Non-reversibility of the isoleucine-acetate pathway in Datura

Five-month-old Datura meteloides plants were fed via the roots with 3-hydroxy-2-methylbutanoic acid-[1-¹⁴C] and isoleucine-[U-¹⁴C] as a positive control. After 5 days the plants were collected and in each case the root alkaloids 3α,6β-ditigloyloxytropane, 3α,6β-ditigloyloxytropan-7β-ol, meteloidine, hyoscine and hyoscyamine were isolated. Whereas isoleucine served as a precursor for the tiglic acid moieties 3-hydroxy-2-methylbutanoic acid did not.     

Stereochemistry of tropane alkaloid formation in Datura

Five-month-old Datura innoxia plants were fed via the roots with either d(+)-hygrine-[2′-¹⁴C] or l(?)-hygrine-[2′-¹⁴C]. After 7 days the root alkaloids 3α,6β-ditigloyloxytropane, 3α,6β-ditigloyloxytropan-7β-ol, hyoscine, hyoscyamine and cuscohygrine were isolated from both groups of plants. d(+) but not l(?)-hygrine acts as a precursor for the tropane alkaloids whereas both enantiomers appeared to serve equally well in the biosynthesis of cuscohygrine.     

The biosynthetic relationship between littorine and hyoscyamine in transformed roots of Datura stramonium

The metabolic relationship between littorine and hyoscyamine has been monitored in transformed roots of Datura stramonium. Quantification by GC of unlabelled littorine and by GCMS of ¹³C-labelled littorine demonstrated that exogenously added littorine (0.1 mm) was significantly metabolised (35%) to hyoscyamine. In contrast, exogenously added hyoscyamine was not metabolised to littorine, indicating that this conversion is irreversible. The conversion of littorine to hyoscyamine was suppressed by P-450 oxidase inhibitors (particularly clotrimazole), implicating the involvement, at least in part of a cytochrome P-450 activity operating hyoscyamine biosynthesis. Received: 15 September 1997 / Revision received: 14 February 1998 / Accepted: 10 March 1998     

Kinetic study of possible intermediates in the biosynthesis of chlorogenic acid in Cestrum poeppigii

p-Coumaric and 3-O-p-coumarylquinic acid seem to be important precursors of chlorogenic acid in the leaves of Cestrum poeppigii. 3-O-Cinnamylquinic acid, which has a very small metabolic activity, is of little importance in this respect. The kinetics of incorporation of radioactivity from t-cinnamic acid-3-[¹⁴C] into p-coumaric, 3-O-p-coumarylquinic, chlorogenic and 3-O-cinnamylquinic acid showed that the biosynthetic rates for these products decrease in the order shown. For p-coumaric acid, which has a markedly high metabolic activity, a turnover rate of 28 μg/hr and per gram fresh plant leaf, was calculated. Some trapping experiments with caffeic acid, and the acids mentioned above and using either t-cinnamic acid-3-[¹⁴C] or p-coumaric acid-2-[¹⁴C] as precursor, are discussed. A HPLC method for the rapid determination of phenolic acids in plant extracts, is described.     

Norlittorine and norhyoscyamine identified as products of littorine and hyoscyamine metabolism by 13C-labeling in Datura innoxia hairy roots

The presence of two compounds, norlittorine and norhyoscyamine, has been reported in leaves and roots of Datura innoxia; however their metabolic origin in the tropane alkaloid pathway has remained unknown. Precise knowledge of this pathway is a necessary pre-requisite to optimize the production of hyoscyamine and scopolamine in D. innoxia hairy root cultures. The exact structure of norlittorine and norhyoscyamine was confirmed by LC–MS/MS and NMR analyses. Isotopic labeling experiments, using [1-¹³C]-phenylalanine, [1′-¹³C]-littorine and [1′-¹³C]-hyoscyamine, combined with elicitor treatments, using methyl jasmonate, coronalon and 1-aminocyclopropane-1-carboxylic acid, were used to investigate the metabolic origin of the N-demethylated tropane alkaloids. The results suggest that norlittorine and norhyoscyamine are induced under stress conditions by conversion of littorine and hyoscyamine. We propose the N-demethylation of tropane alkaloids as a mechanism to detoxify cells in overproducing conditions.     

Biosynthesis of the tigloyl esters of Datura: Cis-trans isomerism

Datura innoxia plants were wick fed with angelic acid-[1-¹⁴C] and l-isoleucine-[U-¹⁴C] to act as a positive control. After 7 days the root alkaloids 3α-tigloyloxytropane, 3α,6β-ditigloyloxytropane, and 3α,6β-ditigloyloxytropan-7β-ol were isolated and it was determined that angelic acid is not a precursor for the tigloyl moiety of these alkaloids. Tiglic acid-[1-¹⁴C] which was fed via the roots to hydroponic cultures of Datura innoxia, was incorporated to a considerable degree after 8 days.     

