The Incorporation of Ciliatine (2-Aminoethylphosphonic Acid) into Lipids of the Rat Liver

Four alcohols, 1-penten-3-ol, n-amylalcohol, trans-2-hexenol and one of the linalool oxides, were newly identified as the components of carbonyl-free neutral fraction of the essential oil of black tea.

On the gas chromatogram of carbonyl fraction three unknown peaks were identified with those of n-valeraldehyde, n-heptanal and trans-2-octenal.

From these results almost all main components of carbonyl and carbonyl free fractions were clarified.

Flavor change during the manufacture of black tea was investigated by gas chromatography. During withering, hexylalcohol, nerol, trans-2-hexenoic acid, trans-2-heхenol, linalool oxide (cis, furanoid), n-valeraldehyde, capronaldehyde, n-heptanal, trans-2-hexenal, trans-2-octenal, benzaldehyde, phenylacetaldehyde, n-butyric, isovaleric, n-caproic, cis-3-hexenoic and salicylic acids and o-cresol were increased, especially the former three greatly increased, while cis-2-pentenol, linalool, geraniol, benzylalcohol, phenylethanol and acetic acid diminished markedly. In the process of fermentation almost all constituents increased, especially, 1-penten-3-ol, cis-2-pentenol, benzylalcohol, trans-2-hexenal, benzaldehyde, n-caproic, cis-3-hexenoic and salicylic acids were remarkable.

On firing, most alcohols, carbonyl and phenolic compounds decreased remarkably whereas acetic, propionic and isobutyric acids greatly increased.     

trans- and cis-Linalool 3,6-Oxide 6-O-β-d-Xylopyranosyl-β-d-glucopyranosides Isolated as Aroma Precursors from Leaves for Oolong Tea

New glycosidic aroma precursors (1 and 2) of the main volatile constituents, trans- and cis-linalool 3,6-oxides (linalool oxides I and II), were isolated from oolong tea leaves (Camellia sinensis var. sinensis cv. Maoxie). The isolation was guided by an enzymatic hydrolysis with acetone powder prepared from fresh tea leaves (cv. Yabukita) followed by GC or GC-MS analyses. Chromatographic purification of hot water extracts of the tea leaves on active charcoal, Amberlite XAD-2, and Sephadex LH-20 columns as well as HPLC gave two new glycosides, trans- and cis-linalool 3,6-oxide 6-O-β-d-xylopyranosyl-β-d-glucopyra-nosides (1 and 2).     

Constituents and Composition of Steam Volatile Aroma from Ceylon Tea

The constituents of steam volatile aroma, which were responsible for topnote of Ceylon tea aroma, were identified. A total of 57 compounds were identified, of which 10 (ter-pinolene, n-nonanal, trans-2-pentenal, trans-3-octen-2-one, 6-methyl-3,5-heptadien-2-one, n-nonanol, cis-3-hexenylbutyrate, cis-3-hexenylcaproate, α-terpinylacetate and nerylacetate) had not previously been reported as associated with aroma of black tea. Approximate composition of topnote aroma from Ceylon flavory tea was also determined.     

Identification des constituants de l'essence des aiguilles de Pinus pinaster

The chromatographic analysis of the volatile leaf oil of Pinus pinaster Ait. showed 42% of monoterpene hydrocarbons (α-pinene, camphene, β-pinene, myrcene, 3-carene, limonene, cis-ocimene, terpinolene, para-cymene, 35% of sesquiterpene hydrocarbons (cubebene, copaene, caryophyllene, humulene, germacrene D, α- and γ-muurolenes, δ- and γ-cadinenes) and 23% of oxygenated compounds including esters (linalyl, bornyl, geranyl, neryl and farnesyl acetates), alcohols (cis-hexenol, linalool, α-fenchol, trans-pinocarveol, terpinen-4-ol, α-terpineol, dihydrocarveol, guaiol, junenol and α-cadinol), one aldehyde (hexenal) and one ketone (piperitone). Three non terpenoid phenylethyl esters were also identified: phenylethyl isovalerate, methyl-2 burtyate and 3-3 dimethylacrylate. Some alcohols and mainly α-terpineol and linalool seemed to be formed during the steam distillation process, they were absent when the leaf oil was obtained by maceration of small portions of leaves in the usual solvents of terpenes.     

