Review Properties and Applications of Urease

Urease is a highly efficient catalyst for the hydrolysis of urea with a rate approximately 10 14 times the rate of the noncatalyzed reaction. It has a long and distinguished history in the development of enzymology. In this work the properties of urease and its applications in biotechnology are reviewed, including urea content analysis in blood, urine, alcoholic beverages, natural water and environmental wastewaters; analysis of heavy metal content in natural waters, wastewaters and soil; determination of creatinine, arginine and IgG; urea removal from artificial kidney dialyzates, alcohol beverages and fertilizer wastewaters; wastewater reclamation for life support systems in space; pH control or shift for multi-enzyme reaction system; and urea hydrolysis as sources of ammonia or carbon dioxide in special cases. Future research trends are also outlined.     

Rate of hydrolysis of urea as influenced by thiourea and pellet size

Summary Two incubation experiments and a number of field experiments were conducted to determine the effect of soil moisture tension, pellet size and addition of thiourea to urea on the rate of urea hydrolysis. In the incubation experiments at 20°C, the rate of hydrolysis of urea increased from 15 bar to 1/3 bar soil moisture tension, with the largest change (doubling) occurring from 15 bar to 7 bar moisture tension. Increasing pellet size reduced the rate of urea hydrolysis by about 12% with urea pellets weighing 0.21 g as compared to 0.01 g urea pellets after 114h. When thiourea (a metabolic inhibitor) was pelleted with urea in a ratio of two parts urea and one part thiourea, the rate of hydrolysis was halved.In a field experiment, the addition of thiourea to urea and increasing pellet size suppressed the rate of urea hydrolysis considerably for 8 days. The amount of urea hydrolyzed with urea+thiourea (21) pellets weighing 2.51 g was one-fourth of the amount of urea hydrolyzed with 0.01 g pellets of urea alone. In the other six field experiments which were set out in October, only 22% to 39% of urea +thiourea (21) was hydrolyzed at two weeks after application, while almost all of the urea was hydrolyzed when it was mixed into the soil without an inhibitor.Unter our field conditions, we would estimate that the hydrolysis of urea can be inhibited for at least one week. The inhibition of urea hydrolysis appears to be great enough that the problems encountered from the rapid hydrolysis of urea, wherever these occur, may be reduced by combined use of thiourea and either increased pellet size or band placement.     

Ammonium and urea removal by Spirulina platensis

Different concentrations either of ammonium chloride or urea were used in batch and fed-batch cultivations of Spirulina platensis to evaluate the possibility of substituting nitrate by cheaper reduced nitrogen sources in wastewaters biotreatment. The maximum nitrogen concentration able to sustain the batch growth of this microalga without inhibition was 1.7 mM in both cases. Ammonium chloride was limiting for the growth at lower concentrations, whereas inhibition took place at higher levels. This inhibition effect was less marked with urea, likely because the enzymatic hydrolysis of this compound by urease controlled the ammonia transfer into the cell. Fed-batch experiments carried out by pulse-feeding either ammonium or urea proved that the use of these compounds as nitrogen sources can sustain the long term-cultivation of S. platensis, provided that the conditions for their feeding are accurately optimized.     

A Multistage Well‐Mixed Model for Urea Removal from Industrial Wastewater

A multistage well‐mixed model for urea removal from industrial wastewater has been proposed. The model incorporates reaction rate of urea hydrolysis and takes into account the effects of backmixing on the reactor performance. The model provides temperature and concentration distribution of different components along the height of reactor. The predicted data of the model were consistent with the plant data indicating the validity of the model. The impact of different parameters on the performance of urea hydrolyzer has been examined. The result of this work showed that an increase in inlet temperature of wastewater and steam flow rate would improve the urea removal efficiency.     

