamide-induced oxidation

The thiol oxidant diazene dicarboxylic acid bis [N,N-dimethylamide] (diamide) is known to reversibly activate K-Cl cotransport in sheep red blood cells [1]. Although the detailed mechanism of activation is unknown, functional thiols at the membrane or at the cytoplasmic level are recognized as important. To search for membrane bound thiols involved in the regulation of K-Cl cotransport, sheep red cells were first exposed to diamide at concentrations activating K-Cl cotransport, and then to the alkylating agent N-ethylmaleimide (NEM) in order to block non-oxidized thiols. White ghosts, prepared by osmotic lysis from these cells, were again treated with NEM followed by reduction of the diamide-induced dithiols with dithio-threitol (DTT) concentrations known to reverse the diamide-induced K-Cl flux [1]. Maximum ³H-NEM incorporation into the DTT-reduced thiols occurred at 50 M DTT. Saturation labelling by ³H-NEM of about 2 × 10⁴ diamide-protected thiols/cell occurred at 25 M NEM. Diamide protected about 0.1% of all membrane thiols chemically determined earlier [2]. Membranes from high K (HK) and low K (LK) sheep red cells did not differ significantly in the number of diamide-protected thiols, and polyacrylamide gels revealed a similar protein distribution of 3H-NEM-labelled thiols. Since diamide is known to stimulate K-Cl flux in LK cells ten times more than in HK cells this finding is consistent with the hypothesis of a cytoplasmic control effecting different K-Cl flux activities in the membranes of the two cation genotypic red blood cells.     

Passive potassium transport in LK sheep red cells. Modification by N- ethyl maleimide

Passive K transport, as modified by N-ethyl maleimide (NEM), was studied in erythrocytes of the low-K (LK) phenotype of sheep. Brief (5- min) treatment with NEM at less than 0.5 mM caused inhibition of passive K influx; NEM at concentrations greater than 0.5 mM caused stimulation of K influx. NEM had similar effects on K efflux. The treatments with NEM did not affect cell volumes (passive K transport in LK cells is sensitive to changes in cell volume). The stimulation of K transport by high [NEM] was also not a consequence of an effect on the metabolic state of the cells. Passive K transport in LK cells is dependent on Cl (it is inhibited in Cl-free media; it may be K/Cl cotransport). NEM had no effect on K influx in Cl-free (NO3- substituted) media. Pretreatment of the cells with anti-L antiserum (L antigen is found on LK cells and not on HK cells) prevented stimulation of K influx by NEM, but did not prevent inhibition. Therefore, NEM modifies the Cl-dependent K transport pathway at two separate sites, a low-affinity site, at which it stimulates, and a high-affinity site, at which it inhibits. Anti-L antibody prevents NEM's action, but only at the low-affinity site.     

Effects of A23187 and Ca2+ on volume- and thiol-stimulated, ouabain-resistant K+C1- fluxes in low K+ fluxes in low K+ sheep erythrocytes

Ouabain-resistant (OR), C1- -dependent K+ (K+C1-) transport measured by Rb+ influx in isosmotic and anisosmotic media was stimulated by the Ca2+ ionophore A23187 and EGTA (ethylene-glycol-tetracetic acid) in low K+ (LK) but not in high K+ (HK) sheep red cells. Increasing external Ca2+ concentrations, [Ca2+]o, from about 10(-7) to 10(-3)M in presence of A23187 and in absence of EGTA inhibited OR Rb+ influx, in LK red cells osmotically shrunken or swollen as well as treated with the thiol reagent N-ethylmaleimide (NEM). Hence the volume- and the NEM-stimulated K+C1- transport system in LK cells can be experimentally modulated by cellular Ca2+ or other Me2+, which may interact with sites on the K+C1- transporter under the control of membrane sulfhydryl (SH) groups.     

The effect of anti-L on ouabain binding to sheep erythrocytes.

Binding of 3H-ouabain was studied in high potassium (HK) and low potassium (LK) sheep red cells. In particular, we investigated the effect of anti-L, an antibody raised in HK sheep against L-positive LK sheep red cells, on 3H-oubain binding and its relation to K+ -pump flux inhibition in LK cells. HK cells were found to have about twice as many 3H-ouabain binding sites and a higher association rate for 3H-ouabain than homozygous LL-type LK cells. The number of 3H-ouabain molecules bound to heterozygous LM-type LK cells is lower than that on LL cells, but the rate of ouabain binding is between that of HK and LL red cells. A close correlation was observed between the rates of 3H-oubain binding and fraction K+-pump inhibition. Exposure of LM and LL cells to anti-L did not affect the number of 3H-ouabain molecules bound at saturation, but increased the rates of glycoside binding and K+ -pump inhibition proportionately, so that for LK cells in the presence of anti-L, the rates of the two processes approximate those of HK cells. These data exclude the possibility that anti-L generates entirely new pump sites in LK sheep cells, but suggest that the antibody increases the affinity of the existing -a+ -K+ pumps for the glycoside.     

