On enzymatic activity in organic solvents as a function of enzyme history

Catalytic activities of alpha-chymotrypsin and subtilisin Carlsberg in various hydrous organic solvents were measured as a function of how the enzyme suspension had been prepared. In one method, lyophilized enzyme was directly suspended in the solvent containing 1% water. In another, the enzyme was precipitated from its aqueous solution by a 100-fold dilution with an anhydrous solvent. In most cases, the reaction rate in a given nonaqueous enzymatic system strongly (up to an order of magnitude) depended on the mode of enzyme preparation. The magnitude of this dependence was markedly affected by the nature of the solvent and enzyme. A mechanistic hypothesis proposed to explain the observed dependencies was verified in additional experiments in which the water contents and enzyme history were further varied.     

Solid-state nuclear magnetic resonance investigation of solvent dependence of tyrosyl ring motion in an enzyme

Tyrosyl ring motions in alpha-lytic protease were investigated by solid-state deuterium nuclear magnetic resonance (NMR) spectroscopy in lyophilized enzyme powder, in powder suspended in organic solvents, and in aqueous crystals. Ring flipping rates were determined by examining deuterium quadrupole echo line shapes. Of the four Tyr residues in the enzyme, one was flipping at the slow (< or =10(3) s(-1)) and one at the fast (> or =10(7) s(-1)) exchange limit of the line shape experiment in all the environments tested. Flipping rates of the remaining two Tyr residues depended markedly on the solvent, with the lowest flipping rates (< or =10(3) s(-1) for both residues) observed in the enzyme powder, whether dry or suspended in hydrophobic tert-butyl methyl ether. In hydrophilic dioxane and acetonitrile, the mobility of these residues increased to 10(4) and 10(5) s(-1). The latter rate rose further to 10(6) s(-1) in the hydrated hydrophilic solvents and to > or =10(7) s(-1) in aqueous crystals. The deuterium spectrum of native alpha-lytic protease was compared with that of the enzyme whose active center was covalently modified with an inhibitor, which binds next to Tyr-123, constraining its ring. This experiment revealed that water addition to acetonitrile specifically increased the flipping rate of this active center residue. Librational motions ("wobbling"), estimated by their effect on spin-lattice relaxation times, were slowest in the anhydrous solvents, intermediate in the hydrated solvents, and fastest in the aqueous crystals. Thus, alpha-lytic protease is more rigid in organic solvents than in water, as judged by mobility of its tyrosyl residues. Water stripping by hydrophilic solvents did not increase enzyme rigidity, nor were there clear correlations between mobility and either enzymatic activity or solvent dielectric constant.     

Stability of protease in organic solvent: structural identification by solid-state NMR of lyophilized papain before and after 1-propanol treatment and the corresponding enzymatic activities

Lyophilized enzyme powder is often used in organic solvents. However, the enzymatic activity decreases during the reaction process. In the present study, the relation between structural stability and enzymatic activity in an organic solvent was investigated. 13C cross-polarization magic angle spinning NMR spectroscopy was used to determine the secondary structure of lyophilized papain in the solid-state. Deconvolution of the peaks of the backbone carbonyl carbons suggested that the proportion of beta-sheet conformation increased after lyophilization from a phosphate buffer solution. The esterification of N-benzyloxycarbonyl phenylalanylalanine amide was attempted using the lyophilized papain as a catalyst in anhydrous 1-propanol. The yield of ester was 46.1% after 48 h at 50 degrees C, but this reaction slowed remarkably after 48 h. When the lyophilized papain was suspended in anhydrous 1-propanol for 7 days without the substrate, the proportion of beta-sheet conformation was further increased and the suspended papain had no activity. These results suggest that the increase in beta-sheet conformation caused inactivation of papain. The increase in beta-sheet conformation caused by both lyophilization and suspension in propanol was found, which was related to a decrease in enzymatic activity.     

Variations in the enantioselectivity of salt-activated subtilisin induced by lyophilization

Including excess salt during lyophilization has been shown to increase the activity of freeze-dried subtilisin Carlsberg (SC) in anhydrous media by over 20,000-fold [Ru et al. (1999) Biotechnol Bioeng 63:233-241]. In the present study, salt-activated SC (KCl-SC) showed a 30% enhancement in enantioselectivity compared to the salt-free enzyme in a variety of organic solvents. Activity toward both enantiomers of N-acetyl-phenylalanine methyl ester (APME) increased in tandem by 2-3 orders of magnitude in all solvents, indicating that the mechanism of salt activation is inherent to the enzyme and does not strongly favor one enantiomer over the other. However, activity and enantioselectivity of salt-activated SC could be manipulated through changes in the lyophilization conditions. Variations in lyophilization time, initial KCl concentration, and initial lyophilization volume altered enantioselectivity over 2-fold. The changes in enantioselectivity reflected the activity for the L enantiomer, while the activity toward the D enantiomer was mostly unaffected. The results indicate that the lyophilization time and final water content of the KCl-SC are important determinants of enzyme activity for the L enantiomer, suggesting that the favored reaction is more sensitive to the structural integrity of the salt-activated enzyme.     

