Subcellular localization of enzymes of anthocyanin biosynthesis in protoplasts

Flavanone synthase, chalcone-flavanone isomerase and UDP-glucose; anthocyanidin-3-O-glucosyltransferase activities of protoplasts and subcellular fractions of protoplasts of Hippeastrum and Tulipa were investigated. Subcellular fractions studied were intact vacuoles, cytosol and particulate components of protoplasts less the vacuole. The cytosol fraction had the highest activity of the three enzymes studied. Results similar to those found for Hippeastrum were obtained with fractions from leaves and petals of Tulipa. The increase in flavanone synthase activity in the cytosol fraction from petals of Hippeastrum during development paralleled the increase in anthocyanin content of the petals.     

Content and vacuole/extravacuole distribution of neutral sugars, free amino acids, and anthocyanin in protoplasts

Neutral sugar, free amino acid, and anthocyanin levels and vacuole/extravacuole distribution were determined for Hippeastrum and Tulipa petal and Tulipa leaf protoplasts. Glucose and fructose, the predominant neutral monosaccharides observed, were primarily vacuolar in location. Glutamine, the predominant free amino acid found, was primarily extravacuolar. γ-Methyleneglutamate was identified as a major constituent of Tulipa protoplasts. Qualitative characterization of Hippeastrum petal and vacuole organic acids indicated the presence of oxalic, malic, citric, and isocitric acids. Data are presented which indicate that vacuoles obtained by gentle osmotic shock of protoplasts in dibasic phosphate have good purity and retain their contents.     

Membrane-bound ATPase of intact vacuoles and tonoplasts isolated from mature plant tissue.

Intact vacuoles were isolated from petals of Hippeastrum and Tulipa (Wagner G.J. and Siegelman, H.W. (1975) Science 190, 1298--1299). The ATPase activity of fresh vacuole suspensions was found to be 2--3 times that of protoplasts from the same tissue. 70--80% of the ATPase activity of intact vacuoles was recovered in tonoplast preparations. The antibiotic Dio-9 at 6mug/10(6) vacuoles or protoplasts causes 40% inhibition. However, only the protoplast ATPase is sensitive to oligomycin. N,N'-dicyclohexylcarbodiimide (DCCD) slightly stimulates ATPase activity in both vacuole and protoplast suspensions, whereas ethyl-3-(3-dimethylaminopropyl carbodiimide) (EDAC) strongly inhibits. Spectrophotometric studies show that in the petal the vacuolar contents have a pH of 4.0 for Tuplipa and 4.3 for Hippeastrum, whereas the intact isolated vacuole has an internal pH of 7.0 (in pH 8.0 buffer) for (Tulipa and about 7.3 for Hippeastrum. Internal ion concentrations of 150, 46, 30, 30 and 6 mM were found for K+, Na+, Mg2+, Cl-, and Ca2+ respectively, which are about the same as those in protoplasts.     

An active proton pump of intact vacuoles isolated from Tulipa petals

Anthocyanin pigments within Tulipa petal vacuoles provide the means for real-time spectrophotometric monitoring of vacuolar sap pH and for studying ATP-dependent proton transport in isolated, intact vacuoles. Spectra of petal extracts were used to select empirically those wavelengths giving an approximately linear variation in anthocyanin absorbance with pH over a pH range of interest. A sensitive single-beam spectrophotometer with vertical optics was used to minitor absorbance changes of intact, settled vacuoles. Substrates and inhibitors of vacuolar ATPase (Lin, W., Wagner, G.J., Siegelman, H.W. and Hind, Q. (1977) Biochim. Biophys. Acta 465, 110–117) were added to probe proton transport. Acidification of the vacuole sap occurred following addition of MgATP, but not CaATP. Proton accumulation was inhibited by 10 μM Dio 9, an inhibitor of tonoplast ATPase in vitro, and the proton gradient established by addition of MgATP was dissipated after addition of 10 μM CCCP. No pumping response was observed with intact protoplasts. Potential differences across the tonoplast were directly measured by impaling vacuoles with glass microelectrodes. Potential differences of 10–20 mV (inside positive) were recorded when vacuoles were suspended in 0.7 M mannitol/10 mM Hepes buffer (adjusted to pH 8.0 with KOH), and 0.5 mM dithiothreitol. Addition of MgATP increased the potential difference by 2–5 mV.     

