The modulation of membrane fluidity by hydrogenation processes. III. The hydrogenation of biomembranes of spinach chloroplasts and a study of the effect of this on photosynthetic electron transport

A method is reported for the in situ modification of the lipids of isolated spinach chloroplast membranes. The technique is based on a direct hydrogenation of the lipid double bonds in the presence of the catalyst, chlorotris(triphenylphosphine)rhodium (I). The pattern of hydrogenation achieved suggests that the catalyst distributes amongst all of the membranes. The polyunsaturated lipids within the membranes are hydrogenated at a faster rate and at an earlier stage than are the monoenoic lipids.Whilst addition of the catalyst to the chloroplast causes an initial 10–20% decrease in Hill activity, saturation of up to 40% of the double bonds present can be accomplished without causing further significant alterations in photosynthetic electron transport processes or marked morphological changes of the chloroplast structure as observed in the electron microscope.     

The modulation of membrane fluidity by hydrogenation processes. II. Homogeneous catalysis and model biomembranes

A homogeneous catalyst, chlorotris (triphenylphosphine) rhodium (I) has been incorporated into model biomembrane structures in the form of lipid bilayer dispersions in water. This enables the hydrogenation of the double bonds of the unsaturated lipids within the bilayers to be accomplished. To decide the optimum conditions for efficient hydrogenation the reaction conditions have been varied. The effect of catalyst concentration, hydrogen gas pressure and lipid composition (with and without cholesterol) have all been studied. The partition of the catalyst into the lipid medium was checked by rhodium analysis. The results show that an increase of catalyst concentration or an increase of hydrogen gas pressure leads to increasing rates of hydrogenation. Successful hydrogenation was accomplished with different types of lipid dispersions (mitochondrial, microsomal and erythrocyte lipids). A selectivity of the homogeneous hydrogenation process is indicated. The polyunsaturated fatty acyl residues are hydrogenated at an earlier stage and at a faster rate than the monoenoic acids. Furthermore, an increase in the proportion of cholesterol to lipid within the bilayer structures causes a progressive decrease in the rate of hydrogenation. The fluidity of the lipid bilayers can be altered to such an extent by the hydrogenation process that new sharp endotherms corresponding to the order-disorder transition of saturated lipids occur at temperatures as high as 319 K. Some potential uses of hydrogenation for the modulation of cell membrane fluidity are discussed as well as the design of new types of catalyst molecules.     

trans- and cis-Ru(II) aminophosphine complexes: Syntheses, X-ray structures and catalytic activity in transfer hydrogenation of acetophenone derivatives

The ability of transition metal catalysts to add or remove hydrogen from organic substrates by transfer hydrogenation process is a valuable synthetic tool. For this aim, a novel Ru(II) complex with the P-N ligand [(Ph₂P)₂NCH₂-C₄H₃S] derived from thiophene-2-methylamine was synthesized starting with the complex [Ru(η⁶-p-cymene)(μ-Cl)Cl]₂ and isolated in two isomeric forms: trans- and cis-[Ru((PPh₂)₂NCH₂-C₄H₃S)₂Cl₂], 2 and 3, respectively. The structures of both isomers were also determined by single crystal X-ray diffraction. The cis-isomer 3 can be isolated from the solution of major trans-isomer 2 as yellow crystals. However, upon dissolution 3 is rapidly converted to the trans-isomer 2. The new ruthenium(II) complex provides high catalytic activity in the transfer hydrogenation of acetophenone derivatives to 1-phenylethanol derivatives in the presence of 2-propanol as the hydrogen source. This transfer hydrogenation is characterized by low reversibility under the experimental conditions.     

A highly enantioselective rhodium catalyst for the hydrogenation of aliphatic α-keto esters

The enantioselective hydrogenation of several α-keto acid derivatives with rhodium diphosphine catalysts has been investigated using a random screening approach. The neutral rhodium catalyst prepared in situ from bis(2,5-norbornadiene rhodium chloride) and NORPHOS has been found to be an excellent catalyst for preparing aliphatic α-hydroxy esters in high optical purities. The reaction parameters for the hydrogenation of ethyl 2-oxo-4-phenyl-butyrate, an intermediate for the ACE inhibitor Benazepril, were optimized and the best optical yields obtained were 96%.     

