Mechanism of ion transport through lipid bilayer-membranes mediated by peptide cyclo-(d-Val-l-Pro-l-Val-d-Pro)3

The cyclic dodecapeptide PV, cyclo-(d-Val-l-Pro-l-Val-d-Pro)₃, a structural analogue of the ion-carier valinomycin, increase the cation permeability of lipid bilayer membranes. This paper reports the results of two types of relaxation experiments, namely relaxation of the membrane current after a voltage jump and decay of the membrane voltage after a charge pulse in lipid bilayer membranes exposed to PV. From the relaxation data, the rate constant for the translocation of the ion carrier complex across the membrane, as well as the partition coefficient of the complex between water and membrane solution interface were computed and found to be about one order of magnitude less than the comparable values for valinomycin (Val). Furthermore, the dependence of the initial membrane conductivity on ion concentration was used to evaluate the equilibrium constant, K, of complexation between PV and some monovalent cations in water. The values of K yield the following selectivity sequence of PV: Na⁺ < NH₄⁺ < K⁺ < Cs⁺ < Rb⁺. These and earlier results are consistent with the idea that PV promotes cation movement across membranes by the solution complexation mechanism which involves complexation between ion and carrier in the aqueous phase and transport of the carrier across the membrane. In the particular form of the solution complexation mechanism operating here, the PV present in the PV-cation complex carrying charge across the membrane derives from the side from which the current is flowing (cis-mechanism). As shown previously, valinomycin, in contrast to PV, acts by an interfacial complexation mechanism in which the Val in the Val-cation complex derives from the side toward which current is flowing (trans-mechanims). The comparison of the kinetic properties of these two closely related compounds yields interesting insights into the relationship between chemical structure and function of ion carriers.     

Electrical responses of the marine ciliate Euplotes vannus (Hypotrichia) to mechanical stimulation at the posterior cell end

Electrical responses upon mechanostimulation at the posterior cell end were investigated in the marine hypotrichous ciliate Euplotes vannus. A new mechanostimulator was developed to mimic stimuli that are identical with those involved in cell-cell collisions. The receptor potential hyperpolarized by 18–35 mV within 12–25 msec, reached a peak value of -62 mV with a delay of 4–9 msec after membrane deformation, and was deactivated after 50–70 msec. Cirri were stimulated to beat accelerated backward. The corresponding receptor current exerted a similar time course with a peak of 2.4 nA. The shift of the reversal potential by 57.6 mV at a tenfold increase of [K⁺] ₀ identifies potassium ions as current carriers within the development of the receptor potential. An intracellular K concentration of 355 mmol/liter was calculated for cells in a medium that was composed similar to sea-water. The mechanically activated potassium current was totally inhibited by extracellular TEA and intracellular Cs⁺, and partially inhibited by extracellular 4-AP. The total inhibition of the current by injected EGTA points to a Ca dependence of the posterior mechanosensitivity. It was confirmed by the increase of the peak current amplitude with rising [Ca²⁺] ₀ . Sodium presumably repolarizes the receptor potential because the repolarization was delayed and after-depolarizations were eliminated in media without sodium. Since deciliation did not affect mechano-sensitivity, the corresponding ion channels reside within the soma membrane.The authors wish to thank Mr. Norbert Spreckelmeier from the electronics workshop and Mr. Herbert Lutter from the fine-mechanical workshop of the department for their excellent work, Mrs. G. Key and Mr. H. Mikoleit for skillful technical assistance and for preparing the figures. This work was supported by Deutsche Forschungsgemeinschaft, SFB 171, C7.     

pHi regulation in Ehrlich mouse ascites tumor cells: Role of sodium-dependent and sodium-independent chloride-bicarbonate exchange

