Mutational analysis of white spruce (Picea glauca) ent-kaurene synthase (PgKS) reveals common and distinct mechanisms of conifer diterpene synthases of general and specialized metabolism

Conifer diterpene synthases (diTPSs) catalyze the multi-step cycloisomerization of geranylgeranyl diphosphate, or copalyl diphosphate, to a variety of diterpenes in general (i.e., primary) and specialized (i.e., secondary) metabolism. Despite their functional diversity, the known conifer diTPSs are structurally closely related, with variations in three conserved domains, α, β and γ. The catalytic specificity of conifer class I and class I/II diTPSs is predominantly determined by the protein environment of the C-terminal class I active site through stabilization of common and unique carbocation intermediates. Using the crystal structure of Taxus brevifolia taxadiene synthase as template, comparative modeling and mutagenesis of the class I diTPS ent-kaurene synthase from Picea glauca (PgKS) was performed to elucidate the catalytic specificity of PgKS relative to spruce diTPSs of specialized metabolism. N-terminal truncations demonstrated a role for the βγ domain in class I enzyme activity for PgKS, facilitating the closure of the class I active site upon substrate binding. Based on position, Arg476 and Asp736 in the C-terminal α domain of PgKS may contribute to this conformational transition and appear critical for catalysis. Consistent with the mechanism of other diTPSs, the subsequent ionization of a copalyl diphosphate substrate and coordination of the diphosphate group is controlled by strictly conserved residues in the DDxxD and NDIQGCKRE motif of PgKS, such as Asn656 and Arg653. Furthermore, Lys478, Trp502, Met588, Ala615 and Ile619 control the enzymatic activity and specificity of PgKS via carbocation stabilization en route to ent-kaurene. These positions show a high level of amino acid variation, consistent with functional plasticity among conifer diTPSs of different functions in general or specialized metabolism.     

Engineering chimeric diterpene synthases and isoprenoid biosynthetic pathways enables high-level production of miltiradiene in yeast

Miltiradiene is a key intermediate in the biosynthesis of many important natural diterpene compounds with significant pharmacological activity, including triptolide, tanshinones, carnosic acid and carnosol. Sufficient accumulation of miltiradiene is vital for the production of these medicinal compounds. In this study, comprehensive engineering strategies were applied to construct a high-yielding miltiradiene producing yeast strain. First, a chassis strain that can accumulate 2.1 g L^-1 geranylgeraniol was constructed. Then, diterpene synthases from various species were evaluated for their ability to produce miltiradiene, and a chimeric miltiradiene synthase, consisting of class II diterpene synthase (di-TPS) CfTPS1 from Coleus forskohlii (Plectranthus barbatus) and class I di-TPS SmKSL1 from Salvia miltiorrhiza showed the highest efficiency in the conversion of GGPP to miltiradiene in yeast. Moreover, the miltiradiene yield was further improved by protein modification, which resulted in a final yield of 550.7 mg L^-1 in shake flasks and 3.5 g L^-1 in a 5-L bioreactor. This work offers an efficient and green process for the production of the important intermediate miltiradiene, and lays a foundation for further pathway reconstruction and the biotechnological production of valuable natural diterpenes.     

Identification and Functional Characterization of Monofunctional ent-Copalyl Diphosphate and ent-Kaurene Synthases in White Spruce Reveal Different Patterns for Diterpene Synthase Evolution for Primary and Secondary Metabolism in Gymnosperms