Transformation of urea and ammonium sulphate in different soils

Summary The transformation of urea and ammonium sulphate in Ladwa sandy loam and Balsamand sand was studied in laboratory. Urea took at least one week in sandy loam and 2 weeks in sandy soils to hydrolyse completely. The process of hydrolysis was faster in finer soil with high organic matter than in coarse soil having low organic matter. There was no nitrification upto 3 days in sandy loam and upto 7 days in sandy soils, respectively, but there was immobilization of NO₃-N during these initial periods. The NO₃-N content at the end of incubation period (35 days) was more in case of urea than in case of ammonium sulphate treated samples in sandy loam soil and reverse was true in sandy soil. The hydrolysis of urea did not follow zero or first order kinetics as proposed in previous studies.     

On the nature of mechanisms responsible for the higher efficiency of urea supergranules for rice

Summary A laboratory study made with a sandy clay loam soil of pH 7.7 showed that hydrolysis of urea was slower when applied as urea supergranules (USG) than commercial urea prills. This resulted in maintenance of applied nitrogen as ammonium in the soil for a longer period. Nitrite concentration was also much less with USG. These three mechanisms are responsible for the higher efficiency of USG over urea prills.     

Evidence for bacterial urea production in marine sediments

Abstract The quantitative importance of bacteria in urea production and turnover in a defaunated sediment from a Danish estuary was studied. After collecting the sediment, benthic infauna was removed by sieving, followed by anoxic pre-incubation for a week. Yeast extract was added to half of the samples. The urea concentration, urea production/turnover rates and the net ammonium production rate, were followed during a 338 h incubation. The urea concentration was highest in the enriched sediment, although urea production and turnover rates were the same in the enriched and control sediment, indicating that the urea concentration was controlled by the urea turnover rate constant, k _urea. Net ammonium production, urea concetrations and teh urea turnover declined towards the end of the experiment. Comparison of the net ammonium production rate and the urea turnover rate in the enriched and control treatments, showed that urea hydrolysis accounted for up to 100% of the ammonium produced, from all sources. More than 98% of the urea which was hydrolyzed, originated from production during incubation. This suggests that urea was a major nitrogen excretion product from bacteria in this sediment, and that bacteria could also be an important source of urea in other marine sediments.     

Urea hydrolysis and transformations in coastal dune sands and soil

Summary Urea hydrolysis was studied in samples taken from a coastal sand dune succession, from uncolonized sand; the rhizosphere ofAmmophila arenaria and soil from the mature dune. Comparisons were made with urea hydrolysis in a fertile loam soil. Urea was hydrolyzed in all sand and soil samples, with complete hydrolysis occurring after 6 and 3 weeks in the rhizosphere sand and dune soil compared with only 4 days in the fertile loam. A third of the added urea, however, was still present in the uncolonized sand samples 6 weeks after the beginning of the incubation period. Urea hydrolysis broadly correlated with urease activity.The liberated NH ₄ ⁺ was oxidized to NO ₃ ^– –N in all samples. Urea stimulated the release of N from native organic matter in the two soils, but not sands, due presumably to the low organic matter content of the latter. Nitrite accumulated in the dune sands and soil, but not in the fertile loam.Although N-Serve (Nitrapyrin) had no effect on urea hydrolysis in any of the treated samples, it inhibited the nitrification of released NH ₄ ⁺ –N. The relevance of these findings to the use of urea as a fertilizer to improve plant growth and dune stabilization is commented upon.     

脲对棒状链霉菌棒酸合成的影响

【目的】棒酸(Clavulanic acid)是棒状链霉菌(Streptomyces clavuligerus)产生的β-内酰胺酶抑制剂,其合成过程中产生副产物脲,旨在探讨脲对棒酸合成的影响。【方法】通过发酵过程中脲和铵盐添加实验、阻断脲酶活性以及pH梯度实验研究脲对棒酸合成影响。【结果】脲添加实验结果表明:低浓度脲降低棒酸产量,当添加脲浓度达到20 mmol/L时,完全抑制棒酸合成。由于脲酶可以把脲水解为铵离子,导致铵离子浓度及pH提高,因此,通过阻断棒状链霉菌脲酶活性,可以更准确地反映脲对棒酸合成的影响。结果发现,脲酶敲除株发酵液中脲大量积累,浓度高达10 mmol/L,但棒酸产量没有明显降低,说明在该浓度下脲自身并不能抑制棒酸合成。添加脲降低野生菌棒酸产量,可能是脲被水解为铵离子或其引起的pH变化所致。而棒酸发酵液添加铵盐的结果显示铵离子对棒酸产量没有抑制作用;另外,pH梯度实验证实不同pH对棒酸产量影响较大。【结论】排除了脲和铵离子对棒酸合成的抑制作用,证实了脲酶水解脲导致pH提高是脲添加导致野生菌棒酸产量降低的真正原因,为进一步阐明棒酸合成调控机制提供了根据。     

