Subcellular localization of acid proteinase in barley mesophyll protoplasts

Chloroplasts prepared from lysed protoplasts of barley mesophyll contain 2–8% of the total acid proteinase activity. This residual activity is not associated with intact chloroplasts isolated by means of density gradient centrifugation. Vacuoles isolated from lysed protoplasts contain 80–85% of the total acid proteinase activity, indicating that the enzyme(s) which is presumably responsible for the degradation of chloroplastic proteins is located largely in the central vacuoles of mesophyll cells.     

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.     

Transport of anions in isolated barley vacuoles : I. Permeability to anions and evidence for a cl-uptake system

The anion contents of young barley leaves and of mesophyll protoplasts from the leaves was compared. Anion loss from the protoplasts during isolation was small. Although only about 60% of the leaf cells were mesophyll cells, phosphate and sulfate contents of the mesophyll cells accounted for almost 90% of the leaf contents. Chloride accumulated in the leaf epidermis. The rapid isolation of vacuoles from mesophyll protoplasts permitted the determination of vacuolar ion concentrations. Sodium and nitrate levels were very low in the cytoplasm, and much higher in the vacuole. When barley plants were grown in the presence of low NaCl levels, chloride concentrations were comparable in cytoplasm and vacuole, and similar observations were made with sulfate. Cytoplasmic phosphate concentrations were close to 30 millimolar and potassium concentrations 100 millimolar. During a 30 minute incubation period at room temperature, anion contents of isolated vacuoles decreased considerably. Efflux of NO₃⁻ was faster than that of Cl⁻. Phosphate and sulfate crossed the tonoplast only slowly. 4,4′-Diisothiocyano-2,2′-stilbenedisulfonic acid partially inhibited the efflux of nitrate and, to a lesser extent, that of chloride. Decreased efflux was also observed in the presence of MgATP. In remarkable contrast, p-chloromercuribenzene sulfonate and HgCl₂ stimulated the efflux of nitrate and chloride, but not of phosphate. Labeled chloride was taken up by isolated vacuoles. The apparent K_m for chloride uptake at low chloride concentrations was 2.3 millimolar. At elevated chloride concentrations, chloride did not display saturation characteristics but, rather, characteristics of a diffusional process. Uptake was stimulated by ATP.     

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.     

Subcellular Location of NADP-Isocitrate Dehydrogenase in Pisum sativum Leaves

The subcellular location of NADP⁺-isocitrate dehydrogenase was investigated by preparing protoplasts from leaves of pea seedlings. Washed protoplasts were gently lysed and the whole lysate separated on sucrose gradients by a rate-zonal centrifugation. Organelles were located by marker enzymes and chlorophyll analysis. Most of the NADP⁺-isocitrate dehydrogenase was in the soluble fraction. About 10% of the NADP⁺-isocitrate dehydrogenase was present in the chloroplasts as a partially latent enzyme. Less than 1% of the activity was found associated with the peroxisome fraction. NADP⁺-isocitrate dehydrogenase was partially characterized from highly purified chloroplasts isolated from shoot homogenates. The enzyme exhibited apparent K_m values of 11 micromolar (NADP⁺), 35 micromolar (isocitrate), 78 micromolar (Mn²⁺), 0.3 millimolar (Mg²⁺) and showed optimum activity at pH 8 to 8.5 with Mn²⁺ and 8.8 to 9.2 with Mg²⁺. The NADP⁺-isocitrate dehydrogenase activity previously claimed in the peroxisomes by other workers is probably due to isolation procedures and/or nonspecific association. The NADP⁺-isocitrate dehydrogenase activity in the chloroplasts might help supply α-ketoglutarate for glutamate synthase action.     

Subcellular localization of proteases in wheat and corn mesophyll protoplasts

Mesophyll protoplasts were isolated from the leaves of wheat and corn seedlings. After purification the protoplasts were judged to be free of contaminating proteases in the isolation enzymes based on specific activity of the proteases in comparison to leaf tissue and their response to inhibitors that “differentiated” between leaf and isolation enzyme proteases. Wheat protoplasts showed rates of photosynthesis of 95 to 100 micromoles O₂ per milligram chlorophyll per hour, while corn exhibited rates of 35 to 85 micromoles O₂ per milligram chlorophyll per hour, indicating the intactness of the chloroplasts within the protoplasts. These chloroplasts were isolated from the protoplasts using the procedure of Robinson and Walker (1979 Arch Biochem Biophys 196: 319-323). Yields of 91 and 82% intact chloroplasts were obtained from wheat and corn, respectively, based on the distribution of ribulose bisphosphate carboxylase in wheat and NADP-malate dehydrogenase in corn. Vacuoles were obtained from the protoplasts using a modification of the techniques of Wagner and Siegelman (1975 Science 190: 1298-1299) and Saunders (1979 Plant Physiol 64: 74-78). The vacuoles were at least 98% free of protoplast contamination as determined by assaying for “marker” enzymes of chloroplasts, mitochondria, and endoplasmic reticulum. Assuming one vacuole per protoplast, the vacuoles contained 4% of the soluble protein of the protoplasts in wheat and 8% in corn. All the proteolytic activity associated with the degradation of ribulose bisphosphate carboxylase in the protoplasts could be accounted for by that localized within the vacuoles. Although the isolated chloroplasts always retained about 13% of the proteolytic activity of the protoplasts, this could be accounted for by that which became associated with the chloroplasts during their isolation.     

