Long-term continuous production of optically active 2-(4-chlorophenoxy)propanoic acid by yeast lipase in an organic solvent system

Summary Long-term continuous optical resolution of 2-(4-chlorophenoxy)propanoic acid was carried out by stereoselective esterification with Celite-adsorbed lipase OF 360 from Candida cylindracea using n-tetradecanol as the second substrate in organic solvent systems. The water content of the Celite-adsorbed lipase affected productivity, 1.0 l water·mg lipase^–1 being optimal for preparation of the adsorbed lipase. Water-saturated carbon tetrachloride-isooctane (8:2, v/v) was found to be an excellent organic solvent for the continuous operation. The particle size of Celite had no effect on productivity. Under optimized conditions, the (R)-enantiomer of the acid was continuously esterified with high stereoselectivity in a packed-bed column reactor for 34 days. Furthermore, it was found that treatment of the reactor with acetone made it possible to restore productivity and extend the period of continuous operation for further 29 days. Offprint requests to: A. Tanaka     

Kinetic resolution of α-lipoic acid via enzymatic differentiation of a remote stereocenter

Kinetic resolution of α-lipoic acid, a case of remote stereocenter discrimination, was accomplished using lipase from Aspergillus oryzae WZ007. Performance of this lipase was investigated for enantioselective esterification of (S)-α-lipoic acid, leaving the target product (R)-α-lipoic acid in unreacted form. The effects of chain length of alcohol, type of solvent, molar ratio of alcohol:acid, and reaction temperature were studied. The optimum reaction conditions were found to be esterification with n-octanol at 50°C in heptane with an alcohol:acid molar ratio of 5:1. The conversion rate of α-lipoic acid was 75.2%, with an enantiomeric excess of 92.5% towards unreacted substrate in a reaction time of 48 h.     

Preparation of an optically pure secondary alcohol of synthetic pyrethroids using microbial lipases

Summary Enzyme-catalysed hydrolysis of esters of 4-hydroxy-3-methyl-2-(2-propynyl)-cyclopent-2-enone (HMPC) was examined for the preparation of the optically pure alcohol moiety of synthetic pyrethroids. Among microorganisms and lipases tested, some bacterial lipases hydrolysed the ester of HMPC with high enantioselectivity and high reaction rate. Arthrobacter lipase gave the optically pure (R)-HMPC at 50% hydrolysis in a two-liquid phase reaction system of water and the insoluble substrate. The hydrolysis proceeded even at a substrate concentration of 80w/v%. The enantioselectivity was not changed with the chain length of the acid moiety of the esters. By combination of the enzymatic resolution with a chemical inversion of the (R)-alcohol, an efficient proess was developed for the total conversion of racemic HMPC to (S)-HMPC, which is an important alcohol for preparation of an insecticidallyactive synthetic pyrethroid.Biological preparation of an optically active alcohol. Part I     

Construction of a non-support bioreactor: optical resolution of 2-(4-chlorophenoxy)propanoic acid in an organic solvent system

Summary A non-support bioreactor, a novel column reactor packed with a free non-supported enzyme was constructed by applying the insolubility of the enzyme in organic solvents. Stereoselective esterification of 2-(4-chlorophenoxy)propanoic acid by lipase OF 360 from Candida cylindracea with n-tetradecanol was selected as a model reaction. Non-supported lipase revealed threefold higher activity than Celite-adsorbed lipase by maintaining high stereoselectivity in a batch reaction. In continuous operation, a non-support bioreactor produced the ester with fourfold higher productivity to that of a column reactor packed with Celite-adsorbed lipase (an adsorbed bioreactor). However, the optical purity of the remaining (S)-acid was low even when the conversion ration was kept at approximately 50%. Lipase recovered from the non-support bioreactor after continuous operation retained the original stereoselectivity in a batch reaction. Therefore, semi-continuous operation was conducted by recycling the substrate solution at a high flow rate. The non-support reactor showed high stereoselectivity and ten times the productivity compared with the adsorbed bioreactor. The reason for this high performance is discussed. Offprint requests to: A. Tanaka     

Reaction conditions for the resolution of 2-methylalkanoic acids in esterification and hydrolysis with lipase from Candida cylindracea

