Structural-Functional Correlations between Unique N-terminal Region and C-terminal Conserved Motif in Short-chain cis-Prenyltransferase from Tomato.

Neryl diphosphate (C10) synthase (NDPS1), a homodimeric soluble cis-prenyltransferase from tomato, contains four disulfide bonds, including two inter-subunit S-S bonds in the N-terminal region. Mutagenesis studies demonstrated that the S-S bond formation affects not only the stability of the dimer but also the catalytic efficiency of NDPS1. Structural polymorphs in the crystal structures of NDPS1 complexed with its substrate and substrate analog were identified by employing massive data collections and hierarchical clustering analysis. Heterogeneity of the C-terminal region, including the conserved RXG motifs, was observed in addition to the polymorphs of the binding mode of the ligands. One of the RXG motifs covers the active site with an elongated random coil when the ligands are well-ordered. Conversely, the other RXG motif was located away from the active site with a helical structure. The heterogeneous C-terminal regions suggest alternating structural transitions of the RXG motifs that result in closed and open states of the active sites. Site-directed mutagenesis studies demonstrated that the conserved glycine residue cannot be replaced. We propose that the putative structural transitions of the order/disorder of N-terminal regions and the closed/open states of C-terminal regions may cooperate and be important for the catalytic mechanism of NDPS1.

Reconstitution of prenyltransferase activity on nanodiscs by components of the rubber synthesis machinery of the Para rubber tree and guayule.

Natural rubber of the Para rubber tree (Hevea brasiliensis) is synthesized as a result of prenyltransferase activity. The proteins HRT1, HRT2, and HRBP have been identified as candidate components of the rubber biosynthetic machinery. To clarify the contribution of these proteins to prenyltransferase activity, we established a cell-free translation system for nanodisc-based protein reconstitution and measured the enzyme activity of the protein-nanodisc complexes. Co-expression of HRT1 and HRBP in the presence of nanodiscs yielded marked polyisoprene synthesis activity. By contrast, neither HRT1, HRT2, or HRBP alone nor a complex of HRT2 and HRBP manifested such activity. Similar analysis of guayule (Parthenium argentatum) proteins revealed that three HRT1 homologs (PaCPT1-3) manifested prenyltransferase activity only when co-expressed with PaCBP, the homolog of HRBP. Our results thus indicate that two heterologous subunits form the core prenyltransferase of the rubber biosynthetic machinery. A recently developed structure modeling program predicted the structure of such heterodimer complexes including HRT1/HRBP and PaCPT2/PaCBP. HRT and PaCPT proteins were also found to possess affinity for a lipid membrane in the absence of HRBP or PaCBP, and structure modeling implicated an amphipathic α-helical domain of HRT1 and PaCPT2 in membrane binding of these proteins.

Structure-based engineering of a short-chain cis-prenyltransferase to biosynthesize nonnatural all-cis-polyisoprenoids: molecular mechanisms for primer substrate recognition and ultimate product chain-length determination.

Most cis-prenyltransferases (cPTs) use all-trans-oligoprenyl diphosphate, such as (E,E)-farnesyl diphosphate (FPP, C15 ), but scarcely accept dimethylallyl diphosphate (DMAPP, C5 ), as an allylic diphosphate primer in consecutive cis-condensations of isopentenyl diphosphate. Consequently, naturally occurring cis-1,4-polyisoprenoids contain a few trans-isoprene units at their ω-end. However, some Solanum plants have distinct cPTs that primarily use DMAPP as a primer to synthesize all-cis-oligoprenyl diphosphates, such as neryl diphosphate (NPP, C10 ). However, the mechanism underlying the allylic substrate preference of cPTs remains unclear. In this study, we determined the crystal structure of NDPS1, an NPP synthase from tomato, and investigated critical residues for primer substrate preference through structural comparisons of cPTs. Highly conserved Gly and Trp in the primer substrate-binding region of cPTs were discovered to be substituted for Ile/Leu and Phe, respectively, in DMAPP-preferring cPTs. An I106G mutant of NDPS1 exhibited a low preference for DMAPP, but a higher preference for FPP. However, an I106G/F276W mutant preferred not only DMAPP but also all-trans-oligoprenyl diphosphates, with 15-fold higher catalytic efficiency than WT. Surprisingly, the mutant synthesized longer polyisoprenoids (~C50 ). Furthermore, one of the helix domains that constitute the hydrophobic cleft for accommodating elongating prenyl chains was also demonstrated to be critical in primer substrate preference. An NDPS1 I106G/F276W mutant with a chimeric helix domain swapped with that of a medium-chain cPT synthesizing C50-60 polyisoprenoids showed over 94-fold increase in catalytic efficiency for all primer substrates tested, resulting in longer products (~C70 ). These NDPS1 mutants could be used in the enzymatic synthesis of nonnatural all-cis-polyisoprenoids.

Comprehensive identification of terpene synthase genes and organ-dependent accumulation of terpenoid volatiles in a traditional medicinal plant Angelica archangelica L.

Angelica archangelica L. is a traditional medicinal plant of Nordic origin that produces an unusual amount and variety of terpenoids. The unique terpenoid composition of A. archangelica likely arises from the involvement of terpene synthases (TPSs) with different specificities, none of which has been identified. As the first step in identifying TPSs responsible for terpenoid chemodiversity in A. archangelica, we produced a transcriptome catalogue using the mRNAs extracted from the leaves, tap roots, and dry seeds of the plant; 11 putative TPS genes were identified (AaTPS1-AaTPS11). Phylogenetic analysis predicted that AaTPS1-AaTPS5, AaTPS6-AaTPS10, and AaTPS11 belong to the monoterpene synthase (monoTPS), sesquiterpene synthase (sesquiTPS), and diterpene synthase clusters, respectively. We then performed in vivo enzyme assays of the AaTPSs using recombinant Escherichia coli systems to examine their enzymatic activities and specificities. Nine recombinant enzymes (AaTPS2-AaTPS10) displayed TPS activities with specificities consistent with their phylogenetics; however, AaTPS5 exhibited a strong sesquiTPS activity along with a weak monoTPS activity. We also analyzed terpenoid volatiles in the flowers, immature and mature seeds, leaves, and tap roots of A. archangelica using gas chromatography-mass spectrometry; 14 monoterpenoids and 13 sesquiterpenoids were identified. The mature seeds accumulated the highest levels of monoterpenoids, with ß-phellandrene being the most prominent. α-Pinene and ß-myrcene were abundant in all organs examined. The in vivo assay results suggest that the AaTPSs functionally identified in this study are at least partly involved in the chemodiversity of terpenoid volatiles in A. archangelica.