Immobilization–stabilization of the lipase from Thermomyces lanuginosus: Critical role of chemical amination

This paper describes the immobilization and stabilization of the lipase from Thermomyces lanuginosus (TLL) on glyoxyl agarose. Enzymes attach to this support only by the reaction between several aldehyde groups of the support and several Lys residues on the external surface of the enzyme molecules at pH 10. However, this standard immobilization procedure is unsuitable for TLL lipase due to the low stability of TLL at pH 10 and its low content on Lys groups that makes that the immobilization process was quite slow. The chemical amination of TLL, after reversible immobilization on hydrophobic supports, has been shown to be a simple and efficient way to improve the multipoint covalent attachment of this enzyme. The modification enriches the enzyme surface in primary amino groups with low pKb, thus allowing the immobilization of the enzyme at lower pH values. The aminated enzyme was rapidly immobilized at pH 9 and 10, with activities recovery of approximately 70%. The immobilization of the chemically modified enzyme improved its stability by 5-fold when compared to the non-modified enzyme during thermal inactivation and by hundreds of times when the enzyme was inactivated in the presence of organic solvents, being both glyoxyl preparations more stable than the enzyme immobilized on bromocyanogen.     

Solid-phase chemical amination of a lipase from Bacillus thermocatenulatus to improve its stabilization via covalent immobilization on highly activated glyoxyl-agarose

In this paper, the stabilization of a lipase from Bacillus thermocatenulatus (BTL2) by a new strategy is described. First, the lipase is selectively adsorbed on hydrophobic supports. Second, the carboxylic residues of the enzyme are modified with ethylenediamine, generating a new enzyme having 4-fold more amino groups than the native enzyme. The chemical amination did not present a significant effect on the enzyme activity and only reduced the enzyme half-life by a 3-4-fold factor in inactivations promoted by heat or organic solvents. Next, the aminated and purified enzyme is desorbed from the support using 0.2% Triton X-100. Then, the aminated enzyme was immobilized on glyoxyl-agarose by multipoint covalent attachment. The immobilized enzyme retained 65% of the starting activity. Because of the lower p K of the new amino groups in the enzyme surface, the immobilization could be performed at pH 9 (while the native enzyme was only immobilized at pH over 10). In fact, the immobilization rate was higher at this pH value for the aminated enzyme than that of the native enzyme at pH 10. The optimal stabilization protocol was the immobilization of aminated BTL2 at pH 9 and the further incubation for 24 h at 25 degrees C and pH 10. This preparation was 5-fold more stable than the optimal BTL2 immobilized on glyoxyl agarose and around 1200-fold more stable than the enzyme immobilized on CNBr and further aminated. The catalytic properties of BTL2 could be greatly modulated by the immobilization protocol. For example, from (R/S)-2- O-butyryl-2-phenylacetic acid, one preparation of BTL2 could be used to produce the S-isomer, while other preparation produced the R-isomer.     

Oxidation of phenyl compounds using strongly stable immobilized-stabilized laccase from Trametes versicolor

The hydrolysis of phenolic compounds using an immobilized and highly active and stable derivative of laccase from Trametes versicolor is presented. The enzyme was immobilized on aldehyde supports. For this, the enzyme was enriched in amino groups by chemical modification of its carboxyl groups. The aminated enzyme was immobilized with a high recovered activity (over 60%). Aldehyde derivatives were more stable than soluble or aminated-soluble enzyme and the reference derivatives after incubation in different inactivating conditions (high temperatures, different pH values or presence of organic cosolvents). The most stable derivative was obtained immobilizing the chemically aminated enzyme at pH 10 on aldehyde supports with a stabilization factor approximately 280 fold after incubation at pH 7 and 55 °C. In addition, it was possible to prepare immobilized derivatives with a maximal enzyme loading of 60 mg g^?1 of support. This derivative could be reused for 10 reaction cycles with negligible lost of activity.     