Maintenance of quaternary structure in the frozen state stabilizes lactate dehydrogenase during freeze-drying

Sugars inhibit protein unfolding during the drying step of lyophilization by replacing hydrogen bonds to the protein lost upon removal of water. In many cases, polymers fail to inhibit dehydration-induced damage to proteins because steric hindrance prevents effective hydrogen bonding of the polymer to the protein's surface. However, in certain cases, polymers have been shown to stabilize multimeric enzymes during lyophilization. Here we test the hypothesis that this protection is due to inhibition of dissociation into subunits during freezing. To test this hypothesis, as a model system we used mixtures of lactate dehydrogenase isozymes that form electrophoretically distinguishable hybrid tetramers during reversible dissociation. We examined hybridization and recovery of catalytic activity during freeze-thawing and freeze-drying in the presence of polymers (dextran, Ficoll, and polyethylene glycol), sugars (sucrose, trehalose, glucose), and surfactants (Tween 80, Brij 35, hydroxy-propyl beta-cyclodextrin). The surfactants did not protect LDH during freeze-thawing or freeze-drying. Rather, in the presence of Brij 35, enhanced damage was seen during both freeze-thawing and freeze-drying, and the presence of Tween 80 exacerbated loss of active protein during freeze-drying. Polymers and sugars prevented dissociation of LDH during the freezing step of lyophilization, resulting in greater recovery of enzyme activity after lyophilization and rehydration. This beneficial effect was observed even in systems that do not form glassy solids during freezing and drying. We suggest that stabilization during drying results in part from greater inherent stability of the assembled holoenzyme relative to that of the dissociated monomers. Polymers inhibit freezing-induced dissociation thermodynamically because they are preferentially excluded from the surface of proteins, which increases the free energy of dissociation and denaturation.     

Active-site titration of serine proteases in organic solvents

Calculation of kinetic constants of an enzymatic reaction in organic solvents requires knowledge of the functional active-site concentration in organic solvents, and this can be significantly different than that in water. An experimental method for active-site titration of serine proteases in organic media has been developed based on the kinetics of inhibition by phenylmethanesulfonyl fluoride (PMSF), a serine-specific inhibitor (or suicide substrate). This kinetic approach is fundamentally different from other techniques that require complete titration of all accessible enzyme active sites. This active site titration method was applied to subtilisins BPN' and Carlsberg and alpha-chymotrypsin and resulted in fractions of active sites that ranged from 8 to 62% (of the fraction active in water) depending on the enzyme, the method of enzyme preparation, and the organic solvent used. The active-site concentration of subtilisin BPN' and Carlsberg increased with increasing hydrophobicity of the solvent and with increasing solvent hydration in tetrahydrofuran. The dependence of the fraction of active sites on the nature of the organic solvent appears to be governed largely by solvent-induced inactivation caused by direct interaction of a hydrophilic solvent with the enzyme. (c) 1996 John Wiley & Sons, Inc.     

Activity and flexibility of alcohol dehydrogenase in organic solvents

The oxidation of cinnamyl alcohol to cinnamaldehyde by horse liver alcohol dehydrogenase (LADH) was carried out in nearly anhydrous organic solvents and in solvents containing from 0.1 to 10% added water. In nearly anhydrous solvents containing less than 0.02% water, the oxidation rate increased as the water solubility in the solvent decreased, but the reaction did not require active LADH. Moreover, the highest activity in nearly anhydrous heptane was obtained by lyophilizing the enzyme from a solution of pH 2.0, even though LADH exhibits virtually no enzymatic activity in water at this pH. The catalytic activity of LADH was restored and increased dramatically as small amounts of water were added to each solvent. In conjunction with the activity measurements, electron paramagnetic resonance (EPR) spectroscopy and two active-site directed spin labels were used to examine solvent-dependent structural features of LADH. The EPR spectra indicated that LADH became more rigid as the dielectric constant of the solvent decreased. The degree of rigidity also depended on the pH from which the enzyme was lyophilized, indicating that the ionization state of the enzyme can have an important influence on its dynamics in organic solvents. Finally, adding 1% water to organic solvents had no apparent effect on the enzyme's conformation or flexibility near the spin label, even though enzyme activity was an order of magnitude higher when 1% water was present.     

