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.     

Repression of urease biosynthesis in Neurospora crassa by ammonium ions]

The regulation of the synthesis of the enzyme urease (urea amido hydrolase E.C. 3.5.1.5.) in Neurospora crassa was investigated. The biosynthesis of urease is repressed by ammonium ions. Under ammonium excess conditions the specific activity of urease decreases from 0.980 to 0.180 mumoles NH3/min/mg protein. By addition of cycloheximide it was shown that ammonia influences the synthesis of this enzyme. Enzyme induction by the substrate could be excluded. Even under the conditions of highest repression a specific activity of urease of 0.180 mumoles NH3/min/mg protein was measured. Possible causes of this constitutive enzyme level are discussed.     

Evidence for urea cycle activity in Sporosarcina ureae

Sporosarcina ureae BS 860, a motile, sporeforming coccus, possesses the enzymes required for a functioning urea (ornithine) cycle. This is only the second known example of urea cycle activity in a prokaryote. Specific activities are reported for ornithine carbamoyltransferase, argininosuccinase, arginase, and urease. Although argininosuccinate synthetase activity could not be detected directly in crude cell extracts, indirect evidence from radiocarbon tracing data for arginine synthesis from the substrate, l-[1-¹⁴C]-ornithine, strongly suggest the presence of this or other similar enzyme activity. Furthermore, good growth in defined media containing either 1.0% glutamine, ornithine, or citrulline as sole carbon sources suggests argininosuccinate synthetase activity is necessary for arginine synthesis. The effect of varying pH on arginase and urease activities indicate that these two enzymes may function within the context of the urea cycle to generate ammonia for amino acid synthesis, as well as for raising the pH of the growth micro-environment.     

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.     

Molecular biology of microbial ureases.

Urease (urea amidohydrolase; EC 3.5.1.5) catalyzes the hydrolysis of urea to yield ammonia and carbamate. The latter compound spontaneously decomposes to yield another molecule of ammonia and carbonic acid. The urease phenotype is widely distributed across the bacterial kingdom, and the gene clusters encoding this enzyme have been cloned from numerous bacterial species. The complete nucleotide sequence, ranging from 5.15 to 6.45 kb, has been determined for five species including Bacillus sp. strain TB-90, Klebsiella aerogenes, Proteus mirabilis, Helicobacter pylori, and Yersinia enterocolitica. Sequences for selected genes have been determined for at least 10 other bacterial species and the jack bean enzyme. Urease synthesis can be nitrogen regulated, urea inducible, or constitutive. The crystal structure of the K. aerogenes enzyme has been determined. When combined with chemical modification studies, biophysical and spectroscopic analyses, site-directed mutagenesis results, and kinetic inhibition experiments, the structure provides important insight into the mechanism of catalysis. Synthesis of active enzyme requires incorporation of both carbon dioxide and nickel ions into the protein. Accessory genes have been shown to be required for activation of urease apoprotein, and roles for the accessory proteins in metallocenter assembly have been proposed. Urease is central to the virulence of P. mirabilis and H. pylori. Urea hydrolysis by P. mirabilis in the urinary tract leads directly to urolithiasis (stone formation) and contributes to the development of acute pyelonephritis. The urease of H. pylori is necessary for colonization of the gastric mucosa in experimental animal models of gastritis and serves as the major antigen and diagnostic marker for gastritis and peptic ulcer disease in humans. In addition, the urease of Y. enterocolitica has been implicated as an arthritogenic factor in the development of infection-induced reactive arthritis. The significant progress in our understanding of the molecular biology of microbial ureases is reviewed.     

Urease formation in purple sulfur bacteria (Chromatiaceae) grown on various nitrogen sources

Batch cultures of Thiocapsa roseopersicina strain 6311, Thiocystis violacea strain 2311 and Chromatium vinosum strain 1611, grown anaerobically in the light on sulfide with urea, ammonia, N₂ or casein hydrolysate as nitrogen source exhibited urease activity, while Chromatium vinosum strain D neither showed any degradation of urea nor urease activity on any of the nitrogen sources tested.In T. violacea and C. vinosum strain 1611 urease was little affected by the nitrogen source and seemed to be constitutive. In T. roseopersicina, however, the enzyme was repressed by ammonia (although a low basal level of activity remained) and, to a lesser degree, induced by urea: The presense of urea stimulated a temporary increase in urease activity in the early exponential growth phase. The highest activities, however, were found after growth on N₂, and especially on 0.1% casein hydrolysate (in the absence or after exhaustion of external ammonia), but not before the stationary growth phase was reached. Derepressed urease synthesis required an efficient external source of nitrogen.In cultures of T. roseopersicina urease activity showed a periodic oscillation which depended on the repeated feeding with sulfide and subsequent variation in the sulfur content of the cells. The possible reasons of this oscillation are discussed.     

