Biosynthesis of the microtubule-destabilizing diterpene pseudolaric acid B from golden larch involves an unusual diterpene synthase

Mafu, Sibongile; Karunanithi, Prema S.; Palazzo, Teresa A.; Harrod, Bronwyn L.; Rodriguez, Selina Marakana; Mollhoff, Iris Natalie; O’Brien, Terrence E.; Shen, Tong; Fiehn, Oliver; Tantillo, Dean J.; Bohlmann, Jörg; Zerbe, Philipp

doi:10.1073/pnas.1612901114

Cited by 23 publications

(25 citation statements)

References 47 publications

(68 reference statements)

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“…Subsequent cyclization of these relatively simple, linear building blocks by terpene cyclases enables the generation of a vast array of multicyclic molecular architectures, with potent biological activities . Stereospecific generation of tailored polycyclic terpenes provides access to chiral fine chemical synthons and antifungal, ‐viral, ‐microbial, and ‐cancer agents . Bifunctional terpene synthases with distinct domains for linear terpene formation and cyclization have been described .…”

Section: Methodsmentioning

confidence: 99%

Protonation‐Initiated Cyclization by a Class II Terpene Cyclase Assisted by Tunneling

2017

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Terpenes represent one of the most diversified classes of natural products with potent biological activities. The key to the myriad of polycyclic terpene skeletons with crucial functions in organisms from all kingdoms of life are terpene cyclase enzymes. These biocatalysts enable stereospecific cyclization of relatively simple, linear, prefolded polyisoprenes by highly complex, partially concerted, electrophilic cyclization cascades that remain incompletely understood. Herein, additional mechanistic light is shed on terpene biosynthesis by kinetic studies in mixed H2O/D2O buffers of a class II bacterial ent‐copalyl diphosphate synthase. Mass spectrometry determination of the extent of deuterium incorporation in the bicyclic product, reminiscent of initial carbocation formation by protonation, resulted in a large kinetic isotope effect of up to seven. Kinetic analysis at different temperatures confirmed that the isotope effect was independent of temperature, which is consistent with hydrogen tunneling.

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Section: Methodsmentioning

confidence: 99%

Protonation‐Initiated Cyclization by a Class II Terpene Cyclase Assisted by Tunneling

2017

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“…Beyond oleoresin and gibberellin biosynthesis, products of various conifer di‐TPSs and their derivatives are of interest as high‐value bioproducts, including pharmaceuticals (Zerbe et al ., ). Example are the anticancer drug taxol found in yew (Croteau et al ., ), the antitumor compound pseudolaric acid B produced in the roots of Pseudolarix amabilis (Mafu et al ., ), and c is ‐abienol as a molecule of interest in the fragrance industry produced in balsam fir (Zerbe et al ., ).…”

Section: Conifer Terpene Synthasesmentioning

confidence: 99%

Oleoresin defenses in conifers: chemical diversity, terpene synthases and limitations of oleoresin defense under climate change

2019

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Summary Conifers have evolved complex oleoresin terpene defenses against herbivores and pathogens. In co‐evolved bark beetles, conifer terpenes also serve chemo‐ecological functions as pheromone precursors, chemical barcodes for host identification, or nutrients for insect‐associated microbiomes. We highlight the genomic, molecular and biochemical underpinnings of the large chemical space of conifer oleoresin terpenes and volatiles. Conifer terpenes are predominantly the products of the conifer terpene synthase (TPS) gene family. Terpene diversity is increased by cytochromes P450 of the CYP720B class. Many conifer TPS are multiproduct enzymes. Multisubstrate CYP720B enzymes catalyse multistep oxidations. We summarise known terpenoid gene functions in various different conifer species with reference to the annotated terpenoid gene space in a spruce genome. Overall, biosynthesis of terpene diversity in conifers is achieved through a system of biochemical radiation and metabolic grids. Expression of TPS and CYP720B genes can be specific to individual cell types of constitutive or traumatic resin duct systems. Induced terpenoid transcriptomes in resin duct cells lead to dynamic changes of terpene composition and quantity to fend off herbivores and pathogens. While terpenoid defenses have contributed much to the evolutionary success of conifers, under new conditions of climate change, these defences may become inconsequential against range‐expanding forest pests.

