Polyethylene glycol as a spacer for solid-phase enzyme immobilization

With the aim to improve the performance of enzyme bound to hydrophilic solid phases, their immobilization with polyethylene glycol (PEG) tether have been studied. Sweet potato β-amylase, which hydrolyses the high molecular weight substrate starch and β-galactosidase, which acts on low molecular weight substrates, were used as model enzymes and beaded thiol–agarose as solid phase. Several two step methods for the introduction of the tether using a bis-oxirane homobifunctional PEG as well as a heterobifunctional derivative with a hydroxysuccinimide ester and a maleimide group have been evaluated. Amino groups, native and de novo thiol groups in the enzymes were utilized for immobilization.

The best approach was found to be to first introduce the PEG derivative via one of its reactive groups to the enzyme. Subsequently the formed conjugate was bound to the solid phase by the remaining reactive group.

Attempts to first introduce the PEG tether into the solid phase were not successful.

A high degree of substitution with PEG chains on the enzyme leads to high immobilization yields for both β-amylase and β-galactosidase, but relatively lower gel-bound activity for the former enzyme which is acting on a high molecular weight substrate and thus more sensitive for steric shielding effects. With optimal degree of PEG substitution (which occurred at five times molar excess of the heterobifunctional reagent) the gel-bound activity of β-amylase was increased from 12% (for the derivative without tether) to 31%.     

Chemically modified nylons as supports for enzyme immobilization. Polyisonitrile-nylon

Four-component condensations between amine, carboxyl, isocyanide and aldehyde lead to the formation of N-substituted amides (Ugi, 1962). The present paper describes the use of such condensations for the introduction of chemically reactive groups on to the polyamide backbone of nylon. Polyisonitrile-nylon was synthesized by partial hydrolysis of nylon-6 powder, followed by resealing of the newly formed -CO(2)... NH(2) (-) pairs via a four-component condensation, by using acetaldehyde and 1,6-di-isocyanohexane. Polyisonitrile-nylon could also be converted into a diazotizable arylamino derivative, polyaminoaryl-nylon, by a four-component condensation by using a bifunctional amine, pp'-diaminodiphenylmethane, in the presence of an aldehyde and a carboxylate compound. The versatility of four-component condensations involving the isocyanide functional group of polyisonitrile-nylon allowed coupling of proteins, in an aqueous medium at neutral pH, through either their amino or carboxyl groups. Trypsin and papain were bound to polyisonitrile-nylon through their amino groups by a four-component condensation by using acetaldehyde and acetate; conversely, succinyl-(3-carboxypropionyl-)trypsin, pepsin and papain were coupled through their carboxyl groups in the presence of acetaldehyde and an amine (Tris). Diazotized polyaminoaryl-nylon could be utilized for the immobilization of papain, via the tyrosine residues of the enzyme.     

Bacterial cellulose-chitosan composite hydrogel beads for enzyme immobilization

In this work, we report the preparation of bacterial cellulose (BC)-chitosan composite hydrogel beads by co-dissolution of BC and chitosan in 1-ethyl-3-methylimidazolium acetate and subsequent reconstitution with distilled water. The BC-chitosan hydrogel beads were used as enzyme supports for immobilizing Candida rugosa lipase by physical adsorption and covalent cross-linking. BC-chitosan hydrogel beads immobilized lipase more efficiently than microcrystalline cellulose (MCC)-chitosan hydrogel beads. The amount of protein adsorbed onto BCchitosan beads was 3.9 times higher than that adsorbed onto MCC-chitosan beads, and the catalytic activity of lipase was 1.9 times higher on the BC-chitosan beads. The lipase showed the highest thermal and operational stability when covalently cross-linked on BC-chitosan hydrogel beads. The half-life time of the lipase cross-linked on BC-chitosan bead at 60°C was 22.7 times higher than that of free lipase. Owing to their inherent biocompatibility and biodegradability, the BC-chitosan composite hydrogel beads described here could be used to immobilize proteins for various biomedical, environmental, and biocatalytic applications.     

Ionic liquid-based preparation of cellulose-dendrimer films as solid supports for enzyme immobilization

Surface-active cellulose films for covalent attachment of bioactive moieties were achieved by codissolution of cellulose with polyamidoamine (PAMAM) dendrimers in an ionic liquid followed by regeneration of the composite as a film. Different generations of PAMAM were used for the formation of cellulose-dendrimer composites, as well as films with the dendrimer covalently bonded to the cellulose by means of the linker 1,3-phenylene diisocyanate. Surface characterization, thermal stability, and utility for immobilization of laccase were determined. The presence of the dendrimer amino groups was confirmed by detailed characterization of the films' surfaces. These modified films exhibit acceptable thermal stability, comparable to that of other regenerated cellulose films, but the number of active functional groups on the surface is much smaller than the theoretical amount expected. Films made with 1,3-phenylene diisocyanate as linker for covalently bound cellulose and dendrimers exhibit a better performance for immobilization of laccase than those prepared by simple mixing of the cellulose and dendrimer. In general, a linear correspondence between the dendrimer generation within the films and the specific activity of immobilized laccase in such films was not observed.     

