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).     

Peritubular Na-K exchange ion pump in maleate-treated frog kidney proximal tubular cells

• 1.1. After perfusion of isolated frog kidneys for 1 hr with 10⁻³ or 10⁻² M maleate Ringer, the peritubular membrane potential gradually declined in a dose-dependent manner.
• 2.2. The ouabain-like effects of maleate on cell Na and K activities were dose-dependent and smaller than the effects of zero K or 10⁻⁴M ouabain. Intracellular pH was not altered in the presence of 10⁻²M maleate.
• 3.3. The driving force for Na entry into the cell was reduced, respectively, to 81.4 and 58.4% (of control) in the presence of 10⁻³ and 10⁻² M maleate.
• 4.4. There was no histochemically detectable inhibition of proximal tubule Na-K ATPase activity during 3 hr of perfusion with 10⁻² M maleate.

     

Measurement of Na-K pump current in acinar cells of rat lacrimal glands.

Isolated cells from rat lacrimal glands were voltage clamped using the tight-seal whole-cell recording technique. The intracellular solution contained ATP and an elevated Na concentration (70 mM). Removing external K ions elicited an inward current shift. Ouabain (0.5 mM) induced an inward current shift of identical amplitude, but with slower kinetics. In the presence of ouabain, removal of K ions did not alter the cell current. The potassium- and ouabain-sensitive current was outward between -120 and +20 mV, and its amplitude decreased below -60 mV. This current was highly sensitive to temperature, and was not affected by blockers of the K channels which are present in these cells. It was attributed to an inhibition of the Na-K pump. The Na-K pump current was estimated to be 15 pA for an average acinar cell at physiological temperature, with 70 mM internal Na ions and 20 mM external K ions. Implications of this value in terms of electrolyte secretion are discussed.     

Na-K pump current in the Amphiuma collecting tubule

There is strong evidence supporting the hypothesis of an electrogenic Na-K pump in the basolateral membrane of several epithelia. Thermodynamic considerations and results in nonepithelial cells indicate that the current carried by the pump could be voltage dependent. In order to measure the pump current and to determine its voltage dependence in a tight epithelium, we have used the isolated perfused collecting tubule of Amphiuma and developed a technique for clamping the basolateral membrane potential (Vbl) through transepithelial current injection. The transcellular current was calculated by subtracting the paracellular current (calculated from the transepithelial conductance measured in the presence of luminal amiloride) from the total transepithelial current. Basolateral membrane current-voltage (I-V) curves were obtained in conditions where the ratio of the pump current to the total basolateral membrane current had been maximized by loading the cells with Na+ (exposure to low-K+ bath), and by blocking the basolateral K+ conductance with barium. The pump current was defined as the difference of the current across the basolateral membrane measured before and 10-15 s after the addition of strophanthidin (20 microM) to the bath solution. With a bath solution containing 3 mM K+, the pump current was nearly constant in the Vbl range of -20 to -80 mV (52 +/- 5 microA.cm-2 at -60 mV) but showed a marked voltage dependence at higher negative Vbl (pump current decreased to 5 +/- 9 microA.cm-2 at -180 mV). In a 1.0 mM K bath, the shape of the pump I-V curve was similar but the amplitude of the current was decreased (24 +/- 4 microA.cm-2 at -60 mV). In a 0.1 mM K bath, the pump current was not significantly different from 0. Our results indicate that the basolateral Na-K pump generates a current which depends on the extracellular potassium concentration. With physiological peritubular concentration of K+ and in the physiological range of potential, the pump activity, measured as the pump-generated current, was independent of the membrane potential.     

Cyclic AMP stimulation of Na-K pump activity in quiescent swiss 3T3 cells

Recently, we have found that an increase in the intracellular level of cAMP acts as a mitogenic signal for Swiss 3T3 cells (Rozengurt et al., Proc. Natl. Acad, Sci. USA, 78:4392, 1981). The results presented in this paper demonstrate that addition of cAMP-elevating agents to confluent and quiescent cultures of Swiss 3T# causes a marked increase in the rate of 86Rb+ uptake but has no effect on the rate of cation efflux. The stimulation of ion uptake is mediated by the Na-K pump as shown by the ouabain sensitivity of the 86Rb+ fluxes. The increase in Na-K pump activity occurs whether cAMP is generated endogenously by stimulation of adenylate cyclase activity by cholera toxin, adenosine agonists, or PGE1 or added exogenously as 8BrcAMP. The stimulatory effect of these compounds on 86Rb+ uptake is potentiated by inhibitors of cyclic nucleotide phosphodiesterase activity. Cholera toxin stimulates the Na-K pump in a dose-dependent manner; half-maximal effect is achieved at 0.7 ng/ml. The stimulation of ouabain-sensitive 86Rb+ uptake by cAMP-elevating agents reaches a maximum after 2-3 h of incubation. This contrasts with the rapid (within minutes) stimulation of the Na-K pump caused by serum and other mitogenic agents. Further, cAMP-elevating agents fail to increase Na+ influx into 3T3 cells whereas serum causes a marked increase in Na+ influx, under identical experimental conditions. These findings suggest that the stimulation of Na-K pump activity caused by increased cAMP levels contrasts mechanistically with the rapid control of pump activity by serum which is primarily mediated by increased Na+ entry into the cells.     

