Amino acid esterification by alpha-chymotrypsin immobilized in spiropyran membrane.

α-Chymotrypsin was immobilized in a collagen membrane modified with a spiropyran compound. The immobilized chymotrypsin was used for the esterification of N-acetyl-l-tyrosine (AT). N-Acetyl-l-tyrosine ethyl ester (ATEE) was synthesized from AT and ethanol by immobilized chymotrypsin under visible light. The optimum pH for the esterification was 7. An increase of the chymotrypsin content in the spiropyran-collagen membrane increased the rate and the yield of ATEE. The yield of ATEE reached 40% under visible light. Initially, ATEE was synthesized in the dark. However, the ATEE synthesized was gradually hydrolyzed in the dark. The amount of ATEE in the reaction mixture increased with irradiation by visible light and decreased in the dark. Therefore, the esterification of N-acetyl-l-tyrosine was controlled by light irradiation.     

Peptide synthesis by proteases in organic solvents: medium effect on substrate specificity.

The substrate specificities of alpha-chymotrypsin and subtilisins for peptide synthesis in hydrophilic organic solvents were investigated. Chymotrypsin exhibited high specificity to aromatic amino acids as acyl donors, while subtilisin Carlsberg and subtilisin BPN' were specific to aromatic and neutral aliphatic amino acids, in accordance with the S1 specificities of the enzymes for peptide hydrolysis in aqueous solutions. On the contrary, chymotrypsin exhibited higher specificities to hydrophilic amino acid amides as acyl acceptors (nucleophiles) for peptide synthesis with N-acetyl-L-tyrosine ethyl ester, in contrast to the S1' specificity for peptide hydrolysis and peptide synthesis in aqueous solutions. Furthermore, nucleophile specificity changed with the change in water-organic solvent composition; the increase in water content led to increase in relative reactivity of leucinamide to that of alaninamide. It was also found that protection of the carboxyl group of alanine by amidation is much preferable to protection by esterification in terms of reactivity as nucleophiles.     

Enzymatic reactions in aqueous-organic media. IV. Chitin-alpha-chymotrypsin complex as a catalyst for amino acid esterification and peptide synthesis in organic solvents

Summary Chitin--chymotrypsin complex was found to be an effective catalyst for the esterification of N-acetyl-L-tryptophan in ethanol and for peptide synthesis from N-acetyl-L-tyrosine and glycinamide in acetonitrile. In the former reaction both initial rate of ester formation and equilibrium yield of the ester markedly increased by the complexation of chymotrypsin with chitin compared to free chymotrypsin.     

The isoinhibitors of chymotrypsin/elastase from Ascaris lumbricoides: the reactive site

Five isoinhibitors of chymotrypsin/elastase present in aqueous extracts of Ascaris were isolated. The reactive site in each isoinhibitor, the peptide bond that during encounter is positioned over the catalytic site in chymotrypsin, is Leu-Met. This bond was hydrolyzed by incubating intact isoinhibitors with 5-25 mol% chymotrypsin at pH 3.2 for 4-6 days (isoinhibitor 1) or 2.5-5 weeks (isoinhibitors 2-5). The reaction under these conditions did not proceed beyond 60% modified isoinhibitor (peptide bond hydrolyzed) and 40% intact inhibitor. The Leu-Met bond, hydrolyzed in modified isoinhibitor, can be resynthesized at pH 7.6 by incubating modified inhibitor with a stoichiometric amount of chymotrypsin bound to Sepharose CL-4B and then dissociating the complex in a kinetically controlled fashion with 5% trichloroacetic acid. The product, intact inhibitor, was obtained in greater than 80% yield. The site in the isoinhibitor that is positioned over the catalytic site in elastase during encounter is the same as for encounter with chymotrypsin. The Leu-Met bond hydrolyzed during encounter with elastase can be resynthesized by chymotrypsin. Chymotrypsin and elastase bind to the inhibitor at the same site.     

Modification of Lipase by Polyethylene Glycol

Lipase was modified using polyethylene glycol activated by p-nitrochloroformate. The hydrolytic activity of the polyethylene glycol-derivatised lipase (PEG-lipase) was relatively low compared with that of the unmodified enzyme in aqueous system. The esterification activity, however, was enhanced following the modification. The rate of esterification of butyric acid was higher than that of oleic acid. Benzene was the best solvent for the esterification reaction.     

