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(Last modification: 13. May 2010)

Proposal for STS-type Reaction: Anacardic Acids and Urushiols

Anacardiaceae: An excellent overview of the secondary compounds in this family can be found here: more...

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• A few examples of plant containing these compounds

• A proposal for their biosynthesis

• References

• Link to a few pictures

     Well-known, at least to the Americans, are probably the urushiols: they are the main reason for the strong allergenic properties of poison ivy (Rhus radicans, Toxidodendron radicans), poison oak (Rhus toxidodendron), poison alder (Rhus vernix), and other plants of the family Anacardiaceae. They were also described very early (Symes and Dawson, 1954) because of the medical importance. According to the summary in the Wikipedia entry (Urushiol), urushiol is a mixture of several closely related organic compounds. Each consists of a catechol, i.e. an aromatic ring of 6 carbon atoms with attachment of two neighboring hydroxyl groups, and a side chain that has 15 or 17 carbon atoms. The side chain may be saturated or unsaturated, and the exact mixture depends on the plant species. For example, poison oak urushiol contains mostly catechols with C₁₇ side chains, but poison ivy and poison sumac contain mostly catechols with C₁₅ side chains. The allergic potential is dependent on the degree of unsaturation of the alkyl chain. Less than half of the general population reacts with the saturated urushiol alone, but over 90% react with urushiol containing at least two double bonds. Wikipedia also provides an overview of the allergenic effects and their treatments (Urushiol-induced contact dermatitis).

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The principle of the biosynthesis: a proposal

   From all the previously published data on the biosynthesis, it is very likely that anacardic acids, urushiol, and the other compounds are derived from the same biosynthetic pathway. The key reaction should be a polyketide synthase reaction, with a long-chain acyl-CoA as substrate (the length and degree of saturation are variable), three condensation reactions, followed by an aldol condensation. These are the basics; in addition to that, tailoring reactions are included, e.g. decarboxylations, reduction steps, hydroxylations; these lead to the variations in the compounds.

The biosynthetic scheme:

Actually, almost all of the reactions proposed here are known to be carried out by type III PKS in other plants. A few comments: 

• Anacardic acids
  - the biosynthesis corresponds to the reactions of the stilbenecarboxylate synthases in Hydrangea macrophylla, including the reduction step (more...) that has to be postulated (more...),  

• Cardanols
  - their formation, including the reduction step  (more...), corresponds to the sequence of the reactions in the biosynthesis of lunularin in the liverwort Marchantia polymorpha: the type III PKS reaction to prelunularic acid, aromatization to lunularic acid, and decarboxylation to lunularin (more...).

• Resorcylic acids
  - that should be just about the same as that postulated for the biosynthesis of olivetolic acid in Cannabis sativa (more...), which also uses an aliphatic starter CoA-ester (hexanoyl-CoA).

• Resorcinols
  - that is the standard stilbene synthase reaction (more...). Actually, with the long-chain acyl-CoAs as starters, it is exactly the reaction carried out by the type III PKS in the biosynthesis of sorgoleone in Sorghum bicolor (more...), and by the orphan PKS in Physcomitrella patens (more...). In the case of the resorcinols discussed here (the cardols) it is not known, however, whether the decarboxylation is integrated in the overall reaction mechanism, and it cannot be excluded at this point that the resorcylic acid is a detectable precursor. There is at least one example with contradictory results (an enzyme from Neurospora crassa), and interestingly, this is a case of a type III PKS using long-chain acyl-CoAs as substrate: one group found resorcinols as product, while another group detected resorcylic acids as major products (more...).

• Urushiols: it seems pretty obvious that anacardic acids are the biosynthetic precursors, but the sequence of the reactions to the urushiols (a decarboxylation and a hydroxlation) is unknown.

