Epicuticular waxes from Agropyron dasystachyum,agropyron riparium and Agropyron elongatum

Epicuticular waxes from whole plants of Agropyron dasystachyum var. psammophylum, A. riparium and A. elongatum contain hydrocarbons (5–8 %), long chain esters (12–15%) and free acids (2–5%). The major esters are C₃₄C₅₆ esters derived from C₁₆C₃₀ acids and alcohols (1-hexacosanol is the major alcohol) but C₃₁, C₃₃ and C₃₅ esters (3–11%) are also present. The latter esters are C₁₈ and C₂₀ acid esters of C₁₃ and C₁₅ 2-alkanols. A. dasystachyum wax contains 2% free alcohols, that of A. riparium contains 17% and that of A. elongatum 11% (1-hexacosanol is the major alcohol in each). Diesters (2%), C₈C₁₂ diols esterified by (E)-2-alkenoic acids, are present in A. riparium wax. Hentriacontane-14,16-dione is present: 29% in A. dasystachyum wax and 32% in A. riparium wax, but only 5% in A. elongatum wax. 25-Oxohentriacontane-14,16-dione forms 14% of A. dasystachyum wax and 27% of A. elongatum wax but the oxo β-diketones of A. riparium wax (5%) consist of both 10-oxo- and 25-oxohentriacontane-14,16-diones in the ratio 4:1. Hydroxy β-diketones of the waxes are 25- and 26-hydroxyhentriacontane-14,16-diones; in A. dasystachyum (20%) the ratio is 3:1, in A. elongatum (20%) the ratio is 9:1 but in A. riparium (5%) it is ca 1:2. The configuration of the hydroxyl group in the 26-hydroxy β-diketone is opposite to that in the 25-hydroxy derivative. The unusual composition of the oxygenated β-diketones of A. riparium confirms that this species should be regarded as separate from A. dasystachyum. Wax from A. elongatum also contains 4-hydroxy-25-oxohentriacontane-14,16-dione (4%) and an unusual oxo-β-ketol, 18-hydroxy-7,16-hentriacontanedione (2%), both these components are probably derived biosynthetically from the 25-oxo β-diketone which is the major component of this wax. Syntheses of racemic 18-hydroxy-7,16-hentriacontanedione and of a model β-ketol, 12-hydroxy-10-pentacosanone, are described.     

Epicuticular wax of Poa ampla leaves

Leaf wax of a glaucous variety of Poa ampla contains hydrocarbons (5%, C₂₃–C₃₅), esters (9%, C₃₆–C₅₆), free acids (3%, C₁₆–C₃₄), free alcohols (6%, mainly C₂₆); hentriacontane-14,16-dione (14%), 5-oxohentriacontane-14,16-dione (1%); hydroxy β-diketones (56%) and unidentified material (6%). The hydroxy β-diketones, which are more abundant in this wax than in others, were shown by ¹³C NMR to consist of 4-hydroxy (15%), 5-hydroxy (70%) and 6-hydroxy (15%) hentriacontane-14,16-diones.     

Epicuticular waxes of Secale cereale and Triticale hexaploide leaves

Wax on leaves of rye and of hexaploid Triticale (60–70-day-old plants) contains hydrocarbons (6–8%), esters (10%), free alcohols (14-8%), free acids (3%), hentriacontane-14,16-dione (39–45%), 25 (S)-hydroxyhentriacontane-14,16-dione (13–11%) and unidentified (14–15%). Diesters (1–3%) are also present in rye wax. Compositions of hydrocarbons (C₂₇-C₃₃) and esters (C₂₈,C₅₈) are similar for both waxes. Free and combined alcohols of rye wax are mainly hexacosanol but alcohols of Triticale wax are mainly octacosanol. The composition of Triticale wax is close to that of its wheat parent Triticum durum (cv. Stewart 63). Esters of wax from ripe rye contain 58% of trans 2,3-unsaturated esters. *NRCC No. 14033.     

Leaf wax of Triticum aestivum

Leaf waxes from spring wheat varieties Selkirk and Manitou contain hydrocarbons (6%, 10%), long chain esters (14%, 13%), free acids (5%, 8%), free alcohols (19%, 21%), β-diketone (16%, 20%), hydroxy β-diketones (8%, 10%), unidentified gum (29%, 16.5%) and minor amounts of diol diesters, glycerides and aldehydes. The major hydrocarbon is nonacosane and major esters are octacosyl esters of C₁₄–C₃₂ acids but C₂₀ and C₂₂ alcohol esters of trans 2-docosenoic and tetracosenoic acids are also present (Selkirk 20%, Manitou 10% of total esters). Previously unknown trans 2-docosen-1-ol is present as an ester (Selkirk 5%, Manitou 2.5% of total esters). Free acids are C₁₄–C₃₂ acids and trans 2-docosenoic and tetracosenoic acids (Selkirk 30%, Manitou 9% of free acids). Octacosanol is the principal free alcohol. Hentriacontane-14,16-dione is the β-diketone and the hydroxy β-diketones are a 1:1 mixture of 8- and 9- hydroxyhentriacontane-14,16-diones.     

