Immobilization of lipase into mesoporous silica particles by physical adsorption

Mesoporous silica particles for immobilization of lipase from Candida rugosa were prepared by precipitation and aggregation of primary particles from highly basic sodium silicate solution but without addition of templates. The average pore size of the material was 15.8 nm, which allowed enzyme adsorption inside the pores and high enzyme loading. Specific surface area of the material was found to be 359 m²g^?1. A loading of 100 mglipasegdrysilica^?1 was obtained at initial enzyme concentration of 1.8 mgmL^?1 by physical adsorption. The FTIR spectrum showed the structural conformation of lipase to be retained after adsorption into the mesoporous silica support. Although the efficiency of the mesoporous biocatalyst was shown to be lower than that of the free enzyme, the immobilized enzyme showed enhanced thermal stability and could be desorbed with Triton X-100, indicating the hydrophobic nature of the adsorption.     

Lipase immobilized on hydrophobic porous polymer supports prepared by concentrated emulsion polymerization and their activity in the hydrolysis of triacylglycerides

Microporous polymer supports for the immobilization of lipase have been prepared by the polymerization of a concentrated emulsion precursor. The concentrated emulsion consists of a mixture of styrene and divinyl-benzene containing a suitable surfactant and an initiator as the continuous phase and water as the dispersed phase. The volume fraction of the latter phase was greater than 0.74, which is the volume fraction of the dispersed phase for the most compact arrangement of spheres of equal radius. The lipase from Candida rugosa has been immobilized on the internal surface of the hydrophobic microporous poly(styrene-divinyl benzene) supports and used as biocatalysts for the hydrolysis of triacylglycerides. The effects of the amount of surfactant, of the molar ratio of divinylbenzene/styrene in the continuous phase, and of the aquaphilicity of the supports on the adsorption, activity, and stability of the immobilized lipase have been investigated. The microporous poly(styrene-divinylbenzene) adsorbents constitute excellent supports for lipase because both the amount adsorbed is large and the rate of enzymatic reaction per molecule of lipase is higher for the immobilized enzyme than for the free one. (c) 1993 John Wiley & Sons, Inc.     

Improvement of the functional properties of a thermostable lipase from alcaligenes sp. via strong adsorption on hydrophobic supports

Lipase QL from Alcaligenes sp. is a quite thermostable enzyme. For example, it retains 75% of catalytic activity after incubation for 100 h at 55 °C and pH 7.0. Nevertheless, an improvement of the enzyme properties was intended via immobilization by covalent attachment to different activated supports and by adsorption on hydrophobic supports (octadecyl-sepabeads). This latter immobilization technique promotes the most interesting improvement of enzyme properties: (a) the enzyme is hyperactivated after immobilization: the immobilized preparation exhibits a 135% of catalytic activity for the hydrolysis of p-nitrophenyl propionate as compared to the soluble enzyme; (b) the thermal stability of the immobilized enzyme is highly improved: the immobilized preparation exhibits a half-life time of 12 h when incubated at 80 °C, pH 8.5 (a 25-fold stabilizing factor regarding to the soluble enzyme); (c) the optimal temperature was increased from 50 °C (soluble enzyme) up to 70 °C (hydrophobic support enzyme immobilized preparations); (d) the enantioselectivity of the enzyme for the hydrolysis of glycidyl butyrate and its dependence on the experimental conditions was significantly altered. Moreover, because the enzyme becomes reversibly but very strongly adsorbed on these highly hydrophobic supports, the lipase may be desorbed after its inactivation and the support may be reused. Very likely, adsorption occurs via interfacial activation of the lipase on the hydrophobic supports at very low ionic strength. On the other hand, all the covalent immobilization protocols used to immobilize the enzyme hardly improved the properties of the lipase.     

Improved activity of a lipase by vacuum drying on to a hydrophobic microporous support

Summary Lipase from Rhizopus arrhizus was immobilized by physical adsorption on hydrophobic microporous polypropylene supports. The immobilized enzyme catalyst was employed for the hydrolysis of palm kernel olein in the presence of n-hexane. The initial rate of lipolysis for vacuum dried immobilized lipase is nearly double that of air dried. The initial rate of lipolysis declines with increase of drying time. Immobilized lipase clearly reveals a relatively high initial rate after 30 days of storage at 4 °C. Stability of the immobilized lipase in buffer could be enhanced up to three-fold that of the free lipase.     

