Biosynthesis of sitosterol in barley seedlings

A method is described for the chemical synthesis of stigmasta-5,24-dien-3β-ol-[26-¹⁴C] and (24S)-24-ethylcholesta-5,25-dien-3β-ol-[26-¹⁴C] (clerosterol). 28-Isofucosterol-[7-³H₂] fed to developing barley seedlings (Hordeum vulgare) was incorporated into sitosterol and stigmasterol confirming the utilisation of a 24-ethylidene sterol intermediate in 24α-ethyl sterol production in this plant. Also, the use of mevalonic acid-[2-¹⁴C(4R)-4-³H₁] verified the loss of the C-25 hydrogen of 28-isofucosterol during its conversion into sitosterol and stigmasterol in agreement with the previously postulated isomerisation of the 24-ethylidene sterol to a Δ²⁴⁽²⁵⁾-sterol prior to reduction. However, feeding stigmasta-5,24-dien-3β-ol [26-¹⁴C] to barley seedlings gave very low incorporation into sitosterol. Attempts to trap radioactivity from mevalonic-[2-¹⁴C(4R)-4-³H₁] in stigmasta-5,24-dien-3β-ol when this unlabelled sterol was administered to barley seedlings gave only a very small incorporation although both 28-isofucosterol and sitosterol were labelled.     

Ergosterol biosynthesis in Mucor pusillus

Ergosterol, 22-dihydroergosterol, obtusifoliol and 24-methylene-24,25-dihydrolanosterol, isolated from Mucor pusillus grown in the presence of methionine-[methyl-²H₃], each contained two deuterium atoms; lanosterol, however, was unlabelled. Ergosterol and 22-dihydroergosterol, isolated from M. pusillus grown in the presence of mevalonic acid-[2-¹⁴C, (4R)-4-³H₁] had ¹⁴C:³H atomic ratios of 5:3. The significance of these results in terms of sterol biosynthesis in this organism in general and alkylation at C-24 in particular is discussed.     

The conversion of 24-ethylidene sterols into poriferasterol by the alga Ochromonas malhamensis

A convenient method is described for the preparation of fucosterol-[7-³H₂] and 28-isofucosterol-[7-³H₂]. Both of these 24-ethylidene sterols, as well as 5α-stigmasta-7,Z-24(28)-diene-3β-ol-[2,4-³H₄], were converted into the 24β-ethyl sterol, poriferasterol, by cultures of the chrysophyte alga Ochromonas malhamensis. However, fucosterol-[7-³H₂] was not so efficiently incorporated as the other two compounds thus indicating that the configuration of the 24-ethylidene group is of some importance. It is suggested that a 24-ethylidene sterol of the Z-configuration is produced in de novo poriferasterol synthesis and that a Δ^22,24(28)-diene may be an important subsequent intermediate.     

Mechanism of alkylation at C-24 during ergosterol biosynthesis in Phycomyces blakesleeanus

Ergosterol isolated from Phycomyces blakesleeanus grown in the presence of methionine-[methyl-²H₃] contained two ²H atoms showing that one ²H atom is lost during transmethylation. Ergosterol isolated from P. blakesleeanus grown in the presence of mevalonic acid-[2-¹⁴C,(4R)-4-³H₁] had a ¹⁴C:³H atomic ratio of 5:3. Chemical degradation of 2,3-dimethylbutanal obtained by ozonolysis of the doubly-labelled ergosterol showed that the ³H atom originally at C-24 of lanosterol is transferred to C-25 of ergosterol during transmethylation. The mechanism of formation of the ergosterol side chain in P. blakesleeanus is presented.     

Sitosterol biosynthesis in Hordeum vulgare

Excised barley embryos cultured on a nutrient medium containing methionine-[CD₃] incorporated deuterium into the newly biosynthesized sterols. Two deuterium atoms were present in 24-methylenecycloartanol, 24-methylenelophenol and campesterol and a maximum of four deuterium atoms were incorporated into 24-ethylidenelophenol, stigmasterol and sitosterol. Mevalonic acid-[2-¹⁴C(4R)4-³H₁] was utilized by the barley embryos to give 28-isofucosterol with a ³H-¹⁴C atomic ratio of 3:5 and stigmasterol and sitosterol with a ³H-¹⁴C atomic ratio of 2:5. 24-Methylenelophenol and 24-ethylidenelophenol were isolated from barley seed and 24-ethylidenelophenol-[2,4-³H₃] was incorporated into sitosterol by barley seedlings. These results show that in the production of sitosterol a 24-ethylidenesterol intermediate is produced and it is suggested that this is isomerized to give a Δ^24,(25) sterol prior to reduction to the saturated C₂₉ sterol side chain.     