Alkaloids of Datura suaveolens

The alkaloid mixture of Datura suaveolens shows distinct differences compared with that of other tree daturas. Aerial parts contain in addition to hyoscine, apohyoscine, norhyoscine, atropine and noratropine, a relatively high proportion of tigloyl esters—3α,6β-ditigloyloxytropan-7β-ol, 6β-tigloyloxytropan-3α,7β-diol,3α-tigloyloxytropan-6β,7β-diol (meteloidine) and (—)- and (±)-3α-tigloyloxytropan-6β-ol. The roots contain hyoscine, meteloidine, atropine, littorine, 3α-acetoxytropane, 6β-(α-methylbutyryloxy)-3α-tigloyloxytropane, 3α,6β-ditigloyloxytropan-7β-ol, 3α-tigloyloxytropan-6β-ol, tropine and cuscohygrine. Other, as yet uncharacterized, bases are present in the plant. Norhyoscine is a principal alkaloid of the corollas.     

Biosynthesis of p-hydroxybenzoic acid in poplar lignin

Biosynthetic pathways to p-hydroxybenzoic acid in polar lignin were examined by tracer experiments. High incorporation of radioactivity to the acid was observed when shikimic acid-[1-¹⁴C], phenylalanine-[3-¹⁴C], trans-cinnamic acid-[3-¹⁴C], p-coumaric acid-[3-¹⁴C] and p-hydroxybenzoic acid-[COOH-¹⁴C] were administered, while incorporation was low from shikimic acid-[COOH-¹⁴C], phenylalanine-[1-¹⁴C], phenylalanine-[2-¹⁴C], tyrosine-[3-¹⁴C], benzoic acid-[COOH-¹⁴C], sodium acetate-[1-¹⁴C] and d-glucose-[U-¹⁴C]. Thus p-hydroxybenzoic acid in poplar lignin is formed mainly via the pathway: shikimic acid → phenylalanine → trans-cinnamic acid → p-coumaric acid → p-hydroxybenzoic acid.     

Biosynthesis of tropic acid: Feeding experiments with cinnamoyltropine and littorine

The administration of cinnamoyl-[2-¹⁴C]-tropine-[N-methyl-¹⁴C] to Datura stramonium plants resulted in the formation of labeled atropine and scopolamine. However the atropine was found to have almost all its radioactivity located on the N-methyl group of the alkaloid, indicating that the administered ester had undergone hydrolysis in the plant affording tropine and cinnamic acid, the latter not being utilized for the biosynthesis of tropic acid. Dual labeled RS-littorine (3β-(2-hydroxy-3-phenylpropionyloxy-[1-¹⁴C]-tropane-[3β-³H]) was also fed to D. stramonium and radioactive atropine was obtained. However the drastic change in the ³H:¹⁴C ratio found in the atropine indicated that the littorine was not converted directly to the alkaloid, and it is suggested that the littorine is hydrolysed _{in vivo} to tropine and phenyl-lactic acid, the latter undergoing rearrangement to tropic acid prior to esterification with tropine.     

The metabolism of [3−3H]oleanolic acid-3-O-mono-[14C]glucoside in isolated cells from Calendula officinalis leaves

The radioactive precursor, [3?³H]oleanolic acid-3-O-mono-[¹⁴C]glucoside was administrated to isolated cells obtained from the leaves of Calendula officinalis. The radioactivity of the precursor was incorporated into fractions containing free oleanolic acid, individual glucosides, glucuronide F and other glucuronides. The ratio of ³H: ¹⁴C radioactivity in these fractions indicated that glucosides were formed in a process involving direct glycosylation of the precursor, whereas the glucuronides were formed from oleanolic acid released by hydrolysis of the precursor. Dynamics curves showed that glucoside II formed by direct glycosylation of the precursor was intensively transformed to other derivatives.     

Distribution of alkaloids in Anthocercis littorea and A. viscosa

The distribution of tropane alkaloids in organs of Anthocercis littorea and A. viscosa is reported. The following alkaloids have been isolated: atropine (hyoscyamine), apoatropine, noratropine (norhyoscyamine), littorine, hyoscine, norhyoscine, meteloidine, 3α, 6β-ditigloyloxytropan-7β-ol, 6β-tigloyloxytropan-3α-ol, 3α-tigloyloxytropane, tigloidine, tropine, ψ-tropine, (?)-tropan-3α-6β-diol, cuscohygrine and unknown bases.     