The biosynthesis of the tetracyclic diterpene ent-kaurene is a critical step in the general (primary) metabolism of gibberellin hormones. ent-Kaurene is formed by a two-step cyclization of geranylgeranyl diphosphate via the intermediate ent-copalyl diphosphate. In a lower land plant, the moss Physcomitrella patens, a single bifunctional diterpene synthase (diTPS) catalyzes both steps. In contrast, in angiosperms, the two consecutive cyclizations are catalyzed by two distinct monofunctional enzymes, ent-copalyl diphosphate synthase (CPS) and ent-kaurene synthase (KS). The enzyme, or enzymes, responsible for ent-kaurene biosynthesis in gymnosperms has been elusive. However, several bifunctional diTPS of specialized (secondary) metabolism have previously been characterized in gymnosperms, and all known diTPSs for resin acid biosynthesis in conifers are bifunctional. To further understand the evolution of ent-kaurene biosynthesis as well as the evolution of general and specialized diterpenoid metabolisms in gymnosperms, we set out to determine whether conifers use a single bifunctional diTPS or two monofunctional diTPSs in the ent-kaurene pathway. Using a combination of expressed sequence tag, full-length cDNA, genomic DNA, and targeted bacterial artificial chromosome sequencing, we identified two candidate CPS and KS genes from white spruce (Picea glauca) and their orthologs in Sitka spruce (Picea sitchensis). Functional characterization of the recombinant enzymes established that ent-kaurene biosynthesis in white spruce is catalyzed by two monofunctional diTPSs, PgCPS and PgKS. Comparative analysis of gene structures and enzyme functions highlights the molecular evolution of these diTPSs as conserved between gymnosperms and angiosperms. In contrast, diTPSs for specialized metabolism have evolved differently in angiosperms and gymnosperms.Conifers (Coniferophyta) are well known for producing an abundant and diverse assortment of oleoresin diterpenoids, predominantly in the form of diterpene resin acids from specialized (or secondary) metabolism, that play roles in conifer defense (Trapp and Croteau, 2001a; Keeling and Bohlmann, 2006a; Bohlmann, 2008) and are an important source of biomaterials (Bohlmann and Keeling, 2008). Several conifer diterpene synthases (diTPSs) that biosynthesize these compounds have been functionally characterized (Stofer Vogel et al., 1996; Peters et al., 2000; Martin et al., 2004; Keeling and Bohlmann, 2006b; Ro and Bohlmann, 2006). The formation of diterpene resin acids of conifer specialized metabolism parallels the formation of ent-kaurenoic acid in the biosynthesis of the gibberellin diterpenoid phytohormones (Fig. 1; Keeling and Bohlmann, 2006a; Yamaguchi, 2008). In gibberellin biosynthesis, geranylgeranyl diphosphate (GGPP) is cyclized by diTPS activity to ent-copalyl diphosphate (ent-CPP), and the ent-CPP is further cyclized by diTPS activity to ent-kaurene. A cytochrome P450 (P450)-dependent monooxygenase (CYP701) oxidizes ent-kaurene to ent-kaurenoic acid (Davidson et al., 2006), paralleling the activity of a P450 (CYP720B1) that oxidizes abietadiene to abietic acid in conifer diterpene resin acid biosynthesis (Ro et al., 2005). Other P450s further functionalize ent-kaurenoic acid to form the biologically active gibberellins. Surprisingly, no conifer diTPS involved in the general (or primary) metabolism of gibberellins has been reported to date, while metabolite profiles of gibberellins have been well characterized in conifers for their role in flowering (Moritz et al., 1990).Open in a separate windowFigure 1.Comparison of the biosynthesis of gibberellins, as it is known in angiosperm and lower plants, with the biosynthesis of diterpene resin acids in conifers, a large group of gymnosperm trees. In conifers, the formation of diterpene resin acids involves bifunctional diTPS (e.g. abietadiene synthase) for the stepwise cyclization of GGPP into diterpenes such as abietadiene via a copalyl diphosphate intermediate that moves between the two active sites of the bifunctional diTPS (Peters et al., 2001). The products of the diTPS are subsequently oxidized by P450 to the resin acids. In contrast, gibberellin biosynthesis in angiosperms requires two monofunctional diTPSs to convert GGPP into ent-kaurene, which is subsequently