(2-Azidomethyl)phenylacetyl as a new, reductively cleavable protecting group for hydroxyl groups in carbohydrate synthesis

The (2-azidomethyl)phenylacetyl group (AMPA) is described as a new protecting group for carbohydrates. AMPA was introduced to carbohydrate hydroxyl groups in the presence of DCC, while its removal was conveniently achieved via Lindlar catalyst-catalyzed hydrogenation that had no influence on other protecting groups including benzyl, acyl, acetal and ketal.     

Polymer-supported biopolymer synthesis: 2. Phenolic poly(acryloylmorpholine)-based preparation of protected arginyl acylpeptide segments and derived arginyl peptides

A new poly(acryloylmorpholine)-based phenolic support matrix, Koch-Light Peptide Resin A, has been utilized for the solid (gel) phase assembly of protected or ginyl acylpeptide segments. Two methods, selective hydrazimolysis and autocatalysed transesterification with 2-dimethylaminoethanol, have been used to detach the peptide segments from the resin. Selective hydrazinolysis illustrates the use of the phenolic support matrix in the preparation of arginyl acylpeptide hydrazides bearing hydrazine-labile nitroguanidino and benylaxycarbonyl side chain protecting groups. Autocatalysed hydrolysis in trifluoroethanol/sodium trifluoroethanoate buffer has been used to convert the protected arginyl acylpeptide 2-dimethylaminoethyl esters to the corresponding protected arginyl acylpeptide acids. Total deprotection of the latter was effected by catalytic transfer hydrogenation in formic acid.     

Identification of the New Hydrocarbon (Z,Z)-1,6,9-Heptadecatriene as the Secretory Component of Caloglyphus polyphyllae (Astigmata: Acaridae)

A new heptadecatriene was isolated from the acarid mite, Caloglyphus polyphyllae, as the major characteristic component which could be used to identify the species chemo-taxonomically. Its structure was elucidated as 1,6,9-heptadecatriene by partial hydrogenation and a subsequent GC/MS analysis of the dimethyldisulfide derivative, together with evidence of the terminal vinyl group and Z-configuration of double bonds that was provided by GC-FT/IR and NMR. The triene was identified as (Z,Z)-1,6,9-heptadecatriene by its synthesis and is revealed to be a new compound as a natural product.     

Density functional computations of Rh(I)-catalysed hydroacylation and hydrogenation of ethene using formic acid

The rhodium-catalysed hydroacylation of alkene is one of the most useful C–H bond activation processes. The C–C bond-forming reactions via C–H bond activation have extensively been the focus of study in the fields of organic and organometallic chemistry. In this work, density functional theory has been used to study Rh(I)-catalysed hydroacylation and hydrogenation of ethene with formic acid. All the intermediates and the transition states were optimised completely at the B3LYP/6-311++G(d,p) level (LANL2DZ(d) for Rh, P). Calculation results confirm that Rh(I)-catalysed hydroacylation of ethene is exothermic and the released Gibbs free energy is ? 60.39 kJ/mol. Rh(I)-catalysed hydrogenation of ethene is also exothermic and the released Gibbs free energy is ? 150.97 kJ/mol. Rh(I)-catalysed hydroacylation of ethene is the dominant reaction mode for Rh(I)-catalysed hydroacylation and hydrogenation of ethene with formic acid. In Rh(I)-catalysed hydroacylation of ethene, the H-transfer reaction is prior to the C–C bond-forming reaction. Therefore, the reaction mode ‘a’ (i.e. ca → M1 → TS1 → M2 → TS2a → M3a → TS3a → M4 → P1) is the dominant reaction pathway for Rh(I)-catalysed hydroacylation and hydrogenation of ethene. The theoretically predicted dominant product is propane acid.     