Vacuole/Extravacuole distribution of soluble protease in hippeastrum petal and triticum leaf protoplasts

The subcellular distribution of soluble protease in anthesis-stage, anthocyanin-containing Hippeastrum cv. Dutch Red Hybrid petal protoplasts has been reevaluated and that of Triticum aestivum L. var. Red Coat leaf protoplasts determined using ¹²⁵I-fibrin as a protease substrate and improved methods for protoplast and vacuole volume estimation. Results indicate that about 20% of the Hippeastrum petal-soluble protease and about 90% of the wheat leaf-soluble protease can be assigned to the vacuole. Protoplast isolation enzyme labeled with ¹²⁵I has been used to assess the efficiency of removing isolation enzyme from protoplasts by repeated washing and by separation of protoplasts from debris using density centrifugation. Results of these studies suggest that protoplasts prepared by both methods retain low levels of isolation enzyme. However, when protoplasts prepared by either method were lysed with washing medium lacking osmoticum, little isolation enzyme contaminated the lysates.     

Subterminal polygalacturonase, a nonmacerating enzyme, attacks pectate from the reducing end

Nicotine was shown to be associated with mature vacuoles isolated from protoplasts of Nicotiana rustica. The vacuolar preparations also contained high levels of acid phosphatase, ATPase, and approximately 30% of the soluble protoplastic protein. The contamination of the vacuolar isolate by chlorophyll, succinate dehydrogenase, and NADPH cytochrome c reductase (markers for chloroplasts, mitochondria, and endoplasmic reticulum) was low. The enzymic activity associated with the vacuoles was not due to the exogenously supplied digestive enzymes used in the preparation of the protoplast. The relatively easy isolation of tobacco vacuoles makes this an excellent system for biochemical investigations of the vacuole.     

Subcellular Localization of Anthocyanin Methyltransferase in Flowers of Petunia hybrida

The subcellular localization of the enzyme anthocyanin-methyltransferase was studied in cells (protoplasts) obtained from the upper epidermis of petals of Petunia hybrida Hort. Vacuoles were isolated from protoplasts to ascertain the possible presence of the enzyme in these organelles. The recovery of methyltransferase activity in vacuole-enriched fractions equalled that of the cytosolic marker enzyme glucose-6-phosphate dehydrogenase. The relative activity of methyltransferase in the vacuole fraction was one tenth of that in the protoplast. Neither whole protoplasts nor isolated vacuoles contained inhibitors of methyltransferase activity. Examination of fractions obtained by differential centrifugation of a protoplast lysate showed that the major part of the methyltransferase activity was cytosolic. Activity found in a 130,000g pellet was due to nonspecific adhesion to membranes. The results indicate that terminal steps of anthocyanin biosynthesis take place in the cytosol. They do not lend support to the notion that the vacuole might be involved in (part of) this process.     

Localization of Acid hydrolases in protoplasts: examination of the proposed lysosomal function of the mature vacuole

The development of techniques to isolate and purify relatively large quantities of intact vacuoles from mature tissues permits direct biochemical analysis of this ubiquitous mature plant cell organelle. Vacuoles and a fraction enriched in soluble cytoplasmic constituents were quantitatively prepared from Hippeastrum flower petal protoplasts. Vacuolar lysate and soluble cytoplasmic fractions were examined for acid hydrolase activities commonly associated with animal lysosomes, and pH optima were determined. Esterase, protease, carboxypeptidase, β-galactosidase, α-glycosidase and β-glycosidase, not found in the vacuole lysate fraction, were components of the soluble cytoplasmic fraction. Acid phosphatase, RNase and DNase were present in both fractions. Vacuolar enzyme activities were also examined as a function of flower development from bud through senescent stages. The data obtained are not consistent with the concept that the mature plant cell vacuole functions as a generalized lysosome.     

Isolation and partial characterization of vacuoles from tobacco protoplasts

Protoplasts from suspension-cultured cells of Nicotiana glutinosa L. were lysed in 0.3 molar sorbitol in 2 millimolar ethylenediaminetetraacetate-tris(hydroxymethyl) aminomethane (pH 7.5) to release intact vacuoles. The vacuoles were purified by centrifugation in a Ficoll step gradient. About 11% of the vacuoles and 13% of the acid phosphatase activity was recovered in the purified vacuole fraction, suggesting that the vacuole is the major site for acid phosphatase in these cells. NADH-cytochrome c reductase, malate dehydrogenase, and cytochrome c oxidase activities were reduced during vacuole purification. The majority of the adenosine 5′-triphosphate (ATP) hydrolytic activity of purified vacuoles was associated with nonspecific acid phosphatase and not with a transport ATPase. As judged by acid phosphatase distribution and electron microscopy, the effective density of vacuoles in a sucrose gradient was low (less than 1.1 grams per cubic centimeter), although an unequivocal estimate of the vacuole or tonoplast density was not possible from the experiments conducted.     

