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.     

Biosynthesis of trans-2-hexenal in chloroplasts from Thea sinensis

The biosynthetic pathway of trans-2-hexenal, leaf aldehyde, in isolated chloroplasts of Thea sinensis leaves. was examined using a tracer experiment. A high and specific incorporation of radioactivity into cis-3-hexenal and trans-2-hexenal, was observed when linolenic acid-[U-¹⁴C] was incubated with the isolated chloroplasts. Thus, trans-2-hexenal was biosynthesized via cis-3-hexenal from linolenic acid in the chloroplasts.     

Seasonal variations in trans-2-hexenal and linolenic acid in homogenates of Thea sinensis leaves

The seasonal variations in the amounts of C₆-volatile components cis-3-hexenal trans-2-hexenal n-hexanal) and their precursors (linoleic and linolenic acid) in homogenates of Thea sinensis leaves were quantitatively analyzed throughout the year. Formation of trans-2-hexenal began in the middle of April and reached a maximum during July. Towards autumn the aldehyde gradually decreased and, in winter (December to March), was virtually absent. The levels of cis-3-hexenol remained constant during May–December. cis-3-Hexenal showed a similar variation pattern to that of trans-2-hexenal. The major fatty acids in the leaves were palmitic, palmitoleic, oleic, linoleic and linolenic acid, and occurred in non-ionic lipids and phospholipid fractions. The amounts of linoleic and linolenic acid did not show any marked variation except for a big peak in October.     

Formation of 12-oxo-trans-10-dodecenoic acid in chloroplasts from Thea sinensis leaves

Linolenic acid-[1-¹⁴C] was converted to 12-oxo-trans-10-dodecenoic acid, via 12-oxo-cis-9-dodecenoic acid by incubation with chloroplasts of Thea sinensis leaves. Thus, it was confirmed that linolenic acid is split into a C₁₂-oxo-acid, 12-oxo-trans-10-dodecenoic acid, and a C₆-aldehyde, trans-2-hexenal, leaf aldehyde, by an enzyme system in chloroplasts of tea leaves.     

Biosynthesis of Leaf Alcohol Formation of 3Z-Hexenal from Linolenic Acid in Chloroplasts of Thea sinensis Leaves

The synthetic activity for 3Z-hexenal, an important precursor of 3Z-hexenol (leaf alcohol), was localized in chloroplasts of Thea sinensis leaves. 3Z-Hexenal, which is easily isomerized to 2E-hexenal (leaf aldehyde), was formed from linolenic acid in the presence of oxygen. 13-l-Hydroperoxy-linolenic acid also served as a precursor, but the triglyceride and methyl ester of linolenic acid did not. This enzyme system appeared to be tightly bound to the lamellae membranes of chloroplasts.     

Enzymic oxidation of linolenate by Ginkgo leaves: Fractionation and characterization of active fractions

An aqueous extract of defatted, macerated leaves of Ginkgo biloba L. catalysed the oxidation of linolenate. Extracts prepared from quickly frozen Ginkgo leaves had almost the same activity as the extract from fresh leaves but no trans-2-hexenal was formed. The activity was surprisingly stable at 100° and to acids. However, at pH 12 a marked loss of activity was observed, particularly when the soln was heated, and Pronase, also destroyed most of the activity.     

Enzymic formation of carbonyls from linoleic acid in leaves of Phaseolus vulgaris

Homogenization of Phaseolus vulgaris leaves at acid pH results in the evolution of hexanal, cis-3- and trans-2-hexenal. With cell-free extracts of leaves, linoleic and linolenic acids are enzymically converted to their hydroperoxides (predominantly the 13-hydroperoxide isomers) and to hexanal or hexenal respectively. Activity was highest in young, dark-green leaves and was stimulated by Triton X-100. Oleic acid is not a substrate for these reactions. Both 9- and 13-hydroperoxides were cleaved to carbonyl fragments and are proposed as intermediates in the formation of volatile aldehydes and non-volatile ω-oxoacids in P. vulgaris leaves. Properties of the enzyme systems are described.     