Inhibitor-induced enzyme activation in organic solvents

The enzymatic activity of the protease subtilisin in anhydrous organic solvents can be dramatically increased by pretreating the enzyme before it is placed in the nonaqueous medium. For instance, lyophilization of subtilisin from aqueous solution containing competitive inhibitors (followed by their removal) created an enzyme which was up to 100 times more active than the enzyme lyophilized in the absence of such ligands. This phenomenon of ligand-induced "enzyme memory" also extends to the stability, affinity, and substrate specificity of subtilisin in organic solvents.     

Dramatic enhancement of enzymatic activity in organic solvents by lyoprotectants

When seven different hydrolytic enzymes (four proteases and three lipases) were lyophilized from aqueous solution containing a ligand, N-Ac-L-Phe-NH(2), their catalytic activity in anhydrous solvents was far greater (one to two orders of magnitude) than that of the enzymes lyophilized without the ligand. This ligand-induced activation was expressed regardless of whether the substrate employed in organic solvents structurally resembled the ligand. Furthermore, nonligand lyoprotectants [sorbitol, other sugars, and poly(ethylene glycol)] also dramaticaliy enhanced enzymatic activity in anhydrous solvents when present in enzyme aqueous solution prior to lyophilization. The effects of the ligand and of the lyoprotectants were nonadditive, suggesting the same mechanism of action. Excipient activated and nonactivated enzymes exhibited identical activities in water. Also, addition of the excipients directly to suspensions of nonactivated enzymes in organic solvents had no appreciable effect on catalytic activity. These observations indicate that the mechanism of the excipient-induced activation is based on the ability of the excipients to alleviate reversible denaturation of enzymes upon lyophilization. Activity enhancement induced by the excipients is displayed even after their removal by washing enzymes with anhydrous solvents. Subtilisin Carlsberg, lyophilized with sorbitol, was found to be a much more efficient practical catalyst than its "regular" counterpart. (c) 1993 John Wiley & Sons, Inc.     

Enzyme stabilization by covalent binding in nanoporous sol-gel glass for nonaqueous biocatalysis

A unique nanoporous sol-gel glass possessing a highly ordered porous structure (with a pore size of 153 A in diameter) was examined for use as a support material for enzyme immobilization. A model enzyme, alpha-chymotrypsin, was efficiently bound onto the glass via a bifunctional ligand, trimethoxysilylpropanal, with an active enzyme loading of 0.54 wt%. The glass-bound chymotrypsin exhibited greatly enhanced stability both in aqueous solution and organic solvents. The half-life of the glass-bound alpha-chymotrypsin was >1000-fold higher than that of the native enzyme, as measured either in aqueous buffer or anhydrous methanol. The enhanced stability in methanol, which excludes the possibility of enzyme autolysis, particularly reflected that the covalent binding provides effective protection against enzyme inactivation caused by structural denaturation. In addition, the activity of the immobilized alpha-chymotrypsin was also much higher than that of the native enzyme in various organic solvents. From these results, it appears that the glass-enzyme complex developed in the present work can be used as a high-performance biocatalyst for various chemical processing applications, particularly in organic media. Published by John Wiley & Sons     

Preparation of highly active alpha-chymotrypsin for catalysis in organic media

A simple one step process for the preparation of free alpha-chymotrypsin, using an organic solvent to precipitate the enzyme from a buffered solution, followed by washing with organic solvents, is described. This preparation gave 132 times greater esterification activity than lyophilized powder.     

Optimizing the salt-induced activation of enzymes in organic solvents: effects of lyophilization time and water content

The addition of simple inorganic salts to aqueous enzyme solutions prior to lyophilization results in a dramatic activation of the dried powder in organic media relative to enzyme with no added salt. Activation of both the serine protease subtilisin Carlsberg and lipase from Mucor javanicus resulting from lyophilization in the presence of KCl was highly sensitive to the lyophilization time and water content of the sample. Specifically, for a preparation containing 98% (w/w) KCl, 1% (w/w) phosphate buffer, and 1% (w/w) enzyme, varying the lyophilization time showed a direct correlation between water content and activity up to an optimum, beyond which the activity decreased with increasing lyophilization time. The catalytic efficiency in hexane varied as much as 13-fold for subtilisin Carlsberg and 11-fold for lipase depending on the lyophilization time. This dependence was apparently a consequence of including the salt, as a similar result was not observed for the enzyme freeze-dried without KCl. In the case of subtilisin Carlsberg, the salt-induced optimum value of kcat/Km for transesterification in hexane was over 20,000-fold higher than that for salt-free enzyme, a substantial improvement over the previously reported enhancement of 3750-fold (Khmelnitsky, 1994). As was found previously for pure enzyme, the salt-activated enzyme exhibited greatest activity when lyophilized from a solution of pH equal to the pH for optimal activity in water. The active-site content of the lyophilized enzyme samples also depended upon lyophilization time and inclusion of salt, with opposite trends in this dependence observed for the solvents hexane and tetrahydrofuran. Finally, substrate selectivity experiments suggested that mechanism(s) other than selective partitioning of substrate into the enzyme-salt matrix are responsible for salt-induced activation of enzymes in organic solvents.     