modified by P450s. The two monofunctional diTPSs in angiosperm gibberellin biosynthesis are CPS and KS. In the lower plant P. patens, the CPS and KS activities are combined in a bifunctional diTPS similar to the bifunctional diTPS in conifer diterpene resin acid biosynthesis. Prior to this work, to our knowledge, it was not known if the formation of gibberellins in a gymnosperm involves two monofunctional diTPSs, as in angiosperms, or a bifunctional diTPS, as in gymnosperm diterpene resin acid biosynthesis and in P. patens gibberellin biosynthesis. (Figure adapted from Keeling and Bohlmann [2006a].)In the fungi Gibberella fujikuroi (Toyomasu et al., 2000) and Phaeosphaeria species L487 (Kawaide et al., 1997) and in the primitive land plant Physcomitrella patens (Bryophyta; Hayashi et al., 2006; Anterola and Shanle, 2008), the formation of ent-kaurene from GGPP is catalyzed by bifunctional diTPS enzymes. These enzymes contain two active sites. The N-terminal active site domain harbors a conserved DXDD motif and catalyzes the protonation-initiated cyclization of GGPP to ent-CPP (Prisic et al., 2007). In the C-terminal active site domain, a conserved DDXXD motif is essential for the diphosphate ionization-initiated cyclization of ent-CPP to ent-kaurene (Christianson, 2006). The presence of two active sites with their characteristic DXDD and DDXXD motifs resembles the structure of conifer bifunctional diTPSs in specialized metabolism of diterpene resin acid biosynthesis (Fig. 1), such as the grand fir (Abies grandis) abietadiene synthase (AgAS) and Norway spruce (Picea abies) levopimaradiene/abietadiene synthases (PaLAS; Peters et al., 2001; Martin et al., 2004; Keeling and Bohlmann, 2006a). In contrast, the formation of ent-kaurene from GGPP in angiosperms is catalyzed by two separate monofunctional enzymes, one with only the DXDD motif and having ent-copalyl diphosphate synthase (ent-CPS) activity and the other with only the DDXXD motif and having ent-kaurene synthase (ent-KS) activity (Yamaguchi, 2008).A previously published model for the evolution of plant diTPS (Trapp and Croteau, 2001b) suggests that genes encoding the monofunctional CPS and KS enzymes known in angiosperms originated by gene duplication and subfunctionalization (Lynch and Force, 2000) of an ancestral bifunctional CPS/KS gene that may have been similar to the gene for the CPS/KS enzyme of the moss P. patens. The same model also suggests that genes for diTPSs of gymnosperm specialized diterpene resin acid metabolism arose from duplication and subsequent neofunctionalization of an ancestral bifunctional diTPS of the gibberellin pathway (Trapp and Croteau, 2001b). The pathways to specialized oleoresin diterpenes existed in ancient plants prior to the differentiation of gymnosperms and angiosperms (Bray and Anderson, 2009). Vascular plants split from nonvascular plants approximately 500 million years ago, and angiosperms split from gymnosperms approximately 300 million years ago (Palmer et al., 2004). As there has been no report to date of genes involved in gibberellin biosynthesis in gymnosperms, it remains unresolved and cannot be predicted whether conifers have a bifunctional CPS/KS for the formation of ent-kaurene similar to the primitive land plant P. patens and paralleling the diTPSs for conifer specialized diterpene resin acid biosynthesis or whether they have separate monofunctional CPS and KS enzymes, as is the case in angiosperms.In this study, we made use of the extensive EST resources for spruce species (Pavy et al., 2005; Ralph et al., 2008), combined with isolation and sequencing of full-length cDNAs, genomic (g)DNA, and targeted bacterial artificial chromosome (BAC) clones, as well as enzyme assays with recombinant proteins to search for, and functionally characterize, possible monofunctional or bifunctional diTPS for ent-kaurene biosynthesis in a gymnosperm. In summary, we successfully isolated and characterized monofunctional ent-CPS (PgCPS) and ent-KS (PgKS) from white spruce (Picea glauca) and isolated orthologous cDNAs from Sitka spruce (Picea sitchensis). Comparison of enzyme functions and gene structures support common ancestry but different routes of evolution of monofunctional and bifunctional diTPS in conifer general and specialized metabolism, respectively.     

