Improved nonporous magnetic supports for immobilized enzymes.

Ni powders coated by deposition of TiO2 or controlled oxidation to NiO develop substantial resistance to corrosion. Chymotrypsin immobilized to these coated Ni supports shows very high stability of activity on storage. Chymotrypsin immobilized by adsorption and glutaraldehyde crosslinking was fairly rapidly eluted under operational conditions in the presence of substrate. If 3-aminopropyltriethoxysilane (APS) was used to produce a covalent linkage, desorption of enzyme still occurred because of relatively unstable bonding of the silane to the oxide surface. A more stable attachment was produced by joining together many silane links with a layer of polyglutaraldehyde. The mechanism of action of APS as a coupling agent under these conditions is discussed. gamma-Fe2O3, and particularly a Mn-Zn ferrite, are suitable magnetic support materials available with smaller particle sizes. Particles below 1 mum give the expected higher specific activities of immobilized enzymes.     

Proteolytic Activity of Chymotrypsin Immobilized on Selenium Nanoparticles

Chymotrypsin was immobilized as a part of hybrid organo-inorganic nanocomplexes on selenium nanoparticles in the reduction reaction of selenious acid with ascorbic acid. Chymotrypsin stabilized the selenium nanoparticles in the solution. The spectral characteristics of synthesized nanocomplexes and the proteolytic activity of immobilized chymotrypsin were studied. It was shown that the immobilized enzyme had increased proteolytic activity in an alkaline medium.     

Purification of chymotrypsin by subunit exchange chromatography on the denatured protein

The alpha-chymotrypsin subunits immobilized under denaturing conditions (6 M urea or 1% SDS) on CNBr-activated Sepharose 4B, were found to interact with soluble chymotrypsin subunits with the formation of oligomers higher than dimers. Subunits immobilized under nondenaturing conditions form only dimers. The effects of several parameters, such as organic solvents, cations, and anions of the lyotropic series, on the associating properties of the immobilized derivatives were examined. The interaction between immobilized and free enzyme was shown to be specific because extraneous proteins and compounds were not bound by the derivatives. Chymotrypsinogen, studied analogously, did not show appreciable self-associating capacity. Chymotrypsin subunits immobilized under denaturing conditions and packed in a column proved to be suitable for the purification of chymotrypsin from both bovine and porcine pancreatic extracts. The "subunit exchange" chromatography of such extracts, carried out between pH 2.5 and 4, gave an eightfold purification with a 93% recovery of chymotryptic activity. The specific activity was ca. 12,000 Schwert and Takenaka units/mg. Only 6% of the tryptic activity was bound by the column. The capacity of the matrix, 6 mg chymotrypsin/mL, dropped to about 70% of the original value after.     

葡聚糖磁性毫微粒固定化L－天冬酰胺酶的研究

葡聚糖磁性毫微粒固定化Ｌ－天冬酰胺酶的研究徐慧显,李民勤,潘再群,马建标,何炳林（南开大学高分子化学研究所,天津３０００７１）大肠杆菌天冬酰胺酶对急性淋巴白血病有明显疗效［１］,注射入体内以后,可迅速清除血清中的天冬酰胺──敏感性肿瘤细胞的必需营养成...     

Affinity chromatography on hydroxyalkyl methacrylate gels. III. Adsorption of chymotrypsin to poly(hydroxyalkyl methacrylates) with covalently bound benzyloxycarbonyl-glycyl-D-phenylalanine and -D-leucine as function of pH and ionic strength.

Chymotrypsin is specifically adsorbed at low ionic strength and alkaline pH to hydroxyalkyl methacrylate gels with N-benzyloxycarbonylglycl-D-phenylalanine or N-benzyloxycarbonylglycyl-D-leucine attached through 1,6-hexanediamine. Chymotrypsin is not adsorbed either to the unmodified gel (Spheron) or to the gel with attached, 1,6-hexanediamine (NH2-Spheron). The adsorption of chymotrypsin to Z-Gly-D-Phe-NH2-Spheron was investigated as a function of pH and ionic strength. Trypsin is not adsorbed to this gel. Chymotrypsin isolated from a crude pancreatic extract by affinity chromatography on Z-Gly-D-Phe-NH2-Spheron had the same activity as the enzyme isolated on a column of Spheron, to which the naturally-occurring trypsin inhibitor had been coupled.     

