Measurement of proton-linked transport activities in pyranine loaded chloroplast inner envelope vesicles

A method has been devised for loading chloroplast inner envelope vesicles prepared from pea (Pisum sativum L. var Progress No. 9) or spinach (Spinacia oleracea L.) with 8-hydroxypyrene-1,3,6-trisulfonate (pyranine), a membrane impermeant, fluorescent pH indicator. Two known proton-linked transport activities of the inner envelope, glycolate/H⁺ co-transport and phosphate/phosphoglycerate exchange have been shown to cause quenching of the internal pyranine fluorescence. This represents the first demonstration that these vesicles are sealed and competent for transport measurements. The technique, as it now stands, is essentially qualitative. It does, however, offer advantages over transport measurements with intact chloroplasts, for example compatibility with rapid mixing techniques and accessibility of the transport proteins to antibodies.     

Nitrite Transport in Chloroplast Inner Envelope Vesicles (I. Direct Measurement of Proton-Linked Transport)

Chloroplast inner envelope membrane vesicles that are loaded with the pH-sensitive fluorophore, pyranine, show rapid internal acidification when nitrite is added. Acidification is dependent upon [delta]pH, with the inside of vesicles being alkaline with respect to the outside. The rate of vesicle acidification was directly proportional to the concentration of nitrite that was added and the imposed pH difference across the membrane. In contrast, added nitrate had no effect on vesicle acidification. Nitrite also caused acidification of asolectin vesicles. The extent of vesicle acidification is dependent on the internal volume of vesicles. Inner envelope and asolectin vesicles that were prepared by extrusion were approximately the same size, allowing them to be compared when the final extent of acidification, measured after the pH gradient had collapsed, was similar. The rate of nitrite-dependent acidification was similar in these two preparations at any single nitrite concentration. These results indicate that nitrite movement occurs by rapid diffusion across membranes as nitrous acid, and this movement is dependent on a proton gradient across the lipid bilayer. Under conditions approximating those in vivo, the rate of diffusion of nitrous acid far exceeds that of nitrite reduction within chloroplasts.     

Effects of Magnesium on Intact Chloroplasts: I. EVIDENCE FOR ACTIVATION OF (SODIUM) POTASSIUM/PROTON EXCHANGE ACROSS THE CHLOROPLAST ENVELOPE

Exogenous Mg²⁺ (2 millimolar) altered the stromal pH of intact spinach chloroplasts. Without added KCl in the medium, Mg²⁺ decreased the stromal pH in the light by approximately 0.3 pH unit. External KCl (25 millimolar) largely prevented the acidification caused by Mg²⁺. Effects on the stromal pH were not caused by changes in H⁺ pumping across the thylakoid membrane because Mg²⁺ had no effect on the light-induced quenching of atebrin fluorescence by intact chloroplasts. However, Mg²⁺ affected H⁺ fluxes across the envelope. Addition of Mg²⁺ to intact chloroplasts in the dark caused a significant acidification of the medium that was dependent on the presence of K⁺.     

Solubilization, partial purification, and reconstitution of the glycolate/glycerate transporter from chloroplast inner envelope membranes

The glycolate/glycerate transporter of spinach (Spinacia oleracea L.) chloroplast inner envelope membranes was solubilized by treatment of the membranes with sodium cholate. Mixtures of the cholate extracts and soy asolectin were subjected to gel filtration to remove the detergent. The reconstituted vesicles were frozen, thawed, and sonicated in a buffer that contained 10 millimolar d-glycerate and, usually, [³H]sucrose as an internal space indicator. The dilution of the vesicles into a medium that contained 0.4 millimolar [¹⁴C]d-glycerate resulted in a rapid accumulation of labeled glycerate, followed by a much slower loss of [¹⁴C]d-glycerate from the vesicles. This behavior is characteristic of counterflow. The accumulation of [¹⁴C]d-glycerate was strongly inhibited by HgCl₂, which blocks glycolate/glycerate transport in intact chloroplasts. In the absence of proton ionophores, the extent of [¹⁴C]glycolate accumulation under similar conditions was much greater than that of [¹⁴C]d-glycerate. External glycolate inhibited d-glycerate counterflow and external d-glycerate inhibited glycolate counterflow. The external pH dependence of the efflux of [¹⁴C]d-glycerate accumulated in vesicles by counterflow and its inhibition by external l-mandelate are characteristics displayed by glycolate transport in intact chloroplasts. Partial purification of the transporter was achieved by glycerol gradient centrifugation. The solubilized glycolate and glycerate counterflow activities, assayed by reconstitution into vesicles, were found to sediment similarly.     

