Transmembrane distribution of lipophilic cations in response to an electrochemical potential in reconstituted cytochromec oxidase vesicles and in vesicles exhibiting a potassium ion diffusion potential

It has been shown previously that biogenic amines and a number of pharmaceutical agents can redistribute across vesicle membranes in response to imposed potassium ion or proton gradients. Surprisingly, drug accumulation is observed for vesicles exhibiting either a pH gradient (interior acidic) or a membrane potential (interior negative), implying that these compounds can traverse the lipid bilayer as either the neutral or charged species. This interpretation, however, is complicated by the fact that vesicles exhibiting a membrane potential (interior negative) accumulate protons in response to this potential, thereby creating a pH gradient (interior acidic). This raises the possibility that in both vesicle systems drug redistribution occurs in response to the proton gradient present. We have therefore compared the uptake of several lipophilic cations by reconstituted cytochromec oxidase vesicles and by similar vesicles exhibiting a potassium ion diffusion potential. While turnover of the oxidase generates a membrane potential of comparable magnitude to the potassium ion diffusion system, it is associated with a proton gradient of opposite polarity (interior basic). Both systems show rapid uptake of the permanently charged lipophilic cation, tetraphenylphosphonium, but only the potassium ion diffusion system accumulates the lipophilic amines doxorubicin and propranolol. This provides compelling evidence that such weak bases redistribute only in response to pH gradients and not membrane potential.     

The influence of pH on cystine and dibasic amino acid transport by rat renal brushborder membrane vesicles

The uptake of cystine and lysine by rat renal brushborder membrane vesicles was examined at various intravesicular and extravesicular hydrogen ion concentrations to discern whether ionic species are determinants of specificity for the shared transport system and whether hydrogen ion gradients play a role in determining uptake values. When intravesicular and extravesicular pH are identical, the highest uptake of cystine occurred at pH 7.4, with lesser uptake at pH 6.0 and 8.3. Since cystine is electroneutral at pH 6.0 and 90% anionic at pH 8.3, it appears that neither form of the amino acid is a preferred species for transport. A similar relationship between pH and uptake occurs for lysine, which is cationic at pH below 8.5. This suggests that pH affects the functioning of the membrane carrier system independent of ionic species of the substrate. There is no apparent relationship of cystine uptake to hydrogen ion gradients across the membrane. Over the range of extravesicular pH studied, optimal cystine uptake occurred whenever the intravesicular pH was 7.4. Competitive interactions between unlabeled amino acids and labeled cystine were not affected by the extravesicular pH and, therefore, did not seem determined by the ionic species of cystine.     

COMPARATIVE pH DEPENDENT METAL INHIBITION OF NUTRIENT UPTAKE BY SCENEDESMUS QUADRICAUDA(CHLOROPHYCEAE)1,2

Cadmium and copper inhibition of nutrient uptake by the green alga Scenedesmus quadricauda is highly pH dependent in an inorganic medium; both metals are less toxic at low pH. The alga was grown in chemostats with both N and P approaching limiting levels; it was then possible to study metal toxicity to the nitrate, ammonium, and phosphate uptake systems of algae in an identical physiological state. When the logarithm of the Cd concentration causing 25% inhibition of nitrate, ammonium, and phosphate uptake was regressed against pH almost perfect linear relationships were obtained. This was also true at the 50% inhibition level, except for a smaller than predicted increase in Cd toxicity to ammonium uptake at pH 8, which may be due to the beginning of Cd precipitation at this pH. Cu²⁺ toxicity was linearly related to pH for ammonium and phosphate uptake and although, its toxicity for nitrate uptake also increased with pH, the increase was not perfectly linear. The toxicity of total Cu showed no linear relationship to pH. Cd²⁺ and Cu²⁺ toxicity increased by up to four orders of magnitude from pH 5 to 8. Competition between free metal and hydrogen ions for uptake sites on the cell surface is suggested as a mechanism increasing the toxicity of free metal, ions as the hydrogen ion content decreases (i.e. at higher pH).     