Flavor of Black Tea

Intermediate and high boiling neutral compounds in the aroma concentrate from black tea were isolated by fractional distillation, silica-gel column chromatography and gas chromatography.

Identification of the compounds was verified by the agreement of IR and mass spectra as well as gas chromatographic data with those of authentic compounds.

Eleven compounds; α-muurolene, δ-cadinene, furfuryl alcohol, methyl phenyl carbinol, cadinenol, geranial, pyrrole-2-aldehyde, benzyl formate, phenylethyl formate, cis-3-hexenyl benzoate and indole, were newly identified as constituents of black tea aroma and ten known components; α-terpineol, 3, 7-dimethyl-l, 5, 7-octatrien-3-ol, trans, trans-2, 4-decadienal, 2-phenyl-2-butenal, α- and β-ionone, cis-jasmone, theaspirone, lactone of 2-hydroxy-2, 6, 6-trimethylcyclohexylidene-l-acetic acid and phenylacetonitrile were confirmed. The geometric structure of theaspirone in tea aroma was determined as the cis-form.     

Enantiomer Distribution of Major Chiral Volatile Organic Compounds in Selected Types of Herbal Honeys

In this article, volatile organic compounds in 14 honey samples (rosemary, eucalyptus, orange, thyme, sage, and lavender) were identified. Volatile organic compounds were extracted using a solid phase microextraction method followed by gas chromatography connected with mass spectrometry analysis. The studied honey samples were compared based on their volatile organic compounds composition. In total, more than 180 compounds were detected in the studied samples. The detected compounds belong to various chemical classes such as terpenes, alcohols, acids, aldehydes, ketones, esters, norisoprenoids, benzene and furane derivatives, and organic compounds containing sulfur and nitrogen heteroatom. Ten chiral compounds (linalool, trans‐linalool oxide, cis‐linalool oxide, 4‐terpineol, α‐terpineol, hotrienol, and four stereoisomers of lilac aldehydes) were selected for further chiral separation. Chirality 26:670‐674, 2014. © 2014 Wiley Periodicals, Inc.     

Bioorganic Diversity of Rare Coriandrum sativum L. Honey: Unusual Chromatographic Profiles Containing Derivatives of Linalool/Oxygenated Methoxybenzene

The compounds responsible for highly individual aroma profile of Coriandrum sativum L. honey were isolated by headspace solid‐phase microextraction (HS‐SPME; used fibers: A: polydimethylsiloxane (PDMS)/divinylbenzene (DVB) and B: divinylbenzene/carboxen/polydimethylsiloxane), as well as ultrasonic solvent extraction (USE; used solvents: A: pentane/Et₂O 1 : 2 (v/v) and B: CH₂Cl₂) and analyzed by gas chromatography (GC) and mass spectrometry (MS). Unusual chromatographic profiles were obtained containing derivatives of linalool/oxygenated methoxybenzene. trans‐Linalool oxide (11.1%; 14.6%) dominated in the headspace, followed by other linalool derivatives (such as cis/trans‐anhydrolinalool oxide (5.0%; 5.9%), isomers of lilac aldehyde/alcohol (14.9%; 13.8%) or p‐menth‐1‐en‐9‐al (15.6%; 18.5%)), octanal, and several low‐molecular‐weight esters. The major compounds in the solvent extracts were oxygenated methoxybenzene derivatives such as 3,4,5‐trimethoxybenzyl alcohol (26.3%; 24.7%), methyl syringate (23.8%; 11.7%), and 3,4‐dimethoxybenzyl alcohol (5.6%; 13.9%). Another group of abundant compounds in the extracts were derivatives of linalool (e.g., (E)/(Z)‐2,6‐dimethylocta‐2,7‐diene‐1,6‐diol (17.8%; 16.1%)). Among the compounds identified, cis/trans‐anhydrolinalool oxides and 3,4,5‐trimethoxybenzyl alcohol can be useful as chemical markers of coriander honey.     

