Reconstituted Cl− pump protein: A novel ion(Cl−)-motive ATPase

Cl^– absorption by theAplysia californica foregut is effected through an active Cl^– transport mechanism located in the basolateral membrane of the epithelial absorptive cells. These basolateral membranes contain both Cl^–-stimulated ATPase and ATP-dependent Cl^– transport activities which can be incorporated into liposomes via reconstitution. Utilizing the proteoliposomal preparation, it was demonstrated that ATP, and its subsequent hydrolysis, Mg²⁺, Cl^–, and a pH optimum of 7.8 were required to generate maximal intraliposomal Cl^– accumulation, electrical negativity, and ATPase activity. Additionally, an inwardly-directed valinomycininduced K⁺ diffusion potential, making the liposome interior electrically positive, enhanced both ATP-driven Cl^– accumulation and electrical potential while an outwardly-directed valinomycininduced K⁺ diffusion potential, making the liposome interior electrically negative, decreased both ATP-driven Cl^– accumulation and electrical potential compared with proteoliposomes lacking the ionophore. Either orthovanadate orp-chloromercurobenzene sulfonate inhibited both the ATP-dependent intraliposomal Cl^– accumulation, intraliposomal negative potential difference, and also Cl^–-stimulated ATPase activity. Both aspects of Cl^– pump transport kinetics and its associated catalytic component kinetics were the first obtained utilizing a reconstituted transporter protein. These results strongly support the hypothesis that Cl^–-ATPase actively transports Cl^– by an electrogenic process.     

Efflux und Transport von Cl− und Rb+ in Maiswurzeln. Wirkung von Außenkonzentration,Ca++, EDTA und IES

Summary The efflux of ³⁶Cl and ⁸⁶Rb and the fluxes of these ions into the xylem were investigated using the device shown in Fig. 1.Efflux of ³⁶Cl is stimulated by external KCl while transport into the xylem is inhibited. Stimulation of the efflux appears to be stronger than inhibition of the transport.The stimulation of the efflux of ³⁶Cl was also observed with roots of intact seedlings.Assuming that the mode of transfer of Cl^– into the xylem (flux 3, Fig. 8) is diffusion exhibiting a linear isotherm (Luttge and Laties, 1966), these results suggest that the primary action of external salts is on the efflux across the plasma-lemma (Weigl, 1967, 1968). We were unable, however, to find a linear relationship between concentration and rate of chloride transport to the shoots of intact seedlings.With respect to the mode of ion transfer to the xylem (Weigl and Lüttge, 1965; Luttge and Laties, 1966) we have to be aware of the following facts:A linear isotherm cannot be taken to signify diffusive permeation (Torii and Laties, 1966; Luttge and Laties, 1966). If the Michaelis constant is extremely high relative to the ion concentration, the relationship between the ion concentration and the rate of a metabolic or mediated transport approaches linearity.The isotherm of the transport into the xylem may primarily reflect the difference of two large fluxes (4 and 5; Fig. 8).The transport data of Luttge and Laties (1966) need not be presented as a straight line (Fig. 6).If at high external ion concentrations the ratio of the ion concentration in the exudation sap to the external ion concentration approaches unity, diffusive permeation into the stele is still not proved to be the mode of migration, since at high stelar ion concentration flux 6 tends to become equal to flux 3.Considerations on radial ion transfer into the xylem depend on contemporary knowledge of the location of transport systems. Cl^–-uptake into root tips (2 mm) from solutions of 1–10 mM KCl did not exhibit a linear isotherm. These results are unpublished since the discrepancy to the results of Torii and Laties (1966) may be due to a higher content of vacuoles in our root tips. We feel it unlikely, however, that a linear isotherm of Cl^–-uptake into root tips is adequately explained by assuming that it is due to a lack of vacuoles while the sensibility to inhibitors is assumed to be due to the presence of vacuoles in root tips.Transport of Cl^– into the xylem is susceptible to inhibitors of oxydative phosphorylation, suggesting that this process, even at high external ion concentrations, is dependent on metabolic energy in contrast to the passive efflux from the cortical cells across the plasmalemma into the environment of the root. The precise location of the metabolic step(s) on the pathway of ions from the environment of the root to the xylem is unknown.The observed effects of Ca⁺⁺, EDTA and IAA may be considered in relation to the theory that auxin exerts its influence on growth by altering the diffusion potential across cell membranes (Brauner and Diemer, 1967). Growth is susceptible to the effect of Ca⁺⁺ and EDTA (Adamson, 1962; Setterfield, 1963; Thimann, 1963). Nevertheless, since IAA exerts no influence on ion fluxes in corn roots, it is not clear whether IAA really exerts its influence on growth by altering the diffusion potential across plant cell membranes. We might be dealing with occasional effects of secondary importance.     

