Biosynthesis of monoterpenes: preliminary characterization of bornyl pyrophosphate synthetase from sage (Salvia officinalis) and demonstration that Geranyl pyrophosphate is the preferred substrate for cyclization.

Previous studies with soluble enzyme preparations from sage (Salvia officinalis) demonstrated that the monoterpene ketone (+)-camphor was synthesized by the cyclization of neryl pyrophosphate to (+)-bornyl pyrophosphate followed by hydrolysis of this unusual intermediate to (+)-borneol and then oxidation of the alcohol to camphor (R. Croteau, and F. Karp, 1977, Arch. Biochem. Biophys.184, 77–86). Preliminary investigation of the (+)-bornyl pyrophosphate synthetase in crude preparations indicated that both neryl pyrophosphate and geranyl pyrophosphate could be cyclized to (+)-bornyl pyrophosphate, but the presence of high levels of phosphatases in the extract prevented an accurate assessment of substrate specificity. The competing phosphatases were removed by combination of gel filtration on Sephadex G-150, chromatography on hydroxylapatite, and chromatography on O-(diethylaminoethyl)-cellulose. In these fractionation steps, activities for the cyclization of neryl pyrophosphate and geranyl pyrophosphate to bornyl pyrophosphate were coincident, and on the removal of competing phosphatases, the synthetase was shown to prefer geranyl pyrophosphate as substrate ($\text{V}\text{K}{}_{\mathrm{m}}$ for geranyl pyrophosphate was 20-fold that of neryl pyrophosphate). No interconversion of geranyl and neryl pyrophosphates was detected. The partially purified bornyl pyrophosphate synthetase had an apparent molecular weight of 95,000, and required Mg²⁺ for catalytic activity (K_m for Mg²⁺ ~ 3.5 mm). Mn²⁺ and other divalent cations were ineffective in promoting the formation of bornyl pyrophosphate. The enzyme exhibited a pH optimum at 6.2 and was strongly inhibited by both p-hydroxymercuribenzoate and diisopropylfluorophosphate. Bornyl pyrophosphate synthetase is the first monoterpene synthetase to be isolated free from competing phosphatases, and the first to show a strong preference for geranyl pyrophosphate as substrate. A mechanism for the cyclization of geranyl pyrophosphate to bornyl pyrophosphate is proposed.     

Demonstration of a cyclic pyrophosphate intermediate in the enzymatic conversion of neryl pyrophosphate to borneol

A soluble enzyme preparation obtained from young sage (Salvia officinalis) leaves catalyzes the conversion of neryl pyrophosphate to (+)-borneol and the oxidation of (+)-borneol to (+)-camphor. Attempts to purify the borneol synthetase activity by gel permeation column chromatography resulted in the apparent loss of catalytic capability; however, subsequent recombination of column fractions demonstrated that two separable enzymatic activities were required for the conversion of neryl pyrophosphate to borneol. Several lines of evidence indicated that a water-soluble, dialyzable intermediate was involved in this transformation. The intermediate was isolated and subsequently identified as bornyl pyrophosphate by direct chromatographic analysis and by the preparation of derivatives and chromatographic analysis of both the hydrogenolysis (LiAlH₄) and enzymatic hydrolysis products of bornyl pyrophosphate. The results presented indicate that borneol is derived by cyclization of neryl pyrophosphate to bornyl pyrophosphate, followed by hydrolysis. This is the first demonstration of a cyclic pyrophosphorylated intermediate in the biosynthesis of bicyclic monoterpenes.     

Mechanism of the pyrophosphate migration in the enzymatic cyclization of geranyl and linalyl pyrophosphates to (+)- and (-)-bornyl pyrophosphates