Epicuticular wax of Panicum virgatum

Leaf and stem wax of Panicum virgatum contains hydrocarbons (4%), esters (3%), free acids (2%), free alcohols (1%), triterpene alcohols (2%), β-diketones (69%) and hydroxy β-diketones (6%). Principal free alcohols range in chain length from C₂₆ to C₃₂. β-Diketones consist almost entirely of tritriacontane-12,14-dione and the hydroxy β-diketone consists only of 5(S)-5-hydroxytritriacontane-12,14-dione. The configuration of the hydroxyl group is the same as that of hydroxy β-diketones from festucoid grasses but opposite to that of the hydroxy β-diketone from Andropogon species.     

Epicuticular waxes of Andropogon hallii and A. Scoparius

Leaf waxes of Andropogon hallii and A. scoparius contain hydrocarbons (2%, 2%), esters (4%, 2%), free acids (3%, 4%), free alcohols (1%, 0.2%, major component dotriacontanol) β-diketones (67%, 80%) and hydroxy β-diketones (16%, 5%). β-Diketones of A. hallii consist mainly of tritriacontane-12,14-dione and hentriacontane-12,14-dione (86:8) and of A. scoparius of tritriacontane-12,14-dione and hentriacontane-10,12-dione (67:29). Hydroxy β-diketones of A. hallii are composed mainly of 5-hydroxytritriacontane-12,14-dione and 5-hydroxy-hentriacontane-12,14-dione (90:8); wax of A. scoparius contains only 5-hydroxytritriacontane-12,14-dione. The hydroxyl group of the major hydroxy β-diketone has the R-configuration opposite to that of all previously described hydroxy β-diketones.     

Epicuticular wax of Eragrostis curvula

Epicuticular wax of Eragrostis curvula contains hydrocarbons (6%), esters (13%), acids (3%), alkanols (4%), tritriacontane-12,14-dione (47%), 5(S)-5-hydroxytritriacontane-12,14-dione (14%) as major components. The esters consist of triterpenol esters (42%) as well as alkanol esters. The free alkanols consist principally Of C₁₆C₃₂ components, resembling those of waxes from panicoid, and some other eragrostoid, grasses. Minor components are triterpenols (0.7%), triterpenones (0.5%), triacylglycerols (0.3%), secondary alkanols (0.1%) and 5-oxotritriacontane-12,14-dione (0.1%).     

Epicuticular waxes of four eragrostoid grasses

The major components of Sporobolus airoides wax were hydrocarbons (37%, C₂₇–C₃₃), those of Bouteloua curtipendula and Eragrostis trichoides waxes esters (28% and 31%, respectively) and those of Muhlenbergia wrightii wax free alcohols (57%, almost entirely C₂₈). Free alcohols formed 22% of the wax from B. curtipendula, 19 % of the wax from E. trichoides and 10% of the wax from S. airoides; the compositions ranged from C₂₆ to C₃₂ with C₃₂ the major component. These alcohol compositions are similar to those found for other species in the subfamily Eragrostoideae. The esters contain 32–46% of acylated triterpenols, principally α- and β-amyrins. Aldehydes were present in all the waxes except for that from S. airoides.     

The chemical composition of the wax of the white wax scale,Ceroplastes destructor (Newstead)

The wax of the White Wax Scale [Ceroplastes destructor (Newstead)] is shown to consist principally of a mixture of esters formed from the C₂₆ and C₂₈ alcohols and acids, together with these acids and alcohols in an uncombined state. Paraffin hydrocarbons were not detected. There is a similarity in the composition of the wax secreted by the four members of the genus Ceroplastes which have been investigated.     

