Muscle: A Three Phase System : The partition of divalent ions across the membrane

The partition of sulfate, Ca⁺⁺, and Mg⁺⁺ across the membrane of the sartorius muscle has been studied, and the effect of various concentrations of these ions in the Ringer solution on the cellular level of Na⁺, K⁺, and Cl^- has been determined. The level of the three divalent ions in toad plasma and muscle in vivo has been assayed. Muscle was found to contain an almost undetectable amount of inorganic sulfate. Increases in the external level of these ions brought about increases in intracellular content, calculated from the found extracellular space as determined with radioiodinated serum albumin or inulin. Less of the cell water is available to sulfate than to Cl^-, and the Mg⁺⁺ space is less than the Na⁺ space. An amount of muscle water similar to that found for Li⁺ and I^- appears to be available to these divalent ions. Sulfate efflux from the cell was extremely rapid, and it was not found possible to differentiate kinetically between intra- and extracellular material. These results are consistent with the theory of a three phase system, assuming the muscle to consist of an extracellular phase and two intracellular phases. Mg⁺⁺ and Ca⁺⁺ are adsorbed onto the ordered phase, and increments in cellular content found on raising the external level are assumed to occur in the free intracellular phase.     

The relationship between sodium,potassium, and chloride in amphibian muscle

The Na,⁺ Cl^-, and K⁺ content of toad plasma and the sartorius muscle has been determined. Although the Na⁺ and Cl^- level of the muscles in the living animal varied greatly (0 to 38.0 m.eq. per kg., and 0 to 31.8 m.eq. per kg. respectively) the K⁺ level was subject to a smaller variation (76.5 to 136 m.eq. per kg.). There was a direct relationship between Na⁺ and Cl^-, which was independent of the K⁺ level. There is a closely related gain of Na⁺ and Cl^- when muscle is soaked in normal Ringer. These gains are not related to the K⁺ loss, frequently found on soaking. The relationship between the three ions was studied in a large series of 124 muscles in normal Ringer. As found in vivo, there was a correlation between Na⁺ and Cl.^- This correlation was independent of K⁺ content, except when this was abnormally low. Alteration of the external NaCl level produced concomitant changes in the internal levels of these ions. Alteration of the external KCl level produced an increase in internal Cl^- similar to that found with high NaCl solutions, but the amount of K⁺ entering the cell was approximately one-third of the external increase. Removal of K⁺ from the external solution did not result in a loss of K⁺ from the cell, although there was an adequate amount of Cl^- present to accompany it. The results cannot be reconciled with either a Donnan concept for the accumulation of K⁺, or a linked carrier system. A theory is proposed to account for the ionic differentiation within the cell. The K⁺ is assumed to be adsorbed onto an ordered intracellular phase. The normal metabolic functioning of the cell is necessary to maintain the specificity of the adsorption sites. There is another intracellular phase, which lacks the structural specificity for K⁺, and which contains Na⁺, Cl^-, and K⁺ in equilibrium with the external solution. The dimensions of the free intracellular phase will vary from cell to cell, but it will be smaller in the intact animal, and will increase on soaking in normal Ringer, until it is approximately one-third of the total cellular volume. The increase in this phase may be ascribed to a decrease in the energy available to maintain the ordered phase.     

Mechanisms of phosphate uptake into brush-border membrane vesicles from goat jejunum

This study concerns the uptake of inorganic phosphate into brush-border membrane vesicles prepared from jejunal tissues of either control or Ca-and/or P-depleted goats. The brush-border membrane vesicles showed a time-dependent accumulation of inorganic phosphate with a typical overshoot phenomenon in the presence of an inwardly directed Na⁺ gradient. The Na⁺-dependent inorganic phosphate uptake was completely inhibited by application of 5 mmol·l^-1 sodium arsenate. Half-maximal stimulation of inorganic phosphate uptake into brush-border membrane vesicles was found with Na⁺ concentrations in the order of 5 mmol·l^-1. Inorganic phosphate accumulation was not affected by a K⁺ diffusion potential (inside negative), suggesting an electroneutral transport process. Stoichiometry suggested an interaction of two or more Na ions with one inorganic phosphate ion at pH 7.4. Na⁺-dependent inorganic phosphate uptake into jejunal brush-border membrane vesicles from normal goats as a function of inorganic phosphate concentration showed typical Michaelis-Menten kinetic with V _max=0.42±0.08 nmol·mg^-1 protein per 15 s^-1 and K _m=0.03±0.01 mmol·l^-1 (n=4, x ±SEM). Long-term P depletion had no effect on these kinetic parameters. Increased plasma calcitriol concentrations in Ca-depleted goats, however, were associated with significant increases of V _max by 35–80%, irrespective of the level of P intake. In the presence of an inwardly directed Na⁺ gradient inorganic phosphate uptake was significantly stimulated by almost 60% when the external pH was decreased to 5.4 (pH_out/pH_in=5.4/7.4). The proton gradient had no effect on inorganic phosphate uptake in absence of Na⁺. In summary, in goats Na⁺ and calcitriol-dependent mechanisms are involved in inorganic phosphate transport into jejunal brush-border membrane vesicles which can be stimulated by protons.Abbreviations AP activity of alkaline phosphatase - BBMV brush-border membrane vesicles - EGTA ethyleneglycol-triacetic acid - n _app apparent Hill coefficient - P _i inorganic phosphate - PTH parathyroid hormone     