Polymer-supported biopolymer synthesis: 3. Preparation of fully and partially protected βh-endorphin segments with a new phenolic poly [N-(2-methoxyethyl)-acrylamide]-based support

A new phenolic peptide resin, which is a bead-form derivative of crosslinked poly[N-(2-methoxyethyl)acrylamide], has been prepared by a suspension polymerization technique. The resin, which is highly expanded in all common peptide solvents, has been used for the solid (gel) phase synthesis of protected acylpeptide hydrazides. Fully protected acylpeptide hydrazide segments corresponding to β_h-endorphin (15–17), β_h-endorphin (6–14) and β_h-endorphin (6–17) have been prepared. Conversion, by selective catalytic transfer hydrogenation, of the fully protected acylpeptide hydrazide segment corresponding to β-_h-endorphin (15–17) to the partially protected form has been explored.     

新型二氢嘧啶类化合物的合成及其抗乙型肝炎病毒活性研究

以芳香氰基化合物为起始原料,经胺解、乙酰化、催化氢化、关环等步骤得到新型二氢嘧啶类化合物14个,结构通过核磁共振氢谱、质谱、元素分析确证,并利用HepG2.2.15细胞进行了体外抗HBV活性评价.结果表明部分化合物具有明显的抗HBVDNA复制作用,其中化合物5c和5n抑制HBVDNA复制的半数有效浓度分别为0.87μmol/L和0.67μmol/L.初步探讨了活性化合物的构效关系,同时运用分子排阻色谱法考察了活性化合物与病毒衣壳蛋白的相互作用.     

DNA methylation and development.

(1) Isolated rat liver mitochondria were subjected to catalytic hydrogenation using a water-soluble Pd complex and molecular H2. This treatment resulted in a reduction of double bonds on phospholipid acyl chains as judged by gas chromatography of fatty acid methyl esters and HPLC of dinitrobenzoyldiacylglycerols. (2) After hydrogenation, mitochondria lost their ability to hydrolyze endogenous phospholipids in alkaline, Ca2+ containing medium, while phospholipase A2 retained full activity against exogenous substrates, regardless of whether those substrates were hydrogenated or not. (3) Inhibition by hydrogenation of endogenous phospholipid hydrolysis correlated with the loss of polyunsaturated fatty acyls, rather than with changes of the bulk membrane fluidity as measured by ESR and fluorescence studies. (4) These data suggest that the unsaturation of mitochondrial membrane lipids might be important for regulation of phospholipid breakdown by endogenous phospholipases. In particular, polyunsaturated molecular species seem to be involved in making phospholipids accessible to phospholipase A-mediated hydrolysis.     

Interconversion between Rotenone and Dalpanol

Photosensitized oxidation of trioleoylglycerol (TO), trilinoleoylglycerol (TL), trilinolenoylglycerol (TLn) and vegetable oil triacylglycerols (triglycerides, TG) was carried out in isopropanol using methylene blue as a photosensitizer. Isomeric compositions of hydroperoxy fatty acid components of the oxidized TG were determined by hydrogenation, methanolysis and mass chromatographic analysis of the resulting methyl hydroxy octadecanoate. TO gave 9- and 10-isomers; TL, 9-, 10-, 12- and 13-isomers; and TLn, 9-, 10-, 12-, 13-, 15- and 16-isomers. It was concluded that each unsaturated fatty acid component of vegetable oil TG yields isomeric hydroperoxides during photosensitized oxidation in a manner similar to the corresponding unsaturated fatty acid methyl ester. TL monohydroperoxides were isolated from the photooxidized TL and hydrolyzed by pancreatic lipase. The hydrolysis products consisted of dilinoleoylglycerol, monolinoleoylglycerol, linoleic acid and their respective hydroperoxides. Formation of a hydroperoxy fatty acid component was observed during photoirradiation of vegetable oils in the bulk phase without methylene blue. The isomeric compositions of the resulting methyl hydroxy octadecanoate support the idea that singlet oxygen is responsible for the formation of hydroperoxides in the initial stage of photooxidation.     

Kinetic study of the enzymatic inactivation of progestogens by rat liver microsomes.

