Activity and distribution of urease following microencapsulation within polyamide membranes.

Urease was microencapsulated by forming a semipermeable polyamide membrane around aqueous microdroplets (266 microns mean diameter) containing the soluble enzyme. The yield of the interfacial polymerization technique, determined spectrophotometrically, was 83% of the original enzyme on a mass basis, resulting in a final intracapsular urease concentration of 62.3 mg ml-1 or 0.1 mM. Similar absorption spectra of broken and intact microcapsules suggested that spectrophotometry may be applied in performing direct studies on the intact microcapsules. The high activity yield of urease microcapsules relative to the mass of entrapped enzyme (92.5%) indicated minimal effects of mass transfer limitation. The mass of active urease incorporated into the nylon membrane represented 6% of the encapsulated enzyme activity. The soluble intracapsular enzyme fraction (94%) was released into solution upon rupture of the membrane. A complete mass and activity balance of the encapsulated enzyme was achieved.     

Photocontrol of urease-collagen membrane activity.

(1) Urease (EC 3.5.1.5.) was modified with beta-1-[3,3-dimethyl-6'-nitrospiro-(indoline-2,2'-2H-benzopyrene)] propionic anhydride. Three amino acid residues of urease were modified by the anhydride at a molar ratio of 2000. (2) The activity of modified urease was decreased with ultraviolet irradiation and then restored to the initial activity with visible light irradiation. (3) Modified urease was used to prepare a urease-collagen membrane. The apparent Michaelis constant (Km) of the modified urease-collagen membrane ultraviolet light was identical to that of the membrane under visible light. (4) The optimum pH of the modified urease-collagen membrane was displaced toward lower pH values with ultraviolet irradiation. At higher ionic strength, the pH activity curve of the membrane was displaced toward higher pH values. (5) The thermostability of urease was increased with its modification.     

Microencapsulation of Urease by Interfacial Polymerization with Liquid-air Nozzle Method

Microencapsulation of urease solution was performed through the liquid-air nozzle by using an interfacial polymerization reaction. The diameter of microcapsules was well controlled by the air flowing through. The urease activity remaining after microencapsulation was affected by pH value of the aqueous phase, concentration of hexamethylenediamine and addition of protective proteins. The optimum condition for microencapsulation was searched, under which the capsulated urease retained 78% of the initial activity. Michaelis–Menten constant did not change significantly after microencapsulation. To strengthen the mechanical properties of capsules, reentrapment into polyvinylalcohol gel was attempted and a good result was obtained.     

Polyaniline as a support for urease immobilization

Polyaniline synthesized by chemical oxidative polymerization was used as an immobilization support for jack bean urease. Such immobilized enzyme has a good catalytic activity, storage stability, and reusability. Properties of free and immobilized urease were compared. Blends of polystyrene, cellulose acetate and poly(methyl methacrylate) with polyaniline were used for urease immobilization as well.     

Acid resistance of Helicobacter pylori depends on the UreI membrane protein and an inner membrane proton barrier

ureI encodes an inner membrane protein of Helicobacter pylori. The role of the bacterial inner membrane and UreI in acid protection and regulation of cytoplasmic urease activity in the gastric microorganism was studied. The irreversible inhibition of urease when the organism was exposed to a protonophore (3,3',4', 5-tetrachlorsalicylanide; TCS) at acidic pH showed that the inner membrane protected urease from acid. Isogenic ureI knockout mutants of several H. pylori strains were constructed by replacing the ureI gene of the urease gene cluster with a promoterless kanamycin resistance marker gene (kanR). Mutants carrying the modified ureAB-kanR-EFGH operon all showed wild-type levels of urease activity at neutral pH in vitro. The mutants resisted media of pH > 4.0 but not of pH < 4.0. Whereas wild-type bacteria showed high levels of urease activity below pH 4.0, this ability was not retained in the ureI mutants, resulting in inhibition of metabolism and cell death. Gene complementation experiments with plasmid-derived H. pylori ureI restored wild-type properties. The activation of urease activity found in structurally intact but permeabilized bacteria treated with 0.01% detergent (polyoxy-ethylene-8-laurylether; C12E8), suggested a membrane-limited access of urea to internal urease at neutral pH. Measurement of 14C-urea uptake into Xenopus oocytes injected with ureI cRNA showed acid activation of uptake only in injected oocytes. Acceleration of urea uptake by UreI therefore mediates the increase of intracellular urease activity seen under acidic conditions. This increase of urea permeability is essential for H. pylori survival in environments below pH 4.0. ureI-independent urease activity may be sufficient for maintenance of bacterial viability above pH 4.0.     

Localization of enzymes in Ureaplasma urealyticum (T-strain mycoplasma).