Enzyme asymmetry in hepatic microsomal vesicles. Criteria for localization of lumenal enzymes with proteases

Chymotrypsin inactivation of lysophosphatidic acid acyltransferase activity in detergent-disrupted rat liver microsomes, but not in intact microsomes, falsely indicated a lumenal location for the enzyme. Inhibition by several other proteases in the absence of detergent showed that lysophosphatidic acid acyltransferase activity is located on the cytoplasmic surface of microsomes. Chymotrypsin inactivation did not occur in vesicles disrupted by nitrogen cavitation unless deoxycholate was present, suggesting that deoxycholate exposes a cryptic chymotrypsin cleavage site. Criteria for localization of lumenal microsomal enzymes should include studies using several proteases and/or employ more than one method of microsomal disruption.     

Characterization of heterogeneous immobilized enzyme subpopulations using EPR spectroscopy

Direct evidence was obtained for the existence of two distinct forms of active alpha-chymotrypsin immobilized on CNBr-activated Sepharose 4B. Electron paramagnetic resonance (EPR) spectra of five different spin-labeled immobilized enzyme formulations in the presence of indole were all resolved into the same two spectral components. Both subpopulation spectra were approximately identified experimentally, and the subpopulation exhibiting greatly restricted spin-label motion was shown also to be relatively inaccessible to solvent. Using overall specific activity data and subpopulation fractions from EPR spectral analysis, the specific activity of the more constricted immobilized enzyme active form was shown to be approximately 15 times smaller than that of the other class of immobilized enzyme molecules with an indole EPR spectrum similar to that of chymotrypsin in solution. Variations in overall specific activity of formulations with different loadings and different supports results entirely from changes in the proportions of the same two subpopulations of immobilized enzyme molecules.     

Rational protein modification leading to resistance of enzymes to TiO2-UV irradiation-induced inactivation

Photoexcited TiO2 degrades biomolecules such as nucleic acids, cell membrane proteins, and enzymes. Stabilization of enzyme activity against the deactivation caused by the combination of TiO2-UV is essential if we are to develop novel hybrid materials exhibiting photocatalytic and biocatalytic activities useful for decontamination applications. In this paper we describe the stabilization of a model enzyme, chymotrypsin, against TiO2-UV-induced deactivation by conjugating the enzyme with UV-absorbing, carboxyl-terminated oligo[2-[3-(2H-benzotriazol-2-yl)-4-hydroxyphenyl]ethyl methacrylate] [oligo(HBMA)-COOH]. Chymotrypsin was completely deactivated within 3 h, whereas the chymotrypsin-oligo(HBMA) conjugate retained > 50% activity even after 5 h of exposure to TiO2-UV (lambdamax 365 nm). The degree of enzyme stabilization induced by the conjugated UV absorber was 2-fold higher than that from the equivalent number of conjugated PEG chains. Spectroscopic characterizations revealed that chymotrypsin-oligo(HBMA) absorbs UV light and initially resists photoexcitation of TiO2. Modified chymotrypsin also exhibited resistance to changes in the secondary structure during the deactivation. This method of stabilizing enzymes against photodegradation could be also useful in photolithographic enzyme immobilizations for sensors and arrays or for stabilization of any UV-sensitive protein.     

Latex particles with thermo-flocculation and magnetic properties for immobilization of alpha-chymotrypsin

Core-shell-type latex particles composed of styrene, N-isopropylacrylamide (NIPAAm), and N-acryloxysuccinimide (NAS) were synthesized by surfactant-free emulsion polymerization. The latex particles show thermo-flocculation behavior due to the presence of temperature-sensitive monomer NIPAAm and could be used for immobilization of alpha-chymotrypsin through covalent bonding with the reactive ester groups of NAS. Enzyme recycle could be accomplished in this immobilized enzyme system by sedimentation of the thermo-flocculated latex particles in 20 min at 30 degrees C by raising the salt (NaCl) concentration to 0.5 M. To further enhance the sedimentation rate, ultrafine magnetite particles were prepared and included during polymerization to produce magnetic temperature-sensitive latex particles (MTLP), which could be recovered 6 times faster after thermo-flocculation by applying a low magnetic field. However, a higher salt concentration was necessary to flocculate the MTLP under the same condition as a result of its increased surface hydrophilicity, which originates from different polymerization conditions and the incorporation of magnetite. The immobilized enzyme shows high activity even against macromolecular substrates (hemoglobin and casein) owing to limited diffusion resistance, with full activity retention for nonmagnetic latex but one-half reduction in activity if the magnetic property was introduced. Optimal enzyme immobilization pH and enzyme loading were determined, and properties of the immobilized enzyme were characterized. The immobilized enzyme was used in 10 repeated batch hydrolyses of casein with successive flocculation/dispersion cycles and showed less than 15% activity decrease at the end. Overall, introducing the magnetic property to the latex could effectively enhance the solid-liquid separation rate after thermo-flocculation and maintain enzyme activity after repeated use but adversely influence the activity of the immobilized enzyme.     

