Biosynthesis of oleanolic acid glycosides in protoplasts isolated from Calendula officinalis L. roots

Many medicinal plants contain oleanane saponins in roots, however, only scarce data on their biosynthesis in this organ are available so far, including our previous results concerning Calendula officinalis plant. Thus, the purpose of the present work was to confirm the presumable biosynthetic pathway of oleanolic acid glycosides in roots of young C. officinalis plants. First of all, the effective method of isolation of protoplasts from C. officinalis roots was established. Then, isolated root protoplasts were supplied with radioactive precursors, [2-¹⁴C] mevalonate (MVA) and [3-³H] oleanolic acid (OL) and their transformations were studied with comparison to results obtained with excised roots. The penetration of both precursors into protoplasts was more rapid and effective than in the case of excised roots. The labeling of sterols and OL during the incubation with MVA showed that the isoprenoid pathway leading to triterpenoids was operative in excised roots as well as isolated root protoplasts. Moreover, the transformations of OL into two series of its glycosides, i.e. glucosides and glucuronides were investigated. It has been shown that both series of OL glycosides are synthesized in isolated root protoplasts in the same way as in excised roots of young marigold plants.     

The mechanism of oleanolic acid monoglycosides transport into vacuoles isolated from Calendula officinalis leaf protoplasts

The uptake of [3-³H]-oleanolic acid 3-O-monoglucoside and 3-O-monoglucuronide into vacuoles isolated from Calendula officinalis leaf protoplasts was investigated under various conditions. The transport of monoglucoside was stimulated by ATP and pyrophosphate, and sensitive to protein-modifying agent as well as dissipaters of the membrane potential. On the contrary, the transport of monoglucuronide was not dependent on tonoplast energization and was affected only by a protein-modifying factor. Moreover, the kinetics of tonoplast transport of both monoglycosides was characterized as concentration-dependent with saturation phase. The obtained results indicate that oleanolic acid monoglucoside is transported to isolated vacuoles by an active, carrier-mediated and energy-dependent mechanism, whereas the transport of monoglucuronide is a passive, carrier-mediated process.     

The effect of pH and ATP on the transport of oleanolic acid monoglycosides into isolated vacuoles of Calendula officialis leaves.

The transport of oleanolic acid and its glycosides (3-O-monoglucuronide F and 3-O-monoglucoside I) into the vacuoles of C. officinalis leaves was studied. It was found that these monoglycosides are transported into the vacuolar space whereas free oleanolic acid only binds with the tonoplast. The transport of monoglycosides depends on pH of the medium, the optimum pH for monoglucoside I and monoglucuronide F being 6.0 and 7.0, respectively. Moreover, it was demonstrated that the transport of monoglucoside I, in contrast to that of monoglucuronide F, depends on ATP at 0.5-2.0 mM concentrations. The presented results indicate that different mechanisms underlie the transport of these two compounds into vacuoles.     

Exoamylase activity in vacuoles isolated from pea and wheat leaf protoplasts

Vacuoles isolated from pea (Pisum sativum), and wheat (Triticum aestivum) leaf protoplasts contained considerable activities of electrophoretically highly mobile exoamylases. Vacuoles from spinach (Spinacia oleracea) leaf and photoautotrophic Chenopodium rubrum suspension culture cell protoplasts were devoid of amylolytic activity. Endoamylase activity was in all cases associated primarily with the chloroplast.     

Polyribosomes in protoplasts isolated from tobacco leaves

Polyribosomes (polysomes), active in an amino acid incorporation system in vitro, were isolated from tobacco leaf protoplasts. A comparison of polysome profiles indicated that the polysome/monosome ratio is greatly decreased in isolated protoplasts as compared to the intact leaf. In isolated protoplasts, a marked accumulation of ribosomal subunits was also found. The division of protoplasts, as investigated in the 8-cell and callus stages, was associated with a(n) (at least) partial regeneration of polysome profiles characteristic for leaves. Plasmolysis of leaves attached to the plant had no great effect on the polysome profile. However, leaf excision per se resulted in a dramatic loss of polysomes, even when the leaf tissue was floated on water. It is concluded that the isolation of the cell from its normal environment, and not the osmotic stress and associated increase in RNase activity, is the most important factor responsible for the loss of polysomes in isolated protoplasts.Abbreviations EGTA ethylene glycol bis (2-aminoethyl ether)-tetraacetic acid - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - mRNA messenger ribonucleic acid - RNase ribonuclease - Tris tris(hydroxymethyl)aminomethane - TCA trichloroacetic acid     

