Reaction equilibrium for lipase-catalyzed condensation in organic solvent systems

Lipase-catalyzed condensation in an organic solvent is useful for the syntheses of esters. To reasonably design and optimize the reaction conditions, knowledge of the reaction equilibrium is required. The interaction of water with other reactants and the quantitative predictions for adsorption of water by a desiccant are discussed. The solvent effects on the reaction equilibrium are also elucidated in mixtures of nitrile and tert-alcohol.     

Reaction equilibrium for lipase-catalyzed condensation in organic solvent systems

Lipase-catalyzed condensation in an organic solvent is useful for the syntheses of esters. To reasonably design and optimize the reaction conditions, knowledge of the reaction equilibrium is required. The interaction of water with other reactants and the quantitative predictions for adsorption of water by a desiccant are discussed. The solvent effects on the reaction equilibrium are also elucidated in mixtures of nitrile and tert-alcohol.     

Tailoring of alginates by enzymatic modification in vitro

High molecular weight alginates having a variety of initial composition and sequential structures were modified with a mannuronan-C-5 epimerase from Azotobacter vinelandii to yield polymers with a high content of guluronic acid and, hence, an enhanced ability to form gels with calcium ions. The monad, diad and triad frequencies in the modified polymers were determined by n.m.r. spectroscopy, and the strength of homogeneous gels prepared from them with calcium ions were measured and compared with those prepared from the starting materials and other naturally occurring alginates. Immobilization of the bacterial enzyme on Eupergite beads greatly increased its stability and favoured high degree of conversion.     

Enzymatic synthesis of the precursor of Leu-enkephalin in water-immiscible organic solvent systems.

The precursor of Leu-enkephalin, Z-L-TyrGlyGly-L-Phe-L-LeuOEt, was synthesized from amino acid derivatives with three proteinases without the protection of the side chain of L-Tyr. First, Z-GlyGlyOBut and Z-L-TyrGlyGlyOBut were synthesized in quite a high yield, 83% and 99%, in an aqueous/organic biphasic system by papain and alpha-chymotrypsin, respectively. Then, Z-L-Phe-L-LeuOEt was synthesized by thermolysin from Z-L-Phe and L-LeuOEt either in buffer or in a biphasic system; the yields were 95% and 100%, respectively. The synthesis of Z-L-TyrGlyGly-L-Phe-L-LeuOEt from Z-L-TyrGlyGly and L-Phe-L-LeuOEt was performed effectively by thermolysin immobilized on Amberlite XAD-7 in a buffer and in an aqueous/organic biphasic system, as well as in saturated ethyl acetate, while the yield was low in reactions by free thermolysin. In the reaction with the immobilized enzyme (IME) in saturated ethyl acetate, the maximum yield of the precursor of Leu-enkephalin was 68%. The reasons for effective synthesis with IME are: (1) higher concentration of L-Phe-L-LeuOEt inside support, which resulted in rising the rate of the synthesis reaction and protecting the competitive hydrolysis of Z-L-TyrGlyGly by thermolysin, (2) entrapment of the product inside the support where thermolysin could not act in the case of reaction in buffer, and (3) extraction of the product with the organic solvent in the case of reaction in a biphasic system or in saturated organic solvent.     

Chemical modification of silk sericin in lithium chloride/dimethyl sulfoxide solvent with 4-cyanophenyl isocyanate

This paper reports chemical modification of silk sericin in LiCl/dimethyl sulfoxide (DMSO) solvent with 4-cyanophenyl isocyanate. Sericin is a highly hydrophilic protein secreted by Bombyx mori, serving as a protein glue in a cocoon. LiCl/DMSO was found to be a good solvent of sericin and useful for homogeneous modification of its abundant hydroxyl groups under nonaqueous condition. Fourier transform infrared (FTIR) analysis of the modified sericins revealed that 4-cyanophenyl groups were incorporated into sericin molecules mainly through urethane linkages. Several characteristics of the modified sericins such as solubility characteristic, hygroscopic property, and thermal stability were investigated. Secondary structure analysis using FTIR spectra suggested that formation of strong intermolecular hydrogen bonds was inhibited by the modification that is probably attributable to the incorporation of bulky 4-cyanophenyl groups. These results demonstrate that chemical modification of sericin using LiCl/DMSO solvent markedly alters its characteristics.     

