Functional Analysis and Molecular Modeling of a Cloned Urate Transporter/Channel

Recombinant protein, designated UAT, prepared from a cloned rat renal cDNA library functions as a selective voltage-sensitive urate transporter/channel when fused with lipid bilayers. Since we previously suggested that UAT may represent the mammalian electrogenic urate transporter, UAT has been functionally characterized in the presence and absence of potential channel blockers, several of which are known to block mammalian electrogenic urate transport. Two substrates, oxonate (a competitive uricase inhibitor) and pyrazinoate, that inhibit renal electrogenic urate transport also block UAT activity. Of note, oxonate selectively blocks from the cytoplasmic side of the channel while pyrazinoate only blocks from the channel's extracellular face. Like oxonate, anti-uricase (an electrogenic transport inhibitor) also selectively blocks channel activity from the cytoplasmic side. Adenosine blocks from the extracellular side exclusively while xanthine blocks from both sides. These effects are consistent with newly identified regions of homology to uricase and the adenosine A1/A3 receptor in UAT and localize these homologous regions to the cytoplasmic and extracellular faces of UAT, respectively. Additionally, computer analyses identified four putative α-helical transmembrane domains, two β sheets, and blocks of homology to the E and B loops of aquaporin-1 within UAT. The experimental observations substantiate our proposal that UAT is the molecular representation of the renal electrogenic urate transporter and, in conjunction with computer algorithms, suggest a possible molecular structure for this unique channel. Received: 13 October 1998/Revised: 28 January 1999     

Electrogenic transport of sodium ions in cytoplasmic and extracellular ion access channels of Na+,K+-ATPase probed by admittance measurement technique

Electrogenic movements of sodium ions in cytoplasmic and extracellular access channel of the Na⁺,K⁺-ATPase have been studied by the admittance measurement technique which allows the detection of small changes of the membrane capacitance and conductance induced by phosphorylation of the ion pump. The measurements were carried out on a model system consisting of a bilayer lipid membrane, to which membrane fragments with ion pumps were adsorbed that contain the ion pumps in high density. Small changes of the membrane capacitance and conductance were induced by a fast release of ATP from caged ATP. The effect was measured at various frequencies and in solutions with different Na⁺ concentrations. The experimentally observed frequency dependences were explained using a theoretical model assuming that Na⁺ movement through the cytoplasmic access channel occurs in one step and through the extracellular access channel, in two steps. The phosphorylation of the protein by ATP leads to a block of the cytoplasmic access channel and an opening the extracellular access channel. The disappearance of electrogenic Na⁺ movements on the cytoplasmic side produces a negative change of capacitance and conductance, while the emergence of extracellular Na⁺ movements generates a positive change. Fitting the experimental dependences of capacitance and conductance by theoretical curves allowed the determination equilibrium and kinetic parameters of sodium transport in the access channels. The text was submitted by the authors in English.     

Electrogenic Partial Reactions of the SR-Ca-ATPase Investigated by a Fluorescence Method

A fluorescence method was adapted to investigate active ion transport in membrane preparations of the SR-Ca-ATPase. The styryl dye RH421 previously used to investigate the Na,K-ATPase was replaced by an analogue, 2BITC, to obtain optimized fluorescence changes upon substrate-induced partial reactions. Assuming changes of the local electric field to be the source of fluorescence changes that are produced by uptake/release or by movement of ions inside the protein, 2BITC allowed the determination of electrogenic partial reactions in the pump cycle. It was found that Ca²⁺ binding on the cytoplasmic and on the lumenal side of the pump is electrogenic while phosphorylation and conformational transition showed only minor electrogenicity. Ca²⁺ equilibrium titration experiments at pH 7.2 in the two major conformations of the protein indicated cooperative binding of two Ca²⁺ ions in state E₁ with an apparent half-saturation concentration, K _M of 600 nm. In state P-E₂ two K _M values, 5 μm and 2.2 mM, were determined and are in fair agreement with published data. From Ca²⁺ titrations in buffers with various pH and from pH titrations in P-E₂, it could be demonstrated that H⁺ binding is electrogenic and that Ca²⁺ and H⁺ compete for the same binding site(s). Tharpsigargin-induced inhibition of the Ca-ATPase led to a state with a specific fluorescence level comparable to that of state E₁ with unoccupied ion sites, independent of the buffer composition. Received: 21 September 1998/Revised: 18 December 1998     

