Enantioselective behavior of lipases from <Emphasis Type="Italic">Aspergillus niger</Emphasis> immobilized in different supports

Considering the extraordinary microbial diversity and importance of fungi as enzyme producers, the search for new biocatalysts with special characteristics and possible applications in biocatalysis is of great interest. Here, we report the performance in the resolution of racemic ibuprofen of a native enantioselective lipase from Aspergillus niger, free and immobilized in five types of support (Accurel EP-100, Amberlite MB-1, Celite, Montmorillonite K10 and Silica gel). Amberlite MB-1 was found to be the best support, with a conversion of 38.2%, enantiomeric excess of 50.7% and enantiomeric ratio (E value) of 19 in 72 h of reaction. After a thorough optimization of several parameters, the E value of the immobilized Aspergillus niger lipase was increased (E = 23) in a shorter reaction period (48 h) at 35°C. Moreover, the immobilized Aspergillus niger lipase maintained an esterification activity of at least 80% after 8 months of storage at 4°C and could be reused at least six times.     

Synthesis of aspartame precursor: alpha-L-aspartyl-L-phenylalanine methyl ester in ethyl acetate using thermolysin entrapped in polyurethane

Cross-linked polyurethane (PU) was prepared for entrapping thermolysin. Using the immobilized thermolysin (IT), Z-L-aspartic acid (ZA) was reacted with -Lphenylalanine methyl ester (L-PM) in water-saturated ethyl acetate to give only alpha-Z-L-aspartylL-phenylalanine methyl ester (alpha-ZAPM). Ninety-four percent conversion of alpha-ZAPM was obtained for 30 h of reaction at 40 degrees C when 46 mg of enzyme was entrapped. PU support prepared from polypropylene glycol (#2000) showed better properties than from polypropylene (#1000) and polyethylene (#1000). Addition of polyol could increase the gel fraction of PU. The IT PU-ll-G-3, prepared from 1/2 mole ratio of PPG (#2000)/glycerin, gave the highest gel fraction and best swelling, and 89.0% of residual activity was obtained after four times of reuse (72 h). The stability of immobilized thermolysin was good; the activity loss resulting from degradatin and leak of enzyme in each time of reuse were found only about 2%. The kinetics of immobilized thermolysin-catalyzed condensation reaction of ZA with L-PM in water-saturated ethyl acetate was found to be first order in L-PM and the Lineweaver-Burk plot of 1/V against 1/[ZA] yields a straight line, showing that the reaction involves consecutive reactions of ZA and L-PM with the immobilized enzyme and with the ZA-immobilized enzyme complex, with the second reaction being the rate determining step.     

Covalent immobilization of pure isoenzymes from lipase of Candida rugosa

Covalent immobilization of pure lipases A and B from Candida rugosa on agarose and silica is described. The immobilization increases the half-life of the biocatalysts ( ) with respect to the native pure lipases ( ). The percentage immobilization of lipases A and B is similar in both supports (33–40%). The remaining activity of the biocatalysts immobilized on agarose (70–75%) is greater than that of the enzymatic derivatives immobilized on SiO₂ (40–50%). The surface area and the hydrophobic/hydrophilic properties of the support control the lipase activity of these derivatives. The thermal stability of the immobilized lipase A derivatives is greater than that of lipase B derivatives. The nature of the support influences the thermal deactivation profile of the immobilized derivatives. The immobilization in agarose (hydrophilic support) gives biocatalysts that show a greater initial specific reaction rate than the biocatalysts immobilized in SiO₂ (hydrophobic support) using the hydrolysis of the esters of (R) or (S) 2-chloropropanoic and of (R,S) 2-phenylpropanoic acids as the reaction test. The enzymatic derivatives are active for at least 196 h under hydrolysis conditions. The stereospecificity of the native and the immobilized enzymes is the same.     

