Metabolism of monoterpenes: demonstration that (+)-cis-isopulegone, not piperitenone, is the key intermediate in the conversion of (-)-isopiperitenone to (+)-pulegone in peppermint (Mentha piperita)

Piperitenone is commonly considered to be the key intermediate in the conversion of (-)-isopiperitenone to (+)-pulegone in peppermint; however, [3H]piperitenone gave rise only to the inert metabolite (+)-piperitone when incubated with peppermint leaf discs. Under identical conditions, (-)-[3H]isopiperitenone was efficiently incorporated into (+)-pulegone, (-)-menthone, and (+)-isomenthone in leaf discs, and yielded an additional metabolite identified as (+)-cis-isopulegone; piperitenone was poorly labeled. Moreover, (+)-cis-[3H]isopulegone was rapidly converted to (+)-pulegone, (-)-menthone, and (+)-isomenthone in leaf discs, and the reduction of (+)-[3H]pulegone to (-)-menthone and (+)-isomenthone was similarly documented. Each step of the pathway was demonstrated in a crude soluble preparation from peppermint leaf epidermis and each of the relevant enzymes was partially purified in order to compare relative rates of catalysis. The results of these studies indicate that the endocyclic double bond of (-)-isopiperitenone is reduced to yield (+)-cis-isopulegone, which is isomerized to (+)-pulegone as the immediate precursor of (-)-menthone and (+)-isomenthone, and they rule out piperitenone as an intermediate of the pathway.     

Metabolism of Monoterpenes : EVIDENCE FOR COMPARTMENTATION OF l-MENTHONE METABOLISM IN PEPPERMINT (MENTHA PIPERITA) LEAVES

Previous studies have shown that the monoterpene ketone l-[G-(3)H]-menthone is reduced to the epimeric alcohols l-menthol and d-neomenthol in leaf discs of flowering peppermint (Mentha piperita L.), and that a portion of the menthol is converted to menthyl acetate while the bulk of the neomenthol is transformed to neomenthyl-beta-d-glucoside (Croteau, Martinkus 1979 Plant Physiol 64: 169-175). The metabolic disposition of the epimeric reduction products of the ketone, which is a major constituent of peppermint oil, is highly specific, in that little neomenthyl acetate and little menthyl glucoside are formed. However, when l-[3-(3)H]menthol and d-[3-(3)H]neomenthol are separately administered to leaf discs, both menthyl and neomenthyl acetates and menthyl and neomenthyl glucosides are formed with nearly equal facility, suggesting that the metabolic specificity observed with the ketone precursor was not a function of the specificity of the transglucosylase or transacetylase but rather a result of compartmentation of each stereospecific dehydrogenase with the appropriate transferase. A UDP-glucose:monoterpenol glucosyltransferse, which utilized d-neomenthol or l-menthol as glucose acceptor, was demonstrated in the 105,000g supernatant of a peppermint leaf homogenate, and the enzyme was partially purified and characterized. Co-purification of the acceptor-mediated activities, and differential activation and inhibition studies, provided strong evidence that the same UDP-glucose-dependent enzyme could transfer glucose to either l-menthol or d-neomenthol. Determination of K(m) and V for the epimeric monoterpenols provided nearly identical values. The acetylcoenzyme A:monoterpenol acetyltransferase previously isolated from peppermint extracts (Croteau, Hooper 1978 Plant Physiol 61: 737-742) was re-examined using l-[3-(3)H]menthol and d-[3-(3)H]neomenthol as acetyl acceptors, and the K(m) and V for both epimers were, again, very similar. These results demonstrate that the specific in vivo conversion of l-menthone to l-menthyl acetate and d-neomenthyl-beta-d-glucoside cannot be attributed to the selectivity of the transferases, and they clearly indicate that the metabolic specificity observed is a result of compartmentation effects.     