Adenine-nucleotide levels and metabolism-dependent membrane potential in cells of Nitellopsis obtusa Groves

The relationship between adenine-nucleotide levels and metabolism-dependent membrane potential was studied in cells of Nitellopsis obtusa. Effects of ADP and AMP in the presence of ATP on electrogenic pump activity were measured in the dark, using the continuous perfusion method. Both ADP and AMP acte as competitive inhibitors for ATP, the K_i value for either compound being about 0.4 mM. The role of ADP and AMP as regulating factors for the electrogenic pump was investigated under various metabolic conditions. Application of N₂ gas in the dark caused a significant membrane depolarization amounting to 90 mV, but cytoplasmic streaming and membrane excitability were not affected. Under anoxia, the ATP level decreased from 1.6 to 0.5 mM; ADP increased but only slightly, and AMP increased greatly. However, the time course of changes in the adenine nucleotides was not concurrent with that of the membrane-potential changes, thus, the adenine-nucleotide level changes cannot fully account for the N₂-elicited depolarization. Under light, although the membrane hyperpolarized, no significant changes in the adenine-nucleotide levels were observed. Therefore, the light-induced membrane hyperpolarization cannot be explained solely by changes in adenine-nucleotide levels.Abbreviations APW artificial pond water - E_m membrane potential - R_m membrane resistance     

The carrier reorientation step in erythrocyte choline transport: pH effects and the involvement of a carrier ionizing group

Summary Under zero-trans conditions, the facilitated transport of choline across the erythrocyte membrane is limited by the rate of reorientation of the free carrier; as a result the pH dependence of this step can be investigated, independent of other steps in transport. It is found that as the pH declines (between 8.0 and 6.0) the rate of inward movement of the free carrier rises and the rate of outward movements falls, so that the partition of the free carrier increasingly favors the inward-facing form. When the pH of the cell interior and of the medium are varied independently, the partition responds to the internal but not the external pH. The membrane potential, which varies somewhat as the pH is altered, has no effect on the carrier partition. The analysis of the results indicates that the carrier mobility is dependent on an ionizing group of pK _a 6.8, which is exposed on the cytoplasmic surface of the membrane in the inward-facing carrier; in the out-ward-facing carrier the ionizing group appears to be masked, in that its pK _a is shifted downward by more than one unit. The observations can be explained by assuming that an ionizing group is located in the wall of a gated channel connecting the substrate site with the cytoplasmic face of the cell membrane.     

Stimulation of the glucose carrier SGLT1 by JAK2

JAK2 (Janus kinase-2) overactivity contributes to survival of tumor cells and the ^V617FJAK2 mutant is found in the majority of myeloproliferative diseases. Tumor cell survival depends on availability of glucose. Concentrative cellular glucose uptake is accomplished by Na⁺ coupled glucose transport through SGLT1 (SLC5A1), which may operate against a chemical glucose gradient and may thus be effective even at low extracellular glucose concentrations. The present study thus explored whether JAK2 activates SGLT1. To this end, SGLT1 was expressed in Xenopus oocytes with or without wild type JAK2, ^V617FJAK2 or inactive ^K882EJAK2 and electrogenic glucose transport determined by dual electrode voltage clamp experiments. In SGLT1-expressing oocytes but not in oocytes injected with water or JAK2 alone, the addition of glucose to the extracellular bath generated a current (I_g), which was significantly increased following coexpression of JAK2 or ^V617FJAK2, but not by coexpression of ^K882EJAK2. Kinetic analysis revealed that coexpression of JAK2 enhanced the maximal transport rate without significantly modifying the affinity of the carrier. The stimulating effect of JAK2 expression was abrogated by preincubation with the JAK2 inhibitor AG490. Chemiluminescence analysis revealed that JAK2 enhanced the carrier protein abundance in the cell membrane. The decline of I_g during inhibition of carrier insertion by brefeldin A was similar in the absence and presence of JAK2. Thus, JAK2 fosters insertion rather than inhibiting retrieval of carrier protein into the cell membrane. In conclusion, JAK2 upregulates SGLT1 activity which may play a role in the effect of JAK2 during ischemia and malignancy.     

