Bilitranslocase is the protein responsible for the electrogenic movement of sulfobromophthalein in plasma membrane vesicles from rat liver: immunochemical evidence using mono- and poly-clonal antibodies

Monoclonal antibodies raised against bilitranslocase, may display either inhibitory or enhancing activity on the electrogenic transport of sulfobromophthalein, evoked in rat liver plasma-membrane vesicles by the addition of valinomycin in the presence of K+. In both cases, the target protein is identified with a 37 kDa band in SDS-mercaptoethanol gel electrophoresis of solubilized membranes. The electrophoretically homogeneous protein isolated by ion-exchange chromatography, corresponds in all respects to the 37 kDa protein band of bilitranslocase, obtained in the past by different techniques. Using this protein as antigen, a polyclonal monospecific antibody preparation has been obtained. As expected, the antibody preparation inhibits the electrogenic movement of sulfobromophthalein in plasma membrane vesicles from rat liver. It is concluded that the 37 kDa protein of bilitranslocase is at least a necessary component of the transport system involved in the sulfobromophthalein movement in plasma membrane.     

Sodium-gradient-stimulated transport of l-alanine by plasma-membrane vesicles isolated from liver parenchymal cells of fed and starved rats. Crucial role of the adrenal glucocorticoids

The ability of liver efficiently to take up amino acids, particularly l-alanine, during starvation was studied in a cell-free system by isolating plasma-membrane vesicles in a transport-competent state from rat liver parenchymal cells. These membrane vesicles have the capacity to accumulate l-alanine against an apparent concentration gradient when exposed to an artificial and transient transmembrane Na⁺ gradient (extravesicular Na⁺ concentration greater than inside). The rate of accumulation of l-alanine is dependent on the plasma-membrane vesicle concentration, and the steady-state concentration attained is inversely related to the osmolarity of the medium. The Na⁺-mediated stimulation is not exhibited if the membrane vesicles are pre-equilibrated with NaCl, if K⁺ or Li⁺ are substituted for Na⁺, or if SO₄²⁻ replaces Cl⁻ as the counterion. The apparent active transport of l-alanine into the membrane vesicles appears to occur by an electrogenic mechanism: (1) the use of NaSCN significantly heightens the early concentrative phase of transport when compared with the effect of NaCl; (2) an enhanced active transport is also observed when a valinomycin-induced K⁺ efflux occurs concomitant with Na⁺ and l-alanine influx. Plasma-membrane vesicles isolated from liver parenchymal cells of a 24 h-starved rat exhibit an initial l-alanine transport rate that is 3–4 times that for membrane vesicles derived from a fed animal. The increased rate of l-alanine transport by plasma-membrane vesicles from starved animals can be obliterated by adrenalectomy and restored by administration of glucocorticoid. These results establish that stimulation of the gluconeogenic pathway by starvation involves a plasma-membrane-localized change affecting l-alanine transport which is regulated in part by the glucocorticoid hormones.     

Identification and biochemical characterization of the plasma-membrane H+-ATPase in guard cells of Vicia faba L.

The plasma-membrane H⁺-pump in guard cells generates the driving force for the rapid ion fluxes required for stomatal opening. Since our electrophysio-logical studies revealed a two fold higher pump-current density in guard cells than in mesophyll cells of Vicia faba L. we elucidated the biochemical properties of this proton-translocating ATPase in plasma-membrane vesicles isolated from both cell types. The capability of the H⁺ —ATPase to create an H⁺ gradient is maintained in plasma-membrane vesicles derived from purified guard cells via blender maceration, high-pressure homogenization and polymer separation. The H⁺-pumping activity of these vesicles coincides with the presence of two polypeptides of approx. 100 and 92 kDa which are recognized by a monoclonal antibody raised against the plasma-membrane H⁺-ATPase from Zea mays L. coleoptiles. Comparison of H⁺-pumping activities of isolated membranes revealed an approximately two fold higher activity in guard cells than in mesophyll cells with respect to the total membrane protein content. Furthermore, we demonstrated by western blotting that the difference in pump activities resulted from a higher abundance of the electroenzyme per unit membrane protein in guard-cell plasma membranes. We suggest that the high H⁺-pump capacity is necessary to enable guard cells to respond to sudden changes in the environment by a change in stomatal aperture.     