Direct measurement of ferrous ion transport across membranes using a sensitive fluorometric assay

The fluorophore, Phen Green SK (PGSK), was assessed for its suitability to be used in an assay for ferrous ion transport into membrane vesicles. The long wavelengths of excitation and emission (506 and 520 nm, respectively) enable PGSK fluorescence to be detected in membranes, such as the chloroplast inner envelope, that contain high levels of carotenoids which absorb light at lower wavelengths. At low concentrations of Fe2+, less than 3 microM, the interaction between PGSK and Fe2+ appears to result in both static and dynamic quenching of the PGSK fluorescence. The characteristics of this quenching were used to develop a calibration curve to determine the concentration of free Fe2+ at these low concentrations. Pronounced quenching of PGSK fluorescence entrapped within chloroplast inner envelope membrane vesicles was observed when Fe2+ was added. The extent of quenching of PGSK fluorescence trapped inside asolectin vesicles on Fe2+ addition was much less. The kinetics of the quenching of PGSK fluorescence by Fe2+ in vesicles was quite different from that for PGSK and Fe2+ in solution. Using the calibration curve developed for interaction of PGSK and low Fe2+ concentrations the initial rates of iron transport could be determined for the chloroplast inner envelope membranes.     

Ferrous ion transport across chloroplast inner envelope membranes

The initial rate of Fe(2+) movement across the inner envelope membrane of pea (Pisum sativum) chloroplasts was directly measured by stopped-flow spectrofluorometry using membrane vesicles loaded with the Fe(2+)-sensitive fluorophore, Phen Green SK. The rate of Fe(2+) transport was rapid, coming to equilibrium within 3s. The maximal rate and concentration dependence of Fe(2+) transport in predominantly right-side-out vesicles were nearly equivalent to those measured in largely inside-out vesicles. Fe(2+) transport was stimulated by an inwardly directed electrochemical proton gradient across right-side-out vesicles, an effect that was diminished by the addition of valinomycin in the presence of K(+). Fe(2+) transport was inhibited by Zn(2+), in a competitive manner, as well as by Cu(2+) and Mn(2+). These results indicate that inward-directed Fe(2+) transport across the chloroplast inner envelope occurs by a potential-stimulated uniport mechanism.     

Protonmotive force and photophosphorylation in single swollen thylakoid vesicles

Swollen vesicles generally 40 micron in diameter were prepared from spinach chloroplasts. These vesicles appear to originate from thylakoids. The present study reports results obtained with individual vesicles using micromanipulative procedures. The electric potential across the membrane was measured with microelectrodes and the pH of the internal space was calculated from the fluorescence of the pH indicator pyranine. The individual vesicles photophosphorylate as measured with luciferin-luciferase. Impalement with microelectrodes did not affect the ability of individual vesicles to photophosphorylate. However, there was no significant membrane potential either with continuous illumination or light flashes. In contrast, we found a delta pH of 3.7 under photophosphorylative conditions and the incubation with the appropriate buffers blocked photophosphorylation presumably by preventing formation of a pH gradient. We propose that, in these vesicles, the membrane potential plays no role in photophosphorylation, whereas a pH gradient is obligatory.     