Stimulation of heart sarcolemmal calcium pump by calmodulin

The sarcolemmal membranes obtained from rat heart by sucrose-density gradient method were found to exhibit Ca²⁺ stimulated Mg²⁺ dependent ATPase and ATP-dependent Ca²⁺ binding activities. The Ca²⁺ stimulated ATPase activity was increased by calmodulin; maximal effect was seen at 1 to 5 μg/ml concentrations of calmodulin. The observed activation of the enzyme was associated with an increase in Vmax value from 3.45 to 5.26 μmol Pi/mg protein/hr and a decrease in Ka value from 2.78 to 0.84 μM Ca²⁺. Calmodulin was also found to increase ATP-dependent Ca²⁺ binding by 1.6 to 2.2 fold. These results suggest that the activity of Ca²⁺ pump mechanism in heart sarcolemma is regulated by calmodulin.     

Pharmacological intervention in oxidant-induced calcium pump dysfunction of dog heart

Micromolar concentrations of HOCl, an oxidant produced by activated neutrophils, inhibited Ca2+ uptake and Ca2+ATPase of isolated dog heart sarcoplasmic reticulum (SR). DTT antagonized completely the HOCl effect only when it was given within 5 min after the addition of HOCl. When the pharmacological intervention was delayed, the recovery with DTT was not complete, and administration of DTT 30 min after the start of HOCl's reaction with SR resulted in only a small improvement in SR Ca2+ uptake. Although H2O2 and Fe ion-chelate (a free radical-generating procedure) also inhibited Ca2+ uptake and ATPase, the concentrations required were very large. The response of cardiac sarcolemmal and skeletal muscle SR calcium pumps to oxidants was similar to that of the cardiac SR calcium pump.     

Stimulation of calcium pump activity in heart sarcolemma by timolol

The effects of beta-adrenergic blocking agents, timolol and atenolol (1-1000 microM), were studied on rat heart sarcolemmal ATPase and Ca2+ binding activities. Timolol, unlike atenolol, increased both Ca2+-stimulated ATPase and ATP-dependent Ca2+ binding; the maximal effects were seen at 1 microM concentration of timolol. Both timolol and atenolol did not alter the sarcolemmal Mg2+ ATPase and nonspecific Ca2+ binding activities. Sarcolemmal Ca2+-stimulated ATPase was also activated by concanavalin A (6-66 micrograms/mL) which is known to alter membrane fluidity; however, Mg2+ ATPase was unaffected by this agent. These results indicate that timolol may stimulate Ca2+ pump activity in heart sarcolemma by changing membrane fluidity in a manner similar to that of concanavalin A.     

Coupling ratio of the Na-K pump in the lobster cardiac ganglion

The electrogenic Na-K pump coupling ratio in the large neurons of the lobster cardiac ganglion was determined by two different electrophysiological techniques. A graphical analysis plotting exp(EmF/RT) vs. [K]o after the pump was blocked by ouabain was used to determine values for [K]i, PNa/PK, and the pump coupling ratio. These measurements were made 4-8 h after the cells were penetrated with microelectrodes, and thus represent non-Na-loaded steady state values. The value obtained for the pump coupling ratio under these conditions was 1.44 +/- 0.06 (n = 9) or close to 3 Na for 2 K. The second technique used to measure the coupling ratio was to iontophoretically inject Na ions into the neuron. Neurons were penetrated with three microelectrodes, two of which were filled with 2 M Na-citrate; the third electrode contained either 2 M K-citrate or 3 M KCl. By passing current between the Na salt-containing electrodes, Na was injected into the cell soma. The injection system was calibrated by injecting 24Na-citrate into counting vials from representative microelectrodes (calculated 24Na transport = 0.92). By knowing the Na load injected into the cells, and by measuring the time-current area produced by the Na activation of the Na-K pump, the coupling ratio was calculated to be 1.54 +/- 0.05 (n = 19), which is not significantly different from the value obtained by the first method. This value represents a Na-loaded experimental situation. When Na was removed from the external bathing solution, the coupling ratio shifted to 2 Na to 1 K (2.0 +/- 0.07, n = 4). These results suggest that the pump normally operates with a 3:2 ratio both in steady state and under Na load but that in the absence of external Na, it can operate with less than a full complement (2) of K on the external surface of the pump.     

