Localization and Substrate Specificity of Glycosidases in Vacuoles of Nicotiana rustica

Vacuoles isolated from Nicotiana rustica var brasilia have been shown to contain significant levels of glycosidase activity when assayed using p-nitrophenyl-glycosides as substrates. The substrate specificity for the glycosidases in the vacuolar fraction closely paralleled that found in the protoplasts, and the leaf tissue from which the vacuoles were isolated. The substrate specificity of the vacuolar enzyme(s) was different from glycosidic activity found in the commercial digestive enzyme preparations used to isolate the protoplasts from leaf tissue. It was demonstrated that 70 to 90% of the glycosidases that were found in the protoplasts appeared to be localized within the vacuole, when the p-nitrophenyl substrates α- and β-;d-galactose, β-d-glucose, and α-d-mannose were used. Neither the vacuolar nor the protoplast enzymes were active towards the naturally occurring phenolic glycoside, rutin. α-Mannosidase appears to be a valuable marker enzyme for vacuoles isolated from mesophyll leaf cells of tobacco.     

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 6 μg/10⁶ 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 Tulipa 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.     

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.     

Subcellular localization of spermidine synthase in the protoplasts of chinese cabbage leaves

Previous studies on the presence of spermidine synthase (EC 2.5.1.16) in the protoplasts of Chinese cabbage (Brassica pekinensis var Pak Choy) leaves had detected a small but significant fraction of the enzyme in a crude chloroplast fraction (Cohen, Balint, Sindhu 1981 Plant Physiol 68: 1150-1155). To establish whether this enzyme is truly a chloroplast component, we have isolated purified intact chloroplasts from protoplasts by density gradient centrifugation in silica sols (Ludox AM). Such chloroplasts contained all of the diaminopimelate decarboxylase (EC 4.1.1.20) of the protoplasts, but were essentially devoid of spermidine synthase. Control experiments showed that the latter had not been inactivated under conditions of isolation, purification, and assay of the intact chloroplasts. Isolation and assay of protoplast vacuoles in a further examination of the supernatant fluid containing the enzyme revealed a significant fraction of the enzyme in the vacuole fraction. However this fraction was found to contain similar proportions of a soluble enzyme, glucose 6-phosphate dehydrogenase. It has been concluded that vacuolar fractions are difficultly separable from soluble cytoplasmic material, which is probably the only compartment containing spermidine synthase.     

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.     

Subcellular Distribution of O-Acetylserine(thiol)lyase in Cauliflower (Brassica oleracea L.) Inflorescence

The subcellular localization of O-acetyiserine(thiol)lyase (EC 4.2.99.8) in nongreen tissue from higher plants has been studied using purified proplastids, mitochondria, and protoplasts from cauliflower (Brassica oleracea L.) buds as a source of subcellular fractions. O-Acetylserine(thiol)lyase has been detected in both organelles (proplastids and mitochondria) and a cytosolic extract obtained by protoplast fractionation. We confirmed these observations, demonstrating that a form of the enzyme different in global charge and separated from others by anion-exchange chromatography corresponded to each subcellular location. Our observations are consistent with the need for cysteine biosynthesis in each subcellular compartment where the synthesis of proteins occurs.     

Surface-Bound Nuclease of Staphylococcus aureus: Localization of the Enzyme

The cellular localization of staphylococcus nuclease, previously known as an exoenzyme, was investigated, and the following results were obtained. (i) When Staphylococcus aureus cells were converted to protoplasts by cell wall lytic enzyme L-11 (a bacteriolytic enzyme purified from Flavobacterium sp. which specifically hydrolyzes amide and peptide linkages of murein layers), over 80% of the cell-bound nuclease was released into the surrounding sucrose medium. (ii) The cell-bound nuclease was associated with the cell-wall membrane fraction of mechanically disrupted cells. (iii) The nuclease activity of cell-wall membrane fractions from cells during early and late stages of protoplast formation were compared. Less activity was found in the late stage. These results suggest that nuclease may be located at or near the surface of the cells. The distribution of cell-bound nuclease in the cell-wall membrane fraction varied with the growth conditions of S. aureus. The activity of alkaline phosphatase, another surface enzyme, was also investigated. Less of this enzyme than nuclease was released when the cells were converted to protoplasts.     

Intracellular Localization of the Neurotoxin 2,4-Diaminobutyric Acid in Lathyrus sylvestris L. Leaf Tissue

The intracellular distribution of the neurotoxin 2,4-diaminobutyric acid (DABA) in mature leaves of the perennial legume Lathyrus sylvestris L. var `Lathco' (flatpea) was determined using subcellular fractions from mesophyll protoplasts. Chloroplasts contained about 15% of the cellular DABA. At least 75% of the DABA was vacuolar, based on the assumptions that each protoplast contained a single vacuole and that acid phosphatase occurred exclusively in the vacuole. DABA was not detectable in peroxisomal and mitochondrial fractions. Because the vacuole is not a major site of amino acid synthesis, this distribution implicates synthesis of DABA within chloroplasts with subsequent transport to and storage within the vacuoles of the mesophyll cells.     