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.     

The role of nickel in urea assimilation by algae

Nickel is required for urease synthesis by Phaeodactylum tricornutum and Tetraselmis subcordiformis and for growth on urea by Phaeodactylum. There is no requirement for nickel for urea amidolyase synthesis by Chlorella fusca var. vacuolata. Neither copper nor palladium can substitute for nickel but cobalt partially restored urease activity in Phaeodactylum. The addition of nickel to nickel-deficient cultures of Phaeodactylum or Tetraselmis resulted in a rapid increase of urease activity to 7–30 times the normal level; this increase was not inhibited by cycloheximide. It is concluded that nickel-deficient cells over-produce a non-functional urease protein and that either nickel or the functional urease enzyme participates in the regulation of the production of urease protein.Abbreviation UALase ATP; urea amidolyase     

Hydrolysis of urea by Ureaplasma urealyticum generates a transmembrane potential with resultant ATP synthesis.

When urea is added to Ureaplasma urealyticum, it is hydrolysed internally by a cytosolic urease. Under our measuring conditions, and at an external pH of 6.0, urea hydrolysis caused an ammonia chemical potential equivalent to almost 80 mV and, simultaneously, an increase in proton electrochemical potential (delta p) of about 24 mV with resultant de novo ATP synthesis. Inhibition of the urease with the potent inhibitor flurofamide abolished both the chemical potential and the increase of delta p such that ATP synthesis was reduced to approximately 5% of normally obtained levels. Uncouplers of electrochemical gradients had little or no effect on these systems. The electrochemical parameters and ATP synthesis were measured similarly at three other external pH values. Any change in delta p was primarily via membrane potential (delta psi), and the level of de novo ATP synthesis was related to the increase in delta p generated upon addition of urea and more closely to the ammonia chemical potential. Although the organisms lack an effective mechanism for internal pH homeostasis, they maintained a constant delta pH. The data reported are consistent with, and give evidence for, the direct involvement of a chemiosmotic mechanism in the generation of around 95% of the ATP by this organism. Furthermore, the data suggest that the ATP-generating system is coupled to urea hydrolysis by the cytosolic urease via an ammonia chemical potential.     

Urea metabolism in isolated perfused lungs of the laboratory rat and of a desert rodent, Notomys alexis

1. Using the isolated perfused lung preparation we have demonstrated a low-activity ureolytic enzyme present in rodent lung tissue. The enzyme shares four characteristic features with jack bean urease (EC 3.5.1.5). 2. Ureolytic activity was inhibited by fluoride ions and methionine hydroxamic acid; using the latter inhibitor, the I50 value and maximum inhibition were similar to those reported for jack bean urease. The apparent Km for rat lung urease was similar to the plasma urea level. 3. The low level of urease activity in the rat lung and in that of Notomys alexis, a desert rodent, suggests that the enzyme is not involved in urea excretion, rather that pulmonary ammonia production may influence fluid balance at the alveolus.     

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.     

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.     

Anabolic and catabolic enzymes of urea metabolism in a carbohydrate-utilizing strain of Candida guilliermondii]

The yeast "H" of the genus Candida guilliermondii can grow on hydrocarbons as the only source for carbon. Urea can serve as a nitrogen source for this yeast which lacks detectable urease activity. During urea metabolism ammonia has never been accumulated in the culture medium. However, transferring the yeast from complete urea-medium into an urea containing phophate-buffer, the degradation of urea continues and ammonia is accumulated as well as CO2 evolved. In cell-free extracts of the yeast urea amidolyase activity was detected in the presence of ATP, biotin and specific cations. Obviously, the synthesis of urea amidolyase is induced by urea and arginine and repressed by the catabolite ammonia. Similarly the synthesis of arginase is regulated by arginine and ammonia. The analytical data of the arginase action differ significantly in relation to the carbon source of the culture medium. Both the level of arginase and ornithine carbamyl-transferase change in a characteristic way during the batch-culture. From the lower level of arginase in relation to ornithine carbamyltransferase it can be concluded that especially in alkane-metabolizing yeast the arginine catabolism is not very intensive.     

