Bioconversions leading to minor cardiac glycosides in Convallaria majalis

The biosynthesis of two minor cardenolides in Convallaria majalis, sarhamnoloside and tholloside, was investigated by application of labelled cardenolide precursors to leaves. Evidence for the concomitant occurrence of alternative pathways differing in the sequence of hydroxylation reactions at C-11 and C-19 was obtained.     

Zur biogenese von strophanthidin-glykosiden: Convallatoxol als vorstufe von convallatoxin in Convallaria majalis

Labelled convallatoxin was isolated from leaves of Convallaria majalis after administration of convallatoxol-19-³H and convallatoxol-U-¹⁴C, resp. Oxidation of-CH₂OH → -CHO at the glycoside level therefore is a possible step in the biogenesis of strophanthidin glycosides.     

Subcellular localization of glucosyltransferases involved in cardiac glycoside glucosylation in leaves of Convallaria majalis

The glucosylation of convallatoxin and convallatoxol was investigated using homogenates and various subcellular fractions from leaves of Convallaria majalis. The enzyme activity reached a maximum about 5 weeks after the onset of flowering and was found distributed among the soluble and the light membrane fraction. Upon separation of the light membranes by sucrose density gradient centrifugation, glucosyltransferase activity was found solely in a fraction banding at a density of 1.07 g/cm³, which is thought to represent vacuole membranes.     

Cardiac glycoside interconversions at the subcellular level in Convallaria majailis

Further evidence for the biosynthetic sequence periplorhamnoside → convallatoxol → convallatoxin, proposed after experiments in vivo, was obtained with subcellular fractions of Convallaria majalis leaves. A NADPH-dependent monooxygenase tentatively localized on mitochondrial membranes converted periplorhamnoside into convallatoxol. In contrast the enzyme transforming convallatoxol into convallatoxin could be detected only in the soluble fraction. The conversion required NAD as a cofactor, thus the specifity observed is that of an alcohol dehydrogenase.     

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.     

Biogenese von cardenolid-glycosiden in Convallaria majalis: Umwandlungen auf der monoglycosidstufe

The sequence periplorhamnoside → convallatoxol → convallatoxin → convalloside,i.e. stepwise oxidation of C-19 followed by glucosidation, is one of the major biosynthetic routes of cardenolide metabolism in Convallaria majalis. Two different pathways lead to lokundjoside: one involving 5β-hydroxylation of rhodexin A, the other involving 11α-hydroxylation of periplorhamnoside. Glucosidation takes place mainly with convallatoxin and to a smaller extent with convallatoxol and rhodexin A.     

Immunological Identification of Proteinase Inhibitors I and II in Isolated Tomato Leaf Vacuoles

Proteinase inhibitor I has been identified and quantified in isolated vacuoles from tomato (Lycopersicon esculentum) leaves induced to accumulate inhibitors either by wounding or by supplying excised leaves with the wound hormone, proteinase inhibitor-inducing factor. Proteinase inhibitor II was also identified in the vacuoles but not quantified. Control vacuoles were prepared from unwounded plants that did not contain inhibitors. Vacuole to leaf cell ratios of inhibitors, chlorophyll, and several vacuolar and cytoplasmic enzymes were determined. The inhibitors were found almost entirely in the vacuoles. Acid phosphatase was located in control leaf vacuoles, but was found in both vacuoles and cytoplasm in induced leaves. Carboxypeptidase, induced by wounding, was found distributed between the vacuoles and cytoplasm of induced leaves. Low vacuole to leaf cell ratios of three cytoplasmic markers, triosephosphate isomerase, catalase, and chlorophyll, indicated that the isolated vacuoles were relatively free of intact protoplasts and cell debris.     

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.     

Isolation and Characterization of Vacuoles from Melilotus alba Mesophyll

Methods for the preparation of protoplasts and vacuoles from mesophyll tissues of sweet clover (Melilotus alba Desr.) are described. Vacuoles are obtained using a new procedure which involves lysis of the plasmalemma during a brief centrifugation of protoplasts through a diethylaminoethyl dextran layer. This method combines the release of vacuoles and their purification in one step. The contamination of vacuole preparations was found to be low, as judged by enzymic markers and microscopic inspection. The method described is rapid and gives a good yield of vacuoles without causing changes in osmotic pressure. Several hydrolases were found to be located in vacuoles from sweet clover, which were also examined for their amino acid content.     

Replication of cauliflower mosaic virus DNA in leaves and suspension culture protoplasts of cotton

Cauliflower mosaic virus (CaMV) replicated in protoplasts and in inoculated leaves of the non-host, cotton (Gossypium hirsutum, L.). Protoplasts prepared from suspension-cultured cotton cells were infected by incubation with liposome-encapsulated CaMV virions. During a 1-week culture period the amount of CaMV nucleic acid as detected by nucleic acid hybridization in the protoplasts increased significantly regardless of whether or not the protoplasts contained vacuoles. In leaves inoculated with CaMV virions or CaMV DNA, viral DNA sequences were found by leaf skeleton hybridization to be located in small circular areas. DNA extracted from ultracentrifugal pellets of homogenates of inoculated leaves contained circular, gapped CaMV DNA only when inocula contained CaMV virions, CaMV DNA, or partial nested dimer CaMV plasmid DNA. When plants had been heavily watered, the CaMV DNA recovered contained degraded CaMV DNA. The results suggest that the host range limitation for CaMV is not due to an inability to replicate or spread locally in inoculated leaves.     

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.

     

Cardenolide glycosides of Strophanthus divaricatus

The isolation and structures of 12 cardenolide glycosides from the leaves, stems and roots ofStrophanthus divaricatus is described.     