The Role of Calcium Ions in Modulation of Impulse Activity of the Isolated Muscle Spindle of the Frog Rana temporaria

The effect of various concentrations of Ca⁺² and Mg⁺² as well as of calcium channel blockers verapamil and nifedipin on impulse activity of frog isolated muscle spindles was studied. Removal of Ca ions from the external Ringer solution was established to increase spontaneous and evoked activity of the muscle spindle. A 4- and 8-fold increase of Ca⁺² concentration produces inhibition and complete cessation of the spontaneous and evoked activity in the muscle spindle. Replacement of Ca⁺² by Mg⁺² is observed to cause no statistically significant change of the spontaneous activity of the isolated muscle spindle; at the same time, at the dynamic spindle extension, the impulse activity rate at the dynamic and static phases of the response rises. Nifedipin and verapamil, blockers of Ca⁺² channels, suppress impulse activity both in norm and on the background of increased impulse activity evoked by removal of Ca⁺² from the external solution. An increase of muscle spindle impulse activity after the removal of Ca⁺² from the external solution is accounted for by transformation of calcium channels of the muscle spindle sensory endings into selective sodium channels.     

Ion metabolism in a halophilic blue-green alga,Aphanothece halophytica

The intracellular ion content of the halophilic blue-green alga, Aphanothece halophytica was studied as a function of age, external sodium and external potassium concentration. Intracellular Na⁺ was found to be about 0.38 millimoles/g dry mass. Intracellular K⁺ concentrations were as high as 1 M and varied directly with external salinity. Intracellular Ca⁺⁺ and Mg⁺⁺ were in the range previously reported for fresh water blue-green algae despite their extremely high extracellular concentrations. Average cell size is consistent at room temperature with two exceptions. When the outside K⁺ is lower than 6.5 mM the cells tend to be smaller with less intracellular K⁺ and high Ca⁺⁺. In stationary phase cultures the cells are larger with high intracellular Mg⁺⁺ and low K⁺.     

Effects of monovalent cations on phosphate accumulation and storage of the ectomycorrhizal fungus Suillus bovinus

Comparative in vivo ³¹P-NMR studies of the fungus Suillus bovinus (L.: Fr.) O. Kuntze in pure culture have produced interesting new data. To investigate the response of phosphate metabolism to a change in external monovalent cations, samples were exposed to a Hoagland solution containing different monovalent cations Li⁺, Na⁺, K⁺, or Rb⁺ at 10 mM concentration. A method of nutrient cycling during analysis where the cation was changed and the phosphate kept constant allowed us to determine the kinetics of phosphate accumulation, storage and incorporation into polyphosphate following exposure to the range of test cations. Different external monovalent cations had different effects upon changes in the content of both phosphate and polyphosphate. Treatment with Li⁺, Na⁺, or Rb⁺ resulted in a change in phosphate accumulation to 60, 73, and 107% and in content of the intracellular mobile polyphosphate (polyP) to 119, 112, and 94%, respectively, compared with the control taken as 100%. The effect of each cation is related to its position in the periodic table. Reversing this process, i.e., exchanging with K⁺, returned phosphate metabolism to normal. Although, the increase in depolarization of the cell membrane should affect the internal pH, fungal metabolism using energy requiring mechanisms appeared necessary to maintain the intracellular pH. Thus, increasing contents of mobile polyP were the consequence of an increasing energy demand. On the other hand, the increasing depolarization of the cell membrane following the sequence Rb⁺ < K⁺ < Na⁺ < Li⁺ inhibited the net P_i accumulation. Furthermore, it is postulated that the P_i accumulation was also regulated by the intracellular content in polyP.     

