Enzyme immobilization on macroreticular polystyrene

Macroreticular polystyrene beads may be converted into suitable supports for covalent binding of enzymes. In many respects the supports are physically similar to controlled pore glass (CPG). Our results for immobilized glucoamylase were very similar to published results using CPG as a carrier. The characteristics of immobilized papain were less satisfactory. The product exhibited a Z-shaped activity-time profile suggestive of the involvement of multiple mechanisms.     

Immobilization of a proteinase from the extremely thermophilic organism Thermus Rt41A

An extracellular proteinase from Thermus strain Rt41A was immobilized to controlled pore glass (CPG) beads. The properties of the free and CPG-immobilized enzymes were compared using both a large (azocasein) and a small (peptidase) substrate. The specific activity of the immobilized proteinase was 5284 azoU/mg with azocasein and 144 sucU/mg for SucAAPFpNA. The percentage recovery of enzyme activity was unaffected by pore size when it was immobilized at a fixed level of activity/g of beads, whereas it increased with increasing pore size when added at a fixed level/m(2) of support. Saturation of the CPG beads was observed at 540 azoU/m(2) of 105-nm beads. Lower levels (50 azoU/m(2) of 50-nm beads) were used in characterization experiments. The pH optimum of the immobilized Rt41A proteinase was 8.0 for azocasein and 9.5 for SucAAPFpNA, compared with the free proteinase which was 10.5 for both substrates. The immobilized enzyme retained 65% of its maximum activity against azocasein at pH 12, whereas the free proteinase retained less than 10% under the same conditions. Stability at 80 degrees C increased on immobilization at all pH values between 5 and 11, the greatest increase in half-life being approximately 12-fold at pH 7.0. Temperature-activity profiles for both the free and immobilized enzymes were similar for both substrates. The stability of the immobilized proteinase, however, was higher than that of the free enzyme in the absence and presence of CaCl(2). Overall, the results show that low levels of calcium (10 muM) protect against thermal denaturation, but that high calcium or immobilization are required to protect against autolysis. (c) 1994 John Wiley & Sons, Inc.     

Immobilization of acetylcoenzyme A synthetase and the preparation of an enzyme reactor for the synthesis of [11C]acetylcoenzyme A

The enzyme acetylcoenzyme A synthetase (acetate-CoA ligase (AMP forming), EC 6.2.1.1) from Saccharomyces cerevisiae (baker's yeast) is used for the synthesis of 1 mumol [11C]acetylcoenzyme A. (CoA-[11C]Ac). A screening of the immobilization of the enzyme on differently derivatized controlled pore glass beads (50 nm pore size and 125-180 micron particle size) was performed. Several silanes, spacer arms and terminal reactive groups were tested. The immobilized enzyme was subjected to storage stability tests. From these experiments, the method of choice was selected: immobilization on CNBr-activated controlled pore glass. The immobilized parameters were optimized further to improve the activity of the enzyme-loaded glass beads. The latter were packed in a glass column. The kinetic properties of the column were investigated and optimized to obtain an almost complete conversion of 1 mumol acetate into acetylcoenzyme A (CoA-Ac) within a few minutes. This is realized with an enzyme reactor (13.0 x 0.5 cm) containing 6.12 U active acetylcoenzyme A synthetase immobilized onto 1 g controlled pore glass.     

Purification and immobilization of acetate kinase from Desulfovibrio vulgaris

Summary The enzyme acetate kinase (EC 2.7.2.1) was purified fromDesulfovibrio vulgaris by a combination of ammonium sulfate precipitation, hydroxyl-apatite and dye-affinity chromatography. An overall-purification factor of 15 was obtained resulting in a specific activity of 24 U/mg protein. The purified enzyme was immobilized on differently derivatized controlled pore glass beads.     

