Redox interconversions of geraniol and nerol in higher plants

Use of ¹⁴C, ³H-labelled precursors showed that for feedings carried out in winter, isothujone (trans-thujan-3-one) was formed in Tanacetum vulgare from nerol (3,7-dimethyl-octa-cis-2,6-dien-1-ol) without loss of hydrogen from C-1 of the precursor. In contrast, formation from geraniol (the corresponding trans-isomer) involved stereospecific loss ofthe pro-(1S) hydrogen. This suggests that geraniol and nerol were interconverted by a redox system. Similar studies at other seasons with T. vulgare and on the biosynthesis of α- and β-pinenes (pin-3-ene; pin-2-(10)-ene) in Pinus pinaster; 1,8-cineole (1,8-oxidomethane) in Mentha piperita and Eucalyptus globulus; and carvone (menth-6,8(9)-dien-2-one) in M. spicata did not lead to such unambiguous conclusions. The results may be rationalized if (i) the redox system was reversible and/or (ii) tracer at C-1 of the phosphate esters of the precursors was scrambled by action of a phosphatase that induced CO bond fission.     

Biosynthesis of geraniol and nerol in cell-free extracts of Tanacetum vulgare

Cell-free extracts from leaves of Tanacetum vulgare synthesised geraniol and nerol (3,7-dimethylocta-trans-2-ene-1-ol and its cis isomer) in up to 11·9 and 2·4% total yields from IPP-[4-¹⁴C] and MVA-[2-¹⁴C] respectively. Optimum preparations were obtained from plant material just before the onset of flowering. The ratio of the monoterpenols varied 28-fold for different preparations under conditions where these products or their phosphate esters were not interconverted. Similar extracts incorporated α-terpineol-[¹⁴C] and terpinen-4-ol-[¹⁴C] (p-menth-1-en-8- and -4-ol respectively) in 0·05 to 2·2% yields into a compound tentatively identified as isothujone (trans-thujan-3-one), and preparations from flowerheads converted IPP-[4-¹⁴C] in 2·7% yield into geranyl and neryl β-d-glucosides. Inhibitors of IPP-isomerase had little effect on the incorporation of IPP into the monoterpenols in cell-free systems from which endogenous compounds of low molecular-weight had been removed. The inference that a pool of protein-bonded DMAPP or its biogenetic equivalent was present was supported by the demonstration that geraniol and nerol biosynthesised in the absence of the inhibitors were predominantly (65 to 100%) labelled in the moiety derived from IPP.     

Biosynthetic relationship of citral-trans and citral-cis in cymbopogon flexuosus (lemongrass)

Use of [¹⁴C,³H]-labelled precursors revealed that leaf blades of Cymbopogon flexuosus converted geraniol (3,7-dimethylocta-trans-2,6-diene-1-ol) into citral-trans with loss of pro-(1S) hydrogen whereas nerol lost the pro-(1R) hydrogen while being converted into citral-cis. Secondly, the citral-trans is converted into citral-cis and vice versa and there is no separate route for the biosynthesis of either of the two aldehyde isomers.     

Biosynthesis of irregular monoterpenes in extracts from higher plants

Extracts from Artemisia annua and Santolina chamaecyparissus converted ¹⁴C-labelled IPP, DMAPP and DMVC into artemisia ketone, its corresponding alcohol, lavandulol and trans-chrysanthemyl alcohol with up to 12.0 % incorporation of tracer. DMVC was the most effective precursor under standard conditions and led to unequal distribution of tracer in the C-5 moieties. The same extracts interconverted cis and trans-chrysanthemyl alcohols and their pyrophosphates, artemisia ketone, and artemisyl alcohol in up to 10·4% yields, but geraniol, nerol and linalol or their pyrophosphates were not precursors of any of these compounds. Formation of artemisia ketone and its alcohol from C-5 intermediates was enhanced by NAD⁺ and NADP⁺ but was unaffected by absence of oxygen. These co-factors did not affect the yields of lavandulol or trans-chrysanthemyl alcohol. These observations suggest closely related biogenetic pathways to the three irregular skeltons that do not involve the usual C-10 intermediates of monoterpene biosynthesis: i.e. the biogenetic isoprene rule is not obeyed.     

