Metabolism of hygrine in Atropa,Hyoscyamus and Physalis

Three-month-old plants of Physalis alkekengi, Atropa belladonna and Hyoscyamus niger were fed via the roots with either d( + ) or l( - )-hygrine-[2′- ¹⁴C]. The feeding experiments were terminated after 7 days when the following alkaloids were isolated from the paired groups of plants: tigloidine, 3α-tigloyloxytropane and cuscohygrine from Physalis; hyoscyamine from Hyoscyamus and from Atropa. In contrast to Datura these genera appear to use both hygrine enantiomers in the biosynthesis of the tropane ring.     

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.     

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.     

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.     

Metabolism of nicotine in Nicotiana glauca

A mixture of (?)-nicotine-[2′-³H] and (±)-nicotine-[2′-¹⁴C] was administered to Nicotiana glauca plants for 3 days, resulting in the formation of radioactive nornicotine (49·5% incorporation) and myosmine (2·05% incorporation). Negligible activity was detected in anabasine, cotinine, or 3-acetylpyridine, the last two compounds being added as carriers to the harvested plants. The radioactive nornicotine consisted of 48% (?)-nornicotine-[2′-¹⁴C,³H] and 52% (+)-nornicotine-[2′-¹⁴C]. Thus if (+)-nornicotine is formed from (?)-nicotine the transformation must involve loss of the hydrogen from C-2′. Myosmine is presumably formed from nicotine via nornicotine. However by feeding myosmine-[2′-¹⁴C] to N. glauca it was shown that the dehydrogenation is not reversible, no activity being detected in nornicotine. Nicotinic acid (0·14% incorporation) was a metabolite of myosmine-[2′-¹⁴C]. Essentially all the activity of the nicotinic acid was located on its carboxyl group, indicating that myosmine was a direct precursor.     

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.     

Biosynthesis of 3α,6β-ditigloyloxytropane and 3α,6β-ditigloyloxytropan-7β-ol in Datura

Datura meteloides; plants were fed with tiglic acid-[-¹⁴C] via the roots and after 2 days the percentage incorporation into the alkaloids 3α-tigloyloxytropane, 3α,6β-ditigloyloxytropane, meteloidine and 3α,6β-ditigloyloxytropan-7β-ol were 15·2, 1·82, 2·2 and 1·8 respectively. 3α,6β-Ditigloyloxytropane was partially hydrolysed to 6β-hydroxy-3α-tigloyloxytropane which contained 58·1% of the radioactivity of the original base, whereas 3α,6β-ditigloyloxytropan-7β-ol gave meteloidine containing only 9·2% of the original activity. The results suggest that the di- and tri-hydroxytropanes may be formed by different routes.     

Minor alkaloids of Heliotropium curassavicum

Isolation and structure determination of the minor alkaloids of Heliotropium curassavicum are described. These include the new pyrrolizidine alkaloids, heliocurassavine [isoretronecanol (?) curassavine], heliocoromandaline [isoretronecanol (+) viridiflorate], heliocurassavicine [isoretronecanol (?) trachelanthate], heliocurassavinine [laburnine (?) trachelanthate], curassavinine [supinidine (?) curassavate], coromandalinine [supinidine (+) viridifloratel, heliovinine [supinidine (?) trachelanthate] and curassanecine [1-(α-hydroxy-methyl)-8α pyrrolizidin-1β-ol]. Structures were established by high resolution ¹H NMR, mass spectrometry and paper electrophoresis of the alkaloids and their hydrolysis products.     

Biosynthesis of Camptotheca acuminata alkaloids

Tracer feeding experiments with Camptotheca acuminata plants show that [1′-¹⁴C]L-tryptophan, [Ar-³H₄]L-tryptophan, [Ar-³H₄,1′-¹⁴C]tryptophan, [1′-¹⁴C]-tryptamine, [2-¹⁴C]DL-mevalonate, and [2-¹⁴C]geraniol-[2-¹⁴C]nerol are incorporated into camptothecin. Direct stem injection of the labeled precursors into C. acuminata plants resulted in a substantial increase in the activity of isolated Camptotheca alkaloids as compared to root feeding of the same tracer.     