Differences between Effects of Undissociated and Anionic 2,4-Dinitrophenol on Permeability of Barley Roots

Effects of 2,4-dinitrophenol (DNP) and several other substituted phenols on permeability of barley roots (Hordeum vulgare var. Trebi) to ions were assayed as a function of pH and phenol concentration. Solutions containing 0.1 micromolar undissociated DNP increase the permeability of barley root cells to small ions such as K⁺, Na⁺, Ca²⁺, and Cl⁻ with no inhibition of respiration. Undissociated forms of the other phenols increase permeability also, but they are less effective than DNP. Only the undissociated DNP is effective. Anionic DNP does not increase permeability or inhibit ion uptake, although it is the major species accumulated by the roots, both at pH 5 and pH 7. At pH 7, in contrast to pH 5, 10 micromolar DNP has no effect on ion permeability of barley roots yet it uncouples oxidative phosphorylation of barley root mitochondria. This indicates that the all too common use of DNP as a test for active transport or involvement of ATP synthesis can be misleading.     

Effect of Metabolic Inhibitors on Membrane Potential and Ion Conductance of Rat Astrocytes

1. The aim of this study was to elucidate the effect of metabolic inhibition on the membrane potential and ion conductance of rat astrocytes. The metabolic inhibitors investigated were dinitrophenol (DNP), carbonyl cyanide p-trifluoromethoxyphenyl hydrazone (FCCP), cyanide, and oligomycin.2. Primary cultures of astroglial cells from newborn rat cerebral cortex were cultivated for 13–20 days on chamber slides. The effect of metabolic inhibitors on the cellular ATP concentration was estimated from the decrease in peak chemiluminescence from the luciferin/luciferase reaction. The membrane potential and ion conductances were measured from whole-cell recordings with the patch-clamp technique.3. After 2.0 min of incubation ATP decreased from the control level to 43%with cyanide (2 mM), 58% with DNP (1 mM), 47% with FCCP (1 M), and 69% with oligomycin (10 M).4. Under normal conditions V was –74.4±1.0 mV. DNP and FCCP both caused a rapid and reversible depolarization equivalent to a shift in the I/V curve of 8.2±1.3 and 19.7±3.8 mV, respectively. DNP decreased the slope conductance (g) by 22.1% but FCCP had no significant effect on g. In contrast, neither oligomycin nor cyanide had any significant effect on the I/V curve.5. Tetraethylammonium (TEA; 10 mM) depolarized the cells by 7.1±2.0 mV but had no significant effect on g. In the presence of TEA, DNP caused a depolarization of 52.8±3.5 mV and increased g by 45.5±9.6%. The action of FCCP was not affected by the presence of TEA.6. Perfusion of the astrocytes with a Cl^– free solution inhibited the action of DNP and FCCP. Thus the depolarization was only 4.2±1.5mV in DNP and 3.7±0.3 mV in FCCP, which were significantly smaller effects than in the presence of a high intracellular [Cl^–].7. Block of tentative K_ATP channels with tolbutamide (1 mM) or Cl^– channels with Zn²⁺ (1 mM) did not inhibit the depolarization caused by DNP or FCCP.8. In conclusion, DNP and FCCP have specific effects on the plasmalemma in rat astrocytes which may be due to opening of Cl^– channels. This effect was not seen with cyanide or oligomycin and should be considered as a possible complication when DNP and FCCP are used for metabolic inhibition.     