Chemical modification of alpha-chymotrypsin for obtaining high transesterification activity in low water organic media

Alpha-chymotrypsin was made more hydrophilic by modifying 11 (out of 16) ε-amino groups with pyromellitic dianhydride. The hydrophilic preparation was precipitated with n-propanol. This preparation gave significantly higher initial rates at the optimum a_w (127.51 nmol mg^?1 min^?1 in n-octane and 21.30 nmol mg^?1 min^?1 in acetonitrile at a_w=0.33) compared with the lyophilized preparation (53.50 nmol mg^?1 min^?1 in n-octane and 0.26 nmol mg^?1 min^?1 in acetonitrile at a_w=0.97). FT-IR showed that the precipitate of modified alpha-chymotrypsin has a higher content of alpha-helices and beta-sheets compared to the lyophilized powder.     

Enzyme activation by denaturants in organic solvent systems with a low water content.

The effect of urea and guanidine hydrochloride (GdmCl) on the activity of heart lactate dehydrogenase, glycerol-3-phosphate dehydrogenase, hexokinase, inorganic pyrophosphatase, and glyceraldehyde-3-phosphate dehydrogenase was studied in low-water systems. Most of the experiments were made in a system formed with toluene, phospholipids, Triton X-100, and water in a range that varied over 1.0-6.5% (by vol.) [Garza-Ramos, G., Darszon, A., Tuena de Gómez-Puyou, M. & Gómez-Puyou, A. (1990) Biochemistry 29, 751-757]. In such conditions at saturating substrate concentrations, the activity of the enzymes was more than 10 times lower than in all-water media. However the activity of the first four aforementioned enzymes was increased between 4 and 20 times by the denaturants. The most marked activating effect was found with lactate dehydrogenase; with 3.8% (by vol.) water maximal activation was observed with 1.5 M GdmCl (about 20-fold); 4 M urea activated, but to a lower extent. Activation by guanidine thiocyanate was lower than with GdmCl. The activating and inactivating effects of GdmCl on lactate dehydrogenase depended on the amount of water; as the amount of water was increased from 2.0% to 6.0% (by vol.), activation and inactivation took place with progressively lower GdmCl concentrations. When activity was measured as a function of the volume of 1.5 M GdmCl solution, a bell-shaped activation curve was observed. In a low-water system formed with n-octane, hexanol, cetyltrimethylammonium bromide and 3.0% water, a similar activation of lactate dehydrogenase by GdmCl and urea was observed. The water solubility diagrams were modified by GdmCl and urea, and this could reflect on enzyme activity. However, from a comparison of denaturant concentrations on the activity of the enzymes studied, it would seem that, independently of their effect on the characteristics of the low-water systems, denaturants bring about activation through their known mechanism of action on the protein. It is suggested that the effect of denaturants is due to the release of constraints in enzyme catalysis imposed by a low-water environment.     

Optimization of organic solvent in multiphase biocatalysis

The microbial epoxidation of propene and 1-butene was used to study some fundamental aspects of two-liquid-phase biocatalytic conversions. Introduction of a water-immiscible organic solvent phase in a free-cell suspension gave rise to a series of undesired phenomena, e.g., inactivation by the solvent, clotting of biomass, and aggregation of cells at the liquid-liquid interface. Immobilization of the cells in hydrophilic gels, e.g., calcium alginate, prevented direct cell-organic solvent contact and the related clotting and aggregation of biomass. However, the gel entrapment did not seem to provide additional protection against the organic solvent. The influence of various organic solvents on the retention of immobilized-cell activity was related to solvent properties like the polarity (as expressed by the Hildebrand solubility parameter) and the molecular size (as expressed by the molecular weight or molar volume). High activity retention was favored by a low polarity in combination with a high molecular weight. The solubility parameter also proved useful to describe the capacity of various organic solvents for oxygen and alkene oxides. This facilitated the optimization of the solvent polarity.     