Tuning of Lecitase features via solid-phase chemical modification: Effect of the immobilization protocol

Lecitase Ultra (a quimeric fosfolipase commercialized by Novozymes) has been immobilized via two different strategies: mild covalent attachment on cyanogen bromide agarose beads and interfacial activation on octyl-agarose beads. Both immobilized preparations have been submitted to different individual or cascade chemical modifications (amination, glutaraldehyde or 2,4,6-trinitrobenzensulfonic acid (TNBS) modification) in order to check the effect of these modifications on the catalytic features of the immobilized enzymes (including stability and substrate specificity under different conditions). The first point to be remarked is that the immobilization strongly affects the enzyme catalytic features: octyl-Lecitase was more active versus p-nitrophenylbutyrate but less active versus methyl phenylacetate than the covalent preparations. Moreover, the effects of the chemical modifications strongly depend on the immobilization strategy used. For example, using one immobilization protocol a modification improves activity, while for the other immobiled enzyme is even negative. Most of the modifications presented a positive effect on some enzyme properties under certain conditions, although in certain cases that modification presented a negative effect under other conditions. For example, glutaraldehyde modification of immobilized or modified and aminated enzyme permitted to improve enzyme stability of both immobilized enzymes at pH 7 and 9 (around a 10-fold), but only the aminated enzyme improved the enzyme stability at pH 5 by glutaraldehyde treatment. This occurred even though some intermolecular crosslinking could be detected via SDS-PAGE. Amination improved the stability of octyl-Lecitase, while it reduced the stability of the covalent preparation. Modification with TNBS only improved enzyme stability of the covalent preparation at pH 9 (by a 10-fold factor).     

Effect of solid-phase chemical modification on the features of the lipase from Thermomyces lanuginosus

The lipase from Thermomyces lanuginosus (TLL) was immobilized on octyl Sepharose and further modified with ethylenediamine (EDA) after activation of the carboxylic groups with carbodiimide. Different degrees of modification of the carboxyl groups were carried out by controlling the concentration of carbodiimide (10%, 50% or 100%). Subsequently, the effect of incubation of the modified preparations on hydroxylamine to recover the modified tyrosine was also studied. The modified enzymes exhibited a mobility in native electrophoresis quite different from that of the unmodified lipase (as expected by the changes in charge), and required higher concentrations of cationic detergent to become desorbed from the support. Interestingly, the chemical modification of the immobilized TLL produced an improvement in its activity, proportional to the amination degree. This increase in activity was much more significant at pH 10, where the fully modified preparation increased the activity by a factor of 10 as compared to the unmodified preparation. Moreover, the incubation of the chemically aminated preparations in a hydroxylamine solution improved the activity by an additional factor of 1.2. The fully aminated and incubated in hydroxylamine preparation exhibited a thermostability higher than that of the unmodified preparation, mainly at pH 5 (almost a 30 fold factor). In the presence of tetrahydrofurane, some stabilization was observed at pH 7, while at pH 9 the stability of the modified enzyme decreased (under all the assayed amination degrees) when compared to that of the unmodified enzyme. Thus, this simple protocol may be a rapid and efficient way of preparing a TLL biocatalyst with higher activity and stability, although this will depend on the inactivation conditions.     

The presence of thiolated compounds allows the immobilization of enzymes on glyoxyl agarose at mild pH values: New strategies of stabilization by multipoint covalent attachment

Highly activated glyoxyl-supports rapidly immobilize proteins at pH 10 (where the -amino groups of the Lys groups of the protein surface are very reactive), and stabilize them by multipoint covalent attachment. However, they do not immobilize proteins at pH 8. This paper shows that the enzyme immobilization at this mild pH value is possible by incubation of the enzymes in the presence of different thiolated compounds (dithiothreitol, DTT; was selected as optimal reagent). The thiolated compounds (even the not reducing ones) stabilized the imino bonds formed at pH 8 between the aldehydes in the support and the amino groups of the protein. However, thiolated compounds are unable to reduce the imino bonds or the aldehyde groups and a final reduction step (e.g., using sodium borohydride) was always necessary. After enzyme immobilization through the most reactive amino group of the protein, the further incubation of this immobilized enzyme at pH 10 would improve the reactivity of the -amino groups of the Lys residues of the protein surface. Then, an intense multipoint covalent reaction of the enzyme with the dense layer of glyoxyl groups in the support could be obtained, increasing the stability of the immobilized enzyme. Using three different industrially relevant enzymes (penicillin G acylase from Escherichia coli (PGA), lipase from Bacillus thermocatenulatus (BTL2) and glutaryl acylase from Pseudomonas sp. (GA)), new immobilized-stabilized biocatalysts of the enzymes were produced. After reduction, the preparations incubated at pH 10 were more stable than those that were only immobilized and reduced at pH 8. In the case of the PGA, this preparation was even 4–5-fold more stable than those obtained by direct immobilization at pH 10 (around 40,000–50,000-fold more stable than the soluble enzyme).     

