Determination of proton flux and conductance at pH 6.8 through single FO sectors from Escherichia coli

We have developed a mathematical model in concert with an assay that allows us to calculate proton (H+) flux and conductance through a single FO of the F1FO ATP synthase. Lipid vesicles reconstituted with just a few functional FO from Escherichia coli were loaded with 250 mM K+ and suspended in a low K+ solution. The pH of the weakly buffered external solution was recorded during sequential treatment with the potassium ionophore valinomycin, the protonophore carbonyl cyanide 3-chlorophenylhydrazone, and HCl. From these pH traces and separate determinations of vesicle size and lipid concentration we calculate the proton conductance through a single FO sector. This methodology is sensitive enough to detect small (15%) conductance changes. We find that wild-type FO has a proton flux of 3100 +/- 500 H+/s/FO at a transmembrane potential of 106 mV (25 degrees C and pH 6.8). This corresponds to a proton conductance of 4.4 fS.     

Protein AQ_1862 from the hyperthermophilic bacterium Aquifex aeolicus is a porin and contains two conductance pathways of different selectivity

The "hypothetical protein" AQ_1862 was isolated from the membrane fraction of Aquifex aeolicus and identified as the major porin. In experiments with one conducting unit (molecule) a conductance of 1.4 nS was observed in 0.1 M KCl at pH 7.5. This stable (basic) conductance was superimposed by conductance fluctuations of approximately 0.25 nS. Because both events were always observed simultaneously, it is suggested that they are caused by the same molecular entity. Nonetheless they show very different properties. The basic conductance is anion selective at neutral pH with a conductance sequence Cl- approximately Br- approximately NO3->F->gluconate approximately acetate approximately propionate and does not saturate up to 0.5 M KCl. At alkaline pH and in the presence of large anions, it becomes unselective and the conductance saturates at low concentrations (Km approximately 20 mM). In contrast the fluctuating component is mainly cation selective with a conductance sequence K+ approximately Rb+>NH4+>Na+ approximately Li+ approximately Cs+. It saturates at low salt concentrations (Km approximately 15 mM) and is not affected by pH. In view of the diverging properties of both conductance components, it seems appropriate to assume that AQ_1862 has two different conducting pathways rather than one with two different open states.     

Calcium channel current of vascular smooth muscle cells: extracellular protons modulate gating and single channel conductance

Modulation of L-type Ca2+ channel current by extracellular pH (pHo) was studied in vascular smooth muscle cells from bovine pial and porcine coronary arteries. Relative to pH 7.4, alkaline pH reversibly increased and acidic pH reduced ICa. The efficacy of pHo in modulating ICa was reduced when the concentration of the charge carrier was elevated ([Ca2+]o or [Ba2+]o varied between 2 and 110 mM). Analysis of whole cell and single Ca2+ channel currents suggested that more acidic pHo values shift the voltage-dependent gating (approximately 15 mV per pH- unit) and reduce the single Ca2+ channel conductance gCa due to screening of negative surface charges. pHo effects on gCa depended on the pipette [Ba2+] ([Ba2+]p), pK*, the pH providing 50% of saturating conductance, increased with [Ba2+]p according to pK* = 2.7-2.log ([Ba2+]p) suggesting that protons and Ba2+ ions complete for a binding site that modulates gCa. The above mechanisms are discussed in respect to their importance for Ca2+ influx and vasotonus.     

Disulfide cross-linking of H,K-ATPase opens Cl- conductance, triggering proton uptake in gastric vesicles. Studies with specific inhibitors