Immunocytochemical localization of short-chain family reductases involved in menthol biosynthesis in peppermint

Biosynthesis of the p-menthane monoterpenes in peppermint occurs in the secretory cells of the peltate glandular trichomes and results in the accumulation of primarily menthone and menthol. cDNAs and recombinant enzymes are well characterized for eight of the nine enzymatic steps leading from the 5-carbon precursors to menthol, and subcellular localization of several key enzymes suggests a complex network of substrate and product movement is required during oil biosynthesis. In addition, studies concerning the regulation of oil biosynthesis have demonstrated a temporal partition of the pathway into an early, biosynthetic program that results in the accumulation of menthone and a later, oil maturation program that leads to menthone reduction and concomitant menthol accumulation. The menthone reductase responsible for the ultimate pathway reduction step, menthone-menthol reductase (MMR), has been characterized and found to share significant sequence similarity with its counterpart reductase, a menthone-neomenthol reductase, which catalyzes a minor enzymatic reaction associated with oil maturation. Further, the menthone reductases share significant sequence similarity with the temporally separate and mechanistically different isopiperitenone reductase (IPR). Here we present immunocytochemical localizations for these reductases using a polyclonal antibody raised against menthone-menthol reductase. The polyclonal antibody used for this study showed little specificity between these three reductases, but by using it for immunostaining of tissues of different ages we were able to provisionally separate staining of an early biosynthetic enzyme, IPR, found in young, immature leaves from that of the oil maturation enzyme, MMR, found in older, mature leaves. Both reductases were localized to the cytoplasm and nucleoplasm of the secretory cells of peltate glandular trichomes, and were absent from all other cell types examined.     

Evidence for metabolic turnover of monoterpenes in peppermint

Two types of experimental evidence are presented which suggest that the monoterpenes of peppermint (Mentha piperita L.) are subject to metabolic turnover. In kinetic studies with ¹⁴CO₂, peppermint cuttings rapidly incorporate label into the monoterpenes and then lose most of the label from the monoterpenes, without corresponding changes in the amount of monoterpenes present. When peppermint plants are grown in a controlled environment (16-hr photoperiod, 24° day, 8° night) and analyzed at intervals leaf pair by leaf pair, there is a steady increase in monoterpenes until the time of floral initiation, followed by a rapid decrease. It is suggested that monoterpenes may serve as substrates for energy metabolism in the secretory cells after other stored substrates have been depleted.     

Purification of 4S-limonene synthase, a monoterpene cyclase from the glandular trichomes of peppermint (Mentha x piperita) and spearmint (Mentha spicata).

The p-menthane monoterpenes of the Mentha species are biosynthesized from geranyl pyrophosphate via the monocyclic olefin 4S-limonene. A monoterpene cyclase was isolated from both Mentha x piperita (peppermint) and Mentha spicata (spearmint) that catalyzes the cyclization of geranyl pyrophosphate to 4S-limonene. This enzyme, 4S-limonene synthase, was purified to apparent homogeneity by dye ligand, anion exchange, and hydrophobic interaction chromatography. Since the monoterpenes of Mentha are synthesized and secreted in modified epidermal hairs called glandular trichomes, an extract of isolated glandular trichome cells was used as the source of this enzyme. A combination of gel permeation chromatography and sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that purified 4S-limonene synthase had a native molecular weight of 56,000 and was monomeric. The principal product of the enzyme was enantiomerically pure (-)-4S-limonene, and a catalytic constant of 0.3/s was determined. The basic properties of 4S-limonene synthase from both M. x piperita and M. spicata are identical and, in general, are similar to those of other monoterpene, sesquiterpene, and diterpene cyclases isolated from microorganisms and higher plants.     

Hyperconjugation enhances electrophilic addition to monocyclic monoterpenes: a Fukui function perspective

The local and condensed Fukui functions as well as the principle of hard and soft acids and bases were used to study the addition of free radicals to the exocyclic and endocyclic double bonds of seven monocyclic monoterpenes of formula C₁₀H₁₆. The results obtained showed that, in general, the most reactive double bond was the one with the most substituents on the double-bonded carbon atoms, and that the reaction of a double bond with an electrophile is a soft–soft interaction. The effects of substituents on the double-bonded carbon atoms and the stabilization of the monoterpenes were interpreted by invoking hyperconjugated structures, which led us to propose a simple rule: the larger the value of the Fukui function for the double bond, the greater the hyperconjugative stabilization and the susceptibility of the double bond to electrophilic attack. In general, our results are in good accordance with relevant experimental and theoretical results published in the literature.

