Calmodulin-mediated reversible immobilization of enzymes

This work demonstrates the use of the protein calmodulin, CaM, as an affinity tag for the reversible immobilization of enzymes on surfaces. Our strategy takes advantage of the of the reversible, calcium-mediated binding of CaM to its ligand phenothiazine and of the ability to produce fusion proteins between CaM and a variety of enzymes to reversibly immobilize enzymes in an oriented fashion to different surfaces. Specifically, we employed two different enzymes, organophosphorus hydrolase (OPH) and beta-lactamase and two different solid supports, a silica surface and cellulose membrane modified by covalently attaching a phenothiazine ligand, to demonstrate the versatility of our immobilization method. Fusion proteins between CaM-OPH and CaM-beta-lactamase were prepared by using genetic engineering strategies to introduce the calmodulin tail at the N-terminus of each of the two enzymes. In the presence of Ca(2+), CaM adopts a conformation that favors interaction between hydrophobic pockets in CaM and phenothiazine, while in the presence of a Ca(2+)-chelating agent such as EGTA, the interaction between CaM and phenothiazine is disrupted, thus allowing for removal of the CaM-fusion protein from the surface under mild conditions. CaM also acts as a spacer molecule, orienting the enzyme away from the surface and toward the solution, which minimizes enzyme interactions with the immobilization surface. Since the method is based on the highly selective binding of CaM to its phenothiazine ligand, and this is covalently immobilized on the surface, the method does not suffer from ligand leaching nor from interference from other proteins present in the cell extract. An additional advantage lies in that the support can be regenerated by passing through EGTA, and then reused for the immobilization of the same or, if desired, a different enzyme. Using a fusion protein approach for immobilization purposes avoids the use of harsh conditions in the immobilization and/or regeneration steps, which could cause inactivation of the immobilized enzyme. Moreover, we have demonstrated that the CaM affinity tag allows immobilization of enzymes on a variety of surfaces without compromising their enzymatic activity substantially; for example, the immobilized OPH retained more than 80% of the activity of the free enzyme. Our results with beta-lactamase showed the feasibility of using a phenothiazine surface in several consecutive loading and regeneration cycles. This can be advantageous when expensive and/or difficult to obtain immobilization surfaces have to be employed; the immobilization surface could be reused to immobilize the same or a different enzyme using the CaM affinity tail. We also determined that the phenothiazine-modified silica particles are stable for long periods of time, i.e., up to 2 years when stored at 4 degrees C. It is envisioned that this type of reversible immobilization may find applications in the development of reversible, reusable biosensors and bioreactors endowed with the additional advantage that the biological element at the surface of the sensor or bioreactor could be replaced under mild conditions when needed to sense or process a different target molecule.     

Solid-phase thiolsulfinates for the reversible immobilization of thiols

A new method for the reversible immobilization of thiol-containing substances on agarose beads is presented. It is based on the use of thiolsulfinate (disulfide monoxide) as a solid-phase reactive group. The thiolsulfinate groups are introduced by controlled oxidation of thiol agarose. The method comprises two steps: First, mild oxidation of the agarose thiol groups to disulfide structures with potassium ferricyanide. Second, the oxidation of the so-formed agarose disulfide groups to thiolsulfinate groups by use of a stoichiometric amount of the oxidizing agent magnesium monoperoxyphtalate. The solid-phase thiolsulfinate groups react very easily with thiols, which, as a result of the reaction, will be bound to the agarose beads by disulfide bonds. The adsorbent derivative is very suitable for the reversible immobilization of low as well as high-mol-wt thiols as demonstrated with reduced glutathione, penicillamine, mercaptoethanesulfonic acid, thiolated bovine serum albumin,β-galactosidase, and ±₁-antitrypsine. Since treatment of the agarose derivatives with an excess of low-mol-wt thiols (e.g., dithiothreitol) leads to release of the bound molecules and regeneration of the original thiol groups, the reactive thiolsulfinate groups can easily be regenerated by the mentioned two-step procedure. The cycle of oxidation, binding, reduction, and reoxidation can be performed several times while retaining thiol binding capacity.     