Determination of malate levels during the swelling of vacuoles isolated from guard-cell protoplasts

A method for the preparation of vacuoles from guard cells ofVicia faba L. is described. Vacuoles were released from guard-cell protoplasts by osmotic shock and purified on a Ficoll gradient. Contamination of the vacuoles was examined by assaying marker enzymes, such as fumarase, glucose-6-phosphate dehydrogenase, phosphofructokinase, acid phosphatase and mannosidase. Potassium ions in the incubation medium caused increases in the volume of the vacuoles by a factor of about 2.6, while the malate level remained unchanged. In contrast, malate synthesis was stimulated during the swelling phase when complete guard-cell protoplasts were exposed to K⁺. The possible role of K⁺ as an efficient osmotic effector is discussed.Abbreviations DEAE diethylaminoethyl - GCP guard-cell protoplast(s) - GCV guard-cell vacuoles(s) - MCP mesophyll cell protoplast(s) - MCV mesophyll cell vacuole(s)     

Distribution of Sorbitol, Neutral Sugars, Free Amino Acids, Malic Acid and Some Hydrolytic Enzymes in Vacuoles of Apple Cotyledons

Vacuoles of apple cotyledons (Malus pumila Mill. var. domesticaSchneid.) were obtained by purification with Ficoll densitygradient centrifugation after the protoplasts were lysed byboth osmotic shock and the addition of EDTA. High levels ofacid protease and carboxypeptidase activity were detected inthe vacuoles along with acid phosphatase, phosphodiesteraseand ATPase. The distribution of sorbitol and other sugars inthe vacuoles, the protoplast and extracellular free space wasdetermined. About 45, 60 and 90% of the sorbitol, glucose andsucrose, respectively, contained in whole tissue were foundin the extracellular free space, and 54% of the sorbitol inthe protoplast was detected in the vacuole. The sorbitol inthe vacuoles and the extravacuole of the protoplast was about80 and 70%, respectively, of the total sugar content of thecell. Arginine was the most abundant free amino acid in theprotoplast, and about 90% of it was contained in the vacuole.More than 80% of the total amino acids and 50% of the proteinwere also located in the vacuole, as well as most of the malate.The amounts of the total sugars, total amino acids, proteinand malate in the vacuoles were to 250, 400, 48 and 9 µg/10⁶cells, respectively. The results suggest that the vacuoles ofapple cotyledons contain a large pool of amino acids and proteinsrather than sugars, and have a close connection with proteinbody degradation. ¹ This paper is contribution A-l37 of the Fruit Tree ResearchStation. (Received January 20, 1982; Accepted May 18, 1982)     

Isolation and Characterization of Vacuoles from the Ergot Fungus Claviceps purpurea

Protoplasts of Claviceps purpurea were prepared by treatment of mycelium with a lytic mixture of snail gut enzyme and cellulase from Trichoderma viride. Such protoplasts could be efficiently lysed by Triton X-100 treatment at high osmotic pressure without Ca²⁺ or Mg²⁺, allowing the release of intact vacuoles in high yields. Vacuoles obtained from cells grown in modified Vogel medium (vegetative-type cells not producing alkaloids) were isolated and purified by centrifugation from a 5% Ficoll 400 (wt/vol) phase into the interphase between two layers, one containing 0.25 M each of mannitol and sucrose, and one containing 0.5 M mannitol. Vacuoles derived from cells grown in a medium favoring ergot alkaloid synthesis (sclerotia-like cells) were isolated by gentle centrifugation of filtered protoplast lysates without addition of Ficoll 400. Biochemical analyses of the vacuole fraction isolated from either kind of cell revealed their function as compartments harboring several hydrolytic enzymes. However, the enrichment of free amino acids in vacuoles of sclerotia-like cells was less pronounced than that in vacuoles of vegetative-type cells, indicating a difference in metabolic compartmentation in the two types of cells.     