Electrogenic effect during active lithium transport through somatic membrane of molluscan neurons

The effect of replacement of sodium and (or) potassium by lithium on the electrogenic effect of active ion transport through the somatic membrane of isolated neurons was studied in the snailPlanorbarius corneus. Changes observed in the electrogenic effect are evidence that intracellular lithium can be actively exchanged for extracellular potassium; lithium can play the role of extracellular potassium during activation of the pump, and intracellular lithium is actively exchanged for extracellular.     

Sequential potassium binding at the extracellular side of the Na,K-Pump

Ion binding at the extracellular face of the Na,K-ATPase is electrogenic and can be monitored by the styryl dye RH 421 in membrane fragments containing a high density of the Na,K-pumps. The fluorescent probe is noncovalently bound to the membrane and responds to changes of the local electric field generated by binding or release of cations inside the protein. Due to the fact that K⁺ binding from the extracellular side is an electrogenic reaction, it is possible to detect the amount of ions bound to the pump as function of the aqueous concentration. The results are in contradiction to a second order reaction, i.e., a simultaneous binding of two K⁺ ions. A mathematical model is presented to discuss the nature of the two step binding process. On the basis of this model the data allow a quantitative distinction between binding of the first and the second K⁺ ion. The temperature dependence of ion binding has been investigated. At low temperatures the apparent dissociation constants differ significantly. In the temperature range above 20°C the resulting apparent dissociation constants for both K⁺ ions merge and have values between 0.2 and 0.3 mm, which is consistent with previous experiments. The activation energy for the half saturating concentration of K⁺ is 22 kJ/mol. Additional analysis of the titration curve of K⁺ binding to the state P — E₂ by the Hill equation yields a Hill coefficient, n_Hill, of 1.33, which is in agreement with previously published data.The authors would like to thank G. Witz for technical assistance. This work has been financially supported by the Deutsche Forschungsgemeinschaft (SFB 156).     

The electrogenic sodium pump of the frog retinal pigment epithelium

Summary It was previously shown that ouabain decreases the potential difference across anin vitro preparation of bullfrog retinal pigment epithelium (RPE) when applied to the apical, but not the basal, membrane and that the net basal-to-apical Na⁺ transport is also inhibited by apical ouabain. This suggested the presence of a Na⁺–K⁺ pump on the apical membrane of the RPE. In the present experiments, intracellular recordings from RPE cells show that this pump is electrogenic and contributes approximately –10 mV to the apical membrane potential (V _AP). Apical ouabain depolarizedV _AP in two phases. The initial, fast phase was due to the removal of the direct, electrogenic component. In the first one minute of the response to ouabain,V _AP depolarized at an average rate of 4.4±0.42 mV/min (n=10, mean ±sem), andV _AP depolarized an average of 9.6±0.5 mV during the entire fast phase. A slow phase of membrane depolarization, due to ionic gradients running down across both membranes, continued for hours at a much slower rate, 0.4 mV/min. Using a simple diffusion model and K⁺-specific microelectrodes, it was possible to infer that the onset of the ouabain-induced depolarization coincided with the arrival of ouabain molecules at the apical membrane. This result must occur if ouabain affects an electrogenic pump. Other metabolic inhibitors, such as DNP and cold, also produced a fast depolarization of the apical membrane. For a decrease in temperature of 10°C, the average depolarization of the apical membrane was 7.1±3.4 mV (n=5) and the average decrease in transepithelial potential was 3.9±0.3 mV (n=10). These changes in potential were much larger than could be explained by the effect of temperature on anRT/F electrodiffusion factor. Cooling the tissue inhibited the same mechanism as ouabain, since prior exposure to ouabain greatly reduced the magnitude of the cold effect. Bathing the tissue in 0mm [K⁺] solution for 2 hr inhibited the electrogenic pump, and subsequent re-introduction of 2mm [K⁺] solution produced a rapid membrane hyperpolarization. We conclude that the electrogenic nature of this pump is important to retinal function, since its contribution to the apical membrane potential is likely to affect the transport of ions, metabolites, and fluid across the RPE.     