pH _i recovery in acid-loaded Ehrlich ascites tumor cells and pH _i maintenance at steady-state were studied using the fluorescent probe BCECF.Both in nominally HCO ₃ ^– -free media and at 25 mm HCO ₃ ^– , the measured pH _i (7.26 and 7.82, respectively) was significantly more alkaline than the pH _i . value calculated assuming the transmembrane HCO ₃ ^– gradient to be equal to the Cl^– gradient. Thus, pH _i in these cells is not determined by the Cl^– gradient and by Cl^–/HCO ₃ ^– exchange.pH _i recovery following acid loading by propionate exposure, NH ₄ ⁺ withdrawal, or CO₂ exposure is mediated by amiloride-sensitive Na⁺/H⁺ exchange in HCO₃ ^– free media, and in the presence of HCO ₃ ^– (25 mm) by DIDS-sensitive, Na⁺-dependent Cl^–/HCO ₃ ^– exchange. A significant residual pH _i recovery in the presence of both amiloride and DIDS suggests an additional role for a primary active H⁺ pump in pH _i regulation. pH _i maintenance at steady-state involves both Na⁺/H⁺ exchange and Na⁺-dependent Cl^–/HCO ₃ ^– exchange.Acute removal of external Cl^– induces a DIDS-sensitive, Na⁺-dependent alkalinization, taken to represent HCO ₃ ^– influx in exchange for cellular Cl^–. Measurements of ³⁶Cl^– efflux into Cl^–-free gluconate media with and without Na⁺ and/or HCO ₃ ^– (10 mm) directly demonstrate a DIDS-sensitive, Na⁺ dependent Cl^–/HCO ₃ ^– exchange operating at slightly acidic pH _i (pH_o 6.8), and a DIDS-sensitive, Na⁺-independent Cl^–/HCO ₃ ^– exchange operating at alkaline pH _i (pH _o 8.2).The excellent technical assistance of Marianne Schiødt and Birgit B. Jørgensen is gratefully acknowledged. The work was supported by the Carlsberg Foundation (B.K.) and by a grant from the Danish Natural Science Foundation (E.K.H. and L.O.S.).     

Three-year field response of young olive trees (Olea europaea L., cv. Arbequina) to soil salinity: Trunk growth and leaf ion accumulation

Irrigated olive is rapidly increasing in arid and semiarid areas, many of which may be negatively affected by soil salinity. We evaluated changes in trunk growth and leaf Cl^–, Na⁺ and K⁺ concentrations in young Arbequina olives (Olea europaea L.) grown in a saline-sodic field over a three-year period. The trunk diameter was measured at the beginning and the end of the 1999 (70 trees), 2000 (59 trees) and 2001 (42 trees) growing periods. Leaves, sampled in August of each year, were analyzed for Cl^–, Na⁺ and K⁺ concentrations. Soil salinity (apparent electrical conductivity, ECa) of each monitored tree was measured 14 times during the 1999–2001 experimental period with an electromagnetic sensor and converted to root zone electrical conductivity of the soil saturation extract (ECe) based on ECa–ECe calibration curves. Salinity tolerance was determined using the Maas and Hoffman threshold–slope response model. Based on salinity thresholds (ECe_thr), the tolerance of olive in terms of trunk growth was high in 1999 (ECe_thr = 6.7 dS m^–1), but declined with age and time of exposure to salts by 30% in 2000 (ECe_thr = 4.7 dS m^–1) and by 55% in 2001 (ECe_thr = 3.0 dS m^–1). Based on the high absolute slopes obtained in all years (values between 16% and 23% dS^–1 m), olive was classified as very sensitive to ECe values above the threshold. Trunk growth thresholds based on leaf ion concentrations varied, depending on years, between 2.6 and 4.0 mg g^–1 (Cl_thr) and between 1.0 and 1.2 mg g^–1 (Na_thr), indicating that Arbequina olive was less sensitive to leaf Cl^– and much more sensitive to leaf Na⁺ than values reported as toxic in greenhouse studies. Leaf K⁺ slightly decreased with increasing salinity, whereas the K⁺/Na⁺ ratio sharply decreased with increasing salinity. We concluded that the initial salinity tolerance of olive was high, but declined sharply with time of exposure to salts and became quite sensitive due primarily to increasing toxic concentrations of Na⁺ in the leaves.     

Some effects of trinitrocresolate and valinomycin on Na and K transport across thin lipid bilayer membranes: A steady-state analysis with simultaneous tracer and electrical measurements