Transport du sulfate à travers la double membrane limitante, ou enveloppe, des chloroplastes d'épinard

Evidence is presented for low rates of carriermediated uptake of sulphate, thiosulphate and sulphite into the stroma of the C3 plant Spinacia oleracea. Uptake of sulphate in the dark was followed using two techniques (1) uptake of sulphate [³⁵S] as determined by silicon oil centrifugal filtration and (2) uptake as indicated by inhibition of CO₂-dependant O₂ evolution rates after addition of sulphate.Sulphate, thiosulphate and sulphite were transported across the envelope leading to an accumulation in the chloroplasts. Sulphate transport had saturation kinetics of the Michaelis-Menten type (Vmax : 25 μmoles . mg⁻¹ chl . h⁻¹ at 22°C ; Km : 2.5 mM). The rate of transport for sulphate was not influenced either by illumination or pH change in the external medium. Phosphate was a competitive inhibitor of sulphate uptake by chloroplasts (Ki : 0.7 mM, fig. 1). The rate of transport for phosphate appeared to be much higher than for sulphate. When the chloroplasts were pre-loaded with labelled sulphate, radioactivity was rapidly released after addition of phosphate into the external medium. Consequently, the transport of sulphate occurs by a strict counter-exchange : for each molecule of sulphate entering the chloroplast, one molecule of phosphate leaves the stroma, and vice-versa.The uptake of sulphate by isolated intact chloroplasts exchanging for internal free phosphate induced a lower rate of photophosphorylation, which in turn inhibited CO₂-dependent O₂ evolution.The presence, on the inner membrane of the chloroplast envelope, of a specific sulphate carrier, distinct from the phosphate translocator, is discussed.     

Multiple Effects of Dithiothreitol on Nonphotochemical Fluorescence Quenching in Intact Chloroplasts (Influence on Violaxanthin De-epoxidase and Ascorbate Peroxidase Activity)

Reversible nonphotochemical fluorescence quenching depends on thylakoid lumen acidification and violaxanthin de-epoxidation and is correlated with photoprotection of photosynthesis. The O2-dependent electron flow in the coupled Mehler-ascorbate peroxidase reaction (MP-reaction) mediates the electron flow necessary for lumen acidification and violaxanthin de-epoxidation in isolated, intact chloroplasts. Inhibition of violaxanthin de-epoxidation by dithiothreitol (DTT) was correlated with suppression of fluorescence quenching. In addition, DTT was also found to suppress fluorescence quenching due to inhibition of ascorbate peroxidase activity, a main enzyme of the MP-reaction, even in the presence of zeaxanthin. In intact, non-CO2-fixing chloroplasts, violaxanthin and antheraxanthin de-epoxidation and the ascorbate peroxidase activity show different sensitivities to increasing DTT concentrations. Violaxanthin de-epoxidase activity, measured as the sum of zeaxanthin and antheraxanthin formed, was inhibited with an inhibitor concentration for 50% inhibition (I50) of 0.35 mM DTT. In contrast, inhibition of the O2-dependent electron flow and corresponding lumen acidification occurred with higher I50 values of 2.5 and 3 mM DTT, respectively, and was attributed to inhibition of ascorbate peroxidase activity (I50 = 2 mM DTT). Accordingly, the DTT-induced inhibition of the nigericin-sensitive nonphotochemical fluorescence quenching was correlated linearly with the decreasing concentrations of zeaxanthin and antheraxanthin and was almost unaffected by DTT inhibition of the MP-reaction and correlated [delta]pH. The nigericin-insensitive, photoinhibitory kind of nonphotochemical fluorescence quenching up to 1 mM was mainly correlated with inhibition of violaxanthin de-epoxidation. At higher DTT concentrations, it was attributed to inhibition of both violaxanthin de-epoxidation and MP-reaction. The results show that DTT has multiple, but distinguishable, effects on nonphotochemical fluorescence quenching in isolated chloroplasts, necessitating careful interpretation.     