Modulation of synaptosomal high affinity choline transport.

Depolarization of synaptosomes produced by incubation in 35mMK⁺ Krebs Ringer phosphate buffer results in an increased Vmax and no change in K_T of the high affinity transport of [³H]-choline as determined upon re-incubation in normal K⁺ Krebs Ringer phosphate buffer. The high K⁺ induced increase in the uptake of choline appears to be independent of transmitter release. The K⁺ stimulated increase in the Vmax of the high affinity transport of choline is totally blocked by high, 11mM, Mg⁺². The proportion of choline converted to acetylcholine in synaptosomes previously depolarized is the same as those incubated in normal K⁺ Krebs Ringer; thus the absolute rate of acetylcholine synthesis in nerve terminals is increased as a result of prior depolarization.     

Ischemic changes in myocardial ionic contents of the isolated perfused rat hearts as studied by NMR

Using³¹P-,²³Na- and³⁹K-NMR, we assessed ischemic changes in high energy phosphates and ion contents of isolated perfused rat hearts continuously and systematically. To discriminate intra- and extracellular Na⁺, a shift reagent (Dy(TTHA)^3–) was used in²³Na-NMR study. In³⁹K-NMR study, the extracellular K⁺ signal was suppressed by inversion recovery pulse sequence in order to obtain intracellular K⁺ signal without using shift reagnets. During the early period of ischemia, increases in intracellular Na⁺ and inorganic phosphate (Pi) were observed in addition to the well-documented decreases in creatine phosphate and ATP and a fall of intracellular pH, suggesting an augmented operation of Na⁺–H⁺ exchange triggered by a fall of the intracellular pH resulted from breakdown of ATP. At around 15 min of ischemia, a second larger increase in intracellular Na⁺ and a decrease in intracellular K⁺ were observed in association with a second increase in Pi. This was accompnanied by an abrupt rise of the ventricular end-diastolic pressure. As there was a depletion of ATP at this time, the increase in intracellular Na⁺ and associated decrease in intracellular K⁺ may be explained by inhibition of the Na⁺–K⁺ ATPase due to the depletion of ATP. A longer observation with³¹P-NMR revealed a second phosphate peak (at lower magnetic field to ordinary Pi peak) which increased its intensity as ischemic time lengthened. The pH of this 2nd peak changed in parallel with the changes in pH of the bathing solution, indicating the appearance of a compartment whose hydrogen concentration is in equilibrium with that of the external compartment. Thus, the peak could be used as an index of irreversible membrane damage of the myocardium.     

Muscle pain after exercise is linked with an inorganic phosphate increase as shown by31P NMR

³¹P nuclear magnetic resonance (NMR) spectra were obtained from the forearm muscles of 5 subjects before and after performing a muscle stretching (eccentric) exercise routine. Spectra collected before and immediately after exercise showed normal resting phosphorylated metabolite levels and unchanged intracellular pH (pH_i). Measurements made on the day following exercise, when muscular pain was apparent, revealed an elevated inorganic phosphate level. No significant changes in other metabolites or pH_i were detected. This study gives the first indication of biochemical change following a form of exercise that is associated with considerable muscle pain and damage. The findings may help in understanding pathological processes resulting in pain and damage in muscle.     

The non-correlation of bioelectric potentials with ionic gradients

The sartorius muscles of 320 toads have been analyzed for Na⁺ and K⁺. There is a wide variation in the Na⁺ content which when calculated intracellularly varied from 0 m.eq./kg. to 58 m.eq./kg. In particular it was found that the distribution of internal Na⁺ in the intact animal was such that only 17 per cent of the muscles should give from the Nernst equation the observed overshoot of 37 mv. In contrast to this wide variation the K⁺ content is comparatively constant, the range being 71 to 112 m.eq./kg. The mean observed resting potential of 87 mv. agreed well with the potential calculated from the mean intracellular K⁺ by the Nernst equation. Analyses of plasma show that the Na⁺ content is constant at 130 m.eq./liter, and the K⁺ is 3.0 m.eq./liter. The resting and action potentials of 77 muscles have been recorded and then the muscles have been analyzed. The results have shown that there is no correlation between the level of intracellular Na⁺ and the overshoot. Furthermore the apparent correlation between the average K⁺ content and the average resting potential has been shown to be fortuitous, when the correlation in individual muscles is considered. When a muscle is soaked in Ringer solution for several hours there is a gain of Na⁺ and a loss of K⁺. These shifts should result in changes in the respective potentials, but such changes were not found. The above findings have been discussed in the light of the present theories that the resting potential and the action potential are directly related to the ionic ratio across the membrane. Our results very definitely do not support the theory that the overshoot is related to the Na⁺ gradient, and this also applies with respect to the K⁺ gradient and the resting potential.     