Enzymatic (13)C labeling and multidimensional NMR analysis of miltiradiene synthesized by bifunctional diterpene cyclase in Selaginella moellendorffii

Diterpenes show diverse chemical structures and various physiological roles. The diversity of diterpene is primarily established by diterpene cyclases that catalyze a cyclization reaction to form the carbon skeleton of cyclic diterpene. Diterpene cyclases are divided into two types, monofunctional and bifunctional cyclases. Bifunctional diterpene cyclases (BDTCs) are involved in hormone and defense compound biosyntheses in bryophytes and gymnosperms, respectively. The BDTCs catalyze the successive two-step type-B (protonation-initiated cyclization) and type-A (ionization-initiated cyclization) reactions of geranylgeranyl diphosphate (GGDP). We found that the genome of a lycophyte, Selaginella moellendorffii, contains six BDTC genes with the majority being uncharacterized. The cDNA from S. moellendorffii encoding a BDTC-like enzyme, miltiradiene synthase (SmMDS), was cloned. The recombinant SmMDS converted GGDP to a diterpene hydrocarbon product with a molecular mass of 272 Da. Mutation in the type-B active motif of SmMDS abolished the cyclase activity, whereas (+)-copalyl diphosphate, the reaction intermediate from the conversion of GGDP to the hydrocarbon product, rescued the cyclase activity of the mutant to form a diterpene hydrocarbon. Another mutant lacking type-A activity accumulated copalyl diphosphate as the reaction intermediate. When the diterpene hydrocarbon was enzymatically synthesized from [U-(13)C(6)]mevalonate, all carbons were labeled with (13)C stable isotope (>99%). The fully (13)C-labeled product was subjected to (13)C-(13)C COSY NMR spectroscopic analyses. The direct carbon-carbon connectivities observed in the multidimensional NMR spectra demonstrated that the hydrocarbon product by SmMDS is miltiradiene, a putative biosynthetic precursor of tanshinone identified from the Chinese medicinal herb Salvia miltiorrhiza. Hence, SmMDS functions as a bifunctional miltiradiene synthase in S. moellendorffii. In this study, we demonstrate that one-dimensional and multidimensional (13)C NMR analyses of completely (13)C-labeled compound are powerful methods for biosynthetic studies.     

Production of miltiradiene by metabolically engineered Saccharomyces cerevisiae

Metabolic engineering of microorganisms is an alternative and attractive route for production of valuable terpenoids that are usually extracted from plant sources. Tanshinones are the bioactive components of Salvia miltiorrhizha Bunge, which is a well‐known traditional Chinese medicine widely used for treatment of many cardiovascular diseases. As a step toward microbial production of tanshinones, copalyl diphosphate (CPP) synthase, and normal CPP kaurene synthase‐like genes, which convert the universal diterpenoid precursor geranylgeranyl diphosphate (GGPP) to miltiradiene (an important intermediate of the tanshinones synthetic pathway), was introduced into Saccharomyces cerevisiae, resulting in production of 4.2 mg/L miltiradiene. Improving supplies of isoprenoid precursors was then investigated for increasing miltiradiene production. Although over‐expression of a truncated 3‐hydroxyl‐3‐methylglutaryl‐CoA reductase (tHMGR) and a mutated global regulatory factor (upc2.1) gene did improve supply of farnesyl diphosphate (FPP), production of miltiradiene was not increased while large amounts of squalene (78 mg/L) were accumulated. In contrast, miltiradiene production increased to 8.8 mg/L by improving supply of GGPP through over‐expression of a fusion gene of FPP synthase (ERG20) and endogenous GGPP synthase (BTS1) together with a heterologous GGPP synthase from Sulfolobus acidocaldarius (SaGGPS). Auxotrophic markers in the episomal plasmids were then replaced by antibiotic markers, so that engineered yeast strains could use rich medium to obtain better cell growth while keeping plasmid stabilities. Over‐expressing ERG20‐BTS1 and SaGGPS genes increased miltiradiene production from 5.4 to 28.2 mg/L. Combinatorial over‐expression of tHMGR‐upc2.1 and ERG20‐BTS1‐SaGGPS genes had a synergetic effects on miltiradiene production, increasing titer to 61.8 mg/L. Finally, fed‐batch fermentation was performed, and 488 mg/L miltiradiene was produced. The yeast strains engineered in this work provide a basis for creating an alternative way for production of tanshinones in place of extraction from plant sources. Biotechnol. Bioeng. 2012; 109: 2845–2853. © 2012 Wiley Periodicals, Inc.     