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Graphical abstract The specific electrophilic addition to monocyclic monoterpenes.

     

Regulation of monoterpene accumulation in leaves of peppermint

Plants synthesize numerous classes of natural products that accumulate during development and are thought to function as constitutive defenses against herbivores and pathogens. However, little information is available about how the levels of such defenses are regulated. We measured the accumulation of monoterpenes, a model group of constitutive defenses, in peppermint (Mentha x piperita L.) leaves and investigated several physiological processes that could regulate their accumulation: the rate of biosynthesis, the rate of metabolic loss, and the rate of volatilization. Monoterpene accumulation was found to be restricted to leaves of 12 to 20 d of age, the period of maximal leaf expansion. The rate of monoterpene biosynthesis determined by (14)CO(2) incorporation was closely correlated with monoterpene accumulation, as determined by gas chromatographic analysis, and appeared to be the principal factor controlling the monoterpene level of peppermint leaves. No significant catabolic losses of monoterpenes were detected throughout leaf development, and monoterpene volatilization was found to occur at a very low rate, which, on a monthly basis, represented less than 1% of the total pool of stored monoterpenes. The composition of volatilized monoterpenes differed significantly from that of the total plant monoterpene pool, suggesting that these volatilized products may arise from a separate secretory system. With the demonstration that the rate of biosynthesis is the chief process that determines monoterpene accumulation in peppermint, efforts to improve production in this species can now focus on the genes, enzymes, and cell differentiation processes that regulate monoterpene biosynthesis.     

Metabolism of Monoterpenes: Acetylation of (-)-Menthol by a Soluble Enzyme Preparation from Peppermint (Mentha piperita) Leaves

The essential oil from mature leaves of flowering peppermint (Mentha piperita L.) contains up to 15% (—)-menthyl acetate, and leaf discs converted exogenous (—)-[G-³H]menthol into this ester in approximately 15% yield of the incorporated precursor. Leaf extracts catalyzed the acetyl coenzyme A-dependent acetylation of (—)-[G-³H]menthol and the product of this transacetylase reaction was identified by radiochromatographic techniques. Transacetylase activity was located mainly in the 100,000g supernatant fraction, and the preparation was partially purified by combination of Sephadex G-100 gel filtration and chromatography on O-diethylaminoethyl-cellulose. The transacetylase had a molecular weight of about 37,000 as judged by Sephadex G-150 gel filtration, and a pH optimum near 9. The apparent K_m and velocity for (—)-menthol were 0.3 mm and 16 nmol/hr· mg of protein, respectively. The saturation curve for acetyl coenzyme A was sigmoidal, showing apparent saturation near 0.1 mm. Dithioerythritol was required for maximum activity and stability of the enzyme, and the enzyme was inhibited by thiol directed reagents such as p-hydroxymercuribenzoate. Diisopropylfluorophosphate also inhibited transacylation suggesting the involvement of a serine residue in catalysis. The transacylase was highly specific for acetyl coenzyme A; propionyl coenzyme A and butyryl coenzyme A were not nearly as efficient as acyl donors (11% and 2%, respectively). However, the enzyme was much less selective with regard to the alcohol substrate, suggesting that the nature of the acetate ester synthesized in mint is more dependent on the type of alcohol available than on the specificity of the transacetylase. This is the first report on an enzyme involved in monoterpenol acetylation in plants. A very similar enzyme, catalyzing this key reaction in the metabolism of menthol, was also isolated from the flowers of peppermint.     

