14985-60-5

Upstream product

• 14790-72-8 zerumbone 
• 108101-44-6 (1S,2S)-1,2-epoxyhumulene 
• 17678-70-5 zerumbol 
• 17678-70-5 Zerumbol 
• 79729-85-4 (5E,9E)-(1S,11S)-1,5,8,8-Tetramethyl-12-oxa-bicyclo[9.1.0]dodeca-5,9-dien-2-one 
• 79729-84-3 (5E,9E)-(1R,2S,11S)-1,5,8,8-Tetramethyl-12-oxa-bicyclo[9.1.0]dodeca-5,9-dien-2-ol 
• 79729-83-2 (2Z,4E,8E)-(S)-2,6,6,9-Tetramethyl-cycloundeca-2,4,8-trienol 

Downstream Products

• 430-19-3 Humulan 
• 14790-73-9 Δ⁶,Δ⁹-di-(Z)-zerumbone 
• 22471-70-1 zerumbone epoxide 

Relevant academic research and scientific papers

Br?nsted acid-induced transannulation of the phytochemical zerumbone

The sesquiterpene zerumbone was treated with HCl in ethyl acetate under the light-protected condition, and the time-dependent conversions were analyzed by gas chromatography. Nine products were isolated, and their structures were revealed by several NMR m

The thia-Michael reactivity of zerumbone and related cross-conjugated dienones: Disentangling stoichiometry, regiochemistry, and addition mode with an NMR-spectroscopy-based cysteamine assay

The cross-conjugated and electrophilic dienone system of the humulane sesquiterpene zerumbone (1a) was modified by E/Z photochemical isomerization and/or by removal of homoconjugation with the isolated endocyclic double bond of the medium-sized ring. The site (C-6/C-9), mode (transient or irreversible), stoichiometry (single or twofold), and comparative rates of thiol addition were evaluated using an NMR-spectroscopy-based cysteamine assay. Dramatic effects were seen, and this highlights the subtleties of the reaction and the limitations of our predictive power in this field. For biological endpoints sensitive to thiol trapping, a substantial separation between Michael reactivity and biological activity was found for 1a and its analogues. This supports the view that shape complementarity plays a critical role in the covalent binding of Michael acceptors to their macromolecular target(s). Using the NMR-spectroscopy-based cysteamine assay, the thia-Michael reactivity of the cross-conjugated dienone zerumbone and its photoisomers and epoxides was investigated, and marked differences were found. For biological endpoints sensitive to Michael acceptors, a substantial separation between reactivity and biological activity was observed.

A short-chain dehydrogenase involved in terpene metabolism from Zingiber zerumbet

The rhizome oil of Zingiber zerumbet Smith contains an exceptionally high content of sesquiterpenoids with zerumbone, a predominating potential multi-anticancer agent. Biosynthetic pathways of zerumbone have been proposed, and two genes ZSS1 and CYP71BA1 that encode the enzymes catalyzing the first two steps have been cloned. In this paper, we isolated a cDNA clone (ZSD1) that encodes an alcohol dehydrogenase capable of catalyzing the final step of zerumbone biosynthesis. ZSD1 has an open reading frame of 804 bp that encodes a 267-residue enzyme with a calculated molecular mass of 28.7 kDa. After expression in Escherichia coli, the recombinant enzyme was found to catalyze 8-hydroxy-α-humulene into zerumbone. ZSD1 is a member of the short-chain dehydrogenase/reductase superfamily (SDR) and shares high identities with other plant SDRs involved in secondary metabolism, stress responses and phytosteroid biosynthesis. In contrast to the transcripts of ZSS1 and CYP71BA1, which are almost exclusively expressed in rhizomes, ZSD1 transcripts are detected in leaves, stems and rhizomes, suggesting that ZSD1 may also be involved in other biological processes. Consistent with its proposed flexible substrate-binding pocket, ZSD1 also converts borneol to camphor with Km and k cat values of 22.8 μm and 4.1 s-1, displaying its bisubstrate feature.

The chemistry of zerumbone. Part 5: Structural transformation of the dimethylamine derivatives

Zerumbone (1) and its 6,7-epoxide (2) react with ammonia and dimethylamine regio- and stereospecifically, affording monoamines 3, 4, 7 and 8. All adducts have the same relative configuration at C2 and C3. The conjugate amination is thermodynamically controlled to arrive at a single diastereomer. At 15°C 7 reacts with cyanide to give aminonitrile 10 as the single product, while at 30°C, acyclic aminonitrile 11 is also formed. The reaction with 8 affords at 0°C bicyclic aminonitrile 12 of the asteriscane skeleton, while at 30°C or higher temperature, mixtures of 12 and tricyclic nitriles 13 and 13′ are obtained. Refluxing of 7, 8 and 10 in aqueous acetonitrile promotes scission of the zerumbone ring by retro-Mannich reaction to provide acyclic aldehydes 16-18, respectively. The dimethylamino group of 7, 8 and 10 is eliminated stereospecifically by Cope- and base-catalyzed eliminations to regenerate the zerumbone skeleton in the products 1, 2 and 21. Cope elimination of 12 results in a mixture of 13 and 13′ by deaminative transannular etherification.

CONVERSION OF HUMULENE TO ZERUMBONE

Humulene was first converted to zerumbone through a sequence of chemical reactions.