Activation of K-Cl cotransport by mild warming in guinea pig red cells

Unidirectional, ouabain-insensitive K+ influx rose steeply with warming at temperatures above 37 degreesC in guinea pig erythrocytes incubated in isotonic medium. The only component of ouabain-insensitive K+ influx to show the same steep rise was K-Cl cotransport (Q10 of 10 between 37 and 41 degrees C); Na-K-Cl cotransport remained constant or declined and residual K+ influx in hypertonic medium with ouabain and bumetanide rose only gradually. Similar results were obtained for unidirectional K+ efflux. Thermal activation of K-Cl cotransport-mediated K+ influx was fully dependent on the presence of chloride in the medium; none occurred with nitrate replacing chloride. The increase of K+ influx through K-Cl cotransport from 37 to 41 degrees C was blocked by calyculin A, a phosphatase inhibitor. The Q10 of K-Cl cotransport fully activated by hydroxylamine and hypotonicity was about 2. The time course of K+ entry showed an immediate transition to a higher rate when cells were instantly warmed from 37 to 41 degrees C, but there was a 7-min time lag in returning to a lower rate when cells were cooled from 41 to 37 degrees C. These results indicate that the steepness of the response of K-Cl cotransport to mild warming is due to altered regulation of the transporter. Total unidirectional K+ influx was equal to total unidirectional K+ efflux at 37-45 degrees C, but K+ influx exceeded K+ efflux at 41 degrees C when K-Cl cotransport was inhibited by calyculin or prevented by hypertonic incubation. The net loss of K+ that results from the thermal activation of isosomotic K-Cl cotransport reported here would offset a tendency for cell swelling that could arise with warming through an imbalance of pump and leak for Na+ or for K+.

On the trail of potassium in heat injury

In both classical and exertional heatstroke and in various animal models of human heat injury, clinical manifestations have included observations of normokalemia, hyperkalemia, and hypokalemia. This review attempts to address these observations as well as the role of potassium and potassium depletion in heat injury with an emphasis on the integration of information from the level of transmembrane potassium transport mechanisms to systems physiology. Under moderate conditions of passive heat exposure or exercise in the heat, the adaptive capacity of the Na-K pump (Na+-K+ ATPase activity) and cotransport mechanisms can ordinarily accommodate the attendant increased efflux of intracellular K+ and influx of extracellular Na+ to maintain ionic equilibrium. Several factors affecting transmembrane K+ kinetics include protracted K+ deficiency, extreme hyperthermia, dehydration, and excessive exertion. These could elicit reduced membrane potentials and conductance, futile cycling of the Na-K pump with concomitant energy depletion and greatly increased metabolic heat production, reduced arteriolar vasodilation, altered neurotransmitter release, or cell swelling, each of which could contribute to the pathophysiology of heat injury. This review represents a preliminary attempt to link transmembrane K+ pathophysiology with clinical heat injury.

Elevating intracellular free Mg2+ preserves sensitivity of Na(+)-K+ pump to ATP at reduced temperatures in guinea pig red blood cells

Red cells of hibernating species have a higher relative rate of Na(+)-K+ pump activity at low temperature than the red cells of a mammal with a typical sensitivity to cold. The kinetics of ATP stimulation of the Na(+)-K+ pump were determined in guinea pig and ground squirrel red cells at different temperatures between 5 and 37 degrees C by measuring ouabain-sensitive K+ influx at different levels of ATP. In guinea pig cells, elevation of intracellular free Mg2+ to 2 mmol.1-1 by use of the divalent cation ionophore A23187 caused the apparent affinity of the pump for ATP to increase with cooling to 20 degrees C, rather than to decrease, as occurs in cells not loaded with Mg2+. In ground squirrel cells raising intracellular free Mg2+ had little effect on apparent affinity of the pump for ATP at 20 degrees C. ATP affinity rose slightly with cooling both in Mg(2+)-enriched and in control ground squirrel cells. Increased intracellular free Mg2+ in guinea pig cells stimulated Na(+)-K+ pump activity so that at 20 degrees C the pump rate was the same in the Mg(2+)-enriched guinea pig and control ground squirrel cells. Pump activity in Mg(2+)-enriched guinea pig cells at 5 degrees C was significantly improved but still lower than pump activity in control cells from ground squirrel. Thus, loss of affinity of the Na(+)-K+ pump for ATP that occurs with cooling in cold-sensitive guinea pig red cells can be, at least partially, prevented by elevating cytoplasmic free Mg2+. Conversely, in ground squirrel red cells natural rise of free Mg2+ may in part account for the preservation of the ATP affinity of their Na(+)-K+ pump with cooling.

