Urease-negative uropathogen Kalamiella piersonii YU22 metabolizes urea by urea carboxylase and allophanate hydrolase enzyme system.

Urea is one of the major components of the human urine and its breakdown by the uropathogens occurs mainly through the activity of the enzyme urease. However, a few reports suggest the presence of an alternate enzyme system for urea breakdown namely urea carboxylase (UC) and allophanate hydrolase (AH). We have previously reported the UC and AH system in the genome of a urease-negative uropathogen Kalamiella piersonii YU22 of the novel genus Kalamiella (reclassified recently as Pantoea).To validate the UC and AH activity in the presence of urea, we investigated the growth and urea utilization patterns of this bacterium. Growth kinetics, variations in media pH, NH4-N generation and UC and AH gene expressions were probed using urea-containing media. YU22 was able to grow in M9 media containing urea and increase the pH of the media due to the urea breakdown. Further, significantly higher concentrations of extracellular NH4-N (p < 0.001) was also detected in the cultures along with over-expression of UC and AH genes. The bacterium formed biofilm, and displayed swimming and swarming motilities in presence of urea. Additional glucose supply to urea boosted the colonization but ameliorated the media alkalization and ammonification through suppression of gene expressions encoding UC and AH. These results show that the urease-negative strain YU22 can utilize the UC and AH system for urea metabolism. We propose to further investigate the UC and AH system in other urease-negative uropathogens and its implications for pathogenicity and urinary tract colonization.

Discovery of a widespread prokaryotic 5-oxoprolinase that was hiding in plain sight.

5-Oxoproline (OP) is well-known as an enzymatic intermediate in the eukaryotic γ-glutamyl cycle, but it is also an unavoidable damage product formed spontaneously from glutamine and other sources. Eukaryotes metabolize OP via an ATP-dependent 5-oxoprolinase; most prokaryotes lack homologs of this enzyme (and the γ-glutamyl cycle) but are predicted to have some way to dispose of OP if its spontaneous formation in vivo is significant. Comparative analysis of prokaryotic genomes showed that the gene encoding pyroglutamyl peptidase, which removes N-terminal OP residues, clusters in diverse genomes with genes specifying homologs of a fungal lactamase (renamed prokaryotic 5-oxoprolinase A, pxpA) and homologs of allophanate hydrolase subunits (renamed pxpB and pxpC). Inactivation of Bacillus subtilis pxpA, pxpB, or pxpC genes slowed growth, caused OP accumulation in cells and medium, and prevented use of OP as a nitrogen source. Assays of cell lysates showed that ATP-dependent 5-oxoprolinase activity disappeared when pxpA, pxpB, or pxpC was inactivated. 5-Oxoprolinase activity could be reconstituted in vitro by mixing recombinant B. subtilis PxpA, PxpB, and PxpC proteins. In addition, overexpressing Escherichia coli pxpABC genes in E. coli increased 5-oxoprolinase activity in lysates ≥1700-fold. This work shows that OP is a major universal metabolite damage product and that OP disposal systems are common in all domains of life. Furthermore, it illustrates how easily metabolite damage and damage-control systems can be overlooked, even for central metabolites in model organisms.

Crystal structure analysis of c4763, a uropathogenic Escherichia coli-specific protein.

Urinary-tract infections (UTIs), which are some of the most common infectious diseases in humans, can cause sepsis and death without proper treatment. Therefore, it is necessary to understand their pathogenicity for proper diagnosis and therapeutics. Uropathogenic Escherichia coli, the major causative agents of UTIs, contain several genes that are absent in nonpathogenic strains and are therefore considered to be relevant to UTI pathogenicity. c4763 is one of the uropathogenic E. coli-specific proteins, but its function is unknown. To investigate the function of c4763 and its possible role in UTI pathogenicity, its crystal structure was determined at a resolution of 1.45 Šby a multiple-wavelength anomalous diffraction method. c4763 is a homodimer with 129 residues in one subunit that contains a GGCT-like domain with five α-helices and seven ß-strands. c4763 shows structural similarity to the C-terminal domain of allophanate hydrolase from Kluyveromyces lactis, which is involved in the degradation of urea. These results suggest that c4763 might be involved in the utilization of urea, which is necessary for bacterial survival in the urinary tract. Further biochemical and physiological investigation will elucidate its functional relevance in UTIs.

The structure of allophanate hydrolase from Granulibacter bethesdensis provides insights into substrate specificity in the amidase signature family.