Summary This paper describes the effect of trinitrocresolate anions (TNC^–) on the electrical conductance (G _m ), and tracer-measured unidirectional Na and K fluxes (M _Na andM _K) across bilayers formed from sheep red cell lipids dissolved in decane. In the absence of TNC^–, typical low conductances were observed, while the cation fluxes were too low to measure by our techniques (<10^–12 moles cm^–2 sec^–1). In the presence of TNC^– (10^–2 m),G _m increased and TNC^– was the main charge carrier in the system. The cationic fluxes were also much increased, but the membranes showed no significant selectivity between K and Na. Furthermore, the Na and K fluxes were at least two orders of magnitude larger than the ionic fluxes calculated fromG _m . Thus, almost all of the K and Na transport across the membrane in the presence of TNC^– is electrically silent and is probably carried out as KTNC and NaTNC ion pairs.In the presence of valinomycin (10^–6 m) and no TNC^–, both the ion fluxes andG _m were 10³ times larger in KCl than in NaCl, thus exhibiting the characteristic high selectivity of valinomycin for K over Na. In the presence of both valinomycin (10^–6 m) and TNC^– (10^–2 m), this selectivity disappeared in that bothG _m andM _Na in the NaCl system were similar to the respective values in the KCl system. Even under these conditions, most of the Na is still transported by a process which does not carry charge.BothG _m andM _x increased alike and monotonically with increasing temperature over the range 7 to 30°C. In the absence of TNC^– the enthalpies of activation were invariably higher in KCl than in NaCl. Addition of TNC^– produced equal enthalpies of activation for both Na and K containing systems suggesting a common, temperature-dependent, ratedetermining step in charge transfer and the electrically silent cation fluxes.     

Charybdotoxin blocks with high affinity the Ca-activated K+ channel of Hb A and Hb S red cells: Individual differences in the number of channels

Summary We have investigated the effect of a purified preparation of Charybdotoxin (CTX) on the Ca-activated K⁺ (Ca–K) channel of human red cells (RBC). Cytosolic Ca²⁺ was increased either by ATP depletion or by the Ca ionophore A23187 and incubation in Na⁺ media containing CaCl₂. The Ca–K efflux activated by metabolic depletion was partially (77%) inhibited from 15.8±2.4 mmol/liter cell · hr, to 3.7±1.0 mmol/liter cell · hr by 6nm CTX (n=3). The kinetic of Ca–K efflux was studied by increasing cell ionized Ca²⁺ using A23187 (60 mol/liter cell), and buffering with EGTA or citrate; initial rates of net K⁺ efflux (90 mmol/liter cell K⁺) into Na⁺ medium containing glucose, ouabain, bumetanide at pH 7.4 were measured. Ca–K efflux increased in a sigmoidal fashion (n of Hill 1.8) when Ca²⁺ was raised, with aK _m of 0.37 m and saturating between 2 and 10 m Ca²⁺. Ca–K efflux was partially blocked (71±7.8%, mean ±sd,n=17) by CTX with high affinity (IC₅₀0.8nm), a finding suggesting that is a high affinity ligand of Ca–K channels. CTX also blocked 72% of the Ca-activated K⁺ efflux into 75mm K⁺ medium, which counteracted membrane hyperpolarization, cell acidification and cell shrinkage produced by opening of the K⁺ channel in Na⁺ media. CTX did not block Valinomycin-activated K⁺ efflux into Na⁺ or K⁺ medium and therefore it does not inhibit K⁺ movement coupled to anion conductive permeability.TheV _max, but not theK _m–Ca of Ca–K efflux showed large individual differences varying between 4.8 and 15.8 mmol/liter cell · min (FU). In red cells with Hb A,V _max was 9.36±3.0 FU (mean ±sd,n=17). TheV _max of the CTX-sensitive, Ca–K efflux was 6.27±2.5 FU (range 3.4 to 16.4 FU) in Hb A red cells and it was not significantly different in Hb S (6.75±3.2 FU,n=8). Since there is larger fraction of reticulocytes in Hb S red cells, this finding indicates that cell age might not be an important determinant of theV _max of Ca–K⁺ efflux.Estimation of the number of CTX-sensitive Ca-activated K⁺ channels per cell indicate that there are 1 to 3 channels/per cell either in Hb A or Hb S red cells. The CTX-insensitive K⁺ efflux (2.7±0.9 FU) may reflect the activity of a different channel, nonspecific changes in permeability or coupling to an anion conductive pathway.     

Determination of the primary charge separation rate in Photosystem II reaction centers at 15 K