Polyelectrolyte microcapsules as the systems for delivery of biologically active substances

Based on the method of the layer-by-layer (LbL) adsorption of oppositely charged polyelectrolytes, sodium alginate (Alg) and poly-L-lysine (PLL), novel biodegradable microcapsules have been prepared for delivery of biological active substances (BAS). Porous spherical CaCO₃ microparticles were used as templates. The template cores were coated with several layers of oppositely charged polyelectrolytes forming shell on the core surface. The core-shell microparticles were converted into hollow microcapsules by means of core dissolution with EDTA. Mild conditions for microcapsules preparation allow to perform incorporation of various biomolecules maintaining their bioactivity. Biocompatibility and biodegradability of the polyelectrolytes give a possibility to use the microcapsules as the target delivery systems. Chymotrypsin entrapped into the microcapsules was used as a model enzyme. The immobilized enzyme retained about 86% of the activity compared to a native chymotrypsin. The resultant microcapsules were stable in acidic medium and could be easily decomposed by trypsin treatment in slightly alkaline medium. Chymotrypsin was shown to be active after its release from the microcapsules decomposed by the trypsin treatment. Thus, the microcapsules prepared by the LbL technique can be used for the development of new type of BAS delivery systems in humans and animals.     

Porous zirconia: a new support material for enzyme immobilization

Four different proteases (trypsin, chymotrypsin, papain and pepsin) were covalently attached to the surface of a new type of porous zirconia, as well as a conventional porous silica, activated with 3-isothiocyanatopropyltriethoxy silane (NCS-silane). The immobilization efficiency onto the porous zirconia material was evaluated in terms of the amount of enzyme attached to the particles and from the biological activity remaining after the immobilization step. The results were compared with the corresponding experiments with a porous silica of similar surface area/g support material. In addition, the storage stability of the modified zirconia and silica biocatalysts were evaluated. These results indicated that specific immobilized enzyme biocatalysts can be achieved with this new zirconia support material which exhibits different properties to those observed with the more conventional silica-based materials. Moreover, the results with the enzyme-zirconia biocatalysts also indicate different characteristics when compared with data for the same enzymes immobilized under similar buffer conditions to organic support materials as previously described by various other investigators. The advantages of zirconia-based immobilized enzyme biocatalysts in terms of their density and chemical robustness are also described relative to other alternative support materials currently in use.     

Polymer materials for enzyme immobilization and their application in bioreactors

Enzymatic catalysis has been pursued extensively in a wide range of important chemical processes for their unparalleled selectivity and mild reaction conditions. However, enzymes are usually costly and easy to inactivate in their free forms. Immobilization is the key to optimizing the in-service performance of an enzyme in industrial processes, particularly in the field of non-aqueous phase catalysis. Since the immobilization process for enzymes will inevitably result in some loss of activity, improving the activity retention of the immobilized enzyme is critical. To some extent, the performance of an immobilized enzyme is mainly governed by the supports used for immobilization, thus it is important to fully understand the properties of supporting materials and immobilization processes. In recent years, there has been growing concern in using polymeric materials as supports for their good mechanical and easily adjustable properties. Furthermore, a great many work has been done in order to improve the activity retention and stabilities of immobilized enzymes. Some introduce a spacer arm onto the support surface to improve the enzyme mobility. The support surface is also modified towards biocompatibility to reduce non-biospecific interactions between the enzyme and support. Besides, natural materials can be used directly as supporting materials owning to their inert and biocompatible properties. This review is focused on recent advances in using polymeric materials as hosts for lipase immobilization by two different methods, surface attachment and encapsulation. Polymeric materials of different forms, such as particles, membranes and nanofibers, are discussed in detail. The prospective applications of immobilized enzymes, especially the enzyme-immobilized membrane bioreactors (EMBR) are also discussed.     