Summary We have demonstrated resolution of 2-methylalkanoic acids using lipase from Candida cylindracea as a catalyst. The resolution of 2-methyldecanoic acid was more successful than that of 2-methylbutyric acid both by esterification and hydrolysis. This indicates that the resolution of the acid is dependent on the chain length of the acid moiety. The chain length of the alcohol moiety of the ester affected the resolution of the long-chain acid only. Using esterification, (R)-2-methyldecanoic acid was produced in an enantiomeric excess (e.e.) of 95% (E = 40). If the enantiomeric ratio is low (E = 3.6), as in the resolution of 2-methylbutyric acid, esterification combined with a high equilibrium conversion could be used to yield the remaining acid in a high e.e. In the hydrolytic reactions, the e.e and the equilibrium conversion were dependent on the pH and the presence of CaCl₂. When octyl 2-methyldecanoate was hydrolysed at pH 8.0 in the presence of CaCl₂, the (S)-acid was formed with an e.e. of 80% (E = 9), but when the hydrolysis was carried out at pH 7.5 without CaCl₂, a very low e.e. and a low equilibrium conversion were observed. The latter conditions allowed the esterification of 2-methyldecanoic acid with 1-octanol even in aqueous medium. Offprint requests to: K. Hult     

Resolution of 2-phenoxy-1-propanols through the enantioselective acylation mediated by Achromobacter sp. lipase as biocatalyst

Enantioselective acylation employing vinyl alkanoates as acyl donors was exploited for the resolution of 2-(substituted phenoxy)-1-propanols carrying different substituents on the benzene ring using Achromobacter sp. lipase. These primary alcohols with an oxygen atom at the stereocenter, were resolved with moderate to good enantioselectivity, based on the enantiomeric ratio E (up to 27), through acylation with vinyl butanoate in diisopropyl ether, after the examination of potential factors affecting the reaction such as organic solvents and acyl donors. Using this procedure, enantiomerically enriched (R)-2-(4-chlorophenoxy)-1-propanol was prepared in 97% e.e. and 33% yield in a gram-scale reaction.     

Solvent effect in the stereoselective polymerization of α-amino acid N-carboxyanhydride and some considerations on the mechanism of stereoregulation

In the Polymerization of phenylalanine N-carboxyanhydride (NCA) in No₂Oh initiated by MeNHBzl, L -,D -, and DL -NCA As were polymerized at the same rate, and no stereoselectivity was observed. When the same experiment was carried out in HCONEt₂, however, L - and D -NCA were both polymerized at a rate which was about twice as large as that of DL -NCA. In this case, the polymerization is stereoselective, ascribable to a preferable reaction between the optical enantiomorphs of the terminal residue of the growing chain and the NCA of the same chirality. On the other hand, the polymerization initiated by SarNMe₂ and MeNH(CH₂)₂CONMe₂ were stereoselective in NO₂Ph and HCONEt₂, but they were not stereoselective in m-(MeO)₂Ph. These findings indicate that the polymerizations initiated by a strong base in highly dipolar solvents are stereoselective. Apparently, the reaction between a chiral, cyclic terminal of growing chain and a chiral, cyclic activated NCA in the activated-NCA mechanism is highly stereoselective. In addition, from a kinetic investigation on on the copolymerization between L - and D -NCAs, the penultimate chiral centers were also suggested to contribute to the stereoselection. Stereoselection by the α-helical conformation of the growing chain and by a chiral, linear terminal amine have been considered so far, and the contribution from the present type of stereoselection must have been overlooked.     

Effect of 2, 4-D analogues on the induction and maintenance of callus in maize tissue culture1

Six analogues of 2, 4-D: 2(2-methyl-4-chlorophenoxy) propionic, 2(2,4-dichloro-phenoxy) propionic, 2(2-methyl-4-chlorophenoxy) butyric, 2(2,4-dichlorophenoxy) butyric, 2(2,4-dichlorophenoxy) butyric acids and the separated enantiomers of 2(2, 4, 5-trichlorophenoxy) propionic acid were examined for their ability to induce callus development and maintain its growth in maize (Zea mays) tissue cultures. The results indicate that the analogues were more effective than 2, 4-D in both respects and that alkyl substitution on the carbon side chain of the acids increased the auxin effect. It was also shown that only the (+) isomer of the two enantiomers studied, had auxin activity.     