The co-operative effect of physical and covalent protein adsorption on heterofunctional supports

It has been found that the enzymes penicillin G acylase from Escherichia coli (PGA) and lipase from Bacillus thermocatenulatus (BTL) did not significantly adsorb on highly activated amino-agarose beads at pH 7 (a support where 85–90% of a crude extract of proteins become adsorbed). Moreover, it has been found that these enzymes do not covalently immobilize on highly activated epoxy-agarose beads at pH 7. However, both enzymes slowly immobilize on heterofunctional supports having a high density of amino–epoxy groups. The immobilized enzymes retain a high percentage of activity (more than 90% for PGA and 60% for BTL). On the other hand, the immobilization of a crude extract of proteins on amino–epoxy supports under conditions where only a limited protein ionic exchange was permitted (by using high ionic strength or lowly activated supports), also permitted a similar high immobilization yield of the proteins. Similarly, glutamate dehydrogenase (GDH) and β-galactosidase from Thermus thermophilus can be fully immobilized under conditions where less than 20% of these enzymes can be ionically exchanged in the aminated support. The results suggested that the percentage of proteins that may be physically adsorbed on the support becomes irreversibly immobilized by the covalent reaction between the nucleophilic groups in the protein surface and the very near epoxy groups of the support (in an almost intramolecular reaction). Thus, using these supports, it is possible to immobilize almost all the proteins by anionic exchange, that is, the area with the highest density in anionic groups. In many cases, this region could not correspond to the protein regions usually utilized to immobilize proteins. This way, it is possible to achieve, in a very simple fashion and without modifying the protein, new orientations of some immobilized enzymes and proteins.     

Stabilization of enzymes by multipoint attachment via reversible immobilization on phenylboronic activated supports

In this work, we have used supports activated with m-amino-phenylboronic groups to “reversibly” immobilize proteins under very mild conditions. Most of the proteins contained in a crude extract from E. coli could be immobilized on Eupergit C-250 L activated with phenylboronic and then fully desorbed from the support by using mannitol or SDS. This suggested that the immobilization of the proteins on these supports was not only via sugars interaction, but also by other interaction/s, quite unspecific, that might be playing a key role in the immobilization of the proteins. Penicillin acylase from E. coli (PGA) was also immobilized in Eupergit C activated with m-amino-phenylboronic groups. The enzyme could be fully desorbed with mannitol immediately after being immobilized on the support. However, longer incubation times of the immobilized preparation caused a reduction of protein elution from the boronate support in presence of mannitol. Moreover, these immobilized preparations showed a higher stability in the presence of organic solvents than the soluble enzyme; the stability also improved when the incubation time was increased (to a factor of 100). By desorbing the weakest bound enzyme molecules, it was possible to correlate adsorption strength with stabilization; therefore, it seems that this effect was due to the rigidification of the enzyme via multipoint attachment on the support.     

Increase in conformational stability of enzymes immobilized on epoxy-activated supports by favoring additional multipoint covalent attachment*