Sodium transport through the amiloride-sensitive Na-Mg pathway of hamster red cells

Previous work showed that in hamster red cells the amiloride-sensitive (AS) Na+ influx of 0.8 mmol/liter cells/hr is not mediated by Na-H exchange as in other red cells, but depends upon intracellular Mg2+ and can be increased by 40-fold by loading cells with Mg2+ to 10 mM. The purpose of this study was to verify the connection of AS Na+ influx with Na-dependent, amiloride-sensitive Mg2+ efflux and to utilize AS Na+ influx to explore that pathway. Determination of unidirectional influx of Na+ and net loss of Mg2+ in parallel sets of cells showed that activation by extracellular [Na+] follows a simple Michaelis-Menten relationship for both processes with a Km of 105-107 mM and that activation of both processes is sigmoidally dependent upon cytoplasmic [Mg2+] with a [Mg2+]0.5 of 2.1-2.3 mM and a Hill coefficient of 1.8. Comparison of Vmax for both sets of experiments indicated a stoichiometry of 2 Na:1 Mg. Amiloride inhibits Na+ influx and Mg2+ extrusion in parallel (Ki = 0.3 mM). Like Mg2+ extrusion, amiloride-sensitive Na+ influx shows an absolute requirement for cytoplasmic ATP and is increased by cell swelling. Hence, amiloride-sensitive Na+ influx in hamster red cells appears to be through the Na-Mg exchange pathway. There was no amiloride-sensitive Na+ efflux in hamster red cells loaded with Na+ and incubated with high [Mg2+] in the medium with or without external Na+, nor with ATP depletion. Hence, this is not a simple Na-Mg exchange carrier.

A comparison of effect of temperature on phosphorus metabolites, pH and Mg2+ in human and ground squirrel red cells

1. 31P NMR spectra were obtained at temperatures ranging from 2 to 30 degrees C from freshly drawn human (cold-sensitive) and ground squirrel (cold-tolerant) red cells. The concentration of ATP was also determined by luciferin-luciferase assay over the same temperature range. 2. The concentration of ATP as determined by NMR or by the luciferin-luciferase assay did not change with temperature in either species. The absolute concentration of ATP in human cells determined by NMR was not significantly different from the total ATP determined enzymatically. 3. The concentration of 2,3-diphosphoglycerate was higher and that of pyridine nucleotides lower in human than in ground squirrel red cells. This species difference was independent of temperature. 4. Intracellular pH, as determined from the positions of the NMR peaks of 2- and 3-phosphates of diphosphoglycerate, became more alkaline as the temperature was lowered. 5. Free intracellular magnesium, determined from the difference in the positions of the peaks for alpha- and beta-phosphorus of ATP, increased in the ground squirrel red cells and decreased in the human red cells with cooling from 30 to 2 degrees C. Total magnesium, as determined by atomic emission spectroscopy, did not change with temperature in red cells of either species. 6. The intensities of all phosphorus metabolite signals from the ground squirrel cells increased with decreasing temperature, while those from the human cells were unaffected. Since chemical shift anisotropy in the presence of magnesium is a powerful spin-lattice relaxation mechanism for phosphates, this is additional evidence for the temperature dependence of free magnesium concentration in the ground squirrel cells. 7. We conclude that there is no difference in phosphorus metabolites or intracellular pH which could account for the differential cold sensitivity in human and ground squirrel red cells. We suggest that, in the cold-tolerant red cells from the ground squirrel, magnesium is released from binding sites as the temperature is lowered. The change in free intracellular Mg2+ may account at least in part for the unusually low temperature sensitivity of the Na(+)-K+ pump in the red cells of this species.

Cold activation of Na influx through the Na-H exchange pathway in guinea pig red cells

Previous work showed that amiloride partially inhibits the net gain of Na in cold-stored red cells of guinea pig and that the proportion of unidirectional Na influx sensitive to amiloride increases dramatically with cooling. This study shows that at 37 degrees C amiloride-sensitive (AS) Na influx in guinea pig red blood cells is activated by cytoplasmic H+, hypertonic incubation, phorbol ester in the presence of extracellular Ca2+ and is correlated with cation-dependent H+ loss from acidified cells. Cytoplasmic acidification increases AS Na efflux into Na-free medium. These properties are consistent with the presence of a Na-H exchanger with a H+ regulatory site. Elevation of cytoplasmic free Mg2+ above 3 mM greatly increases AS Na influx: this correlates with a Na-dependent loss of Mg2+, indicating the presence of a Na-Mg exchanger. At 20 degrees C activators of Na-H exchange have little or no further stimulatory effect on the already elevated AS Na influx. AS Na influx is much larger than either Na-dependent H+ loss or AS Na efflux at 20 degrees C. The affinity of the AS Na influx for cytoplasmic H+ is greater at 20 degrees C than at 37 degrees C. Depletion of cytoplasmic Mg2+ does not abolish the high AS Na influx at 20 degrees C. Thus, elevation of AS Na influx with cooling appears to be due to increased activity of a Na-H exchanger (operating in a "slippage" mode) caused by greater sensitivity to H+ at a regulatory site.

