Transport of phenylalanine into vacuoles isolated from barley mesophyll protoplasts

The energy-dependent transport of phenylalanine into isolated vacuoles of barley (Hordeum vulgare L.) mesophyll protoplasts has been studied by silicone-layer floatation filtering. The uptake of this aromatic amino acid into the vacuolar compartment is markedly increased by MgATP, showing saturation kinetics; the K _m values were 0.5 mM for MgATP and 1.2 mM for phenylalanine. V _max for phenylalanine transport was estimated to 140 nmol phenylalanine·(mg·Chl)^-1·h^-1. The transport shows a distinct pH optimum at 7.3 and is markedly inhibited by 40 mM nitrate. Azide (1 mM) and vanadate (400 M) had no or little effect on rates of transport while p-fluorophenylalanine seemed to be an effective inhibitor, indicating a possible competition at an amino-acid carrier. Ionophores such as valinomycin, nigericin or gramicidin were strong inhibitors of phenylalanine transport, indicating that this process is coupled to both the transmembrane pH gradient (pH) and the transmembrane potential ().Abbreviations and symbols BSA bovine serum albumin - Chl chlorophyll - Hepes 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid - pH transmembrane pH gradient - transmembrane potential     

Transport of arginine and aspartic Acid into isolated barley mesophyll vacuoles

The transport of arginine into isolated barley (Hordeum vulgare L.) mesophyll vacuoles was investigated. In the absence of ATP, arginine uptake was saturable with a K_m of 0.3 to 0.4 millimolar. Positively charged amino acids inhibited arginine uptake, lysine being most potent with a K_i of 1.2 millimolar. In the presence of free ATP, but not of its Mg-complex, uptake of arginine was drastically enhanced and a linear function of its concentration up to 16 millimolar. The nonhydrolyzable adenylyl imidodiphosphate, but no other nucleotide tested, could substitute for ATP. Therefore, it is suggested that this process does not require energy and does not involve the tonoplast ATPase. The ATP-dependent arginine uptake was strongly inhibited by p-chloromercuriphenylsulfonic acid. Furthermore, hydrophobic amino acids were inhibitory (I₅₀ phenylalanine 1 millimolar). Similar characteristics were observed for the uptake of aspartic acid. However, rates of ATP-stimulated aspartic acid transport were 10-fold lower as compared to arginine transport. Uptake of aspartate in the absence of ATP was negligible.     

Direct evidence for a sugar transport mechanism in isolated vacuoles

Sugar transport has been directly observed in isolated higher plant vacuoles for the first time. The latter were released from protoplasts isolated from the mesophyll of Pisum sativum L.     

Characterization of a specific transport system for arginine in isolated yeast vacuoles.

The transport of L-arginine was studied in isolated vacuoles of Saccharomyces cerevisiae. A centrifugation method allowed rapid separation of the fragile vacuoles from the incubation media so that initial uptake rates of [14C]arginine could be measured. Labelled arginine added to the medium was accumulated in the isolated vacuoles; it was found to exchange specifically with the arginine already present in the vacuoles. Such an exchange did not take place in intact spheroplasts. The pH dependence of the arginine transport in the vacuoles was tested. As the vacuoles are unstable in the pH range of optimal transport activity (pH above 7.0), the pH optimum of the transport reaction could not be determined. From the temperature dependence, the apparent energy of activation was calculated to be 9800 cal/mol. Arginine transport shows saturation kinetics with an apparent Km of 30 muM in the isolated vacuoles, and of 1.5 muM in the spheroplasts. Competition experiments with amino acids and arginine analogues demonstrated that the arginine transport in both vacuoles and spheroplasts, is highly specific. The two systems, however, were shown to have distinct specificities. The inhibition of vacuolar L-arginine transport by D-arginine, L-histidine, and L-canavanine was competitive with apparent Ki values of 60 muM, 400 muM and 600 muM respectively.     

Single potassium channels in membranes of isolated mesophyll barley vacuoles

Summary Voltage-dependent K channels could be identified in on-cell and excised patch-clamp records on membranes of isolated plant cell vacuoles. The current through a membrane patch is dominated by a channel population with a conductance of about 121 pS in symmetrical 250mm KCl solution. The single channel adopts at least two conducting levels the 121-pS state being most frequently observed. The channel shows outward rectification, representing a cation flux into the vacuoles. The rectification appears to be caused by a vanishing open probability and a short channel lifetime at hyperpolarizing voltages. A selectivity ratio of potassium over sodium of about 6 was derived as an estimate. Occasionally, an additional population of K channels with a single-channel conductance of approximately 18 pS is observed. This channel type exhibits outward rectification as well.     