Application of immobilized cells ofThermoanaerobium brockii for stereoselective reductions of oxo-acid esters

Summary Cells ofThermoanaerobium brockii were immobilized by entrapment methods as easy-to-handle biocatalyst for stereoselective reductions of oxo-acid esters. Different matrix materials were tested: agarose, k-carrageenan, alginate, polyacrylamide and polyurethanes. The two latter matrices allowed useful lifetimes of the immobilized biocatalysts of more than 2 months at thermophilic operation temperatures (around 65°C). Permeabilization of cells did not improve the catalytic activity. Immobilization of the cells did not enhance the thermostability. Only after a considerable period of operation could the immobilized biocatalysts be fed with medium lacking the complex substrates yeast extract and tryptone. Compared with freely suspended cells, reaction rates were lower. The immobilized system proved to be a relatively stable easy-to-handle biocatalyst, however, the freely suspended cells were superior with respect to flexibility of application and reaction velocity.     

Catalytic properties of the immobilized Aspergillus tamarii xylanase

Xylanase from Aspergillus tamarii was covalently immobilized on Duolite A147 pretreated with the bifunctional agent glutaraldehyde. The bound enzyme retained 54.2% of the original specific activity exhibited by the free enzyme (120 U/mg protein). Compared to the free enzyme, the immobilized enzyme exhibited lower optimum pH, higher optimum reaction temperature, lower energy of activation, higher K_m (Michaelis constant), lower V_max (maximal reaction rate). The half-life for the free enzyme was 186.0, 93.0, and 50.0 min for 40, 50, and 60°C, respectively, whereas the immobilized form at the same temperatures had half-life of 320, 136, and 65 min. The deactivation rate constant at 60°C for the immobilized enzyme is about 6.0 × 10⁻³, which is lower than that of the free enzyme (7.77 × 10⁻³ min). The energy of thermal deactivation was 15.22 and 20.72 kcal/mol, respectively for the free and immobilized enzyme, confirming stabilization by immobilization. An external mass transfer resistance was identified with the immobilization carrier (Duolite A147). The effect of some metal ions on the activity of the free and immobilized xylanase has been investigated. The immobilized enzyme retained about 73.0% of the initial catalytic activity even after being used 8 cycles.     

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.     

Effect of various parameters on viability and growth of bacteria immobilized in sol–gel-derived silica matrices

Immobilized bacteria are being extensively used for metabolite production, biocatalysts, and biosensor construction. However, long-term viability and metabolic activity of entrapped bacteria is affected by several conditions such as their physiological state, the presence of high-osmolarity environments, porous structure and shrinkage of the matrix. The aim of this work was to evaluate the effect of various parameters on bacteria immobilized in sol–gel-derived silica matrices. With this purpose, we evaluated the stress of immobilization over bacteria cultures obtained from different growing states, the effect of cell density and bacteria capability to proliferate inside matrices. Best results to attain longer preservation times were obtained when we immobilized suspensions with an optimized bacterial number of 1 × 10⁷ cfu/gel in the presence of LB medium using aqueous silica precursors. Furthermore, the impact of osmotic stress with the subsequent intracellular trehalose accumulation and the addition of osmolites were investigated. Shorter preservation times were found for bacteria immobilized in the presence of osmolites while trehalose accumulation in stressed cells did not produce changes on entrapped bacteria viability. Finally, nutrient addition in silica matrices was studied indicating that the presence of a carbon source without the simultaneous addition of nitrogen was detrimental for immobilized E. coli. However, when both carbon and nitrogen sources were present, bacteria were able to survive longer periods of time.     

