116296-75-4

Upstream product

• 142739-16-0 3-hydroxy-β-ionone 
• 142739-15-9 2-Methyl-2-[(E)-2-(2,6,6-trimethyl-cyclohexa-1,3-dienyl)-vinyl]-[1,3]dioxolane 
• 79-77-6 (E)-β-ionone 
• 14398-35-7 (3E)-4-(2,6,6-trimethylcyclohexa-1,3-dien-1-yl)but-3-en-2-one 
• 84817-80-1 trans-4-bromo-β-ionone 
• 144-68-3 zeaxanthin 
• 127-40-2 lutein 
• 120710-56-7 3-tert-butyldimethylsilyloxy-β-ionone 
• 38963-41-6 (rac)-4-(4-hydroxy-2,6,6-trimethyl-2-cyclohexen-1-yl)-3-buten-2-one 
• 127-41-3 alpha-ionone 
• 14398-37-9 (E)-4-<2',6',6'-trimethylcyclohex-2'-enyl>but-3-en-2-one ethylene ketal 
• 1200125-02-5 (rac)-(E)-4-(4-hydroxy-2,6,6-trimethyl-2-cyclohexen-1-yl)-2,2-ethylenedioxy-3-butene 
• 76739-74-7 (E)-4-((1R,4R)-4-hydroxy-2,6,6-trimethylcyclohex-2-en-1-yl)-but-3-en-2-one 
• 20548-02-1 trans (4R,6R)-4-hydroxy-2,2,6-trimethylcyclohexanone 

Downstream Products

• 120710-56-7 3-tert-butyldimethylsilyloxy-β-ionone 
• 473758-74-6 3-triethylsiloxy-β-ionone 
• 473758-78-0 (2E,4E)-3-Methyl-5-(2,6,6-trimethyl-4-triethylsilanyloxy-cyclohex-1-enyl)-penta-2,4-dienal 
• 473758-81-5 3-hydroxy-all-trans-retinol chloroacetate 
• 473758-79-1 3-triethylsiloxy-all-trans-retinol 
• 473758-73-5 3-triethylsiloxy-all-trans-retinoic acid ethyl ester 
• 473758-80-4 3-triethylsiloxy-all-trans-retinol chloroacetate 
• 50281-38-4 (3R)-3-hydroxy-β-ionone 
• 120674-60-4 ethyl 3-tert-butyldimethylsilyloxy-β-ionylideneacetate 
• 120657-96-7 ethyl 3-tert-butyldimethylsilyloxy-β-ionylideneacetate 
• 54165-55-8 (3R)-3-Acetoxy-β-ionon 

Relevant academic research and scientific papers

Overexpression and Characterization of a Novel Plant Carotenoid Cleavage Dioxygenase 1 from Morus notabilis

Synthesis of β-ionone in microbial cell factories is limited by the efficiency of carotenoid cleavage dioxygenases (CCDs). To obtain genes responsible for specific cleavage of carotenoids generating β-ionone, a novel carotenoid cleavage dioxygenase 1 from Morus notabilis was cloned and overexpressed in Escherichia coli. The MnCCD1 protein was able to cleave a variety of carotenoids at the positions 9, 10 (9′, 10′) to produce β-ionone, 3-hydroxy-4-oxo-β-ionone, 3-hydroxy-β-ionone, and 3-hydroxy-α-ionone in vitro. MnCCD1 could also cleave lycopene and β-carotene at the 9, 10 (9′, 10′) bind bond to produce pseudoionone and β-ionone, respectively, in E. coli accumulating carotenoids. The enzyme activity of MnCCD1 was reached 2.98 U/mL at optimized conditions (temperature 28 °C, IPTG 0.1 mM, induction time 24 h). The biochemical characterization of MnCCD1 revealed the optimal activities were at pH 8.4 and 35 °C. The addition of 10 % ethanol could increase enzyme activity at above 15 %. However, an obvious decline was observed on enzyme activity as the concentration of Fe2+ increased (0–1 mM). The Vmax for β-apo-8′-carotenal was 72.5 U/mg, while the Km was 0.83 mM. The results provide a foundation for developing the application of carotenoid cleavage dioxygenases as biocatalysis and synthetic biology platforms to produce volatile aroma components from carotenoids.