Effects of parathion and malathion on transformations of urea and ammonium sulfate nitrogen in soils

Summary A study of the effects of malathion and parathion applied at 10 and 50 g/g of soil on transformations of urea and (NH₄)₂SO₄–N in a sandy loam showed that the insecticides retarded urea hydrolysis as well as nitrification of urea and (NH₄)₂SO₄–N. At 50 parts/10⁶ rate of the insecticides, inhibition of urea hydrolysis ranged from 44 to 61% after 0.5 week and from 7 to 21% after 3 weeks of application. The insecticides inhibited the conversion of NH₄ ⁺ to NO₂ ^– without appreciably affecting the subsequent oxidation of NO₂ ^– to NO₃ ^– –N. This resulted in accumulation of higher amounts of NH₄ ⁺–N in soil samples treated with ammonium sulfate or urea N.The results suggest that transformations of urea and NH₄ ⁺ fertilizers in soils may be influenced by the amount of organophosphorus insecticide present and this may affect plant nutrition and fertilizer use.     

The simple open soil method of measuring urea volatilisation losses

Summary A simple technique of estimating ammonia volatilisation loss from urea applied to soil is described. The soil is incubated with urea, after which hydrochloric acid is added to prevent loss of N from the hydrolysed urea during drying of the soil. The volatilisation loss is estimated by difference between the N recovered from the soil and the urea applied. Recovery studies of urea hydrolysis on 3 Malaysian soils show that the hydrolysis products, consisting of ammonium N and any unreacted urea, can be quantitatively recovered from the soil by this technique, with average recoveries of 95%–97%. A cross-check by 9 laboratories indicated good accuracy and precision in the method. When the open soil method was compared with the direct measurement of ammonia loss in simple volatilisation chambers, it gave much higher results suggesting that the closed system of trapping tended to underestimate volatilisation losses during urea hydrolysis.     

Salt effects on urea hydrolysis and nitrification during leaching through laboratory soil columns

Summary We studied the transport and transformation of urea under steady-state conditions in two soils and at three water salinities (1.0, 5.0, and 10.0 dS/m) using laboratory soil columns. A mathematical model that considers diffusion, convection, adsorption and first-order kinetic transformation of nitrogen was used to describe measured effluent concentration of the two nitrogen species. Increasing salt levels in the applied water decreased the hydrolysis of urea in the two soils studied with first-order rate coefficients decreasing from 0.015 to 0.009 h^–1 in the fine sandy loam, and from 0.075 to 0.015 h^–1 in a silty loam. Similarly, the nitrification rate decreased by 50% and 70% in the two soils as salinity increased. The rate coefficients measured in the leaching studies were much smaller than measured in incubation-type experiments. Calculated half-lives for urea and NH ₄ ⁺ provided a method interpreting the kinetic rate coefficients as a function of the experimental conditions.     

Piezoelectric urea biosensor based on immobilization of urease onto nanoporous alumina membranes

The urease was immobilized onto nanoporous alumina membranes prepared by the two-step anodization method, and a novel piezoelectric urea sensing system with separated porous alumina/urease electrode has been developed through measuring the conductivity change of immobilized urease/urea reaction. The process of urease immobilization was optimized and the performance of the developed urea biosensor was evaluated. The obtained urea biosensor presented high-selectivity monitoring of urea, better reproducibility (S.D. = 0.02, n = 6), shorter response time (30 s), wider linear range (0.5 μM to 3 mM), lower detection limit (0.2 μM) and good long-term storage stability (with about 76% of the enzymatic activity retained after 30 days). The clinical analysis of the urea biosensor confirmed the feasibility of urea detection in urine samples.     