Immobilization of lipase for effective interesterification of fats and oils in organic solvent

In order to investigate quantitatively the interesterification reaction, triolein and stearic acid were used as substrates and eight commercially available lipases were tested for their suitability for the reaction. Three fungal lipase preparations were found to be suitable. The hydrolytic activity of the commercial lipases was tested with olive oil, and it 2was noted that there was no correlation between their hydrolytic and interesterification activities. Among the lipases tested, Mucor miehei lipase was chosen for further study because of it high protein content and its relatively high hydrolytic and interesterification activities, both of which are required for effective interesterification. The effect of water activity of the interesterification reaction was investigated. interesterification activity was shown to be maximum at the water activity of 0.25. As the water activity of the lipase increased, hydrolysis of triglyceride was accelerated. At zero water activity, high conversion was achieved, although interesterification activity was relatively lower than that at the water activity of 0.25. A new and simple immobilization method was developed in order to render hydrophobicity to the lipase and hence to improve the interesterification activity of the lipase. The lipase was immobilized covalently with glutaraldehyde or with six alkyl chains as spacers onto Florisil (magnesium silicate, a inorganic matrix). Interesterification activity of the immobilized lipase with the hydrophobic spacers were increased against that of re lipase. The increase of activity was up to 8-fold that of the original activity of free lipase when the spacer was 7-aminoheptanoic acids. Relatively high stability of the immobilized lipase was shown in a continuous packed bed column reactor with a half-life of 97 days. (c) 1993 John Wiley & Sons, Inc.     

Production of biodiesel fuel from soybean oil catalyzed by fungus whole-cell biocatalysts in ionic liquids

The methanolysis of soybean oil to produce a fatty acid methyl ester (ME, i.e., biodiesel fuel) was catalyzed by lipase-producing filamentous fungi immobilized on biomass support particles (BSPs) as a whole-cell biocatalyst in the presence of ionic liquids. We used four types of whole-cell biocatalysts: wild-type Rhizopus oryzae producing triacylglycerol lipase (w-ROL), recombinant Aspergillus oryzae expressing Fusarium heterosporum lipase (r-FHL), Candida antarctica lipase B (r-CALB), and mono- and diacylglycerol lipase from A. oryzae (r-mdlB). w-ROL gave the high yield of fatty acid methyl ester (ME) in ionic liquid [Emim][BF₄] or [Bmim][BF₄] biphasic systems following a 24 h reaction. While lipases are known to be severely deactivated by an excess amount of methanol (e.g. 1.5 Mequiv. of methanol against oil) in a conventional system, methanolysis successfully proceeded even with a methanol/oil ratio of 4 in the ionic liquid biphasic system, where the ionic liquids would work as a reservoir of methanol to suppress the enzyme deactivation. When only w-ROL was used as a biocatalyst for methanolysis, unreacted mono-glyceride remained due to the 1,3-positional specificity of R. oryzae lipase. High ME conversion was attained by the combined use of two types of whole-cell biocatalysts, w-ROL and r-mdlB. In a stability test, the activity of w-ROL was reduced to one-third of its original value after incubation in [Bmim][BF₄] for 72 h. The stability of w-ROL in [Bmim][BF₄] was greatly enhanced by cross-linking the biocatalyst with glutaraldehyde. The present study demonstrated that ionic liquids are promising candidates for use as the second solvent in biodiesel fuel production by whole-cell biocatalysts.     

Response surface methodology-based optimization of glucose acylation bio-catalyzed by immobilized lipase

This paper describes in detail the selection and optimization of immobilized lipases for enhanced regioselective acylation of glucose into glucose monolaurate (GlcML). Initially, nature of biocatalyst, immobilization approach, reaction media, glucose, and lauric acid concentration were screened out. Finally, lipases from Rhizopus arrhizus immobilized on dead mycelia were investigated under various reaction conditions (Temperature, shaking speed, enzyme dose, and water content) following a fully rotatable central composite design (FRCCD) to optimize the activity of lipases. The immobilized lipases-based biocatalysts in the presence of polar solvents (tertiary alcohols) and higher concentrations of substrates i.e. glucose and lauric acid (100 and 300?mmol?L^?1, respectively) offered conversion rate of 1.5 mmolmin^?1?L^?1. Moreover, optimization of reaction conditions revealed that 162.5 lipase units/100mL at 31.25?°C, 3% water content, and 105?RPM shaking speed enhanced the conversion rate by 0.5 mmolmin^?1?L^?1 rendering the reaction more economical. Hence, lipases-based immobilized biocatalysts may provide an intelligent and green choice for commercial scale synthesis of GlcML for food and pharmaceutical industries.     