Biosynthetic origin of the gem-methyls of geraniol

Degradation of geraniol (3,7-dimethylocta-trans-2,6-dien-1-ol) biosynthesized in Rosa dilecta has proved that C-10 is exclusively derived from C-2 of mevalonate. This verifies the generally accepted but hitherto unproven view of the origin of the gem-methyls in this compound and of the corresponding groups in other terpenoids.     

Redox interconversion of geraniol and nerol in Rosa damascena

Use of ¹⁴C, ³H-labelled precursors revealed that flowerheads of Rosa damascena converted geraniol (3,7-dimethylocta-trans-2,6-dien-1-ol) into nerol (the corresponding cis-isomer) with loss of the pro-(1S) hydrogen, whereas the reverse isomerization involved loss of the pro-(1R) atom. The inference that the interconversion proceeded by redox reactions with the formation of the corresponding aldehydes was supported by the preparation of cell-free extracts from R. damascena and R. dilecta that sustained such processes. These reactions were NADP⁺-NADPH dependent and had pH optima at 7.0 and 9.0, respectively.     

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%).     

Purification and properties of alcohol oxidase from Tanacetum vulgare

Alcohol oxidase (alcohol: O₂ oxidoreductase) from leaves of Tanacetum vulgare has been purified 5150-fold to homogeneity on disc electrophoresis and gel electrofocussing. The enzyme which is probably flavoprotein, has molecular weight 180 000 daltons and is comprised of two sub-units of 94 000 and 75 000 daltons. It is active over a broad range (pH 5–9) and best accepts primary aliphatic alcohols with 6 to 10 carbons, especially those with a 2-ene group. K_m values for hex-trans-2-ene-1-ol, geraniol (3,7-dimethylocta-trans-2,6-dien-1-ol) and n-octanol were 0.19, 1.56 and 0.49 mM respectively. The significance of the enzyme in the formation of leaf aldehyde (hex-trans-2-ene-1-al) and in terpene metabolism is discussed.     

Biosynthesis of artemisia ketone in higher plants

MVA-[2-¹⁴C], IPP-[4-¹⁴C] and DMAPP-[4-¹⁴C] were incorporated (optimum 0.04%–0.8 %) into artemisia ketone by Artemisia annua in a position-specific manner so that the C-5 moiety not containing the carbonyl group was preferentially (87–95 %) labelled. IPP and DMAPP, but not MVA, were similarly utilised in Santolina chamaecyparissus. Feeding of geraniol-[2-¹⁴C] to A.annua resulted in artemisia ketone being labelled in a position indicating extensive degradation of the precursor. ¹⁴C-labelled cis and trans-chrysanthemyl alcohols and chrysanthemates or DMVC were negligibly (< 5 × 10^?4 %) incorporated into artemisia ketone in both species over a range of feeding conditions. (+)-trans-Chrysanthemyl alcohol-[Me¹⁴C] was an effective (ca 2 % incorporation) precursor of the terpenoid part of pyrethrins I and II in flowers of Chrysanthemum cinerariaefolium but ¹⁴C-labelled artemisyl alcohol (3, 3, 6-trimethylheptan-1, 5-dien-4-ol) or (±)-cis-chrysanthemyl alcohol were not detectably incorporated. Although some of the negligible incorporations are probably attributable to compartmentation effects preventing access of precursors to biosynthetic sites, the experiments indicate some limitation of the previously proposed pathways of biogenesis of artemisia ketone and related irregular monoterpenes.     