Immobilization of acetyl-CoA:arylamine N-acetyltransferase and the preparation of an enzyme reactor for the synthesis of N-[11C]acetylserotonin

The enzyme arylamine acetyltransferase (acetyl-CoA:arylamine N-acetyltransferase, EC 2.3.1.5) from pigeon liver is immobilized onto differently derivatized controlled pore glass beads. Different silanes, spacer arms and reactive end-groups were tested, and immobilized enzyme stability tests were performed. From these experiments, the method of choice was selected: immobilization on controlled pore glass beads (24 nm pore size, 75-125 microns particle size) derivatized with gamma-aminopropyl and glutaraldehyde as the reactive end group. The kinetic properties of an enzyme reactor were investigated and optimized. The goal was to obtain a rapid high-yield conversion of 0.5-1 mumol acetyl-CoA to N-acetylserotonin, so that the reactor is useful for the 11C-labelling of N-acetylserotonin. Using an enzyme reactor (9.8 x 0.5 cm i.d.) containing 4.6 U active arylamine acetyltransferase immobilized onto 930 mg carrier, a 70% conversion of acetyl-CoA was obtained within 4 min.     

Immobilization of cellulase and d-xylanase complexes from Aspergillus terreus F-413 on controlled porosity glasses

The major components of cellulase [see 1,4-(1,3;1,4)-β-d-glucan 4-glucanohydrolase, EC 3.2.1.4] and d-xylanase (see 1,4-β-d-xylan xylanohydrolase, EC 3.2.1.8) complexes have been immobilized on glass beads activated by 3-aminopropyltriethoxysilane or 3-glycidoxypropyltrimethoxysilane. The final preparations contained over 20 mg protein g^?1 glass beads. The activity retained was 71.6–98.1% for cellulase complexes and 81–100% for d-xylanase complexes. The immobilization of the enzymes spread their optimum pH range. Cellulose and d-xylan were quantitatively hydrolysed by the immobilized enzymes. The major reaction products were identified as a d-glucose and d-xylose respectively.     

Lignocellulose biotransformation with immobilized cellulase,d-glucose oxidase and fungal peroxidases

Three enzymes, cellulase [see 1,4-(1,3;1,4)-β-d-glucan 4-glucanohydrolase, EC 3.2.1.4], d-glucose oxidase (β-d-glucose: oxygen 1-oxidoreductase, EC 1.1.3.4) and peroxidase (donor:hydrogen peroxide oxidoreductase, EC 1.11.1.7) immobilized on glass beads, have been incubated with lignocellulose. Fungal peroxidases from Trametes versicolor and Inonotus radiatus when mixed with cellulase and d-glucose oxidase were able to liberate phenolic compounds and d-glucose from lignocellulose. Three lignin monomers were identified. When the immobilized enzymes were incubated individually with lignocellulose they did not degrade lignin.     

Polymethylglutamate as a new matrix for covalently immobilized enzymes: Preparation and properties of urease and uricase

Polymethylglutamate (PMG), a synthetic polypeptide, was used as a new carrier to immobilize urease (EC 3.5.1.5) and uricase (EC 1.7.3.3) by the azide method. The enzymes could be immobilized onto PMG in various forms, such as film, fiber, coating on various beads, and a silicon tube. The retained activities of the immobilized enzymes were excellent (more than 95%), therefore it was possible to immobilized almost all activities of the enzymes added in the coupling mixtures. Heat stabilities of the resulting immobilized enzymes were markedly improved, while the optimal pH and K_m values remained almost unchanged. The urease immobilized on the PMG-coated glass beads packed in a column, was found to retain its activity more than 80% of the initial value, even after the occasional use for a year. In view of the improved retained activities and stabilities of the immobilized enzymes, PMG may therefore be a very versatile matrix for the immobilized enzymes.     