Cyclodextrin glucanotransferase production by cell biocatalysts of alkaliphilic bacilli

Cells of obligated alkaliphiles Bacillus pseudalcaliphilus 20RF and Bacillus pseudalcaliphilus 8SB isolated from Bulgarian habitats, producers of cyclodextrin glucanotransferase (CGTase, EC 2.4.1.19), were immobilized by three different techniques: on two types of polysulphone membranes; entrapped in agar-gel beads containing magnetite and by nano-particles of silanized magnetite covalently bound on the cell surface. The biocatalysts obtained demonstrated the opportunity for a significantly enhanced CGTase production compared to free cells for a long period of time (10 days semicontinuous cultivation) without impact on their mechanical stability. The cell membrane-biocatalysts exhibited the highest enzyme activity after 240 h repeated batch cultivation and retained 1.3–2.3-fold increase of the CGTase yield compared to free cells at the end of the process. Membrane biocatalysts were applied for a direct cyclodextrin (CD) production. The results obtained demonstrated the possibility of starch conversion into cyclodextrins by immobilized cells without using of crude or purified enzyme. The membrane biocatalysts of both obligated alkaliphiles formed mainly β- and γ-CDs after 6 h enzyme reaction at pH 9.0 of the reaction mixture. Under these conditions, the quantity of γ-CDs was a relative high, to 35–37% of the total CD amount.     

Biological denitrification by <Emphasis Type="Italic">Pseudomonas stutzeri</Emphasis> immobilized on microbial cellulose

This study demonstrated the feasibility of a biological denitrification process using immobilized Pseudomonas stutzeri. The microbial cellulose (MC) from Acetobacter xylinum was used as the support material for immobilization of the bacterium. Nitrate removal took place mainly in the anoxic system. The effects of various operating conditions such as the initial nitrate concentration, pH, and carbon source on biological denitrification were demonstrated experimentally. The system demonstrated a high capacity for reducing nitrate concentrations under optimum conditions. The denitrification rate increased up to a maximal value of 1.6 kg NO₃-N m⁻³ day⁻¹ with increasing nitrate loading rate. Because of its porosity and purity, MC may be considered as appropriate supports for adsorbed immobilized cells. The simplicity of immobilization and high efficiency in operation are the main advantages of such systems. To date, the immobilization of microorganisms onto MC has not been carried out. The results of this research shows that a pilot bioreactor containing P. stutzeri immobilized on MC exhibited efficient denitrification with a relatively low retention time.     

Acidolysis between Triolein and Short-Chain Fatty Acid by Lipase in Organic Solvents

Ten kinds of lipases were examined as biocatalysts for the incorporation of short-chain fatty acids (acetic, propionic, and butyric acids) into triolein in order to produce one kind of reduced-calorie structured lipids. Trans-esterification (acidolysis) was successfully done in n-hexane by several microbial lipases. Among them, lipase from Aspergillus oryzae was used to investigate the effects of incubation time, substrate molar ratio, and water content on acidolysis. Finally, more than 80% of triolein was incorporated by butyric acid (molar ratio of triolein to butyric acid, 1:10) in the dried n-hexane at 52 °C for 72 h. More than 90% of the products was monosubstituent, which was esterified with this short chain fatty acid at the 1-position of the glycerol moiety of triolein. These results suggest that A. oryzae lipase would be a powerful biocatalyst for the synthesis of low caloric oil, such as triacylglycerol containing a mixture of long- and short-chain aliphatic acids.     