Enhanced Reactivity of Rhizopus oryzae Lipase Displayed on Yeast Cell Surfaces in Organic Solvents: Potential as a Whole-Cell Biocatalyst in Organic Solvents

Immobilization of enzymes on some solid supports has been used to stabilize enzymes in organic solvents. In this study, we evaluated applications of genetically immobilized Rhizopus oryzae lipase displayed on the cell surface of Saccharomyces cerevisiae in organic solvents and measured the catalytic activity of the displayed enzyme as a fusion protein with α-agglutinin. Compared to the activity of a commercial preparation of this lipase, the activity of the new preparation was 4.4 × 10⁴-fold higher in a hydrolysis reaction using p-nitrophenyl palmitate and 3.8 × 10⁴-fold higher in an esterification reaction with palmitic acid and n-pentanol (0.2% H₂O). Increased enzyme activity may occur because the lipase displayed on the yeast cell surface is stabilized by the cell wall. We used a combination of error-prone PCR and cell surface display to increase lipase activity. Of 7,000 colonies in a library of mutated lipases, 13 formed a clear halo on plates containing 0.2% methyl palmitate. In organic solvents, the catalytic activity of 5/13 mutants was three- to sixfold higher than that of the original construct. Thus, yeast cells displaying the lipase can be used in organic solvents, and the lipase activity may be increased by a combination of protein engineering and display techniques. Thus, this immobilized lipase, which is more easily prepared and has higher activity than commercially available free and immobilized lipases, may be a practical alternative for the production of esters derived from fatty acids.     

Evaluation of a silica-coated magnetic nanoparticle for the immobilization of a His-tagged lipase

Magnetic particles of size 10 nm have been coated with silica to a mean diameter of 40 nm and charged with Cu²⁺ ions via a multidentate ligand, iminodiacetic acid (IDA), for the immobilization of His-tagged Bacillus stearothermopilus L1 lipase. Microporous (average pore diameter of 60 Å) silica gel with a mean particle diameter of 115 µm has been used as a comparative support material. The molar ratio of Cu²⁺ to IDA was found to be 1:1.14 and 1:1.99 in the silica gel and the silica-coated magnetic nanoparticles (SiMNs), respectively. The specific activity of the immobilized enzyme was found to conform to the following order: Cu²⁺-charged SiMN>SiMN>Cu²⁺-charged silica gel>silica gel. When it was immobilized on the Cu²⁺-charged SiMNs, over 70% of the initial activity of the lipase remained after it had been reused five times. However, only 20% of the initial activity remained after the enzyme immobilized on the Cu²⁺-charged silica gel had been reused five times. For the enzyme immobilized on supports without Cu²⁺ cations, all activity was lost after threefold reuse. The differences in the specific activities and the efficiencies of reuse of the enzymes immobilized on the various support materials are discussed in terms of immobilization mechanisms (physical adsorption vs. coordination bonding), mass transfer of a substrate and a product of the enzyme reaction, and the status of the Cu (Cu bound to the IDA on the silica layer vs. Cu directly adsorbed on the silica layer).     

Enhancement of the activity and enantioselectivity of lipase in organic systems by immobilization onto low-cost support

Lipase from Arthrobacter sp. was immobilized onto low-cost diatomite materials using different protocols for the resolution of 4-hydroxy-3-methyl-2-(2-propenyl)-2-cyclopenten-1-one (HMPC) by asymmetric acylation. The support surface was grafted various functional groups including methacryloxypropyl, vinyl, octyl, dodecyl and γ-(aminopropyl)-glutaraldehyde. These modifications resulted in various mechanisms during the immobilization and thus introduced different characteristics to the prepared lipases. The interfacially adsorbed lipase onto dodecyl-modified support exhibited both higher activity and stability among these immobilized preparations. The modified enzyme-aggregate coating method was performed based on interfacial adsorption in our work, and the characteristics of this immobilized lipase were investigated and compared with those by cross-linking and interfacial adsorption methods. It was shown that the enzyme-aggregate coated lipase yielded the highest activity with a recovered activity of 8.5-fold of the free enzyme, and the highest operational stability with 85% of initial activity remained after 10 recycles. Excellent enantioselectivity (E ≥ 400, with e.e. = 99% of S-HMPC) was obtained for most lipase preparations in our paper (E = 85 for the free enzyme).     

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.     