2 methods of preparing solvent systems for the chromatographic separation of organic acids]

The solvent system of alcohol-acid-water gradually forms an equilibrated amount of ester which facilitates the separation of di- and tri-carboxylic acids on paper chromatograms. Using the system of n-butanol-formic acid-water (3:1:1) as an illustration, two methods of accelerating the system ageing are demonstrated: 1) butanol-acid mixture at a required ratio is kept for several hours before water is added and 2) butanol-acid mixture is passed through the KU-2 layer in the H-form. The effect identical to that achieved as a result of 5-day storage of the solvent system under usual conditions can be reached with the first scheme during 6 hours and with the second scheme during 20-30 min.     

The modification of the membrane of Oceanomonas baumannii when subjected to both osmotic and organic solvent stress

Oceanomonas baumanniioff a novel halotolerant bacterium which was isolated from the estuary of the river Wear (Sunderland, UK). When grown in tryptone soya broth it can tolerate high levels of phenol, which is not utilised as a carbon source in this medium. However, the level of tolerance was reduced from 35 mM to 3 mM phenol as salinity increased from 1% to 12% NaCl (w/v). Increasing salinity up to 12% NaCl also decreased the growth rate 8-fold and caused modifications to the cytoplasmic membrane particularly anionic phosphatidylglycerol levels, which doubled at the expense of zwitterionic phosphatidylethanolamine. In addition, changes in the phospholipid fatty acid composition were noted, cis-vaccenic acid decreased significantly at higher salinities. Intracellular solute levels also increased with increasing salinity and there was an accumulation of the compatible solutes ectoine, glycine betaine and glutamate. The addition of phenol to osmotically compromised cultures led to a further modification of the cytoplasmic membrane phospholipid composition, in particular, that the decrease in zwitterionic phosphatidylethanolamine and the increase of anionic phospholipid species was much less pronounced. A further decrease in unsaturation, particularly in the proportion of cis-vaccenic acid, and the mean chain length of the fatty acids suggested that this response was important in maintaining membrane integrity in the presence of phenol.     

Chemical modification of heparin

Heparin was modified at carboxyl groups by reaction with several pharmacologically important amino-containing compounds in aqueous medium in the presence of 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide. In dependence on the nature of the amine and the ratio of reagents, conjugates containing 36–100% amide and 0–25% isoureidocarbonyl groups were synthesized. Isoureidoarylamide groups are present, along with amide moieties, in the products of heparin modification by hydroxyl-containing aromatic amines. The conjugate of heparin with p-aminobenzoic acid contained oligomeric arylamide.     

Chemical modification of heparin

Heparin was modified at carboxyl groups by reaction with several pharmacologically important amino-containing compounds in aqueous medium in the presence of 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide. In dependence on the nature of the amine and the ratio of reagents, conjugates containing 36-100% amide and 0-25% isoureidocarbonyl groups were synthesized. Isoureidoarylamide groups are present, along with amide moieties, in the products of heparin modification by hydroxyl-containing aromatic amines. The conjugate of heparin with p-aminobenzoic acid contained oligomeric arylamide.     

Chemical modification of neamine

The aminocyclitol antibiotic neamine has been modified by changing the configuration of one or two hydroxyl groups of the aminocyclitol moiety to elucidate the relationship between configuration and antimicrobial activity. 5-Epi-, 6-epi-, and 5,6-diepineamine have been prepared and their antimicrobial activity has been determined against several micro-organisms.     