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“…Pairwise activity of the remaining class‐II and class‐I diTPSs resulted in the formation of a range of specialized diterpenoids, including manoyl oxide derived from LPP ( Tc KSL1 and Tc KSL3‐7), as well as the conversion of (+)‐CPP into biformene ( Tc KSL1), levopimaradiene ( Tc KSL3) and phyllocladanol ( Tc KSL5), as verified by NMR analysis and authentic standards. Although levopimaradiene formation by Tc CPS4 and Tc KSL3 is functionally analogous to bifunctional class‐I/II diTPSs producing levopimaradiene in other gymnosperm species (Peters et al ., ; Schepmann et al ., ; Martin et al ., ; Hall et al ., ; Mafu et al ., ; Celedon and Bohlmann, ), diTPSs forming phyllocladanol or biformene have not previously been reported in gymnosperms. Notably, abienol synthase from Nicotiana tabacum has been shown to produce biformene when acting together with a (+)‐CPS (Sallaud et al ., ; Ignea et al ., ).…”

Section: Discussionmentioning

confidence: 90%

“…Although the presence of class‐II/I diTPSs in T. cryptomerioides cannot be excluded, given that five of the transcripts identified could only be obtained as partial sequences, it appears that diterpenoid metabolism in T. cryptomerioides relies predominantly, or perhaps exclusively, on pairwise‐acting monofunctional diTPSs (Figure ). Thus, the diTPSs identified in this study add new catalysts to the group of monofunctional class‐I diTPSs involved in gymnosperm specialized metabolism, which also includes taxadiene synthases in species of yew ( Taxus ) that directly convert GGPP into the macrocyclic intermediate taxadiene and related compounds (Wildung and Croteau, ), monofunctional pimaradiene and isopimaradiene synthases involved in DRA biosynthesis in Jack pine and lodgepole pine (Hall et al ., ), and the pseudolaratriene synthase of Pseudolarix amabilis (golden larch) that converts GGPP into the unusual bicyclic diterpene pseudolaratriene (Mafu et al ., ).…”

Section: Discussionmentioning

confidence: 97%

Biochemical characterization of diterpene synthases of Taiwania cryptomerioides expands the known functional space of specialized diterpene metabolism in gymnosperms

Lee

Tsao

et al. 2019

The Plant Journal

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Taiwania cryptomerioides is a monotypic gymnosperm species, valued for the high decay resistance of its wood. This durability has been attributed to the abundance of terpenoids, especially the major diterpenoid metabolite ferruginol, with antifungal and antitermite activity. Specialized diterpenoid metabolism in gymnosperms primarily recruits bifunctional class-I/II diterpene synthases (diTPSs), whereas monofunctional class-II and class-I enzymes operate in angiosperms. In this study, we identified a previously unrecognized group of monofunctional diTPSs in T. cryptomerioides, which suggests a distinct evolutionary divergence of the diTPS family in this species. Specifically, five monofunctional diTPS functions not previously observed in gymnosperms were characterized, including monofunctional class-II enzymes forming labda-13en-8-ol diphosphate (LPP, TcCPS2) and (+)-copalyl diphosphate (CPP, TcCPS4), and three class-I diTPSs producing biformene (TcKSL1), levopimaradiene (TcKSL3) and phyllocladanol (TcKSL5), respectively. Methyl jasmonate (MeJA) elicited the accumulation of levopimaradiene and the corresponding biosynthetic diTPS genes, TcCPS4 and TcKSL3, is consistent with a possible role in plant defense. Furthermore, TcCPS4 and TcKSL3 are likely to contribute to abietatriene biosynthesis via levopimaradiene as an intermediate in ferruginol biosynthesis in Taiwania. In conclusion, this study provides deeper insight into the functional landscape and molecular evolution of specialized diterpenoid metabolism in gymnosperms as a basis to better understand the role of these metabolites in tree chemical defense.

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Biosynthesis of the microtubule-destabilizing diterpene pseudolaric acid B from golden larch involves an unusual diterpene synthase

Cited by 23 publications

References 47 publications

Protonation‐Initiated Cyclization by a Class II Terpene Cyclase Assisted by Tunneling

Protonation‐Initiated Cyclization by a Class II Terpene Cyclase Assisted by Tunneling

Oleoresin defenses in conifers: chemical diversity, terpene synthases and limitations of oleoresin defense under climate change

Biochemical characterization of diterpene synthases of Taiwania cryptomerioides expands the known functional space of specialized diterpene metabolism in gymnosperms

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