We have measured the rate constant for the formation of the oxidized chlorophyll a electron donor (P680⁺) and the reduced electron acceptor pheophytin a ^– (Pheo a ^–) following excitation of isolated Photosystem II reaction centers (PS II RC) at 15 K. This PS II RC complex consists of D₁, D₂, and cytochrome b-559 proteins and was prepared by a procedure which stabilizes the protein complex. Transient absorption difference spectra were measured from 450–840 nm as a function of time with 500fs resolution following 610 nm laser excitation. The formation of P680⁺-Pheo a ^– is indicated by the appearance of a band due to P680⁺ at 820 nm and corresponding absorbance changes at 490, 515 and 546 nm due to the formation of Pheo a ^–. The appearance of the 490 nm and 820 nm bands is monoexponenital with =1.4±0.2 ps. Treatment of the PS II RC with sodium dithionite and methyl viologen followed by exposure to laser excitation results in accumulation of Pheo a ^–. Laser excitation of these prereduced RCs at 15 K results in formation of a transient absorption spectrum assigned to ^1*P680. We observe wavelength-dependent kinetics for the recovery of the transient bleach of the Q_y absorption bands of the pigments in both untreated and pre-reduced PS II RCs at 15K. This result is attributed to an energy transfer process within the PS II RC at low temperature that is not connected with charge separation.Abbreviations PS I Photosystem I - PS II Photosystem II - RC reaction center - P680 primary electron donor in Photosystem II - Chl a chlorophyll a - Pheo a pheophytin a     

Cl−, Na+, and H+ fluxes during the acidification of rabbit reticulocyte endocytic vesicles

The ionic fluxes associated with the ATP-dependent acidification of endocytic vesicles were studied in a preparation isolated from rabbit reticulocytes enriched for transferrin-transferrin receptor complexes. No vesicle acidification was observed in the absence of intra- and extravesicular ions (sucrose_in/sucrose_out), while maximal acidification was observed with NaCl_in/KCl_out·K _in ⁺ was a poor substitute for Na _in ⁺ , and Cl _out ^– could be replaced by other anions with the following efficacy of acidification: Cl^–>Br^–>I^–>PO ₄ ^3– >gluconate>SO ₄ ^2– . Flux studies using³⁶Cl^– and²²Na⁺ showed that the vesicles had a permeability for Cl^– and Na⁺, and that ATP-dependent H⁺ pumping was accompanied by a net influx of Cl^– and a net efflux of Na⁺ provided that there was a Na⁺ concentration gradient. After 3 mins, the time necessary to maximal acidification, the electrical charge generated by the entrance of H⁺ was countered to about 45% by the Cl^– influx and to about 42% by the Na⁺ efflux. These studies demonstrated that both Cl^– and Na⁺ fluxes are necessary for optimal endocytic vesicle acidification.     

Characteristics of antibody inhibition of rat kidney (Na+−K+)-ATPase

Summary Antibodies which were raised against highly purified membrane-bound (Na⁺–K⁺)-ATPase from the outer medulla of rat kidneys inhibit the (Na⁺–K⁺)-ATPase activity up to 95%. The antibody inhibition is reversible. The time course of enzyme inhibition and reactivation is biphasic in semilogarithmic plots.In the purified membrane-bound (Na⁺–K⁺)-ATPase negative cooperativity was observed (a) for the ATP dependence of the (Na⁺–K⁺)-ATPase activity (n=0.86), (b) for the ATP binding to the enzyme (n=0.58), and (c) for the ouabain inhibition of the (Na⁺–K⁺)-ATPase activity (n=0.77). By measuring the Na⁺ dependence of the (Na⁺–K⁺-ATPase reaction, a positive homotropic cooperativity (n=1.67) was found.As reactivation of the antibody-inhibited enzyme proceeds very slowly (t _0.5=5.2hr), it was possible to measure characteristics of the antibody-(Na⁺–K⁺)-ATPase complex: The antibodies exerted similar effects on the ATP dependence of the (Na⁺–K⁺)-ATPase reaction and on the ATP binding of the enzyme.V _max of the (Na⁺–K⁺)-ATPase reaction and the number of ATP binding sites were reduced whileK _{0.5 ATP} for the (Na⁺–K⁺)-ATPase activity and for the ATP binding were increased by the antibodies. The Hill coefficients for the ATP binding and for the ATP dependence of the enzyme activity were not significantly altered by the antibodies. The antibodies increased theK _0.5 value for the Na⁺ stimulation of the (Na⁺–K⁺)-ATPase activity, but they did not alter the homotropic interactions between the Na⁺-binding sites. The negative cooperativity which was observed for the ouabain inhibition of the (Na⁺–K⁺)-ATPase activity was abolished by the antibodies.The data are tentatively explained by the following model: The antibodies bind to the (Na⁺–K⁺)-ATPase from the inner membrane side, reduce the ATP binding symmetrically at the ATP binding sites and reduce thereby also the (Na⁺–K⁺)-ATPase activity of the enzyme. The antibodies may inhibit the ATP binding by a direct interaction or by means of a conformational change at the ATP binding sites. This may possibly also lead to the alteration of the Na⁺ dependence of the (Na⁺–K⁺)-ATPase activity and to the observed alteration of the dose response to the ouabain inhibition.     