ATP dependence of Na(+)-K+ pump of cold-sensitive and cold-tolerant mammalian red blood cells

1. The ATP concentration of intact, cold-tolerant (ground squirrel) red cells and cold-sensitive (guinea-pig and human) red cells was monitored by use of the firefly tail, luciferin-luciferase assay. ATP kinetics of the pump in intact red blood cells was investigated by altering cell [ATP] by progressive depletion of ATP in the presence of 2-deoxy-D-glucose and then by measurement of ouabain-sensitive K+ influx at each level of [ATP] at various temperatures between 37 and 5 degrees C. Na(+)-K(+)-ATPase activity of broken membranes was also determined in parallel experiments using ouabain-sensitive release of 32P from [gamma-32P]ATP as a measure of activity. 2. Without depletion, there is no immediate decrease in [ATP] of intact cold-sensitive cells at low temperature (5 degrees C) at times when there are marked differences in the activities of the Na(+)-K+ pump of cold-tolerant and cold-sensitive cells. 3. At 37 degrees C Na(+)-K(+)-ATPase of all three species exhibited two components of ATP dependence at 37 degrees C, one with high velocity, low affinity, the other with low velocity, high affinity. Affinities of both components rose with cooling. 4. A similar, two component pattern was observed in intact guinea-pig and human red cells at 37 degrees C, except that the segment corresponding to the high affinity component had an apparent Km (Michaelis-Menten constant) 3- to 4-fold higher than that of the broken membrane preparation. 5. Cooling intact guinea-pig and human red cells decreased the apparent affinity of the high velocity, low affinity component for ATP, so that at 20 degrees C the value of Km approached or exceeded the levels of physiological ATP concentration. Below 20 degrees C only one component with values corresponding to that of the low velocity, high affinity component could be observed. 6. In intact ground squirrel cells only the low affinity, high velocity component was apparent between 37 and 5 degrees C. Its affinity for ATP rose with cooling between 37 and 5 degrees C.

Diversities of transport of sodium in rodent red cells

1. Na-K pumps of rodent red cells reveal variations among species in terms of kinetic properties such as ouabain sensitivity, Na/K coupling and temperature sensitivity and variations within an individual organism related to such physiological challenges as K deficiency, calorie deficiency and seasonal changes in temperature. 2. Passive Na entry among rodents collectively occurs through the same routes as in red cells of other mammals, but red cells of hamsters, rats and thirteen-lined ground squirrels lack or are deficient in an amiloride-sensitive, shrinkage-activated Na-H exchange. 3. In guinea-pig this pathway appears to be both activated and uncoupled by cooling from 37 to 20 degrees C. 4. Red cells of rodents in general and hamsters in particular are rich in a Na-Mg exchange pathway. In hamsters, this appears to be the only amiloride-sensitive pathway in simple media. 5. In hamster cells, Na entry through the amiloride-sensitive Mg-activated pathway exhibits the same kinetics as previously shown for Na activation of Mg extrusion.

Seasonal changes in cation transport in red blood cells of grey squirrel (Sciurus carolinensis) in relation to thermogenesis and cellular adaptation to cold

1. Unidirectional influx of 42K was measured in red cells of grey squirrels at seasonal intervals over two years. 2. Na/K pump-related (i.e. ouabain-sensitive) K influx at 37 degrees C was maximal in cells collected in January and was more than three times greater than cells collected in summer. Na/K pump activity, maximized by loading the cells with Na, exhibited a similar difference. 3. At 5 degrees C in fresh cells, ouabain-sensitive K influx, expressed as per cent of that at 37 degrees C, was highest in March. In Na-loaded cells it was lowest in summer. 4. Passive "leak" K influx (i.e., the residual influx remaining in presence of ouabain and bumetanide) was highest in October, and declined progressively to the summer months, when it was only 27% of that in October. 5. Cotransport (i.e., bumetanide-sensitive K influx) exhibited the same seasonal pattern as Na/K pump activity in fresh cells. 6. Net gain of Na in cells stored at 5 degrees C for three days in March was less than half of that in January or summer. 7. High transport activity in January may correlate with a requirement for increased non-shivering thermogenesis. However, red cells of grey squirrels exhibit maximum resistance to low temperature in March and at this time resemble the red cells of hibernating mammals.