Recent trends using natural polymeric nanofibers as supports for enzyme immobilization and catalysis

All the disciplines of science, especially biotechnology, have given continuous attention to the area of enzyme immobilization. However, the structural support made by material science intervention determines the performance of immobilized enzymes. Studies have proven that nanostructured supports can maintain better catalytic performance and improve immobilization efficiency. The recent trends in the application of nanofibers using natural polymers for enzyme immobilization have been addressed in this review article. A comprehensive survey about the immobilization strategies and their characteristics are highlighted. The natural polymers, e.g., chitin, chitosan, silk fibroin, gelatin, cellulose, and their blends with other synthetic polymers capable of immobilizing enzymes in their 1D nanofibrous form, are discussed. The multiple applications of enzymes immobilized on nanofibers in biocatalysis, biosensors, biofuels, antifouling, regenerative medicine, biomolecule degradation, etc.; some of these are discussed in this review article.     

Modeling enzyme immobilization in porous solid supports

Enzymes are often immobilized on the internal surfaces of porous solid by immersing enzyme-free particles in a well mixed solution of enzyme. The ensuing impregnation process involves coupled transient mass transfer and surface attachment of enzyme. A mathematical model is employed to explore the influences of process parameters on the amount of enzyme loaded and the distribution of immobilized enzyme within the support particles. Nonuniform loading of the support occurs under some conditions. This is significant since the distribution of enzyme within the support particle influences the overall activity and stability of the immobilized enzyme catalyst. The model developed here may also be used to describe removal of reversibly immobilized enzyme during washing or utilization of the immobilized enzyme catalyst.     

Chemical procedures for enzyme immobilization on porous cellulose beads.

In a previous article, the method of preparation and the physical properties of porous (75 to 80% porosity) cellulose beads were described (Biotechnol. Bioeng., 18, 1057 (1976). The present article reports that the chemical procedures employed for immobilizing enzymes on ordinary cellulose can be applied to the porous cellulose beads. The results showed more enzyme loading on the beads than ordinary cellulose. The choice of the procedures might also affect the mechanical strength of the cellulose beads.     

Keratin and polyamide-coated inorganic matrices as supports for glucoamylase immobilization

Previously solubilized feather keratin and polyamide were used for coating sand, glass beads and silica gel. These new seven supports were employed for comparative studies on pure glucoamylase / EC 3.2.1.3 / immobilization. The immobilization yield of glucoamylase on keratin and polyamide coated supports was comparable with conventional matrices used earlier. The highest activity per 1 g of support was shown by the enzyme bound to polyamide-coated CPG, and the bests operational stability by the enzyme immobilized on polyamide-coated CPG with keratin subsequently deposited on it.     

Chitin and its derivative as supports for immobilization of enzymes

The ideal enzyme support should show high affinity to proteins, availability of reactive groups for direct reactions with proteins or for chemical modifications, easiness of preparing in different physical forms, nontoxicity and physiological compatability if required (food industry, biomedicine), as well as low cost. Chitin and its derivatives fullfil most of these requirements. The paper reviews enzymes immobilized on chitin and its derivatives along with techniques applied for their immobilization.     

Strategies of enzyme immobilization on nanomatrix supports and their intracellular delivery

Abstract

Enzymes are one of the foundations and regulators for all major biological activities in living bodies. Hence, enormous efforts have been made for enhancing the efficiency of enzymes under different conditions. The use of nanomaterials as novel carriers for enzyme delivery and regulating the activities of enzymes has stimulated significant interests in the field of nano-biotechnology for biomedical applications. Since, all types of nanoparticles (NPs) offer large surface to volume ratios, the use of NPs as enzyme carriers affect the structure, performance, loading efficiency, and the reaction kinetics of enzymes. Hence, the immobilization of enzymes on nanomatrices can be used as a useful approach for direct delivery of therapeutic enzymes to the targeted sites. In other words, NPs can be used as advanced enzyme delivery nanocarriers. In this paper, we present an overview of different binding of enzymes to the nanomaterials as well as different types of nanomatrix supports for immobilization of enzymes. Afterwards, the enzyme immobilization on nanomaterials as a potential system for enzyme delivery has been discussed. Finally, the challenges associated with the enzyme delivery using nano matrices and their future perspective have been discussed.