Immobilization of uricase on protamine bound to glass beads and its application to determination of uric acid

Uricase was found to be stabilized by protamine from salmon testis. Protamine was then bound to controlled-pore glass beads aminohexyl CPG 500 using glutaraldehyde. Microbial uricase was readily immobilized on the protamine bound to glass beads. The immobilized uricase proved to be stable even at 70 degrees C, whereas free uricase was inactivated at 45 degrees C and showed activity over a broader pH range than free uricase. Automated analysis of uric acid was facilitated using the immobilized uricase. The standard curve for uric acid was linear in the range of 2 to 10 micrograms/sample and passed through the origin. This automated procedure was also applicable to the determination of uric acid in human serum. Protamine bound to glass beads is expected to be useful for the simple immobilization and stabilization of enzymes.     

A controlled pore glass bead assay for the measurement of cytoplasmic and nuclear glucocorticoid receptors

An assay for the quantitation of cytoplasmic and nuclear glucocorticoid receptors in lymphoid tissue has been developed using controlled pore glass (CPG) beads. Soluble receptor--3H-steroid complex (cytosol or nuclear extract) is adsorbed quantitatively within the crevasses of porous glass beads. Excess labeled steroid as well as most non-specifically bound steroid is easily washed away, leaving the hormone-receptor complex retained by the beads. Bound 3H-steroid is eluted with ethanol and measured for radioactivity. This procedure which is simple, rapid, and highly reproducible is carried out using frozen samples (stable for many months) containing as few as 1 X 10(7) cells. A comparison of the CPG assay to dextran coated charcoal and a whole cell assay demonstrates that CPG and dextran coated charcoal give equivalent measurements of cytosolic receptor concentration, while the CPG and whole cell assays provide equivalent values for total receptor content.     

Spherical vs. granular immobilization support selection and performance on an optical flow cell immunosensor based on the fluorescence of Cyanine-5

A spherical porous glass support Trisoperl (TRISO) with four pore diameters (? 47.8; 55.9; 102.6, and 108.8 nm) was characterized and selected for application in an optical flow cell immunosensor, in comparison with controlled pore glass (CPG). The TRISO support was functionalized with aldehyde and isothiocyanate (-NCS) groups to attach bovine serum albumin and alkaline phosphatase (AP). The TRISO isothiocyanate pore diameter 47.8 nm (TRISO(-NCS) 47.8 nm) showed the better potential to be used in the immunosensor. It immobilized more protein (19.3 mg AP per g support) while presenting an optical performance comparable to the CPG. CPG(-NCS) and TRISO(-NCS) 47.8 nm were tested in the immunosensor model where the saturation of the Goat IgG immobilized in the supports with Monoclonal Anti-Goat IgG conjugated with Cyanine-5 was reached, followed by regeneration with the elution buffer modified PBS pH 2.0. The TRISO(-NCS) 47.8 nm presented lower fluorescence intensity at saturation (around 39 AU) than CPG(-NCS) (150 to 104 AU), but revealed a major advantage related to the uniform arrangement of the spherical particles in the flow cell, generating no significant fluorescence differences between gravity and flow package.     

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Molecular sieve chromatography of proteoglycans: a comparative analysis.

The separation of three major populations of proteoglycans (PG) by molecular sieve chromatography with either controlled-pore glass beads (CPG) or 1% agarose (A-150m) is compared. The resolving power and recovery on CPG or A-150m columns are comparable. However, CPG columns can be operated at a flow rate 50–100 times higher than those packed with 1% agarose. Chromatography on A-150m separates the purifled PG into three major peaks in a single run. Two sequential runs using material of two different pore sizes (CPG-10-1250, CPG-10-2500) are needed to obtain the same separation with CPG. CPG-10-1250 separates the ubiquitous peak (II) from the two peaks known to have an aggregate-subunit relationship. CPG-10-2500 resolves these two peaks allowing analysis of their interactions. Larger pore sized beads (CPG-10-2795) reveal size heterogeneity within the PG aggregate population.     

Lipoamide dehyrogenase immobilized on porous glass.

