Role of the support surface on the loading and the activity of Pseudomonas fluorescens lipase used for biodiesel synthesis

The present work investigates the influence of the support surface on the loading and the enzymatic activity of the immobilized Pseudomonas fluorescens lipase. Different porous materials, polypropylene (Accurel), polymethacrylate (Sepabeads EC-EP), silica (SBA-15 and surface modified SBA-15), and an organosilicate (MSE), were used as supports. The immobilized biocatalysts were compared towards sunflower oil ethanolysis for the sustainable production of biodiesel. Since the supports have very different structural (ordered hexagonal and disordered) and textural features (surface area, pore size, and total pore volume), in order to consider only the effect of the support surface, experiments were performed at low surface coverage. The different functional groups occurring on the support surface allowed either physical (Accurel, MSE, and SBA-15) or chemical adsorption (Sepabeads EC-EP and SBA-15–R-CHO). The surface-modified SBA-15 (SBA-15–R-CHO) allowed the highest loading. The lipase immobilized on the MSE was the most active biocatalyst. However, in terms of catalytic efficiency (activity/loading) the lipase immobilized on the SBA-15, the support that allowed the lowest loading, was the most efficient.     

Chitosan-based hybrid immobilization in bienzymatic reactions and its application to the production of laminaribiose

A hybrid-immobilization method was developed to improve the long-term stability of laminaribiose phosphorylase immobilized on epoxy supports Sepabeads EC-EP/S. Entrapment in chitosan retained all of the enzyme activity depending on the amount of entrapped solid materials and increased half-life by a factor of 10–94.4 h. No enzyme activity loss was determined during 12 times reuse. The immobilization method is also applicable to sucrose phosphorylase immobilized on Sepabeads EC-EP/S. Up to 31.9 g/L laminaribiose were produced in bienzymatic batch experiments with reaction-integrated product separation by adsorption on zeolites.

     

Synthetic resin-bound truncated Candida antarctica lipase B for production of fatty acid alkyl esters by transesterification of corn and soybean oils with ethanol or butanol

A gene encoding a synthetic truncated Candida antarctica lipase B (CALB) was generated via automated PCR and expressed in Saccharomyces cerevisiae. Western blot analysis detected five truncated CALB variants, suggesting multiple translation starts from the six in-frame ATG codons. The longest open reading frame, which corresponds to amino acids 35-317 of the mature lipase, appeared to be expressed in the greatest amount. The truncated CALB was immobilized on Sepabeads? EC-EP resin and used to produce ethyl and butyl esters from crude corn oil and refined soybean oil. The yield of ethyl esters was 4-fold greater from corn oil than from soybean oil and was 36% and 50% higher, respectively, when compared to a commercially available lipase resin (Novozym 435) using the same substrates. A 5:1 (v/v) ratio of ethanol to corn oil produced 3.7-fold and 8.4-fold greater yields than ratios of 15:1 and 30:1, respectively. With corn oil, butyl ester production was 56% higher than ethyl ester production. Addition of an ionic catalytic resin step prior to the CALB resin increased yields of ethyl esters from corn oil by 53% compared to CALB resin followed by ionic resin. The results suggest resin-bound truncated CALB has potential application in biodiesel production using biocatalysts.     

Hydrolysis of triacetin catalyzed by immobilized lipases: effect of the immobilization protocol and experimental conditions on diacetin yield

