Characterization of oxalate transport by the human erythrocyte band 3 protein

This paper describes characteristics of the transport of oxalate across the human erythrocyte membrane. Treatment of cells with low concentrations of H2DIDS (4,4'-diisothiocyanatostilbene-2,2'- disulfonate) inhibits Cl(-)-Cl- and oxalate-oxalate exchange to the same extent, suggesting that band 3 is the major transport pathway for oxalate. The kinetics of oxalate and Cl- self-exchange fluxes indicate that the two ions compete for a common transport site; the apparent Cl- affinity is two to three times higher than that of oxalate. The net exchange of oxalate for Cl-, in either direction, is accompanied by a flux of H+ with oxalate, as is also true of net Cl(-)-SO4(2-) exchange. The transport of oxalate, however, is much faster than that of SO4(2-) or other divalent anions. Oxalate influx into Cl(-)-containing cells has an extracellular pH optimum of approximately 5.5 at 0 degrees C. At extracellular pH below 5.5 (neutral intracellular pH), net Cl(-)- oxalate exchange is nearly as fast as Cl(-)-Cl- exchange. The rapid Cl(- )-oxalate exchange at acid extracellular pH is not likely to be a consequence of Cl- exchange for monovalent oxalate (HOOC-COO-; pKa = 4.2) because monocarboxylates of similar structure exchange for Cl- much more slowly than does oxalate. The activation energy of Cl(-)- oxalate exchange is about 35 kCal/mol at temperatures between 0 and 15 degrees C; the rapid oxalate influx is therefore not a consequence of a low activation energy. The protein phosphatase inhibitor okadaic acid has no detectable effect on oxalate self-exchange, in contrast to a recent finding in another laboratory (Baggio, B., L. Bordin, G. Clari, G. Gambaro, and V. Moret. 1993. Biochim. Biophys. Acta. 1148:157-160.); our data provide no evidence for physiological regulation of anion exchange in red cells.     

DNA strand break rejoining in human lymphocytes during the S phase

Induction and repair of DNA strand breaks in asynchronous and synchronized cultures of human lymphocytes was investigated by using the alkaline DNA-unwinding technique followed by chromatography on hydroxylapatite. Strand break rejoining in exponentially growing human PHA stimulated lymphocytes, irradiated with 20 Gy of X-rays, is temperature-dependent, being fast at 37 degrees C (half-time of a few minutes), and very slow at around 4 degrees C. In synchronized cells irradiated with the same X-ray dose, the repair capacity increases during S phase reaching its maximum when DNA is entirely duplicated.     

Multiple fractions of sodium exchange in human lymphocytes

Human lymphocytes contain a large, saturable fraction of K⁺ that exchanges slowly with K⁺ in the external medium, and a small non-saturable fraction that exchanges rapidly. We determined whether or not Na⁺ exchanges in a similar manner with external Na⁺. Cells were pre-equilibrated to ensure absence of net ion movements. Efflux was studied by loading with ²²Na and transferring without washing to a non-labeled medium. Influx was studied by transferring to labeled medium and separating large samples of cells at 6,000g. There are fast, intermediate, and slow fractions of Na⁺ exchange, with half-times of 2, 14, and 120 minutes. At normal external K⁺, most cell Na⁺ exchanges rapidly, while at lower external K⁺ the Na⁺ that replaces cell K⁺ exchanges slowly. Parallel sources of fast and slow fractions, such as extracellular ones and subpopulations of cells, were ruled out by simultaneous ⁴²K and ²²Na fluxes and by a quantitative analysis of the combined K⁺ and Na⁺ content and flux data over a range of external K⁺ and Na⁺ levels. Five possible models of ion fluxes occurring in series were considered. Surface matrix, surface binding sites, and cytoplasmic channels with rapid nuclea exchange were eliminated as sources of the fast fractions. Therefore, the fast fractions of K⁺ and Na⁺ must reflect the permeability of the surface membrane. This left only two possible sources of the slow fractions. One, a subcellular compartment (e.g., nucleus), was eliminated by the combined content and flux data. We conclude that the slow fractions of ion flux are rate-limited by adsorption onto and desorption from cellular macromolecules. The data support the association-induction hypothesis and are understood by reference to two fundamental concepts: that of rapid solute exclusion from cell water existing in a polarized state; and that of solute accumulation limited by adsorption onto fixed anionic sites within the cell.     