Remarkable activation of enzymes in nonaqueous media by denaturing organic cosolvents

The rates of transesterification reactions catalyzed by the protease subtilisin Carlsberg suspended in various anhydrous solvents at 30 degrees C can be increased more than 100-fold by the addition of denaturing organic cosolvents (dimethyl sulfoxide or formamide); in water, the same cosolvents exert no enzyme activation. At 4 degrees C, the activation effect on the lyophilized protease is even higher, reaching 1000-fold. Marked enhancement of enzymatic activity in anhydrous solvents by formamide is also observed for two other enzymes, alpha-chymotrypsin and Rhizomucor miehei lipase, and is manifested in two transesterification reactions. In addition to lyophilized subtilisin, crosslinked crystals of subtilisin are also amenable to the dramatic activation by the denaturing cosolvents. In contrast, subtilisin solubilized in anhydrous media by covalent modification with poly(ethylene glycol) exhibits only modest activation. These observations are rationalized in terms of a mechanistic hypothesis based on an enhanced protein flexibility in anhydrous millieu brought about by the denaturing organic cosolvents. The latter exert their lubricating effect largely at the interfaces between enzyme molecules in a solid preparation, thus easing the flexibility constraints imposed by protein-protein contacts. (c) 1996 John Wiley & Sons, Inc.     

冻干乙型脑炎减毒活疫苗的冻干工艺优化研究

为了研究优化冻干乙型脑炎减毒活疫苗的冻干工艺,运用正交试验法L934考察不同冻干参数对该疫苗成品质量的影响,以外观、残余水分、病毒滴度以及热稳定性为直观分析指标,并对病毒滴度进行方差分析。结果显示,主干燥时间和主干燥真空压力对病毒滴度的影响有显著统计学意义(P<0.05)。优化的冻干参数为预冻温度-35℃、时间2h;主干燥温度从-35℃升温至-10℃,再由-10℃升温至33℃,总耗时16h,真空压力0.220mbar;二次干燥的温度维持于30℃,真空压力为0.001mbar,终点测试压力无变化时结束。对冻干乙型脑炎减毒活疫苗冻干参数筛选优化后,可得到较佳的冻干曲线,经验证该曲线适用于生产。     

Comparison of theoretical and experimental data to evaluate substrate diffusional limitations for crown ether- and methyl-beta-cyclodextrin-activated serine protease subtilisin Carlsberg in tetrahydrofuran

Simple co-lyophilization of serine protease subtilisin Carlsberg with [12]-crown ether-4 (12-crown-4) or methyl-beta-cyclodextrin (MbetaCD) drastically increases its catalytic activity in organic solvents. We investigated whether the improved activity would cause substrate diffusional limitations. To experimentally assess the issue, the enzyme was inactivated with PMSF. Different amounts of active and inactive subtilisin were codissolved in 10 mM phosphate buffer (pH 7.8) followed by lyophilization with or without 12-crown-4 or MbetaCD. Initial rates for the transesterification reaction of N-acetyl-L-phenylalanine ethyl ester and 1-propanol in anhydrous THF were plotted vs. the amount of active enzyme present in the formulations. For all three enzyme formulations a linear relationship was observed and the results clearly show that activation of subtilisin Carlsberg by crown ethers and MbetaCD did not cause diffusional limitations. This was somewhat surprising because theoretical models predicted such diffusional limitations for the activated formulations. However, investigation of the protein powder particles obtained after co-lyophilization with 12-crown-4 and MbetaCD revealed a drastically reduced particle size for these formulations when suspended in THF. The particle micronization afforded by the excipients prevented substrate diffusional limitations, a factor that should be taken into account when designing improved enzyme formulations for synthetic applications in organic solvents.     