An S-S cross-linking reagent, Cu2+-o-phenanthroline, increased the 36Cl-/Cl- exchange rate across the hog gastric vesicle membrane, which contains H,K-ATPase, but did not affect the 86Rb+/Rb+ exchange rate. The results show that closed Cl- conductance can be opened by S-S cross-linking. Gastric vesicles with opened Cl- conductance could take up H+ upon addition of MgATP without prolonged preincubation in a solution containing K+. Preincubation of gastric vesicles with picoprazole, which is a specific inhibitor of H,K-ATPase and binds to 100-kDa polypeptides of the enzyme, dose dependently inhibited opening of the Cl- conductance by Cu2+-o-phenanthroline, indicating that the Cl- conductance is part of the function of the H,K-ATPase. The effect of picoprazole was greater at alkaline pH than at acidic pH. Another H,K-ATPase inhibitor, 2-[2-(3,5-dimethyl-4-methoxy)-pyridylmethylsulfinyl] (5-methoxycarbonyl-6-methyl)-benzimidazole (H compound), had a similar but stronger effect on the Cl- conductance than that of picoprazole. A pungent ingredient of curry, allylisothiocyanate, caused similar pH-dependent inhibition to that of picoprazole. However, another substituted benzimidazole, omeprazole, did not inhibit Cl- conductance. Substituted benzimidazoles, such as picoprazole, H compound, and omeprazole, inhibited the H,K-ATPase activity progressively with a decrease in pH of the medium. This pH dependence was the reverse of that in inhibition of Cl- conductance, suggesting that the inhibitory site of Cl- conductance is different from that of the H,K-ATPase activity and that the conformational states of the two sites change in different ways with change in pH of the medium.     

Noncontact dipole effects on channel permeation. I. Experiments with (5F-indole)Trp13 gramicidin A channels.

Gramicidin A (gA), with four Trp residues per monomer, has an increased conductance compared to its Phe replacement analogs. When the dipole moment of the Trp13 side chain is increased by fluorination at indole position 5 (FgA), the conductance is expected to increase further. gA and FgA conductances to Na+, K+, and H+ were measured in planar diphytanoylphosphatidylcholine (DPhPC) or glycerylmonoolein (GMO) bilayers. In DPhPC bilayers, Na+ and K+ conductances increased upon fluorination, whereas in GMO they decreased. The low ratio in the monoglyceride bilayer was not reversed in GMO-ether bilayers, solvent-inflated or -deflated bilayers, or variable fatty acid chain monoglyceride bilayers. In both GMO and DPhPC bilayers, fluorination decreased conductance to H+ but increased conductance in the mixed solution, 1 M KCl at pH 2.0, where K+ dominates conduction. Eadie-Hofstee plot slopes suggest similar destabilization of K+ binding in both lipids. Channel lifetimes were not affected by fluorination in either lipid. These observations indicate that fluorination does not change the rotameric conformation of the side chain. The expected difference in the rate-limiting step for transport through channels in the two bilayers qualitatively explains all of the above trends.     

Effect of chloride on pH microclimate and electrogenic Na+ absorption across the rumen epithelium of goat and sheep

Active Na+ absorption across rumen epithelium comprises Na+/H+ exchange and a nonselective cation conductance (NSCC). Luminal chloride is able to stimulate Na+ absorption, which has been attributed to an interaction between Cl-/HCO3- and Na+/H+ exchangers. However, isolated rumen epithelial cells also express a Cl- conductance. We investigated whether Cl- has an additional effect on electrogenic Na+ absorption via NSCC. NSCC was estimated from short-circuit current (Isc) across epithelia of goat and sheep rumen in Ussing chambers. Epithelial surface pH (pHs) was measured with 5-N-hexadecanoyl-aminofluorescence. Membrane potentials were measured with microelelectrodes. Luminal, but not serosal, Cl- stimulated the Ca2+ and Mg2+ sensitive Isc. This effect was independent of the replacing anion (gluconate or acetate) and of the presence of bicarbonate. The mean pHs of rumen epithelium amounted to 7.47 +/- 0.03 in a low-Cl- solution. It was increased by 0.21 pH units when luminal Cl- was increased from 10 to 68 mM. Increasing mucosal pH from 7.5 to 8.0 also increased the Ca2+ and Mg2+ sensitive Isc and transepithelial conductance and reduced the fractional resistance of the apical membrane. Luminal Cl- depolarized the apical membrane of rumen epithelium. 5-Nitro-2-(3-phenylpropylamino)-benzoate reduced the divalent cation sensitive Isc, but only in low-Cl- solutions. The results show that luminal Cl- can increase the microclimate pH via apical Cl-/HCO3- or Cl-/OH- exchangers. Electrogenic Na+ absorption via NSCC increases with pH, explaining part of the Cl- effects on Na+ absorption. The data further show that the Cl- conductance of rumen epithelium must be located at the basolateral membrane.     