Incorporation of methionine-[methyl-2H3] and mevalonic acid-[2-14C,(4R)-4-3H1] into Phycomyces blakesleeanus sterols

Ergosterol, episterol, 4α-methyl-5α-ergosta-8,24(28)-dien-3β-ol and 24-methylene-24,25-dihydrolanosterol, isolated from Phycomyces blakesleeanus grown in the presence of methionine-[methyl-²H₃], each contained two deuterium atoms; lanosterol, however, was unlabelled. The ¹⁴C:³H atomic ratio of the following sterols isolated from P. blakesleeanus grown in the presence of mevalonic acid-[2-¹⁴C,(4R)-4-³H₁], was: ergosterol, 5:3; episterol, 5:4; ergosta-5,7,24(28)-trien-3β-ol, 5:3; 4α-methyl-5α-ergosta-8,24(28)-dien-3β-ol, 5:4; 24-methylene-24,25-dihydrolanosterol, 6:5; lanosterol, 6:5. The significance of these results in terms of ergosterol biosynthesis is discussed.     

Investigations on the Δ23-, Δ24(28)- and Δ25-Sterols of zea mays

The sterols of Zea mays shoots were isolated and characterized by TLC, HPLC, GC/MS and ¹H NMR techniques. In all, 22 4-demethyl sterols were identified and they included trace amounts of the Δ²³-, Δ²⁴- and Δ²⁵-sterols, 24-methylcholesta-5,E-23-dien-3β-ol, 24-methylcholesta-5,Z-23-dien-3β-ol, 24-methylcholesta-5,25-dien-3β-ol, 24-ethylcholesta-5,25-dien-3β-ol and 24-ethylcholesta-5,24-dien-3β-ol. In the 4,4-dimethyl sterol fraction, cycloartenol and 24-methylenecycloartanol were the major sterol components but small amounts of the Δ²³-compound, cyclosadol, and the Δ²⁵-compound, cyclolaudenol, were recognized. These various Δ²³- and Δ²⁵-sterols may have some importance in alternative biosynthetic routes to the major sterols, particularly the 24β-methylcholest-5-en-3β-ol component of the C₂₈-sterols. Radioactivity from both [2-¹⁴C]MVA and [methyl-¹⁴C]methionine was incorporated by Z. mays shoots into the sterol mixture. Although 24-methylene and 24-ethylidene sterols were relatively highly labelled, the various Δ²³- and Δ²⁵-sterols contained much lower levels of radioactivity, which is possibly indicative of their participation in alternative sterol biosynthetic routes. (24R)-24-Ethylcholest-5-en-3β-ol (sitosterol) had a significantly higher specific activity than the 24-methylcholest-5-en-3β-ol indicating that the former is synthesized at a faster rate.     

Observations on the biosynthesis of 24-methylcholesterol and 24-ethylcholesterol by Zea mays

Examination of the sterols of Zea mays shoots has established that the 24-ethylcholesterol is predominately the 24α-epimer, sitosterol, but the 24-methylcholesterol is a mixture of the 24α- and 24β-epimers. After incubation of Z. mays shoots with [2-¹⁴C, (4R)4-³H₁]mevalonic acid the sitosterol had a ³H: ¹⁴C atomic ratio of 2.09:5 which is consistent with previous results indicating that a Δ²⁴⁽²⁵⁾ -sterol is implicated in its biosynthesis. By contrast, the 24α- and 24β-methylcholesterol mixture had a higher ³H: ¹⁴C atomic ratio of 2.82:5. This can be explained by the operation of two routes for the elaboration of the 24-methylcholesterol side chain. One may proceed via Δ²⁴⁽²⁵⁾- and Δ²⁴⁽²⁵⁾-sterols to produce the 24α-methylcholesterol with a ³H: ¹⁴C atomic ratio of 2:5. The other route may involve reduction of either a Δ²⁴⁽²⁸⁾-, a Δ²³- or a Δ²⁵-sterol intermediate to give the 24β1-methylcholesterol with a ³H: ¹⁴C atomic ratio of 3:5. The proportion of these two labelled compounds in the mixture then determines the observed ³H: ¹⁴C atomic ratio (2.82:5). Some evidence for the formation of a Δ²⁵-compound, cyclolaudenol, by Z. mays shoots was provided by incorporation studies employing either [2-¹⁴C]mevalonic acid or [Me-¹⁴C]methionine as the sterol precursor.     