Isolation of amyloplasts from developing maize endosperm

Methods for the formation of protoplasts from developing maize endosperm and for the aqueous isolation of intact amyloplasts from such protoplasts are described. Protoplasts were obtained after incubating endosperm slices in a medium containing cellulase and pectolyase for 5 days at 4°C or 5 hours at 30°C. After purification in a Ficoll density gradient, the protoplasts were reptured by forcing the suspension through a Nitex mesh (20 micrometer) positioned at the lower end of a modified disposable syringe. The resulting filtrate was layered on a discontinuous Ficoll density gradient of 30, 15, and 10%. Each Ficoll solution contained 0.7 molar sucrose, 10 millimolar arginine, 10 millimolar dl-dithiothreitol, 50 millimolar 2-(N-morpholino)ethanesulfonic acid (pH 5.6), and 2 millimolar CaCl₂. After 3 hours in the cold, an amyloplast fraction 50 to 93% intact and free from cytoplasmic, mitochondrial, and glyoxysomal contamination was recovered in the 15% Ficoll layer. Amyloplast intactness was estimated by fluorescent microscopy and activity of certain amyloplast marker enzymes before and after rupture of the amyloplast membrane. Starch branching enzyme, ADPG-pyrophosphorylase, and nitrite reductase were used as amyloplast marker enzymes.     

Presence of the cyanogenic glucoside dhurrin in isolated vacuoles from sorghum

Large numbers of vacuoles (10⁶-10⁷) have been isolated from Sorghum bicolor protoplasts and analyzed for the cyanogenic glucoside dhurrin. Leaves from light-grown seedlings were incubated for 4 hours in 1.5% cellulysin and 0.5% macerase to yield mesophyll protoplasts which then were recovered by centrifugation, quantitated by a hemocytometer, and assayed for cyanogenic glucosides. Mature vacuoles, released from the protoplasts by osmotic shock, were purified on a discontinuous Ficoll gradient and monitored for intactness by their ability to maintain a slightly acid interior while suspended in an alkaline buffer as indicated by neutral red stain. Cyanide analysis of the protoplasts and the vacuoles obtained there from yielded equivalent values of 11 μmoles of cyanogenic glucoside dhurrin per 10⁷ protoplasts or 10⁷ vacuoles. This work supports an earlier study from this laboratory which demonstrated that the vacuole is the site of accumulation of the cyanogenic glucoside in Sorghum.     

Galactinol Synthase is an Extravacuolar Enzyme in Tubers of Japanese Artichoke (Stachys sieboldii)

Galactinol synthase (GS, UDP-α-d-galactose:1l-myo-inositol-1-O- α-d-galactopyranosyltransferase) is a key enzyme in the biosynthetic pathway of the raffinose family of oligosaccharides. The subcellular location of GS was studied in the parenchyma of stachyose-storing tubers of Japanese artichoke (Stachys sieboldii) by isolation of protoplasts and vacuoles. A comparison of the activities of GS, malate dehydrogenase, and alcohol dehydrogenase (extravacuolar markers) and α-mannosidase and β-N-acetylglucosaminidase (vacuolar markers) in parenchyma protoplasts with those of vacuoles isolated from them showed that GS was an extravacuolar enzyme.     

