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.     

12β-Hydroxylation of digitoxin by Digitalis lanata cells. Production of deacetyllanatoside C in a 20-litre airlift bioreactor

Digitalis lanata cell lines obtained via cell aggregate cloning have been characterized with regard to their growth and ability to form deacetyllanatoside C from digitoxin. Cell line W.1.4 achieved 12-hydroxylation rates as high as 200 mg/L d. It was thus used in biotransformation experiments on a 20-litre scale. Six fermentor runs were performed, the best of which yielded 13.2 g deacetyllanatoside C.     

Two-stage cultivation of Digitalis lanata cells: semicontinuous production of deacetyllanatoside C in 20-litre airlift bioreactors.

A two-stage cultivation method was employed to develop a semicontinuous biotransformation process for the production of deacetyllanatoside C, a cardenolide of the important digoxin series. Digitoxin was used as the substrate for biotransformation. The process was optimized in 1-l shake flasks and then established on the 20-l scale using two airlift bioreactors, one for cell growth (working volume 12 litres) and another for deacetyllanatoside C production (working volume 18 litres). Growth and production phases were synchronized and the process finally ran semicontinuously in 7-d cycles. Six consecutive production runs were performed yielding a total of 43.8 g deacetyllanatoside C.     

Biotransformation of Digitoxin in Cell Cultures of Capsicum frutescens in the Presence of β-cyclodextrin

Cell suspension cultures of Capsicum frutescens accumulated digoxin, purpureaglycoside A and other unknown derivatives when digitoxin, a cardiac glycoside, was used as a precursor. The feeding of digitoxin complexed with β-cyclodextrin increased the accumulation of digoxin, purpureaglycoside A and other unknown derivatives. Control cultures (without digitoxin) did not produce any of these metabolites. The growth of cells was affected by both digitoxin as well as digitoxin- β-cyclodextrin. The accumulation of purpureaglycoside A and digoxin reached a maximum of 1241 and 374 μg 100 ml -1 culture on the 6th and 2nd day, respectively, which was 3.9 and 4.5 fold higher than cultures treated with digitoxin alone (sampled on the 13th day). The other unknown derivatives formed in digitoxin- β-cyclodextrin fed cultures were 15 times higher than digitoxin alone fed C. frutescens cultures. The addition of glucose to digitoxin- β-cyclodextrin treated cultures increased the accumulation of purpureaglycoside A which reached a maximum of 3589 μg 100 ml -1 culture after 12 h incubation, which was a 2.9 fold increase over cultures treated with digitoxin- β-cyclodextrin alone.     

UDP-glucose:digitoxin 16′-O-glucosyltransferase from suspension-cultured Digitalis lanata cells

Suspension cultures from several cell lines of Digitalis lanata, as well as cultures from 6 other plant species were checked for their ability to form purpurea-glycoside A from digitoxin. An in-vitro assay for the UDP-glucose:digitoxin 16-O-glucosyltransferase (DGT, EC 2.4.1.-) has been established based on an HPLC method. The enzyme is located in the soluble fraction. Its pH optimum is at 7.4. No enzyme activity was found in either purified vacuole preparations or lysed vacuoles. Ascorbate (10 mM) increased the transferase activity about 4-fold. Of the sugar nucleotides tested, only UDP-glucose served as a glucosyl donor. Digitoxin, digoxin, -acetyldigitoxin, and -acetyldigoxin are substrates for the glucosyltransferase. The role of the DGT during the biotransformation of cardenolides in Digitalis lanata cell suspension cultures is discussed.Abbreviation DGT UDP-glucose:digitoxin 16-C-glucosyltransferase     

Biotransformation of Digitoxin in Cell Cultures of Capsicum frutescens in the Presence of β-cyclodextrin

Cell suspension cultures of Capsicum frutescens accumulated digoxin, purpureaglycoside A and other unknown derivatives when digitoxin, a cardiac glycoside, was used as a precursor. The feeding of digitoxin complexed with &#103 -cyclodextrin increased the accumulation of digoxin, purpureaglycoside A and other unknown derivatives. Control cultures (without digitoxin) did not produce any of these metabolites. The growth of cells was affected by both digitoxin as well as digitoxin- &#103 -cyclodextrin. The accumulation of purpureaglycoside A and digoxin reached a maximum of 1241 and 374 &#119 g 100 ml &#109 1 culture on the 6th and 2nd day, respectively, which was 3.9 and 4.5 fold higher than cultures treated with digitoxin alone (sampled on the 13th day). The other unknown derivatives formed in digitoxin- &#103 -cyclodextrin fed cultures were 15 times higher than digitoxin alone fed C. frutescens cultures. The addition of glucose to digitoxin- &#103 -cyclodextrin treated cultures increased the accumulation of purpureaglycoside A which reached a maximum of 3589 &#119 g 100 ml &#109 1 culture after 12 h incubation, which was a 2.9 fold increase over cultures treated with digitoxin- &#103 -cyclodextrin alone.     