Concerted bifunctionality of the dCTP deaminase-dUTPase from Methanocaldococcus jannaschii: A structural and pre-steady state kinetic analysis

Two mutant dCTP deaminase-dUTPases from Methanocaldococcus jannaschii were crystallised and the crystal structures were solved: E145A in complex with the substrate analogue α,β-imido-dUTP and E145Q in complex with diphosphate. Both mutant enzymes were defect in the deaminase reaction and had reduced dUTPase activity. In the structure of E145Q in complex with diphosphate, the diphosphate occupied the same position as the β- and γ-phosphoryls of the nucleotide analogue in the E145A complex. The C-terminal region that is unresolved in the apo-form of the enzyme was ordered in both complexes and closed over the active site by interacting with the phosphate backbone of the nucleotide or with the diphosphate. A magnesium ion was readily observed to complex with all three phosphoryls in the nucleotide complex or with the diphosphate. A water molecule that is likely to be involved in the nucleotidyl diphosphorylase reaction was observed in the E145A:α,β-imido-dUTP complex and positioned similarly as in the monofunctional trimeric dUTPase. A comparison of the active sites of the bifunctional enzyme and the monofunctional family members, dCTP deaminase and dUTPase, suggests similar reaction mechanisms. The similar side chain conformations in the deaminase site between the nucleotide and diphosphate complexes indicated a concerted re-arrangement, or induced fit, of the whole active site promoted by enzyme and nucleotide phosphoryl interactions. A pre-steady state kinetic analysis of the bifunctional reaction and the dUTPase half-reaction supported a conformational change upon substrate binding in both reactions and a concerted catalytic step for the bifunctional reaction.     

Direct production of dihydroxylated sesquiterpenoids by a maize terpene synthase

The astounding structural and biological diversities of the large class of terpenoid natural products are imparted by both their complex hydrocarbon backbones and further elaboration by the addition of multiple hydroxyl groups, which provide both solubility and specific binding properties. While the role of terpene synthases (TPSs) in generating hydrocarbons with complex backbones is well known, these also are known to generate (singly) hydroxylated products by the addition of water prior to terminating deprotonation. Here a maize sesquiterpene synthase was unexpectedly found to generate dually hydroxylated products directly from (E,E)‐farnesyl diphosphate, primarily eudesmane‐2,11‐diol, along with two closely related structural isomers. The unprecedented formation of these diols was proposed to proceed via initial addition of water to a germacradienyl⁺ intermediate, followed by protonation of the internal carbon‐6,7‐double‐bond in the resulting hedycarol, with subsequent cyclization and further addition of water to an eudesmolyl⁺ intermediate. Evidence for the proposed mechanism was provided by labeling studies, as well as site‐directed mutagenesis, based on structural modeling, which identified an active site phenylalanine required for the protonation and further elaboration of hedycaryol. This dihydroxylated sesquiterpenoid synthase was specifically expressed in maize roots and induced by pathogen infection, with its major enzymatic product only detected in root exudates or infected roots, suggesting a role in defense. Regardless of the ultimate metabolic fate or physiological role of these diols, this report not only reveals an unanticipated extension of the catalytic prowess of TPSs, but also provides insight into the underlying enzymatic mechanism.     

Relation between Neutral Lipid Accumulation and the Growth Phase in the Yeast,Lipomyces starkeyi,a Fat Producing Yeast

In order to investigate the substrate binding feature of undecaprenyl diphosphate synthase from Micrococcus luteus B-P 26 with respect to farnesyl diphosphate and a reaction intermediate, (Z,E,E)-geranylgeranyl diphosphate, we examined the reactivity of artificial substrate analogs, 3-desmethyl farnesyl diphosphate and 3-desmethyl Z-geranylgeranyl diphosphate, which lack the methyl group at the 3-position of farnesyl diphosphate and Z-geranylgeranyl diphosphate, respectively. Undecaprenyl diphosphate synthase did not accept either of the 3-desmethyl analogs as the allylic substrate, indicating that the methyl group at the 3-position of the allylic substrate is important in the undecaprenyl diphosphate synthase reaction. These analogs showed different inhibition patterns in the cis-prenyl chain elongation reaction with respect to the reactions of farnesyl diphosphate and Z-geranylgeranyl diphosphate as allylic substrate. These results suggest that the binding site for the natural substrate farnesyl diphosphate and those for the intermediate allylic diphosphate, which contains the cis-prenyl unit, are different during the cis-prenyl chain elongation reaction.     