Chymotrypsin inhibitors in mosquitoes: Activity profile during development and after blood feeding

Chymotrypsin and trypsin inhibitors persist throughout all developmental instars of Aedes aegypti. After a blood meal, inhibitor activity against chymotrypsin was more than double that of sugar-fed females, but only weak activity was detected in midguts where proteinase inhibitors has been thought to regulate proteinases during blood digestion. A fourfold increase in the ratio of abdominal/thoracic inhibitor activity after the blood meal strongly suggested that fat body, or other abdominal tissues, represent the major source of inhibitor. Chymotrypsin inhibitor activity was deposited in maturing oocytes. Similar results were obtained with blood-fed Anopheles albimanus. Chymotrypsin inhibitor was active against different mosquito proteinases and against bovine α-chymotrypsin and trypsin, but not against subtilisin, pancreatic elastase, or fungal proteases; chymotrypsin inhibitors did not interfere with bacterial growth. The hypothesis on the regulation of blood digestion through the action of proteinase inhibitors during the gonotrophic cycle was abandoned and its involvement in the phenoloxidase cascade in the mosquito egg chorion is suggested instead. Arch. Insect Biochem. Physiol. 36:315–333, 1997. © 1997 Wiley-Liss, Inc.     

Non-porous magnetic supports for cell immobilization

A new method for covering magnetic particles with a stable non-porous layer of a material like zeolite or activated carbon was used for the preparation of support materials with good properties for the immobilization of yeast Saccharomyces cerevisiae cells. The immobilized cells can be used in batch and continuous alcoholic fermentation. A productivity of 35.6 g ethanol/l · h was reached. The adsorption isotherms of the immobilized yeast cells were determined. Yeast cell immobilization on non-porous magnetic supports obeyed the Langmuir isotherm equation. Satisfactory results were obtained also from repeated batch fermentations with fixed cells on supports additionally treated with glutaraldehyde or by simple adsorption.     

Studies on the transverse localization of lysophospholipase in bovine liver microsomes using proteolytic enzymes.

1. Sonication of bovine liver microsomes completely solubilized the membrane-bound lysophospholipase II (EC 3.1.1.5). Co-chromatography with purified 125I-labelled lysophospholipase indicated that the enzyme was solubilized from microsomes in a lipid-free state. 2. In the presence of residual microsomal membranes, the solubilized lysophospholipase could only be partly degraded by trypsin (EC 3.4.21.4). Therefore, trypsin could not be used to study the transmembrane disposition of lysophospholipase in intact microsomes. 3. Chymotrypsin (EC 3.4.21.1) destroyed the solubilized lysophospholipase activity, even in the presence of residual microsomal membranes. 4. Lysophospholipase in intact microsomal vesicles was resistant to chymotrypsin digestion. 5. When microsomal vesicles were made leaky with lysophosphatidylcholine, chymotrypsin destroyed more than 95% of the lysophospholipase activity. 6. It is concluded from these experiments that at least the active center of lysophospholipase is located at the luminal side of the bovine liver microsomal membrane.     

Characterization of deoxyribonuclease I immobilized on magnetic hydrophilic polymer particles

Magnetic bead cellulose particles and magnetic poly(HEMA-co-EDMA) microspheres with immobilized DNase I were used for degradation of chromosomal and plasmid DNAs. Magnetic bead particles were prepared from viscose and magnetite powder. Magnetic poly(HEMA-co-EDMA) microspheres were prepared by dispersion copolymerization of 2-hydroxyethyl methacrylate and ethylene dimethacrylate in the presence of magnetite. Divalent cations (Mg(2+), Ca(2+), Mn(2+) and Co(2+)) were used for the activation of DNase I. A comparison of free and immobilized enzyme (magnetic bead particles) activities was carried out in dependence on pH and activating cation. The maximum of the activity of immobilized DNase I was shifted to lower pH compared with free DNase I. DNase I immobilized on magnetic bead cellulose was used 20 times in the degradation of chromosomal DNA. Its residual activity was influenced by the nature of activating divalent cation. The immobilized enzyme with decreased activity was reactivated by Co(2+) ions.     

Partition zone penetration by chymotrypsin, and the localization of the chloroplast flavoprotein and photosystem II.