Desmosterol als biogenetische vorstufe für convallamarogenin

Labelled 4-¹⁴C-desmosterol, but not cholesterol, is used by plants of Convallaria majalis L. for the biosynthesis of convallamarogenin. It can therefore be concluded that precursors of cholesterol biosynthesis can in some cases be converted directly into steroidal sapogenins, the pathway via cholesterol not always being obligatory.     

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.     

Evidence that a part of cellular uridine of a tomato (Lycopersicon esculentum) cell suspension culture is located in the vacuoles

Cells, protoplasts and isolated vacuoles of a tomato (Lycopersicon esculentum) cell suspension culture were analyzed by high pressure liquid chromatography (HPLC) for the presence of uridine. It was found that the uridine content in 10⁸ cells or protoplasts varied between 70 and 150 nmol for different growth stages. The vacuolar location of a part of cellular uridine was evidenced by its co-migration (i) with α-mannosidase, a soluble vacuolar marker, in the gradient used for the purification of vacuoles and (ii) with α-mannosidase and vacuoles (counted microscopically) during repeated centrifugation of isolated vacuoles. Quantitatively, vacuoles sequestered about 13–35% of the amount of uridine present in protoplasts of different culture age. The possible origin of uridine in the vacuoles is discussed.     

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.     

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.     

Glycosylation in cardenolide biosynthesis

The glycosylation and deglycosylation of cardiac glycosides was investigated using cell suspension cultures and shoot cultures, both established from Digitalis lanata EHRH. plants, as well as isolated enzymes. Shoots were capable of glucosylating digitoxigenin, evatromonoside, digiproside, glucodigitoxigenin and digitoxin. Suspension cultured Digitalis cells glucosylated all the substrates mentioned but digiproside, whereas the UDP-glucosedependent cardinolide glucosyltransferase isolated from that source did not accept digitoxigenin and digiproside as substrates. It is concluded that at least three different glucosyltransferases are involved in cardiac glycoside formation in Digitalis. Similar experiments carried out with glucosylated cardenolides which were administered to cultured cells, shoots and a cardenolide -glucosidase isolated from young leaves revealed that at least two different glucosidases occur in Digitalis lanata, albeit in different tissues or during different phases of development. The biotransformation of glucoevatromonoside was investigated using unlabelled compound and [¹⁴C-glucose]-glucoevatromonoside synthesized enzymatically. After 7 d of incubation almost no radioactivity could be recovered from the cardenolide fraction, indicating that the terminal glucose of glucoevatromonoside was now incorporated into volatile, hydrophilic and insoluble compounds. Since, on the other hand, large amounts of cardenolides were found in the experiments with unlabelled glucoevatromonoside it is assumed that steady state or pool size regulation is achieved by the coordinated action of a cardenolide glucosidase and a glucosyltransferase.Abbreviations Acdox D-acetyldigitoxose - dgen digoxigenin - dox D-digitoxose - dten digitoxigenin - dtl D-digitalose - fuc D-fucose - gten gitoxigenin - qun D-quinovose - CGH cardenolide 16-O-glucohydrolase - DFT UDP-fucose:digitoxigenin 3-O-fucosyltransferase - DGT UDP-glucose:Digitoxin 16-O-glucosyltransferase - DQT UDP-quinovose:digitoxigenin 3-O-quinovosyltransferase     

Compartmentation of cyanogenic glucosides and their degrading enzymes

Whereas high activities of β-glucosidase occur in homogenates of leaves of Hevea brasiliensis Muell.-Arg., this enzyme, which is capable of splitting the cyanogenic monoglucoside linamarin (linamarase), is not present in intact protoplasts prepared from the corresponding leaves. Thus, in leaves of H. brasiliensis the entire linamarase is located in the apoplasmic space. By analyzing the vacuoles obtained from leaf protoplasts isolated from mesophyll and epidermal layers of H. brasiliensis leaves, it was shown that the cyanogenic glucoside linamarin is localized exclusively in the central vacuole. Analyses of apoplasmic fluids from leaves of six other cyanogenic species showed that significant linamarase activity is present in the apoplasm of all plants tested. In contrast, no activity of any diglucosidase capable of hydrolyzing the cyanogenic diglucoside linustatin (linustatinase) could be detected in these apoplasmic fluids. As described earlier, any translocation of cyanogenic glucosides involves the interaction of monoglucosidic and diglucosidic cyanogens with the corresponding glycosidases (Selmar, 1993a, Planta 191, 191–199). Based on this, the data on the compartmentation of cyanogenic glucosides and their degrading enzymes in Hevea are discussed with respect to the complex metabolism and the transport of cyanogenic glucosides.     

Sodium, Potassium, Chloride, and Betaine Concentrations in Isolated Vacuoles from Salt-Grown Atriplex gmelini Leaves

Vacuoles were isolated via protoplasts from the leaves of a halophyte Atriplex gmelini C.A.Mey., grown in culture solution supplemented with 250 millimolar NaCl. Lysis of the protoplasts was induced by lowering the medium osmolarity (1.2 to 1.0 molar sorbitol) and adding a detergent, a synthesized cholate derivative, 3-([3-cholamidopropyl] dimethylammonio)-1-propanesulfonate at a concentration of 0.5 millimolar and the resulting vacuoles were purified by successive dilution and floatation. Isolated vacuoles contained almost the same concentration of sodium (569 millimolar) and chloride (260 millimolar) as recorded in protoplasts (582 and 254 millimolar, respectively), suggesting that the vacuoles are the major sequestration site of NaCl in leaves of halophytes. Betaine concentration in the protoplasts was about 16 millimolar, while that in vacuoles was only about 0.24 millimolar, indicating that betaine is accumulated in the cytoplasm as a compatible solute.