The distribution and kinetics of release of radiocalcium in tendon and skeletal muscle

The distribution of Ca(45) in frog (Rana pipiens) sartorius muscle, after 4 hours' exposure to Ringer's solution containing radiocalcium, has been analyzed by observing the kinetics of escape of the radioisotope into a non-radioactive Ringer's solution with calcium present or absent and by assuming that the tendon of Achilles is a satisfactory model of the extent of the uptake and release of Ca(45) by the interstitial connective tissue (c.t.). In a Ringer's solution containing 1 mM/liter calcium, the exchangeable calcium distribution in micromoles per gram wet weight is as follows: (a) Aqueous phase of c.t. space: 0.16; (b) bound to c.t.: 0.16; (c) bound to surface of fibers: 0.13, of which 0.03 is displaced only by self-exchange, whereas the rest, as in c.t., can be displaced by other ions; and (d) in myoplasm: 0.33. The kinetics of Ca(45) exit suggests that in infinite time of exposure to Ca(45) the myoplasmic component would rise to 0.85. In the muscles, the half-time of the quickly emerging Ca(45) averages about 3 minutes, whereas the time constant of the slowly released component is about 500 minutes. In the tendons the percentage rate of escape falls exponentially, the half-time of emergence being about 10 minutes.     

Light-induced proton transport by chloroplasts suspended in fluid media at sub-zero temperatures: kinetics and stoichiometry.

1. Chloroplasts suspended in a medium containing ethanediol and water (1 : 1, v/v) at -16 degrees C show light-induced proton uptake and subsequent dark efflux. Proton uptake in continuous light showed biphasic kinetics. 2. A 1 ms flash caused a single turnover of the photochemical centres at -16 degrees C. Under the same conditions 3H+ were taken up from the external medium in the presence of methyl viologen as electron acceptor. 3. The flash-induced proton uptake was exponential and monophasic with t1/2 = 3 s. The flash-induced proton release into the thylakoid interior was biphasic, with half-times of less than 0.1 s and 3 s. The fast phase represented approximately 30% of the total release and may be correlated with the oxidation of water. 4. The half-time of reduction of cytochrome f in the dark following illumination in the presence of 2 mM NH4Cl (2.5 s) is similar to the half-time of the slow phase of proton release, suggesting a correlation between the kinetics of cytochrome f reduction and plastoquinol oxidation.     

Kainate-induced uptake of calcium by synaptosomes from rat brain

Kainic acid induces a rapid increase in 45Ca2+ uptake by crude synaptosomal fractions isolated from rat brain. This enhanced Ca2+ permeability occurs with a half-time of approx. 1 s, similar to the fast phase of depolarization-induced calcium uptake. The depolarization-induced uptake of calcium is inhibited 85% by 3 mM CoCl2, 80% by 100 microM quinacrine and 50% by 15 microM trifluoperazine while these agents had little effect on the kainate-induced uptake. It is proposed that kainate induces receptor-mediated opening of a class of calcium channels with properties different from those of the voltage-dependent channels.     

Anion/anion exchange in human neutrophils

Of the total one-way chloride fluxes (approximately 1.4 meq/liter cell water X min) in steady state human polymorphonuclear leukocytes bathed in 148 mM Cl media, approximately 70% behaves as self-exchange mediated by a nonselective anion carrier that is not inhibited by stilbene disulfonates. Five properties of this carrier-mediated exchange were investigated: substrate saturation is seen with respect to 36Cl influx as a function of the external Cl concentration [for normal-Cl cells, the apparent Km(Cl) is approximately 22 mM when Cl replaces para-amino- hippurate (PAH) and approximately 5 mM when Cl replaces glucuronate], and with respect to 36Cl efflux as a function of the concentration of internal Cl replacing PAH [apparent Km(Cl) congruent to 35 mM for cells bathed in 148 mM Cl]; there is trans stimulation of 36Cl influx by internal Cl (replacing PAH) with an apparent Km(Cl) congruent to 35 mM, and of 36Cl efflux by external Cl with an apparent Km(Cl) congruent to 22 mM (Cl replacing PAH) or approximately 5 mM (Cl replacing glucuronate); there is substrate competition between Cl and PAH, but the carrier appears devoid of affinity for glucuronate; influxes and effluxes mediated by the carrier are subject to competitive inhibition by extracellular alpha-cyano-4-hydroxycinnamate (CHC), with an apparent Ki congruent to 9 mM in Cl medium or approximately 1 mM in PAH medium (transport of the inhibitor itself is very slow); and internal Cl and external Cl or PAH undergo 1:1 countertransport, which is CHC sensitive. A simple equilibrium-competition model is proposed that accounts for all the extracellular ligand interactions presented for normal-Cl cells. Least-squares values of the carrier's true Michaelis constants for extracellular Cl, PAH, and CHC are 5.03 +/- 0.83, 50.3 +/- 14.9, and 0.29 +/- 0.09 mM, respectively.     