Relationship between proton motive force and potassium ion transport in Halobacterium halobium envelope vesicles.

Membrane vesicles prepared from Halobacterium halobium extrude protons during illumination, and a pH difference (inside alkaline) and an electrical potential (inside negative) develop. The sizes of these gradients and their relative magnitudes are dependent on a complex interaction among the proton-pumping activity of bacteriorhodopsin, Na⁺ extrusion through an antiport system, and the ability of K⁺ and Cl^? to act as counterions to the electrogenic movement of H⁺. The net result of these variable effects is that the electrical potential is relatively independent of external pH, whereas the pH difference tends toward zero when the pH is increased to 7.5–8. Although the light-induced pH difference is greater in KCl than in NaCl, and the electrical potential smaller, this is not caused by a high permeability of the vesicle membranes to K⁺. The vesicle membrane is poorly permeable to K⁺, as shown by: lack of a K⁺ diffusion potential in the absence of valinomycin, light-induced electrical potentials which are in excess of the chemical potential difference for K⁺, and direct measurements of the slow rate of K⁺ influx during illumination. The finding that the rate of K⁺ uptake is a linear function of external K⁺ concentration between 0 and 1 m is inconsistent with the existence of a specific K⁺ permeation mechanism in these vesicles. Since at external K⁺ concentrations < 1.4 m the extrusion of Na⁺ during illumination proceeds much more rapidly than K⁺ influx, it must be concluded that the vesicles also lose Cl^? and water. Measurements of light-scattering changes confirm that under these conditions the vesicles collapse. The light-induced collapse is diminished only when the inward movement of K⁺ is increased, either by increasing the external K⁺ concentration or by adding valinomycin.     

Proton-transport activity,sidedness, and morphometry of tonoplast and plasma-membrane vesicles purified by free-flow electrophoresis from roots of Lepidium sativum L. and hypocotyls of Cucurbita pepo L.

Large-scale preparations of highly purified tonoplast and plasma-membrane vesicles were obtained from roots (garden cress, Lepidium sativum L.) and shoots (etiolated zucchini hypocotyl, Cucurbita pepo L.) of representative dicotyledonous seedlings. When tonoplast-enriched fractions of cress roots were prepared by centrifugation and then subjected to free-flow electrophoresis a highly purified tonoplast fraction was obtained. This fraction from cress roots was characterized by morphometry of filipin-treated freeze-fractured preparations and by enzymology to be about 90% homogeneous. Using latency of nitrate-inhibited ATPase and H⁺-pumping as criteria we found that the majority of the tonoplast vesicles from both sources were oriented right(cytoplasmic)-side-out. Plasma-membrane vesicles were first purified by two-phase partitioning and then subjected to free-flow electrophoresis for further purification. From cress roots, the fraction of highest purity contained 89% plasma-membrane vesicles as judged by morphometry of filipin-treated, freeze-fractured preparations and by enzymology. From both sources, the major plasma-membrane subfraction in the upper phase after two-phase partitioning was shown to have the least electrophoretic mobility in free-flow electrophoresis and to be oriented right(extracytoplasmic)-side-out a slightly more mobile plasma-membrane subfraction was oriented inside-out and originated after freezing thawing from outside-out plasma-membrane vesicles.Part of the doctoral thesis (D5) of B. vom DorpWe thank the Bundesministerium für Forschung und Technologie for financial support.     

Transport of Na+ inside the giant axon of squid

The transport mechanism of Na ions within the nerve cell was studied by measuring the radioactivity distribution profile of²²Na that had been intracellularly injected into the giant axon. Specifically, we tested whether or not the movement of Na ions is coupled with the process of “fast axonal transport.” Results of our measurements indicate that the intracellular transport of Na⁺ and the fast axonal transport are two independent processes. Very few Na ions are irreversibly sequestered into the axoplasmic vesicles involved in axonal transport. The movement of Na⁺ inside the axon can be modeled by a one-dimension diffusion. The effective diffusion coefficient of the intracellular Na⁺ was determined in this study.     