Glossy mutants of maize. VIII. Accumulation of fatty aldehydes in surface waxes of gl5 maize seedlings

In corn seedlings (Zea mays L.) homozygous for the mutation gl5, the surface waxes are characteristically altered. In this mutant the main wax constituents (83.5%) are aldehydes while in the normal waxes alcohols predominate (62.7%). Moreover, in the normal waxes aldehydes and alcohols are made up mainly of the C₃₂ term (99%), whereas in gl5 waxes the principal aldehyde is still C₃₂ (90.7%) but the free alcohol composition pattern is noticeably modified. Here the predominant terms are C₂₄, C₂₆, and C₂₈, with C₃₂ representing only 16.6% of the total. The results indicate that the mutant induces a block in the synthesis of fatty alcohols while accumulating fatty aldehydes, the substrates from which the alcohols originate.     

Epicuticular wax of Pinus radiata needles

Epicuticular wax isolated from the cotyledons and primary needles of 10-week-old Pinus radiata seedlings is similar in composition and contains 86% neutral compounds, viz. alkyl esters (25%, C₂₄–C₆₄), nonacosan-10-ol (52%), heptacosane-5,10-diol (2%), nonacosane-4,10-diol, nonacosane-5,10-diol, and nonacosane-10,13-diol (total 12%) and estolides, MW ca 800 (2%), MW ca 1100 (6%), and MW ca 1500 (1%). The acidic fraction (14%) contains n-acids (78%, C₁₂–C₃₂) and diterpene acids (22%, mainly abieta-8,11,13-trien-18-oic, with lesser amounts of pimara-8(14),15-dien-18-oic, isopimara-7,15-dien-18-oic and hydroxylated aromatic, diene and mono-ene acids). Wax isolated from primary needles of 1-yr-old seedlings had a similar neutral fraction composition, but the acidic fraction contained predominantly the diterpene acid mixture, with only trace amounts of n-acids. The wax from 1-yr-old secondary, needles from P. radiata forest trees aged 5 yr and 40 yr contained an acid fraction (12% 5 yr, 17% 40 yr trees) comprising the diterpene acid mixture, with trace amounts of n-acids together with ω-hydroxy acids (C₁₂, C₁₄ and C₁₆). The neutral fraction from both young and old trees had a similar composition containing alkyl esters (7%, C₂₄–C₆₆), estolides (90%, MW 566-ca 1500), nonacosan-10-ol (2%) and the heptacosane and nonacosane diols (1%). During growth and maturation of P. radiata, the nonacosan-10-ol content of the needle wax decreases while the proportion of estolides and diterpene acids increases, the latter probably being located around the stomatal pore.     

Specific inhibition of alkane synthesis with accumulation of very long chain compounds by dithioerythritol, dithiothreitol, and mercaptoethanol in Pisum sativum

Sodium [1-¹⁴C]acetate and [1-¹⁴C]stearic acid were readily incorporated into hydrocarbons, secondary alcohols, wax esters, aldehydes, primary alcohols, and fatty acids in young pea leaves (Pisum sativum). Dithioerythritol, dithiothreitol, and mercaptoethanol (but not glutathione and cysteine) severely inhibited the incorporation of labeled acetate into alkanes and secondary alcohols with accumulation of label in wax ester and aldehyde fractions. Detailed radio gas-chromatographic analyses of the fatty acids of both the surface lipid components and internal lipids showed that dithioerythritol and mercaptoethanol specifically inhibited n-hentriacontane (C₃₁) synthesis and caused accumulation of C₃₂ aldehyde, suggesting that the inhibition was at or near the terminal step in alkane biosynthesis, presumably decarboxylation. Trichloroacetate, at a concentration that inhibited C₃₁ alkane synthesis but not the synthesis of alcohols (C₂₆ and C₂₈) specifically inhibited the formation of C₃₂ aldehyde but not that of the C₂₆ or C₂₈ aldehyde. From these results, it is concluded that the C₃₂ aldehyde is derived from the C₃₂ acyl derivative which is the precursor of C₃₁ alkane.     

Absence of long chain aldehydes in the wax of the Glossy II mutant of maize

Wax from the glll mutant of maize lacks aldehydes, which constitute 20 % in the normal genotype. The absence of aldehydes is not associated with a block in the synthesis of alcohols. Moreover in contrast to the wild type, glll wax is characterized by a higher content of C₁₆ and C₁₈ free acids, with a clear defect in the synthesis of C₂₄, C₂₆ and C₂₈ homologues. The results from this study are taken as evidence that the wild type elongation-decarboxylation I (EDI) pathway, leading to the synthesis of all the wax classes of compounds except esters, may be split into an early (EDIa) and a late (EDIb) group of reactions. Mutant glll is apparently defective at the EDIa, governing the synthesis of C₂₄–C₂₈ fatty acyl chains.     