Allophanate hydrolase (AH) catalyzes the hydrolysis of allophanate, an intermediate in atrazine degradation and urea catabolism pathways, to NH(3) and CO(2). AH belongs to the amidase signature family, which is characterized by a conserved block of 130 amino acids rich in Gly and Ser and a Ser-cis-Ser-Lys catalytic triad. In this study, the first structures of AH from Granulibacter bethesdensis were determined, with and without the substrate analogue malonate, to 2.2 and 2.8 Å, respectively. The structures confirm the identity of the catalytic triad residues and reveal an altered dimerization interface that is not conserved in the amidase signature family. The structures also provide insights into previously unrecognized substrate specificity determinants in AH. Two residues, Tyr(299) and Arg(307), are within hydrogen bonding distance of a carboxylate moiety of malonate. Both Tyr(299) and Arg(307) were mutated, and the resulting modified enzymes revealed >3 order of magnitude reductions in both catalytic efficiency and substrate stringency. It is proposed that Tyr(299) and Arg(307) serve to anchor and orient the substrate for attack by the catalytic nucleophile, Ser(172). The structure further suggests the presence of a unique C-terminal domain in AH. While this domain is conserved, it does not contribute to catalysis or to the structural integrity of the core domain, suggesting that it may play a role in mediating transient and specific interactions with the urea carboxylase component of urea amidolyase. Analysis of the AH active site architecture offers new insights into common determinants of catalysis and specificity among divergent members of the amidase signature family.

Purification and characterization of TrzF: biuret hydrolysis by allophanate hydrolase supports growth.

TrzF, the allophanate hydrolase from Enterobacter cloacae strain 99, was cloned, overexpressed in the presence of a chaperone protein, and purified to homogeneity. Native TrzF had a subunit molecular weight of 65,401 and a subunit stoichiometry of alpha(2) and did not contain significant levels of metals. TrzF showed time-dependent inhibition by phenyl phosphorodiamidate and is a member of the amidase signature protein family. TrzF was highly active in the hydrolysis of allophanate but was not active with urea, despite having been previously considered a urea amidolyase. TrzF showed lower activity with malonamate, malonamide, and biuret. The allophanate hydrolase from Pseudomonas sp. strain ADP, AtzF, was also shown to hydrolyze biuret slowly. Since biuret and allophanate are consecutive metabolites in cyanuric acid metabolism, the low level of biuret hydrolase activity can have physiological significance. A recombinant Escherichia coli strain containing atzD, encoding cyanuric acid hydrolase that produces biuret, and atzF grew slowly on cyanuric acid as a source of nitrogen. The amount of growth produced was consistent with the liberation of 3 mol of ammonia from cyanuric acid. In vitro, TrzF was shown to hydrolyze biuret to liberate 3 mol of ammonia. The biuret hydrolyzing activity of TrzF might also be physiologically relevant in native strains. E. cloacae strain 99 grows on cyanuric acid with a significant accumulation of biuret.

Allophanate hydrolase, not urease, functions in bacterial cyanuric acid metabolism.

Growth substrates containing an s-triazine ring are typically metabolized by bacteria to liberate 3 mol of ammonia via the intermediate cyanuric acid. Over a 25-year period, a number of original research papers and reviews have stated that cyanuric acid is metabolized in two steps to the 2-nitrogen intermediate urea. In the present study, allophanate, not urea, was shown to be the 2-nitrogen intermediate in cyanuric acid metabolism in all the bacteria examined. Six different experimental results supported this conclusion: (i) synthetic allophanate was shown to readily decarboxylate to form urea under acidic extraction and chromatography conditions used in previous studies; (ii) alkaline extraction methods were used to stabilize and detect allophanate in bacteria actively metabolizing cyanuric acid; (iii) the kinetic course of allophanate formation and disappearance was consistent with its being an intermediate in cyanuric acid metabolism, and no urea was observed in those experiments; (iv) protein extracts from cells grown on cyanuric acid contained allophanate hydrolase activity; (v) genes encoding the enzymes AtzE and AtzF, which produce and hydrolyze allophanate, respectively, were found in several cyanuric acid-metabolizing bacteria; and (vi) TrzF, an AtzF homolog found in Enterobacter cloacae strain 99, was cloned, expressed in Escherichia coli, and shown to have allophanate hydrolase activity. In addition, we have observed that there are a large number of genes homologous to atzF and trzF distributed in phylogenetically distinct bacteria. In total, the data indicate that s-triazine metabolism in a broad class of bacteria proceeds through allophanate via allophanate hydrolase, rather than through urea using urease.

Purification and characterization of allophanate hydrolase (AtzF) from Pseudomonas sp. strain ADP.