Saturable K+ pathway across the outer border of frog skin (Rana temporaria): Kinetics and inhibition by Cs+ and other cations

Summary The reaction of abdominal skins of the frog speciesRana temporaria on mucosal K⁺-containing solutions was studied in an Ussing-type chamber by recording transepithelial potential difference (PD), short-circuit current (SCC) and conductance (G). With Na-Ringer's as serosal medium, a linear correlation between PD and the logarithm of the mucosal K⁺-concentration ([K] _o ) was obtained. The K⁺-dependent SCC saturated with increasing [K] _o , and could quickly and reversibly be depressed by addition of Rb⁺, Cs⁺, and H⁺, Li⁺, Na⁺, and NH ₄ ⁺ did not influence K⁺ current. A large scatter was obtained for kinetic parameters like the slope of the PD-log [K] _o -line (18–36.5 mV/decade), the apparent Michaelis constant (13–200mm), and the maximal current of the saturable SCC (6–50 A·cm^–2), as well as for the degree of inhibition by Cs⁺ ions. This seemed to be caused by a time-dependent change during long time exposure to high [K] _o (more than 30 sec), thereby inducing a selectivity loss of K⁺-transporting structures, together with an increase in SCC andG and a decrease in PD. Short time exposure to K⁺-containing solutions showed a competitive inhibition of K⁺ current by Cs⁺ ions, and a Michaelis constant of 6.6mm for the inhibitory action of Cs⁺. Proton titration resulted in a decrease of K⁺ current at pH<3. An acidic membrane component (apparent dissociation constant 2.5×10^–3 m) is virtually controlling K⁺ transfer. Reducing the transepithelial K⁺-concentration gradient by raising the serosal potassium concentration was accompanied by the disappearance of SCC and PD.     

Phosphate transport in intestinal brush-border membrane

In the small intestine of the rabbit the process of Na⁺-dependent uptake of phosphate occurs only at the brush-border of duodenal enterocytes. Li⁺ can replace Na⁺. The process is activated when either K⁺, Cs⁺, Rb⁺, or choline is present in the intravesicular space. The presence of membrane-permeable anions is essential for maximum rates of phosphate transport. We conclude that the mechanism of the phosphate carrier is electrogenic at pH 6–8, probably two Na⁺ moving with each H₂PO ₄ ^– . This. will lead to the development of a positive charge within the vesicle. The variation of theK _m for H₂PO ₄ ^– with pH is thought to be the consequence of the affinity of the carrier protein for H₂PO ₄ ^– increasing as the pH increases. Polyclonal antibodies against membrane vesicles isolated from rabbit duodenum, jejunum, and ileum were prepared. The antibodies raised against the ileum and jejunum both activated the phosphate transport process, while the anti-duodenum antibody preparation inhibited phosphate transport.     

Relations between intracellular ion activities and extracellular osmolarity inNecturus gallbladder epithelium

Summary The interactions between ion and water fluxes have an important bearing on osmoregulation and transepithelial water transport in epithelial cells. Some of these interactions were investigated using ion-selective microelectrodes in theNecturus gallbladder. The intracellular activities of K⁺ and Cl^– in epithelial cells change when the epithelium is adapted to transport in solutions of a low osmolarity. In order to achieve new steady states at low osmolarities, cells lost K⁺, Cl^– and some unidentified anions. Surprisingly, the apparent K⁺ concentration remained high: at an external osmolartity of 64 mOsm the intracellular K⁺ concentration averaged 95mm. This imbalance was sensitive to anoxia and ouabain. The effects of abrupt changes in the external osmolarities on the intracellular activities of Na⁺, K⁺ and Cl^– were also investigated. The gradients were effectuated by mannitol. The initial relative rates of change of the intracellular activities of Na⁺ and Cl^– were equal. The data were consistent with Na⁺ and Cl^– ions initially remaining inside the cell and a cell membraneL _p of 10^–3 cm sec^–1 osm^–1, which is close to the values determine by Spring and co-workers (K.R. Spring, A. Hope & B.-E. Persson, 1981.In: Water Transport Across Epithelia. Alfred Benzon Symposium 15. pp. 190–200. Munskgaard, Copenhagen). The initial rate of change of the intracellular activity of K⁺ was only 0.1–0.2 times the change observed in Na⁺ and Cl^– activities, and suggests that K⁺ ions leave the cell during the osmotically induced H₂O efflux and enter with an induced H₂O influx. The coupling is between 98 and 102 mmoles liter^–1. Various explanations for the anomalous behavior of intracellular K⁺ ions are considered. A discussion of the apparent coupling between K⁺ and H₂O, observed in nonsteady states, and its effects on the distribution of K⁺ and H₂O across the cell membrane in the steady states, is presented.     