Hydrolytic enzymes in the central vacuole of plant cells

The hydrolase content of vacuoles isolated from protoplasts of suspension-cultured tobacco cells, of tulip petals, and of pineapple leaves, and the sedimentation behavior of tobacco tonoplasts were studied. Three precautions were found to be important for the analysis of vacuolar hydrolases and of the tonoplast. (a) Purification of protoplasts in a Ficoll gradient was necessary to remove cell debris which contained contaminating hydrolases adsorbed from the fungal cell-wall-degrading enzyme preparation. (b) Hydrolase activities in the homogenates of the intact cells or the tissue used and of the purified protoplasts had to be compared to verify the absence of contaminating hydrolases in the protoplast preparation. (c) Vacuoles obtained from the protoplasts by an osmotic shock had to be purified from the lysate in a Ficoll gradient. Since the density of the central vacuole approximates that of the protoplasts, about a 10% contamination of the vacuolar preparation by surviving protoplasts could not be eliminated and had to be taken into account when the distribution of enzymes and of radioactivity was calculated.     

Maintenance carbon cycle in crassulacean Acid metabolism plant leaves : source and compartmentation of carbon for nocturnal malate synthesis

The reciprocal relationship between diurnal changes in organic acid and storage carbohydrate was examined in the leaves of three Crassulacean acid metabolism plants. It was found that depletion of leaf hexoses at night was sufficient to account quantitatively for increase in malate in Ananas comosus but not in Sedum telephium or Kalanchoë daigremontiana. Fructose and to a lesser extent glucose underwent the largest changes. Glucose levels in S. telephium leaves oscillated diurnally but were not reciprocally related to malate fluctuations.

Analysis of isolated protoplasts and vacuoles from leaves of A. comosus and S. telephium revealed that vacuoles contain a large percentage (>50%) of the protoplast glucose, fructose and malate, citrate, isocitrate, ascorbate and succinate. Sucrose, a major constituent of intact leaves, was not detectable or was at extremely low levels in protoplasts and vacuoles from both plants.

In isolated vacuoles from both A. comosus and S. telephium, hexose levels decreased at night at the same time malate increased. Only in A. comosus, however, could hexose metabolism account for a significant amount of the nocturnal increase in malate. We conclude that, in A. comosus, soluble sugars are part of the daily maintenance carbon cycle and that the vacuole plays a dynamic role in the diurnal carbon assimilation cycle of this Crassulacean acid metabolism plant.

     

Vacuolar contents of fruit subepidermal cells from vitis species

Enzymic treatment of mature, anthocyanin-containing grape berry sub-epidermal tissues from DeChaunac grapes released intact protoplasts. Filtration of the protoplast suspension through glass wool under mild suction resulted in the release of vacuoles. The total and individual contents of anthocyanins, flavonol glycosides, hydroxycinnamic acid esters, sugars, organic acids, and cations were determined in both tissue and vacuole preparations. A method for pH determination in intact vacuoles is reported. Based on the qualitative and quantitative anthocyanin composition, the average pH of the vacuoles was determined to be 2.7 (sd +/- 0.17). The data suggest that anthocyanins are present in fruit subepidermal tissues in a noncomplexed form.     

Isolation of tonoplast vesicles from tobacco protoplasts

Vacuoles were isolated from protoplasts of Nicotiana glutinosa by the method of Mettler and Leonard (Plant Physiol 1979 64: 1114-1120) with minor modifications so that the number of intact protoplasts contaminating the vacuole preparation was reduced to less than 1% (by number). Isopycnic centrifugation of a [³H]choline-labeled, sonicated vacuole preparation on linear 5 to 40% sucrose gradients indicated that tonoplast vesicles equilibrated at a density of about 1.12 grams per cubic centimeter. When tonoplast vesicles were isolated on discontinuous sucrose density gradients substrate specific ATPase activity was not found to be associated with this membrane fraction. These results are discussed in terms of the energetics of ion transport through the tonoplast membrane.     

Transport and subcellular localization of polyamines in carrot protoplasts and vacuoles

Putrescine and spermidine uptake in carrot (Daucus carota L., cv “Tip top”) protoplasts and isolated vacuoles was studied. Protoplasts and vacuoles accumulated polyamines very quickly, with maximum absorption within 1 to 2 minutes. The insertion of a washing layer containing 100 millimolar unlabeled putrescine or spermidine did not change this pattern, but strongly reduced the uptake of putrescine and spermidine in protoplasts and in vacuoles. The dependence of spermidine uptake on the external concentration was linear up to the highest concentrations tested in protoplasts, while that in vacuoles showed saturation kinetics below 1 millimolar (K_m = 61.8 micromolar) and a linear component from 1 to 50 millimolar. Spermidine uptake in protoplasts increased linearly between pH 5.5 and 7.0, while there was a distinct optimum at pH 7.0 for vacuoles. Preincubation of protoplasts with 1 millimolar Ca²⁺ affected only surface binding but not transport into the cells. Nonpermeant polycations such as La³⁺ and polylysine inhibited spermidine uptake into protoplasts. Compartmentation studies showed that putrescine and spermidine were partly vacuolar in location and that exogenously applied spermidine could be recovered inside the cells. The characteristics of the protoplast and vacuolar uptake system induce us to put forward the hypothesis of a passive influx of polyamines through the plasmalemma and of the presence of a carrier-mediated transport system localized in the tonoplast.     