Ureaplasma urealyticum cells were lysed by osmotic shock or by digitonin. The membrane fraction contained four to ten times as much protein as the cytoplasmic fraction. These values are in large excess of those reported for classical mycoplasmas, suggesting that the Ureaplasma membrane fraction was heavily contaminated with proteins derived from the growth medium. The U. urealyticum urease activity was localized in the cytoplasmic fraction, whereas the adenosine triphosphatase activity was localized in the membrane fraction. Significant urease activity could be detected also in nonviable cells. Urea, at concentrations above 0.25 M, was mycoplasmastatic to Acholeplasma laidlawii, Mycoplasma hominis, and U. urealyticum, so that the Ureaplasma urease did not afford preferential protection against urea toxicity. The intracellular localization of the urease would be expected to release ammonia from urea in the cytoplasm. The ammonia will take up protons to become ammonium ions. It can be hypothesized that the intracellular NH4+ plays a role in proton elimination or acid-base balance, which might be coupled to an energy producing ion gradient and/or transport mechanisms.     

Selective transport of the mulberry leaf urease from the midgut into the larval hemolymph of the silkworm,Bombyx mori

Just before spinning, larvae of the silkworm, Bombyx mori, absorb intact urease of the host plant (mulberry leaf) from the midgut lumen into the hemolymph. In order to investigate whether the transport of the mulberry leaf urease is selective, crude proteins extracted from the mulberry leaves were labeled with biotin and orally administered to the fifth instar larvae. The biotinylated proteins transported into the hemolymph were detected by ligand blotting using streptavidin. When the biotinylated proteins were administered to 5-day-old fifth instar larvae, a strong signal of a biotinylated protein was detected in the hemolymph 2 days after the administration. In contrast, when the biotinylated mulberry leaf proteins were administered to 3-day-old fifth instar larvae, no signal derived from the biotinylated proteins was detected in the hemolymph. The signal weakened when the biotinylated proteins had been immunoprecipitated before administering to the larvae, indicating that the signal came from the mulberry leaf urease. These results show that the transport of the mulberry leaf urease from the midgut into the hemolymph is selective and larval-stage specific. Subsequently, binding assays were carried out to test the binding ability of the mulberry leaf urease to the brush border membrane in the epithelial cells of larval midgut. The urease was not bound to the brush border membrane vesicles (BBMV) from the midgut of 3-day-old fifth instar larvae, while more than 60% of the total amount of incubated urease was bound to the BBMV from the midgut of 6-day-old fifth instar larvae. The urease binding ability of BBMV correlated with the uptake of the mulberry leaf urease. This suggests that a urease binding molecule(s) exists in the BBM of the midgut epithelium, which is involved in the uptake of the mulberry leaf urease. In addition, the uptake of the mulberry leaf urease into the hemolymph was induced by 20-hydroxyecdysone.     

Energetics of Helicobacter pylori and its implications for the mechanism of urease-dependent acid tolerance at pH 1

In the presence of urea the neutrophilic human pathogen Helicobacter pylori survives for several hours at pH 1 with concomitant cytoplasmic pH homeostasis. To study this effect in detail, the transmembrane proton motive force and cytoplasmic urease activity of H. pylori were determined at various pH values. In the absence of urea, the organism maintained a close-to-neutral cytoplasm and an internally negative membrane potential at external pH values greater than 4 to 5. In the presence of urea, H. pylori accomplished cytoplasmic pH homeostasis down to an external pH of 1.2. At this external pH, the cytoplasmic pH was 4.9 and the membrane potential was slightly negative inside. The latter finding is in contrast to the situation in acidophiles, which develop inside-positive membrane potentials under similar conditions. Measurements of the time course of the membrane potential confirmed that addition of urea to the cells led to hyperpolarization. Most likely, this effect was due to electrogenic export of ammonium cations from the cytoplasm. The urease activity of intact cells increased nearly exponentially with decreasing external pH. This activation was not due to enhanced gene expression at low external pH values. In cell extracts the pH optimum of urease activity was dependent on the buffer system and was about pH 5 in sodium citrate buffer. Since this is the cytoplasmic pH of the cells at pH 1 to 2, we propose that cytoplasmic pH is a factor in the in vivo activation of the urease at low external pH values. The mechanism by which urease activity leads to cytoplasmic pH homeostasis in H. pylori is discussed.     

Characteristics of Ureaplasma urealyticum urease.

Sonication of Ureaplasma urealyticum cells grown in a dialysate growth medium effectively separated the cytoplasmic fraction from the membrane fraction, with both fractions relatively free from exogenous contaminating proteins. The urease activity was associated with the cytoplasmic fraction, and the ureaplasmal urease exhibited a specific activity higher than that of crystalline jack bean urease. The enzymatic activity of the ureaplasmal enzyme was optimum at pH 7.5 and was resistant to the chelating agents EDTA and sodium citrate. Sulfhydryl-blocking agents such as HgCl2 and Pb(NO3)2 inhibited the ureaplasmal urease, which was also shown to be particularly sensitive to flurofamide and, to a much lesser extent, to acetohydroxamic acid. Electrophoretic analysis of the proteins of the ureaplasmal cell fractions combined with Western immunoblot with an antiserum to the ureaplasmal urease indicated that the urease constitutes a major component of the cytoplasm and is composed of several 70-kilodalton polypeptides.     