Role of Nitrite, a Nitric Oxide Derivative, in K-Cl Cotransport Activation of Low-Potassium Sheep Red Blood Cells

K-Cl cotransport (COT) is the coupled movement of K and Cl, present in most cells, associated with regulatory volume decrease, susceptible to oxidation and functionally overexpressed in sickle cell anemia. The aim of this study was to characterize the effect of the oxidant nitrite (NO₂ ⁻) on K-Cl COT. NO₂ ⁻ is a stable metabolic end product of the short-lived highly reactive free radical nitric oxide (NO), an oxidant and modulator of ion channels, and a vasodilator. In some systems, the response to NO₂ ⁻ is identical to that of NO. We hypothesized that NO₂ ⁻ activates K-Cl COT. Low potassium (LK) sheep red blood cells (SRBCs) were used as a model. The effect of various concentrations (10⁻⁶ to 10⁻¹ m) of NaNO₂ was studied on K efflux in hypotonic Cl and NO₃ media, Cl-dependent K efflux (K-Cl COT), glutathione (GSH), and methemoglobin (MetHb) formation. In support of our hypothesis, K efflux and K-Cl COT were stimulated by increasing concentrations of NaNO₂. Stimulation of K efflux was dependent upon external Cl and exhibited a lag phase, consistent with activation of K-Cl COT through a regulatory mechanism. Exposure of LK SRBCs to NaNO₂ decreased GSH, an effect characteristic of a thiol-oxidizing agent, and induced MetHb formation. K-Cl COT activity was positively correlated with Methb formation. N-ethyl-maleimide (NEM), a potent activator of K-Cl COT, was used to assess the mechanism of NO₂ ⁻ action. The results suggest that NEM and NO₂ ⁻ utilize at least one common pathway for K-Cl COT activation. Since NaNO₂ is also a well known vasodilator, the present findings suggest a role of K-Cl COT in vasodilation. Received: 15 January 1998/Revised: 3 September 1998     

Quinine and quinidine inhibit and reveal heterogeneity of K-Cl cotransport in low K sheep erythrocytes

Low K (LK) sheep red blood cells (SRBCs) serve as a model to study K-Cl cotransport which plays an important role in cellular dehydration in human erythrocytes homozygous for hemoglobin S. Cinchona bark derivatives, such as quinine (Q) and quinidine (QD), are effectively used in the treatment of malaria. In the present study, we investigated in LK SRBCs, the effect of various concentrations of Q and QD on Cl-dependent K efflux and Rb influx (K(Rb)-Cl flux), activated by either swelling in hyposmotic media, thiol alkylation with N-ethylmaleimide (NEM), or by cellular Mg (Mg _i ) removal through A23187 in the presence of external chelators. K efflux or Rb influx were determined in Cl and NO₃ medium and K(Rb)-Cl flux was defined as the Cl-dependent (Cl minus NO₃) component. K(Rb)-Cl flux stimulated by all three interventions was inhibited by both Q and QD in a dose-dependent manner. Maximum inhibition of K(Rb)-Cl flux occurred at Q and QD concentrations ?1 mm. The inhibitory effect of Q was manifested in Cl, but not in NO₃, whereas QD reduced K and Rb fluxes both in Cl and NO₃ media. The mean 50% inhibitory concentration (IC⁵⁰) of Q and QD to inhibit K(Rb)-Cl flux varied between 0.23 and 2.24 mm. From determinations of the percentages of inhibition of the different components of K and Rb fluxes, we found that SRBCs possess a Cl-dependent QD-sensitive and a Cl-dependent QD-insensitive K efflux and Rb influx. These two components vary in magnitude depending on the manipulation and directional flux, but in average they are about 50% of the total Cl-dependent flux. This study raises the possibility that, in SRBCs, the Cl-dependent K(Rb) fluxes are heterogeneous. This work was supported by a grant from the National Institutes of Health (NIH DK5RO1 37,160).     

The effect of diamide on amino acid transport by rat renal cortex slices.