Regulation of Vacuolar pH of Plant Cells: I. Isolation and Properties of Vacuoles Suitable for P NMR Studies

For the first time, the ³¹P nuclear magnetic resonance technique has been used to study the properties of isolated vacuoles of plant cells, namely the vacuolar pH and the inorganic phosphate content. Catharanthus roseus cells incubated for 15 hours on a culture medium enriched with 10 millimolar inorganic phosphate accumulated large amounts of inorganic phosphate in their vacuoles. Vacuolar phosphate ions were largely retained in the vacuoles when protoplasts were prepared from the cells and vacuoles isolated from the protoplasts. Vacuolar inorganic phosphate concentrations up to 150 millimolar were routinely obtained. Suspensions prepared with 2 to 3 × 10⁶ vacuoles per milliliter from the enriched C. roseus cells have an internal pH value of 5.50 ± 0.06 and a mean trans-tonoplast ΔpH of 1.56 ± 0.07. Reliable determinations of vacuolar and external pH could be made by using accumulation times as low as 2 minutes. These conditions are suitable to follow the kinetics of H⁺ exchanges at the tonoplast. The ³¹P nuclear magnetic resonance technique also offered the possibility of monitoring simultaneously the stability of the trans-tonoplast pH and phosphate gradients. Both appeared to be reasonably stable over several hours. The buffering capacity of the vacuolar sap around pH 5.5 has been estimated by several procedures to be 36 ± 2 microequivalents per milliliter per pH unit. The increase of the buffering capacity due to the accumulation of phosphate in the vacuoles is, in large part, compensated by a decrease of the intravacuolar malate content.     

Isolation and culture of protoplasts from embryogenic suspension cultures of red fescue (Festuca rubva L.)

Protoplasts were isolated from fast-growing embryogenic suspension cultures of red fescue cv. Dawson (Festuca rubra L.) without agitation. The enzyme isolation solution was highly efficient at releasing protoplasts of greater than 95% viability (5×10⁶–10⁷ protoplasts per ml of packed cell volume). A three step procedure was followed for washing and transferring protoplasts from a solution high in inorganic salts to a medium containing glucose and sucrose. The addition of 30 mM sodium thiosulfate to the wash and culture media was found to be helpful in reducing the number of lysed protoplasts. Isolated protoplasts began to divide within 48–72 h when protoplasts were plated in agarose squares and surrounded by nurse cells (mixed nurse plating technique). Maximum colony formation (plating efficiency) was approximately 1%. Many of the colonies continued to grow and produced embryos when transferred to a medium consisting of half-strength MS salts, 4 mg/l 2,4-D, 3 g/l casein hydrolysate and 30 g/l sucrose. Upon transfer to hormone-free medium and exposure to light 16 h/day, many of the embryos germinated to produce green leaves and roots.Abbreviations BA Benzylaminopurine - 2,4-D 2,4-dicholorophenoxyacetic acid - DMSO dimethyl sulfoxide - MES 2-(N-morpholino)-ethanesulfonicn acid - MS Murashige and Skoog medium (1962) - UGC Ultraclone Growth Chamber - KM Kao and Michayluk medium (1975) - NAA Naphthalene acetic acid     

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.     

Optimization of protoplast isolation from NaCl stressed primary, secondary and tertiary calli derived from mature seeds of Bangladeshi indica rice cultivar Binnatoa

A standardized protocol was developed for the isolation of protoplasts from salt stressed primary, secondary and tertiary calli of the moderately salt tolerant indica rice land race Binnatoa. Calli were induced from mature seeds using MS2 callus induction media supplemented with 0, 50 and 100 mM NaCl. Subsequently cultures were maintained in the same medium for 1–2 passages with or without salt stress at the same concentrations. Large numbers of protoplasts (about 1.57–2.10×10⁵/ml) with high viability were isolated from both control and salt stressed (50 and 100 mM NaCl) secondary and tertiary calli compared with the primary calli. The mannitol concentraion in the isolation and washing media was gradually increased, based on salt concentrations in which 13–15% was the most compatible for the control and 50 mM NaCl stressed calli and 17% for the 100 mM NaCl stressed calli. Isolated protoplasts at a density of 1–1.5×10⁵/ml were cultured in MS1₁₅ medium by liquid culture or agarose droplets. The first division of protoplasts was observed 4–5 days after culture using either method. The agarose droplet method led to sustained division of protoplasts and microcolonies formed within 2 weeks. Although no microcalli or protocalli were observed the procedure described provides a method for the isolation of salt-stressed protoplasts in indica rice which avoids the need for laborious and time-consuming suspension cultures. Subsequent regeneration from calli, derived from these protoplasts is reported in a further publication.     

Isolation of protoplasts and vacuoles from storage tissue of red beet

A fast and efficient method is described for the isolation of protoplasts and vacuoles from storage tissue of Beta vulgaris L. The viability of the isolated protoplasts is indicated by the development within a few hours of plasma strands with active cyclosis as well as by transport activity.     