Immobilization in the presence of Triton X-100: modifications in activity and thermostability of <Emphasis Type="Italic">Geobacillus thermoleovorans</Emphasis> CCR11 lipase

A partially purified lipase produced by the thermophile Geobacillus thermoleovorans CCR11 was immobilized by adsorption on porous polypropylene (Accurel EP-100) in the presence and absence of 0.1% Triton X-100. Lipase production was induced in a 2.5% high oleic safflower oil medium and the enzyme was partially purified by diafiltration (co. 500,000 Da). Immobilization conditions were established at 25 °C, pH 6, and a protein concentration of 0.9 mg/mL in the presence and absence of 0.1% Triton X-100. Immobilization increased enzyme thermostability but there was no change in neither the optimum pH nor in pH resistance irrelevant to the presence of the detergent during immobilization. Immobilization with or without Triton X-100 allowed the reuse of the lipase preparation for 11 and 8 cycles, respectively. There was a significant difference between residual activity of immobilized and soluble enzyme after 36 days of storage at 4 °C (P < 0.05). With respect to chain length specificity, the immobilized lipase showed less activity over short chain esters than the soluble lipase. The immobilized lipase showed good resistance to desorption with phosphate buffer and NaCl; minor loses with detergents were observed (less than 50% with Triton X-100 and Tween-80), but activity was completely lost with SDS. Immobilization of G. thermoleovorans CCR11 lipase in porous polypropylene is a simple and easy method to obtain a biocatalyst with increased stability, improved performance, with the possibility for re-use, and therefore an interesting potential use in commercial conditions.     

Selective immobilization of Bacillus subtilis lipase A from cell culture supernatant: Improving catalytic performance and thermal resistance

Bacillus subtilis lipase A (BSLA) has been extensively studied through protein engineering; however, its immobilization and behavior as an insoluble biocatalyst have not been extensively explored. In this work, for the first time, a direct immobilization of recombinant BSLA from microbial culture supernatant was reported, using chemically modified porous with different electrostatic, hydrophobic, hydrophilic, and hydrophilic−hydrophobic enzyme-support interactions. The resulting biocatalysts were evaluated based on their immobilization kinetics, activity expression (pH 7.4), thermal stability (50 °C), solvent resistance and substrate preference. Biocatalysts obtained using glyoxyl silica support resulted in the selective immobilization of BSLA, resulting in an activity recovery of 50 % and an outstanding aqueous stabilization factor of 436, and 9.5 in isopropyl alcohol, compared to the free enzyme. This selective immobilization methodology of BSLA allows to efficiently generate immobilized biocatalysts, thus avoiding laborious purification steps from cell culture supernatant, which is usually a limiting step when large amounts of enzyme variants or candidates are assessed as immobilized biocatalysts. Direct enzyme immobilization from cell supernatant provides an interesting tool which can be used to facilitate the development and assessment of immobilized biocatalysts from engineered enzyme variants and mutant libraries, especially in harsh conditions, such as high temperatures or non-aqueous solvents, or against non-water-soluble substrates. Furthermore, selective immobilization approaches from cell culture supernatant or clarified lysates could help bridging the gap between protein engineering and enzyme immobilization, allowing for the implementation of immobilization steps in high throughput enzyme screening platforms for their potential use in directed evolution campaigns.     

Practical application of different enzymes immobilized on sepabeads

The immobilization of an endoglucanase, benzoylformate decarboxylase (BFD) from Pseudomonas putida, as well as of lipase B from Candida antarctica (CALB) onto the carrier supports Sepabeads EC-EP, Sepabeads EC-EA, and Sepabeads EC-BU was accomplished. It is shown that via these immobilized biocatalysts the synthesis of both fine and bulk chemicals is possible. This is illustrated by the syntheses of polyglycerol esters and (S)-hydroxy phenyl propanone. The benefit of immobilization is illustrated by repetitive use in a bubble column reactor as well as in a stirred tank reactor. High stability of two biocatalysts was achieved and reusability up to eight times was demonstrated. The comparison of CALB immobilized on Sepabeads EC-EP to Novozym 435 shows similar activity. Dedicated to Prof. Dr. Christian Wandrey on the occasion of his 65th birthday.     