Influence of Ca on the plasma membrane potential and electrogenic uptake of glycine by myeloma cells. Involvement of a Ca-activated K channel

The involvement of Ca²⁺-activated K⁺ channels in the regulation of the plasma membrane potential and electrogenic uptake of glycine in SP 2/0-AG14 lymphocytes was investigated using the potentiometric indicator 3,3′-diethylthiodicarbocyanine iodide. The resting membrane potential was estimated to be −57 ± 6 mV (n = 4), a value similar to that of normal lymphocytes. The magnitude of the membrane potential and the electrogenic uptake of glycine were dependent on the extracellular K⁺ concentration, [K⁺]_o, and were significantly enhanced by exogenous calcium. The apparent V_max of Na⁺-dependent glycine uptake was doubled in the presence of calcium, whereas the K_0.5 was not affected. Ouabain had no influence on the membrane potential under the conditions employed. Additional criteria used to demonstrate the presence of Ca²⁺-activated K⁺ channels included the following: (1) addition of EGTA to calcium supplemented cells elicited a rapid depolarization of the membrane potential that was dependent on [K⁺]_o; (2) the calmodulin antagonist, trifluoperazine, depolarized the membrane potential in a dose-dependent and saturable manner with an IC₅₀ of 9.4 μM; and (3) cells treated with the Ca²⁺-activated K⁺ channel antagonist, quinine, demonstrated an elevated membrane potential and depressed electrogenic glycine uptake. Results from the present study provide evidence for Ca²⁺-activated K⁺ channels in SP 2/0-AG14 lymphocytes, and that their involvement regulates the plasma membrane potential and thereby the electrogenic uptake of Na⁺-dependent amino acids.     

Potassium transport across the frog retinal pigment epithelium

Summary Previous experiments indicate that the apical membrane of the frog retinal pigment epithelium contains electrogenic NaK pumps. In the pressent experiments net potassium and rubidium transport across the epithelium was measured as a function of extracellular potassium (rubidium) concentration, [K] _o ([Rb] _o ). The net rate of retina-to-choroid⁴²K(⁸⁶Rb) transport increased monotonically as [K] _o ([Rb] _o ), increased from approximately 0.2 to 5mm on both sides of the tissue or on the apical (neural retinal) side of the tissue. No further increase was observed when [K] _o ([Rb] _o ) was elevated to 10mm. Net sodium transport was also stimulated by elevating [K] _o . The net K transport was completely inhibited by 10^–4 m ouabain in the solution bathing the apical membrane. Ouabain inhibited the unidirectional K flux in the direction of net flux but had not effect on the back-flux in the choroid-to-retina direction. The magnitude of the ouabain-inhibitable⁴²K(⁸⁶Rb) flux increased with [K] _o ([Rb] _o ). These results show that the apical membrane NaK pumps play an important role in the net active transport of potassium (rubidium) across the epithelium. The [K] _o changes that modulate potassium transport coincide with the light-induced [K] _o changes that occur in the extracellular space separating the photoreceptors and the apical membrane of the pigment epithelium.     