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Direct links to other enzymes with aldol condensations

• Biphenyl synthase (BIS) from Sorbus aucuparia 

• Alkylresorcinol synthase in Sorghum bicolor: Sorgoleone biosynthesis

• MPBD (4-Methyl-5-Pentylbenzene-1,3-diol, "Steely 1") in Dictyostelium discoideum
• An 'Orphan Type III PKS': Alkylresorcinol / Alkylpyrone Synthase from Physcomitrella patens

• Proposals:
  - This page: Anacardic Acids (carboxylated product!) and Urushiols
  - Olivetolic Acid (carboxylated product!) and Bibenzyls
  - Bis-5-Alkylresorcinols

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Other type III PKS with substrate preferences for long-chain CoA-esters in plants and bacteria

• Alkylpyrones und alkylresorcinols in the moss Physcomitrella patens: more...

• Pyrone biosynthesis in A. thaliana: more...

• Alkylresorcinols and long-chain pyrones in the bacterium Azotobacter vinelandii: more...

• Alkylresorcinol biosynthesis in the bacterium Streptomyces griseus: more...         

• Pyrone synthases in the bacteria Mycobacterium tuberculosis and Bacillus subtilis: more...

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References

• Ginkgo biloba (2000), Series: Medicinal and Aromatic Plants - Industrial Profiles, Vol 12. Editor: Van Beek, T.A.; Publisher: Harwood Academic Publishers.
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• Adawadkar, P. D., El Sohly, M. A., 1981. Isolation, purification and antimicrobial activity of anacardic acids from Ginkgo biloba fruits. Fitoterapia 53, 129-135.
  No Abstract.
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• Austin, M. B., Bowman, M. E., Ferrer, J.-L., Schröder, J., Noel, J. P., 2004. An aldol switch discovered in stilbene synthases mediates cyclization specificity of type III polyketide synthases. Chemistry & Biology 11, 1179-1194.
       Stilbene synthase (STS) and chalcone synthase (CHS) each catalyze the formation of a tetraketide intermediate from a CoA-tethered phenylpropanoid starter and three molecules of malonyl-CoA, but use different cyclization mechanisms to produce distinct chemical scaffolds for a variety of plant natural products. Here we present the first STS crystal structure, and identify, by mutagenic conversion of alfalfa CHS into a functional stilbene synthase, the structural basis for the evolution of STS cyclization specificity in type III polyketide synthase (PKS) enzymes. Additional mutagenesis and enzymatic characterization confirms that electronic effects rather than steric factors balance competing cyclization specificities in CHS and STS. Finally, we discuss the problematic in vitro reconstitution of plant stilbenecarboxylate pathways, using insights from existing biomimetic polyketide cyclization studies to generate a novel mechanistic hypothesis to explain stilbenecarboxylate biosynthesis.
  Request a reprint
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• Dewick, P. M., 1997.  Medicinal Natural Products - A Biosynthetic Approach. John Wiley & Sons,  Chichester.
  No Abstract.
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• Gellerman, J. L., Anderson, W. H., Schlenk, H., 1976. Synthesis of anacardic acids in seeds of Ginkgo biloba. Biochimica et Biophysica Acta 431, 16-21.
  Anacardic (6-alkylsalicylic) acids and common lipids are efficiently synthesized by immature seeds of Ginkgo biloba. The seeds were incubated with 14C-labeled acetic, malonic and palmitoleic acids, glucose, and other potential precursors. Levels of 14C in common lipids and in anacardic acids, and the distribution of 14C in anacardic acids were determined. The results show that the salicylic moiety is synthesized by a polyketide pathway via malonic acid. The chain moiety for anacardic acid synthesis is in a different state of activation and/or site than chains that are used for synthesis of the common lipids. Labeled shikimic acid did not contribute 14C to anacardic acids, nor to other lipids, and palmitoleic acid was incorporated only into common lipids.
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• Grazzini, R. A., Paul, P. R., Hage, T., Cox-Foster, D. L., Medford, J. I., Craig, R., Mumma, R. O., 1999. Tissue-specific fatty acid composition of glandular trichomes of mite-resistant and -susceptible Pelargonium xhortorum. Journal of Chemical Ecology 25, 955-968.
