Distribution model for the intact urokinase and urokinases modified by soluble macromolecules in rat and mouse bodies

The activity of intact urokinase (UK) and urokinases modified by soluble macromolecules (dextran and dextran sulfate sodium) in a mouse body was traced after injection of the 125I-labelled enzymes. The residual fraction of the enzyme in blood can be correlated with the time (t) as follows; Xb = Ae-at + Be-bt + Ce-ct Since a greater than b greater than c, the residual fraction of the enzyme in blood chiefly depends on the magnitude of parameter C. The constant C for modified urokinase was larger than that for urokinase, showing the relative residual in blood was increased by modification of the enzyme. The apparent utilization in 50 min was 13.8% for intact UK, 28.1% for the dextran-UK and 25.2% for the sulfate dextran-UK. Therefore, the apparent utilization of UK in blood was approximately doubled by the modification. Since the half-lives of UK and modified UK in kidney and liver were not long, there were no unacceptable accumulation of the enzymes.     

Biochemical and biopharmaceutical properties of macromolecular conjugates of uricase with dextran and polyethylene glycol.

Uricase (UC) was conjugated with dextran and polyethylene glycol and their biochemical and biopharmaceutical properties were studied. UC-dextran conjugates (UC-D) synthesized by four methods, periodate oxidation, cyanogen bromide, carbodiimide and cyanuric chloride largely retained the UC enzymatic activity depending on the extent to which they modified amino groups. The periodate oxidation method seemed best because it gave a conjugate with high yield and satisfactory activity retention. The conjugate of UC with activated polyethylene glycol (UC-PEG2) was also obtained with high yield but the remaining activity was somewhat lower than those of dextran conjugates at the same modification extent. UC-D and UC-PEG2 showed sustained enzymatic activity in plasma after intravenous injection to rats. The advantage of chemical modification of proteins, especially with dextran, by the periodate oxidation method for preparation of a protein-delivery system was thus suggested.     

Large-scale purification of Leuconostoc mesenteriodes NRRL B512F dextransucrase for use in the biosynthesis of dextran by batch and continuous chromatography

The extracellular enzyme dextransucrase was produced from Leuconostoc mesenteriodes NRRL B512F and purified by ultracentrifugation and cross-flow ultrafiltration for use in the biosynthesis of the macromolecule dextran by ion exchange chromatographic reaction—separation techniques. The two-stage purification process yielded over 90% pure dextransucrase with overall enzyme recovery of over 60%. A second stage of centrifugation was required to achieve complete cell removal. The purified enzyme contained 1–2 g l⁻¹ of solute ions, which affected the operation of the chromatographic system. Gel filtration removed over 93% of the remaining ions but resulted in high activity losses. Two-phase separation with polyethylene glycol (PEG) and purification by ion exchange chromatography were less successful in desalting the enzyme. PEG precipitation was successful in concentrating the enzyme, but the ions remained predominantly with the enzyme portion of the two phases. The purified enzyme was found to be unstable during storage.Use of the enzyme in chromatographic reactor—separators for the production of dextran resulted in over 33% more high molecular weight dextran (the desired product) and a useful pure fructose byproduct being obtained than for a conventional reactor. Sodium and potassium ions in the enzyme hampered continuous operation by displacing calcium ions from the resin and thus reducing the separation efficiency of the system. Partial regeneration of the resin with calcium nitrate rather than complete enzyme desalting, which was very expensive and resulted in high activity losses, helped overcome this effect.     

Functional Stabilization of Cellulase from Aspergillus niger by Conjugation with Dextran-aldehyde

The covalent conjugates of cellulase from Aspergillus niger were prepared with various molar ratios by using dextran. The conjugate (n_E/n_D: 1/5) showed higher activity than purified enzyme at all temperatures after 1 h of incubation and its activity could also be measured at higher temperature. Also, this conjugate lost only 60% activity in 2 h at 70°C in comparison to the purified enzyme, which lost all its activity. In addition, conjugation protected cellulase against denaturation in the presence of sodium dodecylsulfate (residual activity of about 80%) and inactivation by air bubbles (residual activity of about 50% for 4 h).     