Soluble enzymes from sage (Salvia officinalis) and tansy (Tanacetum vulgare), which catalyze the cyclization of geranyl pyrophosphate and the presumptive intermediate linalyl pyrophosphate to the (+) and (-) enantiomers, respectively, of 2-bornyl pyrophosphate, were employed to evaluate mechanistic alternatives for the pyrophosphate migration in monoterpene cyclization reactions. Separate incubation of [1-3H2,alpha-32P]- and [1-3H2,beta- 32P]geranyl and (+/-)-linalyl pyrophosphates with partially purified preparations of each enantiomer-generating cyclase gave [3H, 32P]bornyl pyrophosphates, which were selectively hydrolyzed to the corresponding bornyl phosphates. Measurement of 3H:32P ratios of these monophosphate esters established that two ends of the pyrophosphate moiety retained their identifies in the cyclization of both precursors to both products and also indicated that there was no appreciable exchange with exogenous inorganic pyrophosphate in the reaction. Subsequent incubations of each cyclase with [8,9-14C,1-18O]geranyl pyrophosphate and with (1E)-(+/-)-[1-3H,3-18O]linalyl pyrophosphate gave the appropriate (+)- or (-)-bornyl pyrophosphates, which were hydrolyzed in situ to the corresponding borneols. Analysis of the derived benzoates by mass spectrometry demonstrated each of the product borneols to possess an 18O enrichment essentially identical with that of the respective acyclic precursor. The absence of P alpha-P beta interchange and the complete lack of positional 18O isotope exchange of the pyrophosphate moiety are compatible with tight ion pairing of intermediates in the coupled isomerization-cyclization of geranyl pyrophosphate and establish a remarkably tight restriction on the motion of the transiently generated pyrophosphate anion with respect to its cationic terpenyl reaction partner.     

Biosynthesis of monoterpenes: Preliminary characterization of l-endo-fenchol synthetase from fennel (Foeniculum vulgare) and evidence that no free intermediate is involved in the cyclization of geranyl pyrophosphate to the rearranged product

A soluble enzyme preparation from the leaves of fennel (Foeniculum vulgare M.) has been shown to catalyze the cation-dependent cyclization of both geranyl pyrophosphate and neryl pyrophosphate to the bicyclic rearranged monoterpene l-endo-fenchol (R. Croteau, M. Felton, and R. Ronald, 1980 Arch. Biochem. Biophys.200, 524–533). To examine the possible presence of free intermediates between the acyclic precursors and fenchol, and to remove competing cyclase and pyrophosphatase activities, the soluble preparation was partially purified by ammonium sulfate fractionation followed by gel filtration on Sephadex G-150 and ion exchange chromatography on O-diethylaminoethyl-cellulose. Activities for the cyclization of geranyl pyrophosphate and neryl pyrophosphate to fenchol were coincident on Chromatographic fractionation suggesting that the same enzyme was capable of cyclizing both acyclic substrates. No interconversion of the acyclic precursors was detected. Although bornyl pyrophosphate is a free intermediate in the biosynthesis of the related bicyclic monoterpenol borneol, both protein fractionation and isotopic dilution experiments ruled out endo-fenchyl pyrophosphate as a free intermediate in fenchol biosynthesis. Similarly, while construction of the fenchane skeleton was demonstrated to involve the rearrangement of an intermediate pinane skeleton, isotopic dilution experiments ruled out both optical antipodes of α-pinene, β-pinene, cis-2-pinanol, trans-2-pinanol, and the corresponding 2-pinyl pyrophosphates as free intermediates of the enzyme-catalyzed reaction. Furthermore, exhaustive search of the enzymatic reaction products provided no evidence to suggest the involvement of any free intermediate between the acyclic precursor and fenchol. The endo-fenchol synthetase has an apparent molecular weight of 60,000, shows a pH optimum near 7.0, and requires Mn²⁺ (1 mm) for catalytic activity. Co²⁺ can partially substitute for Mn²⁺, but other divalent cations are ineffective. The partially purified synthetase is inhibited by p-hydroxymercuribenzoate and by phenylglyoxal, and it exhibits a preference for geranyl pyrophosphate over neryl pyrophosphate as substrate. An integrated scheme is proposed for the cyclization and rearrangement catalyzed by fenchol synthetase.     

Pinene cyclases I and II. Two enzymes from sage (Salvia officinalis) which catalyze stereospecific cyclizations of geranyl pyrophosphate to monoterpene olefins of opposite configuration