The absence of adapted sodium and potassium transport in erythrocytes of cerebral palsied children with secondary malnutrition

Previous studies of erythrocyte ion (potassium and sodium) transport during marasmus and kwashiorkor have indicated increased passive permeation to both ions in both syndromes, and increased Na,K pump activity in kwashiorkor and reduced activity in marasmus. Children with severe cerebral palsy (CP) frequently suffer secondary protein energy malnutrition (PEM). Unlike marasmus and kwashiorkor, this PEM is uncomplicated by micronutrient deficiency, parasitism and infections. Because of deformities classification of PEM cannot be performed in these children by stature-based anthropometry, therefore we used triceps skinfold thicknesses less than the fifth percentile and absence of weight gain in the previous year as criteria for malnutrition. K influx data from well- and malnourished CP children, and from well-nourished controls reveal that ouabain-sensitive K influx is highest in malnourished CP, followed by well-nourished CP (P = 0.02), and lowest in controls (P less than 0.001, vs. malnourished). Determinations of ouabain-sensitive Na efflux, though less precise and therefore more variable, were consistent with this finding of no decrease of Na,K pump activity occurring during the development of this malnutrition. There were no statistically significant differences in ouabain-insensitive fluxes of either Na or K. Ion transport in undernourished CP children thus resembles that found in kwashiorkor rather than in marasmus; but oedema is rarely seen in this form of secondary PEM.

Membrane transport of sodium ions in erythrocytes of the American black bear, Ursus americanus

1. Membrane transport of Na ions was investigated in red blood cells of bears by methods of measurement of unidirectional isotopic fluxes. 2. Like red blood cells of dogs, bear red cells contain a high Na concentration and low concentrations of K and ATP. 3. As in dog red cells, Na efflux from bear cells was not inhibited by ouabain but was activated by the presence of Ca in the medium, possibly indicating the presence of a Na-Ca exchange mechanism. 4. ATP depletion of cells was accelerated by Ca in the medium, consistent with the presence of a strong ATP-dependent Ca pump. 5. As in other carnivore red cells, Na influx into bear cells was strongly activated by shrinkage and inhibited by swelling. Shrinkage-activated influx was blocked by amiloride. 6. Amiloride-sensitive influx was activated by cytoplasmic Ca and also correlated with the presence of a Na-dependent, amiloride-sensitive H loss. 7. Amiloride-sensitive Na influx exhibited a strong seasonal cycle with a minimum in the middle of the hibernation period, suggesting a possible avenue of cellular energy conservation.

Maintenance of cation gradients in cold-stored erythrocytes of guinea pig and ground squirrel: improvement by amiloride

Red blood cells of ground squirrel, a hibernator, gain Na at one-third the rate of guinea pig red blood cells when stored in saline medium at 5 degrees C for several days. This result correlates with the known slower loss of K during storage in ground squirrel cells. In ground squirrel cells Na gain is balanced by K loss, so that there is no net gain of solute; in guinea pig cells the total cation content rises progressively. Amiloride, a drug which inhibits Na entry, retards Na uptake in cells of both species. Surprisingly, amiloride also slowed K loss and, in guinea pig red cells, the decline of ATP content. In guinea pig cells amiloride reduced the gain of total cation by half. The results substantiate the difference in cold sensitivity of ion regulation of red blood cells of these two species and demonstrate the possible usefulness of amiloride-type drugs in nonfreezing preservation of red blood cells.

Differential effects of cooling in hibernator and nonhibernator cells: Na permeation

Unidirectional Na influx is less inhibited by cooling in guinea pig red blood cells than in ground squirrel cells. To isolate the source of this difference, component pathways of 24Na entry were estimated by use of selective inhibitors (ouabain, bumetanide, amiloride). Amiloride slightly inhibited influx in ground squirrel cells at every temperature between 37 and 5 degrees C. Amiloride did not consistently inhibit Na influx at 37 degrees C in guinea pig cells but caused a 44% inhibition at 25 degrees C and a 35% inhibition at 5 degrees C. Cytoplasmic acidification caused an increase in amiloride-sensitive influx in guinea pig cells, which was greater at 20 degrees C than at 37 degrees C; cytoplasmic acidification decreased amiloride-sensitive Na influx in ground squirrel cells at 37 degrees C and had no effect at 20 degrees C.