Enantiotopically Selective Oxidation of 1,5-Diols with Gluconobacters Preparation of (S)-Mevalonolactone

(±)-(2Z,4E)-α-Ionylideneacetic acid (2) was enantioselectively oxidized to (?)-(l′S)-(2Z,4E)-4′-hydroxy-α-ionylideneacetic acid (3), (+)-(1′R)-(2Z,4E)-4′-oxo-α-ionylideneacetic acid (4) and (+)-abscisic acid (ABA) (1) by Cercospora cruenta IFO 6164, which can produce (+)-ABA and (+)-4′-oxo-α-acid 4. This metabolism was confirmed by the incorporation of radioactivity from (±)-(2-¹⁴C)-(2Z,4E)-α-acid 2 into three metabolites. (?)-4′-Hydroxy-α-acid 3 was a diastereoisomeric mixture consisting of major 1′,4′-trance-4′-hydroxy-α-acid 3a and minor 1′,4′-cis-4′-hydroxy-α-acid 3b. These structures, 3a and 3b, were confirmed by ¹³C-NMR and ¹H-NMR analysis. Also, the enantioselectivity of the microbial oxidation was reexamined by using optically pure α-acid (+)-2 and (?)-2, as the substrates.     

Formation of (-⊃-1′,2′-epi-2-cis-xanthoxin acid from a precursor of abscisic acid

Tomato shoots and avocado mesocarp supplied with (±)-[2-¹⁴C]-5-(1,2-epoxy-2,6,6-trimethylcyclohexyl)-3-methylpenta-cis-2-trans-4-dienoic acid metabolize it into (+)-abscisic acid and a more polar material that was isolated and identified as (?)-epi-1′(R),2′(R)-4′(S)-2-cis-xanthoxin acid. The (+)-1′(S),2′(S)-4′(S)-2-cis-xanthoxin acid recently synthesized from natural violaxanthin, has the 1′,2′-epoxy group on the opposite side of the ring to that of the 4′(S)-hydroxyl group and the compound is rapidly converted into (+)-abscisic acid. The 1′,2′-epoxy group of (?)-1′,2′-epi-2-cis-xanthoxin acid is on the same side of the ring as the 4′(S) hydroxyl group: the compound is not metabolized into abscisic acid. The configuration of the 1′,2′-epoxy group probably controls whether or not the 4′(S) hydroxyl group can be oxidized. (+)-2-cis-Xanthoxin acid is probably not a naturally occurring intermediate because a ‘cold trap’, added to avocado fruit forming [¹⁴C]-labelled abscisic acid from [2-¹⁴C]mevalonate, failed to retain [¹⁴C] label.     

Biosynthesis of pisatin: Experiments with enantiomeric precursors

Feeding experiments in cupric chloride-treated Pisum sativum pods and seedlings have demonstrated the preferential incorporation of (+)-(6aS,11aS)-[³H]maackiain over (?)-(6aR, 11aR)-[¹⁴C]maackiain into (+)-(6aR, 11aR)-pisatin, establishing that the 6a-hydroxylation of pterocarpans proceeds with retention of configuration. (+)- (6aR,11aR)-6a-hydroxymaackiain was similarly incorporated much better than (?)-(6aS,11aS)-6a- hydroxymaackiain. Where (?)-isomers were incorporated, optical activity measurements on the pisatin produced indicated significant synthesis of (?)-pisatin as well as the normal (+)-pisatin. 7,2′-Dihydroxy-4′,5′- methylenedioxyisoflav-3-ene and both enantiomers of 7,2′-dihydroxy-4′,5′-methylenedioxyisoflavan were poor precursors of pisatin.     

Biosynthesis of ditigloyl esters of DI- and tri-hydroxytropanes in Datura

3α-Tigloyloxytropane-[¹⁴CO] [N-¹⁴Me], ratio 1·6:1 and valtropine-[¹⁴CO] [N-¹⁴Me], ratio 1·75:1 were separately fed via cotton wicks to 4-month-old Datura innoxia plants. After 8 days the root alkaloids 3α-tigloyloxytropane, 3α,6β-ditigloyloxytropane and 3α,6β-ditigloyloxytropan-7β-ol were isolated and the distribution of radioactivity in the acid and alkamine moieties was determined by hydrolysis. The precursor ratios were not maintained in the isolated ditigloyl esters, a result which does not support our hypothesis that the ditigloyl esters are formed by the progressive hydroxylation of 3α-tigloyloxytropane.     

Iridoid and phenylethanoid glycosides from Heterophragma sulfureum

An unusual iridoid diglycoside (specioside 6′-O-α-d-galactopyranoside) and a new phenylethanoid triglycoside (heterophragmoside) were isolated from the leaves and branches of Heterophragma sulfureum together with specioside, verminoside, 6-trans-feruloylcatapol, stereospermoside, (−)-lyoniresinol 3α-O-β-d-glucopyranoside, (+)-lyoniresinol 3α-O-β-d-glucopyranoside, (−)-5′-methoxyisolariciresinol 3α-O-β-d-glucopyranoside, (+)-5′-methoxyisolariciresinol 3α-O-β-d-glucopyranoside, and dehydroconiferyl 4-O-β-d-glucopyranoside. The structural elucidations were based on analyses of chemical and spectroscopic data.     