H Uptake and Extrusion by Nitella clavata

Very high rates of H⁺ extrusion by internodal cells of Nitella clavata Kutz were measured after acid loading at pH 4.6. The highest rate observed, 160 picomoles per square centimeter per second, was more than twice the rate of photosynthetic bicarbonate utilization under saturating light. These results are consistent with the recently proposed hypothesis that bicarbonate is not taken in directly but is protonated at the exterior surface; the CO₂ thereby formed diffuses preferentially into the cell because of the asymmetric concentration gradient.

The H⁺ taken up, about 150 nanomoles per square centimeter in 2 hours, was distributed in three fractions: 30% in the cell wall, 40% in the cytoplasm, and 30% in the vacuole. This was concluded from the kinetics of the H⁺ release by intact cells and isolated walls, and from the pH decrease of the vacuolar sap.

The cytoplasmic H⁺ was extruded rapidly, with a half-time of about 2 minutes when the external pH was 5.7 or higher. The extrusion of the vacuolar H⁺ only proceeded at a measurable rate when the [K⁺] in the medium was raised to 20 millimolar; the half-time was about 100 minutes. There was little H⁺ extruded when the external pH was 5.0.

     

The mechanism of anion transport across human red blood cell membranes as revealed with a fluorescent substrate: I. Kinetic properties of NBD-taurine transfer in symmetric conditions

Summary The molecular mechanism of anion exchange across the human red blood cell membrane was assessed with the fluorescent substrate analog NBD-taurine and the method of continuous monitoring of transport by fluorescence. The efflux of NBD-taurine was studied under a variety of experimental conditions such as temperature, pH and anion composition of cells and media. The temperature profile of NBD-taurine transfer from Cl-loaded cells into Cl media resembled that of Cl self-exchange, whereas that of NBD-taurine transfer from sulfate-loaded cells into sulfate media resembled that of sulfate self-exchange. Although the pH profiles of NBD-taurine transfer from Cl-loaded cells into Cl media and that of Cl self-exchange resembled each other, the analogous transfer with sulfate replacing Cl was markedly different. These and other data were analyzed and found to be consistent with a model which comprises the following: (a) a H⁺-titratable group in the carrier mechanism; (b) alteration of transport sites between the two sides of the membrane (i.e., ping-pong kinetics); and (c) transmembrane distribution of transport sites which is modulated by pH. It is shown that NBD-taurine transfer represents a tracer flux of a fluorescent substrate which gives a measure for the presence of monovalent transport sites at the inner surface of the membrane. The latter is markedly affected by the relative concentrations of anions and H⁺ on both sides of the red blood cell membrane.     

Reversibility of the low-salt transition of chromatin core particles.

The low-salt transition of chromatin core particles is reversible if the monovalent cation concentration is kept above 0.2 mM. Exposure of the particles to salt concentrations below this value results in a nonreversible secondary transition. The nonreversible changes are relatively slow with a half-time of about 15 minutes. Once exposed to such low ionic strength, the particles then begin to refold with increasing salt in at least two steps over a much higher ionic strength range than is required for the usual low-salt transition. The refolding is very fast, with a half-time less than a minute. Small differences between particles which had or had not been exposed to very low salt persist even when the particles are returned to near physiological ionic strengths.     

pH-dependent charge equilibria between tyrosine-D and the S states in photosystem II. Estimation of relative midpoint redox potentials