AtzF, allophanate hydrolase, is a recently discovered member of the amidase signature family that catalyzes the terminal reaction during metabolism of s-triazine ring compounds by bacteria. In the present study, the atzF gene from Pseudomonas sp. strain ADP was cloned and expressed as a His-tagged protein, and the protein was purified and characterized. AtzF had a deduced subunit molecular mass of 66,223, based on the gene sequence, and an estimated holoenzyme molecular mass of 260,000. The active protein did not contain detectable metals or organic cofactors. Purified AtzF hydrolyzed allophanate with a k(cat)/K(m) of 1.1 x 10(4) s(-1) M(-1), and 2 mol of ammonia was released per mol allophanate. The substrate range of AtzF was very narrow. Urea, biuret, hydroxyurea, methylcarbamate, and other structurally analogous compounds were not substrates for AtzF. Only malonamate, which strongly inhibited allophanate hydrolysis, was an alternative substrate, with a greatly reduced k(cat)/K(m) of 21 s(-1) M(-1). Data suggested that the AtzF catalytic cycle proceeds through a covalent substrate-enzyme intermediate. AtzF reacts with malonamate and hydroxylamine to generate malonohydroxamate, potentially derived from hydroxylamine capture of an enzyme-tethered acyl group. Three putative catalytically important residues, one lysine and two serines, were altered by site-directed mutagenesis, each with complete loss of enzyme activity. The identity of a putative serine nucleophile was probed using phenyl phosphorodiamidate that was shown to be a time-dependent inhibitor of AtzF. Inhibition was due to phosphoroamidation of Ser189 as shown by liquid chromatography/matrix-assisted laser desorption ionization mass spectrometry. The modified residue corresponds in sequence alignments to the nucleophilic serine previously identified in other members of the amidase signature family. Thus, AtzF affects the cleavage of three carbon-to-nitrogen bonds via a mechanism similar to that of enzymes catalyzing single-amide-bond cleavage reactions. AtzF orthologs appear to be widespread among bacteria.

Expression of the ROAM mutations in Saccharomyces cerevisiae: involvement of trans-acting regulatory elements and relation with the Ty1 transcription.

The regulatory mutations in Saccharomyces cerevisiae designated cargA + Oh, cargB + Oh, and durOh are alterations in the control regions of the respective structural genes. The alteration causing the cargA + Oh mutation has been shown to be an insertion of a Ty1 element in the 5' noncoding region of the CAR1 ( cargA ) locus. All three mutations cause overproduction of their corresponding gene products and belong to the ROAM family of mutations (Regulated Overproducing Allele responding to Mating signals) in yeast. The amount of overproduction in ROAM mutants is determined, at least in part, by signals that control mating functions in yeast. We report the identification of two genetic loci that regulate Oh mutant gene expression but that do not affect mating ability. These loci are defined by the recessive roc mutations ( ROAM mutation control) that reduce the amount of overproduction caused by the cargA + Oh, cargB + Oh, and durOh mutations. RNAs homologous to CAR1 ( cargA ), DUR1 ,2 and Ty1 DNA probes were analyzed by the Northern hybridization technique. In comparison with wild-type strains, cargA + Oh and durOh mutant strains grown on ammonia medium contain increased amounts of CAR1 and DUR1 ,2 RNA. This RNA overproduction is diminished in MATa/MAT alpha diploid strains as well as in haploid strains that also carry the ste7 mutation which prevents mating or that carry either of the roc1 or roc2 mutant alleles. The amount of RNA homologous to Ty1 DNA is also reduced in ste7 , roc1 , and roc2 mutant strains. This reduction is not observed in a strain with the ste5 mutation, which prevents mating but has no effect on overproduction of ROAM mutant gene products.(ABSTRACT TRUNCATED AT 250 WORDS)

Structural analysis of the dur loci in S. cerevisiae: two domains of a single multifunctional gene.

In Saccharomyces cerevisiae, the degradation of urea to carbon dioxide and ammonia is catalyzed by urea carboxylase and allophanate hydrolase. The loci coding for these enzymes (dur1 and dur2) are very tightly linked on the right arm of chromosome II between pet11 and met8. Pleiotropic mutations that fail to complement mutations in either of the dur loci were found to be predominantly located in or near the dur2 locus. We interpret these data as suggesting that the two dur loci might in reality be domains of a single gene that codes for a multifunctional polypeptide. In view of this conclusion, we have renamed the dur loci as the dur1,2 locus.

The regulation of urea amidolyase of Saccharomyces cerevisiae: mating type influence on a constitutivity mutation acting in cis.

Constitutivity for the synthesis of the urea amidolyase bienzymatic complex is obtained by durOh mutations located in the regulatory genetic region adjacent to the dur1, dur2 gene cluster. The durOh mutations act only in cis and are a new case of cis effect strongly cancelled in alpha/a diploid, similar to cargA+Oh mutation shown previously to lead to arginase constitutivity. Illegitimate diploids do not show such a cancellation of constitutivity. The constitutivity produced by durOh mutation comprises the process of induction and the release of the glutamine effect. It does not impair the NH+4 effect.