Solute transport at the plasmalemma and the early evolution of cells

The evolution of the plasmalemma and its porter systems is considered in relation to selective pressures on primitive cells. Initially the polar lipid bilayer acted to separate the genetic apparatus of the protocell from the rest of the world. The requirement for the supply of nutrients and removal of waste products resulted in the evolution of passive uniporters for a number of organic and inorganic solutes. There was also a requirement for primary active transport, whereby one or more solutes is transported across the membrane contrary to the direction predicted from passive driving forces, with an energy input from light, redox reactions, “high-energy phosphate” or some other metabolic process. Active transport is discussed in terms of cytoplasmic pH regulation, cytoplasmic volume regulation, Ca²⁺ exclusion/phosphate accumulation, and the accumulation of organic (heterotrophic) substrates.It is suggested that volume regulation in wall-less cells was initially achieved by Na⁺ exclusion with active Na⁺ extrusion as a later refinement; the same applies to the maintenance of the characteristically low free Ca²⁺ level in the cytoplasm. A requirement for active phosphate influx is also likely in view of the high concentrations of orthophosphate required for phosphorylation reactions relative to the likely external concentration of phosphate and the inside-negative potential difference. This p.d., which results inter alia from Na⁺ extrusion, makes the maintenance of intracellular pH via passive H⁺ fluxes very difficult in the face of continued intracellular production of H⁺ during fermentation. Hence an early role for primary active extrusion (uniport) of H⁺ is very likely. Such uniport is of universal occurrence in present-day cells. Besides its role in pH regulation and in energy-coupling, H⁺ transport energises secondary (H⁺-linked) transport of many other solutes. We suggest that transport of HCO₃^? might also have a pH-regulating role, but apparently HCO₃^? cannot substitute for H⁺ with respect to energy-coupling and secondary active transport.     

Phosphorylation by Inorganic Phosphate of the Plasma Membrane H-ATPase from Red Beet (Beta vulgaris L.)

The phosphorylation of plasma membrane proteins from red beet (Beta vulgaris L.) by radioactive inorganic phosphate was studied. Only few proteins were phosphorylated, among them was one polypeptide with an apparent molecular weight of about 100,000. The phosphorylation of this protein was decreased when orthovanadate was present in the reaction mixture, or when the phosphorylated protein was treated with hydroxylamine. These facts suggest that this protein is a transport ATPase which is phosphorylated in a carboxyl group during the catalytic cycle. This protein was identified immunologically as the plasma membrane H⁺-ATPase. The phosphorylation level of this enzyme was enhanced by dimethyl sulfoxide, whereas potassium ions did not have a significant effect on this level unless ATP was present. ATP stimulated the phosphorylation by inorganic phosphate. This stimulation was more apparent in the presence of potassium ions.     

High-energy phosphate metabolites in loach (Cobitis biwae) during urethane anesthesia

1. Changes in the metabolism of high-energy phosphates in the loach were studied under urethane anesthesia using in vivo³¹P-NMR.2. Little change was observed in creatine phosphate (PCr) and β-ATP concentration after the administration of urethane, but the inorganic phosphate (Pi) concentration decreased with a resultant tilt of the intracellular pH to the acid side.3. Recovery to the initial energy level state occurred about 2 hr after discontinuation of anesthesia.4. Urethane anesthesia is considered to change the intracellular ionic environment in the muscle of the loaches.     