Effect of Amino Acids on Lysosomal Proteolytic Activities in Rat Livers

(R)-2-(4′-Isobutylphenyl)propanoic acid (ibuprofen), (S)-3(4′-isobutylphenyl)butanoic acid and (S)-4-(4′-isobutylphenyl)pentanoic acid were obtained using microbial oxidation of (±)-l-isobutyl-4-(1′ -methyloctyl)benzene by Rhodococcus sp. BPM 1613.     

Long-chain ethers as solvents can amplify the enantioselectivity of the Carica papaya lipase-catalyzed transesterification of 2-(substituted phenoxy)propanoic acid esters

The enantioselectivity of the transesterification of the 2,2,2-trifluoroethyl esters of 2-(substituted phenoxy)propanoic acids, as catalyzed by the lipase from Carica papaya, was greatly improved by using long-chain ethers, such as di-n-hexyl ether, as solvents instead of the conventional diisopropyl ether. Thus, for example, the E value was enhanced from 21 [in diisopropyl ether (0.8 ml)] to 57 [in di-n-hexyl ether (0.8 ml)] in the reaction of 2,2,2-trifluoroethyl(RS)-2-phenoxypropanoate (0.1 mmol) with methanol (0.4 mmol) in the presence of the plant lipase preparation (10 mg); it was also improved from 13 (in diisopropyl ether) to 44 (in di-n-hexyl ether) in the reaction of 2,2,2-trifluoroethyl(RS)-2-(2-chlorophenoxy)propanoate with methanol under the same reaction conditions.     

Fungal Reduction of C6 α,β-Unsaturated Carboxylic Acids

The metabolism of sorbic acid (trans-2,trans-4-hexadienoic acid) and its related compounds by Mucor sp. A-73 was investigated. Sorbic acid was reduced by this fungus to trans-4-hexenol (more than 90% yield). In a series of hexamonoenoic acids, carboxyl groups and α,β-double bond were reduced, but β,γand γ,δ double bonds were hardly reduced. The reduction of cis-2-hexenoic acid was slower than that of the corresponding trans isomer. Sorbic alcohol, one of α,β-unsaturated alcohols, was converted well to trans-4-hexenol by the fungus. These results showed that this fungus could carry out two independent reductions: (i) carboxyl group→alcohol, (ii) α,β-unsaturated alcohol→αβ-saturated one. Furthermore, α,β-unsaturated alcohols were temporarily detected in the course of fungal reductions of some α,β-unsaturated acids. The fact suggested that the reduction of α,β-unsaturated acids to α,β-saturated alcohols was initiated by the reaction (i) and followed by (ii). The biological hydrogenation of α,β-unsaturated alcohols is a new reaction.     

Application of αMNPA to stereochemical studies of monoterpene alcohol

2‐Methoxy‐2‐(1‐naphthyl)propanoic acid (αMNPA) was used to study monoterpene alcohol stereochemically. This reagent has both a rigid chiral center and a high‐resolution naphthyl group for ¹H‐NMR and HPLC analysis. Enantiomeric resolution of citronellol was considered using (−)‐αMNPA and the Mosher‐Trost method was applied to (−)‐menthol using (−)‐ and (+)‐αMNPA. An S configuration is proposed for (−)‐αMNPA based on ¹H‐NMR spectroscopy data. Chirality 11:70–74, 1999. © 1999 Wiley‐Liss, Inc.     

