Effects of precursors on serially propagated Digitalis lanata leaf and root cultures

Serially propagated Digitalis lanata leaf and root cultures established from germinated seeds were studied for digoxin production. Leaf cultures were grown and maintained in a medium containing benzyl adenine, and root cultures in the same medium with indoleacetic acid. A consistently high digoxin content, as determined by radio-immunoassay, is present in the leaf culture (9.0 mg % dry wt) and in root culture (1.9 mg % dry wt) as compared to unorganized cells (0.06 mg % dry wt). Leaf liquid cultures grew very rapidly as compared to the root cultures and the unorganized cell suspension cultures. The concentration of digoxin increased in both leaf and root cultures by adding to the medium either sodium glycocholate, cholesteryl acetate, or progesterone. Smilageninacetate increased the digoxin content of root cultures but not that of leaf cultures. Lanosterol and 5β-androstan-3,17-dione did not significantly increase the concentration of digoxin. Deoxycholic acid was toxic to the tissues studied.     

Cardenolide glycoside production in Digitalis lanata

Leaves of Digitalis lanata metabolize progesterone more rapidly than pregnenolone when applied to the surface of the leaves. Their transformation into digitoxigenin, gitoxigenin, digoxigenin, digitoxin, gitoxin, digoxin and the corresponding cardenolides was demonstrated.     

Increased cardenolides production by elicitation of Digitalis lanata shoots cultured in temporary immersion systems

Digitalis lanata is an important source of cardenolides such as digoxin and lanatoside C, which have been widely applied in the treatment of cardiac insufficiencies. Elicitation is one of the most effective methods to enhance the biosynthesis of several secondary metabolites in medicinal plants. We studied the effect of elicitation with Chitoplant^?, Silioplant^? and methyl jasmonate on biomass and cardenolides accumulation in shoots of D. lanata cultivated in temporary immersion systems. Morphological response of the shoots was influenced by elicitors. A reduction in length and number of shoots was evident with all MJ concentrations. Regarding biomass production, Chitoplant^? (0.1?g?l^?1) was found to impact significantly on fresh and dry weight of the shoots. HPLC analysis revealed a higher content of lanatoside C compared to digoxin in all treatments. The highest accumulation of lanatoside C was achieved with Chitoplant^? (0.1?g?l^?1), which resulted in 316???g?g-DW^?1 and with Silioplant^? (0.01?g?l^?1; 310???g?g-DW^?1), which accounted for a 2.2-fold increase in lanatoside C content compared to non-elicited shoot cultures. Additionally, elicitation of D. lanata shoots in temporary immersion systems resulted in an oxidative stress characterized by hydrogen peroxide and malondialdehyde accumulation. These observations point to a connection between hydrogen peroxide generation, lipid peroxidation and cardenolide accumulation. The optimization of elicitor treatment and culture conditions for cardenolide production as well as the advantages of TIS for this purpose are discussed.     

Induction of digoxin-like material production, and the digoxin binding in the unicellular organism Tetrahymena by digitoxin.

Thin layer chromatographic, and laser-confocal microscopic analyses with a monoclonal antibody to digoxin also displaying high affinity to digoxigenin, were used to determine the presence and localization of cardioactive glycosides. Tetrahymena pyriformis was found to possess digitoxigenin-like material, but digoxin, digitoxin, digoxigenin, gitoxin and lanatoside C were not detected. Digitoxin treatment elicited the appearance of a digoxin-like material in the progeny generations. Digoxin was taken up by untreated Tetrahymena, especially strongly 24 h after digitoxin treatment. While the cardenolide was localized in vesicles of the cell body in untreated Tetrahymena, the engulfed digoxin appeared in the epiplasmic layer and also in the cilia after digitoxin pretreatment. Digoxin pretreatment did not increase digoxin uptake. These data indicate that Tetrahymena has: (1) the capacity to discriminate between closely related molecules; (2) the ability to induce digoxin-like material production; and/or (3) enzymes that can effect a digitoxin-digoxin transformation.     