Ripening‐induced acceleration of volatile aldehyde generation following tissue disruption in tomato fruit

Hexanal and cis-3-hexenal are principal flavor volatiles in ripe tomato fruit, but whether they accumulate during ripening or are formed upon maceration of the tissue has not been clarified. This has been addressed by measuring levels of these aldehydes in green and ripe fruit with discrimination between intrinsic aldehyde content and aldehyde generation following tissue disruption. Volatile sampling of tomato fruit homogenates was accomplished by purge/trapping, followed by thermal desorption on a gas chromatograph equipped with a mass selective detector. Incubation of some samples with alcohol dehydrogenase to convert the aldehydes to their respective alcohols permitted positive identification of the isomeric form of hexenal as cis-3-hexenal. Red and green tomato fruit homogenized in buffer with saturated CaCl₂ contained low (0.1-0.8 µg g^?1 fresh weight) levels of hexanal and cis-3-hexenal; thus there is minimal endogenous volatile content in intact fruit. Volatile levels increased rapidly, up to 10-fold, following homogenization of ripe tomato fruit in the absence of CaCl₂, and more modestly in corresponding green tomato fruit homogenates. Incubation with the appropriate lipoxygenase/hydroperoxide lyase substrate (linoleic acid for hexanal, linolenic acid for cis-3-hexenal) doubled the amount of volatile compound produced. Hexanal generation was suppressed in the presence of linolenic acid, suggesting that the enzyme complex has greater affinity for this substrate. As well, levels of cis-3-hexenal, but not hexanal, tended to decline within 30 min of homogenization, possibly reflecting a specific degradative process. The results collectively indicate that the contribution of six-carbon aldehydes to tomato fruit flavor is attributable to metabolism invoked following tissue disruption rather than within the intact fruit.     

Production of volatiles by degradation of lipids during manufacture of black tea

During manufacture of black tea, lipids are degraded to volatile constituents. Cis-3-hexenal was present in appreciable amounts in the various parts of fresh shoots and decreased in the second leaves during manufacture. There was a simultaneous increase in trans-2-hexenal. Linalol and methyl salicylate also increased appreciably during rolling and fermentation. Most of the volatiles were lost during the firing process. The above trend was borne out by the ‘potential’ of the leaves for the production of volatiles as indicated by the increased amounts of volatiles produced by homogenizing the tissue in water against controls homogenized in 0.1 N acid. The C₆-aldehydes present in the headspace of withered shoots increased significantly following mechanical damage. The major fatty acids of the lipids in the various parts of the shoots were linolenic, linoleic, palmitic, oleic and stearic acids. The ratio of linoleic to linolenic acid in the stems was much higher than that of the leaves or buds and this was reflected in its higher 'potential for formation of hexanal. During withering and rolling of the second leaves, the unsaturated fatty acids showed substantial losses compared with the saturated acids. It is suggested that the enzymic breakdown of membrane lipids initiate the formation of volatile carbonyl compounds which are partly responsible for the flavour of black tea.     

Metabolism of linolenic acid in a cold sensitive (Penjamo 62) and a cold resistant (Miranovskaja 808) wheat cultivar

Formation of linolenic acid in vivo from various precursors [1-¹⁴C]-2:0, -12:0, -16: 0, -18:0, -18:1, 18:2 in the cold resistant wheat cultivar Miranovskaja 808 and cold sensitive wheat cultivar Penjamo 62 was investigated at three different temperatures (+25, +5, and ?6 °C). Both cultivars converted the offered precursors to linolenic acid only very slowly. Decreasing the experimental temperature brought about an increase formation of linolenic acid, however, Miranovskaja 808 being more successful than Penjamo 62. Comparison of the specific activities of linolenic acid at the “time of equal level of tissue labeling” revealed that Miranovskaja 808 formed 2 to 10 times faster linolenic acid from various precursors upon exposure to cold than Penjamo 62. Considering the low rate of formation of linolenic acid in leaves it appears probable that even the cold resistant cultivars are unable to increase the proportion of linolenic acid in their membranes fast enough to prevent the thermotropic phase transition from liquid crystalline to solid gel state at beginning of the onset of cold. It is suggested that rapid accumulation of hitherto unknown cryoprotective substance (s) of lipidic nature precedes the accumulation of linolenic acid upon exposure of the seedlings to chilling temperatures.     

The importance of linoleic acid and linolenic acid as precursors of hexanal and trans-2-hexenal in black tea

During tea fermentation, linoleic acid in the neutral fat fraction,and linolenic acid in both the neutral fat and phospholipidfractions from leaves decreased. The addition of linoleic orlinolenic acid to leaf macerates during fermentation resultedin an increase in hexanal or trans-2-hexenal in the volatilefraction. Tracer experiments showed the direct conversion oflinoleic-U-¹⁴C and linolenic-U-¹⁴C acids to labeled hexanaland trans-2-hexenal, respectively, which were identified as2,4-DNPH derivatives. Further conversion of hexanal and trans-2-hexenal into hexanoicand trans-2-hexenoic acids during tea fermentation was suggestedby the increases in these compounds after the addition of hexanaland trans-2-hexenal to leaf macerates. (Received December 21, 1971; )     

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; )     