Uptake of l-Ascorbate by Intact Spinach Chloroplasts

Uptake of l-[1-¹⁴C]ascorbate by intact ascorbate-free spinach (Spinacia oleracea L. cv Vital^r) chloroplasts has been investigated using the technique of silicone oil filtering. Rates greater than 100 micromoles per milligram chlorophyll per hour (external concentration, 10 millimolar) of ascorbate transport were observed. Ascorbate uptake into the sorbitol-impermeable space (stroma) followed the Michaelis-Menten-type characteristic for substrate saturation. A K_m of 18 to 40 millimolar was determined. Transport of ascorbate across the chloroplast envelope resulted in an equilibrium of the ascorbate concentrations between stroma and medium. A pH optimum of 7.0 to 7.5 and the lack of alkalization of the medium upon ascorbate uptake suggest that only the monovalent ascorbate anion is able to cross the chloroplast envelope. The activation energy of ascorbate uptake was determined to be 65.8 kilojoules (16 kilocalories) per mole (8 to 20°C). Interference of ascorbate transport with substrates of the phosphate or dicarboxylate translocator could not be detected, but didehydroascorbate was a competitive inhibitor. Preloading of chloroplasts with didehydroascorbate resulted in an increase of V_max but did not change the K_m for ascorbate. Millimolar concentrations of the sulfhydryl reagent p-chloromercuriphenyl sulfonate inhibited ascorbate uptake. The data are interpreted in terms of ascorbate uptake into chloroplasts by the mechanism of facilitated diffusion mediated by a specific translocator.     

Localization of phosphatidylcholine in outer envelope membrane of spinach chloroplasts

We have examined the effects of phospholipase C from Bacillus cereus on the extent of phospholipid hydrolysis in envelope membrane vesicles and in intact chloroplasts. When isolated envelope vesicles were incubated in presence of phospholipase C, phosphatidylcholine and phosphatidylglycerol, but not phosphatidylinositol, were totally converted into diacylglycerol if they were available to the enzyme (i.e., when the vesicles were sonicated in presence of phospholipase C). These experiments demonstrate that phospholipase C can be used to probe the availability of phosphatidylcholine and phosphatidylglycerol in the cytosolic leaflet of the outer envelope membrane from spinach chloroplasts. When isolated, purified, intact chloroplasts were incubated with low amounts of phospholipase C (0.3 U/mg chlorophyll) under very mild conditions (12 degrees C for 1 min), greater than 80% of phosphatidylcholine molecules and almost none of phosphatidylglycerol molecules were hydrolyzed. Since we have also demonstrated, by using several different methods (phase-contrast and electron microscopy, immunochemical and electrophoretic analyses) that isolated spinach chloroplasts, and especially their outer envelope membrane, remained intact after mild treatment with phospholipase C, we can conclude that there is a marked asymmetric distribution of phospholipids across the outer envelope membrane of spinach chloroplasts. Phosphatidylcholine, the major polar lipid of the outer envelope membrane, is almost entirely accessible from the cytosolic side of the membrane and therefore is probably localized in the outer leaflet of the outer envelope bilayer. On the contrary, phosphatidylglycerol, the major polar lipid in the inner envelope membrane and the thylakoids, is probably not accessible to phospholipase C from the cytosol and therefore is probably localized mostly in the inner leaflet of the outer envelope membrane and in the other chloroplast membranes.     

Metabolic regulation by pH gradients. Inhibition of photosynthesis by indirect proton transfer across the chloroplast envelope

Anions of several weak acids inhibited photosynthesis in isolated spinach chloroplasts. Inhibition was drastic at low pH and weak or absent at high pH. Glyoxylate was particularly effective and inhibition decreased in the order: glyoxylate, nitrite, glycerate, formate, hydroxypyruvate, glycolate, propionate, acetate, pyruvate. These anions operated as indirect proton shuttles across the chloroplast envelope. They compensated active proton fluxes into the medium, minimized gradients in proton activity across the chloroplast envelope, and so prevented light-dependent stroma alkalization. This caused inhibition of sugar bisphosphatases which are known to be pH-regulated. At concentrations that caused potosynthesis inhibition, the proton shuttles were not effective in decreasing the proton gradient across the thylakoids. Some anions also inhibited fructose-bisphosphatase directly, when present at concentratins higher than needed for photosynthesis inhibition.     