UPTAKE OF CADMIUM BY FRESHWATER GREEN ALGAE: EFFECTS OF PH AND AQUATIC HUMIC SUBSTANCES1

The effects of humic substances and low pH on short‐term Cd uptake by Pseudokirchneriella subcapitata (Korshikov) Hindak and Chlamydomonas reinhardtii Dang were investigated under defined exposure conditions. The uptake experiments were run in the presence of either a synthetic organic ligand (nitrilotriacetate) or natural organic ligands (Suwannee River fulvic or humic acid). An ion‐exchange method was used to measure the free Cd²⁺ concentrations in the exposure solutions. At pH 5, measured free Cd²⁺ concentrations agreed with estimations made using the geochemical equilibrium model WHAM, but at pH 7 the model overestimated complexation by both Suwannee River fulvic and humic acids compared with the ion‐exchange measurements. Consistent with the metal internalization step being rate limiting for overall short‐term uptake, intracellular Cd uptake was linear for exposure times less than 20 min at pH 5 or pH 7 for both algal species. After taking into account complexation of Cd in solution, Suwannee River humic substances had no additional effects on cadmium uptake at pH 7, as would be predicted by the free ion model. This absence of effects other than complexation persisted at pH 5, where the tendency of humic substances to adsorb to the algal cell surface is favored. Changes in pH strongly influenced Cd uptake, with the intracellular flux of Cd being at least 20 times lower at pH 5 than at pH 7 for P. subcapitata. Our results support models such as the free ion model or the biotic ligand model, in which humic substances act indirectly on Cd uptake by reducing the bioavailability of Cd by complexation in solution.     

Abrupt onset of large scale nonproton ion release in purple membranes caused by increasing pH or ionic strength.

The abrupt onset of large scale nonproton ion release by photo-excited purple membrane suspensions has been observed near neutral pH using transient conductivity measurements. At pH 7 and low ionic strength, the conductivity transients due to proton and nonproton ions are of comparable magnitude but of opposite sign: fast proton release and ion uptake, followed by slow proton uptake and ion release. By increasing either the pH or the NaCl concentration, the amplitude of the conductivity transient increases sharply and the signal is then dominated by nonproton ion release. These results can be understood in terms of light-induced changes in the population of counterions condensed at the purple membrane surface caused by changes in the surface charge density. The critical charge density required for condensation to occur is evidently achieved near neutral pH by ionizing dissociable groups on the membrane by either titration (increasing the pH) or shifting their pKs (increasing the ionic strength).     

Effects of desiccation on the 77°K fluorescence properties of the liverwort Porella navicularis and the isolated lichen green alga Trebouxia pyriformis

The uptake of the auxin type herbicide 2,4-D into rice seedlings ( Oryza sativa L. cv. Dunghan Shali) and its effects on the K⁺, NH⁺₄ and NO₃ ion uptake and the K⁺ content were investigated at different pH values. A short incubation of the roots in 0.01 m M 2,4-D caused a marked ion uptake inhibition only at low pH. The non-auxin type herbicide benthiocarb did not produce such an inhibitory effect. Lowering of the pH in the external medium led to an increased 2,4-D uptake by the roots. These results can be explained by the increased H⁺ permeability of the membranes, allowing a more rapid entrance of 2,4-D into the root cells, thereby inhibiting the active ion uptake. Rice roots not subjected to 2,4-D treatment responded to H⁺ stress with an increased anomalous K⁺ uptake and a decreased K⁺ content. With reference to the effects of pH changes on the ion and 2,4-D uptake, possible transport mechanism of NH⁺₄ and 2,4-D are briefly discussed.     

Uptake of L-leucine by Trout Red Blood Cells and Peripheral Lymphocytes

The uptake of l-leucine by trout red blood cells and peripheral lymphocytes has been analyzed. The present study shows two functionally different Na⁺-independent systems for apolar branched-chain amino acids. They are designated as L systems because they share some properties with the mammalian L system. The carrier present in red blood cells has low K _m values, is trans-stimulable and not stereospecific for leucine uptake; on the other hand, the system present in lymphocytes is stereospecific for leucine uptake and trans-inhibitable. Both carriers are pH sensitive in a similar fashion at low pHs, but there are important differences at higher pH values (above neutrality). These properties are compared with these of the asc systems previously reported in these cells. Received: 2 June 1995/Revised: 7 March 1996     

Uptake of metals by bacterial polysaccharides

J.L. GEDDIE AND I.W. SUTHERLAND. 1993. The binding of cations by a range of bacterial polysaccharides was examined. Comparison of native and deacetylated polymers indicated the influence of polysaccharide acetylation on ion uptake and selectivity. The effects of temperature and pH on ion uptake were also examined. Metal ion uptake was carried out by dialysis and samples were analysed using ion chromatography. The native acetylated polymers showed a selectivity for Ca²⁺ > Mg²⁺ > monovalent cations, whereas samples lacking acetyl groups showed a selectivity for monovalent cations > Mg²⁺ > Ca²⁺. Increased temperatures reduced the capacity for several of the polymers to bind the cations; The Zoogloea ramigera polymer appeared least affected. The pH value also affected uptake.     