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     

Flavonol content of guard cell and mesophyll cell protoplasts isolated from Vicia faba leaves

Guard cells of the lower epidermis of leaflets of Vicia faba L. cv. Weißkernige Hangdown contain several kaempferol 3,7-O-glycosides. This was demonstrated for the first time by the use of isolated, highly purified guard cell protoplasts for flavonol estimation and quantitation. From a total of ca 12 kaempferol glycosides, three were identified by comparative thin layer chromatography and high performance liquid chromatography as kaempferol 3-O-glucoside 7-O-rhamnoside (major component), 3-O-rhamnogalactoside 7-O-rhamnoside and 3,7-O-bisglucoside (minor components). On average, the total flavonol content was estimated to be 85 fmol protoplast⁻¹. From comparative investigations including alkaline-induced (green) fluorescence characteristics of flavonols and UV-microscopical studies we suggest that kaempferol glycosides are present in guard cells and epidermal cells in similar quantities, and that these compounds are in the vacuole.
By contrast, mesophyll protoplasts have a low flavonol content (one sixth that of guard cells). In spite of the different total flavonol contents, individual components of each cell-type are the same. However, they show differences in their quantitative distribution.     

The metabolism of [3-H]oleanolic acid and its monoglycosides in cytoplasm and vacuole of protoplasts isolated from Calendula officinalis leaves

Isolated protoplasts from C. officinalis leaves were supplied with [3-³H]oleanolic acid, its 3-O-monoglucoside and 3-O-monoglucuronide. Transformations of these compounds into two series of oleanolic acid glycosides, i.e. glucosides (derivatives of 3-O-monoglucoside) and glucuronides (derivatives of 3-O-monoglucuronide) in the extravacuolar space and the vacuole were investigated. In the cytoplasm free oleanolic acid is glycosylated to both monoglycosides and to higher glycosides. Monoglycosides are partly hydrolysed to free oleanolic acid and partly glycosylated to higher derivatives. The vacuole contains the same radioactive compounds as the extravacuolar space. However, it seems most likely that these compounds are transported there from the sites of their synthesis in the cytoplasm.     

Antidiabetogenic activity of oleanolic acid glycosides from medicinal foodstuffs

Oleanolic acid glycosides from several medicinal foodstuffs were found to show potent inhibitory activity on the increase of serum glucose levels in oral glucose-loaded rats. By examination of the structure-activity relationships, the 3-O-glucuronide moiety and the 28-carboxyl group in oleanolic acid glycosides were required to exert the hypoglycemic activity. Oleanolic acid glycosides were found to have neither insulin-like nor insulin-releasing activity, but they inhibited gastric emptying and glucose-uptake in the small intestine. Investigation of the mode of action revealed that the inhibition of gastric emptying was mediated by capsaicin-sensitive sensory nerves and the central nervous system. Furthermore, oleanolic acid glycosides were suggested to suppress the gastric emptying by stimulating the release and/or production of dopamine to act through dopamine2 receptors, which in turn causes the release of prostaglandins.     

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     

Amino Acid transport in protoplasts isolated from soybean leaves

We isolated large quantities of mesophyll protoplasts from source and sink leaves of soybean plants and examined them for amino acid uptake. Accumulation of amino acids in isolated protoplasts was linear for at least 40 minutes. Uptake kinetics revealed the presence of both saturable and linear components. Increasing external pH decreases the uptake. The uncoupler, carbonyl cyanide p-trifluoromethoxyphenylhydrazone at 15 micromolar inhibited and fusicoccin at 10 micromolar stimulated amino acid uptake. Our data are consistent with a proton-cotransport mechanism for the uptake of l-glutamine and α-amino isobutyric acid into soybean mesophyll cells.     