Epoxy supports (Eupergit C) may be very suitable to achieve the multipoint covalent attachment of proteins and enzymes, therefore, to stabilize their three-dimensional structure. To achieve a significant multipoint covalent attachment, the control of the experimental conditions was found to be critical. A three-step immobilization/stabilization procedure is here proposed: 1) the enzyme is firstly covalently immobilized under very mild experimental conditions (e.g. pH 7.0 and 20 degrees C); 2) the already immobilized enzyme is further incubated under more drastic conditions (higher pH values, longer incubation periods, etc.) to "facilitate" the formation of new covalent linkages between the immobilized enzyme molecule and the support; 3) the remaining groups of the support are blocked to stop any additional interaction between the enzyme and the support. Progressive establishment of new enzyme-support attachments was showed by the progressive irreversible covalent immobilization of several subunits of multi-subunits proteins (all non-covalent structures contained in crude extracts of different microorganism, penicillin G acylase and chymotrypsin). This multipoint covalent attachment enabled the significant thermostabilization of two relevant enzymes, (compared with the just immobilized derivatives): chymotrypsin (5-fold factor) and penicillin G acylase (18-fold factor). Bearing in mind that this stabilization was additive to that achieved by conventional immobilization, the final stabilization factor become 100-fold comparing soluble penicillin G acylase and optimal derivative. These stabilizations were observed also when the inactivations were promoted by the enzyme exposure to drastic pH values or the presence of cosolvents.     

Solid-phase modification with succinic polyethyleneglycol of aminated lipase B from Candida antarctica: Effect of the immobilization protocol on enzyme catalytic properties

Lipase B from Candida antarctica (CALB) has been modified using succinic polyethyleneglycol via the carbodiimide route. Immobilized enzyme (on octyl Sepharose or Eupergit C) has been used, to take advantage of the solid phase. Modification of immobilized CALB's native amino groups did not produce a significant alteration of CALB. However, if the enzyme was previously aminated, around 14–15 PEG molecules could be introduced per enzyme molecule. Also, it has been found that succinic groups are far more reactive than acetic acid following this strategy.Even after this drastic double modification, the functional properties of the enzyme have not been impoverished to a large extent: stability decreased only to some extent (by a 5–6 fold factor), activity versus some substrates even increased (e.g., around 60% using p-nitrophenyl butyrate). It has been found that both modifications (amination and pegylation) have very different effects on enzyme properties when performed on CALB immobilized on Eupergit C or octyl Sepharose. For example, activity versus pNPP increased using CALB-octyl Sepharose while it decreased when using Eupergit C following amination and PEGylation. The effects also depend on the reaction and substrate, for example in hydrolysis of methyl mandelate, the activity decreased by 50% using CALB-octyl Sepharose after PEGylation of the aminated enzyme, while using CALB-Eupergit C had no effect. In this last case, enantioselecitvity in this hydrolysis significantly improved after both chemical modifications (from 7.5 to 20), while using CALB-octyl Sepharose almost had no effect.     

Positive effects of the multipoint covalent immobilization in the reactivation of partially inactivated derivatives of lipase from Thermomyces lanuginosus

Different immobilized preparations of lipase from Thermomyces lanuginosus (TLL) have been inactivated by exposure to high temperatures, guanidine or 95% of dioxane. The studied preparations were: non-stabilized cyanogen bromide (CNBr-TLL), aminated CNBr-TLL (CNBr-TLL-A), and two stabilized preparations of aminated TLL by immobilization on glyoxyl support, Gx(9/10)-TLL-A (TLL-A immobilized at pH 9 and later incubated at pH 10) or Gx(10)-TLL-A (directly immobilized at pH 10). The reactivation of the partially inactivated immobilized enzymes under mild conditions by incubation in aqueous buffer, allowed recovery of some of the original activity, which was improved when it was pre-incubated in guanidine. Amination produced a fairly negative effect on the reactivation of the enzyme, but the multipoint covalent attachment of this aminated enzyme reversed the effect (e.g., recovered activity increased from 20% for CNBr-TLL to 80% for Gx(9/10)-TLL-A). The negative effect of the amination was clearer when the inactivation was caused by exposure to high temperatures, although the multipoint attachment of aminated enzyme was able to improve the recovered activity. The determination of enzyme activity in the presence of hexadecyltrimethylammonium bromide slowed the inactivation rates of all preparations and improved the recovery of activity after incubation under mild conditions, suggesting that the opening mechanism of the lipase could be a critical step in the TLL inactivation/reactivation. The use of multipoint attached TLL preparations did not only improve enzyme stability, but it also increased activity recovery when the preparation was incubated under mild conditions.     

