Cyclic fatty esters: Stereochemistry of monounsaturated products from the hydrogenation and reduction of 9-(6-propyl-3-cyclohenxenyl)-8-nonenoic acid or its ester

Diunsaturated, C-18 cyclic fatty acid methyl esters (CFAME) were previously synthesized as model derivatives for characterization and biological evaluation of cyclic fatty acids (CFA) formed in heat-abused vegetable oils. The propyl substituted, diunsaturated CFMAE (I) was selectively reduced to prepare two monounsaturated, positional isomers with the double bond located either in the ester substituent (alkene isomer II) or in the ring (cyclohexene isomer III). The stereochemistry of these monounsaturated products was investigated by capillary GLC and NMR. Capillary GLC showed that each positional isomer was a mixture of two ‘ring’ isomers (i.e. a mixture of two isomers with side chains either cis or trans). The ring double bond in diene I was readily hydrogenated with various metal catalysts, and no cyclohexene isomer III was detected in the product. Platinum oxide poisoned with Ph₃P was the most selective catalyst examined to convert diene I to monoene II. Diimide reduction was the only method foud to reduce selectively the double bond in the ester side chain of diene I. This diimide reduction was facilitated when the Z-double bond in the side chain was isomerized to E-double bond with p-toluenesulfinic acid. Cyclohexene isomer III and alkene isomer II were separated by argentation HPLC. These two isomeric monoenes were characterized by GC-MS, capillary GLC, micro-ozonolysis, IR and NMR. Catalytic hydrogenation with Ph₃P-poisoned PtO₂ and diimide reduction of the diunsaturated cyclic ester may provide useful methods to synthesize and label monounsaturated cyclic fatty esters.     

Effect of unsaturated bonds in the sn-2 acyl chain of phosphatidylcholine on the membrane-damaging action of Clostridium perfringens alpha-toxin toward liposomes

Clostridium perfringens alpha-toxin degrades phosphatidylcholine (PC) in the bilayer of liposomes and destroys the membrane. The effect of the type and position of unsaturation in the fatty acyl chain of PC (18:0/18:1 PC) synthesized on the toxin-induced leakage of carboxyfluorescein (CF) from PC liposomes was examined. Differential scanning calorimetry showed that the phase transition temperature (T_m) was minimal when the triple bond was positioned at C (9) in the sn-2 acyl chain. The toxin-induced CF leakage decreased with the migration of the bond from C (9) to either end of the acyl chain in PC. The PC containing the cis-double bond had a similar T_m to that with the triple bond, but a lower value than the PC containing the trans-double bond. Furthermore, the toxin-induced leakage from liposomes composed of PC containing the cis-double bond resembled that with PC having the triple bond and was greater than that from liposomes with PC having the trans-double bond. The binding of a H148G mutant to PC liposomes showed a reciprocal relationship in terms of the T_m value of PC containing the triple bond. These results indicate that the toxin-induced membrane damage is closely related to membrane fluidity in liposomes.     

Cytokinins: synthesis and biological activity of geometric and position isomers of zeatin

Geometric and position isomers of zeatin and of ribosylzeatin and other compounds closely related to zeatin have been tested in the tobacco (Nicotiana tabacum var. Wisconsin No. 38) bioassay. None was more active than zeatin itself. There was a much greater difference in activity (> 50-fold) between trans- and cis-zeatin than between trans-isozeatin [6-(4-hydroxy-2-methyl-trans-2-butenylamino) purine] and cis-isozeatin [6-(4-hydroxy-2-methyl-cis-2-butenylamino) purine], the latter being less active than cis-zeatin and trans-isozeatin. Higher concentrations were required for equivalent callus growth stimulated by the 9-ribosyl derivatives, which followed an order of decreasing activity: ribosyl-trans-zeatin > ribosyl-cis-zeatin > ribosyl-trans-isozeatin > ribosyl-cis-isozeatin, corresponding roughly to that of the bases. The effect of side chain, double bond saturation was to diminish the activity, and in the dihydro series the shift of the methyl group from the 3- to the 2-position in going from dihydrozeatin to dihydroisozeatin [6-(4-hydroxy-2-methylbutylamino) purine] resulted in a 70-fold decrease in activity. cis-Norzeatin [6-(4-hydroxy-cis-2-butenylamino) purine], which was less than one-fifth as active as cis-zeatin, showed the effect of complete removal of the side chain methyl group, and cyclic-norzeatin [6-(3,6-dihydro-1,2-oxazin-2-yl) purine] was about 1/100 as active as cis-norzeatin. These findings delineate completely the effect on the cytokinin activity of zeatin of variation in side chain geometry, presence and position of the methyl substituent, presence and geometry of hydroxyl substitution, presence of the double bond, and of side chain cyclization.     