Nanoparticles of hydrophobically modified dextrans as potential drug carrier systems

Nanoparticles combining a hydrophobically modified dextran core and a polysaccharide surface coverage were elaborated. Their suitability for applications like drug delivery was evaluated. The selected polysaccharide, dextran, was chemically modified by the covalent attachment of hydrocarbon groups (aliphatic or aromatic) via the formation of ether links. According to the extent of modification, either water-soluble or water-insoluble dextran derivatives were obtained. The latter exhibited solubility in organic solvents like tetrahydrofuran or dichloromethane saturated with water. Water-soluble dextran derivatives were used as polymeric surfactants for the control of nanoparticles surface characteristics. Nanoparticles were prepared either by o/w emulsion or solvent-diffusion methods. The size and surface properties of dextran nanoparticles were correlated to processing conditions. The stability of colloidal suspensions was examined as a function of ionic strength and related to the particle surface characteristics. The redispersability of freeze-dried suspensions without the addition of cryoprotectant was demonstrated. Finally, the degradability of modified dextrans was compared to that of starting dextran, after enzymatic hydrolysis in the presence of dextranase.     

氨基酸分子改性的SiO2杂化材料用于胰蛋白酶固定化

为改善二氧化硅载体材料本身的生物相容性和疏水性,维持包埋生物分子的活性,本文对水解前驱体3-氨基丙基三甲氧基硅烷进行氨基酸分子改性。具体过程包括N-Fmoc-L-缬氨酸和氯化亚砜反应生成N-Fmoc-L-缬氨酰氯,再和3-氨基丙基三甲氧基硅烷反应生成N-（3-三甲氧基硅基）丙基-N′-Fmoc-L-缬氨酰胺后。然后去除Fmoc,得到N-（3-三甲氧基硅基）丙基-L-缬氨酰胺作为氨基酸修饰的硅源前驱体。通过IR、MS、1H-NMR等分析测试手段对合成得到的各个化合物的结构进行了表征。利用正硅酸甲酯（TMOS）和N-（3-三甲氧基硅基）丙基-L-缬氨酰胺为复合硅源,经过溶胶-凝胶过程来包埋了胰蛋白酶,研究得到最适的固定化条件为,N-（3-三甲氧基硅基）丙基-L-缬氨酰胺的含量为15mol%。在该条件下,固定化胰蛋白酶活力的绝对值是199U,游离酶的酶活力的绝对值是103U, 四甲氧基硅烷直接包埋的固定化酶活力的活性是38 U。在该条件下,杂化硅源得到的固定化酶的活性是以四甲氧基硅烷水解前驱体的固定化酶活性的5倍,杂化硅源固定化胰蛋白酶的最相比游离酶,酶的最高活力提高的几乎2倍。这些结果表明氨基酸分子对水解前驱体修饰以后,水解产生的固定化载体具有良好的生物相容性。通过改性载体制备的固定化酶,对甲醇变性剂的稳定性,对酸碱的抵抗性及热稳定性也有明显地提高。     

Improved Pharmacokinetics Properties for Catalase by Site‐Specific Glycosidation with Aminated Dextran

Summary: Catalase was chemically modified with an end‐group aminated dextran derivative via a carbodiimide catalyzed reaction. The enzymatic activity of catalase was increased after glycosidation with 4 mol of polymer. This modification improved the pharmacokinetic behavior of catalase, increasing by 7.8‐ and 20‐fold the plasma half‐life times for the α and β phases, and reducing by 176‐fold the total clearance after intravenous administration in rats.

Schematic of the catalase dextran conjugate synthesized here.     

Improved anti-inflammatory and pharmacokinetic properties for superoxide dismutase by chemical glycosidation with carboxymethylchitin

O-carboxymethylchitin (molecular weight = 1.07 x 10(5), degree of carboxymethylation = 80%, degree of N-acetylation = 91%) was chemically attached to superoxide dismutase by the formation of amide linkages through a carbodiimide catalyzed reaction. The glycosidated enzyme contained about 1.8 mole of polysaccharide per mole of protein and retained 57% of the initial catalytic activity. The anti-inflammatory activity of the enzyme was 2.4 times increased after conjugation with the polysaccharide. The modified superoxide dismutase preparation was remarkably more resistant to inactivation with H(2)O(2) and its plasma half-life time was prolonged from 4.8 min to 69 h.     