Epoxy sepabeads: a novel epoxy support for stabilization of industrial enzymes via very intense multipoint covalent attachment

Sepabeads-EP (a new epoxy support) has been utilized to immobilize-stabilize the enzyme penicillin G acylase (PGA) via multipoint covalent attachment. These supports are very robust and suitable for industrial purposes. Also, the internal geometry of the support is composed by cylindrical pores surrounded by the convex surfaces (this offers a good geometrical congruence for reaction with the enzyme), and it has a very high superficial density of epoxy groups (around 100 micromol/mL). These features should permit a very intense enzyme-support interaction. However, the final stability of the immobilized enzyme is strictly dependent on the immobilization protocol. By using conventional immobilization protocols (neutral pH values, nonblockage of the support) the stability of the immobilized enzyme was quite similar to that achieved using Eupergit C to immobilize the PGA. However, when using a more sophisticated three-step immobilization/stabilization/blockage procedure, the Sepabeads derivative was hundreds-fold more stable than Eupergit C derivatives. The protocol used was as follows: (i) the enzyme was first covalently immobilized under very mild experimental conditions (e.g., pH 7.0 and 20 degrees C); (ii) the already immobilized enzyme was further incubated under more drastic conditions (higher pH values, long incubation periods, etc.) in order to "facilitate" the formation of new covalent linkages between the immobilized enzyme molecule and the support; (iii) the remaining epoxy groups of the support were blocked with very hydrophilic compounds to stop any additional interaction between the enzyme and the support. This third point was found to be critical for obtaining very stable enzymes: derivatives blocked with mercaptoethanol were much less stable than derivatives blocked with glycine or other amino acids. This was attributed to the better masking of the hydrophobicity of the support by the amino acids (having two charges).     

Immobilization and stabilization of cephalosporin C acylase on aminated support by crosslinking with glutaraldehyde and further modifying with aminated macromolecules

In this work, cephalosporin C acylase (CA), a heterodimeric enzyme of industrial potential in direct hydrolysis of cephalosporin C (CPC) to 7‐aminocephalosporanic acid (7‐ACA), was covalently immobilized on the aminated support LX1000‐HA (HA) with two different protocols. The stability of CA adsorbed onto the HA support followed by crosslinking with glutaraldehyde (HA–CA–glut) was better than that of the CA covalently immobilized on the glutaraldehyde preactivated HA support (HA–glut–CA). The thermostabilization factors (compared with the free enzyme) of these two immobilized enzymes were 11.2‐fold and 2.2‐fold, respectively. In order to improve the stability of HA–CA–glut, a novel strategy based on postimmobilization modifying with aminated molecules was developed to take advantage of the glutaraldehyde moieties left on the enzyme and support. The macromolecules, such as polyethyleneimine (PEI) and chitosan, had larger effects than small molecules on the thermal stability of the immobilized enzyme perhaps due to crosslinking of the enzymes and support with each other. The quaternary structure of the CA could be much stabilized by this novel approach including physical adsorption on aminated support, glutaraldehyde treatment, and macromolecule modification. The HA–CA–glut–PEI20000 (the HA–CA–glut postmodified with PEI M_w = 20,000) had a thermostabilization factor of 20‐fold, and its substrate affinity (K_m = 14.3 mM) was better than that of HA–CA–glut (K_m = 33.4 mM). The half‐life of the immobilized enzymes HA–CA–glut–PEI20000 under the CPC‐catalyzing conditions could reach 28 cycles, a higher value than that of HA–CA–glut (21 cycles). © 2015 American Institute of Chemical Engineers Biotechnol. Prog., 31:387–395, 2015     