Structure and activity of alpha-chymotrypsin and trypsin in aqueous organic media

The effects of different concentrations (20-95%) of organic solvents (ethanol, 1,4-dioxane and acetonitrile) were studied on alpha-chymotrypsin and trypsin from bovine pancreas. The changes in secondary structure were followed by CD measurements, and the apparent Michaelis constants (KMapp) and the stabilities of the enzymes were determined. Significant alterations in the CD spectra were found for both enzymes at the different organic solvent concentrations. The apparent KM values of trypsin and alpha-chymotrypsin decreased as the low solvent concentrations were elevated, but then increased in the presence of higher organic solvent concentrations. The stabilities of the enzymes changed on increase of the organic solvent concentration; trypsin exhibited a higher stability than that of alpha-chymotrypsin in all organic solvents. These results show that at an organic solvent content of 95% the manifestation of an enzyme activity similar to that measured in water can be attributed to the similar compositions of the secondary structural elements.     

Studies on synthesis of short chain alkyl esters catalyzed by goat pregastric lipase

Goat pregastric lipase, in the form of a suspended enzyme powder, was found to be active in catalyzing the synthesis of alkyl esters in anhydrous organic solvents. The rate of catalyzed synthesis of esters was very dependent on the solvent medium, and maximum activity was found when a hydrocarbon was used as the solvent. The optimal temperature for the catalyzed synthesis ranged from 30 to 40°C and the maximal temperature was 35°C for the synthesis of butyl caproate in isooctane. The selectivity for the carbon-chain length of the fatty acid by the lipase was similar to that seen in hydrolysis reactions in aqueous solution, and the optimal rate of synthesis of alkyl esters was found for synthesis of the esters which had 8 or 10 carbons in the alkyl moieties from the two individual substrates. The rate of synthesis was also dependent on the water content in the system, with maximum activity occurring at 1% w/w water in isooctane.     

Measuring enzyme hydration in nonpolar organic solvents using NMR

A very sensitive NMR method has been developed for measuring deuterated water bound to proteins suspended in nonpolar solvents. This has been used to determine the amount of bound water as a function of water activity for subtilisin Carlsberg suspended in hexane, benzene, and toluene and for alpha-chymotrypsin in hexane. The adsorption isotherms for subtilisin in the three solvents are very similar showing that water activity can be usefully employed to predict the amount of water bound to proteins in nonpolar organic media. Comparison of the degree of enzyme hydration reached in nonpolar solvents with that obtained in air shows that adsorption of strongly bound water is hardly affected by the low dielectric medium, but adsorption of loosely bound water is significantly reduced. This suggests that the hydrophobic regions of the protein surface are preferentially solvated by solvent molecules, and that in a nonpolar environment formation of a complete monolayer of water over the protein surface is thermodynamically unfavorable. (c) 1995 John Wiley & Sons, Inc.     

Are water-immiscibility and apolarity of the solvent relevant to enzyme efficiency?

The question of whether the solvent's water-immiscibility is relevant to enzymatic activity was addressed by assaying four different hydrolases (three lipases and one protease) in nine anhydrous solvents of similar hydrophobicities of which four were infinitely miscible with water and five were not. For no enzyme was a jump in activity observed upon a transition from water-miscible to water-immiscible solvent. The relevance of solvent apolarity to enzymatic efficiency was also examined. To this end, three groups of isomeric anhydrous solvents were selected where within each group of isomeric anhydrous solvents were selected where within each group one solvent was apolar (i.e., lacked a permanent dipole moment). For none of the four enzymes studied was activity significantly higher in apolar solvents than in their polar counterparts. Thus we conclude that often-cited solvent's immiscibility with water and apolarity by themselves are irrelevant to enzymatic activity. (c) 1993 John Wiley & Sons, Inc.     

NMR studies of fluorinated serine protease inhibitors

Powers and co-workers have provided evidence that thiobenzyl N-heptafluorobutyrylanthranilate (I) is an extremely potent inhibitor of serine proteases, especially alpha-chymotrypsin (Teshima, T., Griffin, J. C., and Powers, J. C. (1982) J. Biol. Chem. 257, 5085-5091). We have prepared additional derivatives of this structure in which fluorine substitutions have been made on the aromatic rings and have attempted to carry out fluorine NMR studies of the interaction of Powers' compound and these new derivatives with chymotrypsin. The solubility of all inhibitors examined in solvent systems compatible with the retention of native enzyme structure is extremely low. While some nmr evidence for complex formation could be obtained, preparations of the complexes examined were metastable and precipitation of the inhibitor eventually limits the amount of complex that can be present in solution to such low levels that nmr experiments are impractical. An unusual effect of solvent composition on fluorine chemical shifts suggests that the conformation of the inhibitors in aqueous solution and when bound to the enzyme is different from that in organic solvents.