Biosynthesis of cardenolides in Digitalis lanata

[8-³H]-Cholesterol was synthesized. A doubly labelled sample of [8-³H, 4-¹⁴C]-cholesterol was administered to Digitalis lanata plants and the cardenolides were isolated. Biosynthesized digitoxigenin and digoxigenin retained all the tritium. Barring the migration of the tritium in biosynthesis the results are interpreted as indicative that neither intermediates with δ7, δ⁷ or δ⁸⁸⁽¹⁴⁾ are participating in the elaboration of cardenolides.     

Kinetic model for biotransformation of digitoxin in plant cell suspension culture ofDigitalis lanata

Batch suspension cultures ofDigitalis lanata plant cell were performed to investigate the biotransformation of digitoxin.Digitalis lanata K3OHD plant cells were used to biotransform digitoxin into deacetyllanatoside C. A kinetic model was proposed to describe cell growth, substrate consumption, depletion of digitoxin, formation and depletion of digoxin and purpureaglycoside A, and formation of deacetyllanatoside C. The digoxin and purpureaglycoside A are intermediates of deacetyllanatoside C formation from digitoxin. Interactions between extracellular and intracellular compounds were considered. The proposed model could accurately predict cell growth, substrate consumption and product synthesis. And it can provide a useful framework for quantitative analysis of biotransformation in a plant cell culture system.     

Cardiotonic steroids as potential Na+/K+-ATPase inhibitors – a computational study

Abstract

Cardiotonic steroids (CTS) are steroidal drugs, processed from the seeds and dried leaves of the genus Digitalis as well as from the skin and parotid gland of amphibians. The most commonly known CTS are ouabain, digoxin, digoxigenin and bufalin. CTS can be used for safer medication of congestive heart failure and other related conditions due to promising pharmacological and medicinal properties. Ouabain isolated from plants is widely utilized in in vitro studies to specifically block the sodium potassium (Na⁺/K⁺-ATPase) pump. For checking, whether ouabain derivatives are robust inhibitors of Na⁺/K⁺-ATPase pump, molecular docking simulation was performed between ouabain and its derivatives using YASARA software. The docking energy falls within the range of 8.470?kcal/mol to 7.234?kcal/mol, in which digoxigenin was found to be the potential ligand with the best docking energy of 8.470?kcal/mol. Furthermore, pharmacophore modeling was applied to decipher the electronic features of CTS. Molecular dynamics simulation was also employed to determine the conformational properties of Na⁺/K⁺-ATPase-ouabain and Na⁺/K⁺-ATPase-digoxigenin complexes with the plausible structural integrity through conformational ensembles for 100?ns which promoted digoxigenin as the most promising CTS for treating conditions of congestive heart failure patients.     

Leaf non-structural carbohydrates and leaf dry weight per area in three altitudinal populations ofEspeletia schultzii WEDD

The leaf non-structural carbohydrate (NSC) content and total non-structural carbohydrate content (TNC) were measured on a dry weight basis and on a leaf area basis in three altitudinal (3100, 3550 and 4200 m a.s.l.) populations ofE. schultzii. The values of leaf dry weight per area (LWA) increase with altitude. The leaf non-structural carbohydrate content (expressed as g/kg dry weight) does not show statistically significant difference among populations, but the values expressed on an area basis (g/m²) show a statistically significant increase with altitude. Significant correlations were observed between LWA and TNC (r ²=0.65); insoluble carbohydrate (r ²=0.78); total soluble carbohydrate (r ²=0.53); reducing sugars (r ²=0.47) expressed on area basis. Correlations between LWA and NSC for any fraction and TNC on a dry weight basis were not significant. It appears that along this altitudinal gradient the leaf area is more affected than the leaf dry weight. Since the NSC is known to play a role in the freezing tolerance of plants, the results indicate that the freezing tolerance does not change among the populations along the gradient.     