The conversion of 5α-lanost-24-ene-3β,9α-diol and parkeol into poriferasterol by the alga Ochromon as malhamensis

The 4,4-dimethylsterols 4α-lanost-24-ene-3β,9α-diol-[2-³H₂] and parkeol-[2-³H₂] were synthesized from lanosterol and subsequently incubated with cultures of Ochromonas malhamensis. 5α-Lanost-24-ene-3β,9α-diol was converted into poriferasterol with three times the efficiency of parkeol. Clionasterol was also found to be labelled from both parkeol and 5α-lanost-24-ene-3β,9α-diol. No significant incorporation of radioactivity into sterols was obtained after feeding 5α-lanost-24-ene-3β,9α-diol to higher plants, the chlorophyte alga Trebouxia, yeast or a cell free homogenate of rat liver.     

Conversion of a 24β-ethyl-25-methylene intermediate into poriferasterol by Trebouxia species

Clerosterol-[26-¹⁴C], a 24β-ethyl-25-methylene sterol [(24S)-24-ethylcholesta-5,25-dien-3β-ol], was incorporated into clionasterol and poriferasterol by cultures of the green algae Trebouxia sp. 213/3 and Trebouxia sp. 219/2. Degradation of the labelled poriferasterol showed that the ¹⁴C retained its identity and was not incorporated as a result of metabolism of the clerosterol-[26-¹⁴C] and randomisation of label. These results are consistent with the proposed production, and subsequent reduction, of a 24β-ethyl-25-methylene intermediate in 24β-ethyl sterol biosynthesis in algae of the order Chlorococcales.     

The stereochemistry of biosynthesis of decaprenoxanthin in a cell-free system

Intact cells of Flavobacterium dehydrogenans grown on glucose or acetate did not incorporate mevalonic acid-[¹⁴C]. After treatment with lysozyme the protoplasts were lysed by sonication in a dilute medium containing mevalonic acid-[¹⁴C] and the cell-free system produced incorporated label into uncyclized C₄₀, monocyclic C₄₅ and bicyclic C₅₀ carotenoids of which decaprenoxanthin was the most abundant.With mevalonate-[2-¹⁴C,4R-4-³H₁] the ¹⁴C:³H ratios of the carotenoids showed that the hydrogen atoms at C-2 and C-6 of the ring and that at C-3 of the 1-hydroxy, 2-methyl but-2-ene-4-yl residues of decaprenoxanthin were derived from the 4-pro-R hydrogen atom of mevalonic acid.Mevalonate-[2-¹⁴C,2R-2-³H₁] and mevalonate-[2-¹⁴C,2S-2-³H₁] gave ratios which showed that the C-4 hydrogen atoms of decaprenoxanthin were derived from the 2-pro-S hydrogen atom of mevalonic acid.     

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.     

Stereochemical aspects of the biosynthesis of the side chain of 9beta, 19-cyclopropyl sterols in maize seedlings treated with tridemorph