Movement of Ions and Electrogenesis in Higher Plant Cells

During the past 10 years considerable information has accumulatedon the electrochemical relationships of higher plant cells duringtransport of mineral ions. Using the Nernst equation as a criterion,none of eight ions (K⁺, Na⁺, Ca⁺⁺, Mg⁺⁺, NO₃^–, Cl^–,H₂PO₄^–, and SO₄^–) is in a passive equilibrium. Na⁺,Ca⁺⁺, and Mg⁺⁺ are subject to an exclusion mechanism, and allof the anions appear to be pumped inwardly. K⁺ apparently approachesan electrochemical balance under certain conditions but probablyis actively accumulated. Compartmental analyses giving estimatesof amounts in the cytoplasm and vacuole and of unidirectionalfluxes permit application of the Ussing flux-ratio equation.The criterion in oat coleoptile cells suggests that at the plasmalemmaNa⁺ is pumped out while K⁺ and Cl^– are pumped in. K⁺ andCl^– appear to be coupled in active transport across thetonoplast into the vacuole. Good evidence has been found thatthe cell's electropotential arises from an electrogenic pump:CN^– (cyanide) and DNP (dinitrophenol) reversibly blockthe potential and ionic transport; cell potentials are higherthan can be accounted for by diffusion; the responses of respirationand potential to the concentration of CN^– are nearly parallel;and CN^– inhibited tissue approaches a fit to the Goldmanconstant field equation. Future objectives should be identificationof the ion, or ions, subject to the electrogenic pump and discoveryof the immediate energy source.     

Competence of the pollen of wild species and the cultivar of tomato to affect fertilization at low temperature

Summary The competitive ability of the pollen of wild tomato species (Solanum pennellii, Lycopersicum hirsutum and L. minutum) and a cultivar of tomato to affect fertilization at low temperature was investigated. Pollen grains of wild species were mixed with those of the cultivar and pollinated onto the stigma of the cultivar. The number of seedlings resembling the wild species, excluding L. minutum, were significantly higher when the plants were maintained at a low temperature (8°–12° C) than when they were maintained at a normal temperature (22°–28° C). This indicates that the pollen of S. pennellii and L. hirsutum wild species can compete better with pollen of the cultivar at a low temperature, while there was no change in the competitive ability of L. minutum pollen under these conditions.     

Effect of energy deprivation on intracellular transport and secretion of thyroglobulin

Summary The effect of energy deprivation on the intracellular transport and secretion of thyroglobulin was studied in open follicles isolated from porcine thyroids. Follicles were pulse-labeled with ³H-leucine or ³H-galactose. Labeled thyroglobulin was secreted into the incubation medium where it was isolated by means of immunoprecipitation. Secretion was followed in chase incubations under various experimental conditions using CCCP (carbonyl-cyanide-mchlorophenylhydrazone) or DNP (dinitrophenol), both uncouplers of oxidative phosphorylation, or CN^–, which inhibits respiration. CCCP (1 M) was shown to inhibit exocytosis by about 80%, DNP (0.1–5 mM) by 45–85%, and CN^– (0.5–1.1 mM) by 5–55%. By combining CN^– with the ionophore monensin, which blocks transport through the Golgi complex but does not essentially interfere with exocytosis, evidence was obtained that CN^– also inhibits transport of thyroglobulin from the Golgi cisternae to the exocytic vesicles by 40%. Electron-miroscopic autoradiography of isolated thyroid lobes from the rat also indicated that transport of ³H-leucine label into the follicle lumen is inhibited in the presence of CCCP or CN^–. Intracellular ATP content was found to be about 40% of the control level in follicles incubated with CCCP (1 uM) or CN^– (0.9 mM). The results show that the transport of thyroglobulin from the Golgi complex to the exocytic vesicles as well as from the exocytic vesicles into the follicle lumen is dependent upon metabolic energy. The transport blocks are probably associated with inhibited membrane fusions and fissions.Abbreviations CCCP carbonylcyanide-m-chlorophenylhydrazone - FCCP carbonylcyanide-p-trifluoromethoxyphenylhydrazone - DNP dinitrophenol     

Effects of diclofop and diclofop-methyl on the membrane potentials of wheat and oat coleoptiles