Use of reversible denaturation for adsorptive immobilization of urease

Urease was chosen as a model multimeric protein to investigate the utility of reversible denaturation for immobilization to a hydrophobic support. Of the various procedures investigated, acidic denaturation provided the highest degree of immobilization and enzymatic activity with lowering of K _m (apparent). Exposure of hydrophobic clusters in the protein molecule induced by the acidic pH environment was confirmed by fluorescence studies using 8-anilino-1-naphtalene-sulfonate as a hydrophobic-reporter probe. The catalytic potential of the enzyme at low pH values was dramatically improved with significant heat and pH stability enhancement on immobilization. Furthermore, the immobilized preparation was used successfully in continuous catalytic transformations. Based on the results presented in this article and a recent report involving a relatively more simple monomeric protein, it is suggested that reversible denaturation may be of general utility for immobilization of proteins, which are not normally adsorbed on hydrophobic supports.     

Polyacrylhydrazido-agarose as a support for immobilization of enzymes,lectins, antibodies,and small ligands

Enzymes, antibodies, lectins, and small ligands were coupled to glutaraldehyde-activated polyacrylhydrazido-agarose. High yields of binding and activity were obtained. The bound enzymes exhibited increased stability to heat and 6 M urea when compared with the respective soluble enzyme as well as enzymes coupled to cyanogen bromide-activated agarose. Antibodies and lectins were also found to maintain specificity for the appropriate antigens and glycoprotein receptors, and were used effectively for affinity chromatography purifications. Polyacrylhydrazido-agarose provides a new carrier that combines advantages of both agarose and acrylamide in one resin.     

Methodology for the immobilization of enzymes onto mesoporous materials

Cytochrome c and xylanase were adsorbed onto two mesoporous materials, SBA-15 (a pure silicate) and MSE (an organosilicate), with very similar physical properties but differing chemical compositions. A methodical order was developed whereby the influences of surface area, pore size, extent of order, particle size, surface potentials, isoelectric points, pH, and ionic strength on immobilization were explored. In silico studies of cytochrome c and xylanase were conducted before any immobilization experiments were carried out in order to select compatible materials and probe the interactions between the adsorbents and the mesoporous silicates. The stabilities of the mesoporous materials at different pH values and their isoelectric points and zeta potentials were determined. Electrostatic attraction dominated protein interactions with SBA-15, while weaker hydrophobic interactions are more prominent with MSE for both cytochrome c and xylanase. The ability of the immobilized protein/enzyme to withstand leaching was measured, and activity tests and thermostability experiments were conducted. Cytochrome c immobilized onto SBA-15 showed resistance to leaching and an enhanced activity compared to free protein. The immobilized cytochrome c was shown to have higher intrinsic activity but lower thermostability than free cytochrome c. From an extensive characterization of the surface properties of the silicates and proteins, we describe a systematic methodology for the adsorption of proteins onto mesoporous silicates. This approach can be utilized in the design of a solid support for any protein.     

介孔分子筛在生物酶固定化中的应用

综述了MCM-48和SBA-15等新型介孔分子筛用生物酶固定化载体研究的新进展。介孔分子筛由于拥有巨大的比表面积(~1000m2/g)、纳米尺寸孔道(2~50m)和较大的孔容(~1.0 cm3/g),因此以分子筛为载体利用物理吸附制备的固定化酶呈现出高的催化活性,但固定化酶操作稳定性较低,在使用过程中部分酶分子发生了脱落,其原因是分子筛表面自由的硅羟基通过物理吸附或氢键作用固定酶分子。借助介孔分子筛自身的自由硅羟基在表面嫁接-COOH、-NH2、-CH=CH2等有机官能团来构筑酶固定化的微环境,改善酶分子和载体的亲和作用,提高固定化酶的活性。目前,利用有机官能团功能化介孔分子筛固定化酶是研究发展的趋势。     

Oriented immobilization of chymotrypsin by use of suitable antibodies coupled to a nonporous solid support.