Key structural features of cis-cinnamic acid as an allelochemical

1-O-cis-cinnamoyl-β-d-glucopyranose is one of the most potent allelochemicals isolated from Spiraea thunbergii Sieb. It is suggested that it derives its strong inhibitory activity from cis-cinnamic acid, which is crucial for phytotoxicity. It was synthesized to confirm its structure and bioactivity, and also a series of cis-cinnamic acid analogues were prepared to elucidate the key features of cis-cinnamic acid for lettuce root growth inhibition. The cis-cyclopropyl analogue showed potent inhibitory activity while the saturated and alkyne analogues proved to be inactive, demonstrating the importance of the cis-double bond. Moreover, the aromatic ring could not be replaced with a saturated ring. However, the 1,3-dienylcyclohexene analogue showed strong activity. These results suggest that the geometry of the C–C double bond between the carboxyl group and the aromatic ring is essential for potent inhibitory activity. In addition, using several light sources, the photostability of the cinnamic acid derivatives and the role of the C–C double bond were also investigated.     

Effect of double bond geometry in sphingosine base on the antioxidant function of sphingomyelin

We previously showed that sphingomyelin (SM) inhibits peroxidation of phosphatidylcholine (PC) and cholesterol. Since SM uniquely has a trans unsaturation in its sphingosine base, we investigated whether this feature is important for its antioxidant function. Substitution of the natural trans Δ⁴-double bond with a cis double bond (cis-SM), however, increased SM’s ability to inhibit Cu²⁺-mediated 16:0-18:2 PC oxidation by up to eightfold. Dihydro-SM, which lacks the double bond, was equally effective as trans-SM. In contrast to its effect in the sphingosine base, the presence of a cis double bond in the N-acyl group of trans-SM was not protective. cis-SM also inhibited the oxidation of cholesterol by FeSO₄/ascorbate more efficiently than the trans isomer. The enhanced protective effect of cis-SM is selective for metal ion-promoted oxidation, and appears to arise from a decrease in the effective concentration of metal ions. These studies show that the trans double bond of SM is not essential for its antioxidant effects.     

Structure-Activity Relationships of Abscisic Acid Analogs Based on the Induction of Freezing Tolerance in Bromegrass (Bromus inermis Leyss) Cell Cultures

The induction of freezing tolerance in bromegrass (Bromus inermis Leyss) cell culture was used to investigate the activity of absisic acid (ABA) analogs. Analogs were either part of an array of 32 derived from systematic alterations to four regions of the ABA molecule or related, pure optical isomers. Alterations were made to the functional group at C-1 (acid replaced with methyl ester, aldehyde, or alcohol), the configuration at C-2, C-3 (cis double bond replaced with trans double bond), the bond order at C-4, C-5 (trans double bond replaced with a triple bond), and ring saturation (C-2′, C-3′ double bond replaced with a single bond so that the C-2′ methyl and side chain were cis). All deviations in structure from ABA reduced activity. A cis C-2, C-3 double bond was the only substituent absolutely required for activity. Overall, acids and esters were more active than aldehydes and alcohols, cyclohexenones were more active than cyclohexanones, and dienoic and acetylenic analogs were equally active. The activity associated with any one substituent was, however, markedly influenced by the presence of other substituents. cis, trans analogs were more active than their corresponding acetylenic analogs unless the C-1 was an ester. Cyclohexenones were more active than cyclohexanones regardless of oxidation level at C-1. An acetylenic side chain decreased the activity of cyclohexenones but increased the activity of cyclohexanones relative to their cis, trans counterparts. Trends suggested that for activity the configuration at C-1′ has to be the same as in (S)-ABA, in dihydro analogs the C-2′-methyl and the side chain must be cis, small positional changes of the 7′-methyl are tolerable, and the C-1 has to be at the acid oxidation level.     

Novel polyunsaturated n-alkenes in the marine diatom Rhizosolenia setigera.

Four previously unknown n-C25 and n-C27 heptaenes of the marine diatom Rhizosolenia setigera were isolated and identified using NMR spectroscopy. They possess six methylene interrupted (Z)-double bonds starting at C-3 and an additional terminal or n-2 (Z)-double bond. Structural and stable carbon isotopic evidence suggests that these polyenes are biosynthesized by chain elongation of the C22:6n-3 fatty acid, followed by decarboxylation and introduction of double bonds at specific positions.     