Resolution of racemic carboxylic acids via the lipase‐catalyzed irreversible transesterification of vinyl esters

The lipase‐catalyzed irreversible transesterification procedure using vinyl esters was applied to the resolution of racemic 2‐phenoxypropanoic acids. Aspergillus niger lipase showed high enantioselectivities and reasonable reaction rates. The enantioselectivity was found to be affected profoundly by several variables, e.g., the alcohol as nucleophile, the organic solvent used, and the reaction temperature. A gram‐scale resolution of (RS)‐2‐phenoxypropanoic acid was achieved after optimization of the reaction conditions. Then this irreversible transesterification procedure was applied to the resolution of some related 2‐substituted carboxylic acids. Thus, racemic 2‐methoxy‐2‐phenylacetic acid was resolved via the A. niger lipase‐catalyzed transesterification of the corresponding vinyl ester. 2‐Phenylpropanoic acid and 2‐phenylbutanoic acid were resolved using Pseudomonas sp. lipase. A gram‐scale resolution of 2‐phenylbutanoic acid was achieved by this procedure coupled with the porcine liver esterase‐catalyzed hydrolysis of the resulting methyl ester. Chirality 11:554–560, 1999. © 1999 Wiley‐Liss, Inc.     

Enzymatic resolution of 2-phenoxy-1-propanols through the enantioselective acylation mediated by Achromobacter sp. lipase

2-(Substituted phenoxy)-1-propanols, e.g. 2-(4-chlorophenoxy)-1-propanol, belonging to primary alcohols with an oxygen atom at the stereocenter, were resolved with moderate to good enantioselectivity, as judged by the value of enantiomeric ratio E (up to 27), through the enantioselective acylation with vinyl butanoate mediated by the little-known lipase from Achromobacter sp. in diisopropyl ether, after the examination of potential factors affecting the reaction such as organic solvents and acyl donors.     

Stereoselective enzymatic esterification of 3-benzoylthio-2-methylpropanoic acid

Summary A key intermediate, S-(–)-3-benzoylthio-2-methylpropanoic acid (1) was made in high optical purity by the lipase-catalyzed stereoselective esterification of racemic 1 with methanol in an organic solvent system. Among various lipases evaluated, Amano P-30 lipase from Pseudomonas sp. efficiently catalyzed the esterification of 1 to yield R-(+) methyl ester and unreacted S-(–) 1. A reaction yield of 40 mol% and an optical purity of 97.2% were obtained for compound 1 at a substrate concentration of 0.1 m (22 mg/ml). Lipase P-30 was immobilized on Accurel polypropylene (PP) and the immobilized enzyme was reused (23 cycles) in the esterification reaction without loss of enzyme acitivity, productivity or optical purity. Among various solvents evaluated, toluene was found to be the most suitable organic solvent and methanol was the best alcohol for the esterification of racemic 1 by immobilized lipase. Substrate concentrations as high as 1.0 m were used in the esterification reaction. When the temperature was increased from 28° C to 60° C, the reaction time required for the esterification of 0.1 m substrate decreased from 16 h to 2 h. On increasing the methanol to substrate molar ratio from 1:1 to 4:1, the rate of esterification decreased. A lipase fermentation using Pseudomonas sp. ATCC 21 808 was developed. In the batch-fermentation process, 56 units/ml of extracellular lipase activity was obtained. A fed-batch process using soybean oil gave a significant increase in the lipase activity (126 units/ml). Crude lipase recovered from the filtrate by ethanol precipitation and immobilized on Accurel PP was also effective: S-(–) compound 1 was obtained in 35 mol% yield and 95% optical purity. Offsprint requests to: R. N. Patel     

Reactivity switching and selective activation of C-1 or C-3 in 2,3-unsaturated thioglycosides

Reactivity switching and selective activation of C-1 or C-3 in 2,3-unsaturated thioglycosides, namely, 2,3-dideoxy-1-thio-d-hex-2-enopyranosides are reported. The reactivity switching allowed activation of either C-1 or C-3, with the use of either N-iodosuccinimide (NIS)/triflic acid (TfOH) or TfOH alone. C-1 glycosylation with alcohol acceptors occurred in the presence of NIS/TfOH, without the acceptors reacting at C-3. On the other hand, reaction of 2,3-unsaturated thioglycosides with alcohols mediated by triflic acid led to transposition of C-1 ethylthio-moiety to C-3 intramolecularly, to form 3-ethylthio-glycals. Resulting glycals underwent glycosylation with alcohols to afford 3-ethylthio-2-deoxy glycosides. However, when thiol was used as an acceptor, only a stereoselective addition at C-3 resulted, so as to form C-1, C-3 dithio-substituted 2-deoxypyranosides.     