Demonstration that limonene is the first cyclic intermediate in the biosynthesis of oxygenated p-menthane monoterpenes in Mentha piperita and other Mentha species

The volatile oil of mature Mentha piperita (peppermint) leaves contains as major components the oxygenated p-menthane monoterpenes l-menthol (47%) and l-menthone (24%) as well as very low levels of the monoterpene olefins limonene (1%) and terpinolene (0.1%), which are considered to be probable precursors of the oxygenated derivatives. Immature leaves, which are actively synthesizing monoterpenes, produce an oil with comparatively higher levels of limonene (approximately 3%), and isolation of the pure olefin showed this compound to consist of approximately 80% of the l-(4S)-enantiomer and approximately 20% of the d-(4R)-enantiomer. The time course of incorporation of [U-14C]sucrose into the monoterpenes of M. piperita shoot tips was consistent with the initial formation of limonene and its subsequent conversion to menthone via pulegone. d,l-[9-3H]Limonene and [9,10-3H]terpinolene were prepared and tested directly as precursors of oxygenated p-menthane monoterpenes in M. piperita shoot tips. Limonene was readily incorporated into pulegone, menthone, and other oxygenated derivatives, whereas terpinolene was not appreciably incorporated into these compounds. Similarly, d,l-[9-3H]limonene was specifically incorporated into pulegone in Mentha pulegium and into the C-2-oxygenated derivative carvone in Mentha spicata, confirming the role of this olefin as the essential precursor of oxygenated p-menthane monoterpenes. Soluble enzyme preparations from the epidermis of immature M. piperita leaves converted the acyclic terpenoid precursor [1-3H]geranyl pyrophosphate to limonene as the major cyclic product, providing a further indication that this olefin plays a central role in the formation of oxygenated monoterpenes in Mentha. No free intermediates were detected in the cyclization of geranyl pyrophosphate to limonene, suggesting that the olefin is the first cyclic intermediate to arise in the pathway, and resolution of the biosynthetic limonene, by crystallization of the derived d- and l-carvoximes, indicated an enantiomer mixture nearly identical to that isolated from the leaf oil.     

Biosynthesis of mono- and sesquiterpenes in peppermint from mevalonate-2-C

The volatile oil from peppermint (Mentha piperita L.) is composed primarily of monoterpenes with less than 2% sesquiterpenes. However, radioactivity from mevalonate-2-¹⁴C is incorporated into caryophyllene and other sesquiterpene hydrocarbons much more extensively than into monoterpenes by peppermint cuttings. Both mono- and sesquiterpenes show maximum incorporation of label after 6 hr (0·03% vs. 0·33% of the physiological isomer) and lose 75% of the incorporated label after an additional 6 hr. Caryophyllene derived from mevalonate-2-¹⁴C after 6 hr of incorporation was chemically degraded. The isoprenoid origin of caryophyllene was confirmed, and preferential labelling of the isopentenyl pyrophosphate derived portions of the molecule was noted. On the basis of such evidence it appears that separate sites may exist for the biosynthesis of mono- and sesquiterpenes and that an endogenous dimethylallyl pyrophosphate pool may participate in the biosynthesis of sesquiterpenes in peppermint.     

Phenylalanine ammonia-lyase: enzymic conversion of 3-(1,4-cyclohexadienyl)-L-alanine to trans-3-(1,4-cyclohexadienyl)acrylic acid.

The phenylalanine analogue 3-(1,4-cyclohexadienyl)-L-alanine is converted to the hitherto unknown cinnamate analogue trans-3-(1,4-cyclohexadienyl)acrylic acid by L-phenylalanine ammonia-lyase (EC 4.3.1.5) from maize, potato, or Rhodotorula glutinis. The structure assigned to the product is confirmed by its 1H nuclear magnetic resonance spectrum and by the chemical synthesis to be described in a subsequent paper. On comparing the above substrate analogue with L-phenylalanine, the Km was lowered only slightly but kcat was reduced 14--40-fold depending on the source of the enzyme. Because the compounds closely resemble each other in size and hydrophobic properties, this lowering of kcat may be attributed to the electronic effect of replacing the pi electrons of the aromatic system by those of a double bond. Correct alignment at the active site appears to depend upon the space-filling properties of the ring system; open chain analogues that retain the gamma, beta double bond were found to be inhibitors, not substrates.     