Immobilization of β-galactosidase on modified polypropilene membranes

A new immobilized system: β-galactosidase-modified polypropylene membrane was created. It was obtained 13 different carriers by chemical modification of polypropylene membranes by two stages. The first stage is treatment with K(2)Cr(2)O(7) to receive carboxylic groups on membrane surface. The second stage is treatment with different modified agents ethylendiamine, hexamethylenediamine, hydrazine dihydrochloride, hydroxylamine, o-phenylenediamine, p-phenylenediamine, N,N'-dibenzyl ethylenediamine diacetate to receive amino groups. The quantity of the amino groups, carboxylic groups and the degree of hydrophilicity of unmodified and modified polypropilene membranes were determined. β-Galactosidase was chemically immobilized on the obtained carries by glutaraldehyde. The highest relative activity of immobilized enzyme was recorded at membrane modified with 10% hexamethylenediamine (Membrane 5) - 92.77%. The properties of immobilized β-galactosidase on different modified membranes - pH optimum, temperature optimum, pH stability and thermal stability were investigated and compared with those of free enzyme. The storage stability of all immobilized systems was studied. It was found that the most stable system is immobilized enzyme on Membrane 5. The system has kept 90% of its initial activity at 300th day (pH=6.8; 4°C). The stability of the free and immobilized β-galactosidase on the modified membrane 5 with 10% HMDA in aqueous solutions of alcohols - mono-, diol and triol was studied. The kinetics of enzymatic reaction of free and immobilized β-galactosidase on the modified membrane 5 at 20°C and 40°C and at the optimal pH for both forms of the enzyme were investigated. It was concluded that the modified agent - hexamethylenediamine, with long aliphatic chain ensures the best immobilized β-galactosidase system.     

Enzyme stabilization by glutaraldehyde crosslinking of adsorbed proteins on aminated supports

The stabilization achieved by different immobilization protocols have been compared using three different enzymes (glutaryl acylase (GAC), D-aminoacid oxidase (DAAO), and glucose oxidase (GOX)): adsorption on aminated supports, treatment of this adsorbed enzymes with glutaraldehyde, and immobilization on glutaraldehyde pre-activated supports. In all cases, the treatment of adsorbed enzymes on amino-supports with glutaraldehyde yielded the higher stabilizations: in the case of GOX, a stabilization over 400-fold was achieved. After this treatment, the enzymes could no longer be desorbed from the supports using high ionic strength (suggesting the support-protein reaction). Modification of the enzymes immobilized on supports that did not offer the possibility of react with glutaraldehyde showed the same stability that the non modified preparations demonstrating that the mere chemical modification did not have effect on the enzyme stability. This simple strategy seems to permit very good results in terms of immobilization rate and stability, offering some advantages when compared to the immobilization on glutaraldehyde pre-activated supports.     

Chemical modification of protein surfaces to improve their reversible enzyme immobilization on ionic exchangers

The enzyme penicillin G acylase (PGA) is not adsorbed at pH 7 on DEAE- or PEI-coated supports, neither is it adsorbed on carboxymethyl (CM)- or dextran sulfate (DS)-coated supports. The surface of the enzyme was chemically modified under controlled conditions: chemical amination of the protein surface of carboxylic groups (using soluble carbodiimide and ethylendiamine) and chemical succinylation (using succinic anhydride) of amino groups. The full chemical modification produced some negative effects on enzyme stability and activity, although partial modification (mainly succinylation) presented negligible effects on both enzyme features. The chemical amination of the protein surface permitted the immobilization of the enzyme on CM- and DS-coated support, while the chemical succinylation permitted the enzyme immobilization on DEAE- and PEI-coated supports. Immobilization was very strong on these supports, mainly in the polymeric ones, and dependent on the degree of modification, although the enzymes still can be desorbed after inactivation by incubation under drastic conditions. Moreover, the immobilization on ionic polymeric beds allowed a significant increase in enzyme stability against the inactivation and inhibitory effects of organic solvents, very likely by the promotion of a certain partition of the organic solvent out of the enzyme environment. These results suggest that the enrichment of the surface of proteins with ionic groups may be a good strategy to take advantage of the immobilization of industrial enzymes via ionic exchange on ionic polymeric beds.     

Purification and stabilization of a glutamate dehygrogenase from Thermus thermophilus via oriented multisubunit plus multipoint covalent immobilization

The immobilization of a glutamate dehydrogenase from Thermus thermophilus (GDH) on glyoxyl agarose beads at pH 7 has permitted to perform the immobilization, purification and stabilization of this interesting enzyme. It was cloned in Escherichia coli and a first thermal shock of the crude preparation destroyed most mesophilic multimeric proteins. Glyoxyl agarose can only immobilize enzymes via a multipoint and simultaneous attachment. Therefore, only proteins having several terminal amino groups in a position that permits their interaction with a flat surface can be immobilized. GDH became rapidly immobilized at pH 7 and its multimeric structure became stabilized as evidenced by SDS-PAGE. This derivative was stable at acidic pH value while the non-stabilized enzyme was very unstable under these conditions due to subunit dissociation. After immobilization, a further incubation at pH 10 improved enzyme stability under any inactivating conditions by increasing the enzyme–support bonds. In fact, GDH immobilized at pH 7 and incubated at pH 10 preserved more activity than GDH directly immobilized at pH 10 (50% versus 15% after 24 h of incubation) and was also more stable (1.5- to 3-fold, depending on the conditions).This method could be extended to any other multimeric enzyme expressed in mesophilic hosts.     