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.     

Vacuolar localization of 1-sinapolglucose: l-malate sinapoyltransferase in protoplasts from cotyledons of Raphanus sativus

The distribution of l-malate, sinapic acid esters and 1-sinapoylglucose: l-malate sinapoyltransferase (SMT) which catalyzes the synthesis of sinapoyl-l-malate were examined in preparations of protoplasts obtained from cotyledons of red radish (Raphanus sativus L. var. sativus). Vacuoles isolated from the protoplasts contained all of the SMT activity, all of the accumulated sinapic acid esters and about 50% of free l-malate present initially in the protoplasts. An esterase activity, acting on 1-sinapoyglucose, was found to be exclusively localized in the cytoplasm and a large proportion was found to be recoverable in a 100 000-g pellet obtained from protoplast lysates. The vacuoles were obtained after lysis of the protoplasts by osmotic shock and purification on a Ficoll gradient. The cytoplasmic contamination of vacuole preparations was found to be about 10%, as judged by enzymatic markers and microscopic inspection. No SMT activity was found in a 100 000-g pellet obtained from vacuole lysates. The results indicate that biosynthesis of sinapoyl-l-malate takes place within the central vacuoles of redradish cotyledons.Abbreviation SMT 1-sinapoylglucose: l-malate sinapol-transferase     

Reduction of N-acetyl methionine sulfoxide in plants

An enzymic activity which catalyzes the reduction of N-acetyl-methionine sulfoxide to l-N-acetyl-methionine has been observed in a wide variety of plant tissues. Its activity depended on the presence of dithiotreithol in the incubation medium. l-Methionine-sulfoxide was essentially inactive as a substrate. Of all the physiological reductants tested, only thioredoxin partially replaced dithiothreithol. When fractions obtained by gradient centrifugation of gently disrupted barley protoplasts were assayed for the reductase, the activity was largely associated with chloroplasts although approximately 15% was found in the cytosolic compartment. The enzyme, isolated from spinach chloroplasts, had a broad pH optima between 7.0 and 8.0, and its K_m for N-acetyl methionine sulfoxide is 0.4 millimolar. The possible participation of this ubiquitous enzyme in enzyme regulation is discussed.     

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.     

Isoenzymes of Glutamine Synthetase in Roots of Pea (Pisum sativum L. cv Little Marvel) and Alfalfa (Medicago media Pers. cv Saranac)

Cell organelles have been isolated from protoplast lysates and total homogenates obtained from root tips of Pisum sativum L. (cv Little Marvel) and Medicago media Pers. (cv Saranac) grown in hydroponics with nitrate nutrient solutions. Density-gradient and differential centrifugation procedures have been used to prepare mitochondria-and plastid-enriched fractions in which glutamine synthetase (GS) activity was estimated. Even when purified protoplasts were gently ruptured, significant breakage of plastids occurred during preparation as shown by the high proportion of nitrite reductase recovered in the soluble fraction. Of the total GS activity recovered, up to 20% was associated with the plastid fraction, depending on the source of plant material and the GS assay utilized; when corrected for recovery of the plastid marker nitrite reductase, it was calculated that 15 to 57% of alfalfa and 14 to 64% of pea root GS was located in the plastids. A true biosynthetic assay in which glutamine production was monitored by high performance liquid chromatography was devised to estimate the physiological significance of the transferase and the semibiosynthetic assays currently used for activity measurements. When compared with the true and semibiosynthetic assays, the transferase assay for GS appeared to underestimate the root plastid enzyme. Root plastid GS was partially purified by ion-exchange chromatography, and results show that the isoenzyme found in root plastids is different from chloroplastic or cytosolic GS.     

Reversible light-activation of ribulose bisphosphate carboxylase/oxygenase in isolated barley protoplasts and chloroplasts

The enzyme ribulose-1,5-bisphosphate carboxylase/oxygenase displayed near-maximal activity in isolated, intact barley (Hordeum vulgare L. cv. Pennrad) mesophyll protoplasts. The carboxylase deactivated 40 to 50% in situ when protoplasts were dark-incubated 20 minutes in air-equilibrated solutions. Enzyme activity was fully restored after 1 to 2 minutes of light. Addition of 5 millimolar NaHCO₃ to the incubation medium prevented dark-inactivation of the carboxylase. There was no permanent CO₂-dependent activation of the protoplast carboxylase either in light or dark. Activation of the carboxylase from ruptured protoplasts was not increased significantly by in vitro preincubation with CO₂ and Mg²⁺. In contrast to the enzyme in protoplasts, the carboxylase in intact barley chloroplasts was not fully reactivated by light at atmospheric CO₂ levels. The lag phase in carbon assimilation was not lengthened by dark-adapting protoplasts to low CO₂ demonstrating that light-activation of the carboxylase was not involved in photosynthetic induction. Irradiance response curves for reactivation of the the carboxylase and for CO₂ fixation by isolated barley protoplasts were similar. The above results show that there was a fully reversible light-activation of the carboxylase in isolated barley protoplasts at physiologically significant CO₂ levels.     