The effect of the immobilization protocol and some experimental conditions (pH value and presence of acetonitrile) on the regioselective hydrolysis of triacetin to diacetin catalyzed by lipases has been studied. Lipase B from Candida antarctica (CALB) and lipase from Rhizomucor miehei (RML) were immobilized on Sepabeads (commercial available macroporous acrylic supports) activated with glutaraldehyde (covalent immobilization) or octadecyl groups (adsorption via interfacial activation). All the biocatalysts accumulated diacetin. Covalently immobilized RML was more active towards rac-methyl mandelate than the adsorbed RML. However, this covalent RML preparation presented the lowest activity towards triacetin. For this reason, this preparation was discarded as biocatalyst for this reaction. At pH 7, acyl migration occurred giving a mixture of 1,2 and 1,3 diacetin, but at pH 5.5, only 1,2 diacetin was produced. Yields were improved at acidic pH values and in the presence of 20% acetonitrile (to over 95%). RML immobilized on octadecyl Sepabeads was proposed as optimal preparation, mainly due to its higher specific activity. Each enzyme preparation presented very different properties. Moreover, changes in the reaction conditions affected the various immobilized enzymes in a different way.     

Simple and efficient immobilization of lipase B from Candida antarctica on porous styrene-divinylbenzene beads

Two commercial porous styrene-divinylbenzene beads (Diaion HP20LX and MCI GEL CHP20P) have been evaluated as supports to immobilize lipase B from Candida antarctica (CALB). MCI GEL CHP20P rapidly immobilized the enzyme, permitting a very high loading capacity: around 110 mg CALB/wet g of support compared to the 50 mg obtained using decaoctyl Sepabeads. Although enzyme specificity of the enzyme immobilized on different supports was quite altered by the support used in the immobilization, specific activity of the enzyme immobilized on MCI GEL CHP20P was always higher than those found using decaoctyl Sepabeads for all assayed substrates. Thus, a CALB biocatalyst having 3-8 folds (depending on the substrate) higher activity/wet gram of support than the commercial Novozym 435 was obtained. Half-live of CAL-Diaion HP20LX at 60 °C was 2-3 higher than the one of Novozym 435, it was 30-40 higher in the presence of 50% acetonitrile and it was around 100 folds greater in the presence of 10 M hydrogen peroxide.Results indicate that styrene-divinylbenzene supports may be promising alternatives as supports to immobilize CALB.     

Kinetic resolution of drug intermediates catalyzed by lipase B from Candida antarctica immobilized on immobead‐350

Novozyme 435, which is a commercial immobilized lipase B from Candida antarctica (CALB), has been proven to be inadequate for the kinetic resolution of rac‐indanyl acetate. As it has been previously described that different immobilization protocols may greatly alter lipase features, in this work, CALB was covalently immobilized on epoxy Immobead‐350 (IB‐350) and on glyoxyl‐agarose to ascertain if better kinetic resolution would result. Afterwards, all CALB biocatalysts were utilized in the hydrolytic resolution of rac‐indanyl acetate and rac‐(chloromethyl)‐2‐(o‐methoxyphenoxy) ethyl acetate. After optimization of the immobilization protocol on IB‐350, its loading capacity was 150 mg protein/g dried support. Furthermore, the CALB‐IB‐350 thermal and solvent stabilities were higher than that of the soluble enzyme (e.g., by a 14‐fold factor at pH 5–70°C and by a 11‐fold factor in dioxane 30%–65°C) and that of the glyoxyl‐agarose‐CALB (e.g., by a 12‐fold factor at pH 10–50°C and by a 21‐fold factor in dioxane 30%–65°C). The CALB‐IB‐350 preparation (with 98% immobilization yield and activity versus p‐nitrophenyl butyrate of 6.26 ± 0.2 U/g) was used in the hydrolysis of rac‐indanyl acetate using a biocatalyst/substrate ratio of 2:1 and a pH value of 7.0 at 30°C for 24 h. The conversion obtained was 48% and the enantiomeric excess of the product (e.e._p) was 97%. These values were much higher than the ones obtained with Novozyme 435, 13% and 26% of conversion and e.e.p, respectively. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 34:878–889, 2018     

Kinetic and microstructural characterization of immobilized penicillin acylase from Streptomyces lavendulae on Sepabeads EC-EP