Polypeptide pattern and enzymic character of vacuoles isolated from barley mesophyll protoplasts

Intact chloroplasts and vacuoles were isolated from mesophyll protoplasts of barley. The chloroplasts occupied about 15% of the cellular volume and contained 75% of the protein, whereas the vacuoles occupied about 80% of the volume and contained less than 4% of total cellular protein. Contamination of the vacuolar fraction by foreign protein is included in these values. Chlorophyll was absent from the vacuolar fraction, but less than 1% of several extra-vacuolar marker proteins were still present. The vacuoles contained hydrolytic enzymes. Several of them (-mannosidase, -galactosidase, N-acetylglucosaminidase) were soluble, whereas part of the activity of others semimented with the tonoplasts during centrifugation. Attached proteins could be released from the membranes during freezing in the presence of NaCl. One-dimensional gel electrophoretic separation of soluble vacuolar proteins under non-denaturing conditions yielded more than 10 protein bands. A comparative analysis was performed of thylakoids and vacuoles which were subfractionated into tonoplasts and soluble vacuolar constituents. Sodium dodecyl sulfate gel electrophoresis separated about 15 polypeptides of the soluble fraction which reacted with silver reagent. The tonoplast fraction yielded about 20 bands. A similar number of bands was observed when vacuoles incubated with the ¹⁴C-labelled SH-reagent N-ethylmaleimide were analysed for radioactive polypeptides. Silverstaining of the polypeptides and their SH-content did not correlate. Several polypeptides of the vacuolar fraction had molecular weights very similar to the molecular weights of known chloroplast proteins. However, with the exception of the two subunits of ribulose-1,5-bisphosphate carboxylase, contamination of the vacuolar fraction by chloroplast proteins could be ruled out as a possible cause of the close correspondence. The lipophilic carboxylic-group reagent N,N-dicyclohexylcarbodiimide ([¹⁴C]DCCD) reacted with several polypeptides of thylakoids and tonoplasts. However, the labelling patterns were different. The most heavily labelled polypeptide of thylakoids was the 8-kDa polypeptide of the basal part of the coupling factor CF₀. Tonoplast polypeptides heavily labelled with [¹⁴C]DCCD had molecular weights of 24, 28, and 56 kDa. The vacuolar 8-kDa polypeptide remained unlabelled.Abbreviations DCCD N,N-dicyclohexylcarbodiimide - IA iodoacetamide - NEM N-ethylmaleimide - PAGE polyacrylamide gel electrophoresis - PMSF phenylmethylsulfonylfluoride - SDS sodium dodecyl sulfate     

Characterization of a transport activity for long-chain peptides in barley mesophyll vacuoles

The plant vacuole is the largest compartment in a fully expanded plant cell. While only very limited metabolic activity can be observed within the vacuole, the majority of the hydrolytic activities, including proteolytic activities reside in this organelle. Since it is assumed that protein degradation by the proteasome results in the production of peptides with a size of 3-30 amino acids, we were interested to show whether the tonoplast exhibits a transport activity, which could deliver these peptides into the vacuole for final degradation. It is shown here that isolated barley mesophyll vacuoles take up peptides of 9-27 amino acids in a strictly ATP-dependent manner. Uptake is inhibited by vanadate, but not by NH(+)(4), while GTP could partially substitute for ATP. The apparent affinity for the 9 amino acid peptide was 15 μM, suggesting that peptides are efficiently transferred to the vacuole in vivo. Inhibition experiments showed that peptides with a chain length below 10 amino acids did not compete as efficiently as longer peptides for the uptake of the 9 amino acid peptide. Our results suggest that vacuoles contain at least one peptide transporter that belongs to the ABC-type transporters, which efficiently exports long-chain peptides from the cytosol into the vacuole for final degradation.     

A carboxyl-terminal propeptide is necessary for proper sorting of barley lectin to vacuoles of tobacco.

