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Metelitsa, D. I.; Тарун, Е. И.; Puchkaev, A. V.; Losev, Yu. P.

doi:10.1023/a:1002879815168

Cited by 5 publications

(9 citation statements)

References 12 publications

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“…It follows from Table 2 that ODH polydisulfide (poly(DSODH)) and cyclic triketones CTKs I-III are the most effective inhibitors of urea hydrolysis. K i values of these compounds are comparable with the values of inhibition constants K i of thiols, many derivatives of hydroxammic acid [8,23], and parameters of thiophosphamides previously measured in our experiments [6]. High inhibition efficacy of poly(disulfidoxalyldihydrazide) is determined by a large number of carbonyl groups in the polymer molecule (~28) and, perhaps, direct interaction of this polymer with urease subunits, the concentration of the enzyme in solution being three to four orders of magnitude lower than concentration of inhibitor.…”

Section: Resultssupporting

confidence: 89%

“…pH indicators suggested in [3] and successfully used in our earlier studies [6,9,20,21] is thought to provide the necessary high accuracy of measurement of the initial urea hydrolysis rate at low urease concentration when urease activity is suppressed by inhibitors.…”

Section: Methodsmentioning

confidence: 99%

“…The main groups of urease inhibitors, specificity and efficiency of urease activity were discussed in our earlier review [6]. It was found that urease was produced by many microorganisms and was associated with such pathologies as duodenal and gastric ulcers as well as a number of human and animal urinary diseases [5,7].…”

mentioning

confidence: 99%

“…In earlier studies, we investigated the following urease inhibitors: polydisulfides of urea and thiourea, which compete with the substrate for binding to the urease active sites; amides of thiophosphoric acid, which were analogues of the substituted phosphorodiamidates (these compounds were the most effective urease inhibitors [4][5][6]8]); cyclic β -triketones (CTKs); and fluoride anions. These inhibitors are organic and inorganic ligand chelators of nickel [9].…”

mentioning

confidence: 99%

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Inhibition of soybean urease by polycarbonyl compounds

2005

Appl Biochem Microbiol

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Soybean urease (EC 3.5.1.5) is a homohexameric enzyme (containing six subunits with molecular weights of 90770 Da and two nickel atoms each), which catalyzes urea hydrolysis by water, resulting in the formation of ammonium cations and carbonate anions [1]. Urease is widely used for determination of urea by bioanalytical methods and in immunoassays as an enzyme label for many antigens [2,3]. Despite the great importance of urease in biotechnology and medicine, the detailed mechanism of urea hydrolysis by urease is still not clarified, and the structure of the metal site, containing two nickel atoms, is not precisely known [1,4,5].An important tool for the investigation of the catalytic mechanism of urease is inhibition and activation of this enzyme. The main groups of urease inhibitors, specificity and efficiency of urease activity were discussed in our earlier review [6]. It was found that urease was produced by many microorganisms and was associated with such pathologies as duodenal and gastric ulcers as well as a number of human and animal urinary diseases [5,7]. It was also demonstrated that there was a clear correlation between the inhibiting properties of the same compounds with respect to various ureases of microbial and plant origin. Therefore, the primary screening of potential inhibitors for urease can be performed more easily and quickly using catalytically active and thermally stable soybean urease [4,5,8].In earlier studies, we investigated the following urease inhibitors: polydisulfides of urea and thiourea, which compete with the substrate for binding to the urease active sites; amides of thiophosphoric acid, which were analogues of the substituted phosphorodiamidates (these compounds were the most effective urease inhibitors [4-6, 8]); cyclic β -triketones (CTKs); and fluoride anions. These inhibitors are organic and inorganic ligand chelators of nickel [9]. An important advantage of CTKs and fluoride anions is that they are nontoxic. It is obvious that the range of polycarbonyl compounds (PCCs), potential chelators of nickel ions, should be widened, and nickel ligands of polycarbonyl structure should be tested as urease inhibitors within a broad pH range, because the value of the inhibition constant for urease inhibition by fluoride anions significantly increases due to pH variation within the range from 3.85 to 6.45 [9]. This factor is particularly important for practical purposes because of the acidity of gastric medium in humans and animals.The practical aspect of this work is associated with selection of effective urease inhibitors for use as chemotherapeutical agents in gastroenterology and stopreagents in biochemical assay of urea (enzyme immunoassay and biosensors).The goal of this work was a comparative kinetic study of soybean urease inhibition by such organic chelators of nickel as polycarbonyl compounds, including oxalyldihydrazide (ODH), with two carbonyl groups, cyclic triketones I -VII with three carbonyl groups, and poly(disulfide-oxalyldihydrazide (poly(DSODH)) with 28 carbonyl gro...

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Section: Resultssupporting

confidence: 89%

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Inhibition of soybean urease by polycarbonyl compounds

2005

Appl Biochem Microbiol

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“…For example, urease serves as a virulence factor in pathogens that are responsible for the development of kidney stones, pyelonephritis, peptic ulcers, and other disease states [4,5]. Therefore, urease inhibition studies have attracted increasing attention [6][7][8][9], and the numerous urease inhibitors have been recently reported [10][11][12][13][14][15][16][17]. For example, thiolic compounds, in which thiolate anions react directly with the metallocenters of ureases [18,19].…”

Section: Introductionmentioning

confidence: 99%

Synthesis, crystal structure, and urease inhibition studies of copper(II) and cobalt(III) complexes with bi(2-fluorobenzylaminoethyl)amine

Dong

et al. 2011

Transition Met Chem

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Three new mononuclear Cu(II) and Co(III) complexes [Cu(L)Cl]ClO 4 (1), [Cu(L)Cl(SCN)] (2), and [Co(L)(N 3 ) 3 ] (3), where L is a reduced Schiff-base ligand bi(2-fluorobenzylaminoethyl)amine, were synthesized and characterized. X-ray crystallographical analysis reveals that the Cu(II) atom adopts a square-planar environment in complex 1, while the geometry in 2 can be described as distorted square-pyramidal. The Co(III) atom in 3 is in a distorted octahedral geometry. Three complexes were investigated for their inhibitory activities in vitro against jack bean urease. The Cu(II) complexes 1 and 2 were found to have excellent inhibitory activities. The Co(III) complex 3 was also shown to have activity comparable to that of acetohydroxamic acid.

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Inhibition of soybean urease by triketone oximes

Тарун

Rubinov

Metelitza

2004

Biochemistry (Moscow)

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Competitive inhibition of soybean urease by 15 triketone oximes has been studied at 36 degrees C in aqueous solution (pH 4.95). The studied oximes are supposed chelators for the nickel atom in the urease metallocenter. The inhibition constants of urea hydrolysis (K(i)) varied in the range 2.7-248 microM depending on the oxime structure. Analysis of this dependency demonstrates that the optimal inhibitor is the one containing carbonyl group in position 1 of the cycle, the ethoxyimino group and alkyl residue in the substituent in position 2, as well as the methoxycarbonyl group in position 4 of the cycle.

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Cited by 5 publications

References 12 publications

Inhibition of soybean urease by polycarbonyl compounds

Inhibition of soybean urease by polycarbonyl compounds

Synthesis, crystal structure, and urease inhibition studies of copper(II) and cobalt(III) complexes with bi(2-fluorobenzylaminoethyl)amine

Inhibition of soybean urease by triketone oximes

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