Flow injection analysis of serum urea using urease covalently immobilized on 2-fluoro-1-methylpyridinium salt-activated fractogel and fluorescence detection

Serum samples were analyzed for their urea content using fluorescence flow injection analysis incorporating an immobilized urease bioreactor and a gas permeable separator. The urease was immobilized under mild and facile conditions to a hydrophilic 2-fluoro-1-methylpyridinium-activated support. The ammonia released as a result of urease-catalyzed urea hydrolysis diffused through a gas permeable membrane into a constant stream of o-phthaldehyde solution to form a highly fluorescent product with lambda ex at 340 nm and lambda em at 455 nm. Up to 25 serum samples can be analyzed per hour. The within-day coefficient of variation (CV) was 1.12% and the day-to-day CV was 1.25% for serum containing 10.50 mg urea nitrogen dl-1. The bioreactor shows excellent storage (at 4 degrees C) and operational stabilities (at 37 degrees C).     

A chemiluminescence automatic analyser for the measurement of biological compounds

A compact automated analyser which could analyse constituents in biological fluids with a small sample volume and in a short time has been developed. The instrument was composed of a flow injection analysis system equipped with chemiluminometric detection and an immobilized enzyme column reactor used in combination. Chemiluminescence has high sensitivity, and its reaction proceeds very quickly. Furthermore, an immobilized enzyme column reactor can produce a sufficient amount of hydrogen peroxide from compounds in serum in a short time. When enzymes are used as reagents for the analysis of substances in blood or blood serum, the final signals emitted by different enzyme reactions are usually not only hydrogen peroxide but also ammonia, NAD(P)H and so on. However, the practical chemiluminescence method for ammonia and NAD(P)H has not been established. We have discovered a new practical method for ammonia and NAD(P)H using an enzyme column reactor consisting of both immobilized L -glutamate dehydrogenase and L -glutamate oxidase. The determinations of glucose and uric acid in serum by chemiluminometry after production of hydrogen peroxide by the respective oxidases are presented. A newly chemiluminometric determination of ammonia, NAD(P)H and its applications to other enzymatic analyses that give ammonia and NAD(P)H as a final signal are also described.     

Use of a bioreactor consisting of sequentially aligned L-glutamate dehydrogenase and L-glutamate oxidase for the determination of ammonia by chemiluminescence

A chemiluminometric method for the automated flow injection analysis of ammonia is described. The essence of the invention is the use of a bioreactor consisting of both immobilized L-glutamate dehydrogenase (GLDH) and L-glutamate oxidase (GLXD), which are sequentially aligned in this order in a minicolumn measuring 2.0 X 20 mm. The unidirectional constant flow of liquid through the column reactor minimizes the reversed diffusion of the solutes so that the following sequence of reactions is ensured. Thus, ammonia to be determined is first transformed by GLDH into L-glutamate, which then produces hydrogen peroxide by GLXD. Hydrogen peroxide in the effluent from the column is then determined by its chemiluminescence upon admixing with luminol and potassium ferricyanide. The present method gives linearity of the standard curve for ammonia up to 1.0 mM. It is at least 100 times more sensitive than the conventional method for ammonia assay using ultraviolet absorption measurement.     

Formation of amino acid from urea and ammonia by sequential enzyme reaction using a microencapsulated multi-enzyme system

A microencapsulated multi-enzyme system has been used for the conversion of urea and ammonia into an amino acid, glutamate. The microencapsulated multi-enzyme system contains urease (E.C.3.5.1.5), glutamate dehydrogenase (E.C.1.4.1.3), and glucose-6-phosphate dehydrogenase (E.C.1.1.1.49). The conversion of urea into glutamate is achieved by the sequential reaction of urease and glutamate dehydrogenase; while glutamate dehydrogenase and glucose-6-phosphate dehydrogenase allow for the cyclic regeneration of NADP⁺:NADPH required for the reaction. The rate of production of glutamate is 1.3 μmole per min per ml of microcapsules. The encapsulated multi-enzyme system thus allows for the sequential enzyme reaction for the conversion of urea and ammonia into an amino acid.     