A soluble enzyme preparation from immature sage (Salvia officinalis) leaves has been shown to catalyze the cation-dependent cyclization of geranyl pyrophosphate to the isomeric monoterpene olefins (+/-)-alpha-pinene and (-)-beta-pinene and to lesser amounts of camphene and limonene (Gambliel, H., and Croteau, R. (1982) J. Biol. Chem. 257, 2335-2342). This preparation was fractionated by gel filtration on Sephadex G-150 to afford two regions of enzymic activity termed geranyl pyrophosphate:pinene cyclase I (Mr approximately equal to 96,000), which catalyzed the conversion of geranyl pyrophosphate to the bicyclic olefin (+)-alpha-pinene, and to smaller quantities of the rearranged olefin (+)-camphene and the monocyclic olefin (+)-limonene, and geranyl pyrophosphate:pinene cyclase II (Mr approximately equal to 55,000), which transformed the acyclic precursor to (-)-alpha-pinene and (-)-beta-pinene, as well as to (-)-camphene, (-)-limonene, and the acyclic olefin myrcene. The multiple olefin biosynthetic activities co-purified with pinene cyclase I on four subsequent chromatographic and electrophoretic steps, and the ability to cyclize geranyl pyrophosphate and the related allylic pyrophosphates neryl pyrophosphate and linalyl pyrophosphate was likewise coincident throughout purification. Fractionation of pinene cyclase II by an identical sequence showed that the activities for the synthesis of the stereochemically related (-)-olefins co-purified, as did the ability to utilize the three acyclic precursors. The general properties of cyclase I and cyclase II were determined, and a scheme for the biosynthesis of the pinenes and related monoterpene olefins was proposed.     

Study of lipase-catalyzed hydrolysis of some monoterpene esters

Studies of the hydrolysis of bornyl, citronellyl, geranyl, and terpenyl acetates by commercially available lipases of Candida rugosa, Rhizopus arrhizus, and Mucor miehei are presented. The hydrolysis of these monoterpene esters is investigated at various temperatures and pHs, and the time dependence of the percentage of esters hydrolysed is studied. The catalytic activities of the lipases in hydrolysing the esters are compared and, overall, it is observed that under the experimental conditions used the nonspecific lipase from C. rugosa produces the highest yields of the monoterpene alcohols in comparison to the primary-ester specific lipases such as R. arrhizus and M. miehei. A rate kinetic model has been used to understand the time dependence of the yield of the product acid.     

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.     

Monoterpene formation by leucoplasts of Citrofortunella mitis and Citrus unshiu

Leucoplasts of immature calamondin and satsuma fruits were incubated with [1-¹⁴C] isopentenyl pyrophosphate under various conditions. Optimal incorporation of the tracer into geranyl pyrophosphate and monoterpene hydrocarbons occurred in the presence of exogenous dimethylallyl pyrophosphate and Mn²⁺ which was more effective than Mg²⁺. The dependence of dimethylallyl pyrophosphate showed that about 10 moles were required for 1 mole of isopentenyl pyrophosphate for the best recovery in monoterpene hydrocarbon biosynthesis. A time-course incorporation of isopentenyl pyrophosphate revealed that the C₁₀ hydrocarbon elaboration was dependent on the geranyl pyrophosphate production and at no time neryl pyrophosphate was synthesized by leucoplasts. The amount of labelled farnesyl pyrophosphate was rather low whatever the conditions used in the experiments and sesquiterpene hydrocarbon biosynthesis was never observed.Abbreviations DMAPP dimethylallyl pyrophosphate - FPP farnesyl pyrophosphate - GPP geranyl pyrophosphate - IPP isopentenyl pyrophosphate - LPP linalyl pyrophosphate - NPP neryl pyrophosphate     

Monoterpene biosynthesis: demonstration of a geranyl pyrophosphate:sabinene hydrate cyclase in soluble enzyme preparations from sweet marjoram (Majorana hortensis)

A soluble enzyme preparation from the leaves of sweet marjoram (Majorana hortensis Moench) catalyzes the divalent cation-dependent cyclization of [1-3H]geranyl pyrophosphate to the bicyclic monoterpene alcohols (+)-[6-3H]cis- and (+)-[6-3H]-transsabinene hydrate, providing labeling patterns consistent with current mechanistic considerations. No free intermediates were detectable in the conversion of geranyl pyrophosphate to the sabinene hydrates as determined by isotopic dilution experiments. Label from H2(18)O water was quantitatively incorporated into the products, indicating that the hydroxyl oxygen atoms of both cis- and trans-sabinene hydrate are derived from water and not from the pyrophosphate ester moiety of the substrate. The two enzymatic activities were inseparable by several chromatographic procedures, and differential inactivation studies suggested that the two activities reside with the same enzyme. The sabinene hydrate cyclase (synthase) has an apparent molecular weight of 56,000, shows a pH optimum near 7.0, and requires a divalent metal ion (either Mn2+ or Mg2+) for activity. The enzyme preparation is also capable of cyclizing neryl pyrophosphate, the cis-isomer of geranyl pyrophosphate, and analysis of mixed substrate incubations indicated that the two precursors are mutually competitive. Kinetic analysis and comparison of Vrel/Km values revealed that geranyl pyrophosphate is the more efficient substrate. This is the first report on an enzyme preparation capable of cyclizing geranyl pyrophosphate and neryl pyrophosphate to the isomeric sabinene hydrates.     