Identification of Apocarotenoids as Chemical Markers of in Vitro Anti-Inflammatory Activity for Spirulina Supplements

Identification of chemical markers in food additives and dietary supplements is crucial for quantitative assessment and standardization of their quality and efficacy. Arthrospira platensis, formerly Spirulina platensis and known colloquially as spirulina,

Selective oxygenation of ionones and damascones by fungal peroxygenases

Apocarotenoids are among the most highly valued fragrance constituents, being also appreciated as synthetic building blocks. This work shows the ability of unspecific peroxygenases (UPOs, EC1.11.2.1) from several fungi, some of them being described recently, to catalyze the oxyfunctionalization of α- and β-ionones and α- and β-damascones. Enzymatic reactions yielded oxygenated products such as hydroxy, oxo, carboxy, and epoxy derivatives that are interesting compounds for the flavor and fragrance and pharmaceutical industries. Although variable regioselectivity was observed depending on the substrate and enzyme, oxygenation was preferentially produced at the allylic position in the ring, being especially evident in the reaction with α-ionone, forming 3-hydroxy-α-ionone and/or 3-oxo-α-ionone. Noteworthy were the reactions with damascones, in the course of which some UPOs oxygenated the terminal position of the side chain, forming oxygenated derivatives (i.e., the corresponding alcohol, aldehyde, and carboxylic acid) at C-10, which were predominant in the Agrocybe aegerita UPO reactions, and first reported here.

The Oxidation of Hydrophobic Aromatic Substrates by Using a Variant of the P450 Monooxygenase CYP101B1

The cytochrome P450 monooxygenase CYP101B1, from a Novosphingobium bacterium is able to bind and oxidise aromatic substrates but at a lower activity and efficiency than norisoprenoids and monoterpenoid esters. Histidine 85 of CYP101B1 aligns with tyrosine 96 of CYP101A1, which, in the latter enzyme forms the only hydrophilic interaction with its substrate, camphor. The histidine residue of CYP101B1 was mutated to phenylalanine with the aim of improving the activity of the enzyme for hydrophobic substrates. The H85F mutant lowered the binding affinity and activity of the enzyme for β-ionone and altered the oxidation selectivity. This variant also showed enhanced affinity and activity towards alkylbenzenes, styrenes and methylnaphthalenes. For example the rate of product formation for acenaphthene oxidation was improved sixfold to 245 nmol per nmol CYP per min. Certain disubstituted naphthalenes and substrates, such as phenylcyclohexane and biphenyls, were oxidised with lower activity by the H85F variant. Variants at H85 (A and G) designed to introduce additional space into the active site so as to accommodate these larger substrates did not improve the oxidation activity. As the H85F mutant of CYP101B1 improved the oxidation of hydrophobic substrates, this residue is likely to be in the substrate binding pocket or the access channel of the enzyme. The side chain of the histidine might interact with the carbonyl groups of the favoured norisoprenoid substrates of CYP101B1.

Synthesis and characterization of quantum dot nanoparticles bound to the plant volatile precursor of hydroxy-apo-10′-carotenal

This study is focused on the synthesis and characterization of hydroxy-apo-10′-carotenal/quantum dot (QD) conjugates aiming at the in vivo visualization of β-ionone, a carotenoid-derived volatile compound known for its important contribution to the flavor and aroma of many fruits, vegetables, and plants. The synthesis of nanoparticles bound to plant volatile precursors was achieved via coupling reaction of the QD to C27- aldehyde which was prepared from α-ionone via 12 steps in 2.4% overall yield. The formation of the QD-conjugate was confirmed by measuring its fluorescence spectrum to observe the occurrence of fluorescence resonance energy transfer.

Unusually Broad Substrate Profile of Self-Sufficient Cytochrome P450 Monooxygenase CYP116B4 from Labrenzia aggregata

A new member of the CYP116B subfamily - P450LaMO - was discovered in Labrenzia aggregata by genomic data mining. It was successfully overexpressed in Escherichia coli, purified, and subsequently characterized spectroscopically, and its catalytic properties were assessed. Substrate profiling of the P450LaMO revealed that it was a versatile catalyst, exhibiting hydroxylation and epoxidation activities as well as O-dealkylation and asymmetric sulfoxidation activities. Diverse compounds, including alkylbenzenes, aromatic bicyclic molecules, and terpenoids, were shown to be hydroxylated by P450LaMO. Such diverse catalytic activities are uncommon for the bacterial P450s, and the P450LaMO -mediated stereoselective hydroxylation of inactivated C - H bonds - ubiquitous and relatively unreactive in organic molecules - is particularly unusual. The self-sufficient nature of P450LaMO, coupled with its broad substrate range, highlights it as an ideal template for directed evolution towards various applications.