Recombinant penicillin acylase from Streptomyces lavendulae was covalently bound to epoxy-activated Sepabeads EC-EP303®. Optimization of the immobilization process led to a homogeneous distribution of the enzyme on the support surface avoiding the attachment of enzyme aggregates, as shown by confocal electron microscopy. The optimal immobilized biocatalyst had a specific enzymatic activity of 26.2IUgwetcarrier^?1 in the hydrolysis of penicillin V at pH 8.0 and 40°C. This biocatalyst showed the highest activity at pH 8.5 and 65°C, 1.5 pH units lower and 5°C higher than its soluble counterpart. Substrate specificity of the derivative also showed its ability to efficiently hydrolyze other natural aliphatic penicillins such as penicillins K, F and dihydroF. The immobilized enzyme was highly stable at 40°C and pH 8.0 (t_1/2=625 h vs. t_1/2=397 h for the soluble enzyme), and it could be recycled for at least 30 consecutive batch reactions without loss of catalytic activity.     

Versatility of glutaraldehyde to immobilize lipases: Effect of the immobilization protocol on the properties of lipase B from Candida antarctica

Glutaraldehyde chemistry has been used to immobilize lipase B from Candida antarctica (CALB) under different situations. Using high ionic strength, ionic adsorption is avoided, but CALB is adsorbed on the support via interfacial activation. Using non-ionic detergents (e.g., Triton X-100), the enzyme becomes ionically adsorbed on the activated support. If detergent and salt are simultaneously present during immobilization, a covalent attachment to the support is first produced. In absence of detergent or high ionic strength, a mixture of all of the previous immobilization reasons should coexist. Thus, 5 different CALB biocatalysts were prepared following the previous described protocols, and its stability and activity, pH/activity profile and specificity versus R and S methyl mandelate were analyzed. The existence of covalent attachment of more than 95% of the enzyme molecules was confirmed by washing the biocatalysts in salt and detergent solutions. The glutaraldehyde treatment of the enzyme adsorbed on aminated supports did not produce a significant improvement on the activity of the enzyme versus p-nitrophenylpropinate (pNPB) nor a high stabilization of the enzyme. This differed from the effects of a similar treatment of CAL adsorbed on octyl agarose. However, they were similar to the effects of this treatment on covalently immobilized CALB, suggesting that the immobilization protocol may greatly affect the final effect of a chemical modification on the enzyme properties.Dramatic changes in the enzyme features were observed comparing the different preparations, mainly in the specificity of CALB versus p-NPB and R-methyl mandelate (from 2.5 to 20), or in the enantiospecificity versus R/S methyl mandelate (from 1.8 to 16), confirming that these different immobilization protocols produced biocatalysts with different features. Moreover, changes in experimental conditions produced very different effects on the properties of the different CALB preparations.     

Reversible immobilization of glucoamylase by ionic adsorption on sepabeads coated with polyethyleneimine

Glucoamylase (GA) from Aspergillus niger was immobilized via ionic adsorption onto DEAE-agarose, Q1A-Sepabeads, and Sepabeads EC-EP3 supports coated with polyethyleneimine (PEI). After optimization of the immobilization conditions (pH, polymer size), it was observed that the adsorption strength was much higher in PEI-Sepabeads than in Q1A-Sepabeads or DEAE-supports, requiring very high ionic strength to remove glucoamylase from the PEI-supports (e.g., 1 M NaCl at pH 5.5). Thermal stability and optimal temperature was marginally improved by this immobilization. Recovered activity depended on the substrate used, maltose or starch, except when very low loading was used. The optimization of the loading allowed the preparation of derivatives with 750 IU/g in the hydrolysis of starch, preserving a high percentage of immobilized activity (around 50%).     

An efficient enzymatic synthesis of 5-aminovaleric acid

The title compound was prepared enzymatically from l-lysine in an excellent yield and under buffer-free conditions. l-Lysine was oxidized by the action of l-lysine α-oxidase from Trichoderma viride followed by spontaneous oxidative decarboxylation of the intermediate 6-amino-2-oxocaproic acid in the reaction medium. l-Lysine α-oxidase was immobilized on an epoxy-activated solid support (Sepabeads EC-EP) and the activity of both solution-based and immobilized enzyme in this reaction was determined.     