Immobilisation of <Emphasis Type="Italic">Aspergillus oryzae</Emphasis> α-amylase and <Emphasis Type="Italic">Aspergillus niger</Emphasis> glucoamylase enzymes as cross-linked enzyme aggregates

Cross-linked enzyme aggregates (CLEA) of Aspergillus oryzea α-amylase (AoAA) and Aspergillus niger glucoamylase (AnGA) were prepared using glutaraldehyde and dextran polyaldehyde as cross-linkers. The maximum activity recoveries for glutaraldehyde cross-linking were 21.8 % and 41.2 %, respectively. The addition of a proteic feeder (bovine serum albumin) exhibited a negative effect on the activity recoveries for both enzymes. Dextran polyaldehyde was used as a cross-linking agent instead of glutaraldehyde to reduce the activity losses. As a result, an activity recovery of 60.0 % was obtained for Aspergillus oryzea α-amylase. On the other hand, no activity recovery was observed for Aspergillus niger glucoamylase due to the latter enzyme’s affinity for dextran.     

Affinity partitioning of enzymes using dextran-bound procion yellow HE-3G. Influence of dye-ligand density

The dye Procion Yellow HE-3G was bound to dextran of molecular weight 70,000 and the partitioning of this dye-polymer within an aqueous two-phase system containing dextran and poly(ethylene glycol) was studied as function of ligand density, polymer concentration, type of salt, concentration of salt and concentration of dye-dextran. Even moderate dye:dextran molar ratios (5-8) make the partitioning strongly salt-dependent. The dye-dextran can be directed to either the upper or the lower phase with partition coefficients from 0.02 to 28 by using salts. The dye-dextran in the two-phase system affects the partitioning of dye-binding enzymes (lactate dehydrogenase, glucose-6-phosphate dehydrogenase, 3-phosphoglycerate kinase) towards the dye-containing phase. Measurements of competition with nucleotide binding show an increased affinity of the dye for the enzyme with increasing ligand:dextran ratio. Theoretical considerations indicate that 1-2 dextran molecules are attached per enzyme molecule when affinity partitioning is fully developed.     

聚半乳糖醛酸酶（PG2）中色氨酸残基的化学修饰

用化学修饰法以Ｎ－溴代琥珀酰亚胺作修饰剂，对聚半乳糖醛酸酶（ＰＧ２）中色氨酸（Ｔｒｐ）残基与酶活性的关系进行研究，发现１个ＰＧ２分子中有６个Ｔｒｐ残基，其中４个位于酶分子内部，２个位于酶分子表面，该发现通过表面荧光猝灭实验得到进一步证明，酶分子表面的２个Ｔｒｐ残基中，有１个为活性必需的氨基酸，它的修饰导致大部分酶活力丧失，底物保护实验进一步证明该活性必需的Ｔｒｐ可能位于酶的活性部位，酶被修饰后其圆     

Immobilization and catalytic properties of candida lipolytic lipase on surface of organic intercalated and modified MgAl-LDHs

In this study, MgAl-LDHs (layered double hydroxides) intercalated with sodium dodecyl sulfate and outside surface modified with (3-aminopropyl)triethoxysilane (KH550) were prepared. The existence of organic part in LDHs improved immobilization efficiency and activity recovery of candida lipolytic lipase loaded. Also the positive charge in framework of LDHs was found to be beneficial to the enzyme immobilization. An immobilization efficiency of 56.4% and an activity recovery over 69.2% of the enzyme were obtained after it was loaded on the intercalated and modified LDHs, and catalytic activity of the immobilization can be kept at least five times. Moreover, the immobilized enzyme was found to have higher temperature resistance, wider pH value and better thermostability in reactive activity.     