Electrophysiological measurements were made on the mesophyll cells of wheat (Triticum aestivum L. cv Waldron) and oat (Avena sativa L. cv Garry) coleoptiles treated either with the herbicide diclofop-methyl (methyl 2-(4-(2′,4′-dichlorophenoxy)phenoxy)propanoate), or it's primary metabolite diclofop, (2-(4-(2′,4′-dichlorophenoxy)phenoxy)-propanoic acid). Application of a 100 micromolar solution of diclofop-methyl to wheat coleoptiles had little or no effect on the membrane potential (E_M), however in oat, E_M slowly depolarized to the diffusion potential (E_D). At pH 5.7, 100 micromolar diclofop rapidly abolished the electrogenic component of the membrane potential in both oat and wheat coleoptiles with half-times of 5 to 10 minutes and 15 to 20 minutes, respectively. The concentrations giving half-maximal depolarizations in wheat were 20 to 30 micromolar compared to 10 to 20 micromolar in oat. The depolarizing response was not due to a general increase in membrane permeability as judged from the E_M's response to changes in K⁺, Na⁺, Cl⁻, and SO₄²⁻, before and after treatment with diclofop and from its response to KCN treatment. In both plants, diclofop increased the membrane permeability to protons, making the E_M strongly dependent upon the external pH in the range of pH 5.5 to pH 8.5. The effects of diclofop can best be explained by its action as a specific proton ionophore that shuttles protons across the plasmalemma. The rapidity of the cell's response to both diclofop-methyl (15-20 minutes) and diclofop (2-5 minutes) makes the ionophoric activity a likely candidate for the earliest herbicidal event exhibited by these compounds.     

The transepithelial potential difference in the gills of the fiddler crab,Uca tangeri: Influence of some inhibitors

Summary Euryhaline Crustacea living in dilute media, counterbalance the salt loss by active absorption of NaCl across the gill epithelium. To investigate the mechanisms involved in salt absorption, transeptithelial potential difference (PD_te) was measured in isolated, perfused gills of the fiddler crab,Uca tangeri. The influence of some specific inhibitors of epithelial ion transport on the PD_te was tested.With symmetrical conditions on both sides of the epithelium, the posterior gills ofUca tangeri showed a spontaneous PD_te of +5 to +10 mV, that is an active transport potential which was positive on the bath side as referred to the hemolymph side. This potential decreased considerably after application of KCN or 2,4-dinitrophenol (DNP) to the perfusion saline.Omission of K⁺ from the perfusion saline or addition of ouabain led to a reversible drop of the PD_te, suggesting that the absorption of Na⁺ and also of Cl^– is driven by the (Na⁺+K⁺)ATPase located in the basolateral membrane of the epithelial cells.Perfusion of the hemolymph space with saline containing diphenylamine-2-carboxylate (DPC) or the loop diuretic furosemide resulted in a decrease of the PD_te.After application of amiloride to the bath saline the PD_te increased. Half-maximum response to amiloride was reached at a concentration of about 10^–5 mol·l^–1. This suggests that one of the Na⁺ pathways across the apical membrane may consist of Na⁺ channels.Abbreviations PD _te transepithelial potential difference - DPC diphenylamine-2-carboxylate - R _ps resistance of perfusate shunt - R _te transepithelial resistance - R _in input resistance - DNP 2,4-dinitrophenol Parts of this study have been reported at the 1st Congress of Comparative Physiology and Biochemistry, Liège 1984, and at the Vth European Colloquium on Renal Physiology, Frankfurt, 1985     

Intracellular redistribution of phytochrome in etiolated soybean (Glycine max L.) seedlings

The intracellular distribution of phytochrome in hypocotyl hooks of etiolated soybean (Glycine max L.) has been examined by immunofluorescence using a newly produced monoclonal antibody (Soy-1) directed to phytochrome purified from etiolated soybean shoots. Cortical cells in the hook region exhibit the strongest phytochrome-associated fluorescence, which is diffusely distributed throughout the cytosol in unirradiated, etiolated seedlings. A redistribution of immunocytochemically detectable hytochrome to discrete areas (sequestering) following irradiation with red light requires a few minutes at room temperature in soybean, whereas this redistribution is reversed rapidly following irradiation with far-red light. In contrast, sequestering in oat (Avena sativa L.) occurs within a few seconds (D. McCurdy and L. Pratt, 1986, Planta 167, 330–336) while its reversal by far-red light requires hours (J. M. Mackenzie Jr. et al., 1975, Proc. Natl. Acad. Sci. USA 72, 799–803). The time courses, however, of red-light-enhanced phytochrome pelletability and sequestering are similar for soybean as they are for oat. Thus, while these observations made with a dicotyledon are consistent with the previous conclusion derived from work with oat, namely that sequestering and enhanced pelletability are different manifestations of the same intracellular event, they are inconsistent with the hypothesis that either is a primary step in the mode of action of phytochrome.Abbreviations DIC differential interference contrast - FR far-red light - Ig immunoglobulin - Pfr, P far-red- and red-absorbing form of phytochrome, respectively - R red light This work was supported by National Science Foundation grant No. DCB-8703057.     