Solubilization of inorganic phosphate byRhizobium

A large number of strains ofRhizobium were able to solubilize the insoluble phosphate compound, hydroxy-apatite, in liquid culture. Solubilization of hydroxyapatite byRhizobium was not mediated by an enzyme but acidity developed in the cultures was involved in the process. An inverse relationship between the level of soluble phosphate and medium pH was evident. The ability to solubilize hydroxyapatite varied among the strains. In a medium without NH ₄ ⁺ , some of the strains showed better activity than when NH ₄ ⁺ was present, suggesting involvement of different mechanisms for phosphate solubilization.R. meliloti SU 47 produced 2-ketogluconic acid along with an unidentified acid in the medium containing NH ₄ ⁺ . 2-Ketogluconic acid was identified as the major factor in inorganic phosphate solubilization. Initial presence of soluble phosphate in the medium had no discernible influence on the extent of hydroxyapatite solubilization. Initial presence of calcium reduced solubilization of phosphate and addition of EDTA to stationary phase cultures caused an increase in the level of soluble phosphate.     

Cation flux in the ehrlich ascites tumor cell evidence for Na-for-Na and K-for-K exchange diffusion

In a previous study, evidence was presented for an external Na⁺-dependent, ouabain-insensitive component of Na⁺ efflux and an external K⁺-dependent component of K⁺ efflux in the Ehrlich ascites tumor cell. Evidence is now presented that these components are inhibited by the diuretic furosemide and that under conditions of normal extracellular Na⁺ and K⁺ they represent Na⁺-for-Na⁺ and K-⁺for-K⁺ exchange mechanisms. Using ⁸⁶Rb to monitor K⁺ movements, furosemide is shown to inhibit an ouabain-insensitive component of Rb⁺ influx and a component of Rb⁺ efflux, both representing approx. 30% of the total fux. Inhibition of Rb⁺ efflux is greatly reduced by removal of extracellular K⁺. Furosemide does not alter steady-state levels of intracellular K⁺ and it does not prevent cells depleted of K⁺ by incubation in the cold from regaining K⁺ upon warming. Using ²²Na to monitor Na⁺ movements, furosemide is shown to inhibit an ouabain-insensitive component of unidirectional Na⁺ efflux which represents approx. 22% of total Na⁺ efflux. Furosemide does not alter steady-state levels of intracellular Na⁺ and does not prevent removal of intracellular Na⁺ upon warming from cells loaded with Na⁺ by preincubation in the cold. The ability of furosemide to affect unidirectional Na⁺ and K⁺ fluxes but not net fluxes is consistent with the conclusion that these components of cation movement across the cell membrane represent one-for-one exchange mechanisms. Data are also presented which demonstrate that the uptake of α-aminoisobutyrate is not affected by furosemide. This indicates that these components of cation flux are not directly involved in the Na⁺-dependent amino acid transport system A.     

Tetanus responses under rapid bath solution change: Electrotonic depolarization of transverse tubules may release Ca2+ from sarcoplasmic reticulum of Rana japonica skeletal muscle

• 1.1. Single skeletal muscle fibers were transferred from a normal Ringer solution to Na⁺ ion free solution, and vice versa, and tetanus responses were recorded immediately after the transfer.
• 2.2. Fractional tetanus tension recorded immediately after the displacement from the Na⁺ ion free solution to normal Ringer solution was dependent on fiber diameter.
• 3.3. Diffusion of Na⁺ ions along the transverse tubules was simulated [apparent diffusion constant was 3.11 × 10⁻⁶ (cm²/s)].
• 4.4. Our results suggest that the electrotonic spreading of membrane potential, caused by an action potential in the transverse tubules, could release Ca²⁺ ions from sarcoplasmic reticulum.

     

A non-equilibrium thermodynamic theory of leakage of complexed Na+ from muscle,with NMR evidence that the non-complexed fraction of muscle Na+ is intra-vacuolar rather than extra-cellular

Recent experimental evidence has provided increasing support for the hypotheses that 60 to 80 per cent of intracellular Na⁺ exists in a complexed state, and that intracellular water exists in a semi-organized, non-liquid state having low solubility for Na⁺. Using these postulates, a previous crude theory of Na⁺ leakage from the cell based on electronion conduction analogies has been redeveloped in a more complete and detailed fashion, following a non-equilibrium thermodynamic approach. The theory, which is based on the postulate of almost 100 per cent complexing of intracellular Na⁺, predicts that Na⁺ leakage from muscle should conform to the Elovich equation, which closely agrees with experiment, despite the fact that experiments indicate that 20 to 40 per cent of muscle Na⁺ isnot complexed. To resolve this apparent paradox, the leakage of complexed and non-complexed Na⁺ from muscle was measured by nuclear magnetic resonance (NMR). The non-complexed Na⁺ leaked much more slowly than the complexed Na⁺, suggesting that the non-complexed Na⁺ may be confined within vacuoles surrounded by an activation energy barrier at the vacuolar membrane. This implies that the measured curves of Na⁺ leakage showing Elovich kinetics are due mostly to leakage of complexed Na⁺ as the theory requires, and that the leakage of 20 to 40 per cent non-complexed Na⁺ is mostly delayed until later times.     