Biosynthesis of monoterpenes. Stereochemical implications of acyclic and monocyclic olefin formation by (+)- and (-)-pinene cyclases from sage

(+)-Pinene cyclase from sage (Salvia officinalis) catalyzes the isomerization and cyclization of geranyl pyrophosphate to (+)-alpha-pinene and (+)-camphene, and to lesser amounts of (+)-limonene, myrcene, and terpinolene, whereas (-)-pinene cyclase from this tissue catalyzes the conversion of the acyclic precursor to (-)-alpha-pinene, (-)-beta-pinene, and (-)-camphene, and to lesser quantities of (-)-limonene, myrcene, and terpinolene. The bicyclic products of these enzymes (pinene and camphene) are derived via the cyclization of the cisoid, anti-endo-conformers of the bound, tertiary allylic intermediates (3R)-linalyl pyrophosphate [+)-pinene cyclase) and (3S)-linalyl pyrophosphate [-)-pinene cyclase). When challenged with either enantiomer of linalyl pyrophosphate or with neryl pyrophosphate (cis-isomer of geranyl pyrophosphate) as substrate, both pinene cyclases synthesize disproportionately high levels of acyclic olefins (myrcene and ocimene) and monocyclic olefins (limonene and terpinolene), compared with the product mixtures generated from the natural geranyl precursor. Resolution of the limonene derived from linalyl pyrophosphate and neryl pyrophosphate demonstrated that this monocyclic olefin was formed via conformational foldings in addition to the cisoid,anti-endo-pattern. These results indicate that the alternate substrates are ionized by the cyclases prior to their achieving the optimum orientation for bicyclization. In the case of geranyl pyrophosphate, a preassociation mechanism is suggested in which optimum folding of the terpenyl chain precedes the initial ionization step.     

Substrate and metal specificity in the enzymic synthesis of cyclic monoterpenes from geranyl and neryl pyrophosphate

A partially purified enzyme (carbocyclase) from the flavedo of Citrus limonum formed α-pinene, β-pinene, limonene, and γ-terpinene from geranyl pyrophosphate (GPP) and neryl pyrophosphate. The maximum specific activities obtained were 7.0 and 3.6 nmol/ min/mg, respectively. Cross-inhibition by the two substrates were observed and the ability to utilize neryl pyrophosphate was almost completely lost with aging. Citronellyl pyrophosphate and dimethylallyl pyrophosphate were the most effective inhibitors of carbocyclase. Isopentenyl pyrophosphate, the monophosphate esters of nerol and geraniol, as well as inorganic pyrophosphate were much less effective inhibitors. The enzyme had an absolute requirement for Mn²⁺. It could be replaced with about 2% effectiveness by Mg²⁺ and Co²⁺. Kinetic studies showed that the observed reaction rate correlates with the calculated concentration of the GPP (Mn²⁺)₂ species. Previous evidence with nonenzymatic reactions and the results presented support the view that the mechanism of carbocyclase may be the intramolecular analog of prenyltransferase.     

