Partial purification and characterization of two sesquiterpene cyclases from sage (Salvia officinalis) which catalyze the respective conversion of farnesyl pyrophosphate to humulene and caryophyllene

Humulene cyclase and caryophyllene cyclase, two enzymes which catalyze the cyclization of farnesyl pyrophosphate to the respective sesquiterpene olefins, have been partially purified from the supernatant fraction of a sage (Salvia officinalis) leaf epidermis extract and separated from each other by a combination of hydrophobic interaction, gel filtration, and ion-exchange chromatography. The molecular weight of both cyclases was estimated by gel filtration to be 57,000 and both cyclases exhibited a pH optimum of 6.5 and preferred Mg2+ (Km approximately 1.5 mM) as the required divalent metal cation. Both enzymes possessed a Km of about 1.7 microM for farnesyl pyrophosphate, were strongly inhibited by p-hydroxymercuribenzoate, and exhibited comparable sensitivities to a variety of other potential inhibitors. The properties of the two sesquiterpene olefin cyclases, which are the first from a higher plant source to be examined in detail, were very similar to each other and to other monoterpene, sesquiterpene, and diterpene cyclases previously described.     

Biosynthesis of the sesquiterpene patchoulol from farnesyl pyrophosphate in leaf extracts of Pogostemon cablin (patchouli): mechanistic considerations

Several mechanistic alternatives have been proposed for the enzyme-catalyzed, electrophilic cyclization of farnesyl pyrophosphate to the tricyclic sesquiterpene alcohol patchoulol, which is the characteristic component of the essential oil of Pogostemon cablin (patchouli). These alternatives include schemes involving deprotonation-reprotonation steps and the intermediacy of the monocyclic and bicyclic olefins germacrene and bulnesene, respectively, and involving a 1,3-hydride shift with only tertiary cationic intermediates and without any deprotonation-reprotonation steps. Analytical studies, based on analyses of P. cablin leaf oil at different stages of plant development, and in vivo time-course investigations, using 14CO2 and [14C]sucrose, gave no indication that germacrene and bulnesene were intermediates in patchoulol biosynthesis. A soluble enzyme system from P. cablin leaves was prepared, which was capable of converting farnesyl pyrophosphate to patchoulol, and isotopic dilution experiments with both labeled and unlabeled olefins were carried out with this system to confirm that sesquiterpene olefins did not participate as fre intermediates in the transformation of the acyclic precursor to patchoulol. Patchoulol derived biosynthetically from [12,13-14C;1-3H]farnesyl pyrophosphate was chemically degraded to establish the overall construction pattern of the product. Similar studies with [12,13-14C;6-3H]farnesyl pyrophosphate as a precursor eliminated deprotonation steps to form bound olefinic intermediates in the biosynthesis of patchoulol, while providing supporting evidence for the hydride shift mechanism.     

Purification and characterization of the sesquiterpene cyclase patchoulol synthase from Pogostemon cablin

The sesquiterpene cyclase, patchoulol synthase, from Pogostemon cablin (patchouli) leaves was purified to apparent homogeneity by chromatofocusing, anion exchange, gel permeation, and hydroxylapatite chromatography. The enzyme showed a maximum specific activity of about 20 nmol/min/mg protein, and a native molecular weight of 80,000 as determined by gel permeation chromatography. The protein was very hydrophobic, as judged by chromatographic behavior on several matrices, and possessed a pI value of about 5.0, as determined by isoelectric and chromatofocusing. SDS-PAGE showed the enzyme to be composed of two apparently identical subunits of Mr approximately 40,000. Maximum activity was observed at pH 6.7 in the presence of Mg2+ (Km approximately 1.7 mM); other divalent metal ions were ineffective in promoting catalysis. The Km value for the substrate, farnesyl pyrophosphate, was 6.8 microM. Patchoulol synthase copurified with the ability to transform farnesyl pyrophosphate to cyclic olefins (alpha- and beta-patchoulene, alpha-bulnesene, and alpha-guiaene) and this observation, plus evidence based on differential inhibition and inactivation studies, suggested that these structurally related products are synthesized by the same cyclase enzyme. In general properties, the patchoulol synthase from patchouli leaves resembles fungal sesquiterpene olefin cyclases except for the ability to synthesize multiple products, a property more typical of monoterpene cyclases of higher plant origin.     