Erv14 cargo receptor participates in regulation of plasma-membrane potential,intracellular pH and potassium homeostasis via its interaction with K+-specific transporters Trk1 and Tok1

Cargo receptors in the endoplasmic reticulum (ER) recognize and help membrane and soluble proteins along the secretory pathway to reach their location and functional site. We characterized physiological properties of Saccharomyces cerevisiae strains lacking the ERV14 gene, which encodes a cargo receptor part of COPII-coated vesicles that cycles between the ER and Golgi membranes. The lack of Erv14 resulted in larger cell volume, plasma-membrane hyperpolarization, and intracellular pH decrease. Cells lacking ERV14 exhibited increased sensitivity to toxic cationic drugs and decreased ability to grow on low K⁺. We found no change in the localization of plasma membrane H⁺-ATPase Pma1, Na⁺, K⁺-ATPase Ena1 and K⁺ importer Trk2 or vacuolar K⁺-Cl⁻ co-transporter Vhc1 in the absence of Erv14. However, Erv14 influenced the targeting of two K⁺-specific plasma-membrane transport systems, Tok1 (K⁺ channel) and Trk1 (K⁺ importer), that were retained in the ER in erv14Δ cells. The lack of Erv14 resulted in growth phenotypes related to a diminished amount of Trk1 and Tok1 proteins. We confirmed that Rb⁺ whole-cell uptake via Trk1 is not efficient in cells lacking Erv14. ScErv14 helped to target Trk1 homologues from other yeast species to the S. cerevisiae plasma membrane. The direct interaction between Erv14 and Tok1 or Trk1 was confirmed by co-immunoprecipitation and by a mating-based Split Ubiquitin System. In summary, our results identify Tok1 and Trk1 to be new cargoes for Erv14 and show this receptor to be an important player participating in the maintenance of several physiological parameters of yeast cells.     

Ionic requirements for taurocholate transport in rat liver plasma membrane vesicles

As part of the enterohepatic circulation, taurocholate is taken up by hepatocytes by a Na⁺-gradient-dependent, carrier-mediated process. The dependence of taurocholate uptake on the presence of a Na⁺ gradient, outside greater than inside, has been studied in isolated rat liver plasma membranes. The uptake is specific for sodium, and a cotransport stoichiometry of 2 Na⁺ per taurocholate taken up was found. The presence of K⁺ ions inside the vesicles was also found to be essential for maximum Na⁺-stimulated uptake of taurocholate, although a K⁺ gradient is not required. Mg²⁺ was almost as effective as K⁺ in this regard. The symport of Na⁺ and taurocholate during uptake was shown to be electrogenic, so that K⁺ may act as an exchange counterion preventing the accumulation of positive charge within the vesicles.Dedicated to the memory of Prof. David E. Green, friend, mentor, and colleague.     

Interaction of auxin-binding protein 1 with maize coleoptile plasma membranes in vitro

In a search for membrane “docking proteins” interacting with Zea mays auxin-binding protein (ABP1) the binding of purified ABP1 to maize coleoptile plasma-membrane vesicles was investigated. Concentration-dependent, saturable binding of ABP1 to the membrane vesicles was observed in binding assays using 10⁻⁸–10⁻⁶␣M ABP1. Biotinylated ABP1 was displaced from the membrane binding sites by competition with unlabeled ABP1, demonstrating specific binding. The association step proved to be pH-dependent with maximum binding at pH 5.0 or lower. Auxins did not influence the ABP1 binding to plasma-membrane vesicles, but ABP1 associated with plasma-membrane vesicles was still able to specifically bind [³H]naphthalene-1-acetic acid. The rather stable interaction of ABP1 with plasma-membrane vesicles was only affected by strong alkaline buffers or detergents. The binding capacity was calculated to be in the range of 0.2 pmol ABP1 per g coleoptile fresh weight. Received: 29 April 1996 / Accepted: 20 September 1996     

Requirement of Cl− and Na+ for the ouabain-resistant control of cell volume in slices of rat liver