Microfluidic conductimetric bioreactor

A microfluidic conductimetric bioreactor has been developed. Enzyme was immobilized in the microfluidic channel on poly-dimethylsiloxane (PDMS) surface via covalent binding method. The detection unit consisted of two gold electrodes and a laboratory-built conductimetric transducer to monitor the increase in the conductivity of the solution due to the change of the charges generated by the enzyme-substrate catalytic reaction. Urea–urease was used as a representative analyte-enzyme system. Under optimum conditions urea could be determined with a detection limit of 0.09 mM and linearity in the range of 0.1–10 mM (r = 0.9944). The immobilized urease on the microchannel chip provided good stability (>30 days of operation time) and good repeatability with an R.S.D. lower than 2.3%. Good agreement was obtained when urea concentrations of human serum samples determined by the microfluidic flow injection conductimetric bioreactor system were compared to those obtained using the Berthelot reaction (P < 0.05). After prolong use the immobilized enzyme could be removed from the PDMS microchannel chip enabling new active enzyme to be immobilized and the chip to be reused.     

The immobilization of enzymes on nylon structures and their use in automated analysis

1. Glucose oxidase (EC 1.1.3.4) and urease (EC 3.5.1.5) were covalently attached through glutaraldehyde to low-molecular-weight nylon powder. 2. Immobilized derivatives of glucose oxidase and urease were prepared by cross-linking the respective enzymes within the matrix of a nylon membrane. 3. An improved process is described for the immobilization of glucose oxidase and urease on the inside surface of partially hydrolysed nylon tube. 4. Automated analytical procedures are described for the determination of glucose with each of the three immobilized glucose oxidase derivatives and for the determination of urea with each of the three immobilized urease derivatives. 5. The efficiencies of the three immobilized enzyme structures as reagents for the automated determination of their substrates were compared.     

A rapid assay method for ammonia using glutamine synthetase from glutamate-producing bacteria

A rapid enzymatic assay method for ammonia was developed by using glutamine synthetase from glutamate-producing bacteria together with pyruvate kinase, lactate dehydrogenase, and NADH. The time required for determination of 25 nmol of ammonia was 5 min with 1 unit of glutamine synthetase, as opposed to 14-30 min with 1 unit of glutamate dehydrogenases from various sources. The present method was used to determine ammonia in serum, microbiol-culture broth, and waste water. The method can be modified for spectrophotometry in the visible region by substituting pyruvate oxidase, peroxidase, and appropriate chromogens for lactate dehydrogenase and NADH. With 4-aminoantipyrine (4AA) and phenol, and with 4AA and N-ethyl-N-2-hydroxyethyl-m-toluidine as chromogens, the sensitivity of ammonia determination was 0.65 and 1.7 times that with glutamate dehydrogenase, respectively. The present method was also applicable to the continuous detection of the activity of some ammonia-forming enzymes such as guanase, adenosine deaminase, and urease and to the determination of 0.5-30 microM ATP-ADP after some modification of the mixture.     