Formation of cis-3-hexenal,trans-2-hexenal and cis-3-hexenol in macerated Thea sinensis leaves

Thea sinensis; Theaceae; tea; cis-3-hexenal: leaf aldehyde; leaf alcohol; linolenic acid; biosynthesis of leaf alcohol.Linolenic acid and cis-3-hexenal were found in macerated leaves of Thea sinensis and this aldehyde may be produced from linolenic acid by an enzyme contained in macerated leaves in the presence of oxygen. This aldehyde was easily isomerized to trans-2-hexenal, and was converted to cis-3-hexenol by alcohol dehydrogenase. During maceration of freshly picked tea leaves, the amounts of trans-2-hexenal quickly increased and were influenced by maceration time, heating, oxygen and the pH. But in unpicked tea leaves the occurrence of trans-2-hexenal is extremely doubtful.     

Optical Isomers of Linalool and Linalool Oxides in Tea Aroma

The main aroma components of oolong and black tea, linalool and four diastereomers of linalool oxides (LOs), were enantioselectively isolated by capillary gas chromatography, using a column coated with an optically active liquid phase, permethylated β-cyclodextrin.

The R/S ratio varied among linalool and LOs, and among the different types of tea, the ratio for a particular compound also being different. However, the complete patterns of R/S ratio were similar in the semi-fermented and fermented teas, respectively.

Using a specific cultivar of black tea, the R/S ratio for each of the five compounds was compared in the free state in black tea with that of an aglycone of the glycoside in fresh tea leaves or in black tea. While the e.e. values of the compounds varied, those for a specific compound were similar, except for linalool, regardless of their free or combined state.

These results show that LOs are not directly transformed from linalool, but are formed enzymatically from glycoside precursors.     

Seasonal Changes in Activities of Enzymes Responsible for the Formation of C6-aldehydes and C6-alcohols in Tea Leaves, and the Effects of Environmental Temperatures on the Enzyme Activities

When tea leaves were homogenized and incubated, the volatileC₆-compounds hexanal, cis-3-hexenal, cis-3-hexenol and trans-2-hexenalwere formed much more by summer leaves than by winter leavesof tea plants (Camellia sinensis). The enzymes lipolytic acylhydrolase (LAH), lipoxygenase, fatty acid hydroperoxide lyase(HPO lyase) and alcohol dehydrogenase (ADH) and an isomerizationfactor were responsible for the sequential reactions of C₆-compoundformation from linoleic and linolenic acids in tea leaf lipids,and there were seasonal changes in their activities. The tealeaf enzymes were of 3 types: LAH and lipoxygenase, which hadhigh activities in summer leaves and low activities in winterleaves; ADH, which had low activity in summer leaves and highactivity in winter ones; and HPO lyase and the isomerizationfactor, which did not seem to have any effect on the rate ofC₆-compound formation throughout the year. Changes in enzymeactivities were induced by shifts in the environmental air temperaturerather than by the age of the leaves. The combined activitiesof these enzymes determined the amounts and compositions ofthe volatile C₆-compounds formed, which are the factors thatcontrol the quality of the raw leaves processed for green tea. (Received October 6, 1983; Accepted December 20, 1983)     

Flüchtige inhaltsstoffe von Adoxa moschatellina

The flowers of Adoxa moschatellina contain, as volatile constituents, trans-2-hexenal, cis-3-hexenol, trans-2-hexenol, n-hexanol and benzylic alcohol. Fragrance compounds of the musk type could not be detected.     