In order to eliminate the kinetic limitation of chymotryptic hydrolysis of proteins due to diffusion, nonporous hydroxyalkyl methacrylate solid support was developed and used for oriented immobilization of chymotrypsin by means of suitable polyclonal antibodies. Nonporous microspheres were prepared by dispersion copolymerization of 2-hydroxyethyl methacrylate and ethylene dimethacrylate in an alcohol-toluene mixture stabilized with cellulose acetate butyrate. The resulting particles were 1.2 microm in diameter and possessed narrow size distribution. After modification with adipic acid dihydrazide they contained 2 micromol of reactive groups available for coupling of anti-chymotrypsin antibodies. Prepared immunosorbent adsorbed 166.7 microg of chymotrypsin per 1 g of dry carrier. Immobilized chymotrypsin retained practically 100% of its native proteolytic activity. Kinetic parameters of catalysis by chymotrypsin immobilized via this way were improved due to the good steric accessibility of the enzyme active site for high-molecular-mass substrates, when digestion of proteins in batch experiments was used.     

Strategies for immobilization of biomolecules in a microarray

Recent advances in the generation of peptide and protein microarrays are reviewed, with special focuses on different strategies available for site-specific immobilization of proteins and peptides.     

Silica Matrix with anhydride groups for immobilization of enzymes

We have studied the process of preparing a silica support with anhydride groups. The process includes introducing vinyl groups onto the surface with subsequent radiative copolymerization of maleic anhydride with them. The maximum degree of grafting of the functional groups of the matrix occurs for -irradiation doses of 20–30 Mrad. The carboxyl groups grafted to the aerosil surface, formed upon hydrolysis of the support, can be converted to anhydride by calcination at 403 K for 3 h.Translated from Teoreticheskaya i Éksperimental'naya Khimiya, Vol. 25, No. 6, pp. 750–753, November–December, 1989.     

Microporous regenerated cellulose-based macrogels for covalent immobilization of enzymes

Cellulose - In this study, regenerated cellulose-based macrogels with abundant carboxyl groups and interconnected microporous structures were synthesized from cellulose fibers (CFs)/cellulose...     

Effects of carbodiimide structure on the immobilization of enzymes

A series of water-soluble disubstituted carbodiimides of different structure was tested for enzyme immobilization. In the experiments, a polyacrylamide-type bead polymer possessing carboxylic functional groups was used as support. The enzymes immobilized were aminoacylase (N-acylamino acid amidohydrolase; EC 3.5.1.14), arginase (L-arginine amidinohydrolase; EC 3.5.3.1), cyclodextrin glycosyltransferase (alpha-1,4-glucan 4-glycosyltransferase, cyclizing; EC 3.2.1.19), glucoamylase (1,4-alpha-D-glucan glycohydrolase, EC 3.2.1.3), and carboxypeptidase B (peptidyl-L-lysine [L-arginine] hydrolase; EC 3.4.17.2). It was found that the degree of immobilization strongly depended on the structure of carbodiimide used.     

Biomimetic engineering of modular bispecific antibodies for biomolecule immobilization

Modular bispecific antibodies (BsAb's) that interact directly with a gold surface were engineered for immobilization on biosensing devices. The BsAb's consist of the variable fragments of antigold and antilysozyme antibodies connected via one of three linkers derived from naturally occurring proteins. The BsAb's were bound tightly to both the gold surface and to lysozyme, thus functioning as interface molecules between lysozyme and the gold surface without a substantial loss of antigen-binding activity. The antigen-binding capacity (the ratio of the amount of immobilized lysozyme to the amount of immobilized BsAb) on the gold surface reached 82%. An analysis of the correlation between binding capacity and linker characteristics indicated that the presence of a long, rigid linker sequence derived from a cellulase resulted in a higher antigen-binding capacity than did the presence of a long but relatively flexible glycine-rich linker. This result suggests a strategy for designing linkers suitable for BsAb-based biomolecular immobilization.     

Combined immobilization of lytic and proteolytic enzymes

The electrooxidation of the alkaloid ephedrine at solid electrodes in a wide range of concentrations and pH values of solutions has been studied by the methods of potentiodynamic voltammetric curves, preparative electrolysis, and quantum-chemical calculations by the SCF MO LCAO method in the MINDO/3 approximation. A quantitative basis has been given for the sequence of stages in the electrooxidation of ephedrine proposed previously by the authors of one of the cited papers. Good agreement has been established between the values found theoretically and experimentally.Institute of Organic Synthesis and Colloid Chemistry, Kazakh SSR Academy of Sciences, Karaganda. Translated from Khimiya Prirodnykh Soedinenii, No. 4, pp. 523–526, July–August, 1989.     