Diamide directly added to renal cortical slices inhibits the uptake of amino acids. Steady-state kinetic analysis indicates an inhibition of alpha-amino acid influx without effect on efflux. The effect could be reversed by addition of pyruvate to the incubation medium. Although there was a good correlation of the transport effect of diamide with its ability to decrease cellular reduced glutathione concentration, there did not appear to be a necessary connection between them. This was shown by the fact that renal cortical slices stored at 4 degrees C have no alteration in amino acid uptake despite the fact that GSH concentration is as low as that seen with diamide. Diamide was shown to have a direct effect on the uptake of glycine by isolated renal brush border membrane vesicles.     

L-antigen and active potassium transport in HK and LK red cells of Barbary sheep (Ammotragus lervia)

1. The potassium concentration in red cells of 21 Barbary sheep showed a bimodal distribution, with five animals of LK type (K+ conc. 30-45 mM) and 16 of HK type (K+ conc. 80-95 mM). 2. Evidence is presented that both Lp and Ll antigens are present on LK Barbary sheep red cells. 3. Active K+ transport in LK Barbary sheep red cells was stimulated 3-5 fold by sheep and goat anti-L. 4. Active K+ transport in HK Barbary sheep red cells was higher than in LK red cells. Five out of six HK animals tested showed no stimulation of active K+ transport with anti-L. One HK animal (2BA2) showed some stimulation of active K+ transport, and also absorbed some anti-L from antisera, suggesting that Lp antigen is present on these red cells. 5. Ouabain-sensitive ATPase in membranes from HK and LK Barbary sheep red cells showed kinetics characteristic of HK and LK membranes of domestic goats and sheep; the ATPase of LK Barbary sheep membranes sensitized with anti-L was stimulated 2-fold due to an alteration in the internal sodium and potassium affinities in favour of sodium.     

The effect of diamide on amino acid transport by rat renal cortex slices

Diamide directly added to renal cortical slices inhibits the uptake of amino acids. Steady-state kinetic analysis indicates an inhibition of α-amino acid influx without effect on efflux. The effect could be reversed by addition of pyruvate to the incubation medium. Although there was a good correlation of the transport effect of diamide with its ability to decrease cellular reduced glutathione concentration, there did not appear to be a necessary connection between them. This was shown by the fact that renal cortical slices stored at 4°C have no alteration in amino acid uptake despite the fact that GSH concentration is as low as that seen with diamide. Diamide was shown to have a direct effect on the uptake of glycine by isolated renal brush border membrane vesicles.     

Direct involvement of spectrin thiols in maintaining erythrocyte membrane thermal stability and spectrin dimer self-association

Human erythrocytes vesiculate upon exposure to temperatures of 49 degrees C and above. Pretreatment of the cells with the thiol-alkylating agent N-ethylmaleimide (NEM) lowers the temperature needed to produce the same effect. Concomitant with the cells' heat susceptibility, skeletal mechanical instability and an increase in spectrin dissociation have been reported (Smith and Palek (1983) Blood 62, 1190). In the present study, similar results were achieved by preincubation of the cells with diamide, which could be reversed by reduction with dithiothreitol. Another oxidative agent, sodium tetrathionate, could only induce the temperature susceptibility, with little effect on spectrin dissociation. Incubation of spectrin solutions with NEM or diamide caused decreased association of spectrin dimers and increased dissociation of spectrin tetramers. Estimation of membrane and spectrin thiols in the treated cells showed that NEM was effective while blocking less than 20% of the thiols. Diamide and tetrathionate blocked more than 50% of the thiols, but were less effective than NEM. It is suggested that some very defined population of thiols is essential for spectrin self-association and for membrane thermal stability. They are more available to NEM than to diamide and less so to tetrathionate. Other thiols participate in maintaining the membrane thermal stability only.     

Regulation of Cell Volume by Active Cation Transport in High and Low Potassium Sheep Red Cells

A model cell which controls its cation composition and volume by the action of a K-Na exchange pump and leaks for both ions working in parallel is presented. Equations are formulated which describe the behavior of this model in terms of three membrane parameters. From these equations and the steady state concentrations of Na, K, and Cl, values for these parameters in high potassium (HK) and low potassium (LK) sheep red cells are calculated. Kinetic experiments designed to measure the membrane parameters directly in the two types of sheep red cells are also reported. The values of the parameters obtained in these experiments agreed well with those calculated from the steady state concentrations of ions and the theoretical equations. It is concluded that both HK and LK sheep red cells control their cation composition and volume in a manner consistent with the model cell. Both have a cation pump which exchanges one sodium ion from inside the cell with one potassium ion from outside the cell but the pump is working approximately four times faster in the HK cell. The characteristics of the cation leak in the two cell types are also very different since the HK cells are relatively more leaky to sodium as compared with potassium than is the case in the LK cells. Both cell types show appreciable sodium exchange diffusion but this process is more rapid in the LK than in the HK cells.     