Monoclonal antibody recognition of abscisic Acid analogs

Specificities of three monoclonal antibodies (15-I-C5, DBPA 1, and MAC 62) raised against the plant hormone (S)-(+)-abscisic acid (ABA) have been compared. Immunological cross-reactivities against fifteen biologically active analogs of ABA were measured. The ABA analogs were altered at one or more of four positions: the double bonds in the ring, at C-2 C-3 and at C-4 C-5, and in the oxidation level at C-1. Several analogs were optically active with chiral centers at C-1′ and C-2′. For cross-reactivity, all three monoclonal antibodies required the carboxylic acid group, and the cis configuration of the double bond at C-2 C-3 of the ABA molecule. Monoclonals 15-I-C5 and DBPA 1 required the entire ABA sidechain from the C-1 to C-1′, but these monoclonals did cross-react with analogs with the ring double bond reduced and the C-2′ methyl cis to the sidechain. Only MAC 62 recognized analogs containing an acetylene at C-4 C-5. MAC 62 had more strict requirements for the ring double bond, but gave some cross-reactivity with acetylenic analogs having a saturated ring. All three monoclonals had higher specificity for analogs having the same absolute configuration at C-1′ as (S)-(+)-ABA. This work provides new information about the spatial regions of the ABA molecule that elicit immunological recognition, and serves as a basis for future investigations of the ABA receptor using ABA analogs and anti-idiotypic antibodies.     

13C-NMR of double and triple bond carbon atoms of unsaturated fatty acid methyl esters

The carbon magnetic resonance spectra of many fatty acid methyl esters with cis and trans double bonds and triple bonds at various positions and in many different combinations have been investigated.The influence of the ester group on double and triple bonds in the fatty acid chain depends strongly on the positions of these bonds. For a given position the influence is constant, even if one or more other double or triple bonds are present.Together with the evaluated chemical shift parameters for the effects of double and triple bonds on each other, complete assignments are possible and spectra of various types of unsaturated esters can be predicted with high accuracy (±0.1 ppm).     

Interaction between C18 fatty acids and DOPE PEG2000 in Langmuir monolayers: effect of degree of unsaturation

In this study, we address the effect of the cis-double bond in 1,2-dioleoyl-sn-glycero-3-phosphoethanolamide-N-[methoxy(polyethylene glycol)-2000, DOPE PEG2000 (DP), on the Langmuir monolayer of C18 fatty acids—namely, stearic acid (SA), oleic acid (L1), linoleic acid (L2), and linolenic acid (L3)—with the same head group but different degrees of saturation on their hydrocarbon chains. Negative values of Gibbs free energy of mixing (ΔG _mix) were obtained throughout the investigated ranges of the unsaturated C18 fatty-acid (L1, L2 and L3) mixed systems, indicating that very strong attractions occurred between molecules in the monolayers. The bend and kink effects from the cis-double bond(s) in the hydrocarbon chain affected the membrane fluidity and molecular packing in the monolayers, which resulted in a greater interaction between unsaturated C18 fatty acids and DP. The most thermodynamically stable mole composition of unsaturated C18 fatty acids to DP was observed at 50:1; this ratio is suggested to be the best mole ratio and will be subsequently used to prepare DP–C18 fatty-acid nanoliposomes. The presence of cis-double bonds in both hydrocarbon chains of DOPE in DP also created an imperfection in the membrane structure of lipid-drug delivery systems, which is expected to enhance lipid-based systems for antibody conjugation and drug encapsulation.     

beta-elimination in uronic acids: evidence for an ElcB mechanism

Methyl esters of methyl pyranosides of 2,3,4-tri-O-methyl-α-D-mannuronic acid (3), -α-D-glucuronic acid (2), and -β-D-galacturonic acid (1) undergo rapid beta-elimination of the 4-methoxyl group in 0.50, 0.20, and 0.02M sodium methoxide in methanol at room temperature to give 4,5-unsaturated esters via cis, cis and trans elimination, respectively. The ease of cis elimination in methyl (methyl 2,3,4-tri-O-methyl-α-D-glucopyranosid)uronate (2) and methyl (methyl 2,3,4-tri-O-methyl-α-D-mannopyranosid)uronate (3) to form the 4,5-unsaturated glycoside is explained by ring flexibility which allows a change in conformation. Only the methyl (methyl 2,3,4-tri-O-methyl-α-D-mannopyranosid)uronate (3) yields a 2,3:4,5-di-unsaturated ester (7) (trans elimination), and this occurs in 0.50M methoxide, in a much slower reaction. The favoring of trans elimination over the cis elimination that would have been needed in the other two compounds in order to form the second double bond is explained by the rigidity of the half-chair conformation of the 4,5-unsaturated esters. It is suggested that both eliminations proceed via an ElcB mechanism. The results of treatment of hydroxypropyl alginate with potassium hydroxide confirmed that its depolymerization is much slower, and more dependent on the concentration of alkali, than that of pectin.     