Proton conductance through phospholipid bilayers: Water wires or weak acids?

The proton/hydroxide (H⁺/OH^–) permeability of phospholipid bilayer membranes at neutral pH is at least five orders of magnitude higher than the alkali or halide ion permeability, but the mechanism(s) of H⁺/OH^– transport are unknown. This review describes the characteristics of H⁺/OH^– permeability and conductance through several types of planar phospholipid bilayer membranes. At pH7, the H⁺/OH^– conductances (G _H/OH) range from 2–6 nS cm^–2, corresponding to net H⁺/OH^– permeabilities of (0.4–1.7)×10^–5 cm sec^–1. Inhibitors ofG _H/OH include serum albumin, phloretin, glycerol, and low pH. Enhancers ofG _H/OH include chlorodecane, fatty acids, gramicidin, and voltages >80 mV. Water permeability andG _H/OH are not correlated. The characteristics ofG _H/OH in fatty acid (weak acid) containing membranes are qualitatively similar to the controls in at least eight different respects. The characteristics ofG _H/OH in gramicidin (water wire) containing membranes are qualitatively different from the controls in at least four different respects. Thus, the simplest explanation for the data is thatG _H/OH in unmodified bilayers is due primarily to weakly acidic contaminants which act as proton carriers at physiological pH. However, at low pH or in the presence of inhibitors, a residualG _H/OH remains which may be due to water wires, hydrated defects, or other mechanisms.     

Differential steric effects in the axial ligation of pyridine and imidazole to α- and β-alkylcobinamides

One subclass of B₁₂-requiring enzymes is now known to bind their B₁₂ coenzymes “base-off,” with a histidine residue from the protein supplying an imidazole ligand to the cobalt center. Recent results from Sirovatka and Finke (J.M. Sirovatka and R.G. Finke, J.Am. Chem. Soc. 119, (1997) 3057) show that imidazole has an extraordinary trans effect on the mode of carbon–cobalt bond cleavage in coenzyme B₁₂ analogs, compared to pyridine or the natural 5,6-dimethylbenzimidazole ligand, and it was suggested that a differential steric effect could, in part, account for the uniqueness of the imidazole ligand. Such a differential steric effect for imidazole and pyridine is now demonstrated by studies of the thermodynamics of ligation of these ligands to the α and β diastereomers of two alkylcobinamides (RCbi⁺s, derivatives of cobalamins which lack the normal axial nucleotide) based on the known differences in steric crowding of the α (“lower”) and β (“upper”) axial ligand positions of cobalt corrinoids. Imidazole binds more tightly than pyridine to both diastereomers of NCCH₂Cbi⁺ and CF₃Cbi⁺, in all cases due to a more favorable entropy change, which is the result of lowered steric interference with corrin side chain thermal motions.     

Deficiency of potassium but not phosphorus enhances root respiration

Root respiration of kohlrabi (Brassica oleraceavar. gongylodes) was measured non-destructivelyin vivo by infrared gas analysis of completeroot systems, using potted plants in sand culture andnutrient solutions, for six weeks under (a) nutrientsufficiency, (b) deficiency of all mineral nutrients,(c) potassium deficiency or (d) phosphorus deficiency.This was to study the adaptation to nutrient stress interms of changes in root growth, root respiration,assimilate allocation and energy requirement fornutrient uptake. Both deficiencies of phosphorus andpotassium increased the root:shoot-ratio. This wasattributed to the plants transferring a largerrelative proportion of assimilates to the roots thanto the shoots relative to nutrient-sufficient plants.Roots of nutrient-sufficient kohlrabi respired 1.7 or7.7 mg CO₂ h^–1 per g fresh or dry matter, respectively. However, potassiumdeficiency enhanced root respiration to 2.4 mgCO₂ h^–1 or 12.2 mg CO₂ h^–1 on a per g fresh or dry weight basis respectively. This originated from an additional2.6 mg glucose g^–1 dry matter h^–1 allocated to the roots and provided 50 Joule additional energy(150 versus 100 Joule g^–1 dry matter h^–1)which may become available for the proposedK⁺:H⁺ symporter for potassium uptake.     