The kinetics of enzymatic hydrogenation of synthetic progestogens by female rat liver microsomes with NADPH as hydrogen donor were investigated by means of an optical test. Steroids with high progestational activity (Clauberg test) showed a low hydrogenation rate (Vmax). There also seemed to be a certain correlation between molecular structure and Vmax. The metabolites from incubation with the progestogens were isolated from the micro-preparations, and identified by infrared spectroscopy. It was found that the hydrogenation of the olefinic and carbonylic groups involved the uptake of hydrogen from NADPH.     

Heterogeneous asymmetric reactions. Part 24. Heterogeneous catalytic enantioselective hydrogenation of the C==N group over cinchona alkaloid modified palladium catalyst.

The enantioselective hydrogenation of C==N-C group containing compounds over modified metal catalysts is as yet an uninvestigated research area. This work contains results obtained on the hydrogenation of 1-pyrroline-2-carboxylate esters and sodium salt over cinchona alkaloid-modified alumina-supported Pd catalyst. The effect of the reaction parameters and the structure of the alkaloid molecule on hydrogenation rate and enantioselectivity allowed us to assume that on the catalyst surface only a weak interaction exists between the modifier and the substrate, resulting in the low enantiomeric excesses (up to 20%) obtainable in these reactions.     

The asymmetric synthesis of (R,R)‐formoterol via transfer hydrogenation with polyethylene glycol bound Rh catalyst in PEG2000 and water

(R,R)‐formoterol was synthesized in seven steps with 4‐hydroxyl‐3‐nitro‐acetophenone as the starting material. The key intermediate, the chiral secondary alcohol 4 , was prepared via Rh‐catalyzed asymmetric transfer hydrogenation with (S,S)‐PEGBsDPEN as the ligand and sodium formate as the hydrogen donor under mild conditions. With a mixture of PEG 2000 and water as the reaction media, the catalyst system could be recycled four times. Chirality, 2010. © 2009 Wiley‐Liss, Inc.     

The modulation of membrane fluidity by hydrogenation processes. III. The hydrogenation of biomembranes of spinach chloroplasts and a study of the effect of this on photosynthetic electron transport.

A method is reported for the in situ modification of the lipids of isolated spinach chloroplast membranes. The technique is based on a direct hydrogenation of the lipid double bonds in the presence of the catalyst, chlorotris(triphenylphosphine)rhodium (I). The pattern of hydrogenation achieved suggests that the catalyst distributes amongst all of the membranes. The polyunsaturated lipids within the membranes are hydrogenated at a faster rate and at an earlier stage than are the monoenoic lipids. Whilst addition of the catalyst to the chloroplast causes an initial 10--20% decrease in Hill activity, saturation of up to 40% of the double bonds present can be accomplished without causing further significant alterations in photosynthetic electron transport processes or marked morphological changes of the chloroplast structure as observed in the electron microscope.     

Biomimetic asymmetric hydrogenation.

Enzymes and synthetic organometallic catalysts utilize different approaches for the creation of chiral centers in prochiral substrates. While chiral organometallic catalysts realize the transfer of chirality mainly by repulsive interactions, several enzymes use preferentially stereodiscriminating hydrogen bonding. To investigate if hydrogen bonding within the catalyst-substrate assembly can also have a benefit on the rhodium diphosphine-catalyzed asymmetric hydrogenation, some model metal complexes and substrates were investigated. As 'biomimetically acting' functionalities, hydroxy groups were incorporated in the chiral ligand. Three secondary interactions could be identified by different analytical methods which influence rate and enantioselectivity of the catalytic reaction: 1) HO/Rh-interactions, 2) HO/HO-interactions within the backbone of the ligand, and 3) hydrogen bonding between HO-groups of the ligand and functional groups of an appropriate substrate. Due to the effect of the additional hydroxy groups, enantioselectivities by up to 99% ee could be induced in the hydrogenation product even with water as solvent.     

Pyrene fluorescence probing of unsaturated lipids in Phytophthora infestans zoospores.