Stereochemistry at C-1 of geranyl pyrophosphate and neryl pyrophosphate in the cyclization to (+)- and (-)-bornyl pyrophosphate

(1R)-1-3H-labeled and (1S)-1-3H-labeled geranyl pyrophosphate and neryl pyrophosphate were prepared from the corresponding 1-3H-labeled aldehydes by a combination of enzymatic and synthetic procedures. Following admixture with the corresponding 2-14C-labeled internal standard, each substrate was converted to (+)-bornyl pyrophosphate and (-)-bornyl pyrophosphate by cell-free enzyme preparations from sage (Salvia officinalis) and tansy (Tanacetum vulgare), respectively. Each pyrophosphate ester was hydrolyzed, and the resulting borneol was oxidized to camphor. The stereochemistry of labeling at C-3 of the derived ketone was determined by base-catalyzed exchange, taking advantage of the known selective exchange of the exo-alpha-protons. By comparison of such exchange rates to those of product generated from (1RS)-2-14C,1-3H2-labeled substrate, it was demonstrated that geranyl pyrophosphate was cyclized to bornyl pyrophosphate with net retention of configuration at C-1 of the acyclic precursor, whereas neryl pyrophosphate was cyclized to product with inversion of configuration at C-1. The observed stereochemistry is consistent with a reaction mechanism whereby geranyl pyrophosphate is first stereospecifically isomerized to linalyl pyrophosphate which, following rotation about C-2-C-3 to the cisoid conformer, cyclizes from the anti-endo configuration. Neryl pyrophosphate cyclizes either directly or via the linalyl intermediate without the attendant rotation.     

Geranyl pyrophosphate synthase: characterization of the enzyme and evidence that this chain-length specific prenyltransferase is associated with monoterpene biosynthesis in sage (Salvia officinalis)

Cell-free homogenates from sage (Salvia officinalis) leaves convert dimethylallyl pyrophosphate and isopentenyl pyrophosphate to a mixture of geranyl pyrophosphate, farnesyl pyrophosphate, and geranylgeranyl pyrophosphate, with farnesyl pyrophosphate predominating. These prenyltransferase activities were localized primarily in the soluble enzyme fraction, and separation of this preparation on Sephadex G-150 revealed the presence of a partially resolved, labile geranyl pyrophosphate synthase activity. The product of the condensation reaction between [1-14C]dimethylallyl pyrophosphate and [1-3H]isopentenyl pyrophosphate was verified as [14C,1-3H]geranyl pyrophosphate by TLC isolation, enzymatic hydrolysis to geraniol, degradative studies, and the preparation of the crystalline diphenylurethane. The cis-isomer, neryl pyrophosphate, was not a product of the enzymatic reaction. By employing a selective tissue extraction procedure, the geranyl pyrophosphate synthase activity was localized in the leaf epidermal glands, the site of monoterpene biosynthesis, suggesting that the role of this enzyme is to supply the C10 precursor for the production of monoterpenes. Glandular extracts enriched in geranyl pyrophosphate synthase were partially purified by a combination of hydrophobic interaction chromatography on phenyl-Sepharose and gel permeation chromatography on Sephadex G-150. Substrate and product specificity studies confirmed the selective synthesis of geranyl pyrophosphate by this enzyme, which was also characterized with respect to molecular weight, pH optimum, cation requirement, inhibitors, and kinetic parameters, and shown to resemble other prenyltransferases.     

Identification des constituants de l'essence des aiguilles de Pinus pinaster

The chromatographic analysis of the volatile leaf oil of Pinus pinaster Ait. showed 42% of monoterpene hydrocarbons (α-pinene, camphene, β-pinene, myrcene, 3-carene, limonene, cis-ocimene, terpinolene, para-cymene, 35% of sesquiterpene hydrocarbons (cubebene, copaene, caryophyllene, humulene, germacrene D, α- and γ-muurolenes, δ- and γ-cadinenes) and 23% of oxygenated compounds including esters (linalyl, bornyl, geranyl, neryl and farnesyl acetates), alcohols (cis-hexenol, linalool, α-fenchol, trans-pinocarveol, terpinen-4-ol, α-terpineol, dihydrocarveol, guaiol, junenol and α-cadinol), one aldehyde (hexenal) and one ketone (piperitone). Three non terpenoid phenylethyl esters were also identified: phenylethyl isovalerate, methyl-2 burtyate and 3-3 dimethylacrylate. Some alcohols and mainly α-terpineol and linalool seemed to be formed during the steam distillation process, they were absent when the leaf oil was obtained by maceration of small portions of leaves in the usual solvents of terpenes.     

Biosynthesis of monoterpene hydrocarbons from [1-3H]neryl pyrophosphate and [1-3H]geranyl pyrophosphate by soluble enzymes from Citrus limonum.