Lack of rapid monoterpene turnover in rooted plants: implications for theories of plant chemical defense

Summary Evidence for the rapid metabolic turnover of leaf monoterpenes is a significant component of theories regarding the evolution and metabolic cost of plant chemical defenses. We re-examined whether monoterpenes are continuously synthesized and lost in intact peppermint plants, and demonstrate that the rapid monoterpene turnover previously observed using detached stems does not occur in intact plants. The apparent artifactual nature of rapid monoterpene turnover in peppermint suggests that a re-evaluation of the rates of metabolic turnover of plant defenses is needed before accurate hypotheses regarding the cost of plant chemical defense can be proposed.     

Characterization and mechanism of (4S)-limonene synthase, a monoterpene cyclase from the glandular trichomes of peppermint (Mentha x piperita).

(4S)-Limonene synthase, a monoterpene cyclase isolated from the secretory cells of the glandular trichomes of Mentha x piperita (peppermint), catalyzes the cyclization of geranyl pyrophosphate to (4S)-limonene, a key intermediate in the biosynthesis of p-menthane monoterpenes in Mentha species. The enzyme synthesizes principally (-)-(4S)-limonene (greater than 94% of the total products), plus several other monoterpene olefins. The general properties of (4S)-limonene synthase resemble those of other monoterpene cyclases. The enzyme shows a pH optimum near 6.7, an isoelectric point of 4.35, and requires a divalent metal ion for catalysis, either Mg2+ or Mn2+, with Mn2+ preferred. The Km value measured for geranyl pyrophosphate was 1.8 microM. The activity of (4S)-limonene synthase was inhibited by sodium phosphate, sodium pyrophosphate, and reagents directed against the amino acids cysteine, methionine, and histidine. In the presence of Mn2+, geranyl pyrophosphate protected against cysteine-directed inhibition, suggesting that at least one cysteine residue is located at or near the active site. Experiments with alternate substrates and substrate analogs confirmed many elements of the proposed reaction mechanism, including the binding of geranyl pyrophosphate in the form of a complex with the divalent metal ion, the preliminary isomerization of geranyl pyrophosphate to linalyl pyrophosphate (a bound intermediate capable of cyclization), and the participation of a series of carbocation:pyrophosphate anion pairs in the reaction sequence.     

Biochemical characterization of a spearmint mutant that resembles peppermint in monoterpene content

A radiation-induced mutant of Scotch spearmint (Mentha × gracilis) was shown to produce an essential oil containing principally C3-oxygenated p-menthane monoterpenes that are typical of peppermint, instead of the C6-oxygenated monoterpene family characteristic of spearmint. In vitro measurement of all of the enzymes responsible for the production of both the C3-oxygenated and C6-oxygenated families of monoterpenes from the common precursor (−)-limonene indicated that a virtually identical complement of enzymes was present in wild type and mutant, with the exception of the microsomal, cytochrome P-450-dependent (−)-limonene hydroxylase; the C6-hydroxylase producing (−)-trans-carveol in the wild type had been replaced by a C3-hydroxylase producing (−)-trans-isopiperitenol in the mutant. Additionally, the mutant, but not the wild type, could carry out the cytochrome P-450-dependent epoxidation of the α,β-unsaturated bond of the ketones formed via C3-hydroxylation. Although present in the wild type, the enzymes of the C3-pathway that convert trans-isopiperitenol to menthol isomers are synthetically inactive because of the absence of the key C3-oxygenated intermediate generated by hydroxylation of limonene. These results, which clarify the origins of the C3- and C6-oxygenation patterns, also allow correction of a number of earlier biogenetic proposals for the formation of monoterpenes in Mentha.     