交联脲酶聚集体的制备和初步应用

为提高游离脲酶的稳定性,将游离脲酶用硫酸铵沉淀下来后,以戊二醛作为交联剂对其进行化学交联,制备新型的固定化脲酶交联脲酶聚集体,并对其酶学性质进行研究。交联脲酶聚集体的最适pH、最适温度和K_m值分别为：pH 8.0、70℃和0.021 mol/L。在对交联脲酶聚集体的热稳定性,储存稳定性,和对抗蛋白水解酶的能力的研究中,交联脲酶聚集体均显示了比游离脲酶更高的稳定性。为考察其使用效果和稳定性,将其与包醛氧淀粉联合,用于慢性肾衰动物模型的口服治疗。以腺嘌呤灌胃法(每天300mg/kg, 共30d)制备慢性肾衰动物模型,将23只大鼠随机分为模型对照组(每天以10mL/kg蒸馏水灌胃)、单纯包醛氧淀粉组(给予含包醛氧淀粉饲料,10mL/kg蒸馏水灌胃)和包醛氧淀粉+交联脲酶聚集体组(给予含包醛氧淀粉饲料,交联脲酶聚集体悬浮液10mL/kg灌胃),经2周治疗后, 模型对照组、治疗对照组和治疗组实验前后的肌酐含量均有小幅下降,但差异不显著(P值分别为0.922、0.972和0.225＞0.05)。模型对照组的尿素氮含量变化不明显(P=0.211＞0.05)。治疗对照组和治疗组实验前后的尿素氮含量均明显下降(P值分别为0.004和小于0.001,均小于0.01)。治疗对照组和治疗组实验前后的尿素氮含量下降量比较,有显著性差异(P=0.016＜0.05)。治疗组尿素氮含量下降更明显。说明交联脲酶聚集体和包醛氧淀粉联合使用时,对尿素的清除效率比单纯使用包醛氧淀粉更高。     

Urease Immobilization on Arylamine Glass Beads and its Characterization

Jack bean urease has been immobilized on arylamine glass beads (200–400 mesh size, 75–100 Å pore size) and its properties compared with soluble enzyme. The binding of urease was 13.71 mg per gram beads. The K_m for soluble and immobilized urease for urea was 4.20 mM and 8.81 mM, respectively. V_max values of urease decreased from 200 to 43.48 μmol of ammonia formed per min per mg protein at 37°C on immobilization. Both pH and buffer ions influenced the activities of soluble as well as immobilized urease. Soluble urease exhibited pH optima at 5.5 and 8.0. However, immobilized urease showed one additional pH optimum at 6.5. In comparison to phosphate buffer, citrate buffer was inhibitory to urease activity. Immobilization of urease on arylamine glass beads resulted in improved thermal, storage and operational stability. Because of inertness of support and stability of immobilized urease, the preparation can find applications in ‘artificial kidney’ and urea estimation in biological fluids viz., blood, milk etc.     

Effect of nickel deficiency in soybeans on the phytotoxicity of foliar-applied urea

The leaf-tip necrosis commonly observed after foliar fertilization of soybean [Glycine max (L.) Merr.] plants with urea is usually attributed to ammonia formed through hydrolysis of urea by plant urease. We recently found, however, that although addition of a urease inhibitor (phenylphosphorodiamidate) to foliar-applied urea increased the urea content and decreased the ammonia content and urease activity of soybean leaves, it increased the leaf-tip necrosis observed after foliar fertilization. We concluded that this necrosis was due to accumulation of toxic amounts of urea rather than formation of toxic amounts of ammonia. To confirm this conclusion, we measured the urea content, urease activity, and leaf-tep necrosis of leaves of soybean plants treated with urea after growth of the plants in nutrient solutions containing different amounts of nickel (Ni), which is an essential component of urease. We found that the urease activity of these leaves decreased, and that their urea content and leaf-tip necrosis increased, with decrease in the Ni content of the nutrient solution. Besides supporting the conclusion that the leaf-tip necrosis observed after foliar fertilization of soybean with urea is due to accumulation of toxic amounts of urea in the soybean leaves, these observations indicate that Ni-deficient plants may have a lower urease activity than plants that are not deficient in Ni and may therefore be more susceptible to leaf burn when foliar-fertilized with urea.     

Studies on the stability of immobilized xanthine oxidase and urate oxidase.

