Characterization of Class IB Terpene Synthase: The First Crystal Structure Bound with a Substrate Surrogate

Structural-model-based genome mining can efficiently discover novel non-canonical terpene synthases hidden in genomes of diverse species

Non-canonical terpene synthases (TPSs) with primary sequences that are unrecognizable as canonical TPSs have evaded detection by conventional genome mining. This study aimed to prove that novel non-canonical TPSs can be efficiently discovered from proteins, hidden in genome databases, predicted to have 3D structures similar to those of class I TPSs. Six types of non-canonical TPS candidates were detected using this search strategy from 268 genome sequences from actinomycetes. Functional analyses of these candidates revealed that at least three types were novel non-canonical TPSs. We propose classifying the non-canonical TPSs as classes ID, IE, and IF. A hypothetical protein MBB6373681 from Pseudonocardia eucalypti (PeuTPS) was selected as a representative example of class ID TPSs and characterized. PeuTPS was identified as a diterpene synthase that forms a 6/6/6-fused tricyclic gersemiane skeleton. Analyses of PeuTPS variants revealed that amino acid residues within new motifs [D(N/D), ND, and RXXKD] located close to the class I active site in the 3D structure were essential for enzymatic activity. The homologs of non-canonical TPSs found in this study exist in bacteria as well as in fungi, protists, and plants, and the PeuTPS gene is not located near terpene biosynthetic genes in the genome. Therefore, structural-model-based genome mining is an efficient strategy to search for novel non-canonical TPSs that are independent of biological species and biosynthetic gene clusters and will contribute to expanding the structural diversity of terpenoids.

Identification and functional/structural analyses of large terpene synthases

Large terpene synthases (large-TSs) are a new family of TSs. The first large-TS discovered was from Bacillus subtilis (BsuTS), which is involved in the biosynthesis of a C35 sesquarterpene. Large-TSs are the only enzymes that enable the biosynthesis of sesquarterpenes and do not share any sequence homology with canonical Class I and II TSs. Thus, the investigation of large-TSs is promising for expanding the chemical space in the terpene field. In this chapter, we describe the experimental methods used for identifying large-TSs, as well as their functional and structural analyses. Additionally, several enzymes related to the biosynthesis of large-TS substrates have been described.

Biosynthesis and the Transcriptional Regulation of Terpenoids in Tea Plants (Camellia sinensis)

Terpenes, especially volatile terpenes, are important components of tea aroma due to their unique scents. They are also widely used in the cosmetic and medical industries. In addition, terpene emission can be induced by herbivory, wounding, light, low temperature, and other stress conditions, leading to plant defense responses and plant-plant interactions. The transcriptional levels of important core genes (including HMGR, DXS, and TPS) involved in terpenoid biosynthesis are up- or downregulated by the MYB, MYC, NAC, ERF, WRKY, and bHLH transcription factors. These regulators can bind to corresponding cis-elements in the promoter regions of the corresponding genes, and some of them interact with other transcription factors to form a complex. Recently, several key terpene synthesis genes and important transcription factors involved in terpene biosynthesis have been isolated and functionally identified from tea plants. In this work, we focus on the research progress on the transcriptional regulation of terpenes in tea plants (Camellia sinensis) and thoroughly detail the biosynthesis of terpene compounds, the terpene biosynthesis-related genes, the transcription factors involved in terpene biosynthesis, and their importance. Furthermore, we review the potential strategies used in studying the specific transcriptional regulation functions of candidate transcription factors that have been discriminated to date.

Structural Understanding of Fungal Terpene Synthases for the Formation of Linear or Cyclic Terpene Products

Terpene synthases (TPSs), known gatekeepers of terpenoid diversity, are the main targets for enzyme engineering attempts. To this end, we have determined the crystal structure of Agrocybe pediades linalool synthase (Ap.LS), which has been recently reported to be 44-fold and 287-fold more efficient than bacterial and plant counterparts, respectively. Structure-based molecular modeling followed by in vivo as well as in vitro tests confirmed that the region of 60-69aa and Tyr299 (adjacent to the motif "WxxxxxRY") are essential for maintaining Ap.LS specificity toward a short-chain (C10) acyclic product. Ap.LS Y299 mutants (Y299A, Y299C, Y299G, Y299Q, and Y299S) yielded long-chain (C15) linear or cyclic products. Molecular modeling based on the Ap.LS crystal structure indicated that farnesyl pyrophosphate in the binding pocket of Ap.LS Y299A has less torsion strain energy compared to the wild-type Ap.LS, which can be partially attributed to the larger space in Ap.LS Y299A for better accommodation of the longer chain (C15). Linalool/nerolidol synthase Y298 and humulene synthase Y302 mutations also produced C15 cyclic products similar to Ap.LS Y299 mutants. Beyond the three enzymes, our analysis confirmed that most microbial TPSs have asparagine at the position and produce mainly cyclized products (δ-cadinene, 1,8-cineole, epi-cubebol, germacrene D, β-barbatene, etc.). In contrast, those producing linear products (linalool and nerolidol) typically have a bulky tyrosine. The structural and functional analysis of an exceptionally selective linalool synthase, Ap.LS, presented in this work provides insights into factors that govern chain length (C10 or C15), water incorporation, and cyclization (cyclic vs acyclic) of terpenoid biosynthesis.