Intracellular pH changes induced by calcium influx during electrical activity in molluscan neurons

Simultaneous measurements of electrical activity and light absorbance have been made on nerve cell bodies from Archidoris monteryensis injected with indicator dyes. pH indicators, phenol red and bromocresol purple, and arsenazo III, which under normal conditions is primarily a calcium indicator have been employed. Voltage clamp pulses which induced calcium influx caused an absorbance decrease of the pH dyes indicating an internal acidification. The onset of the pH drop lagged the onset of Ca2+ influx by 200-400 ms, and pH continued to decrease for several seconds after pulse termination which shut off Ca2+ influx. Trains of action potentials also produced an internal pH decrease. Recovery of the pH change required periods greater than 10 min. The magnitude of the pH change was largely unaffected by external pH in the range 6.8-8.4. The voltage dependence of the internal p/ change was similar to the voltage dependence of calcium influx determined by arsenazo III, and removal of calcium from the bathing saline eliminated the pH signal. In neurons injected with EGTA (1-5 mM), the activity- induced internal Ca2+ changes were reduced or eliminated, but the internal pH drop was increased severalfold in magnitude. After the injection of EGTA, voltage clamp pulses produced a decrease in arsenazo III absorbance instead of the normal increase. Under these conditions the dye was responding primarily to changes in internal pH. Injection of H+ caused a rise in internal free calcium. The pH buffering capacity of the neurons was measured using three different techniques: H+ injection, depressing intrinsic pH changes with a pH buffer, and a method employing the EGTA-calcium reaction. The first two methods gave similar measurements: 4-9 meq/unit pH per liter for pleural ganglion cells and 13-26 meq/unit pH per liter for pedal ganglion cells. The EGTA method gave significantly higher values (20-60 meq/unit pH per liter) and showed no difference between pleural and pedal neurons.     

Use of weak acids to determine the bulk diffusion limitation of H+ ion conductance through the gramicidin channel.

The addition of 2 M formic acid at pH 3.75 increased the single channel H+ ion conductance of gramicidin channels 12-fold at 200 mV. Other weak acids (acetic, lactic, oxalic) produce a similar, but smaller increase. Formic acid (and other weak acids) also blocks the K+ conductance at pH 3.75, but not at pH 6.0 when the anion form predominates. This increased H+ conductance and K+ block can be explained by formic acid (HF) binding to the mouth of the gramicidin channel (Km = 1 M) and providing a source of H+ ions. A kinetic model is derived, based on the equilibrium binding of formic acid to the channel mouth, that quantitatively predicts the conductance for different mixtures of H+, K+, and formic acid. The binding of the neutral formic acid to the mouth of the gramicidin channel is directly supported by the observation that a neutral molecule with a similar structure, formamide (and malonamide and acrylamide), blocks the K+ conductance at pH 6.0. The H+ conductance in the presence of formic acid provides a lower bound for the intrinsic conductance of the gramicidin channel when there is no diffusion limitation at the channel mouth. The 12-fold increase in conductance produced by formic acid suggests that greater than 90% of the total resistance to H+ results from diffusion limitation in the bulk solution.     

Common channels for water and protons at apical and basolateral cell membranes of frog skin and urinary bladder epithelia. Effects of oxytocin, heavy metals, and inhibitors of H(+)-adenosine triphosphatase