Pyranine (8-hydroxy-1,3,6-pyrenetrisulfonate) as a probe of internal aqueous hydrogen ion concentration in phospholipid vesicles

The fluorescence intensity (at 510 nm) of the hydrophilic pyrene analogue 8-hydroxy-1,3,6-pyrenetrisulfonate (pyranine) is strongly dependent upon the degree of ionization of the 8-hydroxyl group (pKa = 7.2) and hence upon the medium pH, over the range pH 6--10. Because of its polyanionic character, pyranine does not bind significantly to phospholipid vesicles having a net anionic surface charge. As a result, it is possible to form vesicles in the presence of pyranine which, after removal of external probe by gel filtration, contain pyranine entrapped within the internal aqueous compartment. Once entrapped, pyranine does not readily leak out of the vesicles. Because the fluorescence properties of entrapped pyranine resemble closely the properties of bulk pyranine solution with respect to pH sensitivity, pyranine can be used as a reliable reporter of aqueous pH changes within anionic vesicles. When HCl is rapidly added to a suspension of unilamellar soybean phospholipid (asolectin) vesicles preincubated at alkaline pH, a biphasic decrease in the pH of the vesicle inner aqueous compartment is observed. An initial, very rapid and electrically uncompensated H+ influx (t 1/2 less than 1 s) results in the generation of a transmembrane electric potential opposing further H+ influx. This leads to the development of a much slower (t 1/2 approximately equal to 5 min), valinomycin-sensitive, proton--counterion exchange which continues until the proton concentration gradient is eliminated. Similar results were obtained in asolectin vesicles prepared by detergent dilution, in sonicated egg phosphatidylcholine vesicles, and in multilamellar asolectin liposomes. The rather high permeability of soybean lipid membranes to H+ is surprising in view of the widespread use of these lipids for the reconstitution of membrane proteins which are thought to generate or utilize H+ ion gradients in energy transduction reactions.     

Apparent Inhibition of Chloroplast Protein Import by Cold Temperatures Is Due to Energetic Considerations Not Membrane Fluidity

The transport of proteins across virtually all types of biological membranes has been reported to be inhibited by low temperatures. Paradoxically, plants are able to acclimate to growth at temperatures below which protein import into chloroplasts is known to be blocked. In examining this incongruity, we made a number of unexpected observations. First, chloroplasts isolated from plants grown at 7/1[deg]C in light/dark and from plants grown at 25[deg]C were able to import proteins with the same efficiency over a temperature range from 5 to 21[deg]C, indicating that no functional adaptation had taken place in the protein import machinery of chloroplasts in these cold-grown plants. Second, chloroplasts from warm-grown plants were able to take up proteins at temperatures as low as 4[deg]C provided that they were illuminated. We determined that light mediates the import process at 5[deg]C by driving ATP synthesis in the stroma, the site of its utilization during protein transport. Direct measurement of the envelope phase transition temperature as well as the activity of the ATP/ADP translocator in the inner envelope membrane at 5 and 25[deg]C demonstrated that the cold block of protein import into chloroplasts observed in vitro is due primarily to energetic considerations and not to decreased membrane fluidity.     

Direct Measurement of Calcium Transport across Chloroplast Inner-Envelope Vesicles

The initial rate of Ca²⁺ movement across the inner-envelope membrane of pea (Pisum sativum L.) chloroplasts was directly measured by stopped-flow spectrofluorometry using membrane vesicles loaded with the Ca²⁺-sensitive fluorophore fura-2. Calibration of fura-2 fluorescence was achieved by combining a ratiometric method with Ca²⁺-selective minielectrodes to determine pCa values. The initial rate of Ca²⁺ influx in predominantly right-side-out inner-envelope membrane vesicles was greater than that in largely inside-out vesicles. Ca²⁺ movement was stimulated by an inwardly directed electrochemical proton gradient across the membrane vesicles, an effect that was diminished by the addition of valinomycin in the presence of K⁺. In addition, Ca²⁺ was shown to move across the membrane vesicles in the presence of a K⁺ diffusion potential gradient. The potential-stimulated rate of Ca²⁺ transport was slightly inhibited by diltiazem and greatly inhibited by ruthenium red. Other pharmacological agents such as LaCl₃, verapamil, and nifedipine had little or no effect. These results indicate that Ca²⁺ transport across the chloroplast inner envelope can occur by a potential-stimulated uniport mechanism.     