Regenerated cell wall of carrot protoplasts isolated from suspension-cultured cells

Protoplasts of Daucus carota L. cultured in a synthetic liquid medium resumed cell division after about 4 days of cultivation. During this lag period, nucleic acid and protein showed only slight increases but the protoplasts commenced cell-wall regeneration soon after the removal of lytic enzymes. The originally spherical protoplasts became ellipsoidal before they underwent division. Radioactive glucose and myo-inositol were readily utilized by the protoplasts. Most of the radioactivity, however, appeared in extracellular polysaccharides and only a small portion was deposited in the regenerated wall. The sugar composition of new cell wall, as studies by chemical analysis and incorporation of labelled precursors, was shown to be considerably different from that of normal cell wall.     

Quantitative characterization of protoplasts and vacuoles from suspension-cultured cells of Catharanthus roseus

A simple and efficient procedure for isolation of protoplasts and then vacuoles from cultured cells of Catharanthus roseus (L.) G. Don is presented. Protoplasts were disrupted by an osmotic shock and the vacuoles vere purified by flotation on a single-step gradient. A comparison of the content and concentration of solutes (proteins, sugars, organic acids, alkaloids, mineral ions) in protoplasts and cells showed that massive and selective losses occur for most solutes during protoplast preparation. These are attributed to the osmotic adjustment and changes of membrane permeabilities occurring during plasmolysis. Data concerning the size, yield and purity of the isolated vacuoles are discussed. By analysis of isolated vacuoles, the vacuolar concentration and localization of solutes within protoplasts have been determined. The limits of this latter approach are stressed, however. Some evidence in favour of the selection of a special class of vacuoles during isolation is reported and discussed.     

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)     

Identification and analysis of a gene from Calendula officinalis encoding a fatty acid conjugase

Two homologous cDNAs, CoFad2 and CoFac2, were isolated from a Calendula officinalis developing seed by a polymerase chain reaction-based cloning strategy. Both sequences share similarity to FAD2 desaturases and FAD2-related enzymes. In C. officinalis plants CoFad2 was expressed in all tissues tested, whereas CoFac2 expression was specific to developing seeds. Expression of CoFad2 cDNA in yeast (Saccharomyces cerevisiae) indicated it encodes a Delta12 desaturase that introduces a double bond at the 12 position of 16:1(9Z) and 18:1(9Z). Expression of CoFac2 in yeast revealed that the encoded enzyme acts as a fatty acid conjugase converting 18:2(9Z, 12Z) to calendic acid 18:3(8E, 10E, 12Z). The enzyme also has weak activity on the mono-unsaturates 16:1(9Z) and 18:1(9Z) producing compounds with the properties of 8,10 conjugated dienes.     

Secondary phenolic products in isolated guard cell,epidermal cell and mesophyll cell protoplasts from pea (Pisum sativum L.) leaves: Distribution and determination

Summary Guard cells and epidermal cells of the abaxial (lower) and adaxial (upper) epidermis ofPisum sativum L., mutant Argenteum, are the predominant sites of flavonoid accumulation within the leaf. This was demonstrated by the use of a new method of simultaneous isolation and separation of intact, highly-purified guard cell and epidermal cell protoplasts from both epidermal layers and of protoplasts from the mesophyll. Isolated guard and epidermal protoplasts retained flavonoid patterns of the parent epidermal tissue; quercetin 3-triglucoside and its p-coumaric acid ester as major constituents, kaempferol 3-triglucoside and its p-coumaric acid ester as minor compounds. Total flavonoid content in the lower epidermis was estimated to be ca. 80 fmol per guard cell protoplast and 500 fmol per epidermal cell protoplast. Protoplasts isolated from the upper epidermis had about 20–30% as much of these flavonoids. Mesophyll protoplasts retained only about 25 fmol total flavonoid per protoplast.By fluorescence microscopy, using the alkaline-induced yellow-green fluorescence characteristics of flavonols, we suggest that these flavonol glycosides are present in cell vacuoles. There was no indication for the presence of flavine-like compounds.Abbreviations uE adaxial (upper) epidermis - IE abaxial (lower) epidermis - GCP guard cell protoplasts - ECP epidermal cell protoplasts - MCP mesophyll cell protoplasts - PP protoplasts - HPLC high performance liquid chromatography - TLC thin layer chromatography - CC column chromatography - HOAc acetic acid