FTIR-ATR characterization of free Rhizomucor meihei lipase (RML), Lipozyme RM IM and chitosan-immobilized RML

The synthesis and characterization of biocatalysts based on lipase from Rhizomucor miehei (RML) immobilized on chitosan-based supports were investigated. The enzyme was immobilized on chitosan following two strategies: (i) physical adsorption; and (ii) covalent bonding using glutaraldehyde. The content of enzyme bound in the supports, as precipitable protein, was analyzed using UV/visible methods. FTIR-ATR spectroscopy was employed to characterize the prepared biocatalysts, as well the native enzyme and a commercial biocatalyst Lipozyme RM IM, used as reference materials. Analysis of the amide I′ signal allowed to follow the changes in the secondary structure of the enzyme after binding to the support and its thermal stability. The hydrolysis of ethyl stearate monitored in situ by FTIR-ATR was used as a test reaction. Results showed that RML was bound to Chit and Glut–Chit with minor changes in its secondary structure, thermal stability and enzymatic activity in a selected reaction test.     

Stabilization ofd-amino-acid oxidase fromTrigonopsis variabilis by manganese dioxide

Stabilization of immobilized D-amino-acid oxidase was achieved as follows. Yeast Trigonopsis variabilis producing D-amino-acid oxidase was used to deaminate cephalosporin C to glutaryl-7-aminocephalosporanic acid. Permeabilized cells were co-immobilized with manganese dioxide by entrapment in (poly)acrylamide gel so that hydrogen peroxide, liberated in the reaction, could be partially deactivated and both the enzyme and the substrate could be stabilized. Activity of entrapped cells was determined by HPLC and enzyme flow microcalorimetry. The process was evaluated in terms of activity, immobilization yield, storage stability and oxo-product formation by immobilized preparations. The storage stability of immobilized biocatalysts with MnO2 was nearly doubled and production of 2-oxoadipyl-7-aminocephalosporanic acid was 2-3-fold higher than by entrapped cells without MnO2. Glutaryl-7-aminocephalosporanic acid can be easily obtained from the resulting oxo-product by a non-enzymic reaction via externally added hydrogen peroxide.     

Membrane microreactor in biocatalytic transesterification of triolein for biodiesel production

Transesterification is a principal chemical reaction that occurs in biodiesel production. We developed a novel biocatalytic membrane microreactor (BMM) for continuous transesterification by utilizing an asymmetric membrane as an enzyme-carrier for immobilization. The BMM was developed by pressure driven filtration of lipase from Pseudomonas fluorescens, which is suitable for highly efficient biocatalytic transesterification. Lipase solution was allowed to permeate through an asymmetric membrane with NMWL 300 kDa composed of polyethersulfone. The performances of BMM were studied in biodiesel synthesis via transesterification of triolein with methanol. Transesterification was carried out by passing a solution of triolein and methanol through the asymmetric membrane. The degree of triolein conversion using this microreactor was ca. 80% with a reaction time of 19 min. The BMM system displayed good stability, with no activity decay over a period of 12 day with continuous operation. Results from triolein transesterification clearly demonstrate the potential of an asymmetric membrane as an enzyme carrier material. Enzyme activity (mmol/h·g_lipase) was approximately 3 fold higher than that of native free lipase.     

Nucleoside synthesis by immobilised bacterial whole cells

Biocatalysed synthesis of nucleosides was carried out using immobilised whole cells of Escherichia coli ATCC 47092, Enterobacter gergoviae CECT 857 and Citrobacter amalonaticus CECT 863. The synthesis of adenosine from uridine was used as reaction model to test the biocatalysts. Reactions were carried out using non-growing cells. Maximum activity was obtained with cells harvested at the beginning of the stationary phase. Immobilization by whole cell entrapment was employed using different matrix such as alginate, agar, agarose and polyacrylamide. The percentage of monomer, the shaking speed, the catalyst load and nature of the matrix were optimized. In the first reutilization cycle, similar yields (80–95%) were obtained with both free and immobilized cells in the reaction model, although in the last case, longer reaction times were necessary. The immobilized cells can be reused at least for more than 30 times without significant loss of the catalytic activity. The immobilized biocatalysts have been used in the synthesis of different nucleosides.