Barley lectin is synthesized as a preproprotein with a glycosylated carboxyl-terminal propeptide (CTPP) that is removed before or concomitant with deposition of the mature protein in vacuoles. Expression of a cDNA clone encoding barley lectin in transformed tobacco plants results in the correct processing, maturation, and accumulation of active barley lectin in vacuoles [Wilkins, T.A., Bednarek, S.Y., and Raikhel, N.V. (1990). Plant Cell 2, 301-313]. The glycan of the propeptide is not essential for vacuolar sorting, but may influence the rate of post-translational processing [Wilkins, T.A., Bednarek, S.Y., and Raikhel, N.V. (1990). Plant Cell 2, 301-313]. To investigate the functional role of the CTPP in processing, assembly, and sorting of barley lectin to vacuoles, a mutant barley lectin cDNA clone lacking the 15-amino acid CTPP was prepared. The CTPP deletion mutant of barley lectin was expressed in tobacco protoplasts, suspension-cultured cells, and transgenic plants. In all three systems, the wild-type barley lectin was sorted to vacuoles, whereas the mutant barley lectin was secreted to the incubation media. Therefore, we conclude that the carboxyl-terminal domain of the barley lectin proprotein is necessary for the efficient sorting of this protein to plant cell vacuoles.     

Colocalization of barley lectin and sporamin in vacuoles of transgenic tobacco plants.

Various targeting motifs have been identified for plant proteins delivered to the vacuole. For barley (Hordeum vulgare) lectin, a typical Gramineae lectin and defense-related protein, the vacuolar information is contained in a carboxyl-terminal propeptide. In contrast, the vacuolar targeting information of sporamin, a storage protein from the tuberous roots of the sweet potato (Ipomoea batatas), is encoded in an amino-terminal propeptide. Both proteins were expressed simultaneously in transgenic tobacco plants to enable analysis of their posttranslational processing and subcellular localization by pulse-chase labeling and electron-microscopic immunocytochemical methods. The pulse-chase experiments demonstrated that processing and delivery to the vacuole are not impaired by the simultaneous expression of barley lectin and sporamin. Both proteins were targeted quantitatively to the vacuole, indicating that the carboxyl-terminal and amino-terminal propeptides are equally recognized by the vacuolar protein-sorting machinery. Double-labeling experiments showed that barley lectin and sporamin accumulate in the same vacuole of transgenic tobacco (Nicotiana tabacum) leaf and root cells.     

INTESTINAL CAPILLARIES : I. Permeability to Peroxidase and Ferritin

Horseradish peroxidase (mol. diam. 50 A) and ferritin (mol. diam. 110 A) were used as probe molecules for the small and large pore system, respectively, in blood capillaries of the intestinal mucosa of the mouse. Peroxidase distribution was followed in time, after intravenous injection, by applying the Graham-Karnovsky histochemical procedure to aldehyde-fixed specimens. The tracer was found to leave the plasma rapidly and to reach the pericapillary spaces 1 min post injection. Between 1 min and 1 min 30 sec, gradients of peroxidase reaction product could be demonstrated regularly around the capillaries; their highs were located opposite the fenestrated parts of the endothelium. These gradients were replaced by even distribution past 1 min 30 sec. Ferritin, followed directly by electron microscopy, appeared in the pericapillary spaces 3–4 min after i.v. injection. Like peroxidase, it initially produced transient gradients with highs opposite the fenestrated parts of the endothelium. For both tracers, there was no evidence of movement through intercellular junctions, and transport by plasmalemmal vesicles appeared less efficient than outflow through fenestrae. It is concluded that, in the blood capillaries of the inintestinal mucosa, the diaphragms of the endothelial fenestrae contain the structural equivalents of the small pore system. The large pore system seems to be restricted to a fraction of the fenestral population which presumably consists of diaphragm-free or diaphragm-deficient units.     

The transport of S-adenosyl-L-methionine in isolated yeast vacuoles and spheroplasts.