Immobilization of Penicillin G Acylase on Calcined Layered Double Hydroxides

A hydrotalcite-like Mg2 /Al3 layered double hydroxide (LDH) material was prepared by means of amodified coprecipitation method involving a rapid mixing step followed by a separate aging process. LDH calcined at 500℃ , denoted as CLDH, was characterized by XRD, IR and BET surface area measurements.CLDH has a poor crystalline MgO-like structure with a high surface area and porosity. CLDH was used as asupport for the immobilization of penicillin G acylase(PGA). The effect of varying the immobilization conditions, such as pH, contact time and the ratio of enzyme to support, on the activity of the immobilized enzymein the hydrolysis of penicillin G has been studied. It was found that the activity of the immobilized enzyme decreased slightly with decreasing pH and reached a maximum after a contact time of 24 h. The activity of theimmobilized enzyme increased with increasing the ratio of enzyme to support. It was found that the adsorption of PGA inhibited the expected reaction of CLDH with an aqueous medium to regenerate a LDH phase. Itsoriginal activity(36%) after 15 cycles of reuse of the immobilized enzyme was retained, but no further loss in the activity was observed.     

聚乙烯亚胺改性聚丙烯腈中空膜固定脂肪酶

聚丙烯腈是富腈基的高分子聚合物,易修饰改性,广泛应用于膜分离应用.我们以聚丙烯腈中空膜为载体,采用化学法交联聚乙烯亚胺并固定脂肪酶,固定过程中引入海藻酸钠,用CaCl_2进行后处理,得到固定化脂肪酶PAN-PEI-SA/E-CaCl_2载酶量为31.70(mg enzyme)/(g support),酶活为50.20 U/(g support),15次重复使用可保留58.77%的酶活,与游离酶相比耐酸性和耐温性有所提高,相同条件下与Nov 435相比,酶活更高,这表明最终得到的固定化脂肪酶有良好的工业应用前景.     

Characterization of dextransucrases fromLeuconostoc mesenteroides NRRL B-1299

Leuconostoc mesenteroides NRRL B-1299 dextransucrase was fractionated into soluble (SGT) and insoluble (IGT) enzyme preparations differing by their dextran content. In spite of this, they displayed the same Km for sucrose (10 g/L) and the same activation energy (35 kJ/mol). But the presence of cells and insoluble dextran led to the IGT behaving like an immobilized enzyme: stabilization against thermal denaturation and diffusional limitations at low substrate concentrations were observed. On the other hand, the behavior of SGT was influenced by the presence, in the preparation, of soluble dextran that reduced enzyme inhibition by excess substrate. SGT and IGT present very different pH profiles. In the presence of 4 g/L of soluble dextran, IGT was activated and displayed the same susceptibility to pH as SGT. The activation of IGT was highly dependent on the nature of the acceptor added but also on the pH of the reaction medium. IGT and SGT synthesize both soluble and insoluble polymer containing α(l → 2), α(l → 3), and α(l → 6) linkages. A larger amount of insoluble dextran is elaborated by SGT. The polymer structures, examined by¹³C NMR spectrometry, revealed that they differ mainly by their α(l → 3) linkage content (from 0 to 11%). This linkage seems to be partly responsible for the dextran insolubility and can be completely eliminated by carrying out the synthesis of soluble polymer at pH 7.4 with SGT.     

Modification of the thermoresistance to spray-drying of a cold-adapted subtilisin by genetic engineering

The thermoresistance of a cold-adapted subtilisin dried by spray-drying was studied. Proteolytic activity of this enzyme was measured before and after spray-drying. Without chemical additives, spray-drying yields ranged from 2–13%. The use of arabic gum and lactose in the composition of the enzyme solutions allowed the strengthening of the enzyme structures and increased water mobility in the product. Increase of water mobility led to a shorter residence time of the product in the spray-drier and a net yield increase was obtained (yield higher than 50%). The effect of two selective mutations on the thermoresistance to spray-drying of the cold-adapted subtilisin was also investigated. Mutation T85D (introduction of an additional link with an ion Ca²⁺ necessary for enzyme activity, by substitution of Asp for Thr 85) had no effect on the thermoresistance of the subtilisin to spray-drying. Mutation H121W (introduction of an additional aromatic link by substitution of Trp for His 121) reduced the drying yield from 66% (not modified subtilisin) to 52%. This higher thermosensitivity could be explained by an increase of the hygroscopic character of the modified subtilisin (mutation H121W).     