Flavour biogenesis. Partial purification and properties of a fatty acid hydroperoxide cleaving enzyme from fruits of cucumber

A membrane-bound enzyme, which catalyses the cleavage of fatty acid hydroperoxides to carbonyl fragments, has been partially purified from cucumber fruit. The isomeric 9- and 13-hydroperoxydienes (but not the hydroxydienes) derived from both linoleic and linolenic acids are cleaved by the enzyme but a mixture of 9- and 10-hydroperoxymonoenoic derivatives of oleic acid was not attacked. No evidence was obtained for free intermediates between fatty acid hydroperoxides and the cleavage products. Major volatile products were: cis-3-nonenal and hexanal (from 9- and 13-hydroperoxides of linoleic acid respectively) or cis-3,cis-6-nonadienal and cis-3-hexenal (from 9- and 13-hydroperoxides of linolenic acid). The increase in the ratio of cis-3- to trans-2-enal products with enzyme purification indicated that cis-3-enals are the immediate cleavage products and that the trans-2- forms are produced by subsequent isomerization.     

Sugar beet leaves as new source of hydroperoxide lyase in a bioprocess producing green-note aldehydes

Hydroperoxide lyase activity was found in sugar beet leaves. Its optimum pH and temperature were, respectively, 6.7 and 22°C. Under these conditions, conversion of linolenic acid 13-hydroperoxide to cis-3-hexenal with a maximum yield of 80% was reached after only 2 min. The stability of cis-3-hexenal was improved by acidifying the reaction medium. Based on these studies, a bioprocess producing green-note aldehydes in a laboratory-scale was achieved. The authors Holy N. Rabetafika and Cédric Gigot contributed equally.     

Gallic acid as a natural inhibitor of flowering in Kalanchoe blossfeldiana

Gallic acid (I) has been isolated as a specific flowering-inhibitory substance from leaves of vegetative Kalanchoe blossfeldiana. It is also present in leaves of flowering Kalanchoe, apparently in an inactive, non-dialysable form. Gallic acid acts as a flowering inhibitor when applied to Kalanchoe, a short-day plant. Its detection and isolation was facilitated by use of a bioassay based on tissue culture of partially induced apices of the long-day plant Viscaria candida.     

Gymnosperm B-sister genes may be involved in ovule/seed development and,in some species,in the growth of fleshy fruit-like structures

Background and Aims

The evolution of seeds together with the mechanisms related to their dispersal into the environment represented a turning point in the evolution of plants. Seeds are produced by gymnosperms and angiosperms but only the latter have an ovary to be transformed into a fruit. Yet some gymnosperms produce fleshy structures attractive to animals, thus behaving like fruits from a functional point of view. The aim of this work is to increase our knowledge of possible mechanisms common to the development of both gymnosperm and angiosperm fruits.

Methods

B-sister genes from two gymnosperms (Ginkgo biloba and Taxus baccata) were isolated and studied. The Ginkgo gene was also functionally characterized by ectopically expressing it in tobacco.

Key Results

In Ginkgo the fleshy structure derives from the outer seed integument and the B-sister gene is involved in its growth. In Taxus the fleshy structure is formed de novo as an outgrowth of the ovule peduncle, and the B-sister gene is not involved in this growth. In transgenic tobacco the Ginkgo gene has a positive role in tissue growth and confirms its importance in ovule/seed development.

Conclusions

This study suggests that B-sister genes have a main function in ovule/seed development and a subsidiary role in the formation of fleshy fruit-like structures when the latter have an ovular origin, as occurs in Ginkgo. Thus, the ‘fruit function’ of B-sister genes is quite old, already being present in Gymnosperms as ancient as Ginkgoales, and is also present in Angiosperms where a B-sister gene has been shown to be involved in the formation of the Arabidopsis fruit.     

Biosynthese de l'acide linolenique dans la feuille de pois

During the development of pea seedlings in complete darkness or under a short-day photoperiod, the capacity of linolenic acid biosynthesis reaches a maximum about 7 days after germination. At all stages of development the light markedly and specifically increases the incorporation of 1-¹⁴C-acetate into the linolenic acid, causing a 20-fold increase in the labelling at the maximum as compared with dark incubation. The evolution of the capacity of linolenic acid biosynthesis in leaves follows strictly the ability to produce chlorophyll under light. First analysis shows that the linolenic acid biosynthesis observed occurs specifically into the galactolipids.     