Reduced ion transport in erythrocytes of male Sprague-Dawley rats during starvation

Although several studies have suggested that the reduced activity of the Na+-K+ pump during starvation is a source of energy conservation, the hypothesis has not been tested in intact cells, nor has the contribution of passive permeability been considered in a controlled animal study. In this study three components of K+ influx (Na+-K+ pump = ouabain sensitive, cotransport = bumetanide sensitive and leak = both ouabain and bumetanide insensitive) and Na+ influx were measured with 42K+ and 24Na+ in intact red blood cells of adult male rats. During starvation rats lost an average of 28% of their body weight; pump K+ influx in cells stabilized for 2 h in incubation medium fell from 7.03 +/- 0.74 (SEM) to 4.82 +/- 0.25 mueq/(mL cells.h) with cell [Na+] of 6.4 +/- 0.9 and 4.4 +/- 0.2 mmol/L cells, respectively. Maximized Na+-K+ pump activity in Na+-loaded cells was also lower in cells of starved rats than in those of controls and was inversely correlated with extent of weight loss in the starved rats. Leak K+ influx was reduced from 0.73 +/- 0.08 to 0.47 +/- 0.03. Lower Na+ influx in cells of starved rats was not significant statistically, although alteration in passive Na+ transport was apparent. The results indicate decreases in both active and passive components of ion turnover of erythrocytes of rats during starvation.

Active and passive transport of sodium and potassium ions in erythrocytes of severely malnourished Jamaican children

Erythrocytes of normal and malnourished children, both marasmic and oedematous (kwashiorkor), were equilibrated in standard incubation medium and their ion transport via the Na/K pump and the pathways of passive permeation were measured as unidirectional fluxes of 86Rb (as a congener of K) and 22Na. Cells of children with kwashiorkor exhibited a 65 per cent higher ouabain-sensitive K(Rb) influx ('pump rate') than those of normal or marasmic children. When allowance was made for cytoplasmic Na concentration, the pump rate was slower in younger (12 months and under) normal children than in older children. Judged by the same criterion, cells of older marasmic children also had slower steady-state pump activity. The passive permeation of K through the residual 'leak' pathway (ie, ouabain-and-bumetanide-insensitive influx) and Na permeation (ouabain-and-bumetanide-insensitive Na efflux) were greater in malnourished children than in normal children by a factor of two or more. During treatment for malnutrition, both Na-pump activity and ouabain binding increased rapidly in marasmic children. Passive permeation did not return to normal levels in malnourished children during the period of hospitalization.

The temperature dependence of passive potassium permeability in mammalian erythrocytes

The effect of temperature on the "passive" permeability of mammalian plasma membranes to K+, measured as the residual flux in the presence of ouabain and bumetanide, was investigated in erythrocytes of several species. Without Ca2+ in the medium, only human red cells demonstrated the "paradoxical" rise in passive flux at low temperature (i.e., below 12 degrees C) seen by other workers. In the other species no such effect was apparent; K+ influx decreased progressively with cooling down to 0 degree C. Below 18.5 degrees C the apparent energy of activation (Ea) was very low--close to that for free diffusion in water--for red cells of all species except human. Above 18.5 degrees C the Ea was much greater and was also more variable amongst the red cells of the species chosen. Neither the inhibitors used nor cell volume changes during incubation accounted for the absence of the paradoxical effect in the species studied here. A rise in permeation of K+ with cooling can, however, be produced by the addition of Ca2+ to the medium, probably by activation of the Ca2+-sensitive K+ channel. This effect would account for previous reports of a paradoxical effect in dog and rat erythrocytes.

Red cell amino acid transport. Evidence for the presence of system Gly in guinea pig reticulocytes

Guinea pig reticulocytes are shown to possess an Na+-dependent glycine transporter which also requires Cl- for activity. Glycine transport by this route is saturable (apparent Km 98 microM; Vmax 24 mumol/g Hb per h) and inhibited by sarcosine. The properties of this carrier closely resemble those of System Gly previously demonstrated in pigeon and human erythrocytes. In contrast, no System Gly activity was detected in mature guinea pig erythrocytes.