1. The properties of S-adenosyl-L-methionine accumulating system for both vacuoles and spheroplasts are described. Yeast vacuoles were obtained by a modified metabolic lysis procedure from spheroplasts of Saccharomyces cerevisiae. 2. Isolated vacuoles accumulate S-adenosyl-L-methionine by means of a highly specific transport system as indicated by competition experiments with structural analogs of S-adenosyl-L-methionine. The S-adenosyl-L-methionine transport system shows saturation kinetics with an apparent Km of 68 muM in vacuoles and 11 muM in spheroplasts. 3. S-Adenosyl-L-methionine accumulation into vacuoles does not require glucose, phosphoenolpyruvic acid, ATP, ADP nor any other tri- or di-phosphorylated nucleotides. It is insensitive to azide and 2,4-dinitrophenol which strongly inhibit the glucose-dependent accumulation of S-adenosyl-L-methionine in spheroplasts. 4. The transport of S-adenosyl-L-methionine into vacuoles is optimal at pH 7.4 and is insensitive to nystatin while the uptake of S-adenosyl-L-methionine into spheroplasts is optimal at pH 5.0 and is strongly sensitive to nystatin. On this basis it has thus been possible to measure both the intracytoplasmic and the intravacuolar pool of S-adenosyl-L-methionine. 5. Our results indicate the existence of a highly specific S-adenosyl-L-methionine transport system in the vacuolar membrane which is clearly different from the one present in the plasma membrane of yeast cells.     

Basic peroxidases in isolated vacuoles of nicotiana tabacum L.

Vacuoles of tobacco mesophyll and of suspension-cultured cells were isolated in order to study the localization of peroxidase isoenzymes. Only basic peroxidases were detectable by electrophoretic separation of the vacuolar sap. Some of the basic peroxidases have formerly been described as an ionically bound cell-wall fraction. This fraction, however, was found to be an artifact produced by incomplete cell breakage. Reinvestigation of isolated cell walls confirmed that mainly acidic peroxidases are localized in the cell walls where they move freely or are bound. As a consequence of former and present results we think it probable that all of the peroxidase isoenzymes are secretory proteins because they have to be transported from the sites of synthesis in the cytoplasm to the sites of function, the extracytoplasmic spaces, cell wall (acidic peroxidases), and vacuole (basic peroxidases).Abbreviation ER endoplasmic reticulum - PAGE polyacrylamide gel electrophoresis     

Response of isolated axonal preparations to hyperosmoticity: evidence for a cellular volume regulation.

When submitted to a hyperosmotic stress, isolated axons of Callinectes sapidus shrink. Volume regulation is observed if the experiment is carried out by using serum from a crab adapted to sea water. 3' : 5'-AMP and dibutyryl AMP are also effective. A compound isolated from the hemolymph and having a molecular weight close to 10 000 mimics the effects of the serum and induces a partial regulation of the axonal volume.     

Transport of heptafluorostearate across model membranes. Membrane transport of long-chain fatty acid anions I

Heptafluorostearic acid, an isogeometric derivative of stearic acid, has a pK(a) value of about 0.5. To evaluate the suitability of heptafluorostearate as model compound for anions of long-chain fatty acids in membrane transport, monolayer and liposome studies were performed with lipid mixtures containing phospholipids;-cholesterol-heptafluorostearate or stearate (100:40:20 molar ratios). Transfer of heptafluorostearate and stearate from liposomes to bovine serum albumin (BSA) was followed by measuring the intrinsic fluorescence of BSA. The percentage of heptafluorostearate, equivalent to the amount placed in their outer monolayer, transferred from liposomes (120;-130 nm diameter) to BSA was 55.7 +/- 3.7% within 10 min at 25 degrees C and 55 +/- 2% within 5 min at 37 degrees C. Slow transfer of 22.7 +/- 2.5% of heptafluorostearate at 25 degrees C followed with a half-life of 2.3 +/- 0.4 h and of 20 +/- 4% at 37 degrees C with a half-life of 0.9 +/- 0.1 h until the final equilibrium distributions between BSA and liposomes were reached, 79 +/- 6% to 21 +/- 5% at 25 degrees C and 75 +/- 5% to 25 +/- 4% at 37 degrees C. The pseudounimolecular rate constants for flip-flop of heptafluorostearate equal k(FF,25) = 0.24 +/- 0.05 h(-) and k(FF,37) = 0.6 +/- 0.1 h(-), respectively. By comparison, transfer of stearate required only 3 min to reach equilibrium distribution.The difference between heptafluorostearate and stearate may be explained by a rapid flip-flop movement of the un-ionized fatty acids which exist in different concentrations in accordance with their pK(a) values. Half-life of flip-flop of heptafluorostearate makes it suitable to study mediated membrane transport of long-chain fatty acid anions.