  Anacardic acids, alkyl phenolic acids excreted by tall glandular trichomes of the garden geranium, Pelargonium xhortorum, confer small-pest resistance. Up to 90% of the trichome exudate from mite-resistant P. x hortorum inbreds consists of an unusual anacardic acid with an unsaturated omega-5 (delta5) alkyl chain. As fatty acids are biochemical precursors to anacardic acids, we examined by GC the fatty acid composition of leaves, pedicels, petals, sepals, mature seeds, and glandular trichomes from pest-resistant and pest-susceptible Pelargonium inbred lines to determine the localization of delta5-fatty acids within plant tissues. The fatty acid composition of lipid classes (galactolipids, phospholipids, and neutral lipids) extracted from glandular trichomes from mite-resistant pedicels were also examined. delta5-Fatty acids (16:1, 11 and 18:1, 13) were found only in the glandular trichomes from pest-resistant geraniums (27.2% in trichomes of pedicels) and were localized predominantly in the phospho- and galactolipids (phosphatidylinositol, 25.9%; phosphatidylcholine, 18.2%; monogalactosyldiglyceride, 15.5%; and diglactosyldiglyceride, 14.0%).
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• Izzo, P. T., Dawson, C. R., 1949. Cashew nut shell liquid. VI. The olefinic nature of anacardic acid. Journal of Organic Chemistry 14, 1039-1047.
  It has been established that the anacardic acid component of the oil of the shell of the cashew nut Anacardium occidentale, is not a homogeneous compound having the structure of a 3-pentadecadienylsalicyclic acid as heretofore believed. The anacardic acid as it occurs naturally in the cashew nut shell and which may be obtained from such shells by cold solvent-extraction, has been found to consist of a mixture of several olefinic components possessing an average unsaturation equivalent to about two double bonds. It has been estimated that at least 25% of the anacardic acid is a monoolefinic component. Using conditions throughout which would not be expected to alter the olefinic nature of the anacardic acid, the free acid was first methylated with diazomethane and the resulting dimethyl-ether-ester, possessing an average unsaturation equivalent to two double bonds, was hydroxylated using a mixture of 30% hydrogen peroxide-formic acid at low temperatures. The resulting mixture of glycols was partially separated by molecular distillation and a pure monoglycol was obtained. The crystalline monoglycol on cleavage with periodic acid yielded n-heptaldehyde, thereby establishing the monoolefin present in the natural anacardic acid mixture as 1-hydroxy-2-carboxy-3-(8'-pentadecenyl)benzene. The higher-boiling glycol fraction yielded formaldehyde on cleavage with periodic acid or lead tetraacetate, thereby establishing the existence of a terminal olefinic linkage in one or more of the higher olefinic components of anacardic acid.
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• Paul, V. T., Yeddanapalli, L. M., 1956. On the olefinic nature of anacardic acid from indian cashew nut shell liquid. Journal of the American Chemical Society 78, 5675-5678.
  The anacardic acid isolated from the solvent-extracted liquid from Indian cashew nut shells has been separated by low-temperature fractional crystallization into a saturated component and a mono-, di- and triolefin which have been identified by analysis of their permanganate oxidation products, respectively, as 1-hydroxy-2-carboxy-3-pentadecyl benzene, 1-hydroxy-2-carboxy-3-(8'-pentadecenyl)-benzene, 1-hydroxy-2-carboxy-3-(8'11'-pentadecadienyl)-benzene and 1-hydroxy-2-carboxy-3-(8',11',14'-pentadecatrienyl)-benzene.
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• Schötz, K., 2004. Quantification of allergenic urushiols in extracts of Ginkgo biloba leaves, in simple one-step extracts and refined manufactured material (EGb 761). Phytochemical Analysis 15, 1-8.
  Extracts of leaves of Ginkgo biloba (family Ginkgoaceae), widely used in the treatment of peripheral and cerebral circulatory disorders as well as for dementia of different aetiology, contain long chain alkylphenols (with allergenic, cytotoxic, mutagenic and tumour-promoting properties) together with the extremely potent allergens, the urushiols. Such hazardous compounds can be present only in very low concentrations in phytopharmaceutical preparations and hence, for the purposes of drug safety, techniques must be available for the identification and quantification of these allergens at extremely low levels in refined manufactured materials. GC-MS analysis of samples collected at various stages during the production process of a standardised extract of G. biloba (EGb 761) demonstrated that all alkylphenols present in the primary acetone extracts were removed in parallel with the same efficiency irrespective of their aromatic substitution pattern. Furthermore, in the final product the content of urushiols was generally below the detection limit of 0.03 ppm. Therefore, it is concluded that demonstrating the absence of the predominant, and easily quantifiable, ginkgolic acids provides a reliable means for the control of pharmaceutical quality of the final product.