Linalool and linalool oxide production in transgenic carnation flowers expressing the Clarkia breweri linalool synthase gene

Most modern cut-flower cultivars, including those of carnation(Dianthus caryophyllus), lack distinct fragrance.Carnationcv. Eilat flowers produce and emit various fragrance compounds, includingbenzoic acid derivatives and sesquiterpenes, but not monoterpenes. Based onGC-MS analysis, benzoic acid, benzyl benzoate, phenylethyl benzoate, methylbenzoate, cis-3-hexenyl benzoate and -caryophylleneare the major fragrance compounds, representing ca. 60% of the total volatilesgenerated by these flowers. The level of these compounds increases dramaticallyduring petal development. To evaluate the possibility of producing monoterpenesin carnation cv. Eilat, we generated transgenic plants expressing the linaloolsynthase gene from Clarkia breweri under the regulation ofthe CaMV 35S constitutive promoter. The product of this gene catalyzes theproduction of the monoterpene linalool from geranyl diphosphate. HeadspaceGC-MSanalysis revealed that leaves and flowers of transgenic, but not controlplants,emit linalool and its derivatives, cis- andtrans-linalool oxide. GC-MS analysis of petal extractrevealed the accumulation of trans-linalool oxide but notlinalool. The emission of linalool by the transgenic flowers did not lead todetectable changes in flower scent for human olfaction.     

A Primeverosidase as a Main Glycosidase Concerned with the Alcoholic Aroma Formation in Tea Leaves

We isolated and characterized a primeverosidase from fresh tea leaves (Camellia sinensis var. sinensis cv. Yabukita) as a main glycosidase involved in alcoholic aroma (geraniol, linalool, benzyl alcohol, 2-phenylethanol, linalool oxides etc.) formation from their aroma precursors (β-primeverosides: 6-O-β-D-xylopyranosyl-β-D-glucopyranosides) in tea leaves.     

Seasonal changes in activity of the enzyme system producing cis-3-hexenal and n-hexanal from linolenic and linoleic acids in tea leaves

The enzyme system producing cis-3-hexenal, a precursor of cis-3-hexenol(leaf alcohol) and trans-2-hexenal (leaf aldehyde), from linolenicacid showed high activity in summer and no activity in winterin tea (Thea sinensis) leaves and isolated chloroplasts. Theenzyme system producing n-hexanal from linoleic acid also showedsimilar seasonal changes in activity. These changes were closelyrelated to temperature and solar radiation. Enzyme activitycould not be induced after the leaves had been cut and was notaccompanied by de novo protein synthesis. (Received July 9, 1976; )     

Aroma Components Characteristic of Spring Green Tea

To investigate the aroma components characteristic of spring green tea, analysis of the aroma concentrates of green tea and fresh tea-leaves was accomplished. The research on the changes in aroma constituents of spring green tea and the aroma concentrate from fresh tea-leaves during storage, showed that cis-3-hexenylhexanoate and cis-3-hexenyl-trans-2-hexenoate contributed to the typical fresh aroma of spring green tea. Twelve isomers of hexenol esters were synthesized for comparison of the fresh green note.     

Minor Constituents of Japanese Ho-Leaf Oil

The main component of Japanese Ho-leaf oil has been shown to be (?)-linalool (80~90%), and the following twenty minor constituents newly have been identified; methyl vinyl ketone, methyl isobutyl ketone, mesityl oxide, β-pinene, myrcene, (+)-limonene, cis- and trans-ocimene, n-hexanol, cis-3-hexenol, cis- and trans-linalool oxide, (?)-1-terpinen-4-ol, (+)-cis and (+)-trans-2,6,6-trimethyl-2-vinyl-5-hydroxytetrahydropyran, citronellol, nerol, (+)-β-selinene, (+)-tagetonol and (?)-trans-hotrienol. (+)-Tagetonol and (?)-trans-hotrienol have been demonstrated to be (+)-3,7-dimethyl-3-hydroxy-1-octen-5-one (III) and (3R)-(?)-trans-3,7-dimethyl-3-hydroxy-1,5,7-octatriene (IX), respectively.     