Failure of 3-hydroxy-3-phenylpropanoic acid and cinnamic acid to serve as precursors of tropic acid in Datura innoxia

Datura innoxia plants were fed the R- and S-isomers of [3-¹⁴C]-3-hydroxy-3-phenylpropanoic acid, and [3-¹⁴C]cinnamic acid along with dl-[4-³H]phenylalanine. The hyoscyamine and scopolamine isolated from the plants 7 days later were labeled with tritium, but devoid of ¹⁴C, indicating that 3-hydroxy-3-phenylpropanoic acid and cinnamic acid are not intermediates between phenylalanine and tropic acid. The [³H] tropic acid obtained by hydrolysis of the hyoscyamine was degraded and shown to have essentially all its tritium located at the para position of its phenyl group, a result consistent with previous work.     

Hyoscyamine and proline accumulation in water-stressed Hyoscyamus muticus ‘hairy root’ cultures

Summary The patterns of hyoscyamine and proline accumulation were studied in Agrobacterium-transformed ‘hairy root’ cultures of Hyoscyamus muticus to determine if proline is a metabolic precursor of hyoscyamine. Root cultures were stressed osmotically with mannitol and the subsequent growth, hyoscyamine levels, and proline levels were measured after each transfer to fresh experimental medium for a total of four transfers. H. muticus ‘hairy roots’ were also treated with [U-¹⁴C] proline or [1,4-¹⁴C] putrescine and analyzed for radioactive hyoscyamine. Growth of ‘hairy root’ cultures was reduced by up to 90% in 0.4 M mannitol, and this inhibition persisted for at least four transfers. ‘Hairy root’ cultures of H. muticus accumulated hyoscyamine and free proline (up to 6-fold and 25-fold, respectively) when osmotically stressed with mannitol, and this effect also persisted for four transfers when grown in the same mannitol concentration. Because the total production of hyoscyamine was also increased by twofold, we conclude that the elevated hyoscyamine concentration results from increased hyoscyamine synthesis and not from reduced growth. H. muticus ‘hairy roots’ incorporated radioactivity from [1,4-¹⁴C] putrescine efficiently into hyoscyamine in both treatments, but failed to convert [U-¹⁴C] proline into hyoscyamine. We thus conclude that accumulated proline does not serve as a precursor for hyoscyamine.     

Conversion of geranylgeranyl pyrophosphate to ent-kaurene in enzyme extracts of sonicated chloroplasts

Farnesyl pyrophosphate-[¹⁴C] and geranylgeranyl pyrophosphate-[¹⁴C] were biosynthesized from mevalonic acid-[2-¹⁴C] by cell-free enzyme extracts of pea (Pisum sativum) cotyledons containing MgCl₂, MnCl₂, ATP and AMO-1618. Maximum yields of farnesyl pyrophosphate were obtained after 30 min incubation while geranylgeranyl pyrophosphate was the primary product after 180 min. Biosynthesized geranylgeranyl pyrophosphate-[¹⁴C] served as an efficient substrate for ent-kaurene biosynthesis in reaction mixtures containing cotyledon enzymes when AMO-1618 was omitted. Enzyme extracts from green pea shoot tips and chloroplasts also converted geranylgeranyl pyrophosphate to ent-kaurene in very low yields. Ent-kaurene production from mevalonic acid-[2-¹⁴C] in extracts of pea shoot tips was also enhanced by addition of chloroplast enzymes. This evidence indicates that kaurene synthetase is present in pea chloroplasts and adds to the possibility that some gibberellin biosynthesis may be compartmentalized in those organelles.     

Biosynthesis of lysine and other amino acids in the developing maize endosperm

Tracer studies with aspartic acid-[4-¹⁴C], alanine-[1-¹⁴C] acetate-[2-¹⁴C] and diaminopimelic acid-[1,(7)-¹⁴C] injected into the developing endosperm of maize revealed that the biosynthesis of lysine and other amino acids occurs in this organ. The data suggest that lysine is synthesized via the diaminopimelic acid pathway.     

The biosynthesis of angelic acid in Cynoglossum officinale

Six-month-old Cynoglossum officinale plants were fed via the roots with tiglic acid-[1-¹⁴C]. After a week the plants were harvested, the alkaloid heliosupine was isolated and hydrolysed to heliotridine and angelic acid. The latter contained all the radioactivity of the original heliosupine showing that angelic acid may be formed from tiglic acid by a cis-trans isomerization.     

Biosynthesis of the tigloyl esters in Datura: The role of 2-methylbutyric acid

Datura innoxia plants were wick fed with (±)-2-methylbutyric acid-[1-¹⁴C] and harvested after 7 days. The root alkaloids 3α,6β-ditigloyloxytropane and 3α,6β-ditigloyloxytropan-7β-ol were isolated and degraded. In each case the radioactivity was located in the ester carbonyl group indicating that this acid is an intermediate in the biosynthesis of tiglic acid from l-isoleucine. On the other hand, (±)-2-hydroxy-2-methylbutyric acid-[1-¹⁴C], which was fed to hydroponic cultures of Datura innoxia alongside isoleucine[U-¹⁴C] positive control plants, is not an intermediate.     