Terpene biosynthesis in glandular trichomes of hop

Hop (Humulus lupulus L. Cannabaceae) is an economically important crop for the brewing industry, where it is used to impart flavor and aroma to beer, and has also drawn attention in recent years due to its potential pharmaceutical applications. Essential oils (mono- and sesquiterpenes), bitter acids (prenylated polyketides), and prenylflavonoids are the primary phytochemical components that account for these traits, and all accumulate at high concentrations in glandular trichomes of hop cones. To understand the molecular basis for terpene accumulation in hop trichomes, a trichome cDNA library was constructed and 9,816 cleansed expressed sequence tag (EST) sequences were obtained from random sequencing of 16,152 cDNA clones. The ESTs were assembled into 3,619 unigenes (1,101 contigs and 2,518 singletons). Putative functions were assigned to the unigenes based on their homology to annotated sequences in the GenBank database. Two mono- and two sesquiterpene synthases identified from the EST collection were expressed in Escherichia coli. Hop MONOTERPENE SYNTHASE2 formed the linear monterpene myrcene from geranyl pyrophosphate, whereas hop SESQUITERPENE SYNTHASE1 (HlSTS1) formed both caryophyllene and humulene from farnesyl pyrophosphate. Together, these enzymes account for the production of the major terpene constituents of the hop trichomes. HlSTS2 formed the minor sesquiterpene constituent germacrene A, which was converted to β-elemene on chromatography at elevated temperature. We discuss potential functions for other genes expressed at high levels in developing hop trichomes.     

Amorpha-4,11-diene synthase of Artemisia annua: cDNA isolation and bacterial expression of a terpene synthase involved in artemisinin biosynthesis

Artemisia annua, an indigenous plant to Korea, contains an antimalarial sesquiterpene, artemisinin. The first committed step of artemisinin biosynthesis is the cyclization of farnesyl diphosphate by a sesquiterpene synthase to produce an amorphane-type ring system. The aims of this research were to molecularly clone and express amorpha-4,11-diene synthase for metabolic engineering. PCR amplification of genomic DNA with a pair of primers, designed from the conserved regions of sesquiterpene synthases of several plants, produced a 184-bp DNA fragment. This fragment was used in Northern blot analysis as a probe, showing approximately 2.2 kb of a single band. Its sequence information was used to produce 2106 bp of a full-length cDNA sequence including 1641 bp of open reading frame for 546 amino acids (kcs12) through a rapid amplification of cDNA ends (RACE). The deduced amino acid sequence displayed 36% identity with 5-epi-aristolochene synthase of Nicotiana tabacum. A soluble fraction of Escherichia coli harboring kcs12 catalyzed the cyclization of farnesyl diphosphate to produce a sesquiterpene, which was identified through GC-MS analysis as amorpha-4,11-diene.     

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.     

Substrate specificity of α‐humulene synthase from Zingiber zerumbet Smith and determination of kinetic constants by a spectrophotometric assay

Terpene synthases are the key enzymes in terpene biosynthesis that provide a structurally complex and highly diverse product spectrum. A suitable and reliable analytical assay is indispensable to measure terpene synthase activity accurately and precisely. In this study, a malachite green assay (MG) was adapted to rapidly assay terpene synthase activity and was validated in comparison to an already established gas chromatography assay. A linear correlation between both assays was observed. Kinetic properties for the previously described sesquiterpene synthase α‐humulene synthase (HUM) from Zingiber zerumbet Smith were investigated for the bioconversion of the monoterpene precursors geranyl pyrophosphate (2E‐GPP) and neryl pyrophosphate (2Z‐NPP) as well as for the sesquiterpene precursor farnesyl pyrophosphate (2E,6E‐FPP). Also, gas chromatography mass spectrometry (GS‐MS) was carried out to identify the products of the bioconversion of (2E)‐GPP and (2Z)‐NPP.     