Evidence for interactions between the energy-dependent transport of sugars and the membrane potential in the yeastRhodotorula gracilis (Rhodosporidium toruloides)

Summary A membrane potential (inside negative) across the plasma membrane of the obligatory aerobic yeastRhodotorula gracilis is indicated by the intracellular accumulation of the lipid-soluble cations tetraphenylphosphonium and triphenylmethylphosphonium. The uptake of these ions is inhibited by anaerobic conditions, by uncouplers, by addition of diffusible ions, or by increase of the leakiness of the membrane caused by the polyene antibiotic nystatin. The membrane potential is strongly pH-dependent, its value increasing with decreasing extracellular proton concentration. Addition of transportable monosaccharides causes a depolarization of the electrical potential difference, indicating that the H⁺-sugar cotransport is electrogenic. The effect on the membrane potential is enhanced by increasing the sugar concentration. The half-saturation constants of depolarization ford-xylose andd-galactose were comparable to those of the corresponding transport system for the two sugars. All agents that depressed the membrane potential inhibited monosaccharide transport; hence the membrane potential provides energy for active sugar transport in this strain of yeast.     

The ascorbate-driven reduction of extracellular ascorbate free radical by the erythrocyte is an electrogenic process

Erythrocytes can reduce extracellular ascorbate free radicals by a plasma membrane redox system using intracellular ascorbate as an electron donor. In order to test whether the redox system has electrogenic properties, we studied the effect of ascorbate free radical reduction on the membrane potential of the cells using the fluorescent dye 3,3'-dipropylthiadicarbocyanine iodide. It was found that the erythrocyte membrane depolarized when ascorbate free radicals were reduced. Also, the activity of the redox system proved to be susceptible to changes in the membrane potential. Hyperpolarized cells could reduce ascorbate free radical at a higher rate than depolarized cells. These results show that the ascorbate-driven reduction of extracellular ascorbate free radicals is an electrogenic process, indicating that vectorial electron transport is involved in the reduction of extracellular ascorbate free radical.     

The effect of changing extracellular osmolality on water transport in the human red blood cell as measured by the cell water residence time and the activation energy of water transport

A pulse NMR technique employing low extracellular Mn²⁺ concentrations has been used in following the effect of variations in extracellular osmolality on water transport through the human red blood cell membrane. We report results including the effect of osmolality on the cell water lifetime (τ_a) and, for the first time, the effect on the proton spin-spin relaxation of the intracellular water (T_2a) and the activation energy for the water transport process. Current results are encouraging in correlating the effects seen in this study with suspected membrane functional changes occurring in both in vivo and in vitro aging and during in vitro preservation attempts.     

Role of cytoplasmic inorganic phosphate in light-induced activation of H+-pumps in the plasma membrane and tonoplast of Chara corallina

A unique variant strain of Chara corallina, which contains little inorganic phosphate in the vacuole ([Pi]_v) was isolated. The level of cytoplasmic inorganic phosphate ([Pi]_c) in these cells was the same as that in normal cells. Using these unique cells, we studied the change in [Pi]_c and the effect of Pi on the activities of electrogenic H⁺-pumps associated with the plasma membrane and tonoplast. Upon illumination, the plasma membrane of C. corallina became hyperpolarized by 15 mV, the pH of the vacuolar sap decreased by 0.5 unit, and [Pi]_c decreased by 30% with a similar time course. The activities of the electrogenic H ⁺-pump in the plasma membrane and the ATP and PPi-dependent H⁺-transport in the tonoplast were noncompetitively inhibited by Pi with K_i values of, in the order given, 21.3 mM, 22.1 mM and 37.7 mM. From the kinetics study we calculated that the electrogenic H⁺-pump in the plasma membrane and the ATP and PPi-dependent H⁺ transport in the tonoplast were activated by, again in this order, 13%, 13% and 9%, in accordance with the decrease in [Pi]_c. We propose that the change in [Pi]_c is one of the regulators of photosynthesis-mediated activation of the H⁺-pumps in the plasma membrane and the tonoplast in C. corallina upon illumination.     