Enzymatic transesterification in a solvent-free system: synthesis of sn-2 docosahexaenoyl monoacylglycerol

Abstract

The enzymatic transesterification of docosahexaenoic acid (DHA) ethyl ester with glycerol was carried out by using several immobilized lipases in a solvent-free system. This reaction involves the initial formation of sn-2 docosahexaenyl monoacylglycerol. This DHA derivative is highly relevant for improving the bioavailability of DHA and it has received increasing interest in the field of nutrition. Three commercial lipases, from Rhizomucor miehei (RML), Alcaligenes sp. (AQ) and Candida antarctica-fraction B (CALB) were immobilized by interfacial adsorption on a commercial hydrophobic support (a methacrylate resin containing octadecyl groups, Sepabeads C-18) and tested for glycerolysis of DHA ethyl ester. In certain cases (e.g. immobilized CALB), the transesterification reaction continues to the formation of triacylglycerol (80%) by using a very high excess of DHA ethyl ester ((115 mmols versus 1.24 mmols of glycerol and high temperatures (50?°C). However, the same biocatalyst working at lower temperatures, 37?°C, synthetizes a 90% of sn-2 monoacylglycerol even in the presence of that a high excess of DHA ethyl ester. Interestingly, immobilized RML derivative synthesizes a 98% of sn-2 monoacylglyceride (2-MG) in 15?min at 37?°C with a 4% of immobilized biocatalyst. These high activity and regioselectivity under very mild reaction conditions are very interesting for the thermal oxidative stability of the omega-3 fatty acid as well as for the thermal stability of the biocatalyst. Using Normal Phase HPLC-ELSD and accurate commercial markers, the formation of the 2-MG was confirmed.     

Covalent Immobilization of Alcohol Dehydrogenase (ADH2) from Haloferax volcanii: How to Maximize Activity and Optimize Performance of Halophilic Enzymes

Alcohol dehydrogenase from halophilic archaeon Haloferax volcanii (HvADH2) was successfully covalently immobilized on metal-derivatized epoxy Sepabeads. The immobilization conditions were optimized by investigating several parameters that affect the halophilic enzyme–support interaction. The highest immobilization efficiency (100 %) and retention activity (60 %) were achieved after 48 h of incubation of the enzyme with Ni-epoxy Sepabeads support in 100 mM Tris–HCl buffer, pH 8, containing 3 M KCl at 5 °C. No significant stabilization was observed after blocking the unreacted epoxy groups with commonly used hydrophilic agents. A significant increase in the stability of the immobilized enzyme was achieved by blocking the unreacted epoxy groups with ethylamine. The immobilization process increased the enzyme stability, thermal activity, and organic solvents tolerance when compared to its soluble counterpart, indicating that the immobilization enhances the structural and conformational stability. One step purification–immobilization of this enzyme has been carried out on metal chelate-epoxy Sepabeads, as an efficient method to obtain immobilized biocatalyst directly from bacterial extracts.     

Remarkable stability of Candida antarctica lipase B immobilized via cross-linking aggregates (CLEA) in deep eutectic solvents

The combination of Deep-eutectic-solvents (DES) with water as “co-solvent” enables a low-viscous reaction medium that keeps its “non-conventional” nature and thus enables synthetic lyophilization reactions (e.g. esterification) catalyzed by hydrolases. Substrates with different polarity may be employed. This paper shows how the enzyme immobilization with cross-linking aggregates (CLEA) leads to highly stable and active immobilized catalysts in different DES. As a remarkable case, when choline chloride-glycerol DES is used, CLEA derivatives of Candida antarctica lipase B (CLEA-CALB) are stable for at least 14?days without any loss of activity. The immobilized biocatalysts are applied in non-viscous DES-water blends (8% v/v) to catalyze the esterification of benzoic acid and glycerol to furnish glyceryl monobenzoate (α-MBG) in productivities of ～35?g α-MBG L^?1d^?1. Compared to other commercial immobilized CALB, the CLEA-CALB derivatives rendered more product (higher conversions by 30%). Moreover, CLEA derivatives were successfully reused for six times without any loss of activity. Given the ease of immobilization (CLEA), their excellent performance in DES and the low viscosity of the DES-water blends, the reported approach may be useful for many synthetic procedures and even for continuous processes with largely optimized outcomes.     