Total synthesis of (±)-3-hydroxy-β-ionone through a ring-closing enyne metathesis

The total synthesis of (±)-3-hydroxy - ionone, a bisnor-sesquiterpene having allelopathic activity, has been accomplished employing an enyne metathesis for the construction of the C1-C8 segment and two-carbon elongation via a nitrile oxide-alkene [3+2] cycloaddition as the key steps. Georg Thieme Verlag Stuttgart · New York.

Process or synthesis of (3S)- and (3R)-3-hydroxy-beta-ionone, and their transformation to zeaxanthin and beta-cryptoxanthin

Disclosed is a process for the synthesis of (3R)-3-hydroxy-β-ionone and its (3S)-enantiomer in high optical purity from commercially available (rac)-α-ionone. The key intermediate for the synthesis of these hydroxyionones is 3-keto-α-ionone ketal that was prepared from (rac)-α-ionone after protection of this ketone as a 1,3-dioxolane. Reduction of 3-keto-α-ionone ketal followed by deprotection, lead to 3-hydroxy-α-ionone that was transformed into (rac)-3-hydrox-β-ionone by base-catalyzed double bond isomerization in 46% overall yield from (rac)-α-ionone. The racemic mixture of these hydroxyionones was then resolved by enzyme-mediated acylation in 96% ee. (3R)-3-Hydroxy-β-ionone and its (3S)-enantiomer were respectively transformed to (3R)-3-hydroxy-(β-ionylideneethyl)triphenylphosphonium chloride [(3R)-C15-Wittig salt] and its (3S)-enantiomer [(3S)-C15-Wittig salt] according to known procedures. Double Wittig condensation of these Wittig salts with commercial available 2,5- dimethtylocta-2,4,6-triene-1,8-dial provided all 3 stereoisomers of zeaxanthin. Similarly, (3R)-C15-Wittig and its (3S)-enantiomer were each coupled with β-apo-12′-carotenal.

Structural analysis of CYP101C1 from Novosphingobium aromaticivorans DSM12444

CYP101C1 from Novosphingobium aromaticivorans DSM12444 is a homologue of CYP101D1 and CYP101D2 enzymes from the same bacterium and CYP101A1 from Pseudomonas putida. CYP101C1 does not bind camphor but is capable of binding and hydroxylating ionone derivatives including α- and β-ionone and β-damascone. The activity of CYP101C1 was highest with β-damascone (kcat=86 s-1) but α-ionone oxidation was the most regioselective (98% at C3). The crystal structures of hexane-2,5-diol- and β-ionone-bound CYP101C1 have been solved; both have open conformations and the hexanediol-bound form has a clear access channel from the heme to the bulk solvent. The entrance of this channel is blocked when β-ionone binds to the enzyme. The heme moiety of CYP101C1 is in a significantly different environment compared to the other structurally characterised CYP101 enzymes. The likely ferredoxin binding site on the proximal face of CYP101C1 has a different topology but a similar overall positive charge compared to CYP101D1 and CYP101D2, all of which accept electrons from the ArR/Arx class I electron transfer system.Crystal clear: CYP101C1 oxidises ionone derivatives fast (kcat≤86 s-1) and with high regioselectivity (≤98%). Its crystal structure (shown) provides structural insights into how this enzyme differs from those that bind camphor from the same CYP family, and further information on how open conformations of CYP enzymes are involved in substrate entry and binding.

Synthesis of (3S)- and (3R)-3-hydroxy-β-ionone and their transformation into (3S)- and (3R)-β- cryptoxanthin

(3S)- and (3R)-3-Hydroxy-β-ionone and (3S)- and (3R)-3-Hydroxy-β- ionone synthesized in high enantiomeric purity from commercially available () - ionone. These ionones were then transformed into (3R) - cryptoxanthin and (3S) - cryptoxanthin by a C15+C10+C15 Wittig coupling strategy according to known methods. This methodology can considerably simplify the total synthesis of optically active carotenoids with 3-hydroxy - end groups that possess significant biological activities. Georg Thieme Verlag Stuttgart New York.