The 'delta pH'-probe 9-aminoacridine: response time, binding behaviour and dimerization at the membrane

The fluorescence quenching of 9-aminoacridine (9-AA) after imposition of a transmembrane pH gradient (inside acidic) in liposomes has been investigated for a number of different lipid systems. The initial fluorescence decrease after a rapid pH jump, induced in the extravesicular medium by a stopped-flow mixing technique, was ascribed to a response of 9-AA to the imposed pH gradient and not to changes in the vesicular system itself. Time constants for this fluorescence quenching are in the range of several hundred milliseconds at 25 degrees C. Fluorescence recovery which should be correlated to the dissipation of the pH gradient occurs in the 100 s time range and is 10-30-times faster than the delta pH decay monitored with the entrapped hydrophilic pH-indicator dye pyranine. The quenching was severely hindered below the lipid phase transition of dipalmitoylphosphatidylglycerol. No delta pH-induced quenching was obtained in lipid vesicles containing only zwitterionic, net uncharged phosphatidylcholine headgroups. For the occurrence of quenching, the presence of negatively charged headgroups, i.e. phosphatidylglycerol or phosphatidylserine, was necessary. The extent of quenching, at a specific pH difference applied, had a cooperative dependency (Hill coefficient approximately 2) on the number of negative headgroups in the membrane and on the concentration of unquenched (unbound) 9-AA molecules. The concentration of quenched 9-AA molecules was furthermore proportional to the number of dimer-excimer complexes of 9-AA which are formed during the quenching process.     

Effects of uncouplers on Mg2+-dependent fluorescence quenching in isolated chloroplasts

Uncoupling concentrations (about 1 mol l^-1) of desaspidin or carbonyl cyanide-4-trifluoromethoxyphenyl hydrazone reverse the slow light-induced, Mg²⁺-dependent quenching of fluorescence of chlorophyll a in isolated (intact and broken) spinach chloroplasts. Likewise, uncoupling inhibits the light-induced increase of the Mg²⁺ concentration in the stroma of intact chloroplasts, as determined with Eriochrome Blue SE. Addition of higher amounts of the uncouplers to the chloroplasts leads to a slow, light-dependent fluorescence lowering which appears to be promoted by high light intensities and is not reversed in the dark. The reversal of the fluorescence quenching by uncoupling is interpreted to reflect exchange of protons for Mg²⁺ ions at negative sites of the inner thylakoid face, caused by the collapse of the proton gradient across the membrane. The secondary fluorescence lowering caused by high levels of the uncouplers and high light intensities is suggested to be related to an inhibition of non-cyclic photosynthetic electron transport.Abbreviation FCCP carbonyl cyanide-4-trifluoromethoxyphenyl hydrazone     

Identification and characterization of ATP-dependent proton transport by rat liver multivesicular bodies