The effect of protonation events on the charge equilibrium between tyrosine-D and the water-oxidizing complex in photosystem II has been studied by time-resolved measurements of the EPR signal IIslow at room temperature. The flash-induced oxidation of YD by the water-oxidizing complex in the S2 state is a monophasic process above pH 6.5 and biphasic at lower pHs, showing a slow and a fast phase. The half-time of the slow phase increases from about 1 s at pH 8.0 to about 20 s at pH 5.0, whereas the half-time of the fast phase is pH independent (0.4-1 s). The dark reduction of YD+ was followed by measuring the decay of signal IIslow at room temperature. YD+ decays in a biphasic way on the tens of minutes to hours time scale. The minutes phase is due to the electron transfer to YD+ from the S0 state of the water-oxidizing complex. The half-time of this process increases from about 5 min at pH 8.0 to 40 min at pH 4.5. The hours phase of YD+ has a constant half-time of about 500 min between pH 4.7 and 7.2, which abruptly decreases above pH 7.2 and below pH 4.7. This phase reflects the reduction of YD+ either from the medium or by an unidentified redox component of PSII in those centers that are in the S1 state. The titration curve of the half-times for the oxidation of YD reveals a proton binding with a pK around 7.3-7.5 that retards the electron transfer from YD to the water-oxidizing complex. We propose that this monoprotic event reflects the protonation of an amino acid residue, probably histidine-190 on the D2 protein, to which YD is hydrogen bonded. The titration curves for the oxidation of YD and for the reduction of YD+ show a second proton binding with pK approximately 5.8-6.0 that accelerates the electron transfer from YD to the water-oxidizing complex and retards the process in the opposite direction. This protonation most probably affects the water-oxidizing complex. From the measured kinetic parameters, the lowest limits for the equilibrium constants between the S0YD+ and the S1YD as well as between the S1YD+ and S2YD states were estimated to be 5 and 750-1000, respectively.(ABSTRACT TRUNCATED AT 400 WORDS)     

Asymmetry in the mechanism for anion exchange in human red blood cell membranes. Evidence for reciprocating sites that react with one transported anion at a time

The kinetics of chloride and bromide transport were examined in intact human red blood cells and resealed ghosts. Because the influx and efflux of halide ions are almost equal (less than 0.01% difference), the stimulation of the exchange flux by external halides could be determined by measuring 36Cl or 82Br efflux. When the external halide concentration was increased by replacement of isoionic, isotonic solutions of sucrose and the nontransported anion citrate, the stimulation of the exchange flux was hyperbolic and was maximum at 20 mM halide externally. The K 1/2-out, the external concentration of chloride or bromide which stimulated the efflux to half of its maximum value, was 3 and 1 mM respectively, 15-fold smaller than K 1/2-in which we found to be about equal to the K 1/2 of halide self-exchange with nearly equal internal and external concentrations. Thus, the transport mechanism behaves asymmetrically with respect to these transported halides. Bromide flux was two-fold greater in bromide-chloride heteroexchange than in bromide-bromide self-exchange but it was still much smaller than the chloride self-exchange flux. The maximum influx and efflux of bromide in exchange for chloride were roughly eqal. Thus, since the maximum transport rates in the two directions are nearly equal, the kinetics of bromide equilibrium exchange with equal concentrations on the two sides are controlled on the inside where K 1/2 is greatest. The K 1/2-out Cl was a hyperbolic function of internal chloride concentration and was proportional to the maximum flux at each internal chloride concentration. These results are evaluated in terms of two broad categories of models. We conclude that, in contrast to other ion transport systems which have been shown to have kinetics of a sequential mechanism, anion exchange is compatible with a ping-pong mechanism in which a single site reciprocates between inside- and outside-facing orientations with asymmetric K 1/2 values.     

Anion transport in embryonic and adult chicken red blood cells

The rates of Cl and SO₄ transport at 0° and 37°C, respectively, have been measured under exchange conditions for red blood cells of embryonic and adult chickens. It was found that the rate of self-exchange of SO₄ in embryonic red cells decreases as the embryo matures, and that the SO₄ transport rate was lower in adult compared to embryonic red cells. In contrast, no difference in the rate of Cl self-exchange was found between adult and embryonic red cells.     

Fractionation of lymphocyte subpopulations which regulate mixed lymphocyte reactions.