Summary The ability of liver cells to control their volume in the presence of ouabain has been studied in tissue slices that were recovering at 38°C from a period of swelling at 1°C. Morphological observations were made in conjunction with measurements of the net movements of water and ions. Extrusion of water in the presence of ouabain (2mm) was accompanied by a net loss of Na⁺ and Cl^– and by the formation of characteristic, rounded vesicles in the peri-canalicular regions of the hepatocytes; bile canaliculi were patent. When incubation was carried out in a medium in which either NO ₃ ^– or SO ₄ ^2– replaced Cl^–, ouabain-resistant water extrusion was prevented and the cytoplasmic vesicles normally found with ouabain were almost totally absent. When these slices were subsequently transferred to Cl^– medium with oubain, extrusion of intracellular water was initiated and cytoplasmic vesicles reappeared. Replacement of medium Na⁺ by Li⁺ mimicked the effects of ouabain on water and ion movements and ultrastructure. In addition, the ouabain-resistant extrusion of water and Cl^– was reduced and there was some diminution in the number of vesicles induced by ouabain. Furosemide (2mm) had little effect on water movement or ultrastructure in the absence of ouabain, but it slowed the net water loss and substantially reduced the formation of cytoplasmic vesicles in the presence of ouabain. The results show a close relationship between ouabain-resistant water extrusion and the formation of the cytoplasmic vesicles that are characteristic of treatment with ouabain. They further suggest that a cotransport of Na⁺ and Cl^– forms an important part of the mechanism underlying ouabain-resistant water extrusion and, specifically, that this cotransport may take place across the membranes of the cytoplasmic vesicles.     

Reconstitution in vitro of sulfobromophthalein transport by bilitranslocase

Liposomes containing 150 mM KCl and 0.48 mM sulfobromophthalein have been prepared. The internal pH was set at 6.5, a value at which sulfobromopthalein is colorless. When brought to alkaline pH a certain amount of the dye is deprotonated and can be read spectrophotometrically as external sulfobromophthalein. Upon addition of Triton X-100 the membrane is dissolved and all sulfobromophthalein present in the preparation may be measured. Addition of bilitranslocase to such a preparation of liposomes causes the internal sulfobromophthalein to leave the internal compartment. The rate of this phenomenon may be followed directly and shown to be greatly accelerated by the addition of valinomycin. The latter finding indicates that sulfobromophthalein transport occurs in response to a membrane diffusion potential created by permeabilisation to K⁺ of liposomes brought about by valinomycin (uniport). The permeability change induced by bilitranslocase is specific and does not reflect an alteration of the normal impermeability of liposomes to small ions such as protons or Ca²⁺.     

Potassium Stimulation of Corn Root Plasmalemma ATPase : II. H-Pumping in Native and Reconstituted Vesicles with Purified ATPase

The stimulation by K⁺ of the initial rate of H⁺-pumping by ATPase was studied in native plasmalemma (Zea mays L. var Mona) vesicles and in reconstituted vesicles with enzyme purified on a glycerol gradient. In reconstituted vesicles, a very high H⁺-pumping rate (200,000% quenching per minute per milligram protein) was obtained with 9-amino-6-chloro-2-methoxyacridine provided that the pump was short-circuited by K⁺-valinomycin. A constant ionic strength was used to prevent indirect stimulation by the electrostatic effects of K⁺ salts. Indirect stimulation of H⁺-pumping by the short-circuiting effect of internal K⁺, could be abolished by using the permeant anions NO₃⁻ and Br⁻ in native, but not in reconstituted vesicles. In both materials, half-stimulation of the H⁺-pumping by K⁺ was observed at about 5 millimolar. The same stimulation was obtained when K⁺ was present only in the external solution or when it was present both outside and inside the vesicles. It was concluded that the stimulating effect of K⁺ on the H⁺-pumping evidenced in these experiments on both native and reconstituted vesicles was due to a direct effect of the cation on the cytoplasmic face of the ATPase. These results are discussed within the context of the hypothesis of an active K⁺ transport driven by the ATPase through a direct H⁺/K⁺ exchange mechanism.     