Immobilization on octyl-agarose beads and some catalytic features of commercial preparations of lipase a from Candida antarctica (Novocor ADL): Comparison with immobilized lipase B from Candida antarctica

Lipase A from Candida antarctica (CALA, commercialized as Novocor ADL) was immobilized on octyl-agarose, which is a very useful support for lipase immobilization, and coated with polyethylenimine to improve the stability. The performance was compared to that of the form B of the enzyme (CALB) immobilized on the same support, as both enzymes are among the most popular ones used in biocatalysis. CALA immobilization produced a significant increase in enzyme activity vs. p-nitrophenyl butyrate (pNPB) (by a factor of seven), and the coating with PEI did not have a significant effect on enzyme activity. CALB reduced its activity slightly after enzyme immobilization. Octyl-CALA was less stable than octyl-CALB at pH 9 and more stable at pH 5 and, more clearly, at pH 7. PEI coating only increased octyl-CALA stability at pH 9. In organic solvents, CALB had much better stability in methanol and was similarly stable in acetonitrile or dioxane. In these systems, the PEI coating of octyl-CALA permitted some stabilization. While octyl-CALA was more active vs. pNPB, octyl-CALB was much more active vs. mandelic esters or triacetin. Thus, depending on the specific reaction and the conditions, CALA or CALB may offer different advantages and drawbacks. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 35: e2735, 2019     

Modulation of the properties of immobilized CALB by chemical modification with 2,3,4-trinitrobenzenesulfonate or ethylendiamine. Advantages of using adsorbed lipases on hydrophobic supports

Lipase B from Candida antarctica (CALB) has been adsorbed on octyl-agarose or covalently immobilized on cyanogen bromide agarose. Then, both biocatalysts have been modified with ethylenediamine (EDA) or 2,4,6-trinitrobenzensulfonic acid (TNBS) just using one reactive or using several modifications in a sequential way (the most complex preparation was CALB–TNBS–EDA–TNBS). Covalently immobilized enzyme decreased the activity by 40–60% after chemical modifications, while the adsorbed enzyme improved the activity on p-nitrophenylbutyrate (pNPB) by EDA modification (even by a 2-fold factor). These biocatalysts were further characterized. The results showed that the effects of the chemical modification on the enzyme features were strongly dependent on the immobilization protocol utilized, the experimental conditions where the catalyst will be utilized, and the substrate. Significant changes in the activity/pH profile were observed after the chemical modifications. The effect of the modifications on the enzyme activity depends on the substrate and the reaction conditions: enzyme specificity is strongly altered by the chemical modification. Moreover, enzyme activity versus pNPB (using octyl-CALB–EDA) or versus R methyl mandelate (using octyl-CALB–TNBS) increased by almost a 2-fold factor at pH 5. The stability of the modified enzymes at different pH and in the presence of organic solvents generally decreased after the modifications, usually by no more than a 2-fold factor. However, under some conditions, some stabilization was found. CALB enantioselectivity in the hydrolysis of R/S methyl mandelate could be also improved by these chemical modifications (e.g., E-value went from 11 to 16 using octyl-CALB–TNBS at pH 5). Therefore, solid phase chemical modification of immobilized lipases may become a powerful tool in the design of lipase libraries with very different properties, each immobilized preparation may be used to produce a variety of forms with altered properties.     