We have compared the response of proton and water transport to oxytocin treatment in isolated frog skin and urinary bladder epithelia to provide further insights into the nature of water flow and H+ flux across individual apical and basolateral cell membranes. In isolated spontaneous sodium-transporting frog skin epithelia, lowering the pH of the apical solution from 7.4 to 6.4, 5.5, or 4.5 produced a fall in pHi in principal cells which was completely blocked by amiloride (50 microM), indicating that apical Na+ channels are permeable to protons. When sodium transport was blocked by amiloride, the H+ permeability of the apical membranes of principal cells was negligible but increased dramatically after treatment with antidiuretic hormone (ADH). In the latter condition, lowering the pH of the apical solution caused a voltage-dependent intracellular acidification, accompanied by membrane depolarization, and an increase in membrane conductance and transepithelial current. These effects were inhibited by adding Hg2+ (100 microM) or dicyclohexylcarbodiimide (DCCD, 10(-5) M) to the apical bath. Net titratable H+ flux across frog skin was increased from 30 +/- 8 to 115 +/- 18 neq.h-1.cm-2 (n = 8) after oxytocin treatment (at apical pH 5.5 and serosal pH 7.4) and was completely inhibited by DCCD (10(-5) M). The basolateral membranes of the principal cells in frog skin epithelium were found to be spontaneously permeable to H+ and passive electrogenic H+ transport across this membrane was not affected by oxytocin. Lowering the pH of the basolateral bathing solution (pHb) produced an intracellular acidification and membrane depolarization (and an increase in conductance when the normal dominant K+ conductance of this membrane was abolished by Ba2+ 1 mM). These effects of low pHb were blocked by micromolar concentrations of heavy metals (Zn2+, Ni2+, Co2+, Cd2+, and Hg2+). Lowering pHb in the presence of oxytocin (50 mU/ml) produced a transepithelial current (3 microA.cm-2 at pHb 5.5) which was blocked by 100 microM of Hg2+, Zn2+, or Ni2+ at the basolateral side, and by DCCD (10(-5) M) or Hg2+ (100 microM) from the apical side. The net hydroosmotic water flux (JH2O) induced by oxytocin in frog bladder sacs was blocked by inhibitors of H(+)-adenosine triphosphatase (ATPase). Diethylstilbestrol (DES 10(-5) M), oligomycin (10(-8) M), and DCCD (10(-5) M) prevented JH2O when present in the lumen. These effects cannot be attributed to inhibition of metabolism since cyanide (10(-4) M), or 2-deoxyglucose (10(-3) M) had no effect on JH2O.(ABSTRACT TRUNCATED AT 400 WORDS)     

The mammalian Na+/H+ antiporters NHE-1, NHE-2, and NHE-3 are electroneutral and voltage independent,but can couple to an H+ conductance

Na+/H+ exchange in vertebrates is thought to be electroneutral and insensitive to the membrane voltage. This basic concept has been challenged by recent reports of antiport-associated currents in the turtle colon epithelium (Post and Dawson, 1992, 1994). To determine the electrogenicity of mammalian antiporters, we used the whole-cell patch clamp technique combined with microfluorimetric measurements of intracellular pH (pHi). In murine macrophages, which were found by RT- PCR to express the NHE-1 isoform of the antiporter, reverse (intracellular Na(+)-driven) Na+/H+ exchange caused a cytosolic acidification and activated an outward current, whereas forward (extracellular Na(+)-driven) exchange produced a cytosolic alkalinization and reduced a basal outward current. The currents mirrored the changes in pHi, were strictly dependent on the presence of a Na+ gradient and were reversibly blocked by amiloride. However, the currents were seemingly not carried by the Na+/H+ exchanger itself, but were instead due to a shift in the voltage dependence of a preexisting H+ conductance. This was supported by measurements of the reversal potential (Erev) of tail currents, which identified H+ (equivalents) as the charge carrier. During Na+/H+ exchange, Erev changed along with the measured changes in pHi (by 60-69 mV/pH). Moreover, the current and Na+/H+ exchange could be dissociated. Zn2+, which inhibits the H+ conductance, reversibly blocked the currents without altering Na+/H+ exchange. In Chinese hamster ovary (CHO) cells, which lack the H+ conductance, Na+/H+ exchange produced pHi changes that were not accompanied by transmembrane currents. Similar results were obtained in CHO cells transfected with either the NHE-1, NHE-2, or NHE-3 isoforms of the antiporter, indicating that exchange through these isoforms is electroneutral. In all the isoforms tested, the amplitude and time- course of the antiport-induced pHi changes were independent of the holding voltage. We conclude that mammalian NHE-1, NHE-2, and NHE-3 are electroneutral and voltage independent. In cells endowed with a pH- sensitive H+ conductance, such as macrophages, activation of Na(+)-H+ exchange can modulate a transmembrane H+ current. The currents reported in turtle colon might be due to a similar "cross-talk" between the antiporter and a H+ conductance.     