Antibody-Induced Alterations in the Kinetic Characteristics of the Na:K Pump in Goat Red Blood Cells

The kinetic characteristics of the Na:K pump in high potassium (HK) and low potassium (LK) goat red cells were investigated after altering the intracellular cation concentrations. At low concentrations of intracellular K (K_c), increasing K_c at first stimulates the active K influx in HK cells, but at higher K_c the pump is inhibited. These results suggest that in HK cells K_c acts both at a stimulatory site at the inner aspect of the pump and by competition with intracellular Na (Na_c) at the Na translocation sites. In LK cells, K_c inhibits the active K influx and the sensitivity of LK cells to inhibition is much greater than the sensitivity of HK cells. Exposure of LK cells to an antibody (anti-L), raised in an HK sheep by injection of LK sheep cells, increased the active K influx at any given K_c. The effect of the antibody was greater at higher intracellular K concentrations, and in cells with very low concentrations of K the antibody had little effect on the pump rate. The failure of anti-L to stimulate the pump in low K_c LK cells was not due to failure of the antibody to bind to the cells. Anti-L combining at the outer surface of the cell reduces the affinity of the pump at the inner surface for K at the inhibitory sites. The maximal pump rate in LK cells at optimal Na and K concentrations is less than the maximal pump rate of HK cells under the same circumstances.     

Volume-activated Na/H exchange activity in fetal and adult pig red cells: Inhibition by cyclic AMP

Summary Hyposmotic swelling of pig red cells leads to a selective increase in K permeability, whereas hyperosmotic cell shrinkage augments the Na permeability. In this regard, the ouabain-resistant (OR) Na flux of red cells of newborn and adult pigs is characterized in detail. A reduction in cell volume by approximately 18% leads to an increase in the OR Na efflux of fetal and adult cells by 15-and fourfold, respectively. The OR Na influx in both cell types is equally influenced by cell shrinkage. Depletion of cellular K does not influence the volume-activated OR Na efflux. Nor does OR Na influx require external K. Both OR Na efflux and influx activated by shrinkage are inhibited by the diuretics furosemide and amiloride. The rank order of decreasing anion sensitivity for diuretic-sensitive Na efflux was acetate > chloride > gluconate > nitrate. Cell shrinkage induced by the addition of hypertonic salts results in an acidification of the unbuffered and CO₂-free media, provided that both Na and DIDS are present. The qcidification process can be reversed by either of the diuretic agents. These findings suggest that the shrinkageactivated OR Na flux is primarily mediated by a Na/H exchanger rather than by a Na/K/Cl cotransporter. Once loaded with either cAMP or cGMP, cell swelling can no longer activate the Na/H exchanger. The Na/H exchanger activity is detectable in the fetal cells of normal volume but quiescent in adult cells, indicating that the exchanger undergoes a developmental change during the transition from the fetal to adult stage.     

Oxidant-induced S-glutathiolation inactivates protein kinase C-alpha (PKC-alpha): a potential mechanism of PKC isozyme regulation

Protein kinase C (PKC) isozymes are subject to inactivation by reactive oxygen species (ROS) through as yet undefined oxidative modifications of the isozyme structure. We previously reported that Cys-containing, Arg-rich peptide-substrate analogues spontaneously form disulfide-linked complexes with PKC isozymes, resulting in isozyme inactivation. This suggested that PKC might be inactivated by oxidant-induced S-glutathiolation, i.e., disulfide linkage of the endogenous molecule glutathione (GSH) to PKC. Protein S-glutathiolation is a reversible oxidative modification that has profound effects on the activity of certain enzymes and binding proteins. To directly examine whether PKC could be inactivated by S-glutathiolation, we used the thiol-specific oxidant diamide because its oxidant activity is restricted to induction of disulfide bridge formation. Diamide weakly inactivated purified recombinant cPKC-alpha, and this was markedly potentiated to nearly full inactivation by 100 microM GSH, which by itself was without effect on cPKC-alpha activity. Diamide inactivation of cPKC-alpha and its potentiation by GSH were both fully reversed by DTT. Likewise, GSH markedly potentiated diamide inactivation of a PKC isozyme mixture purified from rat brain (alpha, beta, gamma, epsilon, zeta) in a DTT-reversible manner. GSH potentiation of diamide-induced cPKC-alpha inactivation was associated with S-glutathiolation of the isozyme. cPKC-alpha S-glutathiolation was demonstrated by the DTT-reversible incorporation of [(35)S]GSH into the isozyme structure and by an associated change in the migration position of cPKC-alpha in nonreducing SDS-PAGE. Diamide treatment of NIH3T3 cells likewise induced potent, DTT-reversible inactivation of cPKC-alpha in association with [(35)S] S-thiolation of the isozyme. Taken together, the results indicate that PKC isozymes can be oxidatively inactivated by S-thiolation reactions involving endogenous thiols such as GSH.     