Lipoxygenase-mediated cleavage of fatty acids to carbonyl fragments in tomato fruits

Homogenates of tomato fruits catalysed the enzymic conversion of linoleic and linolenic acids (but not oleic acid) to C₆ aldehydes in low (3–5%) molar yield. Hexanal was formed from linoleic acid; cis-3-hexenal and smaller amounts of trans-2-hexenal were formed from linolenic acid. With the fatty acids as substrates, the major products were fatty acid hydroperoxides (50–80% yield) and the ratio of 9- to 13-hydroperoxides as isolated from an incubation with linoleic acid was at least 95:5 in favour of the 9-hydroperoxide isomer. When the 9- and 13-hydroperoxides of linoleic acid were used as substrates with tomato homogenates, the 13-hydroperoxide was readily cleaved to hexanal in high molar yield (60%) but the 9-hydroperoxide isomer was not converted to cleavage products. Properties of the hydroperoxide cleavage system are described. The results indicate that the C₆ aldehydes are formed from C₁₈ polyunsaturated fatty acids in a sequential enzyme system involving lipoxygenase (which preferentially oxygenates at the 9-position) followed by a hydroperoxide cleavage system which is, however, specific for the 13-hydroperoxy isomers.     

Volatile C6-Aldehyde Formation via Hydroperoxides from C18-Unsaturated Fatty Acids in Etiolated Alfalfa and Cucumber Seedlings

1. Etiolated seedlings of alfalfa and cucumber evolved n-hexanal from linoleic acid and cis-3-hexenal and trans-2-hexenal from linolenic acid when they were homogenized.

2. The activities for n-hexanal formation from linoleic acid, lipoxygenase and hydro-peroxide lyase were maximum in dry seeds and 1~2 day-old etiolated seedlings of alfalfa, and in 6~7 day-old etiolated seedlings of cucumber.

3. n-Hexanal was produced from linoleic acid and 13-hydroperoxylinoleic acid by the crude extracts of etiolated alfalfa and cucumber seedlings. cis-3-Hexenal and trans-2-hexenal were produced from linolenic acid and 13-hydroperoxylinolenic acid by the crude extracts of etiolated alfalfa and cucumber seedlings. But these extracts, particulariy cucumber one, showed a high isomerizing activity from cis-3-hexenal to trans-2-hexenal.

4. When the C₈-aldehydes were produced from linoleic acid and linolenic acid by the crude extracts, formation of hydroperoxides of these C₁₈-fatty acids was observed.

5. When 9-hydroperoxylinoleic acid was used as a substrate, trans-2-nonenal was produced by the cucumber homogenate but not by the alfalfa homogenate.

6. As the enzymes concerned with C₆-aldehyde formation, lipoxygenase was partially purified from alfalfa and cucumber seedlings and hydroperoxide lyase, from cucumber seedlings. Lipoxygenase was found in a soluble fraction, but hydroperoxide lyase was in a membrane bound form. Alfalfa lipoxygenase catalyzed formation of 9- and 13-hydroperoxylinoleic acid (35: 65) from linoleic acid and cucumber one, mainly 13-hydroperoxylinoleic acid formation. Alfalfa hydroperoxide lyase catalyzed n-hexanal formation from 13-hydroperoxylinoleic acid, but cucumber one catalyzed formation of n-hexanal and trans-2-nonenal from 13- and 9-hydroperoxylinoleic acid, respectively.

7. From the above results, the biosynthetic pathway for C₆-aldehyde formation in etiolated alfalfa and cucumber seedlings is established that C₆-aldehydes (n-hexanal, cis-3-hexenal and trans-2-hexenal) are produced from linoleic acid and linolenic acid via their 13-hydroperoxides by lipoxygenase and hydroperoxide lyase.     

Drought stress increases the production of 5-hydroxynorvaline in two C4 grasses

Plants produce various compounds in response to water deficit. Here, the presence and identification of a drought-inducible non-protein amino acid in the leaves of two C₄ grasses is first reported. The soluble amino acids extracted from the leaves of three different species were measured by high-performance liquid chromatography of derivatives formed with o-phthaldialdehyde and β-mercaptoethanol. One amino acid that increased in amount with drought stress had a retention time not corresponding to any common amino acid. Its identity was determined by metabolite profiling, using ¹H NMR and GC-MS. This unusual amino acid was present in the dehydrated leaves of Cynodon dactylon (L.) Pers. and Zoysia japonica Steudel, but was absent from Paspalum dilatatum Poir. Its identity as 2-amino-5-hydroxypentanoic acid (5-hydroxynorvaline, 5-HNV) was confirmed by synthesis and co-chromatography of synthetic and naturally occurring compounds. The amount of 5-HNV in leaves of the more drought tolerant C₄ grasses, C. dactylon and Z. japonica, increased with increasing water deficit; therefore, any benefits from this unusual non-protein amino acid for drought resistance should be further explored.