Recombinant Lucilia sericata chymotrypsin in a topical hydrogel formulation degrades human wound eschar ex vivo

Larval biotherapy is a debridement tool used in wound management. The mechanism of action involves degradation of eschar by serine proteases including chymotrypsin within the alimentary fluids of first instar Lucilia sericata. With the rationale of obviating some limitations of biotherapy, including cost, complexity of use, and patient reticence, the present study describes a mobile hydrogel formulation containing freeze-dried recombinant L. sericata chymotrypsin designed for topical application. Neither freeze-drying nor formulation into the hydrogel significantly attenuated the measured activity of released enzyme compared to fresh-frozen enzyme in aqueous solution. Gel electrophoresis confirmed qualitatively that the chymotrypsin/hydrogel formulation both with and without supplementary urea at 10% (w) /(v) degraded human chronic wound eschar ex vivo. Mindful that the hallmark of intractability of chronic wounds is aberrant biochemistry, the pH activity profile for the enzyme/hydrogel formulation was compared with exudate pH in chronic wounds of mixed aetiology in a cohort of 48 hospital in-patients. Five patients' wounds were acidic, however, the remainder were predominantly alkaline and coincided with the pH optimum for the insect enzyme. Thus, a recombinant L. sericata chymotrypsin and hydrogel formulation could represent a pragmatic alternative to larval therapy for the management of chronic wounds.     

Effect of immiscible organic solvents on activity/stability of native chymotrypsin and immobilized-stabilized derivatives

We have developed different activity/stability tests to evaluate the possibilities of fully dispersed chymotrypsin derivatives as industrial catalysts in biphasic systems. We have tested different immiscible organic solvents (log P ranged from 0.65 to 2.8) and used different enzyme derivatives (soluble chymotrypsin and one-point and multipoint covalent attached derivatives). Special emphasis has been given to the role of the "exact composition of the aqueous phase."High phosphate concentrations largely protect every hymotrypsin derivative from the distorting effects of dissolved solvent molecules. The effects on the activity and stability of soluble chymotrypsin due to saturating solvent concentrations in an aqueous solution, and the much more severe effects of contact with the phase interface in a stirred biphasic system, all show the opposite trend for the influence of solvent polarity to that generally observed for biocatalysts. For example, deleterious effects decline in the order chloroform, dichloromethane, ethyl acetate. On the contrary, with or without stirring, our stabilized chymotrypsin-agarose derivatives are much more stable against these water-immiscible solvents, and their relative effects follow the normal trend. From these integrated activity and stability tests we can conclude that fully dispersed immobilized-stabilized derivatives seem to be an interesting alternative to develop industrial biphasic processes catalyzed by chymotrypsin.     

Conformation and stability of the chymotrypsin inhibitor from winged bean seed (Psophocarpus tetragonolobus (L.) DC)

Spectrophotometric measurement was found to be a sensitive method for evaluating the stability of the chymotrypsin inhibitor from the winged bean. The thermal stability of this protein in aqueous solution was much greater at pH 3 than at pH 8 or pH 11. Evidence from u.v. absorption and from circular dichroism indicated that irreversible conformation changes occurred at higher temperature (greater than 70 degrees). Circular dichroism and optical rotatory dispersion studies at pH 8 show that the inhibitor is rich in beta-structure and virtually devoid of alpha-helix in aqueous solution. We conclude from experiments with denaturing solvents that the inhibitor is very stable and that high concentrations of denaturant are required before unfolding occurs. Chemical modification experiments with tetranitromethane were consistent with a tight stable structure; even in 6M guanidine hydrochloride only three of the five tyrosine residues in the inhibitor molecule were nitrated. However, tyrosine does not seem to be implicated at the reactive site of the inhibitor. Interaction of the inhibitor with alpha-chymotrypsin and chymotrypsin B was also followed by difference spectroscopy in the ultraviolet region. Difference spectra were detected that were characteristic of changes in the environment of both tyrosine and tryptophan chromophores. Comparison of the spectral data obtained for the interaction of the inhibitor with bovine alpha-chymotrypsin and with chymotrypsin B indicated that a tryptophan residue may be involved at the reactive site of the inhibitor. Spectral changes were also detected for the interaction between the chymotrypsin inhibitor and trypsin, although it is well established that the specificity of this inhibitor is restricted to the chymotrypsins.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characteristics of chymotrypsin modified with water-soluble acylating reagents and its peptide synthesis ability in aqueous organic media.

Several kinds of modified chymotrypsin were prepared with water-soluble acylating reagents, and their characteristics after hydrolyzing with unmodified chymotrypsin in aqueous-N,N'-dimethylformamide (DMF) media were compared. It was found that chymotrypsin (Csin), of which a 20% amino group was modified with a benzyloxycarbonyl group (Z(20)Csin), had more favorable characteristics than unmodified chymotrypsin with regard to hydrolytic activity in an aqueous DMF media. We also investigated the Z(20)Csin-catalyzed peptide synthesis in two different solution systems. In the one-layer system containing water and DMF, Z(20)Csin catalyzed the peptide bond formation in a higher yield than that by unmodifide chymotrypsin and enabled a synthetic reaction in even an 80% (v/v) DMF media, in which the hydrolytic reaction could not be carried out. Z(20)Csin catalyzed the condensation between some N-acyl amino acids or peptide derivatives and amino acids in 90% ethylacetate, 90% hexane or 50% benzene. This latter method employs a two-layer system, and the modified enzyme may be able to reduce the number of synthetic steps when preparing acyl peptides.     