Lipoamide dehydrogenase (NADH:lipoamide oxidoreductase, EC 1.6.4.3) isolate from pig heart and Escherichia coli was covalently coupled by both diazonium and amide bonds to controlled pore glass beads (96% silica). When the enzyme was immobilized in the presence of NAD+, the enzyme no longer exhibited its normal requirement for NAD+ for full activity. If the immobilized enzyme was then treated with NADase, the requirement for NAD+ was restored. Enzyme immobilized in the absence of NAD+ exhibited normal NAD+ dependence both prior to an after NADase treatment. These results are discussed in terms of co-immobilization of NAD+ at or near the allosteric site of the enzyme.     

Sequential hydrolysis of proline-containing peptides with immobilized aminopeptidases

Proline-containing polypeptides are shown to be sequentially degraded by two aminopeptidases. Clostridial aminopeptidase (EC 3.4.11-) cleaves off any N-terminal amino acid residue including proline from polypeptide chains, but does not cleave the N-terminal secondary peptide bonds involving a prolyl nitrogen. Aminopeptidase P (EC 3.4.11.9) cleaves exclusively such secondary bonds. The two enzymes were immobilized by coupling them covalently to porous amino glass beads. Highly stable preparations were obtained with unchanged pH optimum and thermal stability. The applicability of clostridial aminopeptidase to sequence determination was demonstrated by the time-dependent hydrolysis of enkephalin and Substance P octapeptide. Sequential hydrolysis with the two immobilized enzymes was demonstrated with the proline-containing (Pro-Gly-Pro)10, [Asn1, Val5]angiotensin II, bradykinin, Substance P and tuftsin. Absence of endopeptidase activities was demonstrated by resistance of cytochrome c to hydrolysis and by the ordered release of amino acids during the sequential degradation by immobilized clostridial aminopeptidase and aminopeptidase P.     

Characterization of specific interactions of coenzymes, regulatory nucleotides and cibacron blue with nucleotide binding domains of enzymes by analytical affinity chromatography

The dissociation constant for the complex of rhodanese and Cibacron Blue, determined by analytical affinity chromatography using rhodanese immobilized on controlled-pore glass (CPG) beads (200 nm pore diameter) and aminohexyl-Cibacron Blue, was 44 microM which agreed well with the kinetic inhibition constant, suggesting that the dye binds at or near the active site of this enzyme. Formation of a binary complex of the dye and lactate dehydrogenase (LDH) was also characterized by direct chromatography of LDH on CPG/immobilized Cibacron Blue (KD = 0.29 microM). The binary complex formed between LDH and NADH was characterized by analytical affinity chromatography using both CPG/immobilized LDH and immobilized Cibacron Blue. Since the dye competes with NADH in binding to the active site of LDH, competitive elution chromatography using the immobilized dye allows determination of the dissociation constant of the soluble LDH.NADH complex. Agreement between the dissociation constants determined by direct chromatography of NADH on immobilized LDH (KD = 1.4 microM) and that determined for the soluble complex (KD = 2.4 microM) indicates that immobilization of LDH did not affect the interaction. Formation of various binary, ternary and quaternary complexes of bovine liver glutamate dehydrogenase (GDH) with glutamate, NADPH, NADH, and ADP was also investigated using immobilized GDH. This approach allows characterization of the enzyme/ligand interactions without the complicating effect of enzyme self-association. The affinity for NADPH is considerably greater in the ternary complex (including glutamate) as compared to the binary complex (0.38 microM vs 22 microM); however, occupancy of the regulatory site by ADP greatly reduces the affinity in both complexes (6.4 microM and 43 microM, respectively).(ABSTRACT TRUNCATED AT 250 WORDS)     

Chromatography of Biological Materials on Polyethylene Glycol Treated Controlled-Pore Glass

Controlled-pore glass (CPG) columns will withstand high pressures without damage or loss of flow rates and their pore size and bed dimensions are independent of the eluent. Utilization of untreated CPG has been previously limited for permeation chromatography of various biological materials due to surface adsorption. Treatment of CPG with 1% polyethylene glycol (20, 000) solution prior to column preparation minimizes the adsorption phenomenon. High speed chromatography of proteins and enzymes was performed on treated CPG of various pore diameters. With some exceptions the proteins and enzymes eluted with greater than 92% recovery of the starting material and/or biological activity. Surface-treated CPG represents a useful tool for the characterization of many biological materials.     