Identification of the leaf vacuole as a major nitrate storage pool

Highly purified vacuoles were isolated from protoplasts derived from green barley (Hordeum vulgare var. Numar) leaves, in order to determine their role as a NO₃⁻ storage sink. α-Mannosidase and acid phosphatase activities were used as markers to identify vacuoles, α-mannosidase being the more suitable. Nitrate and α-mannosidase, which were released from vacuoles destroyed during lysis of protoplasts, moved at unequal rates in the density gradient used for vacuole isolation. Purified vacuoles retained less NO₃⁻ than α-mannosidase during a single washing. Empirically determined corrections were used to account for NO₃⁻ movement in estimating the percentage of total cellular nitrate found in the vacuole. Vacuoles from plants grown in the presence of NO₃⁻ contained 58% of the total cellular NO₃⁻ and therefore represent a major NO₃⁻ storage pool.     

Translocation of photosynthates into vacuoles in spinach leaf protoplasts

A method was developed for the isolation of vacuoles from the mesophyll protoplasts of spinach leaf, employing the discontinuous Ficoll density gradient centrifugation technique. Isolated vacuole preparations were judged to be free from other organellar fractions based on the assays of marker enzyme activities of individual organelles.

Using this isolation method, a time-dependent translocation of ¹⁴C-labeled photosynthates into vacuoles was determined. In contrast to a significant transport of ¹⁴C organic acids such as malate and citrate within 10 to 15 minutes ¹⁴C neutral sugars and amino acids were barely transported into vacuoles during 40 minutes incubation, in spite of the fact that a relatively large amount of these compounds are found in the vacuoles. It was also found that a majority of [¹⁴C]sucrose remains in the cytosol, apparently not actively moving into the vacuoles. Overall results appear to suggest that vacuoles are not actively engaged in photosynthetic carbon metabolism in spinach leaf protoplasts.

     

Isolation and culture of protoplasts from cotyledons of Pinus coulteri D. Don.

A protocol was developed for the isolation and culture of protoplasts from the cotyledons of seedlings of Pinus coulteri D. Don. Incubation of cotyledon pieces in a mixture consisting of cellulase Onozuka R10 2%, Pectolyase Y-23 0.1%, mannitol 10%, CaCl₂ 500 mg/l and other macro and micro-nutrients yielded viable protoplasts. After 24 hours of culture in a complex nutrient medium, the protoplasts regenerated new cell walls and the first divisions were observed within 7–10 days. Small cell colonies were formed within 15–20 days, but these started to accumulate phenolics and no further growth of the colonies was observed.     

Isolation and Properties of Deoxyribonucleic Acid from Protoplasts of Cell Suspension Cultures of Ammi visnaga and Carrot (Daucus carota)

A procedure is described for the isolation of native DNA from protoplasts of ammi (Ammi visnaga) and carrot (Daucus carota) cells. Protoplasts were produced from 40 grams of fresh cells by enzyme hydrolysis and lysed with sodium dodecyl sulfate. The DNA was purified by treatment with pronase and ribonuclease. Final isolation was achieved by sucrose density gradient centrifugation.     

Isolation of Guard Cell Protoplasts from Mechanically Prepared Epidermis of Vicia faba Leaves

A method for isolating guard cell protoplasts (GCP) from mechanically prepared epidermis of Vicia faba is described. Epidermis was prepared by homogenizing leaves in a Waring blender in a solution of 10% Ficoll, 5 millimolar CaCl₂, and 0.1% polyvinylpyrrolidone 40 (PVP). Attached mesophyll and epidermal cells were removed by shaking epidermis in a solution of Cellulysin, mannitol, CaCl₂, PVP, and pepstatin A. Cleaned epidermis was transferred to a solution of mannitol, CaCl₂, PVP, pepstatin A, cellulase “Onozuka” RS, and pectolyase Y-23 for the isolation of GCP. Preparations made by this method included both adaxial and abaxial GCP and contained ≤0.017% mesophyll protoplasts, ≤0.6% mesophyll fragments, and no epidermal cell contaminants. Yields averaged 9 × 10⁴ protoplasts/leaflet and 98 to 100% of the GCP excluded trypan blue, concentrated neutral red, and hydrolyzed fluorescein diacetate. Isolated GCP increased in diameter by 2.2 micrometers after incubation in darkness in 10 micromolar fusicoccin, 0.4 molar mannitol, 5 millimolar KCl, and 1 millimolar CaCl₂. Illumination of GCP with 800 micromoles per square meter per second of red light resulted in alkalinization of their suspension medium. When 10 micromolar per square meter per second of blue light was superimposed onto the red light background, the medium acidified. Measurements of chlorophyll a fast fluorescence transients from isolated GCP indicated that GCP were capable of electron transport, and slow transients contained the “M” peak usually associated with a functional photosynthetic carbon reduction pathway.     

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.