The molecular processes of urea hydrolysis in relation to ammonia emissions from agriculture

Ammonia emissions from the agricultural sector give rise to numerous environmental and societal concerns and represent an economic challenge in crop farming, causing a loss of fertilizer nitrogen. Ammonia emissions from agriculture originate from manure slurry (livestock housing, storage, and fertilization of fields) as well as urea-based mineral fertilizers. Consequently, political attention has been given to ammonia volatilization, and regulations of ammonia emissions have been implemented in several countries. The molecular cause of the emission is the enzyme urease, which catalyzes the hydrolysis of urea to ammonia and carbonic acid. Urease is present in many different organisms, encompassing bacteria, fungi, and plants. In agriculture, microorganisms found in animal fecal matter and soil are responsible for urea hydrolysis. One strategy to reduce ammonia emissions is the application of urease inhibitors as additives to urea-based synthetic fertilizers and manure slurry to block the formation of ammonia. However, treatment of the manure slurry with urease inhibitors is associated with increased livestock production costs and has not yet been commercialized. Thus, development of novel, environmentally friendly and cost-effective technologies for ammonia emission mitigation is important. This mini-review describes the challenges associated with the volatilization of ammonia in agriculture and provides an overview of the molecular processes of urea hydrolysis and ammonia emissions. Different technologies and strategies to reduce ammonia emissions are described with a special focus on the use of urease inhibitors. The mechanisms of action and efficiency of the most important urease inhibitors in relation to agriculture will be briefly discussed.     

Purification and properties of glutamine synthetase from liver of Squalus acanthias

Ammonia assimilation for urea synthesis by liver mitochondria in marine elasmobranchs involves, initially, formation of glutamine which is subsequently utilized for mitochondrial carbamoyl phosphate synthesis [P. M. Anderson and C. A. Casey (1984) J. Biol. Chem. 259, 456-462]. The purpose of this study was to determine if the glutamine synthetase catalyzing this first step in urea synthesis has properties uniquely related to this function. Glutamine synthetase has been highly purified from isolated liver mitochondria of Squalus acanthias, a representative elasmobranch. The purified enzyme has a molecular weight of approximately 400,000 in the presence of Mg2+, MgATP, and L-glutamate, but dissociates reversibly to a species with a molecular weight of approximately 200,000 in the absence of MgATP and L-glutamate. Association with the glutamine- and acetylglutamate-dependent carbamoyl phosphate synthetase, also located in the mitochondria, could not be demonstrated. The subunit molecular weight is approximately 46,000. The pH optimum of the biosynthesis reaction is 7.1-7.4. The purified enzyme is stabilized by MgATP and glutamate and by ethylene glycol, and is activated by 5-10% ethylene glycol. The apparent Km values for MgATP, L-glutamate, and ammonia (NH4+-NH3) are 0.7, 11.0, and 0.015 mM, respectively. Mg2+ in excess of that required to complex ATP as MgATP is required for maximal activity; Mn2+ cannot replace Mg2+. The enzyme is activated by low concentrations of chloride, bromide, or iodide; this effect appears to be related to decreases in the apparent Km for glutamate. The enzyme is inhibited by physiological concentrations of urea, but is not significantly affected by physiological concentrations of trimethylamine-N-oxide. Except for activation by halogen anions and the very low apparent Km for ammonia, this elasmobranch glutamine synthetase has properties similar to those reported for mammalian and avian glutamine synthetases. The very low apparent Km for ammonia may be specifically related to the unique role of this glutamine synthetase in mitochondrial assimilation of ammonia for urea synthesis.     

Regulation of urea-uptake in the cyanobacterium Anabaena doliolum

Abstract The utilization of urea was studied in the cyanobacterium Anabaena doliolum . The uptake of urea was unaltered in the presence of ammonium. The cells receiving ATP exogenously showed an induced level of urea-uptake as compared with the control cells. Urease inhibitor acetohydroxamic acid and hydroxyurea as well as glutamate analogue, MSO, did not affect the uptake of urea. These results suggest: (1) urea and ammonia have different uptake sites, (2) urea-uptake is an energy dependent process, and (3) during short-term experiments, urea uptake is not linked with the enzyme urease or the ammonium assimilating enzyme glutamine synthetase.     