Communicated by Ramasamy H. Sarma     

Amyloid fibrils as a nanoscaffold for enzyme immobilization

Amyloid fibrils are a misfolded state, formed by many proteins when subjected to denaturing conditions. Their constituent amino acids make them ideally suited as a readily functionalized nanoscaffold for enzyme immobilization and their strength, stability, and nanometer size are attractive features for exploitation in the creation of new bionanomaterials. We report successful functionalization of amyloid fibrils by conjugation to glucose oxidase (GOD) using glutaraldehyde. GOD retained activity upon attachment and successful cross‐linking was determined using electrophoresis, centrifugation, sucrose gradient centrifugation, and TEM. The resulting functionalized enzyme scaffold was then incorporated into a model poly(vinyl alcohol) (PVOH) film, to create a new bionanomaterial. The antibacterial effect of the functionalized film was then tested on E. coli, the growth of which was inhibited, demonstrating the incorporation of GOD antibacterial activity into the PVOH film. The incorporation of the GOD‐functionalized amyloid fibrils into PVOH provides an excellent ‘proof of concept’ model for the creation of a new bionanomaterial using a functionalized amyloid fibril scaffold. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2010     

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.     

Amino acid modified chitosan beads: Improved polymer supports for immobilization of lipase from Candida rugosa

Amino acid modified chitosan beads (CBs) for immobilization of lipases from Candida rugosa were prepared by activation of a chitosan backbone with epichlorohydrin followed by amino acid coupling. The beads were analyzed by elemental analysis and solid state NMR with coupling yields of the amino acids ranging from 15 to 60%. The immobilized lipase on unmodified chitosan beads showed the highest immobilization yield (92.7%), but its activity was relatively low (10.4%). However, in spite of low immobilization yields (15–50%), the immobilized lipases on the amino acid modified chitosan beads showed activities higher than that of the unmodified chitosan beads, especially on Ala or Leu modified chitosan beads (Ala-CB or Leu-CB) with 49% activity for Ala-CB and 51% for Leu-CB. The immobilized lipases on Ala-CB improved thermal stability at 55 °C, compared to free and immobilized lipases on unmodified chitosan beads and the immobilized lipase on Ala-CB retained 93% of the initial activity when stored at 4 °C for 4 weeks. In addition, the activity of the immobilized lipase on Ala-CB retained 77% of its high initial activity after 10 times of reuse. The kinetic data (k_cat/K_m) supports that the immobilized lipase on Ala-CB can give better substrate specificity than the unmodified chitosan beads.     

Curdlan as a support matrix for immobilization of enzyme

Curdlan, a high molecular weight extracellular β(1→3) glucan produced by pure culture fermentation by Agrobacterium radiobacter NCIM 2443 contains large number of free hydroxyl groups. The reaction of hydroxyl containing supports with epichlorohydrin results in activated epoxy groups that can covalently link with available amino, hydroxyl, or sulfhydryl groups of enzymes, thereby immobilizing it. The present work reports on preparation of epoxy-activated matrix for immobilization of a model enzyme, porcine pancreatic lipase. The binding capacity of the matrix prepared by extraction of epoxy-activated curdlan by isopropyl alcohol was found to be 58.7% with about 0.6% loss of the enzyme activity during immobilization. Further, the specific activity of the enzyme increased marginally from 9.37 to 10.2. The corresponding value was 10.15 for a commercial sample of curdlan, epoxy-activated as for laboratory-isolated curdlan. Sepharose, the most widely used support matrix for the immobilization of enzymes was used for comparison in this study.     

Natural silk fibroin as a support for enzyme immobilization

Silk fibroin derived from Bombyx mori cocoon is being developed and utilized for purposes besides traditional textile material. Fibroin can be easily made up into various forms, several of which can serve as enzyme-immobilized supports. There are numerous reports on immobilized enzymes using these forms of silk fibroin as supports in which the enzyme-immobilized fibroin membranes were characterized in detail by means of spectrophotometry, infrared spectra, NMR, ESR. Enzyme-immobilized fibroin membranes have been successfully used in several biosensors for the determinations of glucose, hydrogen peroxide and uric acid in which glucose and urate biosensors in a flow injection system were able rapidly to analyze various biosamples including human whole blood or serum.     

Solute adsorption and enzyme immobilization on chitosan beads prepared from shrimp shell wastes

The equilibrium and kinetics of adsorption of reactive dye RR222 and Cu²⁺, and the activity of immobilization of acid phosphatase, on highly swollen chitosan beads were examined at 30°C. The chitosan was prepared from shrimp shell wastes and was cross-linked with different dosages of glutaraldehyde or glyoxal (100–80,000 mg/l). It was shown that the amounts of solute adsorption and the immobilization capacity of acid phosphatase on cross-linked chitosan beads were substantially affected by their degree of cross-linking. The cross-linking rate of chitosan with glutaraldehyde could be described by a pseudo-second-order equation and the cross-linking equilibrium by the Freundlich equation. This provided an experimental method to control the degree of cross-linking of chitosan beads. Finally, the activity and lifetime of the immobilized enzyme were measured to evaluate the application potential.