Activation of Archaeoglobus fulgidus Cu-ATPase CopA by cysteine

CopA, a thermophilic ATPase from Archaeoglobus fulgidus, drives the outward movement of Cu⁺ across the cell membrane. Millimolar concentration of Cys dramatically increases (≅ 800%) the activity of CopA and other P_IB-type ATPases (Escherichia coli ZntA and Arabidopsis thaliana HMA2). The high affinity of CopA for metal (≅ 1 μM) together with the low Cu⁺-Cys K_D (< 10^− 10M) suggested a multifaceted interaction of Cys with CopA, perhaps acting as a substitute for the Cu⁺ chaperone protein present in vivo. To explain the activation by the amino acid and further understand the mechanism of metal delivery to transport ATPases, Cys effects on the turnover and partial reactions of CopA were studied. 2-20 mM Cys accelerates enzyme turnover with little effect on CopA affinity for Cu⁺, suggesting a metal independent activation. Furthermore, Cys activates the p-nitrophenyl phosphatase activity of CopA, even though this activity is metal independent. Cys accelerates enzyme phosphorylation and the forward dephosphorylation rates yielding higher steady state phosphoenzyme levels. The faster dephosphorylation would explain the higher enzyme turnover in the presence of Cys. The amino acid has no significant effect on low affinity ATP K_m suggesting no changes in the E₁ ↔ E₂ equilibrium. Characterization of Cu⁺ transport into sealed vesicles indicates that Cys acts on the cytoplasmic side of the enzyme. However, the Cys activation of truncated CopA lacking the N-terminal metal binding domain (N-MBD) indicates that activation by Cys is independent of the regulatory N-MBD. These results suggest that Cys is a non-essential activator of CopA, interacting with the cytoplasmic side of the enzyme while this is in an E1 form. Interestingly, these effects also point out that Cu⁺ can reach the cytoplasmic opening of the access path into the transmembrane transport sites either as a free metal or a Cu⁺-Cys complex.     

Effects on transport of rapidly penetrating,competing substrates: Activation and inhibition of the choline carrier in erythrocytes by imidazole

Summary The properties of the choline transport system are fundamentally altered in saline solution containing 5mm imidazole buffer instead of 5mm phosphate: (i) The system no longer exhibits accelerated exchange. (ii) Choline in the external compartment fails to increase the rate of inactivation of the carrier by N-ethylmaleimide. (iii) Depending on the relative concentrations of choline and imidazole, transport may be activated or inhibited. The maximum rates are increased more than fivefold by imidazole, but at moderate substrate concentrations activation is observed with low concentrations of imidazole and inhibition with high concentrations. (iv) The imidazole effect is asymmetric, there being a greater tendency to activate exit than entry. All this behavior is predicted by the carrier model if imidazole is a substrate of the choline carrier having a high maximum transport rate but a relatively low affinity, and if imidazole rapidly enters the cell by simple diffusion, so that it can add to carrier sites on both sides of the membrane. Addition at thecis side inhibits, and at thetrans side activates. According to the carrier model, asymmetry is a necessary consequence of the potassium ion gradient in red cells, potassium ion being another substrate of the choline system.     

Functionally Important Residues in the Predicted 3<Superscript>rd</Superscript> Transmembrane Domain of the Type IIa Sodium-phosphate Cotransporter (NaPi-IIa)