Synthesis of Optically Active 1,4-Thiazane-3-carboxylic Acid via Optical Resolution by Preferential Crystallization of (RS)-2-Amino-3-[(2-chloroethyl)sulfanyl]propanoic Acid Hydrochloride

Optically active 1,4-thiazane-3-carboxylic acid [TCA] was synthesized from cysteine via optical resolution by preferential crystallization. The intermediate (RS)-2-amino-3-[(2-chloroethyl)sulfanyl]propanoic acid hydrochlo-ride [(RS)-ACS?HCl] was found to exist as a conglomerate based on its melting point, solubility and IR spectrum. (RS)-ACS?HCl was optically resolved by preferential crystallization to yield (R)- and (S)-ACS?HCl. (R)- and (S)-ACS?HCl thus obtained were recrystallized from a mixture of hydrochloric acid and 2-propanol, taking account of the solubility of (RS)-ACS?HCl, efficiently yielding both enantiomers in optically pure forms. (R)- and (S)-TCA were then respectively synthesized by the cyclization of (R)- and (S)-ACS?HCl in ethanol in the presence of triethylamine.     

Stereoselective Synthesis of Ectocarpene and Its Antipode via Microbiological Asymmetric Hydrolysis

Biological asymmetric hydrolysis of ethyl (±)-cycloheptadienecarboxylate with Rhodotorula minuta var. texensis IFO 1102 and chemical resolution of the corresponding carboxylic acid with (?)-quinine provided (R)-(+)-ethyl 2,5-cycloheptadienecarboxylate (78% e.e.) and (S)-(+)-2,5-cycloheptadienecarboxylic acid (95% e.e.), respectively. The (R)-(+)-carboxylate was converted to (R)-(?)-2,5-cycloheptadienylcarbaldehyde and the (S)-(+)-carboxylic acid to (S)-(+)-2,5-cycloheptadienylcarbaldehyde. Ectocarpene (78% e.e.), male-gamete attractant of marine brown alga, and its antipode (95% e.e.) were synthesized by stereoselective Wittig reaction between the (R)-(?)- and (S)-(+)-aldehydes and propyltriphenylphosphonium bromide in a liquid-solid two phase system using 18-crown ether-t-BuOK, respectively.     

Effect of alcohol chain length on the optimum conditions for lipase-catalyzed synthesis of adipate esters

Immobilized Candida antarctica lipase B, Novozym® 435, was used in the esterification of adipic acid and alcohols with different chain lengths (C₁–C₁₈). Optimum conditions for the synthesis of adipate esters were obtained using response surface methodology (RSM) with respect to important reaction parameters including time, temperature, substrate molar ratio and amount of enzyme. Alcohol chain length specificity of the enzyme in the synthesis of adipate esters was also determined. Minimum reaction time (215 min) for achieving maximum ester yield was obtained for butyl alcohol. Methanol required an increased time (358 min) and enzyme amount (10.2%, w/w) for attaining maximum yield. The maximum required temperature and time of 65°C and 523 min, respectively, were obtained for the synthesis of dioctadecyl adipate. The results demonstrate that alcohol chain length is a determining parameter in optimization of the lipase-catalyzed synthesis of adipate esters. Reactions under optimized conditions yielded a high percentage of esterification (>97%). The optimum conditions can be used to scale up the process.     

S-[2-Carboxy-1-(1H-imidazol-4-yl)ethyl]cysteine in normal human urine

Summary A compound, which had the same mobility on a high-voltage paper electrophoretogram and the sameR _F value on a thin-layer chromatogram as those ofS-[2-carboxy-1-(1H-imidazol-4-yl)ethyl]cysteine (I), was partially purified from human urine by ion-exchange column chromatography. The compound gave a signal at m/z 260 on its FAB mass spectrum, which was assigned as MH⁺ of compound I. These results suggest that the urinary compound is compound I and it is a physiological precursor of 3-[(carboxymethyl)thio]-3-(1H-imidazol-4-yl)propanoic acid [Kinuta et al., (1991) Biochem J 275: 617–621].