Preparation of methyl cis-9,cis-12-octadecadienoate-16,16,17,17-d4

An eight-step synthesis is described which gives an overall yield of ～30% methyl cis-9,cis-12-octadecadienoate-16,16,17,17-d₄. The preparation utilizes easily obtainable starting materials. Tris(triphenylphosphine)chlororhodium (I) catalyst is used for incorporation of the deuterium isotopes. The double bond in the 9 position is created by the Wittig coupling of 1-non-3-enyl-d₄-triphenylphosphonium bromide to methyl 8-formyloctanoate. Various methods for preparation of the intermediate and final products are discussed. Partial argentation resin chromatography was used to remove the ～9% trans/cis, cis/trans, and trans/trans isomers also produced. Analysis of the final product by mass spectrometry (MS) indicated 96%-d₄.     

Biotransformation of Unsaturated Long-Chain Fatty Acids by Eubacterium lentum

Eubacterium lentum (33 strains) isomerized the 12-cis double bond of C₁₈ fatty acids with cis double bonds at C-9 and C-12 into an 11-trans double bond before reduction of the 9-cis double bond. The 14-cis double bond of homo-γ-linolenic acid was isomerized by 29 strains into a 13-trans double bond. The same strains isomerized the 14-cis double bond of arachidonic acid into a 13-trans double bond and then isomerized the 8-cis double bond into a 7-trans double bond; the 13-cis double bond of 10-cis, 13-cis-nonadecadienoic acid was isomerized into a 12-trans double bond. None of these isomerization products was further reduced. Studies with resting cells showed optimal isomerization velocity at a linoleic acid concentration of 37.5 μM; higher concentrations were inhibitory. The pH optimum for isomerization was 7.5 to 8.5. The isomerase was inhibited by the sulfhydryl reagents iodoacetamide, bromoacetate, and N-ethylmaleimide and by the chelators EDTA and 1,10-phenanthroline.     

Substrate specificities in ether lipid biosynthesis. Metabolism of polyunsaturated fatty acids and alcohols by rat brain microsomes

Reduction of fatty acids having one to four double bonds per molecule to the corresponding alcohols, and the utilization of such alcohols for alkyl dihydroxyacetone phosphate (alkyl DHAP) synthesis was measured with microsomal preparations from 19-day-old rat brain. While alkyl DHAP formation proceeded well with octadecenol, octadecadienol, octadecatrienol and eicosatetraenol, fatty acids with more than one $\text{cis}$-double bond were not readily reduced to the corresponding alcohols.     

cis–trans isomerization of carbon double bonds in monounsaturated triacylglycerols via generation of free radicals

We investigated the heat-induced cis/trans isomerization of double bonds in monounsaturated lipids. When triolein (9-cis, 18:1) was heated around 180 °C, small amounts of isomerization products were obtained depending on the heating period. The heat-induced isomerization of triolein was considerably suppressed by the addition of different antioxidants or under nitrogen stream, and these additives simultaneously inhibited the thermal oxidation of double bonds in triolein. Therefore, an intermediate of the thermal oxidation reaction might be responsible for the heat-induced isomerization of the double bonds in triolein. The thermodynamics of the heat-induced isomerization of triolein (9-cis, 18:1) and trielaidin (9-trans, 18:1) were investigated using Arrhenius plot. The Arrhenius activation energies of cis double bonds in triolein and trans double bonds in trielaidin were 106 kJ/mol and 137 kJ/mol, respectively. The calculated internal rotational barrier heights of these double bonds were similar to those of the double bond of 2-butene radical and significantly lower than those of non-radicalized double bonds in 2-butene. These results suggest that heat-induced cis/trans isomerization of triolein and trielaidin occurs mainly through the formation of radical species, which are the intermediates produced during thermal oxidation. The activation energy difference between the two forms suggests that trans trielaidin radicals are more stable than cis triolein radicals. The high thermodynamic stability of the trans double bonds in lipid radicals would influence the population of cis and trans isomers in edible oils and contribute to slight accumulation of trans-18:1 isomers during heating or industrial processing.     