Immobilization of Candida rugosa lipase by cross-linking with glutaraldehyde followed by entrapment in alginate beads

Candida rugosa lipase was immobilized by first cross-linking with glutaraldehyde and then entrapping in calcium alginate beads. The presence of 2-propanol during cross-linking markedly improved the enzyme activity and activity recovery. Maximal enzyme activity (2.1?mmol?h^?1?g^?1 immobilized conjugate, wet weight) and activity recovery (117%) were observed at 30% (v/v) 2-propanol for hydrolysis of olive oil, which were 1.7 and 2.0 times higher than those of the immobilized enzyme prepared in the absence of 2-propanol. The half-life of the immobilized lipase prepared by entrapment after cross-linking in 30% 2-propanol was 1.6 times higher than that prepared by entrapment of the native lipase without cross-linking and 2-propanol pretreatment. The enantioselectivity of the former was 11 times higher than that of the latter for hydrolysis of racemic ketoprofen ethyl ester.     

New Evidence for Dimerization-Dependence of the Activity of Candida Rugosa Lipase

The specific activity of the lipase of Cundidu rugosu decreases with increasing enzyme concentration even in the presence of soluble substrates. Data about the hydrolysis of 2-chloropropionic acid ethyl ester (CPEE) had suggested that this phenomenon may be caused either by dimerization of the lipase or by adsorption onto the reactor wall. In order to distinguish between both models, experiments were carried out by changing not only the enzyme concentration but also the wetted surface area of the reaction vessel. These novel data reveal that wetted glass surfaces are of only minor importance - if any. Thus, the decrease of activity seems to be caused by some kind of dimerization of the lipase. In addition, it is shown that adsorption onto hydrophobic surfaces can have a dramatic effect on the specific activity. In the presence of large hydrophobic surface areas the specific activity is found to be almost as high as that observed in the presence of insoluble substrate. The analysis of a commonly used test system for lipase activity measurements based on triacetin hydrolysis exhibits a similar activity-enzyme concentration dependence.     

Immobilization of lipase from Candida rugosa on a polymer support

Lipase from Candida rugosa was immobilized by adsorption onto a macroporous copolymer support. Under optimum conditions the maximum amount of protein bound was 15.4 mg/g and the immobilization efficiency was 62%. The kinetics of lipase binding to the selected polymer carrier was assessed by using a general model of topochemical reactions. The effect of temperature on adsorption was thoroughly investigated, as was the adsorption mechanism itself. Analysis of the proposed kinetic model and the specific kinetic parameters measured suggest that surface kinetics control the adsorption process. According to the activation energy (E _a) and the rate constant, k, the enzyme has rather a high affinity for the support's active sites. The immobilized enzyme was used to catalyse the hydrolysis of palm oil in a lecithin/isooctane reaction system, in which the enzyme's activity was 70% that of the free enzyme. Kinetic parameters such as maximum velocity (V _max) and the Michaelis constant (K _m) were determined for the free and the immobilized lipase. Following repeated use, the immobilized lipase retained 56% of its initial activity after the fifth hydrolysis cycle. Received: 3 April 1998 / Received revision: 28 July 1998 / Accepted: 29 July 1998     

Enhancing performance of lipase immobilized on methyl-modified silica aerogels at the adsorption and catalysis processes: Effect of cosolvents

Hydrophobic silica aerogels modified with methyl group were applied as support to immobilize Candida rugosa lipase (CRL). At the adsorption process, different alcohols were used to intensify the immobilization of CRL. The results showed that n-butanol wetting the hydrophobic support prior to contacting with enzyme solution could promote lipase activity, but the adsorption quantity onto the support decreased. Based on this, a novel immobilization method was proposed: the support contacted with enzyme solution without any alcohols, and then the immobilized enzymes were activated by 90% (V) n-butanol solution. The experimental results showed that this method could keep high adsorption quantity (413.0 mg protein/g support) and increase the lipase specific activity by more than 50%. To improve the stability of immobilized lipase, the support after adsorption was contacted with n-octane to form an oil layer covering the immobilized lipases, thus the leakage can be decreased from over 30–4% within 24 h. By utilizing proper cosolvents, a high enzyme activity and loading capacity as well as little loss of lipase was achieved without covalent linkage between the lipase and the support. This is known to be an excellent result for immobilization achieved by physical adsorption only.     