Ultrastructural and histochemical studies on guard cells

Serial thick sections of guard cells from Vicia faba L., Nicotiana tabacum L., Allium cepa L., Zea mays L. and Beta vulgaris L. were obtained systematically (600–800 nm) and viewed with the transmission electron microscope in an effort to demonstrate the presence or absence of a symplastic transport pathway within the stomatal complex. Eight to ten stomata from each species were examined, and no continuous plasmodesmata were found connecting guard cells to sister guard cells or to adjacent epidermal or subsidiary cells. Continuous plasmodesmata were observed in immature guard cells, but were sealed (truncated) during the development of the mature cell wall. Histochemical stains, phosphotungstic acid and silver methenamine, were used to demonstrate differentiation within the mature guard-cell wall. The structural differentiation of the stomatal apoplastic region is discussed in relation to fanctional specialization. Plasma-membrane elaborations or plasmalemmasomes were identified in the guard cells of Zea, and it is suggested that these structures may function in ion transport.Abbreviations PTA-HCl phosphotungstic acid and hydrochloric acid - SM silver methenamine - UA-LC uranyl acetate and lead citrate     

Intracellular sodium activity and sodium transport inNecturus gallbladder epithelium

Summary Ion-sensitive glass microelectrodes, conventional microelectrodes and isotope flux measurements were employed inNecturus gallbladder epithelium to study intracellular sodium activity, [Na] _i , electrical parameters of epithelial cells, and properties of active sodium transport. Mean control values were: [Na] _i : 9.2 to 12.1mm; transepithelial potential difference, _ms : –1.5 mV (lumen negative); basolateral cell membrane potential, _es : –62 mV (cell interior negative); sodium conductance of the luminal cell membrane,g _Na: 12 mho cm^–2; active transcellular sodium flux, 88 to 101 pmol cm^–2 sec^–1 (estimated as instantaneous short-circuit current). Replacement of luminal Na by K led to a decrease of the intracellular sodium activity at a rate commensurate to the rate of active sodium extrusion across the basolateral cell membrane. Mucosal application of amphotericin B resulted in an increase of the luminal membrane conductance, a rise of intracellular sodium activity, and an increase of short-circuit current and unidirectional mucosa to serosa sodium flux. Conclusions: (i) sodium transport across the basolateral membrane can proceed against a steeper chemical potential difference at a higher rate than encountered under control conditions; (ii) the luminal Na-conductance is too low to accommodate sodium influx at the rate of active basolateral sodium extrusion, suggesting involvement of an electrically silent luminal transport mechanism; (iii) sodium entry across the luminal membrane is the rate-limiting step of transcellular sodium transport and active sodium extrusion across the basolateral cell membrane is not saturated under control conditions.     

Uptake and Distribution of Stable Strontium in 26 Cultivars of Three Crop Species: Oats,Wheat, and Barley for Their Potential Use in Phytoremediation

The main objective of this study was to investigate the accumulation and distribution of strontium (Sr) in 26 cultivars of wheat (Triticum aestivum L.), husk oat (Avena sativa L) and naked oat (Avena nuda), and barley (Hordeum vulgare L.) for their potential use in phytoremediation.Sr levels had no effect on the accumulation of shoot biomass at tillering or at maturity. Mean shoot Sr concentration of naked oat and barley at tillering was significantly (P < 0.05) higher than that of wheat; Neimengkeyimai-1, a naked oat cultivar, had the highest Sr concentrations. At maturity, of four naked oat cultivars, Neimengkeyimai-1 had the highest Sr content at all measured Sr levels. Leaves had the highest Sr concentrations, followed by roots and straw, and then grain with the lowest. Mean enrichment coefficients from soil to shoots ranged from 0.521 to 1.343; the percentage of stable Sr removed from the soil to the shoots at harvest time was more than 1.4% after 120 days. Neimengkeyimai-1 could be used as a model for further research to find more effective cultivars; and naked oat plants could be selected for phytoremediation to clean up contaminated soil.     