Immobilization and stabilization of α-galactosidase on Sepabeads EC-EA and EC-HA

α-Galactosidase from tomato has been immobilized on Sepabead EC-EA and Sepabead EC-HA, which were activated with ethylendiamino and hexamethylenediamino groups, respectively. Two strategy was used for the covalent immobilization of α-galactosidase on the aminated Sepabeads: covalent immobilization of enzyme on glutaraldehyde activated support and cross-linking of the adsorbed enzymes on to the support with glutaraldehyde. By using these two methods, all the immobilized enzymes retained very high activity and the stability of the enzyme was also improved. The obtained results showed that, the most stable immobilized α-galactosidase was obtained with the second strategy. The immobilized enzymes were characterized with respect to free counterpart. Some parameters effecting to the enzyme activity and stability were also analyzed. The optimum temperature and pH were found as 60 °C and pH 5.5 for all immobilized enzymes, respectively. All the immobilized α-galactosidases were more thermostable than the free enzyme at 50 °C. The stabilities of the Sepabead EC-EA and EC-HA adsorbed enzymes treated with glutaraldehyde compared to the stability of the free enzyme were a factor of 6 for Sepabead EC-EA and 5.3 for Sepabead EC-HA. Both the free and immobilized enzymes were very stable between pH 3.0 and 6.0 and more than 85% of the initial activities were recovered. Under the identical storage conditions the free enzyme lost its initial activity more quickly than the immobilized enzymes at the same period of time. The immobilized α-galactosidase seems to fulfill the requirements for different industrial applications.     

Co-aggregation of enzymes and polyethyleneimine: a simple method to prepare stable and immobilized derivatives of glutaryl acylase

We have developed a novel methodology that allowed the preparation of cross-linked enzyme aggregates (CLEAs) of glutaryl acylase (GAC) by co-aggregation of the enzyme with an aminated polymer: polyethyleneimine (PEI). The preparation of CLEAs of GAC from Pseudomonas sp. is not possible when using poly(ethylene glycol) and glutaraldehyde directly as precipitating and cross-linking agent, respectively. This problem arises probably from the low content of surface Lys groups of GAC which prevents an efficient cross-linking of the enzyme molecules in the aggregate. This fact was proven by the release of enzyme molecules from the aggregate and the solubilization of the enzyme when eliminating the precipitating agent. Our new co-aggregation system favors the cross-linking between the very reactive and abundant primary amino groups of the PEI and the primary amino groups on the enzyme surface. The use of PEI prevents the release of enzyme molecules from the aggregate. By this methodology, we prepared a very stable immobilized derivative of GAC. After optimization of the glutaraldehyde treatment conditions, the stability of the enzyme was significantly improved. It kept more than 60% of its initial activity after 72 h of incubation at 45 degrees C, whereas the soluble enzyme was fully inactivated in 2.5 h of incubation in the same conditions. Therefore, we have a new protocol for carrying out the preparation of cross-linked aggregates of enzymes with a low number of lysines on its surface.     

Stabilization of penicillin G acylase from Escherichia coli: site-directed mutagenesis of the protein surface to increase multipoint covalent attachment

Three mutations on the penicillin acylase surface (increasing the number of Lys in a defined area) were performed. They did not alter the enzyme's stability and kinetic properties; however, after immobilization on glyoxyl-agarose, the mutant enzyme showed improved stability under all tested conditions (e.g., pH 2.5 at 4 degrees C, pH 5 at 60 degrees C, pH 7 at 55 degrees C, or 60% dimethylformamide), with stabilization factors ranging from 4 to 11 compared with the native enzyme immobilized on glyoxyl-agarose.