Nitrate or ammonium nutrition in french bean

Summary Bean Plants were grown in a greenhouse in sand irrigated with nutrient solutions containing either 2 mM NO ₃ ^– or 2 mM NH ₄ ⁺ . After 45 days fresh weight of NH ₄ ⁺ plants was half that of NO ₃ ^– plants. Cation concentration in NH ₄ ⁺ plants was 30% less than in NO ₃ ^– plants. Amino acids (SER, ASN, GLN) accummulated 3 to 10 times more in NH ₄ ⁺ plants. The concentration of organic acids (malic, malonic, citric) was 10 to 30 times higher in NO ₃ ^– plants. The ATP-costings for the synthesis of amino acids and organic acids in NH ₄ ⁺ plants was half that of NO ₃ ^– ones: therefore it could not account for the reduction of growth in the ammonium-fed plants.     

Intracellular chloride and potassium ions in relation to excitability ofChara membrane

Summary Internodal cells ofChara australis were made tonoplast-free by replacing the cell sap with EGTA-containing media; then the involvement of internal Cl^– and K⁺ in the excitation of the plasmalemma was studied.[Cl^–] _i was drastically decreased by perfusing the cell interior twice with a medium lacking Cl^–. The lowered [Cl^–] _i was about 0.01mm. Cells with this low [Cl^–] _i generated action potential and showed anN-shapedV–I curve under voltage clamped depolarization like Cl^–-rich cells containing 13 or 29mm Cl^–.E _m at the peak of the action potential was constant at [Cl^–] _i between 0.01 and 29mm. The possibility that the plasmalemma becomes as permeable to other anions as to Cl^– during excitation is discussed.At [Cl^–] _i higher than 48mm, cells were inexcitable. When anions were added to the perfusion medium to bring the K⁺ concentration to 100mm, NO ₃ ^– , F^–, SO ₄ ^2– , acetate, and propionate inhibited the generation of action potentials like Cl^–, while methane sulfonate, PIPES, and phosphate did not inhibit excitability.The duration of the action potential depended strongly on the intracellular K⁺ concentration. It decreased as [K⁺] _i (K-methane sulfonate) increased. Increase in [Na⁺] _i (Na-methane sulfonate) also caused its decrease, although this effect was weaker than that of K⁺. The action of these monovalent cations on the duration of the action potential is the opposite of their action on the membrane from the outside (cf. Shimmen, Kikuyama & Tazawa, 1976,J. Membrane Biol. 30:249).     

Transinhibition and Voltage-gating in a Fungal Nitrate Transporter

We have applied enzyme kinetic analysis to electrophysiological steady-state data of Zhou et al. (Zhou, J.J., Trueman, L.J., Boorer, K.J., Theodoulou, F.L., Forde, B.G., Miller, A.J. 2000. A high-affinity fungal nitrate carrier with two transport mechanisms. J. Biol. Chem. 275:39894–9) and to new current-voltage-time records from Xenopus oocytes with functionally expressed NrtA (crnA) 2H⁺-NO ₃ ^– symporter from Emericella (Aspergillus) nidulans. Zhou et al. stressed two Michaelis-Menten (MM) mechanisms to mediate the observed nitrate-induced currents, I _{NO 3} ^– . We show that a single straightforward reaction cycle describes the data well, pointing out that during exposure to external substrate, S = (2H⁺+NO ₃ ^– )_o, the product concentration inside, [P] = [H⁺] _i ² · [NO ₃ ^– _i, may rise substantially near the plasma membrane, violating the condition [P] [S] for MM kinetics. Here, [P] and its changes during experimentation are treated explicitly. K _1/2 20 µM for I _{NO 3} ^– at pH_o from Zhou et al. is confirmed. According to our analysis, NrtA operates between about 0.2 and 0.6 of the electrical distance in the membrane (outside 0, inside 1). In absence of thermodynamic gradients, the predominant orientation of the binding site(s) is probably inwards. The activity of the enzyme is sensitive to the transmembrane voltage, V, with an apparent gating charge of +1.0 ± 0.5 for inactivation, and transition probabilities of 0.3–1.3 s^–1 at V = 0. This gating mode impedes loss of cellular NO ₃ ^– during depolarization.     