Poly(styrene-divinylbenzene) beads surface functionalized with di-block polymer grafting and multi-modal ligand attachment: performance of reversibly immobilized lipase in ester synthesis

Fibrous poly(styrene-b-glycidylmethacrylate) brushes were grafted on poly(styrene–divinylbenzene) (P(S–DVB)) beads using surface-initiated atom transfer radical polymerization. Tetraethyldiethylenetriamine (TEDETA) ligand was incorporated on P(GMA) block. The ligand attached beads were used for reversible immobilization of lipase. The influences of pH, ionic strength, and initial lipase concentration on the immobilization capacities of the beads have been investigated. Lipase adsorption capacity of the beads was about 78.1 mg/g beads at pH 6.0. The K _m value for immobilized lipase was about 2.1-fold higher than that of free enzyme. The thermal, and storage stability of the immobilized lipase also was increased compared to the native lipase. It was observed that the same support enzyme could be repeatedly used for immobilization of lipase after regeneration without significant loss in adsorption capacity or enzyme activity. A lipase from Mucor miehei immobilized on styrene–divinylbenzene copolymer was used to catalyze the direct esterification of butyl alcohol and butyric acid.     

Comparison of physical and covalent immobilization of lipase from Candida antarctica on polyamine microspheres of alkylamine matrix

Abstract

Polyamine microspheres (PA-M) prepared using polyethyleneimine as matrix were used for the immobilization of Candida antarctica lipase. The isoelectric point of PA-M is 10.6, and the hydrophobicity of PA-M was indicated using naphthalene. Optimization of conditions showed that the maximal loading of lipase on PA-M reached 230.2 mg g^{? 1} at pH 9.0 and 35°C. An increased buffer concentration had no effect on the activity of lipase but decreased the amount of lipase adsorbed. Simulation with Langmuir and Freundlich isotherms demonstrated that the adsorption of lipase on PA-M was thermodynamically favorable. Covalent crosslinking of the lipase adsorbed extended the pH range and increased the optimal temperature of the lipase activity. The physically adsorbed lipase (P-lipase) and the covalently immobilized derivative (C-lipase) retained more than 75% and 85% of their initial activity, respectively, after 10 cycles of usage. The half-lives of P-lipase and C-lipase at 50°C were 15.70 and 27.67 times higher than that of the free enzyme, respectively. Compared to P-lipase, covalent immobilization obviously reduced the catalytic efficiency and activation energy of the enzyme.     

Immobilization and characterisation of a lipase from a new source, Bacillus sp. ITP-001

A new source of lipase from Bacillus sp. ITP-001 was immobilized by physical adsorption on the polymer poly(3-hydroxybutyrate-co-hydroxyvalerate) (PHBV) in aqueous solution. The support and immobilized lipase were characterised, compared to the lyophilised lipase, with regard to the specific surface area, adsorption–desorption isotherms, pore volume (Vp) and size (dp) by nitrogen adsorption, differential scanning calorimetry, thermogravimetric analysis, chemical composition analysis, Fourier transform infrared spectroscopy and biochemical properties. The immobilized enzyme displayed a shift in optimum pH towards the acidic side with an optimum at pH 4.0, whereas the optimum pH for the free enzyme was at pH 7.0; the optimum temperature of activity was 80 and 37 °C for the free and immobilized enzyme, respectively. The inactivation rate constant for the immobilized enzyme at 37 °C was 0.0038 h^?1 and the half-life was 182.41 h. The kinetic parameters obtained for the immobilized enzyme gave a Michaelis–Menten constant (K _m) of 49.10 mM and a maximum reaction velocity (V _max) of 205.03 U/g. Furthermore, the reuse of the lipase immobilized by adsorption allowed us to observe that it could be reused for 10 successive cycles, duration of each cycle (1 h), maintaining 33 % of the initial activity.     

Immobilization of lipases for non-aqueous synthesis

Immobilization of lipases involves many levels of complications relating to the structure of the active site and its interactions with the immobilization support. Interaction of the so called hydrophobic ‘lid’ with the support has been reported to affect synthetic activity of an immobilized lipase. In this work we evaluate and compare the synthetic activity of lipases from different sources immobilized on different kinds of supports with varying hydrophobicity. Humicola lanuginosa lipase, Candida antarctica lipase B and Rhizomucor miehei lipase were physically adsorbed onto two types of hydrophobic carriers, namely hydrophilic carriers with conjugated hydrophobic ligands, and supports with base matrix hydrophobicity. The prepared immobilized enzymes were used for acylation of n-butanol with oleic acid as acyl donor in iso-octane with variable water content (0–2.8%, v/v) as reaction medium. Enzyme activity and effect of water on the activity of the immobilized derivatives were compared with those of respective soluble lipases and a commercial immobilized lipase Novozyme 435. Both R. miehei and H. lanuginosa immobilized lipases showed maximum activity at 1.39% (v/v) added water concentration. Sepabeads, a methacrylate based hydrophilic support with conjugated octadecyl chain showed highest immobilized esterification (synthetic) activity for all three enzymes, and of the three R. miehei lipase displayed maximum esterification activity comparable to the commercial enzyme.     