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• Symes, W. F., Dawson, C. R., 1954. Poison ivy "urushiol". Journal of the American Chemical Society 76, 2959-2963.
  The toxic principle of poison ivy has an olefinic unsaturation of about two double bonds and possesses the carbon skeleton of 3-pentadecylcatechol. It has been found that the dimethyl ether can be separated by chromatography on alumina into four pure components which vary only in their degree of unsaturation in the side chain. One of the components has a completely reduced side chain. The other three contain one, two and three olefinic bonds, respectively. The structures proposed for the olefinic components on the basis of ozonolysis and oxidative degradation experiments are as follows: a monoolefin, 1,2-dihydroxy-3-(pentadecenyl-8')-benzene; a diolefin, 1,2-dihydroxy-3-(pentadecadienyl-8',11')-benzene and a triolefin, 1,2-dihydroxy-3-(pentadecatrienyl-8',11',14')-benzene.
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• Trevisan, M. T. S., Pfundstein, B., Haubner, R., Würtele, G., Spiegelhalder, B., Bartsch, H., Owen, R. W., 2006. Characterization of alkyl phenols in cashew (Anacardium occidentale) products and assay of their antioxidant capacity. Food and Chemical Toxicology 44, 188-197.
  In this study the content of anacardic acids, cardanols and cardols in cashew apple, nut (raw and roasted) and cashew nut shell liquid (CNSL) were analysed. The higher amounts (353.6 g/kg) of the major alkyl phenols, anacardic acids were detected in CNSL followed by cashew fibre 6.1 g/kg) while the lowest (0.65 g/kg) amounts were detected in roasted cashew nut. Cashew apple and fibre contained anacardic acids exclusively, whereas CNSL also contained an abundance of cardanols and cardols. Cashew nut (raw and roasted) also contained low amounts of hydroxy alkyl phenols. Cashew nut shell liquid was used for a basic fractionation of the alkyl phenol classes and the individual anacardic acids, major cardanols and cardols were purified to homogeneity from these fractions by semi-preparative HPLC and definitively identified by nano-ESI-MS-MS, GC-MS and NMR analyses. The hexane extracts (10 mg/ml) of all cashew products tested plus CNSL, displayed significant antioxidant capacity. Cashew nut shell liquid was the more efficient (inhibition = 100%) followed by the hexane extract of cashew fibre (94%) and apple (53%). The antioxidant capacity correlated significantly (P < 0.05) with the concentration of alkyl phenols in the extracts. A mixture of anacardic acids (10.0 mg/ml) showed the higher antioxidant capacity (IC 50 = 0.60 mM) compared to cardols and cardanols (IC50 > 4.0 mM). The data shows that of these substances, anacardic-1 was by far the more potent antioxidant (IC50 = 0.27 mM) compared to cardol-1 (IC50 = 1.71 mM) and cardanol-1 (IC50 > 4.0 mM). The antioxidant capacity of anacardic acid-1 is more related to inhibition of superoxide generation (IC50 = 0.04 mM) and xanthine oxidase (IC 50 = 0.30 mM) than to scavenging of hydroxyl radicals. At present a substantial amount of cashew fibre is mostly used in formulations of animal or poultry feeds. The data presented in this study, indicates that this waste product along with CNSL, both of which contain high contents of anacardic acids, could be better utilized in functional food formulations and may represent a cheap source of cancer chemopreventive agents.
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• Van Beek, T. A., Montoro, P., 2009. Chemical analysis and quality control of Ginkgo biloba leaves, extracts, and phytopharmaceuticals. Journal of Chromatography A 1216, 2002-2032.