Electrically silent anion transport through lipid bilayer membranes containing a long-chain secondary amine

The permeability properties of planar lipid bilayers made from egg lecithin, n-decane and a long-chain secondary amine (n-lauryl [trialkylmethyl]amine) are described. Membranes containing the secondary amine show halide selectivity and high conductance at pH less than 6, as estimated by measurements of zero-current potentials generated by NaBr activity gradients. In the absence of halide ions, the membranes show H+ selectivity, although the total membrane conductance is relatively low. In 0.1 M NaBr both the membrane conductance (Gm) and the Br- self-exchange flux (JBr) are proportional to H+ concentration over the pH range of 7 to 4, and both JBr and Gm saturate at pH less than 4. However, JBr is always more than 100 times the flux predicted from Gm and the transference number for Br-. Thus, greater than 99% of the observed (tracer) flux is electrically silent and is not a Br2 or HBrO flux because the reducing agent, S2O3=, has no effect on JBr. At pH 7, JBr is proportional to Br- concentration over the range of 1-340 mM, with no sign of saturation kinetics. Both urea and sulfate tracer permeabilities are low and are unaffected by pH. The results can be explained by a model in which the secondary amine behaves as a monovalent, titratable carrier which exists in three chemical forms (C, CH+, and CHBr). Br- crosses the membrane primarily as the neurtal complex (CHBr). The positively charged carrier (CH+) crosses the membrane slowly compared to CHBr, but CH+ is the principal charge carrier in the membrane. At neurtal pH greater than 99% of the amine is in the nonfunctional form (C), which can be converted to CH+ or CHBr by increasing the H+ or Br- concentrations. The permeability properties of these lipid bilayers resemble in many respects the permeability properties of red cell membranes.     

Determinants of the phagosomal pH in macrophages. In situ assessment of vacuolar H(+)-ATPase activity, counterion conductance, and H+ "leak".

We studied the factors that determine the intraphagosomal pH (pHp) in elicited murine peritoneal macrophages. pHp was measured in situ by recording the fluorescence of covalently fluoresceinated Staphylococcus aureus ingested by the macrophages. Following spontaneous acidification of the phagosomes, passive (leak) H+ permeability was determined measuring the rate of change of pHp upon complete inhibition of the H+ pump with bafilomycin A1. A significant, but comparatively low passive H+ permeability was detected. The existence of a passive H+ leak implies that continuous energy expenditure is required for the maintenance of an acidic pHp. In combination with ionophores, bafilomycin was also used to estimate the counterion permeability. The counterion conductance was found to be severalfold higher than the H+ leak. Ion substitution experiments in electropermeabilized cells and the inhibitory effects of quinine and 5-nitro-2-(3-phenylpropylamino)benzoic acid suggest that both monovalent anions and cations permeate the phagosomal membrane. The activity of the H+ pump was measured at various pHp levels. In the steady state, the rate of H+ pumping was considerably lower than counterion permeation. These findings suggest that the phagosomal membrane potential is insignificant. Consistent with this notion, increasing phagosomal conductance with ionophores failed to accelerate the rate of H+ pumping. Thus, the transmembrane delta pH is the predominant component of the proton-motive force across the phagosomal membrane in the steady state. The rate of H+ pumping was found to decrease steeply as the phagosomal lumen became acidified. Therefore, the pH sensitivity of the H+ pump, which possibly reflects a kinetic or allosteric effect, is the primary determinant of pHp.     