Four days after injection of allogeneic lymphocytes BALB/c splenic T cells suppress proliferation of syngeneic cells in mixed lymphocyte reactions (MLR). Conversely, lymph node cells from the same mice amplify MLR responses. To further characterize these functional subpopulations, alloantigen-primed lymphocyte suspensions from both organs were fractionated by velocity sedimentation at unit-gravity. After fractionation MLR suppressor cells from spleens localized exclusively in rapidlly sedimenting fractions of large cells. MLR suppressor activity of cells from these fractions, as well as that of unfractionated spleen cell suspensions, was abolished by treatment with anti-Thy-1.2 serum and complement. Spleen cell fractions of similar sedimentation velocity also secreted a soluble MLR suppressor into culture supernatants. Although inhibitory of MLR, spleen cells of rapid sedimentation velocity did not suppress responses to T cell mitogens. In marked contrast with the effects of spleen cells, large 4-day-alloantigen-primed lymph node cells had no suppressive activity in MLR. MLR amplifier cells of uncertain derivation were found in fractions of medium sedimentation velocity from both spleens and lymph nodes. Fractionation of alloantigen-primed lymph node cell suspensions did reveal, however, a subpopulation of small cells with MLR suppressor acitivty which was unaffected by treatment with anti-Thy-1 serum and complement. The data thus indicate that large alloantigen-activated lymphocytes are not intrinsically suppressive nor are cells which suppress MLR necessarily large. We consequently conclude that regulation of MLR responses by alloantigen-primed lymphocytes involves a complex interaction between distinct functional subpopulations of cells which are separable both by physical and biologic properties.     

Membrane flow in plants: Fractionation of growing pollen tubes of tobacco by preparative free-flow electrophoresis and kinetics of labeling of endoplasmic reticulum and golgi apparatus with [3H]leucine

Summary Tobacco (Nicotiana tabacum L.) pollen, germinated 4 hours in suspension culture, was labeled with radioactive leucine and fractionated into constituent membranes by the technique of preparative free-flow electrophoresis. Tubes were ruptured by sonication directly into the electrophoresis buffer. Unfortunately, the Golgi apparatus of the rapidly elongating pollen tubes did not survive the sonication step. However, it was possible to obtain useful fractions of endoplasmic reticulum and mitochondria. To obtain Golgi apparatus, glutaraldehyde was added to the homogenization buffer during sonication. Plasma membrane, which accounted for only about 3% of the total membrane of the homogenates as determined by staining with phosphotungstate at low pH, was obtained in insufficient quantity and fraction purity to permit analysis. Results show rapid incorporation of [³H]leucine into endoplasmic reticulum followed by rapid chase out. The half-time for loss of radioactivity from the pollen tube endoplasmic reticulum was about 10 minutes. Concomitant with the loss of radioactivity from endoplasmic reticulum, the Golgi apparatus fraction was labeled reaching a maximum 20 minutes post chase. The findings suggest flow of membranes from endoplasmic reticulum to the Golgi apparatus during pollen tube growth.     

Glucocorticoid-receptor complexes in rat thymus cells. Rapid kinetic behavior and a cyclic model

We have studied the kinetics, on time scales of minutes and seconds, of formation and interconversion of glucocorticoid-receptor complexes in rat thymus cells under physiological conditions. Nonactivated and activated complexes were measured by a minicolumn technique that permits rapid, multiple simultaneous assays. The rate-limiting step in formation of nuclear complexes was activation, which at 37 degrees C had a half-time of 30-60 s. Activation in cells at 25 degrees C followed first order kinetics. Nuclear binding at 37 degrees C was too fast to measure, and probably has a half-time below 10 s. Earlier findings suggesting that triamcinolone acetonide and dexamethasone give higher steady state ratios of activated to nonactivated complexes than cortisol and corticosterone have been supported by showing that these ratios are concentration-independent, and are unlikely to be due to degradation or dissociation of complexes after cell disruption. A simple cyclic model of receptor kinetics, in which each glucocorticoid is characterized by its dissociation rate constant, accounts quantitatively for these results and many others. The model is based on the assumptions that activation is irreversible, and that energy is required for regenerating functional receptors after each cycle. It yields steady state ratios of activated to nonactivated complexes in agreement with experiment without introducing steroid-specific allosteric influences on activation, and suggests a new mechanism for explaining agonist-antagonist relationships.     