Pyrene rapidly penetrates into isolated zoospores of phytopathogenic fungus Phytophthora infestans localizing predominantly in lipid bodies. An analysis of steady-state monomer and excimer fluorescence spectra, as well as of vibronic structure has suggested a considerable part of the fluorescent probe to be located in a lipid environment. Pyrene partition into hydrophilic phase was observed at its high concentrations. Catalytic hydrogenation of unsaturated lipids in zoospores in situ reduced excimer production. The kinetics of changes of pyrene excimerization suggest that hydrogenation affects both the surface and the intrinsic lipids of the zoospores. The usefulness of pyrene as a fluorescent probe for unsaturated lipids in membranes and lipid bodies of intact cells, and the possible role of eicosapolyunsaturated fatty acids in induction of immune response in potato plants are discussed.     

Cooperative catalysis of a trinuclear ruthenium(II) complex in transfer hydrogenation of ketones by formic acid

A novel TPA derivative (TPA = tris(2-pyridylmethyl)amine) having two 1,10-phenanthroline (phen) moieties via amide linkage was synthesized and this ligand reacted with [Ru(hmb)Cl₂]₂ (hmb: hexamethylbenzene) to give a trinuclear Ru(II) complex, [RuCl(TPA-{phenRuCl(hmb)}₂-H⁺)](PF₆)₂ (1-Cl), in a moderate yield. The complex involves a deprotonated and oxygen-coordinated amide linkage, which exhibits reversible protonation-deprotonation equilibrium. The chlorido complex was converted to be an aqua complex, [Ru(H₂O)(TPA-{phenRu(H₂O)₂(hmb)}₂-H⁺)](SO₄)_5/2 (1-H₂O), by the reaction of 1-Cl with Ag₂SO₄ in H₂O. Transfer hydrogenation of ketones was examined by using 1-Cl as a catalyst and HCOONa as a hydride source in H₂O/CH₃OH (1:1 v/v) at 50 °C under Ar. The time-course of the transfer hydrogenation of cyclohexanone to give cyclohexanol revealed that 1-Cl showed a cooperative effect on the catalytic reactivity as compared with that of mononuclear [RuCl(hmb)(phen)] (3-Cl) and [RuCl((1-Naph)₂-TPA)]PF₆ in H₂O/CH₃OH (1:2 v/v) under the same conditions. The detailed kinetic study has revealed that the catalytic transfer hydrogenation proceeds via the formato complex, which interacts with a substrate rather than via the hydrido complex. The two Ru centers placed at close proximity in 1-H₂O enhanced the interaction of the formato complex with a substrate, resulting in an increase in the catalytic reactivity as compared with the mononuclear complex.     

Cyclic peptides. VI. Asymmetric hydrogenation of dehydroalanine or dehydroaminobutanoic acid residue in cyclodipeptides.

Several cyclo(-L-aminoacyl-deltaAla-) (aminoacyl = Ala, Val, Leu, Phe, Pro and Lys (epsilon-Ac)) were prepared by tosylation and successive detosylation of cyclo(-L-aminoacyl-L-Ser-), which were synthesized via the Nitecki and Fischer methods. Hydrogenation of the double bond of dehydroalanine residues in cyclodipeptides was carried out using Pd black in methanol at 1-atm pressure and room temperature. The degree of asymmetric hydrogenation was assessed by determining the amounts of L- and D-alanine by a modified Manning and Moore procedure. When L-valine was used as a chiral source, L-alanine residue with chiral induction of 98.4% was derived from cyclo(-L-Val-deltaAla-). L-Amino acids other than L-proline also were effective in inducing remarkable asymmetric hydrogenation. Hydrogenation of alpha,beta-dehydro-alpha-aminobutanoic acid residues in cyclodipeptides produced L-alpha-aminobutanoic acid residues with effective chiral induction to the same extent as observed with dehydroalanine residues. Optically pure l-alanine was prepared from cyclo(-L-Lys(epsilon-Ac)-deltaAla-) via asymmetric hydrogenation. A mechanism of chiral induction is discussed.