Reduction of digoxin to 20R-dihydrodigoxin by cultures of Eubacterium lentum.

The anaerobic bacterium Eubacterium lentum, a common constituent of the intestinal microflora, inactivates digoxin by reducing the unsaturated lactone ring. Reduction of the cardiac glycoside by growing cultures of E. lentum ATCC 25559 proceeded in a stereospecific manner, with the 20R-dihydrodigoxin constituting more than 99% of the product formed. This is in contrast to the 3:1 ratio of 20R and 20S epimers formed in the chemical catalytic hydrogenation. Formation of the reduced glycosides proceeded quantitatively when an overall concentration of 10 micrograms/ml was added to the cultures. E. lentum did not hydrolyze the digitoxose sugars from C-3 of the parent glycoside. However, the synthetically prepared sugar-hydrolyzed metabolites (digoxigenin, digoxigenin monodigitoxoside, and digoxigenin bisdigitoxoside) were reduced to the corresponding dihydro metabolites. Repetition of the experiments with a feces sample from a volunteer who was known to be a converter of digoxin to dihydrodigoxin gave results identical to those obtained with pure E. lentum cultures.     

Reduction of digoxin to 20R-dihydrodigoxin by cultures of Eubacterium lentum

The anaerobic bacterium Eubacterium lentum, a common constituent of the intestinal microflora, inactivates digoxin by reducing the unsaturated lactone ring. Reduction of the cardiac glycoside by growing cultures of E. lentum ATCC 25559 proceeded in a stereospecific manner, with the 20R-dihydrodigoxin constituting more than 99% of the product formed. This is in contrast to the 3:1 ratio of 20R and 20S epimers formed in the chemical catalytic hydrogenation. Formation of the reduced glycosides proceeded quantitatively when an overall concentration of 10 micrograms/ml was added to the cultures. E. lentum did not hydrolyze the digitoxose sugars from C-3 of the parent glycoside. However, the synthetically prepared sugar-hydrolyzed metabolites (digoxigenin, digoxigenin monodigitoxoside, and digoxigenin bisdigitoxoside) were reduced to the corresponding dihydro metabolites. Repetition of the experiments with a feces sample from a volunteer who was known to be a converter of digoxin to dihydrodigoxin gave results identical to those obtained with pure E. lentum cultures.     

Overexpression of the anaphase-promoting complex (APC) genes in Nicotiana tabacum promotes increasing biomass accumulation

The anaphase-promoting complex (APC) plays pivotal roles in cell cycle pathways related to plant development. In this study, we present evidence that overproduction of APC10 from Arabidopsis thaliana in tobacco (Nicotiana tabacum) plants promotes significant increases in biomass. Analyzes of plant’s fresh and dried weight, root length, number of days to flower and number of seeds of plants overexpressing AtAPC10 verified an improved agronomic performance of the transgenic plants. Detailed analyzes of the leaf growth at the cellular level, and measurements of leaf cell number, showed that AtAPC10 also produce more cells, showing an enhancement of proliferation in these plants. In addition, crossing of plants overexpressing AtAPC10 and AtCDC27a resulted in a synergistic accumulation of biomass and these transgenic plants exhibited superior characteristics compared to the parental lines. The results of the present study suggest that transgenic plants expressing AtAPC10 and AtAPC10/AtCDC27a concomitantly are promising leads to develop plants with higher biomass.     

In vitro propagation and production of cardiotonic glycosides in shoot cultures of Digitalis purpurea L. by elicitation and precursor feeding