Components of the cytosolic and released virtosomes from stimulated and non-stimulated human lymphocytes

Abstract aimThis work intends to analyse the structure and the composition of virtosomes and their role.BackgroundVirtosomes are newly synthesized DNA-RNA-lipoprotein complexes released from living cells in a regulated and energy-dependent manner.MethodsVirtosome fractions were isolated by ultracentrifugation from human lymphocytes cytoplasm and from culture medium before and after stimulation with phitoemoagglutinin (PHA). The composition in DNA, RNA, protein and lipids was determined. The virtosomes present in the culture medium were put in contact with lymphocytes.ResultsVirtosome fractions released from non-stimulated lymphocytes are shown to reduce replication of stimulated lymphocytes and those from stimulated lymphocytes to increase multiplication of non-stimulated lymphocytes. Biochemical analyses of the virtosomal complexes have shown that those from stimulated lymphocytes have five proteins that are absent from non-stimulated virtosome fractions. A comparison of the cytosolic versus released virtosome fractions from non-stimulated lymphocytes indicated that there is a greater percentage of phospholipids in the released virtosomes with a corresponding decrease in the percentage of protein.ConclusionAlthough there is a presence of cholesterol in the virtosomes, the low levels of phosphatidylcholine and cholesterol, together with the low ratios of cholesterol: phospholipids leads to a confirmation of the apparent lack of a limiting membrane around the virtosomes.General significanceVirtosomes are structural particles formed in the cytoplasm, released from the cells and capable to be transferred in other cells influencing their behaviour.     

Dissociative phosphine exchange for cyclopentadienylmolybdenum(III) systems. Bridging the gap between Werner-like coordination chemistry and low-valent organometallic chemistry

Several phosphine exchange processes on 17-electron CpMoCl₂(PR₃)₂ systems have been investigated. The exchange of two PPh₃ ligands with either two PMe₃ ligands or with Ph₂PCH₂PPh₂ (dppe) is complete within a few minutes at −80 °C. Equally fast is the exchange of two PEt₃ ligands with two PMe₃ ligands. On the other hand, the exchange of two PEt₃ ligands with dppe is much slower ( to a few hours at r.t.), with excess dppe accelerating the exchange and free PEt₃ retarding it. The self-exchange reaction of PMe₃ is extremely slow (less than 25% exchange at r.t. in 6 h at r.t.) and an analysis of the initial rate of this reaction shows a two-term rate law with one [PMe₃]-dependent and one independent term. Finally, PMe₃ self-exchange on Cp^*MoCl₂(PMe₃)₂ proceeds over one order of magnitude faster than for the corresponding Cp system, with a substantially [PMe₃]-independent rate law. All these data are indicative of a dominant dissociative exchange mechanism involving rupture of the Mo---PR₃ bond in the slow step and formation of a 15-electron intermediate. The rate of phosphine dissociation qualitatively correlates with the Mo---P distance in the 17-electron starting complex. Only for the Cp---MoCl₂(PMe₃)₂ system is phosphine dissociation sufficiently slowed down so that the alternative associative exchange pathway becomes competitive. Possible reasons for a low activation barrier in these dissociative exchanges are discussed.     

Respiration-Linked Proton Transport, Changes in External pH, and Membrane Energization in Cells of Escherichia coli

The kinetics of respiration-dependent proton efflux and membrane energization have been studied in intact cells of logarithmic-phase Escherichia coli. Parallel measurements of the rate and extent of proton efflux into the external medium (half-time, about 10 s; ratio of H(+) to O, about 0.5) and the oxidation of E. coli cytochrome b (half-time, 相似文献   

Self-exchange of sodium in human lymphocytes.

Self-exchanges of Na and K in human lymphocytes were measured by isotopic efflux techniques. In washed cells, K exchanged in a single slow exponential fraction, but the Na exchange had a marked curvature. It was shown that the curvature was not caused by simple bulk-phase diffusion, and it was resolved into three major fractions: fast (F) (half-time, t1/2 = 2-4 min), intermediate (I) (t1/2 = 12 min), and slow (S) (t1/2 = 125 min). Each of these appeared to follow an exponential function. The I fraction contained approximately 10 mmol Na/kg cells (25-30% of normal cellular Na), was not affected by manipulations that cause lymphocytes to gain Na, and had little or no temperature dependence. The S fraction of Na in normal cells (S1) contained approximately 10 mmol Na/kg cells, had only a slight temperature dependence, and the amount and rate of S1 were independent of external K concentration (Kex). Another slow fraction (S2) appeared when the cells underwent a net gain of Na in exchange for K, and was characterized by a steep temperature dependence and a peak rate around the transition point (the point at which half of cellular K is replaced by Na) at 0.4 mM Kex. The results are discussed within context of a theory that assigns the exchange of the major part of K in its slow exponential fraction and the Na exchange in S2 to interactions of these ions with fixed anionic sites, on intracellular macromolecules, which have been shown previously to interact cooperatively in their association with K and Na.