Carriers for abscisic acid and indole-3-acetic acid in primary roots: their regional localisation and thermodynamic driving forces

A carrier for the uptake of abscisic acid (ABA) is present in the tips and elongating zones of primary roots of both leguminous (runner bean, French bean, pea) and non-leguminous (sunflower, maize) seedlings. No ABA carrier was present in more mature root regions. For indole-3-acetic acid both carrier-mediated uptake and a 2,3,5-triiodobenzoate-sensitive efflux component are present in growing and in non-elongating runner-bean root tissues. Both ABA and indole-3-acetic acid carriers were inactivated by protein-modifying reagents. The driving forces for the carrier systems were studied using reagents, (KCl, fusicoccin, vanadate, dicyclohexylcarbodiimide, proton ionophores and azide) known to modify transmembrane pH (ΔpH) and electricla gradients (ΔE) and whose effects were independently monitored using radiolabelled, lipophilic, weak acids as probes. For abscisic acid the carrier-mediated uptake depend on ΔpH and the nonsaturable component of uptake, due to diffusion of undissociated ABA. The maximum velocity of the carrier is greater at pH 4 than at pH 5, although the Michaelis constants are similar. Modification of ΔE did not alter ABA net uptake but effects on the indole-3-acetic acid system consistent with perturbation of an electrogenic 2,3,5-triiodobenzoate-sensitive component were observed. It is suggested that the ABA carrier is an ABA anion/hydrogen ion symport or, less likely, represents facilitated diffusion of undissociated ABA.     

Amino acid transport systems of JapaneseParamecium symbiont F36-ZK

Analyses of amino acid transport systems in JapaneseParamecium symbiont F36-ZK were performed using¹⁴C-amino acids. Kinetic analyses of amino acid uptake and competitive experiments revealed three transport systems; a basic amino acid transport system, which catalyzed transport of L-Arg and L-Lys, a general amino acid transport system, which had broad specificity for 19 amino acids (but not L-Arg), and an alanine transport system. These three systems were considered to be capable of active transport. Amino acid-proton symport was indicated by the following data: decreases in pH of the medium observed during L-Ser and L-Ala uptake, and uptake of L-Arg, L-Ser and L-Ala being inhibited by carbonyl cyanide m-chlorophenylhydrazone, sodium azide and vanadate. The optimal pH for uptake of neutral amino acids and L-Arg was around 5 and 5 to 6.5, respectively. Uptake of L-Asp and L-Glu was very sensitive to pH and little uptake of L-Asp was measured above pH 6.0. Amino acid uptake was not inhibited by nitrate or ammonium, and cultured cells with ammonium also possessed constitutive uptake systems.     

Inhibition of respiration and ion uptake by 2,3,5-triiodobenzoic Acid in excised barley roots

The addition of 1 micromolar 2,3,5-triiodobenzoic acid (TIBA) to solutions containing KCl resulted in the inhibition of K and Cl uptake in excised barley roots. The effectiveness of TIBA as an inhibitor increased as the pH of the treatment solution decreased and approached the pK_a of TIBA. A lag period of approximately 20 minutes existed prior to the onset of TIBA induced inhibition of ion uptake. Respiratory activity was also inhibited by TIBA. The data suggest that in this material, TIBA functions by entering the cytoplasm and inhibiting metabolism. Comparisons made on the effect of added Ca, showed that at pH 5.7 and higher, Ca had no effect on ion uptake whereas at lower pH values the presence of Ca enhanced uptake by offsetting the deleterious effects of H⁺.     

The physiological basis for altered Na+ and Cl- movements across the gills of rainbow trout (Oncorhynchus mykiss) in alkaline (pH = 9.5) water