Digitalis purpurea L. (Scrophulariaceae; Foxglove) is a source of cardiotonic glycosides such as digitoxin and digoxin which are commercially applied in the treatment to strengthen cardiac diffusion and to regulate heart rhythm. This investigation deals with in vitro propagation and elicited production of cardiotonic glycosides digitoxin and digoxin in shoot cultures of D. purpurea L. In vitro germinated seedlings were used as a primary source of explants. Multiple shoot formation was achieved for three explant types (nodal, internodal, and leaf) cultured on Murashige and Skoog (MS) medium with several treatments of cytokinins (6-benzyladenine—BA; kinetin—Kin; and thidiazuron—TDZ) and auxins (indole-3-acetic acid—IAA; α-naphthaleneacetic acid—NAA; and 2,4-dichlorophenoxy acetic acid—2,4-D). Maximum multiple shoots (12.7?±?0.6) were produced from nodal explants on MS?+?7.5 μM BA. Shoots were rooted in vitro on MS containing 15 μM IAA. Rooted plantlets were successfully acclimatized. To further maintain the multiple shoot induction, mother tissue was cut into four equal parts and repeatedly sub-cultured on fresh shoot induction liquid medium after each harvest. On adaptation of this strategy, an average of 18 shoots per explant could be produced. This strategy was applied for the production of biomass and glycosides digitoxin and digoxin in shoot cultures on MS medium supplemented with 7.5 μM BA and several treatments with plant growth regulators, incubation period, abiotic (salicylic acid, mannitol, sorbitol, PEG-6000, NaCl, and KCl), biotic (Aspergillus niger, Helminthosporium sp., Alternaria sp., chitin, and yeast extract) elicitors, and precursors (progesterone, cholesterol, and squalene). The treatment of KCl, mycelial mass of Helminthosporium sp., and progesterone were highly effective for the production of cardenolides. In the presence of progesterone (200 to 300 mg/l), digitoxin and digoxin accumulation was enhanced by 9.1- and 11.9-folds respectively.     

Sweetening agents of plant origin: Phenylpropanoid constituents of seven sweet-tasting plants

Field inquiries and organoleptic tests for sweet taste led to the procurement of samples ofPiper marginatum (dried leaves),Tagetes filicifolia (fresh whole plants),Osmorhiza longistylis (fresh roots),Foeniculum vulgare (fresh aerial parts),Myrrhis odorata (fresh whole plants),Ocimum basilicum (fresh aerial parts), andIllicium verum (dried fruits). Follow-up laboratory studies of the leaves ofPiper marginatum demonstrated that trans-anethole (a phenylpropanoid) was the major sweet constituent of this species. In the remaining six species, GC/MS analysis also enabled us to demonstrate that sweetness is attributable, in each case, to the presence of high concentrations of the phenylpropanoids, trans-anethole and estragole, either alone or in combination.     

Selectivity of Digitalis Glycosides for Isoforms of Human Na,K-ATPase

There are four isoforms of the α subunit (α1–4) and three isoforms of the β subunit (β1–3) of Na,K-ATPase, with distinct tissue-specific distribution and physiological functions. α2 is thought to play a key role in cardiac and smooth muscle contraction and be an important target of cardiac glycosides. An α2-selective cardiac glycoside could provide important insights into physiological and pharmacological properties of α2. The isoform selectivity of a large number of cardiac glycosides has been assessed utilizing α1β1, α2β1, and α3β1 isoforms of human Na,K-ATPase expressed in Pichia pastoris and the purified detergent-soluble isoform proteins. Binding affinities of the digitalis glycosides, digoxin, β-methyl digoxin, and digitoxin show moderate but highly significant selectivity (up to 4-fold) for α2/α3 over α1 (K_D α1 > α2 = α3). By contrast, ouabain shows moderate selectivity (≈2.5-fold) for α1 over α2 (K_D α1 ≤ α3 < α2). Binding affinities for the three isoforms of digoxigenin, digitoxigenin, and all other aglycones tested are indistinguishable (K_D α1 = α3 = α2), showing that the sugar determines isoform selectivity. Selectivity patterns for inhibition of Na,K-ATPase activity of the purified isoform proteins are consistent with binding selectivities, modified somewhat by different affinities of K⁺ ions for antagonizing cardiac glycoside binding on the three isoforms. The mechanistic insight on the role of the sugars is strongly supported by a recent structure of Na,K-ATPase with bound ouabain, which implies that aglycones of cardiac glycosides cannot discriminate between isoforms. In conclusion, several digitalis glycosides, but not ouabain, are moderately α2-selective. This supports a major role of α2 in cardiac contraction and cardiotonic effects of digitalis glycosides.     