Hydrogen peroxide biosensor with a supramolecular layer-by-layer design

A new sensor design is reported for the construction of an amperometric enzyme biosensor toward H (2)O(2). It was based in the supramolecular immobilization of alternating layers of horseradish peroxidase (either modified with 1-adamantane or beta-cyclodextrin-branched carboxymethylcellulose residues) on Au electrodes coated with polythiolated beta-cyclodextrin polymer. The analytical response of the electrodes, using 1 mM hydroquinone as an electrochemical mediator, increases when the number of enzyme layers increases. The biosensor having three enzyme layers showed a sensitivity of 720 microA/M cm (2) and a detection limit of 2 microM and retained 96% of its initial activity after 30 days of storage. The host-guest supramolecular nature of the immobilization method was confirmed by cyclic voltammetry.     

Phosphodiesterase production in an aqueous two-phase system by Nicotiana tabacum 1507

Studies were conducted on the production of phosphodiesterases by Nicotiana tabacum 1507 cell suspension in an aqueous two-phase system formed by adding 4% polyethylene glycol (mol wt 20,000) and 7.5% dextran (mol wt 70,000) to the medium. The time course of growth, biosynthesis, secretion, and partitioning of phosphodiesterases was followed in comparison with N. tabacum 1507 cultivation as a free suspension. Partitioning of phosphodiesterases took place mainly in the bottom dextran phase, and a possibility was revealed for obtaining an enzyme preparation with high phosphodiesterase activity.     

Separation of pharmacologically active nitrogen-containing compounds on silica gels modified with 6,10-ionene,dextran sulfate,and gold nanoparticles

New stationary phases for HPLC are obtained via layer-by-layer deposition of polyelectrolytes and studied: (1) silica gel modified layer-by-layer with 6,10-ionene and dextran sulfate (Sorbent 1); (2) silica gel twice subjected to the above modification (Sorbent 2); and (3) silica gel modified with 6,10-ionene, gold nanoparticles, and dextran sulfate (Sorbent 3). The effect the content of the organic solvent in the mobile phase and the concentration and pH of the buffer solution have on the chromatographic behavior of several pharmacologically active nitrogen-containing compounds is studied. The sorbents are stable during the process and allow the effective separation of beta-blockers, calcium channel blockers, alpha-agonists, and antihistamines. A mixture of caffeine, nadolol, tetrahydrozoline, pindolol, orphenadrine, doxylamine, carbinoxamine, and chlorphenamine is separated in 6.5 min on the silica gel modified with 6,10-ionene, gold nanoparticles, and dextran sulfate.

     

Direct introduction of amine groups into cellulosic paper for covalent immobilization of tyrosinase: support characterization and enzyme properties

Tyrosinase is used to eliminate phenolic compounds from wastewater. Therefore, its immobilization is important to enhance catalytic efficiency. Papery materials are of particular interest for use as support for enzyme immobilization since the porous microstructure of fiber networks in papers can provide a suitable reaction environment, especially in flow-type catalytic reactions. However, immobilization of protein onto papery structure needs chemical modifications in severe conditions. To overcome this challenge, a cellulosic paper was directly amine-functionalized in moderate conditions and used for tyrosinase immobilization. The support was pretreated with HCl (0.5 N) solution and then sequentially immersed in ethylenediamine (EDA), glutaraldehyde solution (2% v/v) and the crude enzyme. In comparison with the untreated one, the immobilized enzyme on the EDA-treated support offered a 3.7-fold increase in activity. The FTIR spectra as well as EDX analysis proved the presence of amine groups in the cellulosic paper and also covalent immobilization of tyrosinase on the modified support. When considering the effect of pH on the activity at 25 °C, a maximum relative activity of 134% at pH 6 was revealed. Similarly, evaluating the effect of temperature on the activity at pH 7 displayed a maximum relative activity of 152% at 35 °C. The immobilized enzyme was suitable for use for more than four cycles to degrade a phenolic compound at severe pH and temperature conditions. Additionally, the immobilized enzyme was active after treatment of the surface at different pHs and temperatures for 105 min. The chemically modified cellulosic paper can be used as a support for enzyme immobilization.