Biosynthesis of (+)-car-3-ene in Pinus species

Degradation of (+)-car-3-ene biosynthesized from MVA-[2-¹⁴C] in Pinus palustris or Pinus sylvestris proved that the C-4 atom of the monoterpene is derived from C-2 of MVA rather than C-4 as has been hitherto assumed. The pro-2S hydrogen of MVA is stereospecifically lost in the formation of the Δ³-double bond. These results delineate possible routes for the biosynthesis of the carane skeleton.     

Conversion of [1-3H2,G-14C]geranyl pyrophosphate to cyclic monoterpenes without loss of tritium

Soluble enzyme preparations from Salvia officinalis convert the acyclic precursor [1-³H₂,G-¹⁴C]geranyl pyrophosphate to cyclic monoterpenes of the pinane (α-pinene,β-pinene), isocamphane (camphene), p-menthane (limonene,1,8-cineole), and bornane (bornyl pyrophosphate, determined as borneol) type without loss of tritium, and without significant conversion to other free acyclic intermediates. Similarly, [1-³H₂,G-¹⁴C]geraniol is converted in intact S. officinalis leaves to the cyclic monoterpene olefins and 1,8-cineole, as well as to isothujone and camphor, without loss of tritium from C(1). These results clearly eliminate transcis isomerization of geranyl pyrophosphate to neryl pyrophosphate via aldehyde intermediates prior to cyclization, and they support a scheme whereby the trans precursor is cyclized directly by way of a bound linaloyl intermediate.     

Biosynthesis of Δ5.23 sterols in etiolated coleoptiles from Zea mays

In addition to the previously found ergosta-5, E-23-dien-3β-ol and 5α-ergosta-7, E-23-dien-3β-ol, the following Δ23 sterols have been identified in etiolated maize coleoptiles: cyclosadol, 4α, 14α-dimethyl-5α-ergosta-8, E-23-dien-3β-ol, 4α, 14α-dimethyl-9β, 19-cyclo-5α-ergosta-8, E-23-dien-3β-ol and 4α-methyl-5α-ergosta-7, E-23-dien-3β-ol. The incubation of maize coleoptile microsomes in the presence of cycloartenol and of [¹⁴C-methyl]S-adenosyl methionine gave a mixture of labelled 24-methylene cycloartanol and cyclosadol. No trace of cyclolaudenol could be detected in these conditions. It is suggested that Δ²³ sterols are products of the C-24 methyltransferase reaction and they probably do not arise from a Δ²⁴ → Δ²³ isomerization occurring at a later stage of the biosynthesis. The Δ¹³-sterols may play an intermediary role in the biosynthesis of 24-methyl sterols in this plant material.     

Biosynthesis of chiral α- and β-pinenes in pinus species

C-3 of (+) and (?)-α-pinene and of (?)-β-pinene biosynthesized in several Pinus species was derived from C-2 of mevalonate; and the hydrogen at C-5 in all the isomers was derived from that at C-6 in nerol. This pattern is consistent with two routes for bicyclization of the acyclic biosynthetic precursor: one leads to (?)-β-pinene and the other to (+)-α-pinene of opposite absolute configuration. (?)-α-Pinene probably results from subsequent isomerisation of the (?)-β-isomer, and (very small) amounts of (+)-β-pinene result from similar (unfavoured thermodynamically) isomerisation of the (+)-α-isomer.     

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.     