Immobilization of Candida antarctica lipase B (CALB) on surface-modified rice husk ashes (RHA) via physical adsorption and cross-linking methods

In the present study, the recovery of activity of Candida antarctica lipase B (CALB) immobilized onto surface-modified rice husk ash (RHA) was 90% for both cross-linking and adsorption methods. Both cross-linked and adsorbed immobilized preparations were very stable, retaining more than 48% of their activity over the range of temperatures studied. The optimum temperature and optimum pH values were 37?°C and 7.0, respectively for both immobilized preparations, while the relative activities after storage at 4.0?°C for 60 days were 55% and 65% using cross-linking and adsorption methods, respectively. Also, the activity of the immobilized lipase began to decrease after 10 cycles, more than 58% of the initial activities were still retained after 10 cycles for both immobilization methods. These results indicated that lipase immobilized by cross-linking and adsorption not only effected activity recovery, but also remarkably effected stability, reusability and application adaptability. It can be concluded that, surface-modified RHA can be used as alternative supports for immobilization of CALB for polymerization reactions.     

The slow-down of the CALB immobilization rate permits to control the inter and intra molecular modification produced by glutaraldehyde

Lipase B from Candida antarctica (CALB) has been immobilized on octyl-agarose in two ways: rapidly, in 5 mM sodium phosphate (85% immobilization yield after 30 min), or slowly, in the presence of 30% (v/v) ethanol (40% immobilization yield after 30 min). Both biocatalysts were treated with glutaraldehyde in order to obtain different modification degrees on their amino groups (25, 50 and 100% modification). SDS-PAGE and detergent desorption experiments showed that, when the immobilization was performed in absence of ethanol, very large aggregates were formed by intermolecular crosslinking, while when 30% ethanol was added during immobilization, almost 90% of the enzyme remained as a monomer. The stability of both derivatives improved upon modification, both in thermal inactivation experiments (at pHs 5, 7 and 9) or in the presence of 50% (v/v) dimethylsulfoxide, achieving stabilization values ranging between 5 and 20 depending on the inactivation conditions. The stability increased proportionally with the modification degree, and was also higher when intermolecular bonds were performed (by a 2–4 factor). Moreover, the activity/pH profile was completely altered after enzyme modification, and, under certain conditions, the activity of the modified biocatalysts doubled that of the non-modified immobilized CALB. Results show that the addition of ethanol permits to have a distance between enzyme molecules that did not allow intermolecular crosslinking, and this has permitted to distinguish between the effects of intramolecular glutaraldehyde modifications and intermolecular glutaraldehyde crosslinking. The simple and controlled treatment of CALB-octyl with glutaraldehyde has proved to be an effective way to obtain a biocatalyst with improved activity and stability under different conditions.     

Decarboxylative aldol reaction catalysed by lipases and a protease in organic co-solvent mixtures and nearly anhydrous organic solvent media

Abstract

The effects of the choice of lipase, reaction medium, immobilization, presence of additives and temperature on conversion and stereoselectivity during a lipase catalysed decarboxylative aldol reaction were examined. It was shown that Candida antarctica lipase B (CALB) catalysed a decarboxylative aldol reaction between 4-nitrobenzaldehyde and ethyl acetoacetate in a 60% acetonitrile–40% aqueous buffer co-solvent mixture. Interestingly, free and immobilized forms of CALB showed opposite enantioselectivity in this media. The addition of 30 mol% imidazole increased the reaction rate from 8.5 to 55.7 μM min^??1 mg^??1. A 98% conversion could be achieved in 14 h (instead of 168 h) by adding imidazole. Other lipases also catalysed this reaction in different reaction media to a varying extent. With Mucor javanicus lipase in 30% DMSO, 20% enantiomeric excess (ee) of the (R)-product was observed. CALB also catalysed this reaction in nearly anhydrous acetonitrile. In the presence of cross-linked protein coated microcrystals of CALB, 90% conversion was obtained in this media in 24 h. A commercially available protease, alcalase, was also found to catalyse this reaction. While low water media gave poor conversion, the reaction in aqueous–60% acetonitrile co-solvent mixture gave 99% conversion in 72 h, provided imidazole was used as an additive.     