Molecular regulation of santalol biosynthesis in Santalum album L.

Santalum album L. commonly known as East-Indian sandal or chandan is a hemiparasitic tree of family santalaceae. Santalol is a bioprospecting molecule present in sandalwood and any effort towards metabolic engineering of this important moiety would require knowledge on gene regulation. Santalol is a sesquiterpene synthesized through mevalonate or non-mevalonate pathways. First step of santalol biosynthesis involves head to tail condensation of isopentenyl pyrophosphate (IPP) with its allylic co-substrate dimethyl allyl pyrophosphate (DMAPP) to produce geranyl pyrophosphate (GPP; C10 — a monoterpene). GPP upon one additional condensation with IPP produces farnesyl pyrophosphate (FPP; C15 — an open chain sesquiterpene). Both the reactions are catalyzed by farnesyl diphosphate synthase (FDS). Santalene synthase (SS), a terpene cyclase catalyzes cyclization of open ring FPP into a mixture of cyclic sesquiterpenes such as α-santalene, epi-β-santalene, β-santalene and exo bergamotene, the main constituents of sandal oil. The objective of the present work was to generate a comprehensive knowledge on the genes involved in santalol production and study their molecular regulation. To achieve this, sequences encoding farnesyl diphosphate synthase and santalene synthase were isolated from sandalwood using suppression subtraction hybridization and 2D gel electrophoresis technology. Functional characterization of both the genes was done through enzyme assays and tissue-specific expression of both the genes was studied. To our knowledge, this is the first report on studies on molecular regulation, and tissue-specific expression of the genes involved in santalol biosynthesis.     

Cloning of a Sesquiterpene Cyclase and Its Functional Expression by Domain Swapping Strategy

Sesquiterpene cyclase, the first committed step enzyme from the general isoprenoid building block farnesyl pyrophosphate (FPP) for the synthesis of phytoalexin capsidiol, was isolated from the UV-C treated leaves of Capsicum annuum. This sesquiterpene cyclase, termed as CASC2 showing 77% amino acid identity with the previously cloned sesquiterpene cyclase CASC1, was composed of 560 amino acids with a calculated molecular mass of 64,907. The mRNA expression pattern of CASC2 was very similar to that of CASC1 during the time course of UV-C irradiated leaves of pepper on RNA blot analysis by using each specific probe. The heterologous expression in Escherichia coli using the CASC2 full length failed; however the chimeric construct of CASC2 in which the amino terminal 164 amino acid substituted by the equivalent portion of either CASC1 or tobacco sesquiterpene cyclase was capable of expressing the functional sesquiterpene cyclase activities. The radio-labeled enzymatic products catalyzed by the partially purified chimeric CASC2 were comigrated with authentic radio-labeled sesquiterpene on thin layer chromatography.     

Evidence for differential folding of farnesyl pyrophosphate in the active site of aristolochene synthase: a single-point mutation converts aristolochene synthase into an (E)-beta-farnesene synthase