A soluble enzyme preparation from the flavedo of Citrus limonum transforms [1-³H₁]neryl pyrophosphate or [1-³H₁]geranyl pyrophosphate into β-pinene, sabinene, α-pinene, and limonene. The enzyme has been partially purified and stabilized by precipitation with polyethyleneglycol. The enzymic cyclization requires the presence of Mn²⁺, which cannot be replaced with Mg²⁺. The addition of reagents containing sulfhydryl groups is essential for optimal activity. Allylic C₁₀ monophosphates do not act as substrates, but they inhibit hydrocarbon formation. Inorganic pyrophosphate has a similar inhibitory effect. No interconversion of neryl and geranyl pyrophosphate has been observed. Possible pathways for the enzymic cyclization reactions are proposed.     

Enzymatic cyclization of neryl pyrophosphate to -terpineol by cell-free extracts from peppermint

A cell-free system prepared from peppermint ($\text{Mentha piperita}$ L.) shoot tips catalyzed the cyclization of neryl pyrophosphate to α-terpineol. Cyclization could be demonstrated in the absence of added cofactors, but addition of NaF inhibited competing phosphatase/pyrophosphatase activity, resulting in much higher levels of α-terpineol formation. Under certain conditions cyclization was stimulated by Mg⁺⁺. Similar enzyme preparations were obtained from spearmint ($\text{Mentha spicata}$ L.) leaves and carrot ($\text{Daucus carota}$ L.) storage organ. The cyclization of neryl pyrophosphate to α-terpineol appears to be a key reaction in the biosynthesis of cyclohexanoid monoterpenes.     

Evidence for trans-trans and cis-cis farnesyl pyrophosphate synthesis in Gossipium hirsutum

A protein fraction capable of catalysing the formation of all four geometrical isomers of farnesyl pyrophosphate has been isolated from cotton roots. Using neryl pyrophosphate and isopentenyl pyrophosphate as substrates the product was found to be cis-cis farnesyl pyrophosphate and possibly trans-cis farnesyl pyrophosphate. Geranyl pyrophosphate and isopentenyl pyrophosphate as substrates yielded trans-trans and possible cis-trans farnesyl pyrophosphate. During purification of the active protein fraction, the ratio of utilization of geranyl pyrophosphate and neryl pyrophosphate did not remain constant, indicating that two enzymes may be involved, one specific for cis C₁₀-substrate and the other for trans C₁₀-substrate.     

Biosynthesis of monoterpenes. Enantioselectivity in the enzymatic cyclization of (+)- and (-)-linalyl pyrophosphate to (+)- and (-)-bornyl pyrophosphate

Enzymes from Salvia officinalis and Tanacetum vulgare leaf epidermis catalyze the conversion of the acyclic precursor geranyl pyrophosphate to the cyclic monoterpenes (+)- and (-)-bornyl pyrophosphate, respectively. The antipodal cyclizations are considered to proceed by the initial isomerization of the substrate to the respective bound tertiary allylic intermediates (-)-(3R)- and (+)-(3S)-linalyl pyrophosphate. [(3R)-8,9-14C,(3RS)-1E-3H] Linalyl pyrophosphate (3H:14C = 5.22) was tested as a substrate with the cyclases from both sources to determine the configuration of the cyclizing intermediate. This substrate yielded (-)-bornyl pyrophosphate with 3H:14C ratio greater than 31, indicating specific utilization of (+)-(3S)-linalyl pyrophosphate as predicted. With the (+)-bornyl pyrophosphate cyclase, the 3H:14C ratio of the product was about 4.16, indicating a preference for the (-)-(3R)-enantiomer, but the ability also to utilize (+)-(3S)-linalyl pyrophosphate. (3R)- and (3S)-[1Z-3H]Linalyl pyrophosphate were separately compared to the achiral precursors [1-3H] geranyl pyrophosphate and [1-3H]neryl pyrophosphate (cis-isomer) as substrates for the cyclizations. All functional precursors afforded optically pure (-)-(1S,4S)-bornyl pyrophosphate with the T. vulgare-derived cyclase (as determined by chromatographic separation of diastereomeric ketals of the derived ketone camphor), and (+)-(3S)-linalyl pyrophosphate was the preferred substrate. With the (+)-bornyl pyrophosphate cyclase from S. officinalis, geranyl, neryl, and (-)-(3R)-linalyl pyrophosphates gave the expected (+)-(1R,4R)-stereoisomer as the sole product, and (-)-(3R)-linalyl pyrophosphate was the preferred substrate. However, (3S)-linalyl pyrophosphate yielded (-)-(1S,4S)-bornyl pyrophosphate, albeit at lower rates, indicating the ability of this enzyme to catalyze the anomalous enantiomeric cyclization.     