Differential effects of temperature on three components of passive permeability to potassium in rodent red cells

The effect of temperature on ouabain-insensitive fluxes of K+ was characterized in red cells from a non-hibernator (guinea-pig) and a hibernator (thirteen-lined ground squirrel). The residual K+ influx which remains in the presence of ouabain and bumetanide, and which is linearly dependent on [K+]o was the same in the erythrocytes of the two species at low temperature (5 degrees C). At 5 degrees C co-transport of K+ was abolished in guinea-pig red cells but was still present in ground squirrel red cells. In guinea-pig cells, ouabain-and-bumetanide-insensitive K+ flux was increased by Ca2+ at low temperatures. This flux was inhibited by quinine and selective for K+ over Na+, indicating activation of the Ca2+-sensitive K+ pathway (Gárdos channel). Ouabain-and-bumetanide-insensitive K+ permeability in red cells from the ground squirrel was insensitive to Ca2+ added to the medium at low temperature. When ground squirrel red cells were depleted of ATP or treated with A23187, Ca2+ induced a flux which was inhibitable by quinine. Hence, ground squirrel red cells possess Gárdos channels. The temperature sensitivity of the K+ channels was assessed using A23187-mediated K+ influx as a measure of Gárdos channel activation. The influence of temperature on the Ca2+-stimulated K+ fluxes under these conditions was indistinguishable between the two species. It is concluded that K+ loss through the Ca2+-sensitive K+ channel is minimal in hibernators' erythrocytes because of more efficient regulation of cytoplasmic Ca2+ during cold storage.

The effect of harmaline on unidirectional potassium fluxes and ouabain binding in renal cell cultures

Harmaline inhibits K+ influx into primary cell cultures of ground squirrel kidneys to a greater extent than either ouabain or furosemide. A concentration of 200 microM harmaline was required to inhibit half of the total K+ influx; this effect was also seen at low temperature (5 degrees C), and in another species (hamster). Although kinetic analysis of K+ influx indicates that harmaline does not compete with extracellular K+, harmaline did reduce the binding of [3H]ouabain to the cells. K+ efflux was also reduced. Therefore, harmaline may inhibit the furosemide-sensitive Na+/K+ cotransport system as well as the ouabain-sensitive Na+/K+ pump.

Kinetics of the sodium pump in red cells of different temperature sensitivity

Ouabain-sensitive K influx into ground squirrel and guinea pig red cells was measured at 5 and 37 degrees C as a function of external K and internal Na. In both species the external K affinity increases on cooling, being three- and fivefold higher in guinea pig and ground squirrel, respectively, at 5 than at 37 degrees C. Internal Na affinity also increased on cooling, by about the same extent. The effect of internal Na on ouabain-sensitive K influx in guinea pig cells fits a cubic Michaelis-Menten-type equation, but in ground squirrel cells this was true only at high [Na]i. There was still significant ouabain-sensitive K influx at low [Na]i. Ouabain-binding experiments indicated around 800 sites/cell for guinea pig and Columbian ground squirrel erythrocytes, and 280 sites/cell for thirteen-lined ground squirrel cells. There was no significant difference in ouabain bound per cell at 37 and 5 degrees C. Calculated turnover numbers for Columbian and thirteen-lined ground squirrel and guinea pig red cell sodium pumps at 37 degrees C were about equal, being 77-100 and 100-129 s-1, respectively. At 5 degrees C red cells from ground squirrels performed significantly better, the turnover numbers being 1.0-2.3 s-1 compared with 0.42-0.47 s-1 for erythrocytes of guinea pig. The results do not accord with a hypothesis that cold-sensitive Na pumps are blocked in one predominant form.

Properties of Na-K pump in primary cultures of kidney cells

Activities related to Na-K transport were measured in cell cultures of ground squirrel kidney cortex in order to compare these cells with those of intact kidney and of continuous cell lines. A microsomal preparation containing plasma membrane Na,K-ATPase from fresh kidney showed twice the activity of a similar preparation from 72-hour cultured cells. Na,K-ATPase of homogenates of 72-hour cells showed one-third to one-fourth the specific activity of that from 6-hour cultured cells. The associated K-dependent phosphatase activity also declined as a function of time in culture. The ouabain-sensitive influx of K into 6-hour cultured cells was twice as great as the K influx into 72-hour cells. The number of sites binding 3H-ouabain in intact cultured cells declined 81% on a cell protein basis between 6 and 72 hours in culture. This decline in ouabain binding sites was relatively greater than that of K influx, so that the K turnover number increased over this same time period. The decline in ouabain-sensitive K influx during culture was complementary to an increase in furosemide-sensitive K influx. Measurements of unidirectional and net K fluxes showed that there were three components of K influx into 3-day cultured cells: ouabain-sensitive Na:K exchange, furosemide-sensitive K:K exchange, and K diffusion. In the 6-hour cultures, however, there was no furosemide-sensitive K:K exchange. Thus, after three days in culture ground squirrel kidney cells lose a feature characteristic of the original parent cells (high Na,K-ATPase activity), and gain a feature common to many undifferentiated cultured cells (furosemide-sensitive K:K exchange).