Immobilization of lipase onto a photo-crosslinked polymer network: Characterization and polymerization applications

Abstract

The recovery of activity of lipases immobilized onto a photo-crosslinked polymer network was 76.0% and 41.0% for entrapment and adsorption methods, respectively. Both entrapped and adsorbed immobilized enzymes were very stable, retaining more than 60% of their activity over the range of temperatures studied. Immobilization by either method protected their relative activities nearly 96% at 70°C. The optimum pH was 8.0 for immobilized enzymes and 6.0 for the free enzyme at 40°C, while the relative activities after storage at 0–4°C for 30 days were 98% and 75% using entrapment and adsorption methods, respectively. These results indicated that lipase immobilized by entrapment and adsorption not only had good activity recovery, but also remarkable stability, better reusability and application adaptability than free lipase. Also, it can be safely stated that, photo-crosslinked polymer network can be used as alternative supports for immobilization of lipase for enzymatic polymerization reactions. In the ring-opening polymerization of ?-caprolactone, polymerization rates were clearly affected as monomer conversions were 58% and 49% and the highest molecular weights (M_n) obtained were 7890 and 5600 gmol^{? 1} for entrapment and adsorption methods, respectively.     

Improvement of the enantioselectivity and activity of lipase from Pseudomonas sp. via adsorption on a hydrophobic support: kinetic resolution of 2-octanol

Pseudomonas sp. lipase (PSL) was successfully immobilized on a novel hydrophobic polymer support through physical adsorption and the immobilized PSL was used for resolution of (R,S)-2-octanol with vinyl acetate as acyl donor. Enhanced activity and enantioselectivity were observed from the immobilized PSL compared with free PSL. The effects of reaction conditions such as temperature, water activity, substrate molar ratio and the amount of immobilized lipase were investigated. Under optimum conditions, the residual (S)-2-octanol was recovered with 99.5% enantiomeric excess at 52.9% conversion. The results also indicated that the immobilized PSL could maintain 94% of its initial activity even after reusing it five times.     

Solid-phase handling of hydrophobins: immobilized hydrophobins as a new tool to study lipases

Hydrophobins are fungal proteins that self-assemble spontaneously at hydrophilic-hydrophobic interfaces and change the polar nature of the surfaces to which they attach. This attribute can be used to introduce hydrophobic foci on the surface of hydrophilic supports where hydrophobins are attached by covalent binding. In this paper, we report the binding of Pleurotus ostreatus hydrophobins to a hydrophilic matrix (agarose) to construct a support for noncovalent immobilization and activation of lipases from Candida antarctica, Humicola lanuginosa, and Pseudomonas flourescens. Lipase immobilization on agarose-bound hydrophobins proceeded at very low ionic strength and resulted in increased lipase activity and stability. The enzyme could be desorbed from the support using moderate concentrations of Triton X-100, and its enantioselectivity was similar to that of lipases interfacially immobilized on conventional hydrophobic supports. These results suggest that lipase adsorption on hydrophobins follows an "interfacial activation" mechanism; immobilization on hydrophobins offers new possibilities for lipase study and modulation and reveals a new application for fungal hydrophobins.     

Immobilization of Candida rugosa lipase on sporopollenin from Lycopodium clavatum

Sporopollenin is a natural polymer obtained from Lycopodium clavatum, which is highly stable with constant chemical structure and has high resistant capacity to chemical attack. In this study, immobilization of lipase from Candida rugosa (CRL) on sporopollenin by adsorption method is reported for the first time. Besides this, the enzyme adsorption capacity, activity and thermal stability of immobilized enzyme have also been investigated. It has been observed that under the optimum conditions (Spo-E_(0.3)), the specific activity of the immobilized lipase on the sporopollenin by adsorption was 16.3 U/mg protein, which is 0.46 times less than that of the free lipase (35.6 U/mg protein). The pH and temperature of immobilized enzyme were optimized, which were 6.0 and 40 °C respectively. Kinetic parameters V_max and K_m were also determined for the immobilized lipase. It was observed that there is an increase of the K_m value (7.54 mM) and a decrease of the V_max value (145.0 U/mg-protein) comparing with that of the free lipase.