A model incorporating reversible immobilization for sorption and diffusion in glassy polymers

A model incorporating reversible, bimolecular immobilization for diffusion and sorption in glassy polymers is developed. Sorption is considered to occur by two distinct mechanisms: ordinary diffusion-controlled sorption and sorption resulting from the immobilization of diffusing gas molecules by prexisting sites in the polymer. Expressions are obtained for equilibrium sorption, transient sorption, and time lag. The effects of kinetic parameters of the model are illustrated and discussed.     

Chemoenzymatic reversible immobilization and labeling of proteins without prior purification

Site-specific chemical modification of proteins is important for many applications in biology and biotechnology. Recently, our laboratory and others have exploited the high specificity of the enzyme protein farnesyltransferase (PFTase) to site-specifically modify proteins through the use of alternative substrates that incorporate bioorthogonal functionality including azides and alkynes. In this study, we evaluate two aldehyde-containing molecules as substrates for PFTase and as reactants in both oxime and hydrazone formation. Using green fluorescent protein (GFP) as a model system, we demonstrate that the purified protein can be enzymatically modified with either analogue to yield aldehyde-functionalized proteins. Oxime or hydrazone formation was then employed to immobilize, fluorescently label, or PEGylate the resulting aldehyde-containing proteins. Immobilization via hydrazone formation was also shown to be reversible via transoximization with a fluorescent alkoxyamine. After characterizing this labeling strategy using pure protein, the specificity of the enzymatic process was used to selectively label GFP present in crude E. coli extract followed by capture of the aldehyde-modified protein using hydrazide-agarose. Subsequent incubation of the immobilized protein using a fluorescently labeled or PEGylated alkoxyamine resulted in the release of pure GFP containing the desired site-specific covalent modifications. This procedure was also employed to produce PEGylated glucose-dependent insulinotropic polypeptide (GIP), a protein with potential therapeutic activity for diabetes. Given the specificity of the PFTase-catalyzed reaction coupled with the ability to introduce a CAAX-box recognition sequence onto almost any protein, this method shows great potential as a general approach for selective immobilization and labeling of recombinant proteins present in crude cellular extract without prior purification. Beyond generating site-specifically modified proteins, this approach for polypeptide modification could be particularly useful for large-scale production of protein conjugates for therapeutic or industrial applications.     

Some possibilities for the immobilization of enzymes in poly(vinyl acetate-co-ethylene) tubes

The inside surface of poly(vinyl acetate-co-ethylene) tubes was coated with poly(vinyl alcohol) in the absence as well as in the presence of terephthalaldehyde as crosslinking agent. A hydrophilic inside tube surface was obtained, which was modified by reaction with 2, 4, 6-trichloro-s-triazine resp. with 2-(3-aminophenyl)-l,3-dioxolane. The latter method gave reactive tube supports after diazotization resp. after activation with glutardialdehyde. Furthermore, the amino derivative could be reacted with enzyme aggregates formed by reaction of glucose oxidase with 4-(2,3-epoxypropoxy)-benzaldehyde. Trypsin and glucose oxidase were immobilized onto the activated inside tube surfaces, and the properties of the immobilized enzymes were studied. The flow patterns of tube-immobilized trypsin were studied. The application of tube-immobilized glucose oxidase for automated glucose analysis was tested.     

Supramolecular immobilization of redox enzymes on cyclodextrin-coated magnetic nanoparticles for biosensing applications

Mono-6-formyl-β-cyclodextrin moieties were attached to (3-aminopropyl)triethoxysilane-coated superparamagnetic Fe(3)O(4) nanoparticles by reductive alkylation with NaBH(3)CN. The oligosaccharide-capped core-shell nanoparticles were employed as support for the supramolecular immobilization of two different adamantane-modified enzymes, tyrosinase and xanthine oxidase, through host-guest interactions. The enzyme-modified nanomaterial was further used to magnetically modify carbon paste electrodes for constructing amperometric biosensors toward cathecol and xanthine. The tyrosinase and xanthine oxidase based biosensors showed excellent electroanalytical behaviours, with linear ranges of 100nM-12μM cathecol and 5.0-120μM xanthine, sensitivities of 12mA/M and 130mA/M, and low detection limits of 22nM and 2.0μM, respectively. The supramolecular nature of the immobilization approach was confirmed by electroanalytical methods.