Stability of bilirubin oxidase in organic solvent media: a comparative study on two low-water systems

The storage stability of bilirubin oxidase was studied in water-in-oil CTAB microemulsions with a chloroformrich continuous organic phase. The kinetics of the inactivation process were best described by a double exponential equation. Approximately half of enzymatic activity was lost during a "fast" phase with a half life of ca. 50 min, whereas the remaining activity was lost much more slowly (half life ca. 1000 min). Rates of inactivation were not affected significantly by variation of either solvent composition or concentration of water droplets, but inactivation was more rapid when droplet size was very small. Steady-state enzyme kinetics were studied at various stages in the inactivation process, and it was shown that inactivation occurred without change in the K(m) of the enzyme for bilirubin. Stability was also studied in a liquid/solid two-phase system; it was found that the inactivation process in this system; it was found that the inactivation process in this system was best described by a single exponential term. The rate was similar to the "fast" phase rate observed in the water-in-oil microemulsion system. Inactivation of the enzyme slow. Addition of the surfactant CTAB to the aqueous environment increased the rate of inactivation to levels comparable to those of the "slow" phase observed in water-in-oil microemulsions. (c) 1993 Wiley & Sons, Inc.     

Lipase catalyzed polytransesterification in an organic solvent

Summary Lipase-catalyzed polytransesterification ofbis(2,2,2-trifluoroethyl) dodecanedioate with aliphatic diols (from 1,2-ethanediol to 1,6-hexanediol) was studied with 4 enzymes and a number of solvents. The effects of experimental parameters were investigated with the purpose of obtaining a polyester of as high as possible average molar mass. The highest mass average molar mass (M _w) of 34,750 g mol^-1 (DP = 122) was obtained under vacuum with 1,4-butanediol,Mucor miehei lipase, and diphenyl ether as solvent.     

Enzymes in preparative organic synthesis. Chemical equilibrium in countercurrent biphasic water-organic systems

Summary It is suggested to use biphasic water-organic systems with two flows moving in opposite directions (countercurrent) as a medium for enzymatic organic synthesis. Theoretical consideration and experimental verification are presented.     

Yeast-mediated preparation of l-PAC in an organic solvent

The yeast-mediated acyloin condensation of benzaldehyde and pyruvic acid to form l-PAC occurs in a petroleum spirit solvent system at room temperature with moderate conversion (30%) and high enantioselectivity (86%ee) after 24 h. The addition of a small amount of ethanol (0.5% mL) to the reaction mixture inhibits the formation of the side product benzyl alcohol and increases the conversion to l-PAC. Conducting the reaction using 13C labeled pyruvate indicated that the pyruvate was incorporated into the l-PAC and that the excess pyruvate was converted into ethanol. Conducting the reaction at 5 degrees C results in similar conversion but higher enantioselectivity.     

Biocatalysis of lipoxygenase in selected organic solvent media

The biocatalysis of purified soybean lipoxygenase (LOX) (EC 1.13.11.12), using linoleic acid as a substrate model, was investigated in selected organic solvent media, including chloroform, dichloromethane, hexane, iso-octane, octane and toluene. The results indicated that there was a 2.6-fold increase in LOX activity in the monophasic iso-octane medium compared to that obtained in the aqueous medium. The results also showed that there was an increase of 2.2- and 1.8-fold in LOX activity in the monophasic reaction media of octane and hexane, respectively. However, an inhibitory effect on enzyme activity was observed when the monophasic reaction media of toluene, chloroform and dichloromethane were used. In addition, the results showed that the optimum concentration of octane and iso-octane in the biphasic medium containing the organic solvent and Tris–HCl buffer solution, was determined to be 3.5% and 4%, respectively, for LOX activity. Moreover, the biocatalysis of LOX in a ternary micellar system, containing either 3.5% octane or 4% iso-octane, Tris–HCl buffer solution and an emulsifier, resulted in an overall increase in enzyme activity. The K_m and V_max values, substrate specificity, optimum protein concentration, optimum reaction temperature as well as the enzymatically catalyzed end-products were investigated for LOX biocatalysis in both ternary micellar systems.     

Lipase-catalyzed transamidation of non-activated amides in organic solvent

A novel biocatalytic reaction of transamidation of non-activated amides with amines is reported. Among 45 different lipolytic and proteolytic enzymes tested, only the lipase from Candida antarcticawas able to catalyze this reaction. The reaction proceeded with up to ca. 80% conversion in anhydrous methyl tert-butyl ether and worked with both N-substituted and unsubstituted amides. The biocatalytic transamidation is an equilibrium process and, therefore, higher conversions to the desired amide were achieved by using increased concentrations of the amine nucleophile.