Membrane mediated link between ion transport and metabolism in human red cells

When 10^?6 M oubain is added to human red cells that have been incubated without glucose for two hours, there is a significant shift in the ³¹P nuclear magnetic resonances of both phosphate groups of cellular 2,3-diphosphoglycerate, which is not found in control cells incubated with glucose. This means that an effect induced by ouabain on the outside of the red cell membrane is transmitted through the membrane to alter the environment of an intracellular metabolite. Experiments with glycolytic cycle inhibitors have indicated that the intracellular ligand responsible for the resonance shifts is monophosphoglycerate mutase which requires 2,3-diphosphoglycerate as a cofactor for the reaction it catalyzes. To account for this finding a hypothesis is presented that the (Na⁺ + K⁺)-ATPase in human red cells is linked to monophosphoglycerate mutase through the agency of phosphoglycerate kinase. Evidence is presented for the existence of phosphoglycerate kinase/monophosphoglycerate mutase in solution. It is shown that this complex can interact with the cytoplasmic face of (Na⁺ + K⁺)-ATPase at the outside surface of inside out red cell vesicles, and that this interaction is inhibited when 10^?6 M ouabain is contained within the vesicle. Neither monophosphoglycerate mutase nor phosphoglycerate kinase is significantly bound to the inside surface of the intact human red cell, but glyceraldehyde 3-phosphate dehydrogenase is; it is shown that this enzyme also interacts with the cytoplasmic face of the (Na⁺ + K⁺)-ATPase and that the interaction is inhibited by 10^?6 M ouabain.     

Detection and characterization of acidic compartments (vacuoles) in Chlorella vulgaris 11h cells by 31P-in vivo NMR spectroscopy and cytochemical techniques

Acidic inorganic phosphate (Pi) pool (pH around 6) was detected besides the cytoplasmic pool in intact cells of Chlorella vulgaris 11h by ³¹P-in vivo nuclear magnetic resonance (NMR) spectroscopy. It was characterized as acidic compartments (vacuoles) in combination with the cytochemical technique; staining the cells with neutral red and chloroquine which are known as basic reagents specifically accumulated in acidic compartments. Under various conditions, the results obtained with the cytochemical methods were well correlated with those obtained from in vivo NMR spectra; the vacuoles were well developed in the cells at the stationary growth phase where the acidic Pi signal was detected. In contrast, cells at the logarithmic phase in which no acidic Pi signal was detected contained only smaller vesicles that accumulated these basic reagents. No acidic compartment was detected by both cytochemical technique and ³¹P-NMR spectroscopy when the cells were treated with NH₄OH. The vacuolar pH was lowered by the anaerobic treatment of the cells in the presence of glucose, while it was not affected by the external pH during the preincubation ranging from 3 to 10. Possible vacuolar functions in unicellular algae especially with respect to intracellular pH regulation are discussed.Non-standard abbreviations EDTA ethylenediaminetetraacetic acid - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - MDP methylene diphosphonic acid - NMR nuelear magnetic resonance - PCA perchloric acid - PCV packed cell volume - Pi inorganic phosphate - Pic sytoplasmic inorganic phosphate - Piv vacuolar inorganic phosphate - ppm parts per million - SP sugar phosphates - TCA trichloroacetic acid     

The effect of inorganic phosphate on sodium fluxes in dog red blood cells

The effect of extracellular inorganic phosphate on Na⁺ movements in dog red blood cells has been studied. As the phosphate concentration is increased from 0 to 30 mM, Na⁺ efflux increases by 2- to 3-fold and Na⁺ influx increases approximately 2-fold. This enhancement of Na⁺ fluxes by phosphate can be prevented by the addition of iodoacetate (1 mM), an inhibitor of glycolysis, or 4-acetamido-4′-iso-thiocyantostilbene-2,2′-disulfonic acid (0.01 mM), which blocks anion transport, to the medium. The increases in Na⁺ movements are not caused by changes in cell volumes. These results suggest that phosphate must enter the cell to enhance Na⁺ fluxes and that the mechanism of action may be via a stimulatory effect on glycolysis.