Multilayer binding of proteins to polymer chains grafted onto porous hollow-fiber membranes containing different anion-exchange groups

Various anion-exchange groups were introduced into the polymer chains grafted onto a porous hollow-fiber membrane for protein recovery by radiation-induced graft polymerization and subsequent functionalization of a monomer containing an epoxy group. The graft chains extended from the pore surface toward the pore interior, resulting in the multilayer binding of proteins to the graft chains. Combinations of three anion-exchange groups, namely, amino (AM), ethylamino (EA), and diethylamino (DEA) groups, and three proteins, namely, beta-lactoglobulin, bovine serum albumin, and urease, were examined to evaluate the degree of multilayer binding of protein to the graft chains in the permeation mode. Multilayer binding was observed for hollow-fiber membranes containing EA and DEA groups, with conversions of epoxy groups to EA or DEA groups of higher than 80%. The amount of adsorbed protein remained constant irrespective of the conversion for the hollow-fiber membrane containing an AM group. The dependence of the flux on the conversion was consistent with that of the degree of multilayer binding to the graft chains.     

Stabilization of native and immobilized urease

The stability of native and immobilized urease isolated from Staphylococcus saprophyticus was studied at 4 degrees and 25 degrees C. The activity yield was 20% and 1.4% on the enzyme immobilization in albumin gel and latex membrane, respectively. Inactivation of native microbial urease proceeded 10 times slower in the solution containing 1 mM EDTA and 30 mM sodium sulfite. This solution contributed to a great extent to stabilization of immobilized urease both during storage in the phosphate buffer solution and in case of lyophilization.     

Mechanisms of regulation of urease biosynthesis in Proteus rettgeri

Urease of Proteus rettgeri is an inducible enzyme synthesized specifically in the presence of urea; urea analogues did not act as inducers. Once initiated, the biosynthesis of the enzyme proceeded as a constant fraction of the total protein formed. The rate of urease formation was affected by the carbon source used. In comparison with glycerol, glucose inhibited enzyme synthesis. The addition of ammonium ions to the inducing medium also decreased the rate of urease biosynthesis, and when ammonium ions were present urease activity and urea transport across the cell membrane were inhibited. A kinetic analysis of urease inhibition by ammonium ions, by use of a partially purified preparation of urease, showed that it was a competitive inhibition.     

Development of potentiometric urea biosensor based on urease immobilized in PVA-PAA composite matrix for estimation of blood urea nitrogen (BUN)

A urea biosensor was developed using the urease entrapped in polyvinyl alcohol (PVA) and polyacrylamide (PAA) composite polymer membrane. The membrane was prepared on the cheesecloth support by gamma-irradiation induced free radical polymerization. The performance of the biosensor was monitored using a flow-through cell, where the membrane was kept in conjugation with the ammonia selective electrode and urea was added as substrate in phosphate buffer medium. The ammonia produced as a result of enzymatic reaction was monitored potentiometrically. The potential of the system was amplified using an electronic circuit incorporating operational amplifiers. Automated data acquisition was carried by connecting the output to a 12-bit analog to digital converter card. The sensor working range was 1–1000 mM urea with a response time of 120 s. The enzyme membranes could be reused 8 times with more than 90% accuracy. The biosensor was tested for blood urea nitrogen (BUN) estimation in clinical serum samples. The biosensor showed good correlation with commercial Infinity™ BUN reagent method using a clinical chemistry autoanalyzer. The membranes could be preserved in phosphate buffer containing dithiothreitol, β-mercaptoethanol and glycerol for a period of two months without significant loss of enzyme activity.     

Ultrafiltration membranes for chemical bonding of urease

Asymmetric ultrafiltration membranes suitable for covalent bonding of urease can be prepared from membranes based upon polyamide or polysulfone. Because the original membrane polymers are not chemically reactive, they have to be converted in such a way that known reactions for enzyme fixation can be used such as the diazo, the acyl-acid, the carbodiimide, and the methylbromide reaction. The enzyme was fixed within the porous substructure of the membrane. The amount of enzyme immobilized at the membrane dense skin was found to be negligible. The kinetics can be described according to the Michaelis-Menten model. Compared to the native urease, the activity of the membrane-bonded enzyme was very low. The reasons can be sought in the transmembrane transport and in the fixation procedure as well.     