Discovery, Structure, and Mechanism of a Class II Sesquiterpene Cyclase

Terpene cyclases (TCs), extraordinary enzymes that create the structural diversity seen in terpene natural products, are traditionally divided into two classes, class I and class II. Although the structural and mechanistic features of class I TCs are well-known, the corresponding details in class II counterparts have not been fully characterized. Here, we report the genome mining discovery and structural characterization of two class II sesquiterpene cyclases (STCs) from Streptomyces. These drimenyl diphosphate synthases (DMSs) are the first STCs shown to possess β,γ-didomain architecture. High-resolution X-ray crystal structures of DMS from Streptomyces showdoensis (SsDMS) in complex with both a farnesyl diphosphate and Mg²⁺ unveiled an induced-fit mechanism, with an unprecedented Mg²⁺ binding mode, finally solving one of the lingering questions in class II TC enzymology. This study supports continued genome mining for novel bacterial TCs and provides new mechanistic insights into canonical class II TCs that will lead to advances in TC engineering and synthetic biology.

Insight into the mechanism of geranyl-β-phellandrene formation catalyzed by Class IB terpene synthases

Terpene synthase (TS) from Bacillus alcalophilus (BalTS) is the only Class IB TS for which a 3D structure has been elucidated. Recently, geranyl-β-phellandrene, a novel cyclic diterpene, was identified as a product of BalTS in addition to the acyclic β-springene. In the present study, we have provided insight into the mechanism of geranyl-β-phellandrene formation. Deuterium labeling experiments revealed that the compound is produced via a 1,3-hydride shift. In addition, nonenzymatic reactions using divalent metal ions were performed. The enzyme is essential for the geranyl-β-phellandrene formation. Furthermore, BalTS variants targeting tyrosine residues enhanced the yield of geranyl-β-phellandrene and the proportion of the compound of the total products. It was suggested that the expansion of the active site space may allow the conformation of the intermediates necessary for cyclization. The present study describes the first Class IB TSs to successfully alter product profiles while retaining high enzyme activity.

Selective oxidation of alcohol-d 1 to aldehyde-d 1 using MnO2

The selective oxidation of alcohol-d₁ to prepare aldehyde-d₁ was newly developed by means of NaBD₄ reduction/activated MnO₂ oxidation. Various aldehyde-d₁ derivatives including aromatic and unsaturated aldehyde-d₁ can be prepared with a high deuterium incorporation ratio (up to 98% D). Halogens (chloride, bromide, and iodide), alkene, alkyne, ester, nitro, and cyano groups in the substrates are tolerated under the mild conditions.

A facile method for deutrium incorporation into aldehydes by mild reduction of NaBD₄ of aldehydes and MnO₂ oxidation (98% D) is disclosed.

Structure, catalysis, and inhibition mechanism of prenyltransferase

Isoprenoids, also known as terpenes or terpenoids, represent a large family of natural products composed of five‐carbon isopentenyl diphosphate or its isomer dimethylallyl diphosphate as the building blocks. Isoprenoids are structurally and functionally diverse and include dolichols, steroid hormones, carotenoids, retinoids, aromatic metabolites, the isoprenoid side‐chain of ubiquinone, and isoprenoid attached signaling proteins. Productions of isoprenoids are catalyzed by a group of enzymes known as prenyltransferases, such as farnesyltransferases, geranylgeranyltransferases, terpenoid cyclase, squalene synthase, aromatic prenyltransferase, and cis‐ and trans‐prenyltransferases. Because these enzymes are key in cellular processes and metabolic pathways, they are expected to be potential targets in new drug discovery. In this review, six distinct subsets of characterized prenyltransferases are structurally and mechanistically classified, including (1) head‐to‐tail prenyl synthase, (2) head‐to‐head prenyl synthase, (3) head‐to‐middle prenyl synthase, (4) terpenoid cyclase, (5) aromatic prenyltransferase, and (6) protein prenylation. Inhibitors of those enzymes for potential therapies against several diseases are discussed. Lastly, recent results on the structures of integral membrane enzyme, undecaprenyl pyrophosphate phosphatase, are also discussed.