Isolation of an organic anion binding protein from rat liver plasma membrane fractions by affinity chromatography

As part of a study of hepatic organic anion transport, solubilized liver plasma membrane proteins were subjected to affinity chromatography on bilirubin- and sulfobromophthalein-labeled agarose columns. Both columns retained a Sudan Black and PAS negative protein of molecular weight 60,000 daltons, which cochromatographed with [³⁵S]sulfobromophthalein on Sephadex G-75, and reversibly bound [³⁵S]sulfobromophthalein in vitro with high affinity (K_a ? 10⁷ M^?1) and a valence of 2. Erythrocyte ghost membranes did not contain this protein. Sulfobromophthalein-agarose retained two additional smaller proteins which did not cochromatograph with [³⁵S]sulfobromophthalein. Their significance is unclear. This study supports the hypothesis that liver cell plasma membranes participate in the hepatic transport of organic anions.     

Proton-pumping adenosine triphosphatase in membrane vesicles of tobacco callus: Sensitivity to vanadate and K+

H⁺-pumping adenosinetriphosphatases (ATPases, EC 3.6.1.3) were demonstrated in sealed microsomal vesicles of tobacco callus. Quinacrine fluorescence quenching was induced specifically by MgATP and stimulated by EGTA and Cl^?. Fluorescence quenching reflected a relative measure of pH gradient formation (inside acid), as it could be reversed by gramicidin (an H⁺/cation conductor) or 10 mM NH₄Cl (an uncoupler). H⁺ pumping was inhibited by tributyltin (an ATPase inhibitor) and sodium vanadate, but it was insensitive to oligomycin or fusicoccin. The vanadate concentration required to inhibit pH gradient formation was similar to that needed to inhibit KCl-stimulated Mg²⁺-ATPase activity and generation of a membrane potential (measured by ATP-dependent ³⁵SCN^? uptake). About 45% of all three activities (ATPase, pH gradient, membrane potential generation) were vanadate-insensitive, supporting the idea that non-mitochondrial membranes of plants have at least two types of electrogenic H⁺ pump.A vanadate-insensitive, H⁺-pumping ATPase previously shown by methylamine accumulation was characterized to be anion-sensitive and possibly enriched in vacuolar membranes (Churchill, K.A. and Sze, H. (1983) Plant Physiol. 71, 610–617). Yet, pH gradient formation determined by quinacrine fluorescence quenching was decreased by monovalent cations with a sequence K⁺, Rb⁺, Na⁺ > Cs⁺,Li⁺> choline, bisTris-propane. Since K⁺ stimulated ATPase activity more than Bistris-propane, K⁺ appeared to collapse formation of the pH gradient by an H⁺/K⁺ countertransport. The sensitivity to vanadate and K⁺ provides evidence that the plasma-membrane ATPase is an electrogenic H⁺ pump.     

Phosphorylation of the plasma-membrane H+-ATPase of oat roots by a calcium-stimulated protein kinase

When plasma-membrane vesicles isolated from oat (Avena sativa L.) root cells were incubated with [-³²P]ATP, the H⁺-ATPase was found to be phosphorylated at serine and threonine residues. Phosphotyrosine was not detected. Endogenous ATPase kinase activity was also observed in plasma-membrane vesicles isolated from potato (Solanum tuberosum L.) root cells as well as from yeast (Saccharomyces cerevisiae). Identity of the phosphorylated oat root M_r=100 000 polypeptide as the ATPase was confirmed using conventional glycerol density-gradient centrifugation to purify the native enzyme and by a new procedure for purifying the denatured polypeptide using reversephase high-performance liquid chromatography. Kinase-mediated phosphorylation of the oat root plasma-membrane H⁺-ATPase was stimulated by the addition of low concentrations of Ca²⁺ and by a decrease in pH, from 7.2 to 6.2. These results demonstrate that kinase-mediated phosphorylation of the H⁺-ATPase is a plausible mechanism for regulating activity. They further indicate that changes in the cytoplasmic [Ca²⁺] and pH are potentially important elements in modulating the kinase-mediated phosphorylation.Abbreviations EDTA ethylenediaminetetraacetic acid - EGTA ethylene glycol-bis-(-aminoethyl ether)-N,N,N,N-tetraacetic acid - M_r relative molecular mass - RP-HPLC reverse-phase high-performance liquid chromatography - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis     

Effect of papain treatment on dipeptide transport into rabbit intestinal brush border vesicles

Purified rabbit intestinal brush border membrane vesicles transport glycyl-L-proline into an osmotically responsive intravesicular space by a Na⁺- independent, carrier-mediated process. With short incubation, transport occurs mostly as the intact dipeptide, followed by hydrolysis. Pretreatment of the vesicles with papain results in a 60% reduction of L-alanine transport while glycyl-L-proline transport is stimulated by 40%. Papain treatment does not change the intravesicular volume, nor does it increase membrane permeability. Dipeptide transport into papain treated vesicles remains completely Na⁺- independent as it is in the control vesicles. Many dipeptides inhibit glycyl-L-proline transport into papain treated vesicles both in the presence and absence of a Na⁺ gradient.     