Polyvinyl alcohol--trypsin as a catalyst for amino acid ester synthesis in organic media

The bovine trypsin-catalyzed synthesis of N-alpha-benzoyl-DL-arginine esters from N-benzoyl-DL-arginine were studied in various organic solvents. Trypsin was immobilized to polyvinyl alcohol (PVA) by adsorption from its aqueous solutions. Immobilized enzyme showed higher catalytic activities than free enzyme for amino acid esterification in ethanol. The yield of ester is strongly dependent upon the PVA/trypsin ratio and water content in the reaction medium. The rate and equilibrium constant of the ester formation reaction are also dependent on water content.     

Lipase in biphasic alginate beads as a biocatalyst for esterification of butyric acid and butanol in aqueous media

Esterification of organic acids and alcohols in aqueous media is very inefficient due to thermodynamic constraints. However, fermentation processes used to produce organic acids and alcohols are often conducted in aqueous media. To produce esters in aqueous media, biphasic alginate beads with immobilized lipase are developed for in situ esterification of butanol and butyric acid. The biphasic beads contain a solid matrix of calcium alginate and hexadecane together with 5 mg/mL of lipase as the biocatalyst. Hexadecane in the biphasic beads serves as an organic phase to facilitate the esterification reaction. Under optimized conditions, the beads are able to catalyze the production of 0.16 mmol of butyl butyrate from 0.5 mmol of butyric acid and 1.5 mmol of butanol. In contrast, when monophasic beads (without hexadecane) are used, only trace amount of butyl butyrate is produced. One main application of biphasic beads is in simultaneous fermentation and esterification (SFE) because the organic phase inside the beads is very stable and does not leach out into the culture medium. SFE is successfully conducted with an esterification yield of 6.32% using biphasic beads containing iso-octane even though the solvent is proven toxic to the butanol-producing Clostridium spp.     

Peptide Synthesis Catalyzed by Crosslinked α-Chymotrypsin in Water/Dimethylformamide Solvent System

-Chymotrypsin was crosslinked to give a water-insoluble polymer by treatment with the bifunctional reagent glutaraldehyde. The specific activity of the crosslinked enzyme in aqueous media was three orders of magnitude lower than for the native chymotrypsin. In a medium containing more than 50% (v/v) of dimethylformamide the specific activities of both enzymes were comparable. In addition, the insoluble polymer was more stable in the presence of 60% (v/v) dimethylformamide compared with the native enzyme. Therefore, in this medium enzymatic peptide synthesis could be successfully accomplished with the crosslinked enzyme, but not with the same amount of native chymotrypsin.     

微环境对脂肪酶催化拆分外消旋2－辛醇的影响

微环境对脂肪酶催化拆分外消旋２－辛醇的影响　　　　　　　杨红,曹淑桂,韩四平,黄仲丽,杨同书（吉林大学酶工程国家重点实验室,长春１３００２３）手性２－辛醇不仅是制备液晶材料不可缺少的重要手性原料,也是合成具有光学活性的医药和农药的重要手性中间体．本文...     

Enzymatic production of enantiopure ketoprofen in a solvent-free two-phase system

Enzymatic hydrolysis conducted in a medium composed of solely substrate is considered to resolve racemic ketoprofen esters. In a system composed of two components, the pure liquid substrate (organic phase) and water (aqueous phase), hydrolysis products can be efficiently removed from the reaction mixtures. Accordingly, in this study we designed a solvent-free two-phase system for the enantioselective enzymatic hydrolysis of ketoprofen esters. In order to further optimize this system, the influences of various factors, such as the pH of the aqueous phase, temperature, enzyme content, and the alcohol chain length of esters, were examined on conversion and enantiomeric excess. 1N NaHCO₃ was identified as the most efficient aqueous phase for the extraction of ketoprofen. Changes in the amount of enzyme did not significantly affect the maximum conversion or the enantiomeric excess. On the other hand, ketoprofen esters with shorter alcohol chains displayed higher initial reaction rates and conversions in solventless media. In the case of ketoprofen propyl ester, for example, the productivity of the solvent-free two-phase system was about 10–100 times higher than that obtained to date for ketoprofen esterification with alcohols in organic solvents. The enantioselectivities obtained in solvent-free media were similar to those obtained for the enantioselective esterification of ketoprofen in organic solvents.     