Na-K pump and Na-K-ATPase: disparity of their temperature sensitivity

As previously observed in red blood cells, ouabain-sensitive K influx of kidney cells grown in culture for 3 days was much less inhibited by cooling that Na-K-ATPase of the same cells. (At 5 degrees C K influx was 9.7% of that at 38 degrees C, Na-K-ATPase, 1--2%.) Resealed ghosts of erythrocytes of ground squirrels were made containing 24Na and ATP, and the Na efflux and ATP hydrolysis were measured simultaneously. Under these conditions there was no difference in the reduction of activity with cooling, and the amount of reduction was close to that of active K transport in intact cells. The high sensitivity to temperature, characteristic of broken membranes, could not be induced in intact cells or resealed ghosts by eliminating either the Na/K gradient or the ATP gradient nor by chelation of cellular and extracellular Ca. It could not be eliminated in broken membranes by protection with ATP or Mg. Structural reorganization of membrane during lysis may cause the increase in temperature sensitivity of Na-K-ATPase.

Temperature dependence of membrane function. Disparity between active potassium transport and (Na+ & K+)ATPase activity

Ouabain-sensitive K+ influx in mammalian erythrocytes exhibits far less temperature sensitivity than the ((Na+ & K+)ATPase prepared by hypotonic lysis from the same population of cells. The results are not in accord with lipid phase change as the critical mechanism of cold inhibition of intact pumps.

Cultured cells from renal cortex of hibernators and nonhibernators. Regulation of cell K+ at low temperature

Cells were grown as primary monolayer cultures from kidney cortex of guinea pigs (nonhibernators), hamsters and ground squirrels (both hibernating species). When plates of cells were placed at 5 degrees C, cells of guinea pigs lost 37% of their K+ in 2 h and those of the hibernator lost about 10%. Uptake of 42K into the cells exhibited a simple, single exponential time course at both temperatures. Unidirectional efflux of K+ was equal to K+ influx in all cultures at 37 degrees C and, within limits of error, in hibernator cells at 5 degrees C. Efflux was 3-to 5-fold greater than influx in guinea pig cells at 5 degrees C. After 2 h in the cold the ouabain sensitive K+ influx remaining (7-15% of that at 37 degrees C) was about the same in the cells of the 3 species. Cells from active hamsters and from hibernating ground squirrels, however, exhibited significantly greater pump activity after 45 min in the cold (19 and 14%, respectively). The stimulation of K+ influx by increasing [K+] did not show an increase in Km+ at 5 degrees C in cells of guinea pigs and ground squirrels. Lowering [K+]c and/or raising [Na+]c by treatment in low- and high-K+ media caused only slight stimulation of K+ influx, except in cells of ground squirrels at 5 degrees C in which the stimulation was at least 11-times greater than at 37 degrees C or in cells of guinea pigs at either temperature. This altered kinetic response of K+ transport to cytoplasmic ion stimulation with cooling accounted for about one-third of the improved regulation of K+ at 5 degrees C in ground squirrel cells; the other two-thirds was attributable to a greater decrease in K+ leak with cooling. The inhibition of active transport by cold in all 3 species was much less severe than that previously seen in any (Na++K+)-ATPase of mammalian cells.

Binding of the cardiac glycoside ouabain to intact cells

1. Measurements were made of the binding of [(3)H]ouabain to a variety of cell types.2. Two components of binding could usually be distinguished: a component that saturated at low glycoside concentrations and a component that increased up to the highest ouabain concentrations examined.3. Detailed studies with HeLa cells and kidney slices from guinea-pigs showed that the saturable component is probably associated with inhibition of the Na pump. The main evidence for this is (a) at low concentrations of ouabain there is a close correspondence between the concentration of ouabain giving half-maximum binding and the concentration giving half-maximum inhibition of the Na pump; (b) at low glycoside concentrations, binding precedes inhibition of the Na pump; (c) the rate of binding is very sensitive to external K ions, being highest in the absence of K; (d) binding is reversible and the release of ouabain is associated with reactivation of the Na pump, (e) binding is reduced in the absence of Na ions and in the presence of metabolic inhibitors; (f) binding has a Q(10) of about 4; and (g) in the presence of Na and ATP, lysed HeLa cells bind a similar amount of ouabain and the binding is sensitive to K ions.4. The linear component of binding does not seem to involve the Na pump and it may reflect uptake of ouabain into the cell interior. It has a Q(10) of 2.5 and is unaffected by K concentrations which have a large effect on the saturable component.5. Bound ouabain could be removed from HeLa cells by low pH, trichloroacetic acid, urea, high temperatures and 100% ethanol. These agents did not distinguish between the two components of binding.6. Criteria are developed for estimating the number of Na pumping sites in cells and the data for ouabain-binding to a number of cells is compared with the activity of the (Na + K)-activated ATPase in the same tissues. Although the number of pumping sites varies from less than 1/mu(2) to 1500/mu(2) of membrane, the turnover at these sites seems to be fairly constant between 3,500 and 15,000 min(-1) at 35 degrees C.