The stability of immobilized preparations of xanthine oxidase and urate oxidase was studied, and optimized, because of the potential joint use of both enzymes in clinical analysis. Xanthine oxidase was immobilized on cellulose, Sepharose, hornblende, Enzacryl-TIO, and porous glass. Thehalf-lives of these preparations at 30 degree C ranged from 40 min to 5.0 hr. In this respect immobilized enzyme resembled soluble enzyme in dilute solution (0.11 mg/ml), when the half-live was about 3.5 hr. More concentrated enzyme solution (1 mg/ml) had a half-life of 64 hr, and was, therefore, considerably more stable than the untreated immobilized xanthine oxidase preparations. Inclusion of albumen in storage and assay buffer increased the half-life of bound xanthine oxidase. So also did treatment with glutaraldehyde: in the case of xanthine oxidase bound to Enzarcyl-TIO such treatment increased the half-life at 30 degree C from 3 hr to about 100 hr. Immobilized xanthine dehydrogenase was more stable than immobilized xanthine oxidase: the dehydrogenase lost no activity during continuous assay for 5 hr at 30 degree C. The stability of immobilized urate oxidase depended on the quantity of enzyme used and on the time of stirring during immobilization: thus a preparation was made (by stirring urate oxidase (48 mg/g support) with Enzacryl-TIO for 24 hr) which lost no activity during 350 hr at 30 degree C.     

脲酶抑制剂氢醌对土壤脲酶活性,氨挥发和硝化的抑制动态

1.氢醌对土壤脲酶活性的抑制率及其持续的时间同氢醌浓度成正相关,与土壤脲酶活性成负相关。2.氢醌能有效地抑制施入土壤中尿素氨的挥发,而对铵盐和尿素的硝化强度产生强烈抑制。3.在麦秸还田土壤中,由于脲酶活性增高而提高了施入尿素的水解速度,故需提高氢醌用量;但由于麦秸的“氮因子效应”又固定了尿素分解产物及其氧化产物,从而弥补了氢醌失效后可能造成氮素的继续损失。     

Soybean leaf urease: Comparison with seed urease

Soybeans, Glycine max (L.) Merr., from ureides for transport of nitrogen from the root nodule to the shoot. The most direct routes for ureide utilization include the degradation of ureide-derived urea to NH₃ and CO₂. Ureolytic activity was found in leaf disks of soybean and exhbited optimal activity at pH 7 in the presence of a high concentration of urea (250 m M ). In vitro studies showed neither urea amidolyase nor urea dehydrogenase activity in soybean leaves and the ureolytic activity was characterized as urease. Several biochemical properties of soybean leaf urease were determined and compared to seed urease properties. Soybean leaf urease differed from that of seed in five ways: pH optima (5.25 and 8.75), apparent K_m (0.8 m M ), no inhibition by hydroxyurea, faster electrophoretic mobility and no cross-reactivity with soybean seed urease antibodies. The data suggest that urease is the primary urea metabolizing enzyme present in soybean leaves. The properties of soybean leaf urease support the conclusion that a unique isozyme of urease is present in leaf tissue.     

Urease of Klebsiella aerogenes: control of its synthesis by glutamine synthetase.

Urease was purified 24-fold from extracts of Klebsiella aerogenes. The enzyme has a molecular weight of 230,000 as determined by gel filtration, is highly substrate specific, and has a Km for urea of 0.7 mM. A mutant strain lacking urease was isolated; it failed to grow with urea as the sole source of nitrogen but did grow on media containing other nitrogen sources such as ammonia, histidine, or arginine. Urease was present at a high level when the cells were starved for nitrogen; its synthesis was repressed when the external ammonia concentration was high. Formation of urease did not require induction by urea and was not subject to catabolite repression. Its synthesis was controlled by glutamine synthetase. Mutants lacking glutamine synthetase failed to produce urease, and mutants forming glutamine synthetase at a high constitutive level also formed urease constitutively. Thus, the formation of urease is regulated like that of other enzymes of K. aerogenes capable of supplying the cell with ammonia or glutamate.     