Fatty acids,part 38: Neighbouring group participation in the oxymercuration-demercuration reaction. Another route to 1,4- and 1,5-epoxides

Oxymercuration-demercuration of hydroxy alkenes follows an intramolecular pathway to furnish 1,4-epoxides (tetrahydrofurans) when the hydroxyl group is β (trans only) or γ to a double bond and 1,5-epoxides (tetrahydropyrans) when the hydroxyl group is δ to the double bond. The cis and trans isomers of methyl ricinoleate and methyl 9-hydroxyoctadec-12-enoate, and a series of cis and trans octadecenols (Δ2–Δ6) are used to establish these relationships.1,4- and 1,5-Epoxides are also formed during the oxymercuration of methyl densipolate and methyl 12,13-dihydroxyoleate and during the hydroxymercuration of methyl octadeca-9,12 and 8,12-dienoates.     

Substrate specificity of the epoxidation reaction in sex pheromone biosynthesis of the Japanese giant looper (Lepidoptera: Geometridae)

Female moths of the Japanese giant looper (Ascotis selenaria cretacea, Lepidoptera: Geometridae) secrete (Z,Z)-6,9-cis-3,4-epoxynonadecadiene as a sex pheromone component. To the pheromone glands of the decapitated females, [19,19,19-D₃](Z,Z,Z)-3,6,9-nonadecatriene was applied after an injection of pheromone biosynthesis activating neuropeptide. GC-MS analysis of the gland extract showed its specific conversion into the pheromonal cis-3,4-epoxide indicating that the C₁₉ triene which had been identified in the gland was a precursor of the pheromone. In order to examine the substrate specificity of the enzyme catalyzing this epoxidation step, several unsaturated hydrocarbons not occurring in the gland were applied to it. Not only (Z,Z,Z)-3,6,9-trienes with varying chain lengths (C₁₇, C₁₈ and C₂₀ to C₂₂) but (Z,Z)-3,6-dienes (C₁₇, C₁₉ and C₂₀) were converted into the corresponding cis-3,4-epoxides in a rather good yield, while no 6,7- and 9,10-epoxides could be detected. (Z)-3-Nonadecene was also changed to the cis-epoxide, but (E)-3-, (Z)-2- and (Z)-4-double bonds in the C₁₉ chain were not oxidized. These in vivo experiments revealed that the monooxygenase regiospecifically attacked the (Z)-3-double bond of straight chain hydrocarbons regardless of their length and degree of unsaturation.     

Synthesis and properties of methyl 9,12,15-octadecatrienoate geometric isomers

The eight geometrically isomeric methyl 9,12,15-octadecatrienoates were prepared by using the Wittig reaction to couple cis- or trans-3-hexyenyltriphenylphosphonium bromide and methyl 12-oxo-cis- or trans-9-dodecenoate. Pairs of geometric triene isomers formed were separated by partial silver resin chromatography. Physical constants including melting points, percent trans by infrared, equivalent chain lengths (ECL), and ¹³C nuclear magnetic resonance (NMR) chemcial shifts are tabulated for the individual isomers.     

Ring A-stereoisomers of 1-hydroxyvitamin D3 and their relative binding affinities for the intestinal 1α,25-dihydroxyvitamin D3 receptor protein

A set of eight 1-hydroxyvitamin D₃ compounds comprising the four possible (5Z)-1,3-diol stereoisomers and the corresponding (5E)-double bond isomers, has been prepared in order to assess the effect of 1,3-diol stereochemistry and 5,6-double bond geometry on binding affinity for the intestinal 1,25-(OH)₂D₃-receptor protein. The compounds were synthesized from either vitamin D₃ or 3-epivitamin D₃ via 3,5-cyclovitamin D intermediates. Competitive receptor binding assays establish that all changes from the natural ring A-configuration (1S, 3R, 5Z) lead to decreased binding affinity, and confirm the importance of the 1-hydroxy function since the conversion of stereochemistry at that center from 1α(S) to 1β(R) has the most pronounced effect on binding affinity (attenuation by more than three orders of magnitude). Other modifications (i.e., conversion at C-3, or cis to trans isomerization of the 5,6-double bond) decrease binding affinity by more moderate (ca. 10-fold) but cumulative factors.     

Structure activity studies leading to a tissue-selective hypotensive prostaglandin analog, 13,14-dihydro-16-phenyl-ω-tetranor PGE2

During our systematic search for prostaglandins with improved tissue selectivity and metabolic stability, we synthesized a series of PGE₂ analogs in which the n-amyl carbinol side chain was systematically substituted by a phenyl ring, based on structural considerations incorporating the 17,18-cis-double bond of PGE₃ into an aromatic ring. These compounds were evaluated for uterine stimulant, bronchodilator and hypotensive activity. Among the divergent biological profiles exhibited by these analogs, noteworthy was the tissue-selective hypotensive profile displayed by 13,14-dihydro-16-phenyl-ω-tetranor PGE₂.