Methyl Jasmonate and Lactones Including Jasmine Lactone in Ceylon Tea

The ester and lactone fraction possessing the most attractive aroma was separated from the aroma concentrate of Ceylon flavory tea by silica-gel column chromatography and analyzed by GC-MS.

Methyl 2-(cis-2′-pentenyl)-cyclopentanone-3-acetate(methyl jasmonate), 5-(cis-2′-pentenyl)-5-pentanolide (jasmine lactone), 2,3-dimethyl-2-nonen-4-olide, 4-octanolide, 4-nonanolide and 5-decanolide were newly identified as the constituents of tes aroma. Former two compounds seemed to carry a major share of aroma character of Ceylon flavory tea.     

Enzyme system catalyzing formation of cis-3-hexenal and n-hexanal from linolenic and linoleic acids in Japanese silver (Farfugium iaponicum Kitamura) leaves

Leaf alcohol (cis-3-hexenol) and leaf aldehyde (trans-2-hexenal)are responsible for the green odor in leaves and fruits. cis-3-Hexenal,a precursor of cis-3-hexenol and trans-2-hexenal, was producedfrom linolenic acid by a homogenate of Farfugium japonicum (Japanesesilver) leaves. n-Hexanal was produced from linoleic acid bya homogenate of the leaves. The enzyme system catalyzing formationof C₆-aldehydes from linolenic and linoleic acids was localizedin chloroplast lamellae, and required oxygen for reaction. C₁₈-unsaturatedfatty acids such as linolenic acid, linoleic acid and -linolenicacid, which have carboxyl groups and cis-1, cis-4-pentadienesystems including a double bond at C-12, acted as substrates,and C₆-aldehydes (cis-3-hexenal or n-hexanal), but not C₉-aldehydes,were produced from them. The properties of the enzyme systemin chloroplasts were as follows: optimal pH 7.0; stable at pH5 to 7; thermolabile and no activity at 50?C. These propertieswere very similar to those of tea chloroplasts. The enzyme systemcould be solubilized from chloroplasts by 2% Triton X-100, butwas very unstable in solubilized form. (Received July 9, 1976; )     

Electroantennogram responses of a parasitic wasp, Microplitis croceipes, to host-related volatile and anthropogenic compounds

The parasitic wasp Microplitis croceipes (Cresson) (Hymenoptera: Braconidae) showed its own characteristic electroantennogram (EAG) response profiles to 13 host‐related (cis‐3‐hexenol, α‐pinene (R)‐(+)‐limonene (S)‐(–)‐limonene, trans‐β‐ocimene (±)‐linalool, (–)‐trans‐caryophyllene, α‐humulene, nerolidol, trans‐nerolidol, cis‐nerolidol, methyl jasmonate and indole) and four anthropogenic (2‐diisopropylaminoethanol, 2,2′‐thiodiethanol, 2‐methyl‐5‐nitroaniline and cyclohexanone) volatile compounds. These profiles were similar between males and females except for 2‐diisopropylaminoethanol, which elicited significantly larger EAG responses in males. Among the compounds tested, cis‐3‐hexenol, linalool and cyclohexanone elicited the largest EAG responses. EAG responses were not influenced by the age of wasps between 1 and 13 days after emergence. EAG responses were dose‐dependent, and highly EAG‐active compounds elicited significant EAG responses with less than 10 μg of the compounds at source. Quantification of compounds released from an odour cartridge indicates that release rate is highly dependent on the chemical nature of stimuli, showing up to 10 000‐fold differences in the amount released between different compounds when the same amount was loaded in the odour cartridge. Wasps having undergone a behavioural training regime to be attracted to either cyclohexanone or methyl jasmonate did not show any differences in EAG responses from those of untrained wasps.