GSH depletion, K-Cl cotransport, and regulatory volume decrease in high-K/high-GSH dog red blood cells

Thiol reagents activateK-Cl cotransport (K-Cl COT), the Cl-dependent and Na-independentouabain-resistant K flux, in red blood cells (RBCs) of several species,upon depletion of cellular glutathione (GSH). K-Cl COT isphysiologically active in high potassium (HK), high GSH (HG) dog RBCs.In this unique model, we studied whether the same inverse relationshipexists between GSH levels and K-Cl COT activity found in other species.The effects of GSH depletion by three different chemical reactions[nitrite (NO₂)-mediated oxidation, diazene dicarboxylicacid bis-N,N-dimethylamide (diamide)-induceddithiol formation, and glutathione S-transferase (GST)-catalyzed conjugation of GSH with 1-chloro-2,4-dinitrobenzene (CDNB)] were tested on K-Cl COT and regulatory volume decrease (RVD).After 85% GSH depletion, all three interventions stimulated K-Cl COThalf-maximally with the following order of potency: diamide > NO₂ > CDNB. Repletion of GSH reversed K-Cl COTstimulation by 50%. Cl-dependent RVD accompanied K-Cl COT activationby NO₂ and diamide. K-Cl COT activation at concentrationratios of oxidant/GSH greater than unity was irreversible, suggestingeither nitrosothiolation, heterodithiol formation, or GST-mediateddinitrophenylation of protein thiols. The data support the hypothesisthat an intact redox system, rather than the absolute GSH levels,protects K-Cl COT activity and cell volume regulation from thiol modification.

     

The influence of glutathione oxidation on renal cortex taurine transport

The interaction of diamide, a rapidly reversible thioloxidizing re reagent, with the taurine accumulation system was examined in rat kidney cortex slices from animals of different ages. Diamide at 10 mM lowered renal cortex glutathione content by 80% at a time that taurine accumulation was inhibited by 65%. Although the addition of equimolar GSH overcame diamide inhibition of taurine uptake, GSH per se inhibited taurine accumulation at 0.01 mM, but not at 0.2 or 1.0 mM. Dithiothreitol (DTT) also overcame diamide inhibition of uptake. As previously shown by Pillion et al (Eur. J. Biochem. $\text{79}$, 73, 1977) diamide inhibited gluconeogenesis by cortex slices.Diamide inhibited taurine accumulation by 85% by the low Km taurine transport site in cortex from newborn, 2 week, 4 week and adult animals, but only 50% at the high Km site. In contrast to the situation in adult tissue, efflux of taurine from preloaded slices of immature animals was not increased by diamide. Accordingly, one maturational event identified by these studies is that diamide-enhanced efflux was found only in mature cortex.     

Active Cation Transport and Ouabain Binding in High Potassium and Low Potassium Red Blood Cells of Sheep

Red cells from high K sheep contained 82 mM K/liter cells and had a pump flux of 0.86 mM K/liter cells x hr; similarly, LK cells had 16.5 mM K/liter cells and a pump flux of 0.12 mM K/liter cells x hr. Using [³H]-ouabain, the relation between the number of ouabain molecules bound per cell and the concomitant per cent inhibition of the pump was found to be approximately linear for both HK and LK cells. The number of glycoside molecules necessary for 100 % inhibition of the pump was 42 for HK cells and 7.6 for LK cells, after correction for six nonspecific binding sites for each type of cell. The ratio of ouabain molecules/cell at 100 % inhibition was 5.5, HK to LK, and the ratio of the normal K pump fluxes was 7.2, HK to LK. The similarity of these ratios suggests that an important difference between HK and LK cells, determining the difference in pump fluxes, is the number of pump sites. The turnover times (ions/site x min) are 6000 and 4800 for HK and LK cells, respectively. The results also indicate a high specificity of binding of ouabain to pump sites.