Properties of urease immobilized on the functional organic silica surface

The paper deals with kinetics of the urea hydrolysis by microbial-origin urease dissolved and immobilized on the organic silica surface. It is shown that hydrolysis kinetics for soluble urease is described by the Michaelis-Menten equation until the concentration of urea reaches 1 M. Two fractions differing in the Michaelis constant are revealed for silochrome immobilized urease. The rate of urea hydrolysis by native and immobilized urease was studied depending on the pH value in presence of the substrate in the 1 M and 5 mM concentration. The hydrolysis rate of 1 M urea in the buffer-free solution by silochrome-immobilized urease is practically independent of pH within 4.5-6.5. Application of a 2.5 mM phosphate-citrate buffer as a solvent causes an increase in the hydrolysis rate within this pH range. For a soluble urease the 1 M urea hydrolysis rate dependence on pH is ordinary at pH 5.8-6.0. If the substrate concentration is 5 mM, the pH-dependences for the rate of the urea hydrolysis by silochrome- and aerosil-immobilized urease are close and at pH above 6.0 coincide with those for a soluble enzyme. The found differences in the properties of soluble and immobilized ureases are explained by the substrate and reaction products diffusion.     

Effect of exercise and adrenal insufficiency on urea production in rats

Experiments on Wistar rats were designed to study the effect of exercise on urea production in the liver of intact and adrenalectomized rats. The urea production rate was assessed by the¹⁴C-urea content in liver tissue after administration of NaH¹⁴CO₃. In intact rats swimming caused increases in¹⁴C-urea content in the liver compared to the resting concentrations in intact control rats: by 45% after 30 min of swimming carrying an additional load of 10% body mass by, 35% after 3 h of swimming without an additional load and by 103% after 10 h of swimming. Concentrations of urea in liver and blood were elevated simultaneously. The specific activity of¹⁴C-urea did not change significantly as a result of the exercise performed. In adrenalectomized rats the basal rate of urea production was reduced by an insignificant amount, but swimming for 3 h resulted in a decrease in liver¹⁴C-urea (by 24%). The results confirmed the exercise-induced increase in urea production and indicated as essential role for adrenal hormones in this response.     

Amidase and urease activities in plants

Summary Foliar fertilization has received considerable attention in recent years. Because of the importance of amides and urea as N sources, this work was carried out to study the enzymes that catalyze the hydrolysis of these compounds in plant leaves. The methods developed for assay of these enzymes in plants involve determination by steam distillation of the NH₄ ⁺–N produced by amidase or urease activity when plant materials are incubated at 37°C with buffered (0.1M THAM pH 8.0) amide solution or buffered (0.1M THAM pH 7.5) urea solution, respectively. Amidase and urease were detected in 21 diverse plants in the families of Gramineae and Leguminosae. Results showed that amidase and urease have optimum activities at buffer pH values of 8.0 and 7.5, respectively. Both amidase and urease activities were decreased significantly upon freezing or air-drying of plant samples before enzyme assay. These differences were proportional to the original activities of fresh plant materials. Studies on the effect of temperature on amidase and urease activities showed that these enzymes are inactivated at temperatures above 60 and 70°C, respectively. The energy of activation of the reaction catalyzed by amidase and urease in plants, expressed in kJ·mole^–1, ranged from 44.0 to 51.2 (avg.=47.1) and from 43.1 to 56.5 (avg.=51.2) when formamide and urea were used as substrates, respectively. The apparent K_m constants of these enzymes varied among the plant samples studied. By using the Lineweaver-Burk plot, the K_m values for amidase when formamide was used as a substrate ranged from 2.0 to 9.4 (avg.=5.8 mM) and for urease ranged from 0.4 to 1.6 (avg.=0.8 mM). The V_max values of 7 plant samples, expressed in g of NH₄ ⁺–N produced/0.1 g of plant materials/2h, ranged from 137 to 514 for amidase and from 29 to 123 for urease. The importance of these enzymes in application of amides and urea to plant leaves is discussed.     