Current-voltage curve of electrogenic Cl− pump predicts voltage-dependent Cl− efflux inAcetabularia

Summary The current-voltage relationship of carrier-mediated, passive and active ion transport systems with one charge-carrying pathway can exactly be described by a simple reaction kinetic model. This model consists of two carrier states (one inside, one outside) and two pairs (forwards and backwards) of rate constants: a voltage-dependent one, describing the transport of charge and a voltage-insensitive one, summarizing all the other (voltage-independent) reactions. For the electrogenic Cl^– pump inAcetabularia these four rate constants have been determined from electrical measurements of the current-voltage relationship of the pump (Gradmann, Hansen & Slayman, 1981;in: Electrogenic Ion Pumps, Academic Press, New York). The unidirectional Cl^– efflux through the pump can also be calculated by the availiable reaction kinetic parameters.³⁶Cl^– efflux experiments on singleAcetabularia cells with simultaneous electrical stimulation (action potentials) and recording, demonstrate the unidirectional Cl^– efflux to depend on the membrane potential. After subtraction of an efflux portion which bypasses the pump, agreement is found between the measured flux-voltage relationship and the theoretical one as obtained from the reaction kinetic model and its parameters from the electrical data.     

The measurement of membrane potential using optical indicators

Conclusions Optical methods have become established as a major experimental protocol for following membrane potential. They can provide a rapid, continuous record of the potential and have a very wide applicability. However, when used to make quantitative assertions about membrane potential, optical methods have a number of weaknesses. Even the most reliable calibration procedures depend on accurate evaluation of a small number, namely the internal ion concentration, in a large background, that is total ion levels. However, a consensus seems to be emerging that the plasma membrane potential of non-excitable cells nevertheless has considerable magnitude: typical values are –60 mV for lymphocytes (Rinket al., 1980), –20 to –100 mV, depending on metabolic load, for Ehrlich ascites tumour cells (Philo & Eddy, 1978; but see also Smith & Robinson, 1980), and –66 to –86 mV for neutrophils (Tathamet al., 1980). In our own experiments using monolayer cultures of cells grown to confluence (Bashfordet al., 1981) the potential across the plasma membrane is of the order of –100 mV (see Fig. 2). Membrane potentials of similar magnitude have been found using ion-distribution methods and microelectrodes in neuroblastoma cells and lymphocytes (Deutschet al., 1979a,b). In the latter studies ions of different charge were used to provide upper and lower estimates of the potential, the presumed effects of binding being very different for anions and cations. A similar approach, in this case the use of optical indicators of different charge, has been taken by Rinket al. (1980), and this would seem to be one way in which to diminish the uncertainties involved in dye calibration. Unfortunately many anions, particularly oxonols, form complexes with valinomycin (Lavie & Sonenberg, 1980; Rinket al., 1980), although we have found no evidence for such a complex with bis isoxazolone oxonols (J.C. Smith and C.L. Bashford, unpublished observations). It is apparent that calibration procedures not dependent on valinomycin should be sought in order to establish optical methods as a quantitative approach to the study of membrane potential.     

Compartments and Fluxes of K, NA, and CL in Avena Coleoptile Cells

By the compartmental analysis method of MacRobbie and Dainty, and Pitman, estimates of K⁺, Na⁺, and Cl⁻ concentrations and fluxes were obtained for the cytoplasm and vacuole of coleoptile cells of oat, Avena sativa L. cv. Victory. Double labeling was used in experiments with ⁴²K plus ²²Na and with ⁴²K plus ³⁶Cl in a complete nutrient solution. At the plasmalemma, according to the Ussing-Teorell flux ratio equation, Na⁺ is pumped out and Cl⁻ is actively transported inward. The results with K⁺ are less conclusive, but it is probably pumped in. At the tonoplast there is an active inward transport of Na⁺ and probably of K⁺, but the status of Cl⁻ is uncertain, depending upon whether there is an electrical potential difference between the cytoplasm and vacuole. The results suggest that ion selectivity resides mostly in the plasmalemma. Possible errors in the estimates and interpretations are discussed.     