Serum stimulates na entry and the Na-K pump in quiescent cultures of epithelial cells (MDCK)

The growth of an epithelial canine kidney line (MDCK) was reversibly arrested by gradually lowering the serum concentration in the medium over a 3-day period. The cells were demonstrably quiescent by autoradiography after an additional 24 hours in serum-free media. Addition of fresh serum produced DNA synthesis after an 18-hour lag period. The quiescent cells then grew to confluency retaining their transport capacities as seen by the formation of “domes”. This system allows for measurement of monovalent ion fluxes and its relationship to growth regulation. The addition of fresh serum to quiescent MDCK cells increased the uptake of ⁸⁶Rb, a measure of Na-K pump activity. This stimulation was mediated by increased uptake of Na into the cells. Serum-stimulated DNA synthesis was blocked by the addition of ouabain in concentrations that inhibit the Na-K pump. Serum appears to stimulate growth in epithelial cells by increasing the amount of intracellular Na available to the Na-K pump. Monovalent ion transport may play a role in the regulation of epithelial cell proliferation.     

Reversal of the calcium pump in human red cells

Summary Human red cells containing low ATP and high P_i concentrations were suspended in media with and without 2mm Ca²⁺, and the incorporation of (³²P)P_i into ATP was measured. There was some incorporation whatever the medium, but in every experiment there was an extra incorporation when the cells were in the Ca²⁺-containing medium. This extra incorporation was abolished by the ionophore A23187, which collapses the Ca²⁺ concentration gradient across the membranes, or by LaCl₃, which blocks the Ca²⁺ pump. Starved and phosphate-loaded cells also show an uptake of Ca²⁺ which is not apparent in fresh cells. Results are consistent with the idea that Ca²⁺-dependent incorporation of P_i into ATP is catalyzed by the Ca²⁺ pump using energy derived from the Ca²⁺ concentration gradient.     

Melittin stimulates Na entry,Na-K pump activity and DNA synthesis in quiescent cultures of mouse cells

Melittin, an amphipatic polypeptide, increases several fold the activity of Na-K pump in quiescent Swiss 3T3 cells. As with other growth factors, melittin increases the activity of the pump by increasing Na entry into the cell. In contrast, other early responses are not elicited by the toxin. At concentrations that promote ion fluxes, melittin stimulates DNA synthesis in quiescent mouse cells acting synergistically with insulin, epidermal growth factor and with the growth factor released by SV40 BHK cells. In contrast, melittin does not interact synergistically with either phorbol esters or vasopressin. The cellular effects of melittin are consistent with the proposal that ion fluxes signal the initiation of mitogenesis in quiescent cells.     

The physical mechanism of calcium pump regulation in the heart.

The Ca-ATPase in the cardiac sarcoplasmic reticulum membrane is regulated by an amphipathic transmembrane protein, phospholamban. We have used time-resolved phosphorescence anisotropy to detect the microsecond rotational dynamics, and thereby the self-association, of the Ca-ATPase as a function of phospholamban phosphorylation and physiologically relevant calcium levels. The phosphorylation of phospholamban increases the rotational mobility of the Ca-ATPase in the sarcoplasmic reticulum bilayer, due to a decrease in large-scale protein association, with a [Ca2+] dependence parallel to that of enzyme activation. These results support a model in which phospholamban phosphorylation or calcium free the enzyme from a kinetically unfavorable associated state.     

Quantitative intracellular calcium imaging with laser-scanning confocal microscopy

Laser-scanning confocal microscopy has been used to visualise the fluorescence of a visible wavelength Ca2(+)-sensitive fluorophore, Fluo-3 in isolated cardiac myocytes. A protocol for the derivation of quantitative information from this single wavelength indicator is presented. This paradigm involves co-loading cells with two Ca2(+)-sensitive fluorescent indicators, Fluo-3 and Fura-2. Wide-field ratiometric measurements of Fura-2 fluorescence provided a baseline [Ca2+] upon which changes in Fluo-3 fluorescence could be directly expressed as [Ca2+] changes. The Ca2+ changes occurring in spontaneously active cardiac cells are presented as an example of the method. Although fluorescence energy transfer between Fura-2 and Fluo-3 was detectable in some in vitro mixtures of the two fluorophores, this process was not evident in co-loaded cardiac cells under the loading conditions employed.