Alkyl esters from pinus radiata foliage epicuticular wax

Wax esters from the epicuticular wax of juvenile and mature-tree Pinus radiata foliage have been shown by capillary column GC-MS to consist mainly of short chain (C₆–C₁₂)alkanols esterified with long chain acids (C₂₄–C₃₂) and long chain alkanols (C₂₄–C₃₂) esterified with short chain acids (C₆-C₁₄) in a non-random manner. Mature-tree foliage wax esters also contained nonacosan-10-ol esterified with dodecanoic and tetradecanoic acids.     

Final structure of caulerpicin,a toxin mixture from the green alga Caulerpa racemosa

Caulerpicin from the green alga Caulerpa racemosa is shown to consist of a mixture of ceramides derived from 2S, 3R-sphinganine with C₁₈ (32%), C₂₀(2%), C₂₂(6%), C₂₄(35%) and C₂₆(25%) saturated fatty acid     

Changes in the composition of coffee leaf wax with development

Coffee leaf wax contains alkanes, free primary alcohols and free acids, together with unidentified substances. The relative amounts of each fraction varied with age: alkanes from 22–35% alcohols from 28-25%, and free acids from 22-14%. The major homologues of the alkane fraction were C₂₉ and C₃₁, of the alcohol fraction C₃₀ and C₃₂ and of the acid fraction C₂₈, C₃₀ and C₃₂. The ratio of both C₂₉:C₃₁ alkanes and C_3O:C₃₂ alcohols changed from 1:1 to 1:2 during development, although their combined sum in each case remained constant at 90% (for alkanes) and 73% (for alcohols) of the weight of the respective fractions.     

Composition of leaf epicuticular waxes of Pteridium subspecies

The leaf epicuticular waxes of two subspecies of Pteridium consisted principally of alkyl esters (92 %; C₄₀–C₅₀) together with small amounts of n-alkanols (2 %; C₂₄–C₃₂) and hydrocarbons (2%; C₂₇–C₃₁). The esters comprised C₂₂–C₃₂ alkanols randomly combined with C₂₀ – C₂₄ fatty acids.     

Hydrocarbons and wax esters from seven species of mangrove leaves

Seven species of fresh mangrove leaves were found to contain saturated normal and branched chain hydrocarbons, mostly between C₁₆ and C₃₆ with both odd and even carbon numbers. Significant quantitative variations were found between species. Wax esters were found to contain fatty acids with chain lengths between C₁₂ and C₂₂. Palmitic (16:0) and stearic (18:0) acids were the major component saturated fatty acids, whereas, oleic (18:1) and linolenic (18:3) acids were the major unsaturate α-acids. Chain lengths of the alcohols of wax esters were between C₁₄ and C₃₆. Significant quantitative and minor qualitative differences were noted in the alcohol composition of wax esters. Hydrocarbon and wax ester compositions were characterised by the presence of low M, components in high proportions.     

The composition of external lipids from adult whiteflies,Bemisia tabaci and Trialeurodes vaporariorum

The total surface lipids, including the wax particles, of the adult whiteflies of Bemisia tabaci and Trialeurodes vaporariorum were characterized. At eclosion, there were similar amounts of long-chain hydrocarbons, aldehydes, alcohols and wax esters. Within a few hours post-eclosion, long-chain aldehydes and long-chain alcohols were the dominant surface lipid components, C₃₄ on B. tabaci and C₃₂ on T. vaporariorum. Hydrocarbons, mainly n-alkanes, were minor components of the surface lipids. The major wax esters were C₄₆ on B. tabaci and C₄₂ on T. vaporariorum. The major acid and alcohol moieties in the wax esters of B. tabaci were C₂₀ and C₂₆, respectively, and of T. vaporariorum were C₂₀ and C₂₂, respectively. Both B. tabaci and T. vaporariorum had a minor wax ester composed of the fatty acid C_18:1 esterified to the major alcohols, C₃₄ and C₃₂, respectively. Bemisia were readily distinguished from Trialeurodes based on the composition of their wax particles and/or their wax esters; however, no differentiating surface lipid components were detected between biotypes A and B of B. tabaci.     

Wax composition of sargassum fulvellum

Sixty-seven compounds were characterized in the wax of Sargassum fulvellum. Characteristic components were the 5-methylhexyl esters of octanoic, decanoic, lauric, myristic, palmitic, palmitoleic, stearic, oleic, linoleic and linolenic, and the 2-ethylhexyl esters of the same acids. The wax of S. fulvellum contains hydrocarbons (1.6%), esters (21.8%), free acids (74.9%) and free alcohols (0.3%). The principal free alcohols range in chain length only from C₆ to C₇.