Investigation of the binding mechanism of glucoamylase to alkylamine derivatives of titanium(IV)-activated porous inorganic supports

Glucoamylase (exo-1,4-α-d-glucosidase, EC 3.2.1.3) has been coupled to several porous silica matrices by a new covalent process using alkylamine derivatives of titanium(IV)-activated supports. In order to investigate the interaction of the titanium element with the silanol groups of the inorganic matrices, activation was performed at different times, using titanium(IV) chloride, either pure or as a 15% w/v solution, in 15% w/v hydrochloric acid at 25, 45 and 80°C, followed by washing with sodium acetate buffer (0.02m, pH 4.5) or chloroform. Using pure TiCl₄, the highest activities of all preparations were obtained at 80°C and with acetate buffer washing, resulting from a higher content of titanium coating of the carrier. When activation was performed in aqueous TiCl₄ solution, followed by a drying step, the highest activity was obtained with preparations washed with chloroform, with or without amination. When reacting pure TiCl₄ with controlled pore glass (CPG) and with porous silica (Spherosil), colour formation was observed after reaction of glutaraldehyde with the aminated support. This did not happen when Celite was used as the support. As a criterion for comparison of the different immobilized enzyme preparations, the concept of an ‘instability factor’, which measures the percentage of immobilized enzyme activity due to release of enzyme into solution, is introduced. Instability factors of immobilized enzyme preparations on Celite were always higher than those obtained with the other matrices, confirming that there was no covalent coupling of the enzyme to Celite. However, when the activation was performed with aqueous TiCl₄ solution with drying, Schiff's base formation was observed in all preparations and very stable immobilized enzyme preparations were obtained. The results of the activation of controlled pore glass and porous silica with pure titanium(IV) chloride suggest the existence of a true reaction between the titanium element and the silanol groups of these carriers by formation of a bridge, Si-O-Ti, while with the titanium(IV) chloride solution in hydrochloric acid, a coating of hydrous titanium(IV) oxide is obtained.     

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.     

Comparative study of controlled pore glass, silica gel and poraver for the immobilization of urease to determine urea in a flow injection conductimetric biosensor system

This study compared the responses of three enzyme reactors containing urease immobilized on three types of solid support, controlled pore glass (CPG), silica gel and Poraver. The evaluation of each enzyme reactor column was done in a flow injection conductimetric system. When urea in the sample solution passed though the enzyme reactor, urease catalysed the hydrolysis of urea into charged products. A lab-built conductivity meter was used to measure the increase in conductivity of the solution. The responses of the enzyme reactor column with urease immobilized on CPG and silica gel were similar and were much higher than that of Poraver. Both CPG and silica gel reactor columns gave the same limit of detection, 0.5 mM, and the response was still linear up to 150mM. The analysis time was 4-5 min per sample. The enzyme reactor column with urease immobilized on CPG gave a slightly better sensitivity, 4% higher than the reactor with silica gel. The life time of the immobilized urease on CPG and silica gel were more than 310h operation time (used intermittently over 7 months). Good agreement was obtained when urea concentrations of human serum samples determined by the flow injection conductimetric biosensor system was compared to the conventional methods (Fearon and Berthelot reactions). These were statistically shown using the regression line and Wilcoxon signed rank tests. The results showed that the reactor with urease immobilized on silica gel had the same efficiency as the reactor with urease immobilized on CPG.