Biosynthesis of monoterpenes. Enantioselectivity in the enzymatic cyclization of (+)- and (-)-linalyl pyrophosphate to (+)- and (-)-pinene and (+)- and (-)-camphene

Cyclase I from Salvia officinalis leaf catalyzes the conversion of geranyl pyrophosphate to the stereo-chemically related bicyclic monoterpenes (+)-alpha-pinene and (+)-camphene and to lesser quantities of monocyclic and acyclic olefins, whereas cyclase II from this plant tissue converts the same acyclic precursor to (-)-alpha-pinene, (-)-beta-pinene and (-)-camphene as well as to lesser amounts of monocyclics and acyclics. These antipodal cyclizations are considered to proceed by the initial isomerization of the substrate to the respective bound tertiary allylic intermediates (-)-(3R)- and (+)-(3S)-linalyl pyrophosphate. [(3R)-8,9-14C,(3RS)-1E-3H]Linalyl pyrophosphate (3H:14C = 5.14) was tested as a substrate with both cyclases to determine the configuration of the cyclizing intermediate. This substrate with cyclase I yielded alpha-pinene and camphene with 3H:14C ratios of 3.1 and 4.2, respectively, indicating preferential, but not exclusive, utilization of the (3R)-enantiomer. With cyclase II, the doubly labeled substrate gave bicyclic olefins with 3H:14C ratios of from 13 to 20, indicating preferential, but not exclusive, utilization of the (3S)-enantiomer in this case. (3R)- and (3S)-[1Z-3H]linalyl pyrophosphate were separately compared to the achiral precursors [1-3H]geranyl pyrophosphate and [1-3H]neryl pyrophosphate (cis-isomer) as substrates for the cyclizations. With cyclase I, geranyl, neryl, and (3R)-linalyl pyrophosphate gave rise exclusively to (+)-alpha-pinene and (+)-camphene, whereas (3S)-linayl pyrophosphate produced, at relatively low rates, the (-)-isomers. With cyclase II, geranyl, neryl, and (3S)-linalyl pyrophosphate yielded exclusively the (-)-isomer series, whereas (3R)-linalyl pyrophosphate afforded the (+)-isomers at low rates. These results are entirely consistent with the predicted stereochemistries and additionally revealed the unusual ability of these enzymes to catalyze antipodal cyclizations when presented with the unnatural linalyl enantiomer.     

Lactobacillus plantarum undecaprenyl pyrophosphate synthetase: purification and reaction requirements.

Undecaprenyl pyrophosphate synthetase was partially purified from Lactobacillus plantarum by DEAE-cellulose, hydroxyapatite, and Sephadex G-100 chromatography in Triton X-100. The enzyme has a molecular weight between 53,000 and 60,000. The enzyme demonstrated a fivefold preference for farnesyl pyrophosphate rather than geranyl pyrophosphate as the allylic cosubstrate, whereas dimethylallyl pyrophosphate was not effective as a substrate. Polyprenyl pyrophosphates obtained using either farnesyl or geranyl pyrophosphate as cosubstrate were chromatographically identical. Hydrolysis of these polyprenyl pyrophosphates with either a yeast or liver phosphatase preparation yielded undecaprenol as the major product. Incorporation of radioactive label from mixtures of Δ³-[1-¹⁴C]isopentenyl pyrophosphate and Δ³-2R-[2-³H]isopentenyl pyrophosphate into enzymic product indicated that each isoprene unit added to the allylic pyrophosphate substrate has a cis configuration about the newly formed double bond. The removal of detergent from enzyme solutions resulted in a parallel loss in enzyme activity when analyzed with either farnesyl or geranyl pyrophosphate as cosubstrates. Enzymic activity was restored on addition of Triton X-100 or deoxycholate. The enzyme exhibited a pH-activity profile with optima at pH 7.5 and 10.2. It also demonstrated a divalent cation requirement, with Mg²⁺, Mn²⁺, Zn²⁺, and Co²⁺ exhibiting comparable activities.