Biosynthesis of meteloidine from 3α-tigloyloxytropane in Datura innoxia

The administration of 3α-tigloyl-[1-¹⁴C]-oxytropane-[3β-³H] (³H/¹⁴C = 11·0 to Datura innoxia plants for 7 days led to the formation of radioactive meteloidine (³H/¹⁴C = 11·6). Degradation of the meteloidine indicated that the alkaloid was labeled specifically with ³H at C-3 of its teloidine moiety, and on the carbonyl group of its tigloyl residue with ¹⁴C. These results strongly favor the hypothesis that hydroxylation of tropine occurs after formation of its tigloyl ester.     

Eudesmane alcohols from jasonia glutinosa

Three new sesquiterpene alcohols have been isolated from Jasonia glutinosa. Their structures were elucidated by spectroscopic methods and chemical correlations as (?)-[11R]-4α,14-epoxyeudesm-11,12-diol, (?)-[11R]-eudesm-4(14)-en-5β,11,12-triol and (+)-[11R]-eudesm-4(14)-en-5α,11,12-triol and they are called α-epoxy kudtdiol, 5-epi-kudtriol and kudtriol respectively.     

The homogentisate ring-cleavage pathway in the biosynthesis of acetate-derived naphthoquinones of the droseraceae

Photosynthesis experiments with ¹⁴CO₂ established that of 16 Droseraceae species tested Drosophylum lusitanicum incorporated the highest amount of label into plumbagin (2-methyl-5-hydroxy-1,4-naphthoquinone). Tyrosine-[β-¹⁴C] fed to Drosophyllum was shown to label plumbagin efficiently (20% incorporation). Extensive chemical degradation of the labeled naphthoquinone showed, however, that the incorporation of tyrosine was indirect, the label being distributed throughout the molecule. It was established that plumbagin and the closely related 7-methyljuglone are biosynthesized via the acetate-polymalonate pathway. Tyrosine is broken down to acetate in this tissue via the homogentisate pathway, which was demonstrated by feeding and incorporation of label into plumbagin of intermediates such as homogentisate-[¹⁴C], maleyl- and fumarylacetoacetate-[¹⁴C]. Simultaneous application of tyrosine-[β-¹⁴C] and α,α′-bipyridyl, an inhibitor of the homogentisate oxigenase, led to an accumulation of homogentisate-[¹⁴C] within the tissue. The degradation of tyrosine to acetate by Drosophyllum is not due to epiphytic bacteria since ring cleavage of tyrosine and formation of plumbagin from breakdown products occurred both within sterile grown plants and sterile cell suspension cultures. In tissue kept in darkness, plumbagin undergoes a slow turnover with a half life of about 400 hr.     

The incorporation of ornithine-[2,3-13C2] into nicotine and nornicotine established by NMR

dl-Ornithine-[2,3-¹³C₂] was synthesized from acetate-[1-¹³C] and ethyl acetamidocyanoacetate-[2-¹³C]. This labelled material was mixed with dl-ornithine-[5-¹⁴C] and fed to Nicotiana glutinosa plants by the wick method. After 10 days the plants were harvested affording radioactive nicotine and nornicotine (0.14% and 0.051% specific incorporations, respectively). Even at these low specific incorporations an examination of their ¹³C NMR spectra established the incorporation of ornithine symmetrically into the pyrrolidine rings of these alkaloids. Satellites were observable at the signals due to C-2′, 3′, 4′ and 5′ positions, arising by the presence of contiguous carbons at C-2′, 3′ and C-4′, 5′.     

The metabolism of anatabine to α,β-dipyridyl in Nicotiana species

α,β-Dipyridyl isolated from Nicotiana tabacum plants which had been fed anatabine-[2′-¹⁴C, ¹³C], and then allowed to dry in air for 20 days was radioactive (82% specific incorporation)An examination of its ¹³C NMR spectra established that it was enriched only at C-2, indicative of its direct formation from anatabineThe labelled anatabine was also fed to Nglauca and Nglutinosa plants, which were extracted immediately after harvestingIn these experiments no radioactive α,β-dipyridyl was detected, suggesting that α,β-dipyridyl is an artifact produced by the oxidation of anatabine in the drying leaves of tobaccoAnabasine isolated from the Nicotiana species which had been fed anatabine-[2′- ¹⁴C, ¹³C] was unlabelled, indicating that none of this alkaloid is formed by the reduction of anatabine.     

Biosynthesis of tropane ester alkaloids in Datura

Datura meteloides plants were fed via the roots with [1″,2′-¹⁴C]tigloyl hygroline and as a control, [2′-¹⁴C]hygrine. After a week the alkaloids were isolated and degraded. Despite hydrolysis of the putative precursor it was possible, by label ratio, to show that esterification occurs after, and not before, the tropane ring has been synthesized. Hygroline is proposed as a possible intermediate.