Subcellular Localization of Proteases in Developing Leaves of Oats (Avena sativa L.)

The distribution and subcellular localization of the two major proteases present in oat (Avena sativa L. cv Victory) leaves was investigated. Both the acidic protease, active at pH 4.5, and the neutral protease, active at pH 7.5, are soluble enzymes; a few percent of the enzyme activity was ionically bound or loosely associated with organellar structures sedimenting at 1000g. On the average, 16% of the acidic protease could be washed out of the intercellular space of the leaf. Since isolated protoplasts contained correspondingly lower activities as compared to crude leaf extracts, part of the acidic activity is associated with cell walls. No neutral protease activity was recovered in intercellular washing fluid. Of the activities present in protoplasts, the acidic protease was localized in the vacuole, whereas the neutral protease was not. The localization of the acidic protease in vacuoles did not change during leaf development up to an advanced stage of senescence, when more than 50% of the leaf protein had been degraded. These observations indicate that protein degradation during leaf senescence is not due to a redistribution of acidic protease activity from the vacuole to the cytoplasm.     

Evacuolation and enucleation of mesophyll protoplasts in self-generating percoll gradients

Mesophyll protoplasts from Brassica oleracea, B. napus, Nicotiana tobaccum and Solanum tuberosum were isolated and subjected to uttracentrifugation at 65000g for 30 min in percoll solutions containing various strengths of salt and osmotic stabilizing agents. After centrifugation, the self-generated percoll gradients were evaluated for their effectiveness in protoplast evacuolation and enucleation. The vacuoles, cell debris, evacuolated protoplasts and enucleated protoplasts were separated. Factors that affected evacuolation and enucleation in the percoll gradients were described. Mesophyll protoplasts produced by epidermis peeling and short enzyme incubation periods were more easily evacuolated and enucleated than those produced by leaf-slicing and long incubation periods. Lower centrifugal force at 25000g for 80 min was also successful in evacuolating and enucleating the mesophyll protoplasts. A green band that contained nearly pure evacuolated protoplasts, of which 45% were enucleated protoplasts, was obtained from the self-generated percoll gradient. Rhodamine 123 staining of mitochondria indicated that the evacuolated protoplasts were metabolically active and were capable of regenerating the vacuole and cell wall. Cell divisions were also observed when the evacuolated protoplasts were cultured.     

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.     

Isolation of NADH Oxidation System from the Plasmalemma of Corn Root Protoplasts

A plasmalemma-bound NADH oxidation system (Lin 1982 Proc Natl Acad Sci USA 79: 3773-3776) in corn root protoplasts was isolated by a mild treatment of intact protoplasts with trypsin. The majority of NADH stimulated O₂ consumption activity of the protoplasts could be recovered in the supernatant isolated from the intact protoplasts which have been treated with trypsin. The activation energy of NADH oxidation in the supernatant is similar to that of the intact protoplasts (8.7 versus 9.4 kilocalories per mole per degree). Unlike that of the intact protoplasts, an Arrhenius plot of the temperature response (from 5 to 25°C) of the activity in the supernatant shows no transition suggestive of a dissociation of the enzyme from the membrane. Trypsin treatment did not affect K⁺ uptake into cell volume of the protoplast. However, the NADH-stimulated K⁺ uptake and the increase of cell volume were greatly reduced. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of trichloroacetic acid-precipitated protein from the supernatant showed one extra peptide band with ~42 kilodalton molecular weight.     

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.     

Effect of path or sink anoxia on sugar translocation in roots of maize seedlings

The subcellular and developmental distribution of β-cyanoalanine synthase (EC 4.4.1.9), which catalyzes the reaction between cysteine and HCN to form β-cyanoalanine and H₂S, were investigated in barley (Hordeum vulgare) leaves. Total leaf activity was 1.1 micromoles per minute per gram fresh weight. Sucrose density gradients of lysed mesophyll protoplasts of barley revealed the exclusive or predominant localization of β-cyanoalanine synthase in the mitochondria. The enzyme was absent from both vacuole and chloroplast fractions.

β-Cyanoalanine synthase activity was distributed over the entire length of the barley leaf. Activity was dependent on the developmental stage, with a 3.5-fold higher activity in the oldest (apical) compared to the youngest (basal) parts of the leaf. The corresponding difference in activity for mesophyll protoplasts isolated from these parts was 7.5-fold. In younger leaf seagments, the nonchlorophyllous tissues accounted for up to 70% of the total β-cyanoalanine synthase activity. These results are discussed with reference to the formation of HCN as a substrate in barley leaves.