Enhanced recombinant protein production and differential expression of molecular chaperones in sf-caspase-1-repressed stable cells after baculovirus infection

Background

Industrial-scale biocatalytic synthesis of fine chemicals occurs preferentially as continuous processes employing immobilized enzymes on insoluble porous carriers. Diffusional effects in these systems often create substrate and product concentration gradients between bulk liquid and the carrier. Moreover, some widely-used biotransformation processes induce changes in proton concentration. Unlike the bulk pH, which is usually controlled at a suitable value, the intraparticle pH of immobilized enzymes may deviate significantly from its activity and stability optima. The magnitude of the resulting pH gradient depends on the ratio of characteristic times for enzymatic reaction and on mass transfer (the latter is strongly influenced by geometrical features of the porous carrier). Design and selection of optimally performing enzyme immobilizates would therefore benefit largely from experimental studies of the intraparticle pH environment. Here, a simple and non-invasive method based on dual-lifetime referencing (DLR) for pH determination in immobilized enzymes is introduced. The technique is applicable to other systems in which particles are kept in suspension by agitation.

Results

The DLR method employs fluorescein as pH-sensitive luminophore and Ru(II) tris(4,7-diphenyl-1,10-phenantroline), abbreviated Ru(dpp), as the reference luminophore. Luminescence intensities of the two luminophores are converted into an overall phase shift suitable for pH determination in the range 5.0-8.0. Sepabeads EC-EP were labeled by physically incorporating lipophilic variants of the two luminophores into their polymeric matrix. These beads were employed as carriers for immobilization of cephalosporin C amidase (a model enzyme of industrial relevance). The luminophores did not interfere with the enzyme immobilization characteristics. Analytical intraparticle pH determination was optimized for sensitivity, reproducibility and signal stability under conditions of continuous measurement. During hydrolysis of cephalosporin C by the immobilizate in a stirred reactor with bulk pH maintained at 8.0, the intraparticle pH dropped initially by about 1 pH unit and gradually returned to the bulk pH, reflecting the depletion of substrate from solution. These results support measurement of intraparticle pH as a potential analytical processing tool for proton-forming/consuming biotransformations catalyzed by carrier-bound immobilized enzymes.

Conclusions

Fluorescein and Ru(dpp) constitute a useful pair of luminophores in by DLR-based intraparticle pH monitoring. The pH range accessible by the chosen DLR system overlaps favorably with the pH ranges at which enzymes are optimally active and stable. DLR removes the restriction of working with static immobilized enzyme particles, enabling suspensions of particles to be characterized also. The pH gradient developed between particle and bulk liquid during reaction steady state is an important carrier selection parameter for enzyme immobilization and optimization of biocatalytic conversion processes. Determination of this parameter was rendered possible by the presented DLR method.     

Immobilization of lipase from Candida rugosa on Sepabeads(®): the effect of lipase oxidation by periodates

The objective of this paper was the investigation of a suitable Sepabeads^? support and method for immobilization of lipase from Candida rugosa. Three different supports were used, two with amino groups, (Sepabeads^? EC-EA and Sepabeads^? EC-HA), differing in spacer length (two and six carbons, respectively) and one with epoxy group (Sepabeads^? EC-EP). Lipase immobilization was carried out by two conventional methods (via epoxy groups and via glutaraldehyde), and with periodate method for modification of lipase. The results of activity assays showed that lipase retained 94.8% or 87.6% of activity after immobilization via epoxy groups or with periodate method, respectively, while glutaraldehyde method was inferior with only 12.7% of retention. The immobilization of lipase, previously modified by periodate oxidation, via amino groups has proven to be more efficient than direct immobilization of lipase via epoxy groups. In such a way immobilized enzyme exhibited higher activity at high reaction temperatures and higher thermal stability.