  The chemical analysis and quality control of Ginkgo leaves, extracts, phytopharmaceuticals and some herbal supplements is comprehensively reviewed. The review is an update of a similar, earlier review in this journal [T.A. van Beek, J. Chromatogr. A 967 (2002) 21-55]. Since 2001 over 3000 papers on Ginkgo biloba have appeared, and about 400 of them pertain to chemical analysis in a broad sense and are cited herein. The more important ones are discussed and, where relevant, compared with the best methods published prior to 2002. In the same period over 2500 patents were filed on Ginkgo and the very few related to analysis are mentioned as well. Important constituents include terpene trilactones, i.e. ginkgolide A, B, C, J and bilobalide, flavonol glycosides, biflavones, proanthocyanidins, alkylphenols, simple phenolic acids, 6-hydroxykynurenic acid, 4-O-methylpyridoxine and polyprenols. In the most common so-called "standardised" Ginkgo extracts and phytopharmaceuticals several of these classes are no longer present. About 130 new papers deal with the analysis of the terpene trilactones. They are mostly extracted with methanol or water or mixtures thereof. Supercritical fluid extraction and pressurised water extraction are also possible. Sample clean-up is mostly by liquid-liquid extraction with ethyl acetate although no sample clean-up at all in combination with LC/MS/MS is gaining in importance. Separation and detection can be routinely carried out by RP-HPLC with ELSD, RI or MS, or by GC/FID or GC/MS after silylation. Hydrolysis followed by LC/MS allows the simultaneous analysis of terpene trilactones and flavonol aglycones. No quantitative procedure for all major flavonol glycosides has yet been published because they are not commercially available. The quantitation of a few available glycosides has been carried out but does not serve a real purpose. After acidic hydrolysis to the aglycones quercetin, kaempferol and isorhamnetin and separation by HPLC, quantitation is straightforward and yields by recalculation an estimation of the original total flavonol glycoside content. A profile of the genuine flavonol glycosides can detect poor storage or adulteration. Although the toxicity of Ginkgo alkylphenols upon oral administration has never been undoubtedly proven, most suppliers limit their content in extracts to 5 ppm and dozens of papers on their analysis were published. One procedure in which a methanolic extract is directly injected on a C8 HPLC column appears superior in terms of sensitivity (<5 ppm), separation, simplicity and validation and will be incorporated in the European Pharmacopoeia. Alternatively GC/MS and ELISA methods can be used. A sharp contrast to the plethora of papers on terpene trilactones, flavonol glycosides, and ginkgolic acids forms the low number of papers on biflavones, proanthocyanidins, simple phenolics, simple acids, and other constituents that make up the remaining 70% of Ginkgo standardised extracts. More research in this direction is clearly needed. For the analysis of Ginkgo proanthocyanidins (7%) for instance, no reliable assays are yet existing. Finally the growing literature on pharmacokinetic and fingerprinting studies of Ginkgo is briefly summarised.
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• Walters, D. S., Craig, R., Mumma, R. O., 1990. Fatty acid incorporation in the biosynthesis of anacardic acids of geraniums. Phytochemistry 29, 1815-1822.
  Geraniums, Pelargonium x hortorum, have been shown to possess tall glandular trichomes which secrete anacardic acids, a viscous, sticky exudate which provides defence against small pest species. Pest-resistant geraniums possess primarily C22- and C24-unsaturated (-5) anacardic acids with lesser amounts of the C22- and C24-saturated side chain structures. Previous workers have suggested that anacardic acids are biosynthesized from fatty acids by addition of two carbon units. To investigate this hypothesis, [14C]lauric, -myristic, -palmitic, -stearic and -oleic acids were administered to leaves and floral buds of pest-resistant geraniums. Palmitate and stearate were shown to be the respective precursors for C22 and C24 anacardic acids with saturated side chains. A major portion of the applied [14C]stearate was degraded and subsequently incorporated into the C22- and C24-saturated and unsaturated (-5) anacardic acids indicating an indirect pathway of biosynthesis also exists. Therefore, the -5 anacardic acids must be the result of -5 fatty acid precursors rather than the desaturation of saturated anacardic acids. Data supports the hypothesis that anacardic acids are biosynthesized from saturated and -5 unsaturated C16 and C18 fatty acids by chain elongation through the addition of three acetate groups, which then undergo partial reduction and dehydration, followed by intramolecular aldol condensation, to give the aromatic ring in a manner similar to that proposed for the biosynthesis of salicylic acid.