Urease from Arthrobacter oxydans,a nickel-containing enzyme

In Arthrobacter oxydans, Klebsiella aerogenes and Sporosarcina ureae, growth with urea as a nitrogen source turned out to be more sensitive to inhibition by EDTA than that with ammonia. The inhibition was overcome by added nickel chloride, but not by other divalent metal ions tested. In A. oxydans the uptake of ⁶³Ni was paralleled by an increase in urease (urea amidohydrolase, EC 3.5.1.5) activity under certain conditions. Following growth with radioactive nickel, urease from this strain was enriched by heat treatment and acetone fractionation. Copurification of ⁶³Ni and urease was observed during subsequent Sephadex gel chromatography. Almost the entire labelling was detected together with the purified enzyme after focusing on polyacrylamide gel. The relative molecular mass of the purified urease was estimated to be 242,000. The pH optimum was 7.6, the K _m-value 12.5 mmol/l and the temperature optimum 40°C; heat stability was observed up to 65°C. In presence of 10 mmol/l EDTA the protein-nickel binding remained intact at pH 7; at pH 5 and below, nickel was irreversibly removed with concommitant loss of enzyme activity. The results demonstrated that nickel ions are required for active urease formation in the bacterial strains studied, and that urease from A. oxydans is a nickel-containing enzyme.Dedicated to Professor Dr. H.-G. Schlegel on the occasion of his 60th birthday     

Effect of Urease-Induced Hyperammonemia on Metabolism of Guanidino Compounds

We previously reported that guanidino compounds produced by the catabolism of arginine play an important role in the pathophysiology of acute hyperammonemia. In order to understand the metabolism of guanidino compounds during sustained hyperammonemia, we investigated the effect of intraperitoneal urease injection (800 IU/kg) on the levels of guanidino compounds in blood, liver, kidney, and brain of rats. Control rats received an equal volume of saline. Eight hours following injection, rats were sacrificed and blood and tissues were removed. Ammonia and urea were determined by enzymatic and colorimetric assays, respectively. Guanidino compounds were analyzed by high-performance liquid chromatography. Blood and tissue ammonia were significantly increased and urea decreased in urease-treated animals. Blood and kidney arginine levels were significantly decreased although hepatic arginine was increased following urease injection. Elevated hepatic arginine may be due to the rapid conversion of urea to ammonia by urease and the development of a futile urea cycle. Catabolites produced by the transamidination of arginine were significantly decreased in the blood, liver, kidney, and brain of urease-treated rats, whereas acetylation of hepatic arginine to α-N-acetylarginine was increased. Blood and tissue guanidinosuccinic acid levels were not elevated during urease induced hyperammonemia, supporting the hypothesis that urea is a precursor for the synthesis of guanidinosuccinic acid.     

Some observations on the urea-degrading enzyme of the diatom Cyclotella cryptica and the role of nickel in its production

The urea-degrading enzyme of Cyclotella cryptica was testedin crude cell-free extracts for effects from chemical reagentsknown to distinguish between urease and ATP:urea amidolyase.Inhibition of the enzyme by hydroxyurea and its indifferenceto added ATP, Mg²⁺ or K⁺ avidin or biotin clearly characterizedthe enzyme as urease (EC 3.5.1.5 [EC] ). The Cyclotella urease wasunaffected by thiourea addition, as was also the growth of thediatom in the presence of this substrate analogue. Indirectevidence was obtained from growth studies of the diatom andcorresponding urease production showing that the enzyme: (i)contains Ni²⁺ tightly bound to an apoprotein; (ii) is producedconstitutively even from growth on nitrate and does not requireextracellular urea for its synthesis, although quantitativelythe activity is greatest from growth on urea. It is concludedthat Cyclotella urease is a Ni²⁺ constitutive enzyme similarin many respects to those previously reported from Phaeodactylumtricornutwn and Tetraselmis maculata.     

Purification and properties of urease from the leaf of mulberry, Morus alba

Urease was purified from leaves of mulberry (Morus alba, L.) by ammonium sulfate fractionation, acetone fractionation and sequential column chromatography including Q-Sepharose HP, Phenyl-Sepharose HP, Superdex 200 HR and Mono Q. The enzyme was purified 5700-fold to apparent homogeneity with a recovery of 3.6%. The molecular mass of the enzyme was determined to be 90.5 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis and 175 kDa by gel filtration, indicating that the enzyme was a homodimer. In the western blot analysis, 90.5 kDa subunit of the mulberry leaf urease cross-reacted with antiserum raised against jack bean seed urease. The N-terminal sequence of the first 20 residues of the enzyme revealed that it has a high similarity (80-90%) to ureases from other plant sources, suggesting that the mulberry leaf urease is closely related to other plant ureases. However, the mulberry leaf enzyme showed an optimum pH for activity of 9.0, while the optimum pH of most ureases isolated from plants and bacterial is neutral. In addition, the K(m) value for urea was 0.16 mM, which is lower than those of ureases from other sources. It is also proposed that urease activity ingested by browsing silkworm releases ammonia that is subsequently used in silkworm protein synthesis.