To test the hypothesis that internal ion imbalances at high pH are caused by altered branchial ion transporting capacity and permeability, radiotracers (24Na+ and 36Cl-) were used to measure ion movements across the gills of intact rainbow trout (Oncorhynchus mykiss) during 3 d exposure to pH 9.5. At control pH (pH 8.0), the trout were in net ion balance, but by 8 h at high pH, 60%-70% reductions in Cl- influx (JClin) and Na+ influx (JNain) led to net Cl- and Na+ losses of -200 micromol kg-1 h-1. Outflux (diffusive efflux plus renal ion losses) was not initially altered. By 72 h, net Cl- balance was reestablished because of a restoration of JClin. Although JNain remained 50% lower at this time, counterbalancing reductions in Na+ outflux restored net Na+ balance. One-substrate ion-uptake kinetics analyses indicated that reduced ion influx after 8 h at pH 9.5 was caused by 50% decreases in Cl- and Na+ maximal transport rates (JClmax, JNamax), likely reflecting decreased numbers of functional transport sites. Two-substrate kinetic analyses indicated that reduced internal HCO-3 and H+ supply for respective branchial Cl-/base and Na+/acid transport systems also contributed to lower JClin and, to a lesser extent, lower JNain at pH 9.5. Recovery of JClmax after 3 d accounted for restoration of Cl- balance and likely reflected increased numbers of transport sites. In contrast, JNamax remained 33% lower after 3 d, but a lower affinity of the gills for Na+ (fourfold greater KNam) accounted for the chronic reduction in Na+ influx at pH 9.5. Thus, reestablishment of Cl- uptake capacity and counterbalancing reductions in Na+ outflux allows rainbow trout to reestablish net ion balance in alkaline waters.     

A Comparison of the Uptake and Translocation of Some Organic Herbicides and a Systemic Fungicide by Barley: I. ABSORPTION IN EELATION TO PHYSICO-CHEMICAL PROPERTIES

A comparative study has been made of the uptake by and translocationfrom roots of intact barley plants of six herbicides and a systemicfungicide (four triazines, diuron, 2,4-dichloro-phenoxyaceticacid (2,4-D) and ethirimol). Relationships between uptake andtranspiration rate are discussed in the light of the physico-chemicalproperties of these compounds, notably their partition coefficientsin oil/water systems and their dissociation constants. Apartfrom 2,4-D, sorption of these compounds appears to be a passiveprocess. At pH4 the uptake of 2,4-D seems to be influenced bymetabolism; not only may the concentration of this compoundin the transpiration stream be considerably greater than thatin the medium surrounding the roots but absorption by rootsis markedly reduced at low temperatures and by sodium azide. The initial rate of uptake of these compounds correlates reasonablywell with their partition coefficients in olive oil/water orn-dodecane/water systems; likewise the concentration in thetranspiration stream is greater for lipophilic than for lipophobicsubstances. Whereas the hydrogen ion and calcium concentrations of the ambientmedium appear to have no effect on the uptake of compounds withlow pK's, the uptake of those substances which protonate betweenpH4 and pH6 is affected by them. These findings are discussedfrom the viewpoint that the pathways of transport of lipophilicand lipophobic compounds across the roots may differ. Although there is some evidence that retention by roots canlimit transport to shoots, there is no simple inverse correlationbetween the total concentration of the different substancesin the roots and that in the transpiration stream. This questionis discussed in a subsequent paper.     

Mechanism of proton-linked nitrate uptake in Cyanidium caldarium,an acidophilic non-vacuolated alga

The unicellular non-vacuolated alga Cyanidium caldarium, grown under conditions of nitrogen limitation, possesses two permease systems for nitrate uptake, one of which, the so-called ‘high-affinity nitrate uptake system’, enables the alga to take up nitrate through a mechanism involving cotransport of protons. Measurements of nitrate and proton stoichiometry, and determination of the kinetic parameters of uptake in cells resuspended in medium adjusted at different pH values, are consistent with a mechanism of uptake in which two protons for each nitrate ion are transported across the plasmalemma. Furthermore, kinetic data suggest that the carrier first binds nitrate and, subsequently, protons. Permutations of this binding sequence do not agree with the experimental results.     

The role of intracellular pH in ligand internalization

Internalization of EGF and transferrin measured as the rate of uptake of 125I-labeled ligands was compared in the cell line CCL39 and a mutant derivative, PS-120, lacking the Na+/H+ antiport system. No significant alteration was detected between the two cell lines. In contrast, pretreatment of the mutant cells PS-120 with 20 mM NH4Cl for 30 min to decrease persistently intracellular pH resulted in an increase in 125I-EGF and 125I-transferrin uptake by 60% and 25%, respectively. However, similar NH4Cl pretreatment of the parental cell line, CCL-39, which only affected intracellular pH very transiently did not cause an increase of ligand uptake. The binding of 125I-EGF to CCL-39 and PS-120 cells with or without NH4Cl pretreatment showed that NH4Cl pretreatment did not affect EGF binding in either CCL-39 or PS-120 cells. Since cells regulate intracellular pH by ion transport systems, we also examined the role of Na+, K+-ATPase. Ouabain, an inhibitor of Na+, K+-ATPases, showed no effect on 125I-EGF uptake in either of the cell types with or without NH4Cl pretreatment. Taken together, these results suggest that the plasma membrane-bound Na+/H+ antiport, a major pHi-regulating system in vertebrates, indirectly plays a role in ligand internalization through regulation of intracellular pH.     