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• Yerger, E. H., Grazzini, R. A., Hesk, D., Cox-Foster, D. L., Craig, R., Mumma, R. O., 1992. A rapid method for isolating glandular trichomes. Plant Physiology 99, 1-7.
  A physical method is described for the rapid isolation of plant trichomes, with emphasis on stalked glandular types. The technique involved breaking frozen trichomes with powdered dry ice and collection of glandular heads by sieving from larger tissue fragments. This method was applied to several plants that bear similar stalked trichomes: geranium (Pelargonium), potato (Solanum tuberosum), tomato (Lycopersicon esculentum), squash (Cucurbita pepo), and velvetleaf (Abutilon theophrasti). The tissue preparation was of sufficient quality without further purification for biochemical and molecular studies. The preparation maintained the biochemical integrity of the trichomes for active enzymes and usable nucleic acids. A large quantity of tissue can be harvested; for example, 351 milligrams dry weight of glandular trichomes were harvested from geranium pedicels in 12 hours. The utility of the technique was demonstrated by examining the fatty acid composition of tall glandular trichomes of geraniums, Pelargonium x hortorum L.H. Bailey. These purified cells contained high concentrations of unusual w5-unsaturated fatty acids, proportionally 23.4% of total fatty acids in the trichomes. When the trichomes were removed, the supporting tissue contained no w5-fatty acids, thereby unequivocally localizing w5-fatty acids to the trichomes. Because w 5-fatty acids are unique precursors for the biosynthesis of w5-anacardic acids, we conclude that anacardic acid synthesis must occur in the glandular trichomes.
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• Schultz, D. J., Cahoon, E. B., Shanklin, J., Craig, R., Cox-Foster, D. L., Mumma, R. O., Medford, J. I., 1996. Expression of a D⁹ 14:0-acyl carrier protein fatty acid desaturase gene is necessary for the production of w⁵ anacardic acids found in pest-resistant geranium (Pelargonium xhortorum). Proceedings of the National Academy of Sciences of the United States of America 93, 8771-8775.
  Anacardic acids, a class of secondary compounds derived from fatty acids, are found in a variety of dicotyledonous families. Pest resistance (e.g., spider mites and aphids) in Pelargonium xhortorum (geranium) is associated with high levels (approximately 81%) of unsaturated 22:1 omega 5 and 24:1 omega 5 anacardic acids in the glandular trichome exudate. A single dominant locus controls the production of these omega 5 anacardic acids, which arise from novel 16:1 delta 11 and 18:1 delta 13 fatty acids. We describe the isolation and characterization of a cDNA encoding a unique delta 9 14:0-acyl carrier protein fatty acid desaturase. Several lines of evidence indicated that expression of this desaturase leads to the production of the omega 5 anacardic acids involved in pest resistance. First, its expression was found in pest-resistant, but not suspectible, plants and its expression followed the production of the omega 5 anacardic acids in segregating populations. Second, its expression and the occurrence of the novel 16:1 delta 11 and 18:1 delta 13 fatty acids and the omega 5 anacardic acids were specific to tall glandular trichomes. Third, assays of the recombinant protein demonstrated that this desaturase produced the 14:1 delta 9 fatty acid precursor to the novel 16:1 delta 11 and 18:1 delta 13 fatty acids. Based on our genetic and biochemical studies, we conclude that expression of this delta 9 14:0-ACP desaturase gene is required for the production of omega 5 anacardic acids that have been shown to be necessary for pest resistance in geranium.
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• Schultz, D. J., Olsen, C., Cobbs, G. A., Stolowich, N. J., Parrott, M. M., 2006. Bioactivity of anacardic acid against colorado potato beetle (Leptinotarsa decemlineata) larvae. Journal of Agricultural and Food Chemistry 54, 7522-7529.