Multivesicular bodies (MVB), prelysosomal organelles in the endocytic pathway, were prepared from estrogen-treated rat livers and examined for the presence of ATP-dependent proton transport. Vesicle acidification, assessed by acridine orange fluorescence quenching, was ATP dependent (ATP much greater than GTP, UTP), was enriched 25-fold over homogenate, was abolished by pretreatment with protonophores or a nonionic detergent, exhibited a pH optimum of 7.5, was inhibited by N-ethylmaleimide (NEM) (IC50 approximately 5 microM) and N,N'-dicyclohexylcarbodiimide (IC50 approximately 5 microM), and was resistant to inhibition by vanadate, ouabain, and oligomycin. Acidification exhibited no specific cation requirement; however, maximal rates of acidification depended upon the presence of Cl- (Km approximately 20 mM). Other anions were less effective in supporting acidification (Cl- greater than Br- greater than much greater than gluconate, NO-3, SO2-4, and mannitol), and indeed NO-3 inhibited acidification even in the presence of 150 mM Cl-. The proton transport mechanism appeared to be electrogenic based on: (a) enhancement of acidification by valinomycin in the presence of K gluconate, and (b) ATP-dependent fluorescence quenching of bis(3-phenyl-5-oxoisoxasol-4-yl)pentamethine oxonol, a membrane potential-sensitive anionic dye. Furthermore, the magnitude of the pH and electrical gradients generated by the proton transport mechanism appeared to vary inversely in the presence and absence of Cl-. Finally, MVB exhibited ATPase activity that was resistant to ouabain and oligomycin, but was inhibited 32.3% by 1 mM NEM, 33.7% by 200 microM dicyclohexylcarbodiimide, and 18.7% by KNO3. In isolated MVB, therefore, the NEM-sensitive ATPase activity may represent the enzymatic equivalent of a proton pump. These studies identify and characterize an ATP-dependent electrogenic proton transport process in rat liver MVB which shares many of the properties of the proton pump described in clathrin-coated vesicles, endosomes, lysosomes, Golgi, and endoplasmic reticulum from liver and other tissues. Acidification of MVB differed somewhat from that of rat liver clathrin-coated vesicles in response to Br- and NO-3, suggesting that membrane properties of these two organelles might differ.     

ADP-Glucose Transport by the Chloroplast Adenylate Translocator Is Linked to Starch Biosynthesis

In organello starch biosynthesis was studied using intact chloroplasts isolated from spinach leaves (Spinacia oleracea). Immunoblot analysis using a specific antiserum against the mitochondrial adenylate (ADP/ATP) translocator of Neurospora crassa shows the presence of an adenylate translocator protein in the chloroplast envelope membranes, similar to that existing in mitochondria and amyloplasts from cultured cells of sycamore (Acer pseudoplatanus). The double silicone oil layer-filtering centrifugation technique was employed to study the kinetic properties of adenylate transport in the purified chloroplasts; ATP, ADP, AMP, and most importantly ADP-Glc were shown to be recognized by the adenylate translocator. Similar to the situation with sycamore amyloplasts, only ATP and ADP-Glc uptake was inhibited by carboxyatractyloside, an inhibitor of the mitochondrial adenylate translocator. Evidence is presented to show that the ADP-Glc transported into the chloroplast stroma is utilized for starch synthesis catalyzed by starch synthase (ADP-Glc:1,4-α-d-glucan 4-α-d-glucosyltransferase). The high activity of sucrose synthase producing ADP-Glc observed in the extrachloroplastic fractions suggests that starch biosynthesis in chloroplasts may be coupled with the direct import of ADP-Glc from the cytosol.     

ATP-dependent proton uptake by proteoliposomes reconstituted with purified Na+,K+-ATPase

Proton transport catalyzed by the sodium pump was demonstrated using proteoliposomes reconstituted with purified pig kidney Na+,K+-ATPase. Intravesicular pH was monitored with fluorescence from fluorescein isothiocyanate dextran introduced into the vesicles. An ATP-induced ouabain-sensitive acidification of the intravesicular medium was observed, when the vesicles were incubated with ATP and without Na+. The ATP-induced acidification was blocked by either extravesicular Na+ or pretreatment of the enzyme with ouabain before reconstitution. Protonophores, X-537A or carbonyl cyanide m-chlorophenylhydrazone, abolished the intravesicular acidification. The acidification was not inhibited by 3 mM tetra-n-butylammonium. The initial rate of the H+ uptake was increased with a decrease in pH of the extravesicular medium, and the maximum rate was obtained at pH 5.5-5.6. It is concluded that H+ can be transported in place of Na+ by the sodium pump.