Inhibition of the sodium pump in squid giant axons by cardiac glycosides: dependence on extracellular ions and metabolism

1. The rate of inhibition of the Na pump by ouabain was examined both by direct measurement of the rate of decline of the Na efflux and by the binding of [(3)H]ouabain.2. The onset of inhibition of the Na efflux was concentration-dependent; but did not follow simple first order kinetics. The time course of inhibition was roughly exponential although in about 30% of the axons inhibition was preceded by a transient stimulation of the Na efflux.3. Inhibition of the Na efflux by both ouabain and strophanthidin was apparently irreversible.4. The onset of inhibition was slowed markedly at low temperatures.5. Replacement of external Na by choline, dextrose or potassium slowed the rate of inhibition. Li behaved like Na and inhibition was faster in K-ASW than in choline-ASW.6. The rate of inhibition of Na-Na exchange was similar to that of Na-K exchange, but ouabain failed to bind securely to fully poisoned axons.7. Two components of [(3)H]ouabain-binding could be distinguished. A linear component which probably reflects uptake into the cells and a saturable component which seems to reflect binding to Na-pumping sites.8. The saturable component of binding followed a similar time course to the inhibition of the Na efflux and the rate of binding was reduced in choline-ASW and in fully poisoned axons.9. Measurements of [(3)H]ouabain-binding indicate that the number of Na pumping sites in the axon membrane is probably between 10(3) and 10(4)/mu(2).

Resistance of erythrocytes of hibernating mammals to loss of potassium during hibernation and during cold storage

In two species of hibernators, hamsters and ground squirrels, erythrocytes were collected by heart puncture and the K content of the cells of hibernating individuals was compared with that of awake individuals. The K concentration of hamsters did not decline significantly during each bout of hibernation (maximum period of 5 days) but in long-term bouts in ground squirrels (i.e. more than 5 days) the K concentration of cells dropped significantly. When ground squirrels were allowed to rewarm the K content of cells rose toward normal values within a few hours. Erythrocytes of both hamsters and ground squirrels lose K more slowly than those of guinea pigs (nonhibernators) when stored in vitro for up to 10 days at 5 degrees C. In ground squirrels the rate of loss of K during storage is the same as in vivo during hibernation, and stored cells taken from hibernating ground squirrels also lose K at the same rate. The rate of loss of K from guinea pig cells corresponded with that predicted from passive diffusion unopposed by transport. The actual rate of loss of K from ground squirrel cells was slower than such a predicted rate but corresponded with it when glucose was omitted from the storage medium or ouabain was added to it. Despite the slight loss of K that may occur in hibernation, therefore, the cells of hibernators are more cold adapted than those of a nonhibernating mammal, and this adaptation depends in part upon active transport.

Temperature adaptation of active sodium-potassium transport and of passive permeability in erythrocytes of ground squirrels

Unidirectional active and passive fluxes of (42)K and (24)Na were measured in red blood cells of ground squirrels (hibernators) and guinea pigs (nonhibernators). As temperature is lowered, "active" (ouabain-sensitive) K influx and Na efflux were more greatly diminished in guinea pig cells than in those of ground squirrels. The fraction of total K influx which is ouabain sensitive in red blood cells of ground squirrels was virtually constant at all temperatures, whereas it decreased abruptly in guinea pig cells as temperature was lowered. All the passive fluxes (i.e., Na influx, K efflux, and ouabain-insensitive K influx and Na efflux) decreased logarithmically with decrease in temperature in both species, but in ground squirrels the temperature dependence (Q(10) 2.5-3.0) was greater than in guinea pig (Q(10) 1.6-1.9). Thus, red blood cells of ground squirrel are able to resist loss of K and gain of Na at low temperature both because of relatively greater Na-K transport (than in cells of nonhibernators) and because of reduced passive leakage of ions.