Hyoscyamine 6beta-hydroxylase, a 2-oxoglutarate-dependent dioxygenase, in alkaloid-producing root cultures

Root cultures of various solanaceous plants grow well in vitro and produce large amounts of tropane alkaloids. Enzyme activity that converts hyoscyamine to 6β-hydroxyhyoscyamine is present in cell-free extracts from cultured roots of Hyoscyamus niger L. The enzyme hyoscyamine 6β-hydroxylase was purified 3.3-fold and characterized. The hydroxylation reaction has absolute requirements for hyoscyamine, 2-oxoglutarate, Fe²⁺ ions and molecular oxygen, and ascorbate stimulates this reaction. Only the l-isomer of hyoscyamine serves as a substrate; d-hyoscyamine is nearly inactive. Comparisons were made with a number of root, shoot, and callus cultures of the Atropa, Datura, Duboisia, Hyoscyamus, and Nicotiana species for the presence of the hydroxylase activity. Decarboxylation of 2-oxoglutarate during the conversion reaction was studied using [1-¹⁴C]-2-oxoglutarate. A 1:1 stoichiometry was shown between the hyoscyamine-dependent formation of CO₂ from 2-oxoglutarate and the hydroxylation of hyoscyamine. Therefore, the enzyme can be classified as a 2-oxoglutarate-dependent dioxygenase (EC 1.14.11.-). Both the supply of hyoscyamine and the hydroxylase activity determine the amounts of 6β-hydroxyhyoscyamine and scopolamine produced in alkaloid-producing cultures.     

Phenyllactic acid but not tropic acid is an intermediate in the biosynthesis of tropane alkaloids in Datura and Brugmansia transformed root cultures

(S)-(-)-Tropic acid is the acidic moiety of the tropane ester alkaloids, hyoscyamine and scopolamine (hyoscine). When tropic acid is fed to transformed root cultures of Datura stramonium L. or a Brugmansia (Datura) Candida x B. aurea hybrid, the formation of these alkaloids is inhibited. Phenyllactic acid, from which the tropoyl moiety is derived, is considerably less inhibitory. Label from (RS)-phenyl[1,3-¹³C₂]lactic acid is incorporated at high levels into apoatropine, littorine, aposcopolamine, hyoscyamine, 7-hydroxyapoatropine, scopolamine and 7-hydroxyhyoscyamine when fed to these cultures. The presence of an excess concentration of unlabelled tropic acid has little influence on the specific incorporation into these products. It is concluded that free tropic acid is not an intermediate in hyoscyamine biosynthesis but rather that the rearrangement of phenyllactic acid occurs subsequent to its esterification.Abbreviations FM fresh mass - NMR nuclear magnetic resonance spectroscopy We are grateful to Drs. N.J. Walton, A.J. Parr, M.J.C. Rhodes (Institue of Food Research, Norwich) and B. Dräger (Münster, Germany) for helpful and critical discussions. We also wish to thank Dr. P. Bachmann (Braunschweig, Germany) for suggesting the use of the DB-17 column to separate littorine from hyoscyamine and for the modified Excel programme used to calculate the specific incorporations, Yannick Ford (AFRC Co-operative Award Studentship, University of Oxford) and Abigael Peerless for their able assistance, Dr. I. Colquhoun for assistance with some of the NMR spectroscopy and Drs. K. Shimomura (Tsukuba, Japan) and T. Hashimoto (Kyoto, Japan) for pure samples of 7-hydroxyhyoscyamine. J.G.W, gratefully acknowledges support from the Nuffield Foundation under the Small Grants Scheme to promote collaborative experimentation and M.A. is grateful to the Ministry of Education, Iran for a research scholarship.     

Metabolism of phenylpropanoids in Hydrangea serrata var. thunbergii and the biosynthesis of phyllodulcin

DL-Phenylalanine-[3-¹⁴C] and cinnamic acid-[3-¹⁴C] were fed to this plant and the label from cinnamic acid was incorporated into gallic acid, phyllodulcin and quercetin. By feeding p- coumaric acid-[U-³H], caffeic acid-[U-³H] and hydrangea glucoside A-[U-³H], it was possible to show that hydroxylation at C-3′in phyllodulcin occurs after the ring closure of dihydroisocoumarin. The biosynthetic pathway of phyllodulcin in this plant is thus: phenylalanine → cinnamic acid → p- coumaric acid → hydrangenol → phyllodulcin.