Designing a reusable system based on nanodiamonds for biochemical determination of urea

A reusable system including urease covalently bound to the surface of modified nanodiamonds (MNDs) has been developed for the multiple determination of urea. The immobilized enzyme exhibits functional activity and catalyzes the hydrolysis of urea to yield ammonia. The presence of ammonia is confirmed by the formation of a colored product after the addition of chemical reagents. It was shown that the MNDs-urease complex can function in a wide range of temperatures and pH as well as in deionized water. The complex provides a linear yield of the product at low analyte concentrations and allows the multiple determination of urea in vitro.     

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.     

Urea hydrolysis by immobilized urease in a fixed-bed reactor: analysis and kinetic parameter estimation

Urea hydrolysis by urease immobilized onto ion exchange resins in a fixed-bed reactor has been studied. A modified Michaelis-Menten rate expression is used to describe the pH-dependent, substrate- and product-inhibited kinetics. Ionic equilibria of product and buffer species are included to account for pH changes generated by reaction. An isothermal, heterogeneous plug-flow reactor model has been developed. An effectiveness factor is used to describe the reaction-diffusion process within the particle phase. The procedure for covalent immobilization of urease onto macroporous cation exchangers is described. Urea conversion data are used to estimate kinetic parameters by a simplex optimization method. The best-fitted parameters are then used to predict the outlet conversions and pH values for systems with various inlet pH values, inlet urea and ammonia concentrations, buffers, particle sizes, and spacetimes. Very good agreement is obtained between experimental data and model predictions. This immobilized urease system exhibits quite different kinetic behavior from soluble urease because the pH near the enzyme active sites is different from that of the pore fluid. This effect results in a shift of the optimal pH value of the V(max) (pH) curve from 6.6 (soluble urease) to ca. 7.6 in dialysate solution, and ca. pH 8.0 in 20mM phosphate buffer. The reactor model is especially useful for estimating intrinsic kinetic parameters of immobilized enzymes and for designing urea removal columns.     

Lichen substrates and urease production and secretion: A physiological approach using four Antarctic species

Ramalina terebrata, C. regalis and S. alpinum produce urease in response to urea exogenously supplied. Enzyme activity is abolished by including 300 μM cycloheximide in the incubation media. Urease is affected by feed-back inhibition when ammonia is accumulated in the thalli. Lecania brialmontii has a constitutive urease which is strongly inhibited by an excess of urea. The enzyme is secreted to the media as a function of the soil in which lichens survive.     

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.     

Molecular Modeling and docking of Wheat Hydroquinone Glucosyl transferase by using Hydroquinone,Phenyl phosphorodiamate and n-(n butyl) Phosphorothiocic Triamide as Inhibitors

In agriculture high urease activity during urea fertilization causes substantial environmental and economical problems by releasing abnormally large amount of ammonia into the atmosphere which leads to plant damage as well as ammonia toxicity. All over the world, urea is the most widely applied nitrogen fertilizer. Due to the action of enzyme urease; urea nitrogen is lost as volatile ammonia. For efficient use of nitrogen fertilizer, urease inhibitor along with the urea fertilizer is one of the best promising strategies. Urease inhibitors also provide an insight in understanding the mechanism of enzyme catalyzed reaction, the role of various amino acids in catalytic activity present at the active site of enzyme and the importance of nickel to this metallo enzyme. By keeping it in view, the present study was designed to dock three urease inhibitors namely Hydroquinone (HQ), Phenyl Phosphorodiamate (PPD) and N-(n-butyl) Phosphorothiocic triamide (NBPT) against Hydroquinone glucosyltransferase using molecular docking approach. The 3D structure of Hydroquinone glucosyltransferase was predicted using homology modeling approach and quality of the structure was assured using Ramachandran plot. This study revealed important interactions among the urease inhibitors and Hydroquinone glucosyltransferase. Thus, it can be inferred that these inhibitors may serve as future anti toxic constituent against plant toxins.