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.     

12 beta-Hydroxylation of digitoxin by suspension-cultured Digitalis lanata cells: production of digoxin in 20-litre and 300-litre air-lift bioreactors.

A biotransformation process for the production of digoxin was developed using Digitalis lanata cell suspension cultures. Digitoxin was used as the substrate for biotransformation. Digoxin production was carried out in a variety of vessels, including 1-l exsiccators, 20-l glass reactors and a 300-l air-lift bioreactor. A culture volume of 200 l was established after 28 d and the cells were then cultured semi-continuously in a 300-l bioreactor employing the draw-fill cultivation method. Maximal digoxin production was achieved in an 8% glucose medium with a production optimum after 40-60 h of incubation in the presence of 0.65-0.8 mmol digitoxin per l. Levels of 0.52, 0.53 and 0.60 mmol digoxin per l suspension were achieved in 1-l, 20-l and 300-l vessels, respectively. About 80% of the digoxin produced was found in the bathing medium.     

Expression of recombinant Digitalis lanata EHRH. cardenolide 16′-O-glucohydrolase in Cucumis sativus L. hairy roots

The coding sequence for the Digitalis lanata EHRH. cardenolide 16′-O-glucohydrolase was inserted downstream of the 35S promoter in the binary vector pBI121 resulting in plant expression vector pBI121cgh. Cotyledon explants excised from 10-day-old seedlings of Cucumis sativus L. were transformed using Agrobacterium rhizogenes 15834 harbouring pBI121cgh. Hairy roots were obtained from infected cotyledon explants in vitro 10 days after inoculation. PCR amplification of coding sequences for cgh I, rolB and rolC from Ri plasmid showed that the aimed sequences were inserted into the genome of transformed cucumber hairy roots. Glycolytic activity of the transgenic CGH I was measured by HPLC using Lanatoside glycosides as substrate. Therefore, the cgh I transformed cucumber hairy roots may provide a valuable model for biotransformation of natural compounds by recombinant enzymes.This report is dedicated to Prof. W. Roos on the occasion of his 60th birthday.     

Biotransformation of β-methyldigitoxin by cell cultures ofDigitalis lanata in airlift and stirred tank reactors

Summary Digitalis lanata cells were grown at dif-ferent dissolved-oxygen (DO) levels in 20-1 airlift reactors. A DO level of 30% saturation (using air for aeration) was found to be optimal for growth and the biotransformation ofβ-methyldigitoxin toβ-methyldigoxin. Product yield was further in-creased by using stirred tank reactors instead of the airlift reactor.     

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     

Studies on the Production of Digitalis Cardenolides by Plant Tissue Culture III. Effects of Nutrients on Digitoxin Formation by Shoot-Forming Cultures of Digitalis purpurea L. Grown in Liquid Media

Shoot-forming cultures of Digitalis purpurea L. were grown invarious modifications of Murashige-Skoog medium. The effectsof vitamins, natural extracts, plant growth substances, carbonand nitrogen sources and phosphate on their growth and digitoxinformation were investigated. Sucrose, glucose and raffinosewere suitable carbon sources for both growth and digitoxin formation.The optimum concentration of sucrose was 3%. Reduction of thebasal nitrogen concentration by one-third increased the digitoxincontent per unit weight without suppression of growth. The optimalratio of nitrate-nitrogen to ammonium-nitrogen was 2, as providedin the basal medium. A threefold increase in the phosphate concentrationimproved both growth and digitoxin content. Thiamine.HCl andmyo-inositol were required for digitoxin formation, whereasglycine, nicotinic acid and pyridoxine.HCl, usual componentsof the medium, were not required for either growth or digitoxinformation during the three passages examined. Coconut milk improvedgrowth with no reduction in the digitoxin content per unit weight.Gibberellic and abscisic acids at 0.01 to 0.1 mg per liter slightlyimproved digitoxin formation. Kinetin had no clear positiveeffect on either growth or digitoxin formation. (Received March 12, 1982; Accepted August 5, 1982)     

Cellular organization of cardenolide biotransformation in Digitalis grandiflora Mill