Key structural features in cis-carane, (+)-3-carene,cis-pinane, (+)-α-pinene,and (−)-β-pinene influencing red turpentine beetle primary attraction when released with ethanol

1. In US Pacific Northwest ponderosa pine forests the primary attraction order shown previously for red turpentine beetle, Dendroctonus valens (Coleoptera: Curculionidae: Scolytinae), is (−)-β-pinene+ethanol > (+)-3-carene+ethanol > (+)-α-pinene+ethanol. The monoterpenes are bicyclic C₁₀H₁₆ isomers containing one 6-carbon ring with one double bond. Both pinenes have a 4-carbon second ring and differ only by their endocyclic or exocyclic double bond. The (+)-3-carene second ring has 3-carbons; its double bond is endocyclic like (+)-α-pinene.
2. Ring system and double bond influences on primary attraction were evaluated by hydrogenating (+)-3-carene and (+)-α-pinene to cis-carane and cis-pinane, respectively. Field test primary attraction strengths were (−)-β-pinene+ethanol > cis-carane+ethanol > cis-pinane+ethanol > ethanol.
3. In combination with ethanol (i) a double bond is not required in either ring system to attract D. valens, (ii) the cis-carane bicyclic 3, 6-carbon ring system provides stronger beetle attraction than the cis-pinane 4, 6-carbon bicyclic ring system, and likely structural basis for stronger (+)-3-carene attraction over (+)-α-pinene, (iii) adding an exocyclic double bond to the 4, 6-carbon ring system elevates attraction above the 3, 6-carbon ring system with no double bond, and (iv) the 4, 6-carbon ring system is a much stronger attractant with an exocyclic rather than endocyclic double bond.

     

Morphology and monoterpene biosynthetic capabilities of secretory cell clusters isolated from glandular trichomes of peppermint (Mentha piperita L.)

Secretory cells were isolated from the monoterpene-producing glandular trichomes (peltate form) of peppermint as clusters of eight cells each. These isolated structures were shown to be non-specifically permeable to low-molecular-weight, water-soluble cofactors and substrates. Short incubation periods with the polar dye Lucifer yellow iodoacetamide (M_r=660) resulted in a uniform staining of the cytoplasm, with exclusion of the dye from the vacuole. The molecular-weight exclusion limit for this permeability was shown to be less than approx. 1800, based on exclusion of fluorescein-conjugated dextran (M_r 1800). Intact secretory cell clusters very efficiently incorporated [³H]geranyl pyrophosphate into monoterpenes. The addition of exogenous cofactors and redox substrates affected the distribution of monoterpenes synthesized from [³H]geranyl pyrophosphate, demonstrating that the cell clusters were permeable to these compounds and that the levels of endogenous cofactors and redox substrates were depleted in the isolated cells. When provided with the appropriate cofactors, such as NADPH, NAD⁺, ATP, ADP and coenzyme A, the isolated secretory cell clusters incorporated [¹⁴C]sucrose into monoterpenes, indicating that these structures are capable of the de-novo biosynthesis of monoterpenes from a primary carbon source, and that they maintain a high degree of metabolic competence in spite of their permeable nature.Abbreviations GLC gas liquid chromatography - LSCM laser scanning confocal microscopy - LY-IA Lucifer yellow iodoacetamide This investigation was supported in part by U.S. Department of Energy Grant DE-FG0688ER13869 and by Project 0268 from the Washington State University Agricultural Research Center. Light microscopy was carried out in the Plant Biology Light Microscopy and Image Analysis Facility (WSU) funded by the National Science Foundation (DIR9016138). We thank Greg Wichelns for growing the plants and Stephen Pfeiffer (BioRad Microsciences Division, Cambridge, Mass, USA), for help acquiring the confocal images.     

Identification of a Lysine Residue Important for the Catalytic Activity of Yeast Farnesyl Diphosphate Synthase

The Saccharomyces cerevisiae ERG20 gene (encoding farnesyl diphosphate synthase) has been subjected to a set of mutations at the catalytic site, at position K254 to determine the in vivo impact. The mutated strains have been shown to exhibit various growth rates, sterol profiles and monoterpenol producing capacities. The results obtained suggest that K at position 254 helps to stabilize one of the three Mg²⁺ forming a bridge between the enzyme and DMAPP, and demonstrate that destabilizing two of the three Mg²⁺ ions, by introducing a double mutation at positions K197 and K254, results in a loss of FPPS activity and a lethal phenotype.