Effect of ay-9944 on sterol biosynthesis in Chlorella sorokiniana

When Chlorella sorokiniana was grown in the presence of 4 ppm AY-9944 total sterol production was unaltered in comparison to control cultures. However, inhibition of sterol biosynthesis was shown by the accumulation of a number of sterols which were considered to be intermediates in sterol biosynthesis. The sterols which were found in treated cultures were identified as cyclolaudenol, 4α,14α-dimethyl-9β,19-cyclo-5α-ergost-25-en-3β-ol, 4α,14α-dimethyl -5α-ergosta-8,25-dien-3β-ol, 14α-methyl-9β,19-cyclo-5α-ergost-25-en-3β-ol, 24-methylpollinastanol, 14α-methyl-5α-ergost-8-en-3β-ol, 5α-ergost -8(14)-enol, 5α-ergost-8-enol, 5α-ergosta-8(14),22-dienol, 5α-ergosta-8,22-dienol, 5α-ergosta-8,14-dienol, and 5α-ergosta-7,22-dienol, in addition to the normally occurring sterols which are ergosterol, 5α-ergost-7-enol, and ergosta-5,7-dienol.The occurrence of these sterols in the treated culture indicates that AY-9944 is an effective inhibitor of the Δ⁸ → Δ⁷ isomerase and Δ¹⁴-reductase, and also inhibits introduction of the Δ²²-double bond. The occurrence of 14α-dimethyl-5α-ergosta-8,25-dien-3β-ol and 14α-methyl-9β,19-cyclo-5α-ergost -25-en-3β-ol is reported for the first time in living organisms. The presence of 25-methylene sterols suggests that they, and not 24-methylene derivatives, are intermediates in the biosynthesis of sterols in C. sorokiniana.     

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.     

Inhibition of δ8 → δ7-sterol isomerase and of cycloeucalenol—obtusifoliol isomerase by N-benzyl-8-aza-4α, 10-dimethyl-trans-decal-3β-ol,an analogue of a carbocationic high energy intermediate

An enzymatic assay for the δ⁸ → δ⁷-sterol isomerase, an enzyme involved in sterol biosynthesis, has been developed in higher plants. This assay has been used in the study of various inhibitors. N-Benzyl-8-aza-4α, 10-dimethyl- trans-decal-3β-ol was designed to mimic the C-8 and the C-9 carbocationic high energy intermediates occurring during the reactions catalysed by the δ⁸ → δ⁷-sterol isomerase and the cycloeucalenol obtusifoliol isomerase, respectively. In accordance with the ‘transition state analogues’ theory, this analogue of a high energy intermediate was found to be a very potent and specific inhibitor of the two enzymatic reactions both in vitro and in vivo.     

Comparative study of the inhibition of sterol biosynthesis in Rubus fruticosus suspension cultures and zea mays seedlings by N-(1,5,9-trimethyldecyl)-4α,10-dimethyl-8-aza-trans-decal-3β-ol and derivatives

The nitrogen substituents present in tridemorph and fenpropimorph, which are systemic fungicides, have been linked to an 8-aza-bicyclic skeleton leading to N-(1,5,9-trimethyldecyl)-4α,10-dimethyl-8-aza-trans-decal-3β-ol and N-(3-(4-tert-butylphenyl-)2-methyl)-propyl-8-aza-4α,10-dimethyl-trans-decal-3β-ol respectively. The latter two compounds present in a stable molecule key structural elements of unstable C-8 and C-9 carbocationic high-energy intermediates which occur during the reactions catalysed by the Δ⁸ → Δ⁷-sterol isomerase and the cycloeucalenol-obtusifoliol isomerase, respectively. When given to either bramble cell suspension cultures or maize seedlings, they led to a spectacular accumulation of 9β,19-cyclopropyl sterols and were in that respect much more efficient than any known molecules and in particular than the N-benzyl decalin previously described which led to accumulation of Δ⁸-sterols. Surprisingly, treatment of the plant cells by the N-oxide derivatives of the N-benzyl decalin resulted in dramatic accumulation of Δ^8,14-sterols.     

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.     

Preparation of labelled terpenyl pyrophosphates using extracts of barley seed embryos

A cell-free system derived from seed embryos of barley (Hordeum vulgare cv. Zephyr) grain has been used to prepare substrate quantities of radioactively-labelled C₅-C₂₀ intermediates of terpenoid biosynthesis. The purification and characterization of high specific activity all-trans farnesyl-[4, 8, 12-³H] and all-_trans geranylgeranyl-[4, 8, 12, 16-³H] pyrophosphates, suitable for use in studies of sterol and carotenoid biosynthesis, are described in detail. The effects of the plant growth retardant AMO 1618 on the system are reported.