The Ca2+-sensitive K+-conductance of the human red cell membrane is strongly dependent on cellular pH

The conductance of the Ca2+-sensitive K+-channels in human red cell membranes has been determined as a function of the intracellular pH. A sudden increase in the intracellular concentration of ionized calcium was established by addition of ionophore A23187 to a suspension of cells in buffer-free, Ca2+-containing salt solution. At the various cellular pH-values cellular concentrations of ionized Ca, saturating with respect to activation of the Ca2+-sensitive K+-conductance, were obtained by the use of varied concentrations of extracellular Ca2+ and added ionophore A23187. Changes in membrane potential was monitored as CCCP-mediated changes in extracellular pH. Initial net effluxes of K+, cellular K+ contents and the K+ Nernst equilibrium potentials were calculated from flame photometric measurements. Cellular Ca-contents were determined by aid of 45Ca. With cellular Ca2+ at the saturating level with respect to activation of the K+-channel the K+-conductance calculated from these data was independent of extracellular pH and a steep function of cellular pH with a half maximal conductance of 31 microSeconds/cm2 at a cellular pH of 6.1. The K+-conductance is not a simple function of cellular pH (pHc). From pHc = 6.5 and down to pHc = 6.0 a Hill-coefficient of 2.5 was found, indicating cooperativity between at least two sites regulating the conductance. Below pHc = 6.0 an extremely high Hill-coefficient of 11 was found, probably indicating that the additional titration of the channel protein leads to an increased cooperativity. The importance, as a physiological regulatory mechanism, of a K+-conductance increasing from zero to maximal conductance within less than one unit of pH, is discussed.     

The lysosomal H+ pump: 8-azido-ATP inhibition and the role of chloride in H+ transport

Lysosomes (tritosomes) were purified from the livers of rats injected with Triton WR 1339. The lysosomes developed an Mg2+-ATP-dependent pH gradient as measured by Acridine orange accumulation. H+ transport was supported by chloride, but not sulfate, and was independent of the cation used. H+ transport and Mg2+-stimulated ATPase was inhibited by diethylstilbesterol (K0.5 = 2 microM). N-Ethylmaleimide inhibited H+ transport (K0.5 = 30 microM). At low concentrations of N-ethylmaleimide, ATP partially protected H+ transport from inhibition with N-ethylmaleimide. Photolysis with 8-azido-ATP inhibited H+ transport and Mg2+-stimulated ATPase activity. Under these same conditions, 8-azido-[alpha-32P]ATP reacted with a number of polypeptides of the intact lysosome and lysosomal membranes. Pump-dependent potentials were measured using the fluorescent potential-sensitive dye, DiSC3(5) (3,3'-dipropylthiocarbocyanine) and ATP-dependent potential generation was inhibited by diethylstilbesterol. Chloride, but not sulfate reduced the magnitude of the ATP-dependent membrane potential, as measured using merocyanine 540. The chloride conductance, independent of ATP, was of sufficient magnitude to generate a H+ gradient driven by external chloride in the presence of tetrachlorosalicylanilide. In Cl- free media, ATP-dependent H+ transport was restored to control levels by outwardly directed K+ gradients in the presence of valinomycin. The role of cell Cl- is to provide the necessary conductance for supporting lysosomal acidification by the electrogenic proton pump.     

The effective proton conductance of the inner membrane of mitochondria from brown adipose tissue. Dependency on proton electrochemical potential gradient.

The nucleotide-sensitive H+ (OH-) conducting pathway of mitochondria from the brown-adipose tissue of cold-adapted guinea-pigs passes an effective proton current which is directly proportional to the proton electrochemical gradient. At 23 degrees C and pH 7.0 this conductance is 16 nmol H+ - min-1 - mg-1 - mV-1. Addition of 0.2 mM GDP results in a conductance which is linear and low (0.7 nmol H+ - min-1 - mg-1 - mV-1) until deltamicronH+ exceeds 220 mV. At higher values of deltamicronH+, which can be attained by glycerol 3-phosphate oxidation but not palmitoyl-L-carnitine plus malate oxidation, the membrane conductance greatly increases, effectively limiting the maximal deltamicronH+ to 240 mV. High glycerol 3-phosphate concentrations which have the thermodynamic potential to exceed this value of deltamicronH+ instead create a greatly increased rate of controlled respiration. The generality and significance of this device to limit deltamicronH+, and its relation to the nucleotide-sensitive conductance, are discussed.     