  Anacardic acid (2-hydroxy-6-alkylbenzoic acid) produced and secreted from glandular trichomes of zonal geranium (Pelargonium x hortorum; Geraniaceae family) provides resistance to small pests (aphids and spider mites). To assess the potential bioactivity of anacardic acid against larger insect pests and to determine if an alternate mode of application (ingestion rather than the topical application) could impart resistance to pests, the effects of anacardic acid consumption on the development of Colorado potato beetle larvae were tested. Analysis of dose-response curves indicated a significant effect on weight gain and mortality. Assessment of food preference (treated versus untreated) indicated larvae avoid food containing anacardic acid and have a lower feeding rate on food containing anacardic acid. On the basis of these results, it is suggested that anacardic acid, applied as a chemical spray or through bioengineering production in crop plants, may provide a new tool in the arsenal to minimize damage to plants caused by pests.
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• Hershko, K., Weinberg, I., Ingber, A., 2005. Exploring the mango-poison ivy connection: the riddle of discriminative plant dermatitis. Contact Dermatitis 52, 3-5.
  A relationship between sensitivity to poison oak or poison ivy and mango dermatitis has been suggested by previous publications. The observation that acute allergic contact dermatitis can arise on first exposure to mango in patients who have been sensitized beforehand by contact with other urushiol-containing plants has been documented previously. We report 17 American patients employed in mango picking at a summer camp in Israel, who developed a rash of varying severity. All patients were either in contact with poison ivy/oak in the past or lived in areas where these plants are endemic. None recalled previous contact with mango. In contrast, none of their Israeli companions who had never been exposed to poison ivy/oak developed mango dermatitis. These observations suggest that individuals with known history of poison ivy/oak allergy, or those residing in area where these plants are common, may develop allergic contact dermatitis from mango on first exposure. We hypothesize that previous oral exposure to urushiol in the local Israeli population might establish immune tolerance to these plants.
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• Oka, K., Saito, F., Yasuhara, T., Sugimoto, A., 2004. A study of cross-reactions between mango contact allergens and urushiol. Contact Dermatitis 51, 292-296.
  The allergens causing mango dermatitis have long been suspected to be alk(en)yl catechols and/or alk(en)yl resorcinols on the basis of observed cross-sensitivity reactions to mango in patients known to be sensitive to poison ivy and oak (Toxicodendron spp.). Earlier, we reported the 3 resorcinol derivatives: heptadecadienylresorcinol (I), heptadecenylresorcinol (II) and pentadecylresorcinol (III); collectively named 'mangol', as mango allergens. In this study, we extracted the 1st 2 components (I and II) from the Philippine mango, adjusted them to 0.05% concentration in petrolatum and patch tested the components on 2 subjects with mango dermatitis. Both subjects reacted to I. 1 subject also elicited a weaker positive reaction to II. To investigate the cross-reaction between mangol and urushiol, we also patch tested the same subjects with urushiol. The subject sensitive to II reacted to urushiol. 6 subjects with a history of lacquer contact dermatitis and positive reactions to urushiol were similarly patch tested. 5 persons reacted to I. 2 subjects also exhibited a slower but positive reaction to II. This is the 1st report in which heptadec(adi)enyl resorcinols known to be present in mango have been shown to elicit positive patch test reactions in mango-sensitive patients.
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• Zarnowska, E. D., Zarnowski, R., Kozubek, A., 2000. Alkylresorcinols in fruit pulp and leaves of Ginkgo biloba L. Zeitschrift für Naturforschung 55c, 881-885.
  These studies were undertaken to characterise resorcinolic lipids (5-n-alk(en)ylresorcinols) composition and to determine their seasonal fluctuations in fruit pulp and leaves of Ginkgo biloba L. Resorcinolic lipid concentrations were consistently higher in fruit pulp than in leaves. In pulp, several mono- and di-unsaturated homologs of alkylresorcinols were the predominant group of analysed lipids. Contrary to the fruit pulp, only 5-n-pentadecylresorcinol was demonstrated in leaves. Initially, the alkylresorcinol's content both in pulp and leaves increased until June - July and decreased following seeds ripening. This trend continued until senescence of leaves in late September and October.
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