Sesquiterpene cyclases, many of which share significant structural similarity, catalyze the cyclization reactions of the universal alicyclic precursor farnesyl pyrophosphate to produce more than 300 different hydrocarbon skeletons with high regio- and stereospecificity. The molecular basis of this exquisite specificity is not well-understood, but the conformation adopted by FPP in the active site of a sesquiterpene cyclase is thought to be an important determinant of the reaction pathway. Aristolochene synthase (AS) from Penicillium roqueforti catalyzes the cyclization of farnesyl pyrophosphate to the bicyclic sesquiterpene aristolochene. The X-ray structure of AS suggested that the steric bulk of residue 92 was central in binding of FPP to the active site of AS in a quasi-cyclic conformation, thereby facilitating attack of C1 by the C10-C11 double bond to produce the cis-fused Decalin S-germacrene A. We demonstrate here that reduction of the size of the side chain of residue 92 leads to the production of the alicyclic sesquiterpenes (E)-beta- and (E,E)-alpha-farnesene. The relative amounts of linear products formed depended linearly on the size of the residues at position 92. ASY92A, in which Tyr92 had been replaced with Ala, produced almost 80% of alicyclic sesquiterpenes, suggesting an energetic separation of less than 0.8 kcal/mol between the cyclic and noncyclic reaction pathways. A mechanism by which FPP binds to the mutant enzymes in an extended conformation is proposed to explain the altered selectivity. The mutants also produced small amounts of additional hydrocarbons with a molecular weight of 204, namely, alpha-selinene, beta-selinene, selina-4,11-diene, (E,Z)-alpha-farnesene, and beta-bisabolene. The production of (E)-beta-farnesene and beta-bisabolene suggested that the initial cyclization of FPP to germacrene A in AS proceeded in a stepwise fashion through farnesyl cation.     

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.     

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.     

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.     

Alteration of product formation by directed mutagenesis and truncation of the multiple-product sesquiterpene synthases delta-selinene synthase and gamma-humulene synthase

Two recombinant sesquiterpene synthases from grand fir, delta-selinene synthase and gamma-humulene synthase, each produce more than 30 sesquiterpene olefins from the acyclic precursor farnesyl diphosphate. These enzymes contain a pair of DDxxD motifs, on opposite lips of the presumptive active site, which are thought to be involved in substrate binding and could promote multiple orientations of the substrate alkyl chain from which multiple families of cyclic olefins could derive. Mutagenesis of the first aspartate of either DDxxD motif resulted in depressed k(cat), with lesser effect on K(m), for delta-selinene synthase and afforded a much simpler product spectrum composed largely of monocyclic olefins. Identical alterations in gamma-humulene synthase produced similar kinetic effects with a simplified product spectrum of mostly acyclic and monocyclic olefins. Although impaired in product diversity, none of the mutant synthases lost entirely the capacity to generate complex structures. These results confirm the catalytic significance of the DDxxD motifs and imply that they also influence permitted modes of cyclization. Deletion of an N-terminal arginine pair in delta-selinene synthase (an element potentially involved in substrate isomerization) altered kinetics without substantially altering product outcome. Finally, mutation of an active-site tyrosine residue thought to play a role in proton exchange had little influence; however, substitution of a nearby active site aspartate dramatically altered kinetics and product outcome.     

Sites of control of hepatic cholesterol biosynthesis

An inhibition in the conversion of mevalonate to cholesterol has been demonstrated in liver of cholesterol-fed rats by both in vitro and in vivo methods. Synthesis decreased to 30% of the control value after 1 week and 20% after 1 month on a 1% cholesterol diet. After a year, synthesis from mevalonate was almost completely inhibited. The rate of conversion of squalene to cholesterol was not consistently decreased but that of farnesyl pyrophosphate to cholesterol was decreased considerably. The rate of conversion of mevalonate to farnesyl pyrophosphate by a soluble liver enzyme preparation was also decreased in cholesterol-fed animals. Sites of inhibition of cholesterol synthesis were detected before mevalonate, between mevalonate and farnesyl pyrophosphate, and after farnesyl pyrophosphate, probably at the conversion of farnesyl pyrophosphate to squalene. The inhibition of mevalonate conversion to cholesterol developed more slowly than that of acetate and appeared to be secondary to it. The maximum capacities of normal liver homogenates and slices to synthesize cholesterol from mevalonate were shown to be far greater than from acetate. Consequently, sites of inhibition after mevalonate probably do not have a significant effect on the over-all rate of cholesterol synthesis in the intact cholesterol-fed animal.     