The VEP1 gene (At4g24220) encodes a short-chain dehydrogenase/reductase with 3-oxo-Δ-steroid 5β-reductase activity in Arabidopsis thaliana L.

The Arabidopsis thaliana VEP1 gene product shows about 70% sequence identity to Digitalis lanata progesterone 5β-reductase, an enzyme considered to catalyze a key step in the biosynthesis of cardiac glycosides. A. thaliana does not accumulate cardenolides but protein extracts prepared from its leaves were capable of reducing progesterone to 5β-pregnane-3,20-dione. A full-length cDNA clone encoding a Δ^4,5-steroid 5β-reductase (At5β-StR, EC 1.1.1.145/1.3.1.23), a member of the short-chain dehydrogenase/reductase (SDR) family, was isolated from A. thaliana leaves. A SphI/SalI At5β-StR gene fragment was cloned into the pQE vector system and transformed into Escherichia coli. The gene was functionally expressed and the recombinant His-tagged fusion protein was characterized. K_m values and specific activities for putative 3-oxo-Δ^4,5-steroid substrates such as progesterone, cortisol, cortexone and 4-androstene-3,17-dione, and for the co-substrate NADPH were determined. Progesterone was stereo-specifically reduced to 5β-pregnane-3,20-dione and none of the 3-oxo-Δ^5,6-steroids tested were accepted as a substrate. The gene encoding At5β-StR was strongly transcribed in stems and leaves. A three-dimensional model of At5β-StR highlights a close structural similarity to the related, previously described D. lanata progesterone 5β-reductase. This homology extends to the active site where single amino acid substitutions might be responsible for the increased catalytic efficiency of At5β-StR when compared to the activity of the recombinant form of the D. lanata enzyme.     

Increased production of digoxin by digitoxin biotransformation using cyclodextrin polymer inDigitalis lanata cell cultures

Addition of β-cyclodextrin (β-CD) polymer during the biotransformation of digitoxin into digoxin using cell suspension cultures ofDigitalis lanata enhanced the conversion yield. Digitoxin showed better adsorption to CD polymer compared to digoxin, so that the optimization of addition time was found to be necessary. In the case of adding CD polymer 24 hours after the feeding of substrate digitoxin, the highest digoxin production could be achieved. At this period, digitoxin was almost consumed by cells and productivity was proportionally enhanced according as the amount of substrate was increased. Immobilization of CD polymer did not promote the biotransformation. When 3.33 g/L of CD polymer was added, 90% and 50% of digitoxin and digoxin was adsorbed respectively. Thus selective inclusion complex formation could be expected. Adsorption rate was found to be rapid and saturation was obtained within 10 hours of contact.     

Incorporation of 5α-furostan-3β,26-diol into tigogenin by digitalis lanata

2,2′,4,4′-³H₄-dihydrotigogenin was converted by Digitalis lanata plants into tigogenin.     

Zur biogenese des tigogenins in Digitalis lanata und des solasodins in Solanum laciniatum

7α-[³H]-20-hydroxycholesterol was converted by Digitalis lanata plants into tigogenin. 7α-[³H]-20-hydroxycholesterol and 7α-[³H]-26-aminodihydrodiosgenin were utilized for the biogenesis of solasodine by plants of Solanum laciniatum. These results are discussed in relation to spirostanol and spirosolan alkaloid biogenesis.     

16β-Hydroxycholestanol als biogenetische vorstufe der steroidsapogenine

It has been shown that 5,6-³H,16β-hydroxycholestanol is used in the biogenesis of the steroid sapogenins, tigogenin and gitogenin, by plants of Digitalis lanata but not for the formation of tomatidine by Solanum lycopersicum.