9β, 19-Cyclopropyl sterols such as 24-methyl pollinastanol accumulate dramatically in maize (Zea mays L. var LG 11) seedlings treated with Tridemorph (2,6-dimethyl-N-tridecyl-morpholine), a systemic fungicide (M. Bladocha, P. Benveniste, Plant Physiol 1983 41: 756-762). In contrast to the situation in control plants where 24-ethyl sterols predominate largely, 24-methyl sterols were more than 98% of total cyclopropyl sterols. In addition, 24-methyl cyclopropyl sterols were a mixture of (24-R)- and (24-S)-24-methyl epimers and are similar in that respect to the 24-methyl cholesterol of control plants. The presence of two epimers at C-24 has been previously explained by the operation of two routes (M. Zakelj, L. J. Goad, Phytochemistry 1983 22: 1931-1936). One may proceed via Δ²⁴⁽²⁸⁾- and Δ²⁴⁽²⁵⁾-sterols to produce the (24-R)-24-methyl epimer. The other route may involve reduction of either a Δ²⁴⁽²⁸⁾-, a Δ²³-, or a Δ²⁵-sterol intermediate to give the (24-S)-24-methyl epimer. Such intermediates have been searched for in excised Zea mays axes grown aseptically in the presence of Tridemorph and either [5-¹⁴C]mevalonic acid, or [Me-¹⁴C]-l-methionine. Whereas Δ²⁴⁽²⁸⁾- and Δ²⁴⁽²⁵⁾-cyclopropyl sterols were found in relatively large amounts, only traces of radioactivity were associated with Δ²⁵-sterols. Gas chromatography/mass spectrometry analysis of the sterols from axes grown in the presence of [Me-²H₃]-l-methionine showed that Δ²⁴⁽²⁸⁾-cyclopropyl sterols contained only two ²H atoms at C-28 as expected and that the 24-methyl pollinastanol fraction contained species with two ²H atoms and no species with three ²H atoms. These results indicate that both (24-R)- and (24-S)-epimers originate from a common Δ²⁴⁽²⁸⁾ precursor. After incubation of the axis with [5-¹⁴C,(4-R)-4-³H₁]mevalonic acid, the 24-methyl pollinastanol had a ³H:¹⁴C atomic ratio of 4:6 which is consistent with the intermediacy of a Δ²⁴⁽²⁵⁾-sterol. All these data are in accordance with a pathway where Δ²⁴⁽²⁸⁾-cyclopropyl sterols are isomerized to give Δ²⁴⁽²⁵⁾-cyclopropyl sterols which in turn would be reduced nonregiospecifically to yield both (24-R)- and (24-S)-24-methyl pollinastanols. A plausible mechanism for the reduction step is discussed.     

Studies on the biosynthesis of the carane skeleton

Measurements of isotope ratios in car-3-ene biosynthesized in Pinus sylvestris from (3RS)-mevalonate-[2-¹⁴C,2R-³H₁], and [2-¹⁴C,4R-³H₁] and the corresponding S-epimers and also from geraniol- [¹⁴C,1-³H₂] and nerol-[¹⁴ C,1-³H₂] have shown that the carane skeleton is constructed from its presumed monocyclic precursor with migration of an olefinic bond, together with an unexpected 1,2-shift of a proton to the site of the original double bond. The detailed stereochemistry of the processes allows a two-step mechanism to be inferred for the cyclization in which a bonded intermediate is involved. The conversion of geraniol into nerol (en route to car-3-ene) probably is a redox process with the intermediacy of the corresponding aldehydes. The present results eliminate a possible mechanism for this isomerization wherein cyclopropane derivatives occur as intermediates.     

In vivo conversion of [4-14C]sitosterol and [22,23-3H]sitosterol to stigmasterol in barley seedlings

Six-day-old barley seedlings were allowed to take up [4-¹⁴C]sitosterol and [22, 23-³H]sitosterol for 2.5 hr and the incorporation into the sterol fractions was determined after 0, 6, 12 and 24 hr. Sitosterol was readily incorporated into every sterol class. The ³H/¹⁴C ratio in the free forms dropped when compared with the ³H/¹⁴C ratio of the administered sitosterol. In the free sterol, radioactive stigmasterol, showing a ³H/¹⁴C ratio half that of the sitosterol ³H/¹⁴C ratio, was isolated and its radiochemical purity established by dilution with carrier material and crystallization to constant specific activity.     

Biosynthesis of vitamin E and of the plastoquinones in chloroplasts: Steric course of the decarboxylation