Transport of malic acid in Leuconostoc oenos strains defective in malolactic fermentation: a model to evaluate the kinetic parameters

Two Leuconostoc oenos mutant strains unable to metabolize malic acid were differentiated by [U-¹⁴C]-labelled L-malate transport assays into a malolactic-enzyme-deficient mutant and a malate-transport-defective mutant. A mathematical analysis of the data from L-malic acid uptake at three pH values (5.2, 4.5, and 3.2) in the malolactic-enzyme-deficient strains suggest two simultaneous uptake mechanisms, presumably a carrier-mediated transport and a passive diffusion for the anionic and the undissociated forms of the acid, respectively. The apparent affinity constant (K _m t) and the maximal rate (V _m t) values for L-malate active transport were, 12 mM and 43 mol L-malate·mg^–1·s^–1, respectively. Active transport was constitutive and strongly inhibited by protonophores and by ATPase inhibitors. L-Lactic acid appeared to inhibit L-malic acid transport, suggesting an L-lactate/L-malate exchange. At pH values of 4.5 or above, the passive diffusion of L-malic acid was negligible. However, at pH 3.2, the mean pH of wine, the permeability of the cells to the undissociated acid by simple diffusion could represent more than 50% of total L-malic acid uptake, with a diffusion constant (K _D) of 0.1 s^–1. Correspondence to: C. Divies     

Coupling of ion transport in green cells ofAtriplex spongiosa leaves to energy sources in the light and in the dark

Summary The coupling of ion transport to energy sources in the light and in the dark in green cells ofAtriplex spongiosa leaves was investigated using light of different qualities, an inhibitor of electron transport (dichlorophenyl dimethyl urea), and an uncoupler (p-CF₃O-carbonyl cyanide phenylhydrazone). Two different mechanisms of ion uptake were, distinguished. (1) A light-dependent Cl^– pump which is linked to light-dependent K⁺ uptake. The energy for this pump is probably derived from photosynthetic electron transport or from nicotinamide adenine dinucleotide phosphate, reduced form. This mechanism is dichlorophenyl dimethyl urea-sensitive and enhanced by uncouplers. (2) A mechanism independent of light, which operates at the same rate in the light and in the dark. This mechanism is sensitive to uncouplers. It is probably aK–Na exchange mechanism since K⁺ and Cl^– uptake and a small net uptake of H⁺ are balanced by Na⁺ loss.     

Bicarbonate assimilation by fresh-water charophytes and higher plants: I. Membrane transport of bicarbonate ions is not proven

Summary Although it is generally believed thatChara and some fresh-water angiosperms transport bicarbonate ions inwards across their plasma membranes, there has been no direct demonstration of such transport in these plants. The (indirect) arguments for their transporting HCO ₃ ^– are arguments against the inward diffusion of CO₂ at the observed rates. They rest on calculations of the equilibrium concentration of CO₂ or of the maximum rate at which CO₂ might be produced from HCO ₃ ^– at the pH of the medium outside the cells. SinceChara acidifies the medium over about half the cell surface during C assimilation, these calculations have been based on questionable premises.We propose a model forChara in which the acidification is attributed to active efflux of H⁺, and we calculate that both the equilibrium concentration of CO₂ and its rate of production outside the cell can be high enough to support the observed rates of C assimilation, without postulating transport of the species HCO ₃ ^– or H₂CO₃.Calculations are presented also for alternative models in which there is membrane transport of HCO ₃ ^– . The first includes symport of H⁺ with HCO ₃ ^– , again dependent on active H⁺ efflux. In the second, there is active electrogenic transport of HCO ₃ ^– . In this case the low pH in the medium outside the cell is caused by the dissociation of H₂CO₃ produced by hydration of CO₂ which leaks from the cell cytoplasm.All three models are consistent with the observations to date, but the first is more economical of postulates. It can also explain the apparent transport of HCO ₃ ^– by fresh-water angiosperms such asEgeria.     

Chemical evolution of dehydrogenases: Amino acid pentacyanoferrate (II) as possible intermediates

Dehydrogenation of ascorbic acid and reduced nicotinamide adenine dinucleotide (NADH) with methylene blue using complexes of the type [Fe(II)(CN)₅ (L)] ^n– (wheren=3 or 4; L=glycine, histidine, imidazole, and triglycine) as catalyst have been studied at pH 9.18. Similar kinetic behavior was observed for the dehydrogenation of ascorbic acid as well as for NADH; both reactions showed first order dependency on the substrates. First order dependence was observed only at lower concentrations of methylene blue; at higher concentrations of methylene blue, the reactions were independent of methylene blue. The order with respect to catalyst varied between 0.3–0.5. A tentative mechanism which conforms to the observed kinetics has been proposed. It is believed that on the primitive earth when the reducing potential of the atmosphere was not high enough, lower oxidation state iron complexes like [Fe(II)(CN)₅(L)] ^n– might have been involved in dehydrogenase-type activity.