Amiloride sensitivity of proton-conductive pathways in gastric and intestinal apical membrane vesicles

Summary Passive proton permeability of gastrointestinal apical membrane vesicles was determined. The nature of the pathways for proton permeation was investigated using amiloride. The rate of proton permeation (k _H ⁺ was determined by addition of vesicles (pH _i = 6.5) to a pH 8.0 solution containing acridine orange. The rate of recovery of acridine orange fluorescence after quenching by the acidic vesicles ranged from 4 × 10^–3 (gastric parietal cell stimulation-associated vesicles; SAV) and 5 × 10^–3 (duodenal brush-border membrane vesicles; dBBMV) to 11 × 10+^–3 sec^–1 (ileal BBMV; iBBMV). Amiloride, 0.03 and 0.1 mm, significantly reduced the rate of proton permeation in dBBMV and iBBMV, but not gastric SAV. The decreases in k _H ⁺ were proportionately greater in iBBMV as compared with dBBMV. The presence of Na⁺/H⁺ exchange was demonstrated in both dBBMV and iBBMV by proton-driven (pH _i < pH _o ) ²²Na⁺ uptake. Evidence was also sought for the conductive nature of pathways for proton permeation. Intravesicular acidification, again determined by quenching of acridine orange fluorescence, was observed during imposition of K⁺-diffusion potential ([K⁺] _i [K⁺ _o ). In dBBMV and iBBMV, intravesicular acidification was enhanced in the presence of the K⁺-ionophore valinomycin, indicating that the native K⁺ permeability is rate limiting. In the presence of valinomycin, the K⁺-diffusion potential drove BBMV intravesicular acidification to levels close to the electrochemical potential. In gastric SAV, acidification was not limited by the K⁺ permeability. Valinomycin was without effect, but the K⁺/H⁺ ionophore nigericin enhanced acidification in gastric SAV, illustrating the low proton permeability of these membranes. Amiloride, 0.03–1 mm, resulted in concentration-dependent reductions of K⁺-diffusion potential-driven acidification in dBBMV and iBBMV but not in gastric SAV. These data demonstrate that proton permeation in the three membrane types is rheogenic. The sensitivity of the proton-conductive pathways in intestinal BBMV to high concentrations of amiloride correlated with the presence of the Na⁺/H⁺ antiport and indicates that this transmembrane protein may represent a pathway for proton permeation.We thank Ruth Briggs for assistance with the Na/H exchange experiments. This work was supported by a grant from the Medical Research Council (G8418056CA).     

Electrical effects of potassium and bicarbonate on proximal tubule cells ofNecturus

Summary The effects of stepwise concentration changes of K⁺ and HCO ₃ ^– in the basolateral solution on the basolateral membrane potential (V _bl) of proximal tubule cells of the doubly-perfusedNecturus kidney were examined using conventional microelectrodes. Apparent transference numbers were calculated from changes inV _bl after alterations in external K⁺ concentration from 1.0 to 2.5mm (t _{K, 1.0–2.5}), 2.5 to 10, and in external HCO ₃ ^– concentration (at constant pH) from 5 to 10mm (t _{HCO3, 5–10}), 10 to 20, or 10 to 50.t _{K, 2.5–10} was 0.38±0.02 under control conditions but was sharply reduced to 0.08±0.03 (P>0.001) by 4mm Ba⁺⁺. This concentration of Ba⁺⁺ reducedV _bl by 9±1 mV (at 2.5 external K⁺). Perfusion with SITS (5×10^–4 m) for 1 hr hyperpolarizedV _bl by 10±3 mV and increasedt _{K, 2.5–10} significantly to 0.52±0.01 (P<0.001). Ba⁺⁺ application in the presence of SITS depolarizedV _bl by 22±3 mV. In control conditionst _{HCO3, 10–50} was 0.63±0.05 and was increased to 0.89±0.07 (P<0.01) by Ba⁺⁺ but was decreased to 0.14±0.02 (P<0.001) by SITS. In the absence of apical and basolateral chloride, the response ofV _bl to bicarbonate was diminished but still present (t _{HCO3, 10–20} was 0.35±0.03). Intracellular pH, measured with liquid ion-exchange microelectrodes, increased from 7.42±0.19 to 7.57±0.17 (P<0.02) when basolateral bicarbonate was increased from 10 to 20mm at constant pH. These data show that the effects of bicarbonate onV _bl are largely independent of effects on the K⁺ conductance and that there is a significant current-carrying bicarbonate pathway in the basolateral membrane. Hence, both K⁺ and HCO ₃ ^– gradients are important in the generation ofV _bl, and their relative effects vary reciprocally.