Studies of insulin action on the amphibian oocyte plasma membrane using NMR, electrophysiological and ion flux techniques

Insulin (0.1-10 microM) reinitiates the meiotic divisions in Rana oocytes and produces a 14-20 mV negative-going hyperpolarization of the plasma membrane as well as a 0.25 unit increase in intracellular pH during the first 90 min. During hyperpolarization, the Na+ conductance of the membrane decreases by 40-50% with a concomitant increase in 22Na+ uptake from the medium. The increased uptake of Na+ during a period of decreasing Na+ conductance is apparently due to an increase in fluid phase turnover associated with insulin-mediated endocytosis. Both membrane hyperpolarization and increase in pHi are Na+-dependent and are blocked by the serine proteinase inhibitor, phenylmethylsulfonyl fluoride. The membrane potential of the prophase oocyte has a significant electrogenic component with potential but not conductance sensitive to glycosides and substitution of Li+ for Na+. Insulin hyperpolarizes Li+ or glycoside-treated oocytes whereas glycosides do not affect insulin-hyperpolarized oocytes. [3H]Ouabain binding by the plasma membrane of the untreated oocyte shows at least two K+-sensitive components (Kd = 42 and 2000 nM) linked to inhibition of the Na+ pump. Insulin-treated oocytes show a single class of intermediate-affinity ouabain sites (Kd = 490 nM) which appear to result from insulin-induced internalization of membrane-bound ouabain. [125I]Insulin binding to the plasma membrane shows a class of high-affinity sites (Kd = 87 nM) with 40-50 pump sites per insulin-binding site. Our results suggest that insulin-induced mediator peptides stimulate Na+-H+ exchange resulting in an increase in intracellular pH and Na+ uptake concomitant with an increase in receptor-mediated endocytosis and a decrease in Na+ conductance and associated membrane hyperpolarization. The net result appears to be a down-regulation of the Na+ pump which together with a decrease in Na+ conductance may divert high-energy phosphate compounds from cation regulation to anabolic processes of meiosis.     

The calcium conductance of the inner membrane of rat liver mitochondria and the determination of the calcium electrochemical gradient.

1. A method is described for establishing steady-state conditions of calcium transport across the inner membrane of rat liver mitochondria and for determining the current of Ca2+ flowing across the membrane, together with the Ca2+ electrochemical gradient across the native Ca2+ carrier. These parameters were used to quantify the apparent Ca2+ conductance of the native carrier. 2. At 23 degrees C and pH7.0, the apparent Ca2+ conductance of the carrier is close to 1 nmol of Ca2+-min-1-mg of protein-1 mV-1. Proton extrusion by the respiratory chain, rather than the Ca2+ carrier itself, may often be rate-limiting in studies of initial rates of Ca2+ uptake. 3. Under parallel conditions, the endogenous H+ conductance of the membrane is 0.3 nmol of H+-min-1-mg of protein-1-mV-1. 4. Ruthenium Red and La3+ both strongly inhibit the Ca2+ conductance of the carrier, but are without effect on the H+ conductance of the membrane. 5. The apparent Ca2+ conductance of the carrier shows a sigmoidal dependence on the activity of Ca2+ in the medium. At 23 degrees C and pH7.2, half-maximum conductance is obtained at a Ca2+ activity of 4.7 muM. 6. The apparent Ca2+ conductance and the H+ conductance of the inner membrane increase fourfold from 23 degrees to 38 degrees C. The apparent Arrhenius activation energy for Ca2+ transport is 69kJ/mol. The H+ electrochemical gradient maintained in the absence of Ca2+ transport does not vary significantly with temperature. 7. The apparent Ca2+ conductance increases fivefold on increasing the pH of the medium from 6.8 to 8.0. The H+ conductance of the membrane does not vary significantly with pH over this range. 8. Mg2+ has no effect on the apparent Ca2+ conductance when added at concentration up to 1 mM. 9. Results are compared with classical methods of studying Ca2+ transport across the mitochondrial inner membrane.     