A Protocol for Conducting Rainfall Simulation to Study Soil Runoff

Rainfall is a driving force for the transport of environmental contaminants from agricultural soils to surficial water bodies via surface runoff. The objective of this study was to characterize the effects of antecedent soil moisture content on the fate and transport of surface applied commercial urea, a common form of nitrogen (N) fertilizer, following a rainfall event that occurs within 24 hr after fertilizer application. Although urea is assumed to be readily hydrolyzed to ammonium and therefore not often available for transport, recent studies suggest that urea can be transported from agricultural soils to coastal waters where it is implicated in harmful algal blooms. A rainfall simulator was used to apply a consistent rate of uniform rainfall across packed soil boxes that had been prewetted to different soil moisture contents. By controlling rainfall and soil physical characteristics, the effects of antecedent soil moisture on urea loss were isolated. Wetter soils exhibited shorter time from rainfall initiation to runoff initiation, greater total volume of runoff, higher urea concentrations in runoff, and greater mass loadings of urea in runoff. These results also demonstrate the importance of controlling for antecedent soil moisture content in studies designed to isolate other variables, such as soil physical or chemical characteristics, slope, soil cover, management, or rainfall characteristics. Because rainfall simulators are designed to deliver raindrops of similar size and velocity as natural rainfall, studies conducted under a standardized protocol can yield valuable data that, in turn, can be used to develop models for predicting the fate and transport of pollutants in runoff.     

Felinine stability in the presence of selected urine compounds

Summary. The stability of felinine, an amino acid present in feline urine, was investigated. Synthetic felinine was unstable in the urine of a selection of mammals. Felinine was found to stable in feline urine in which urea had been degraded. Synthetic felinine was found to react specifically with urea and did not react with urea analogues such as biuret or thiourea or other nucleophilic compounds such as ammonia which is more nucleophilic or acetamide and water which are less nucleophilic than urea. The reaction of urea and felinine was independent of pH over the range of 3–10. Urea did not react with N-acetyl-felinine suggesting a felinine N-terminal interaction with urea. Mass spectral analysis of the reaction products showed the presence of carbamylated felinine and fragmentation ions derived from carbamyl-felinine. The physiological relevance of felinine carbamylation is yet to be determined.     

Chemically modified siRNAs and miRNAs bearing urea/thiourea-bridged aromatic compounds at their 3′-end for RNAi therapy

We have developed chemically modified siRNAs and miRNAs bearing urea/thiourea-bridged aromatic compounds at their 3′-end for RNAi therapy. Chemically modified RNAs possessing urea/thiourea-bridged aromatic compounds instead of naturally occurring dinucleotides at the 3′-overhang region were easily prepared in good yields and were more resistant to nucleolytic hydrolysis than unmodified RNA. siRNAs containing urea or thiourea derivatives showed the desired knockdown effect. Furthermore, modified miR-143 duplexes carrying the urea/thiourea compounds in the 3′-end of each strand were able to inhibit the growth of human bladder cancer T24 cells.     

壳聚糖金属离子配合物吸附尿素性能研究

由于尿素吸附剂存在吸附容量低、吸附选择性差、生物相容性和血液相容性差等缺点,使人工肾和口服尿素吸附剂的应用受到限制．近几年,尿素吸附材料方面的研究进展较快,主要有：１９９０年,藤田良枝用活性炭作尿素吸附剂,吸附量为９０ｍｇ／ｇ（尿素初始浓度为２１００ｍｇ／Ｌ）,吸附容量低,且微炭粒易脱落,有造成栓塞的危险,不宜作人工肾材料［１］;１９９３年,何炳林等用交联聚丙烯酸固载化氧化β环糊精作尿素吸附材料,吸附容量较高,为８２１ｍｇ／ｇ（尿素的初始浓度为１３００ｍｇ／Ｌ）．由于其利用的是Ｓｃｈｉｆｆ…