Pentalenene biosynthesis and the enzymatic cyclization of farnesyl pyrophosphate: Proof that the cyclization is catalyzed by a single enzyme

A cell-free preparation from Streptomyces UC5319 has been developed which catalyzes the conversion of trans, trans-farnesyl pyrophosphate (1) to pentalenene (2), the parent hydrocarbon of the pentalenolactone family of sesquiterpene antibiotics. Incubation of [9-³H₂, 12,13-¹⁴C]farnesyl pyrophosphate with the pentalenene synthetase gave [1,8-³H₂, 14,15-¹⁴C]pentalenene, as established by a combination of chemical and microbial degradation methods. The retention of both equivalents of tritium in the enzymatically derived pentalenene establishes that the cyclization of trans, trans-farnesyl pyrophosphate to 2 is catalyzed by a single enzyme.     

Casearia sylvestris Essential Oil Degradation Products Generated by Leaf Processing

Casearia sylvestris is an endemic tree of the Latin America that the essential oil (EO) has anti-inflammatory and gastroprotective actions. This study evaluates the chemical composition of the EO from the volatile fractions of in natura, fresh, and dried C. sylvestris var. sylvestris and var. lingua leaves. For both varieties, the dried leaves presented higher EO yield as compared to fresh leaves. The major EO chemical components were (E)-caryophyllene, α-humulene, germacrene D, bicyclogermacrene, spathulenol, caryophyllene oxide, and humulene epoxide II. In both varieties, the content of sesquiterpene hydrocarbons decreased and oxygenated sesquiterpenes increased on going from in natura to fresh and dried leaves, which indicated that leaf drying and hydrodistillation modified the volatile composition. The results also suggested that bicyclogermacrene and (E)-caryophyllene were oxidized during processing, to generate spathulenol and caryophyllene oxide, respectively. C. sylvestris varieties and in natura, fresh, and dried leaves differed in terms of the chemical composition of volatiles, which could affect the EO biological activities.     

Myrothecium roridum Tri4 encodes a multifunctional oxygenase required for three oxygenation steps

The biosyntheses of both macrocyclic trichothecenes in Myrothecium roridum and simple trichothecenes in Fusarium species begin with the cyclization of farnesyl pyrophosphate to form the sesquiterpene hydrocarbon trichodiene. A previous study showed that Myrothecium has a cluster of 3 genes that are homologous with Fusarium trichothecene genes: Tri4, a P450 oxygenase; Tri5, the sesquiterpene cyclase; and Tri6, a zinc-finger regulatory gene. Fusarium graminearum Tri4 (FgTri4) and M. roridum MrTri4 (MrTri4) have 66.9% identity. In this study, MrTri4 was expressed in Fusarium verticillioides. Liquid cultures of transformant strains expressing MrTri4 converted exogenous trichodiene to isotrichodiol, indicating that MrTri4 controls 3 oxygenation steps and that the product of MrTRI4 is isotrichodiol.     

Exploring biosynthetic diversity with trichodiene synthase

Trichodiene synthase is a terpenoid cyclase that catalyzes the cyclization of farnesyl diphosphate (FPP) to form the bicyclic sesquiterpene hydrocarbon trichodiene (89%), at least five sesquiterpene side products (11%), and inorganic pyrophosphate (PP(i)). Incubation of trichodiene synthase with 2-fluorofarnesyl diphosphate or 4-methylfarnesyl diphosphate similarly yields sesquiterpene mixtures despite the electronic effects or steric bulk introduced by substrate derivatization. The versatility of the enzyme is also demonstrated in the 2.85A resolution X-ray crystal structure of the complex with Mg(2+) (3)-PP(i) and the benzyl triethylammonium cation, which is a bulkier mimic of the bisabolyl carbocation intermediate in catalysis. Taken together, these findings show that the active site of trichodiene synthase is sufficiently flexible to accommodate bulkier and electronically-diverse substrates and intermediates, which could indicate additional potential for the biosynthetic utility of this terpenoid cyclase.