Structures of Gibberellins A33 and A34 from Immature Seeds of Calonyction aculeatum

Several kinds of modified chymotrypsin were prepared with water-soluble acylating reagents, and their characteristics after hydrolyzing with unmodified chymotrypsin in aqueous-N,N’ -dimethylformamide (DMF) media were compared. It was found that chymotrypsin (Csin), of which a 20% amino group was modified with a benzyloxycarbonyl group (Z(20)Csin), had more favorable characteristics than unmodified chymotrypsin with regard to hydrolytic activity in an aqueous DMF media. We also investigated the Z(20)Csin-catalyzed peptide synthesis in two different solution systems. In the one-layer system containing water and DMF, Z(20)Csin catalyzed the peptide bond formation in a higher yield than that by unmodifide chymotrypsin and enabled a synthetic reaction in even an 80% (v/v) DMF media, in which the hydrolytic reaction could not be carried out. Z(20)Csin catalyzed the condensation between some N-acyl amino acids or peptide derivatives and amino acids in 90% ethylacetate, 90% hexane or 50% benzene. This latter method employs a two-layer system, and the modified enzyme may be able to reduce the number of synthetic steps when preparing acyl peptides.     

Esterified coir pith as an adsorbent for the removal of Co(II) from aqueous solution

Coir pith was chemically modified for the adsorption of cobalt(II) ions from aqueous solution. Chemical modification was done by esterification using succinic anhydride followed by activation with NaHCO(3) in order to improve the adsorption of Co(II). Adsorptive removal of Co(II) from aqueous solution onto modified coir pith was evaluated in batch studies under varying conditions of agitation time and metal ion concentration to assess the kinetic and equilibrium parameters. A pseudo-second-order kinetic model fitted well for the sorption of Co(II) onto modified coir pith. Sorption kinetics showed that the loading of Co(II) by this material was quite fast under ambient conditions. The Langmuir and Freundlich equilibrium isotherm models provided excellent fits for the adsorption data, with R(2) of 0.99 and 0.98, respectively. After esterification, the maximum Co(II) sorption loading Q(0); was greatly improved. It is evident that chemically modified adsorbent exhibits better Co(II) removal capability than raw adsorbent suggesting that surface modification of the adsorbent generates more adsorption sites on its solid surface for metal adsorption. A complete recovery of the adsorbed metal ions from the spent adsorbent was achieved by using 1.0N HCl.     

A differential scanning calorimetric study of chymotrypsin in the presence of added polymers

Scanning calorimetry measurements of different amounts of chymotrypsin in water alone gave a temperature of denaturation (T(d)) value of 54 degrees C. However, when high-molecular-weight poly(ethylene glycol) was added to aqueous solutions of chymotrypsin, the thermostability of the enzyme was enhanced. For example, the addition of 20% (w/w) of poly(ethylene glycol) of molecular weight of 100,000 increased the T(d/) value to 66 degrees C. In toluene containing various amounts of added water, ethyl cellulose was used to improve the thermostability of chymotrypsin. For this system, a T(d) value of 82 degrees C was obtained with a 20% (w/w/) concentration of ethyl cellulose and 2% (v/v) of added water. Polymers in these solvents interact with water, which could otherwise denature the enzyme; polymers also from complexes with enzyme molecules to produce a more stable structure. (c) 1994 John Wiley & Sons, Inc.     

The effect of temperature on the kinetics of a reverse micellar protein extraction process

Summary The kinetics of transfer of chymotrypsin from an aqueous into a reverse micellar phase and vice versa has been examined for a two-phase system with planar interface equipped with vibrating disks for separate mixing of both phases. The temperature dependence of the mass-transfer coefficients gives two values for the forward transfer (30 and 90 kJ/mol) depending on the temperature range. Only one value is obtained for the backward transfer (60kJ/mol).     

The activity of PEG-modified chymotrypsin in aqueous and organic media

Summary Polyethylene glycol-modified chymotrypsin was prepared by activation of monomethoxypolyethylene glycols with phenylchloroformates and subsequent coupling with free enzyme. The modification was correlated with enzyme activity in aqueous solution and in organic solvents. The activity in aqueous solution was high (80% of that of non-modified enzyme), even at high degrees of modification. The modified protease was soluble in benzene and DMF and catalyzed transesterification in cyclohexane.     

Studies on the extraction of DesPro(2)-Val15-Leu17-aprotinin from the culture broth of a recombinant Saccharomyces cerevisiae.

The application of an aqueous two-phase system is described for the extraction of DesPro(2)-Val15-Leu17-aprotinin from yeast culture supernatant, using native chymotrypsin as affinity ligand. The interaction is driven by hydrophobic forces and leads to the accumulation of the aprotinin-chymotrypsin complex in the salt-rich (bottom) phase of a polyethyleglycol/salt system. The complex may be dissociated at low pH values. The separation of the recombinant aprotinin and the protease required chromatographic processes, which proved difficult to interface with the affinity extraction.