Mechanisms of catalase activity of heme peroxidases

In the absence of exogenous electron donors monofunctional heme peroxidases can slowly degrade hydrogen peroxide following a mechanism different from monofunctional catalases. This pseudo-catalase cycle involves several redox intermediates including Compounds I, II and III, hydrogen peroxide reduction and oxidation reactions as well as release of both dioxygen and superoxide. The rate of decay of oxyferrous complex determines the rate-limiting step and the enzymes’ resistance to inactivation. Homologous bifunctional catalase-peroxidases (KatGs) are unique in having both a peroxidase and high hydrogen dismutation activity without inhibition reactions. It is demonstrated that KatGs follow a similar reaction pathway as monofunctional peroxidases, but use a unique post-translational distal modification (Met⁺-Tyr-Trp adduct) in close vicinity to the heme as radical site that enhances turnover of oxyferrous heme and avoids release of superoxide. Similarities and differences between monofunctional peroxidases and bifunctional KatGs are discussed and mechanisms of pseudo-catalase activity are proposed.     

Functional analysis of the <Emphasis Type="Italic">Burkholderia cenocepacia</Emphasis> J2315 BceA<Subscript>J</Subscript> protein with phosphomannose isomerase and GDP-<Emphasis Type="SmallCaps">d</Emphasis>-mannose pyrophosphorylase activities

The bceA _J gene from the cystic fibrosis isolate Burkholderia cenocepacia J2315 encodes a 56-kDa bifunctional protein, with phosphomannose isomerase (PMI) and guanosine diphosphate (GDP)-mannose pyrophosphorylase (GMP) activities, a new member of the poorly characterised type II PMI class of proteins. Due to the lack of homology between the type II PMIs and the human PMI, this class of proteins are being regarded as interesting potential targets to develop new antimicrobials. The BceA_J protein conserves the four typical motifs of type II PMIs: the pyrophosphorylase signature, the GMP active site, the PMI active site and the zinc-binding motif. After overproduction of BceA_J by Escherichia coli as a histidine tag derivative, the protein was purified to homogeneity by affinity chromatography. The GMP activity is dependent on the presence of Mg²⁺ or Ca²⁺ as cofactors, while the PMI activity uses a broader range of divalent ions, in the order of activation Mg²⁺ > Ca²⁺ > Mn²⁺ > Co²⁺ > Ni²⁺. The kinetic parameters K _m, V _max and K _cat/K _m for the PMI and GMP activities were determined. Results suggest that the enzyme favours the formation of GDP-mannose instead of mannose catabolism, thus channelling precursors to the formation of glycoconjugates.     

Catalytic sites of medicinal leech enzyme destabilase-lysozyme (mlDL): Structure-function relationship

Based on the three-dimensional model of the bifunctional enzyme destabilase-lysozyme of the medicinal leech (mlDL) in complex with trimer of N-acetylglucosamine (NAG)₃ by site-directed mutagenesis method, the functional role of the group of amino acids (Glu14, Asp26, Ser29, Ser31, Lys38, His92) in manifestation of lysozyme (glycosidase, muramidase) and isopeptidase activities has been investigated by site-directed mutagenesis. The results obtained go well with hypothesis, that lysozyme active site of mlDL includes catalytic Glu14 and Asp26 residues, and isopeptidase site functions as Ser/Lys catalytic dyad presented by catalytic residues Ser29 and Lys38. Thus, among the invertebrate lysozymes, mlDL presents the first example of a bifunctional enzyme with identified position of the isopeptidase active site and localization of the corresponding catalytic residues.