The cellular compartmentalization of cardenolide biotransformation in Digitalis grandiflora Mill. cell cultures was investigated. The presence of UDP-glucose: digitoxin 16-O-glucosyltransferase (DGT; EC 2.4.1.-), acetyl-CoA: digitoxin 15-O-acetyltransferase (DAT; EC 2.3.1.-) and cardenolide 16-O-glucohydrolase (CGH; EC 3.2.1.21) was demonstrated and their time courses during one cell culture cycle were established. The activities of DGT, DAT and CGH were quite constant over time and leveled off at around 3, 30 and 100 ukat, respectively, per kg protein. The cardenolide products formed by DGT action were shown to be exclusively localized in the central vacuole. The cellular distributions of DGT, CGH and unspecific -glucosidase were investigated and it was shown that DGT and CGH are not localized in the vacuoles, whereas unspecific glucosidase is. The influence on cardenolide uptake of the set of biotransformation enzymes present in a given cell line is discussed. An updated cellular model of cardenolide biotransformation is proposed.Abbreviations CGH cardenolide 16-O-glucohydrolase - DAT acetyl-CoA: digitoxin 15-O-acetyltransferase - DGT UDP-glucose: digitoxin 16-O-glucosyltransferase - LAE lanatoside 15-O-acetylesterase This work was supported by a grant from the Deutsche Forschungsgemeinschaft.     

Stability of Lanatoside C content in thein vitro propagatedDigitalis lanata clones

In vitro culture was established from shoot tips ofDigitalis lanata cotyledonous plants. The propagated plant material was rooted, transplanted into soil and grown under field conditions. Lanatoside C content was determined in a total of 20 clones and statistically evaluated by means of variance analysis of unequal-sized samples.In vitro clonal propagation ofD. lanata was found not to affect lanatoside C content. Drug level was dependent on a plant genotype.     

Microbial transformations of cardioglycosides

Summary Penicillium vermiculatum deglycosylated lanatosid C to acetyldigoxin and Arthrobacter citreus deacetylated the latter to digoxin. Both reactions were carried out in a short time with high yields. Lanatosid A was transformed by P. vermiculatum simultaneously to acetyldigitoxin and digitoxin. A. citreus transformed lanatosid A directly to digitoxin and lanatosid C to digoxin, but the reactions took a long time and the yields were low.     

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.     

Extraction and Chromatographic Purification of Digitalis Cardiac Glycosides and Their Binding to Plant Pigments

A procedure is described for extracting cardiac glycosides and their aglycones from dried leaf powder of Digitalis purpureaL. by a water-ethanol gradient elution followed by Soxhlet extraction. Milligram amounts of pure digitoxin had been added to the leaf powder for studying its effects on the solubilities and removal of interfering plant pigments and on the recovery of steroidal substances by thin-layer chromatography. Definite effects of added digitoxin on the turbidity of plant extracts and on plausible com-plexing reactions are described, some of which proceed parallel to aging effects of plant extracts.     

Modeling of growth and sporulation of <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis> in an intermittent fed batch culture with total cell retention

An extended dynamical model for growth and sporulation of Bacillus thuringiensis subsp. kurstaki in an intermittent fed-batch culture with total cell retention is proposed. This model differs from reported models, by including dynamics for natural death of cells and substrate consumption for cell maintenance. The proposed model uses sigmoid functions to describe these kinetic parameters. Equations for time evolution of substrate, vegetative, sporulated and total cell concentration were taken from previous works. Model parameters were determined from batch experimental data obtained in pilot plant. Parameter identification was developed in two stages: (1) coarse identification using a multivariable optimization with constraints algorithm, (2) fine identification by heuristic fit of model parameters looking for a minimal model error. The proposed model estimates adequate time evolution of the process variables with a mean error of 2.6% on substrate concentration and 6.7% on biomass concentration.     

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.     

Cardiotonic glycosides from biomass of <Emphasis Type="Italic">Digitalis purpurea</Emphasis> L. cultured in temporary immersion systems

Cardiotonic glycosides are extracted mostly from leaves of Digitalis plants. Commercial production of bioactive secondary metabolites by traditional agriculture is an inefficient process and can be affected by climatic and soil conditions. Strategies, based on in vitro culture methods, have been extensively studied to improve the production of specific plant derived chemicals. The aim of the present research was to obtain biomass of D. purpurea using the temporary immersion system (TIS) and to determine the content of cardiotonic glycosides (digitoxin, digoxin and lanatoside C) as secondary metabolites of commercial value for the pharmaceutical industry. Shoots were cultured in 1,000 ml TIS during 28 days. The effect of four immersion frequencies (once every 2, 4, 6, and 12 h) was studied. Biomass accumulation was influenced by immersion frequency. The maximum biomass accumulation (values in respect of fresh and dry weight) was obtained with immersions every 4 h (six immersions per day). HPLC analysis revealed the presence of digoxin and digitoxin for all immersion frequencies. No lanatoside C was detected in the biomass cultured in TIS. Digoxin concentrations varied depending on the frequencies tested. In contrast, the digitoxin content showed no dependency on the immersion frequency. Net production of digoxin and digitoxin per TIS were found to be higher with immersions every 4 h. The best net production of digitoxin and digoxin per TIS were 167.6 and 119.9 μg, respectively. The development of organ culture based on temporary immersion system can be a reliable method for the steady production of biomass for cardiotonic glycosides production, which is reported for the first time for Digitalis genus in this communication.