Changes in biochemical composition of vacuoles isolated from Acer pseudoplatanus L. during cell culture

Vacuoles were isolated from Acer pseudoplatanus cell suspension culture using a one-step procedure involving the lysis of the protoplast plasmalemma through a gradient of Ficoll containing DEAE-Dextran. The vacuole suspensions were slightly contaminated by other organelles (less than 5%) and the isolated vacuoles readily accumulated neutral red. Since α-mannosidase was located exclusively in the vacuoles it was used as a convenient marker. It was shown that the number of vacuoles per protoplast decreased as the cell aged. Studies on the biochemical composition of the isolated vacuoles indicated that amino acids, organic acids and protein contents varied with the cell culture cycle, emphasizing the dynamic status of the vacuolar system in cell suspension cultures of Acer pseudoplatanus.     

Characteristics of ATPase from sugarcane protoplast and vacuole membranes

Characteristics of membrane-associated ATPase from commercial Hawaiian varieties of sugarcane ( Saccharum spp. hybrids) were investigated in preparations from sugarcane cell suspension culture and from stalk tissues of the intact plant. In order to examine comparable preparations, protoplasts and vacuoles, in turn, were obtained from both sources. ATPase from preparations of crude protoplast membranes and tonoplast had a pH optimum of 6 to 6.5. The relative effectiveness of divalent cations in stimulating ATPase was Mg²⁺ > Mn²⁺≥ Co²⁺ > Ca²⁺≥ Zn²⁺. Enzyme activity was not stimulated by K⁺, nor by other monovalent cations. Protoplasts and vacuoles from both sources showed significant acid phosphatase activity. Acid phosphatase activity was inhibited by molybdate, but ATPase activity was unaffected. Membrane preparations from protoplasts contained inorganic pyrophosphatase, but enzyme activity was low or not present in tonoplast preparations. Cell suspension and stalk tissue preparations hydrolyzed a large number of nucleoside di- and triphosphates. The hydrolysis is most likely due to a series of enzymes rather than a single enzyme. ATPase from protoplast and tonoplast preparations was inhibited 30–50% by diethylstilbestrol and sodium ortho-vanadate and was unaffected by ionophores. This study illustrates the complexity of phosphohydrolase activities in membrane preparations from sugarcane. The study, however, also illustrates substantial similarity in the behavior of these enzymes, whether they are derived from the plant itself or from cell cultures originating from comparable tissues of the plant.     

Evidence for RNA-Oligonucleotides in Plant Vacuoles Isolated from Cultured Tomato Cells

We have shown that highly purified vacuoles of suspension-cultured tomato (Lycopersicon esculentum) cells contain RNA-oligonucleotides, using two different approaches to label and detect RNA: (a) in vivo labeling of cellular RNA with [5-³H]uridine, followed by preparation of vacuoles from protoplasts and by quantification of radioactively labeled material; and (b) in vitro labeling and analysis on sequencing gels of nucleic acids prepared from tomato vacuoles and their identification as RNA. The intravacuolar location of the RNA found in vacuolar preparations was concluded from analyzing for RNA intact organelles after repeated flotation steps as well as ribonuclease A treatment. About 3% of the RNA in protoplasts was localized within vacuoles, exceeding by severalfold the contribution made by contamination with unlysed protoplasts and subcellular organelles. Investigation of the size distribution of vacuolar RNA revealed an oligonucleotide pattern strikingly different from that which would arise from contaminating protoplasts; vacuolar RNA fragments are considerably shorter than 80 nucleotides. Characterization of these oligoribonucleotides (3′-phosphorylated termini; relatively rich in pyrimidines) as possible products of tomato vacuolar ribonuclease I action, and, in addition, enzymatic hydrolysis of vacuolar RNA by inherent enzyme activities in lysed vacuole preparations support the hypothesis that plant vacuoles are involved in cellular nucleolytic processes.