1. Chymotrypsin treatment of chloroplast membranes inactivates Photosystem II. The inactivation is higher when the activity is measured under low intensity actinic light, suggesting that primary photochemistry is preferentially inactivated. 2. Membrane stacking induced by Mg2+ protects Photosystem II against chymotrypsin inactivation. When the membranes are irreversible unstacked by brief treatment with trypsin, Mg2+ protection against chymotrypsin inactivation of Photosystem II is abolished. 3. The kinetics of inactivation by chymotrypsin of Photosystem II indicates that membrane stacking slows down, but does not prevent, the access of chymotrypsin to Photosystem II, which is mostly located within the partition zones. 4. It is concluded that a partition gap exists between stacked membranes of about 45 A, the size of the chymotrypsin molecule. 5. The kinetics of inhibition of the chloroplast flavoprotein, ferredoxin-NADP reductase, bt its specific antibody is not affected by membrane stacking. This indicates that this enzyme is located outside the partition zones.     

Preparation of Fine Magnetic Particles and Application for Enzyme Immobilization

Fine magnetic particles (ferrofluid) were prepared from a co-precipitation method by oxidation of Fe²⁺ with nitrite. The particles were activated with (3-aminopropyl)triethoxysilane in toluene and the activated particles were combined with some enzymes by using glutaraldehyde. Enzyme-immobilized magnetic particles were between 4-70 nm and the size could be changed corresponding to the ratio of the amount of Fe²⁺ to that of nitrite. In the immobilization of β-glucosidase, activity yield was 83% and 168 mg protein was immobilized per g magnetite. Other enzymes or proteins could be immobilized at the level between about 70 and 200mg/g support. Immobilized β-glucosidase was stable at 4°C. Magnetic particles immobilized with β-glucosidase responded quickly to the magnetic field and “ON-OFF” control of the enzyme reaction was possible.     

Preparation of Fine Magnetic Particles and Application for Enzyme Immobilization

Fine magnetic particles (ferrofluid) were prepared from a co-precipitation method by oxidation of Fe²⁺ with nitrite. The particles were activated with (3-aminopropyl)triethoxysilane in toluene and the activated particles were combined with some enzymes by using glutaraldehyde. Enzyme-immobilized magnetic particles were between 4-70 nm and the size could be changed corresponding to the ratio of the amount of Fe²⁺ to that of nitrite. In the immobilization of β-glucosidase, activity yield was 83% and 168 mg protein was immobilized per g magnetite. Other enzymes or proteins could be immobilized at the level between about 70 and 200mg/g support. Immobilized β-glucosidase was stable at 4°C. Magnetic particles immobilized with β-glucosidase responded quickly to the magnetic field and “ON-OFF” control of the enzyme reaction was possible.     

Development of sensors for direct detection of organophosphates. Part I: Immobilization, characterization and stabilization of acetylcholinesterase and organophosphate hydrolase on silica supports

Biosensors for organophosphates in solution may be constructed by monitoring the activity of acetylcholinesterase (AChE) or organophosphate hydrolase (OPH) immobilized to a variety of microsensor platforms. The area available for enzyme immobilization is small (< 1 mm2) for microsensors. In order to construct microsensors with increased surface area for enzyme immobilization, we used a sol-gel process to create highly porous and stable silica matrices. Surface porosity of sol-gel coated surfaces was characterized using scanning electron microscopy; pore structure was found to be very similar to that of commercially available porous silica supports. Based upon this analysis, porous and non-porous silica beads were used as model substrates of sol-gel coated and uncoated sensor surfaces. Two different covalent chemistries were used to immobilize AChE and OPH to these porous and non-porous silica beads. The first chemistry used amine-silanization of silica followed by enzyme attachment using the homobifunctional linker glutaraldehyde. The second chemistry used sulfhydryl-silanization followed by enzyme attachment using the heterobifunctional linker N-gamma-maleimidobutyryloxy succinimide ester (GMBS). Surfaces were characterized in terms of total enzyme immobilized, total and specific enzyme activity, and long term stability of enzyme activity. Amine derivitization followed by glutaraldehyde linking yielded supports with greater amounts of immobilized enzyme and activity. Use of porous supports not only yielded greater amounts of immobilized enzyme and activity, but also significantly improved long term stability of enzyme activity. Enzyme was also immobilized to sol-gel coated glass slides. The mass of immobilized enzyme increased linearly with thickness of coating. However, immobilized enzyme activity saturated at a porous silica thickness of approximately 800 nm.