Calcium homeostasis of epithelial cells

1. Cytosolic free Ca2+ is an important regulator of ion transport processes in epithelial cells. 2. Free Ca2+ concentration is regulated by a concerted action of Ca2+ transport systems in plasma membranes and intracellular organelles. 3. These transport systems were studied in intestinal and renal cortical cells with emphasis on the transport capacities and Ca2+ affinities. 4. Ca2+ accumulation by permeabilized cells was compared to Ca2+ uptake by isolated organelles and membrane fractions. 5. Effects induced by cell or organelle isolation methods and the influence of temperature and pH on Ca2+ transport capacities were studied.     

Effects of pH Changes on Ion and 2,4-D Uptake of Wheat Roots

The quantitative relationships between pH-dependent ion and 2,4-D uptake in winter wheat seedlings (Triticum aestivum L. cv. Yubileynaya 50) have been investigated. The movement of various ions (potassium, phosphate, nitrate and ammonium) and 2,4-D across the root membranes was monitored with radioactive and stable isotope tracer methods. It was found that the H₊ ion concentration of the absorption solution strongly influences the 2,4-D uptake of the roots. Simultaneously, the 2,4-D uptake stimulates secretion of H⁺ into the absorption solution, that is, a H⁺ efflux can accompany the uptake of 2,4-D. This finding is consistent with the acid secretion theory of auxin and fusicoccin action. At pH 4 the 2,4-D uptake was much higher than at pH 6, thereby inhibiting the ion uptake and increasing the phytotoxicity in the plant. The results indicate that 2,4-D enters the root cells rapidly at the lower pH, mostly as undissociated molecules. With reference to the 2,4-D concentration in the roots at pH 4, a possible transport mechanism of the auxin herbicide is briefly discussed.     

Interaction of cations with phosphate uptake by Saccharomyces cerevisiae. Effects of surface potential.

The effect of bivalent cations on phosphate uptake by Saccharomyces cerevisiae was investigated. Phosphate uptake via the Na+-dependent transport system at pH 7.2 is stimulated by bivalent cations. The apparent affinity of phosphate for the transport mechanism is increased, but the apparent affinity for Na+ is decreased. Uptake of phosphate via the Na+-independent transport system is accompanied by a net proton influx of 2H+ and an efflux of 1 K+ for each phosphate ion taken up. At pH 4.5 phosphate uptake via the Na+-independent system is stimulated by bivalent cations, whereas at pH 7.2 uptake is inhibited. The effect of bivalent cations on phosphate uptake can be ascribed to a decrease in the surface potential.     

Biosorption of uranium and thorium

Selected samples of waste microbial biomass originating from various industrial fermentation processes and biological treatment plants have been screened for biosorbent properties in conjunction with uranium and thorium in aqueous solutions. Biosorption isotherms have been used for the evaluation of biosorptive uptake capacity of the biomass which was also compared to an activated carbon and the ion exchange resin currently used in uranium production processes. Determined uranium and thorium biosorption isotherms were independent of the initial U or Th solution concentration. Solution pH affected the exhibited uptake. In general, lower biosorptive uptake was exhibited at pH 2 than at pH 4. No discernible difference in uptake was observed between pH 4 and pH 5 where the optimum pH for biosorption lies. The biomass of Rhizopus arrhizus at pH 4 exhibited the highest uranium and thorium biosorptive uptake capacity (g) in excess of 180 mg/g. At an equilibrium uranium concentration of 30 mg/liter, R. arrhizus removed approximately 2.5 and 3.3 times more uranium than the ion exchange resin and activated carbon, respectively. Under the same conditions, R. arrhizus removed 20 times more thorium than the ion exchange resin and 2.3 times more than the activated carbon. R. arrhizus also exhibited higher uptake and a generally more favorable isotherm for both uranium and thorium than all other biomass types examined.     

Ionoregulatory specializations for exceptional tolerance of ion-poor, acidic waters in the neon tetra (Paracheirodon innesi)

To better understand how fish are able to inhabit dilute waters of low pH, we examined ionoregulation in exceptionally acid-tolerant neon tetras (Paracheirodon innesi), which are native to the ion-poor, acidic Rio Negro, Amazon. Overall ion balance was unaffected by 2-wk exposure to pH 4.0 and 3.5. Measurements of unidirectional Na+ fluxes during exposure to pH 3.5 showed that tetras experienced only a mild, ionic disturbance of short duration (相似文献