Samples of (3R)- and (3S)-4′hydroxyphenyl[3-²H₁, 3-³H]pyruvate were prepared by taking advantage of the known stereospecificity of phenylpyruvate keto-enol isomerase (tautomerase). 4′-Hydroxyphenyl[3-¹⁴C]pyruvate was obtained by the action of l-amino acid oxidase on dl-[3-¹⁴C]tyrosine, whereas a simple base-catalyzed exchange procedure yielded samples of 4′-hydroxyphenyl[3-³H]- and 4′-hydroxyphenyl[3-²H₂]pyruvate. All labeled samples were converted in situ into the corresponding homogentisic acids on 4′-hydroxyphenyl-pyruvate dioxygenase that is known to catalyze the migration of the acetate side chain with retention of configuration. The isolated doubly labeled homogentisic acids were incubated with chloroplasts from Raphanus sativus cv. saxa Treib, and from the lipophilic products a fraction containing inter alia tocopherol, tocoquinone, and plastoquinone was obtained by chromatographic procedures. The incorporation of radioactivity was between 0.5 and 11% based on homogentisate. Reductive acetylation of the quinones yielded crystalline diacetylhydroquinones, which were submitted to Kuhn-Roth degradation. The radioactive acetate samples thus obtained were analyzed for chirality by an enzymatic procedure previously published. (2R)-[2-²H₁, 2-³H]Homogentisate gave mainly (S)-acetate, whereas (2S)-[2-²H₁, 2-³H]homogentisate was converted mainly into (R)-acetate. It is concluded that the decarboxylation of the side chain occurred with stereochemical retention during the biosynthetic process.     

Biosynthesis of artemisinin in Artemisia annua

The isotope ratios (³H:¹⁴C) in arteannuin B and artemisinin biosynthesized in Artemisia annua from [4R-³H₁,2-¹⁴C]-, [5-³H₂,2-¹⁴C]- and [2-³H₂,2-¹⁴C](3RS)- mevalonate have revealed that two specific 1,2-hydride shifts take place during the oxidation and lactonization of the germacrane skeleton to yield dihydrocostunolide. The gem-methyls of DMAPP retain their identity until the final steps of artemisinin biosynthesis. Arteannuin B is considered to be a late precursor of artemisinin and the following biosynthetic sequence is suggested: farnesylpyrophosphate → germacrane skeleton → dihydrocostunolide → cadinanolide → arteannuin B → artemisinin.     

1,2 Hydrogen-shifts in the biosynthesis of the thujane skeleton

Degradation of (+)-isothujone (trans-thujan-3-one) biosynthesized in Tanacetum vulgare from (3RS)-mevalonic acid (MVA)-[2-¹⁴C, 2-³H₂] showed that one hydrogen from C-2 of the precursor was specifically incorporated at C-4 of product whereas the other was lost. Feeding of α-terpineol-[9-¹⁴C, 4-³H₁, 10-³H₃] (p-menth-1-en-8-ol) yielded isothujone with the same isotope ratios as in precursor. These results indicate 1,2 hydrogen-shifts at two locations in the construction of the the thujane skeleton from α-terpineol or its biogenetic equivalent, and are consistent with a mechanism involving direct cyclization of the latter to a product that by-passes the formation of the biogenetic equivalent of terpinen-4-ol (p-menth-1-en-4-ol) as an intermediate. (3R)-MVA-[¹⁴C, ³H] was more effectively incorporated (up to 1.5 %) into (+)-isothujone in vivo during autumn or winter than in summer (up to 0.02%).     

Biosynthesis of nimbolide from [2-14C,(4R)4-3H1] mevalonic acid lactone in the leaves of Azadirachta indica

Nimbolide was biosynthesized from [2-¹⁴C, (4R)4-³H₁]mevalonic acid lactone in the leaves of Azadirachta indica. The nimbolide had a ³H:¹⁴C ratio of 3:5 which gives support to the suggestion of the involvement of a triterpenoid intermediate with a double bond at the Δ⁸⁽⁹)-position in the biosynthesis of nimbolide.     

A Study of Formate Production and Oxidation in Leaf Peroxisomes during Photorespiration

When glycolate was metabolized in peroxisomes isolated from leaves of spinach beet (Beta vulgaris L., var. vulgaris) formate was produced. Although the reaction mixture contained glutamate to facilitate conversion of glycolate to glycine, the rate at which H₂O₂ became “available” during the oxidation of [1-¹⁴C]glycolate was sufficient to account for the breakdown of the intermediate [1-¹⁴C]glyoxylate to formate (C₁ unit) and ¹⁴CO₂. Under aerobic conditions formate production closely paralleled ¹⁴CO₂ release from [1-¹⁴C]glycolate which was optimal between pH 8.0 and pH 9.0 and was increased 3-fold when the temperature was raised from 25 to 35 C, or when the rate of H₂O₂ production was increased artificially by addition of an active preparation of fungal glucose oxidase.