2244-16-8Relevant articles and documents
A glandular trichome-specific monoterpene alcohol dehydrogenase from Artemisia annua
Polichuk, Devin R.,Zhang, Yansheng,Reed, Darwin W.,Schmidt, Janice F.,Covello, Patrick S.
, p. 1264 - 1269 (2010)
The major components of the isoprenoid-rich essential oil of Artemisia annua L. accumulate in the subcuticular sac of glandular secretory trichomes. As part of an effort to understand isoprenoid biosynthesis in A. annua, an expressed sequence tag (EST) collection was investigated for evidence of genes encoding trichome-specific enzymes. This analysis established that a gene denoted Adh2, encodes an alcohol dehydrogenase and shows a high expression level in glandular trichomes relative to other tissues. The gene product, ADH2, has up to 61% amino acid identity to members of the short chain alcohol dehydrogenase/reductase (SDR) superfamily, including Forsythia × intermedia secoisolariciresinol dehydrogenase (49.8% identity). Through in vitro biochemical analysis, ADH2 was found to show a strong preference for monoterpenoid secondary alcohols including carveol, borneol and artemisia alcohol. These results indicate a role for ADH2 in monoterpenoid ketone biosynthesis in A. annua glandular trichomes.
Discovery and Engineering of Bacterial (?)-Isopiperitenol Dehydrogenases to Enhance (?)-Menthol Precursor Biosynthesis
Zhan, Jing-Ru,Shou, Chao,Zheng, Yu-Cong,Chen, Qi,Pan, Jiang,Li, Chun-Xiu,Xu, Jian-He
supporting information, p. 3973 - 3982 (2021/07/02)
Microbial synthesis of (?)-menthol, a compound of plant origin, is of great importance because of the high demand for this product and related sustainability issues. However, the total biosynthesis of (?)-menthol from easily available feedstocks like (?)-limonene by engineered microbial hosts is stalled by the poor protein expression or activity of several enzymes from the native (?)-menthol biosynthesis pathway of mint (Mentha piperita). Among these unsatisfied steps, (?)-isopiperitenol dehydrogenase (IPDH) catalyzed oxidation reaction of (?)-trans-isopiperitenol was one of the bottlenecks that need to be optimized. In this work, two novel bacterial enzymes with IPDH activity were discovered to replace their inefficient counterpart from plant cells in microbial (?)-menthol synthesis. Two key residues in PaIPDH from Pseudomonas aeruginosa were mutated to PaIPDHE95F/Y199V with 4.4-fold improved specific activity than PaIPDH. The mechanism for the beneficial mutations was elucidated by molecular dynamics simulations. PaIPDHE95F/Y199V was used to synthesize (?)-isopiperitenone from (?)-limonene in vivo via a self-sufficient cofactor cascade enzyme reaction, affording a 3.7-fold enhanced titer of (?)-isopiperitenone compared with that obtained using the original mint IPDH (MpIPDH). The bacterial enzyme PaIPDHE95F/Y199V can be applied in the future for constructing a more efficient artificial pathway to biosynthesize (?)-menthol in a microbial whole-cell system. (Figure presented.).
Scalable Aerobic Oxidation of Alcohols Using Catalytic DDQ/HNO3
Arseniyadis, Stellios,Clavier, Louis,Copin, Chloé,Fournier, Jean,Giffard, Jean-Fran?ois,Jean, Alexandre,Katsina, Tania,Macedo Portela Da Silva, Nayane,Tamion, Rodolphe
supporting information, p. 856 - 860 (2020/07/14)
A selective, practical, and scalable aerobic oxidation of alcohols is described that uses catalytic amounts of 2,3-dichloro-5,6-dicyano-1,4-benzoquinone (DDQ) and HNO3, with molecular oxygen serving as the terminal oxidant. The method was successfully applied to the oxidation of a wide range of benzylic, propargylic, and allylic alcohols, including two natural products, namely, carveol and podophyllotoxin. The conditions are also applicable to the selective oxidative deprotection of p-methoxybenzyl ethers.