A novel method to quantify H-ATPase-dependent Na transport across plasma membrane vesicles

To prevent sodium toxicity in plants, Na⁺ is excluded from the cytosol to the apoplast or the vacuole by Na⁺/H⁺ antiporters. The secondary active transport of Na⁺ to apoplast against its electrochemical gradient is driven by plasma membrane H⁺-ATPases that hydrolyze ATP and pump H⁺ across the plasma membrane. Current methods to determine Na⁺ flux rely either on the use of Na-isotopes (²²Na) which require special working permission or sophisticated equipment or on indirect methods estimating changes in the H⁺ gradient due to H⁺-ATPase in the presence or absence of Na⁺ by pH-sensitive probes. To date, there are no methods that can directly quantify H⁺-ATPase-dependent Na⁺ transport in plasma membrane vesicles. We developed a method to measure bidirectional H⁺-ATPase-dependent Na⁺ transport in isolated membrane vesicle systems using atomic absorption spectrometry (AAS). The experiments were performed using plasma membrane-enriched vesicles isolated by aqueous two-phase partitioning from leaves of Populus tomentosa. Since most of the plasma membrane vesicles have a sealed right-side-out orientation after repeated aqueous two-phase partitioning, the ATP-binding sites of H⁺-ATPases are exposed towards inner side. Leaky vesicles were preloaded with Na⁺ sealed for the study of H⁺-ATPase-dependent Na⁺ transport. Our data implicate that Na⁺ movement across vesicle membranes is highly dependent on H⁺-ATPase activity requiring ATP and Mg²⁺ and displays optimum rates of 2.50 μM Na⁺ mg^− 1 membrane protein min^− 1 at pH 6.5 and 25 °C. In this study, for the first time, we establish new protocols for the preparation of sealed preloaded right-side-out vesicles for the study of H⁺-ATPase-dependent Na⁺ transport. The results demonstrate that the Na⁺ content of various types of plasma membrane vesicle can be directly quantified by AAS, and the results measured using AAS method were consistent with those determined by the previous established fluorescence probe method. The method is a convenient system for the study of bidirectional H⁺-ATPase-dependent Na⁺ transport with membrane vesicles.     

Isolation of a rat liver plasma membrane fraction of probable canalicular origin Preparative technique,enzymatic profile,composition, and solute transport

A technique currently used for isolation of brush border membranes from renal and intestinal epithelium that involves vigorous tissue homogenization and sedimentation of non-luminal membranes in the presence of Mg²⁺ has been adapted to rat liver. Liver plasma membranes so prepared consisted almost exclusively of vesicles by electron microscopy, showed some contamination with endoplasmic reticulum and minimal contamination with mitochondria or Golgi by marker enzymes, were highly enriched in alkaline phosphatase, Mg²⁺-ATPase, and 5′-nucleotidase activity compared with homogenate, and showed little enrichment in (Na⁺,K⁺)-ATPase. Comparison of this enzymatic profile with cytochemical studies localizing (Na⁺,K⁺)-ATPase and alkaline phosphatase to the sinusoidal/lateral and canalicular membranes, respectively, suggested that these membranes were predominantly of canalicular origin. They had a lower ($\text{Na}{}^{\mathrm{+}}\text{+}\text{K}{}^{\mathrm{+}}\text{)-}\text{ATPase}$ specific activity, lower lipid content, and higher cholesterol to phospholipid molar ratio than a conventional plasma membrane preparation believed to be enriched in canaliculi. Moreover, it was possible to measure movement of d-[³H]glucose into an osmotically sensitive space bounded by these membrane vesicles.