Regulation of the conductance and resting potential by extracellular K+ in frog taste receptor cells

The effect of extracellular K+ on membrane currents was investigated by the patch clamp and fast perfusion techniques in frog (Rana temporaria) taste receptor cells (TRCs). When added to the bath, K+ increased the TRC conductance. The integral current and current fluctuations depended on the K+ concentration (2.5-90 mM) in the manner which suggested extracellular K+ to serve as a ligand activating ionic channels (potassium-activated (PA) channels). The influence of different ions on the PA current reversal potential indicated that the responsible channels are mainly permeable to K+ and H+. Relative permeabilities were estimated as P(H):P(K) = 3600:1. With 110 mM KCl in the patch pipette and 110 mM NaCl in the bath, isolated TRCs exhibited the resting potentials from -75 to -65 mV. When raised from 2.5 to 110 mM, extracellular K+ intensively depolarized TRCs. Membrane potential vs. K+ concentration displayed a slope of about 41 mV per logarithmic unit. This indicates that the K+ permeability of the TRC membrane dominates the other in setting the potential. With 10 mM K+ in the bath, the PA channels were the major contributor to setting the TRC resting potential. External K+ markedly increased the sensitivity of isolated TRCs to bath solution pH due to the activation of the PA channels suggesting their role in sour transduction.     

Heterologous expression of the glutamine transporter SNAT3 in Xenopus oocytes is associated with four modes of uncoupled transport

The glutamine transporter SNAT3 (SLC38A3, former SN1) plays a major role in glutamine release from brain astrocytes and in glutamine uptake into hepatocytes and kidney epithelial cells. Here we expressed rat SNAT3 in oocytes of Xenopus laevis and reinvestigated its transport modes using two-electrode voltage clamp and pH-sensitive microelectrodes. In addition to the established coupled Na+-glutamine-cotransport/H+ antiport, we found that there are three conductances associated with SNAT3, two dependent and one independent of the amino acid substrate. The glutamine-dependent conductance is carried by cations at pH 7.4, whereas at pH 8.4 the inward currents are still dependent on the presence of external Na+ but are carried by H+. Mutation of threonine 380 to alanine abolishes the cation conductance but leaves the proton conductance intact. Under Na+-free conditions, where the substrate-dependent conductance is suppressed, a substrate-independent, outwardly rectifying current becomes apparent at pH 8.4 that is carried by K+ and H+. In addition, we identified a glutamine-dependent uncoupled Na+/H+ exchange activity that becomes apparent upon removal of Na+ in the presence of glutamine. In conclusion, our results suggest that, in addition to coupled transport, SNAT3 mediates four modes of uncoupled ion movement across the membrane.     

Escherichia coli membrane proton conductance and proton efflux depend on growth pH and are sensitive to osmotic stress

The dependence of Escherichia coli membrane H+ conductance (Gm H+) with a steady-state pH in the presence and absence of an external source of energy (glucose) was studied, when cells were grown under anaerobic and aerobic conditions, with an assay pH of 7.0. Energy-dependent H+ efflux by intact cells growing at pH of 4.5-7.5 was also measured. The elevated H+ conductance and lowered H+ flux were shown for cells growing in acidic pH and under anaerobic conditions, when bacteria were fermenting glucose. The atp mutant, which is deprived of the F0F1- adenosine triphosphatase, had less Gm H+ independent of growth conditions. In contrast with wild-type or precursor strain, a remarkable difference in Gm H+ for atp mutant was observed between aerobic and anaerobic conditions; such a difference was significant at pH 4.5. These results could indicate distinguishing pathways determining Gm H+ under anaerobic conditions after the fermentation of glucose at different pH and an input of the F0F1-adenosine triphosphatase in Gm H+. In addition, the effect of osmotic stress was demonstrated with grown cells. Gm H+ and H+ efflux both were increased after hyperosmotic stress at pH 7.5, and these changes were inhibited by N,N\'-dicyclohexylcarbodiimide, whereas these changes were lower in atp mutant. A role of the F0F1-adenosine triphosphatase in osmo-sensitivity of bacteria was confirmed under fermentative conditions.