Urease immobilized on an aminated polysulphone membrane – inhibition by boric acid

An enzymatic membrane for application in the processes of decomposition and removal of urea from aqueous solutions was prepared: jack bean urease was immobilized on an aminated polysulphone membrane by adsorption. The inhibition of the system by boric acid was studied using procedures based on the MICHAELIS-MENTEN integrated equation (non-linear regression, and the linear transformations of WALKER and SCHMIDT, JENNINGS and NIEMANN, and BOOMAN and NIEMANN). The reaction was carried out in a 100 mM phosphate buffer of pH 7.0, containing 2 mM EDTA, obtained by neutralization of orthophosphoric acid with NaOH, at an initial urea concentration of 10 mM, and a temperature of 25 °C. The reaction was initiated by the addition of the enzyme to the urea solution, and was monitored by removing samples of the reaction mixture for NH₃ determinations by the phenol-hypochlorite method until the urea was exhausted. The results were compared with those obtained earlier under the same reaction conditions for free urease and urease covalently immobilized on chitosan. The inhibition was found to be competitive, similar to that of the free enzyme and urease immobilized on chitosan, with inhibition constants K_i equal to 0.36, 0.19 and 0.60 mM. The results show that adsorption of the enzyme on a polysulphone membrane changed the enzyme to a lesser degree than covalent immobilization of the enzyme on a chitosan membrane.     

Histochemical and biochemical urease localization in the periplasm and outer membrane of two Proteus mirabilis strains

Proteus mirabilis, a gram-negative bacillus, is often implicated in the formation of infectious kidney stones. As ureolytic activity of this organism is thought to play a major role in its pathogenesis, we adapted our recently described urease localization technique to visualize urease activity in vivo. Urease activity was ultrastructurally localized in two clinically isolated P. mirabilis strains by precipitating the enzymatic reaction product (ammonia) with sodium tetraphenylboron. Subsequent silver staining of the cells revealed urease activity to be predominantly associated with the periplasm and outer membranes of each strain. Biochemical measurements of urease activity in P. mirabilis cell fractions correlated well with histochemical observations in that the majority of urease activity was associated with the periplasm. Membrane-bound urease activity of these strains was associated mainly with the peptidoglycan in the detergent-insoluble (outer membrane) fraction.     

Permeability and Molecular Sieving Characteristics of Nylon Microcapsule Membrane

The permeability of nylon microcapsule membrane was measured by two methods: (1) by NH₄Cl tracer permeation method and (2) by the overall reaction behaviour of urease immobilized in microcapsule. The latter method gave higher values of permeability. It was possible to calculate permeability and activity simultaneously by the application of the least squares method to the results of overall microencapsulated urease reaction. Permeability varied with protein used in microencapsulation, which seemed to show the participation of proteins in the copolymerization reaction of nylon. The cut-off molecular weight of capsule membrane was measured to be 1,000~10,000 by permeation experiments using tracers of different molecular weights. These membrane characteristics were successfully applied to molecular sieving chromatography using a column packed with microcapsules.     

Regulation of actin polymerization by membrane fraction of platelets

We studied the interaction between the purified membrane fraction of human platelets and the polymerization of skeletal actin. The viscosity of actin was measured by the falling ball method. The fraction suppressed the polymerization of actin in the presence of 20 mM KCl and 0.4 mM EGTA. The addition of calcium ion or thrombin to the fraction did not cause suppression. A DNase I affinity column bound the membrane fraction in the presence of calcium ion. The frozen membrane fraction and the vesicles reconstituted with lipids from the platelet membrane enhanced the polymerization of actin. Trypsinized membrane fraction and the membrane fraction treated with phospolipase A2 enhanced the polymerization of actin, but membrane fraction treated with phospholipase C had no effect. The reconstituted membrane vesicles mentioned above lowered the critical concentration for actin polymerization. These findings suggested that the polymerization of intracellular actin is enhanced not only by the mobilization of calcium ion, but also by biochemical changes in the membrane lipids.     

Regulation of urease by urea and its precursors in the lichen Evernia prunmtri

Thallus samples of £. prunastri (L.) Adi, floated on 40 mM urea developed urease (EC 3.5.1.5.) activity which levelled off after 6h. L-Arguiine, L-ornitfaine and patrescine added to the incubation media intitially enhanced the effect of urea, but the urease activity ceased after 4h of incubation in the presence of the latter two compounds or when L-arginine was used; as the sole source of nitrogen. This decline in activity was observed after 6h when L-arginine was added to urea-containing media. The loss of urease activity is thought to result from the synthesis of repressers in the presence of the amino acids, whereas putrescine appears to affect membrane permeability by increasing the uptake of urea by the cells. Declining urease activity in the latter case would then be due to feedback inhibition caused by the excess of ammonia produced in both hydrolysis of urea and oxidation of putrescine.