The type IIa Na⁺/P_i, cotransporter (NaPi-IIa) mediates electrogenic transport of three Na⁺ and one divalent P_i ion (and one net positive charge) across the cell membrane. Sequence comparison of electrogenic NaPi-IIa and IIb isoforms with the electroneutral NaPi-IIc isoform pointed to the third transmembrane domain (TMD-3) as a possibly significant determinant of substrate binding. To elucidate the role of TMD-3 in the topology and mechanism underlying NaPi-IIa function we subjected it to cysteine scanning mutagenesis. The constructs were expressed in Xenopus oocytes and P_i transport kinetics were assayed by electrophysiology and radiotracer uptake. Cys substitution resulted in only marginally altered kinetics of P_i transport in those mutants providing sufficient current for analysis. Only one site, at the extracellular end of TMD-3, appeared to be accessible to methanethiosulfonate reagents. However, additional mutations carried out at D224 (replaced by E, G or N) and N227 (replaced by D or Q) resulted in markedly altered voltage and substrate dependencies of the P_i-dependent currents. Replacing Asp-224 (highly conserved in electrogenic a and b isoforms) with Gly (the residue found in the electroneutral c isoform) resulted in a mutant that mediated electroneutral Na⁺-dependent P_i transport. Since electrogenic NaPi-II transports 3 Na⁺/transport cycle, whereas electroneutral NaPi-IIc only transports 2, we speculate that this loss of electrogenicity might result from the loss of one of the three Na⁺ binding sites in NaPi-IIa.     

Discontinuities in the Temperature Function of Transmembrane Water Transport in Chara: Relation to Ion Transport

The NMR (nuclear magnetic resonance) method of Conlon and Outhred (1972) was used to measure diffusional water permeability of the nodal cells of the green alga Chara gymnophylla. Two local minima at 15 and 30°C of diffusional water permeability (P _d ) were observed delimiting a region of low activation energy (E _a around 20 kJ/mol) indicative of an optimal temperature region for membrane transport processes. Above and below this region water transport was of a different type with high E _a (about 70 kJ/mol). The triphasic temperature dependence of the water transport suggested a channel-mediated transport at 15–30°C and lipid matrix-mediated transport beyond this region. The K⁺ channel inhibitor, tetraethylammonium as well as the Cl⁻ channel inhibitor, ethacrynic acid, diminished P _d in the intermediate temperature region by 54 and 40%, respectively. The sulfhydryl agent p-(chloromercuri-benzensulfonate) the water transport inhibitor in erythrocytes also known to affect K⁺ transport in Chara, only increased P _d below 15°C. In high external potassium (`K-state') water transport minima were pronounced. The role of K⁺ channels as sensors of the optimal temperature limits was further emphasized by showing a similar triphasic temperature dependence of the conductance of a single K⁺ channel also known to cotransport water, which originated from cytoplasmic droplets (putatively tonoplast) of C. gymnophylla. The minimum of K⁺ single channel conductance at around 15°C, unlike the one at 30°C, was sensitive to changes of growth temperature underlining membrane lipid involvement. The additional role of intracellular (membrane?) water in the generation of discontinuities in the above thermal functions was suggested by an Arrhenius plot of the cellular water relaxation rate which showed breaks at 13 and 29°C. Received: 12 August 1998/Revised: 13 November 1998     

Effect of sodium on cellular calcium transport in rat kidney

Summary The influence of extracellular Na (Na _o ) on cellular Ca transport and distribution was studied in rat kidney slices. Calcium efflux from prelabeled slices was depressed when Na _o was completely replaced by choline or tetraethylammonium (TEA) ions and it was markedly stimulated when Na was reintroduced in a Na-free medium. However, reducing Na _o (with choline or TEA as substituting ions) did not increase the total slice⁴⁰Ca, their total exchangeable Ca pool, or the⁴⁰Ca or⁴⁵Ca of mitochondria isolated from these slices. Kinetic analyses of steady-state⁴⁵Ca desaturation curves showed that reducing Na _o depressed the exchange of Ca across the plasma membrane, slightly decreased the cytosolic Ca pool, but did not significantly affect the mitochondrial Ca pool and Ca cycling. Ouabain (10^–3 m) which should reduce the Na gradient across the plasma membrane had no effect on calcium distribution and transport. These results suggest that in kidney cells low Na _o depresses Ca influx as well as Ca efflux; there may be an interaction between Na and Ca at a possible carrier located in the plasma membrane, but there is no Na/Ca exchange as described in several excitable tissues.