Light-driven periodic changes in urocanase activity of a heterotrophic bacterium

Summary Urocanase activity in Pseudomonas putida cells showed periodic changes corresponding to a light-dark cycle. Apparent interconversion of the active and inactive forms of urocanase was accomplished by photoactivation by nearultraviolet light and by dark thermal inactivation. The purified enzyme exhibited similar behavior. This system suggests a possible molecular basis for an hour-glass timer. Photoinactivation by light of 290 nm alternated with photoactivation at 340 nm also generated regular changes in urocanase activity.     

Identification of the prosthetic group of urocanase. The mode of its reaction with sodium borohydride and of its photochemical reactivation.

Urocanase from Pseudomonas putida and from beef liver were isolated by modifying described procedures. Both enzymes were inactivated and labeled on treatment with tritiated sodium borohydride and gave, upon subsequent hydrolysis, a radioactive acid. The previously reported identity of this acid as 2-hydroxybutanoic acid was disproved by several criteria. Other hydroxy acids were also proved to be different from the radioactive acid derived from urocanase. A large portion of the radioactive material from P. putida was found to be nicotinic acid by 1H NMR spectroscopy, gas-liquid chromatography of its methyl ester, and co-crystallization with authentic reference compounds both as the acid and as the hydrazide. A significant portion of the radioactive material derived from beef liver urocanase also co-crystallized with nicotinic acid. Sodium borohydride-treated inactive urocanase was partially reactivated by light. The action spectrum of the photoreactivation showed a maximum at 330 nm. Treatment of urocanase with sodium borodeuteride followed by hydrolysis afforded a sample of nicotinic acid which carried deuterium mainly in position 6. Both the reversible reducibility of urocanase and its action spectrum of photoreactivation suggest that urocanase contains an enzyme-bound nicotinamide nucleotide molecule which is essential for enzymic activity.     

Roles of cysteine sulfinate and transaminase on in vitro dark reversion of urocanase in Pseudomonas putida.

Urocanase is inactivated in intact cells of Pseudomonas putida and photoactivated by brief exposure of the cells to the UV radiation in sunlight. The dark reversion (inactivation) in vitro is explained by the formation of a sulfite-NAD adduct. Our objective was to investigate the dark reversion in vivo. Various compounds were added to P. putida cells, and the reversion was measured, after sonication, by comparison of the activity before and after UV irradiation. Sulfite, cysteine sulfinate, and hypotaurine enhanced the reversion of urocanase in resting cells. The reversion was time and concentration dependent. Sulfite modified the purified enzyme, but cysteine sulfinate and hypotaurine could not, indicating that those two substances had to be metabolized to support the reversion. Both of those compounds yielded sulfite when they were incubated with cells. Transaminases form sulfite from cysteine sulfinate. P. putida extract contained a transaminase whose activity involved as alpha-keto acid and either cysteine sulfinate or hypotaurine for (i) production of sulfite, (ii) disappearance of substrates, (iii) formation of corresponding amino acids, and (iv) urocanase reversion. Porcine crystalline transaminase caused reversion of highly purified P. putida urocanase with cysteine sulfinate and alpha-ketoglutarate. We conclude that in P. putida cysteine sulfinate or hypotaurine is catabolized in vivo by a transaminase reaction to sulfite, which modifies urocanase to a form that can be photoactivated. We suggest that this photoregulatory process is natural because it occurs in cells with the aid of sunlight and cellular metabolism.     

Activation of urocanase from Pseudomonas putida by electronically excited triplet species

Urocanase from Pseudomonas putida becomes inactive in growing and resting cells and, as shown previously, is activated by the direct absorption of ultraviolet light. In this study, we describe the activation of urocanase by energy transfer from triplet indole-3-aldehyde, generated in the peroxidase-catalyzed aerobic oxidation of indole-3-acetic acid. The activation was time-, temperature-, and pH-dependent. The involvement of reactive oxygen intermediates was excluded by the lack of effect of appropriate quenchers and traps. Triplet quenchers, in contrast, reduced the level of activation. Photoexcited rose bengal, a triplet species of a different nature and origin, was also effective in promoting activation. These results demonstrate a potential mechanism of urocanase regulation not dependent on an environmental source of light, but rather brought about by an enzymically generated excited species.     

The stoichiometry of the tightly bound NAD+ in urocanase. Separation and characterization of fully active and inhibited forms of the enzyme

1. Urocanase, purified by classical methods [Keul, V., Kaeppeli, F., Ghosh, C., Krebs, T., Robinson, J. A. and Rétey, J. (1979) J. Biol. Chem. 254, 843-851] from Pseudomonas putida was submitted to high-performance liquid chromatography on a TSK-DEAE column. The enzyme was eluted in three resolved peaks (A, B and C) exhibiting specific activities of 3.4 U/mg, 1.85 U/mg and 0.4 U/mg, respectively. 2. The difference spectra of peaks B and A as well as of C and A showed maxima at 330 nm. 3. Irradiation of peaks B and C at 320 nm resulted in an increase of urocanase activity by 45% and 400%, respectively. Peak A could not be photoactivated. Rechromatography of the photoactivated peaks B and C on the TSK-DEAE column confirmed their partial transformation into peak A. 4. Spectroscopic methods for quantitative protein determination were adapted to urocanase. The stoichiometry of bound NAD+/urocanase (form A) was determined to be 1.75 by enzymic analysis of the free NAD+ released upon acid denaturation of the holoenzyme. A similar stoichiometry (1.8-1.9) was found for all three forms (A, B and C) by biosynthetic incorporation of [7-14C]nicotinate into urocanase using a nicotinate auxotrophic mutant of P. putida. 5. Form A of urocanase showed, after treatment with NaBH4 up to 50% inhibition, an elution pattern (TSK-DEAE column) similar to a mixture of forms A, B and C in the approximate ratio of 1:2:1. None of these forms could be photoactivated. 6. We conclude that form A of the urocanase dimer contains two intact NAD+ molecules. In form B one of the two subunits contains an NAD+-nucleophile adduct which is present in both subunits of form C. Full urocanase activity requires intact NAD+ in both subunits. Intact NAD+ can be regenerated from the adduct but not from the reduced form by photolysis. The two subunits of urocanase are independent both in their catalytic activity and in modification reactions.     

Allantoin racemase: a new enzyme from Pseudomonas species.

1. Allantoin racemase is a novel enzyme which catalyzes the conversion of S(+)-and R(minus)-allantoin into the racemate. 2. The enzyme is present in Pseudomonas testosteroni, Pseudomonas putida and five biotypes of Pseudomonas fluorescens, but absent in a number of other Pseudomonas species. 3. The enzyme of Ps. testosteroni was purified 133-fold and exposes optimal activity at pH 8.0-8.2 and 50 degrees C. The enzyme is stable on heating for 15 min at 70 degrees C. 4. The enzyme appeared to be specific for the optical isomers of allantoin and no cofactors are involved in the reaction. 5. The optical aspecificity of allantoinase of Proteus rettgeri was reaffirmed.     

The control of the enzymes degrading histidine and related imidazolyl derivatives in Pseudomonas testosteroni

1. The induction of the enzymes for the degradation of l-histidine, imidazolylpropionate and imidazolyl-l-lactate in Pseudomonas testosteroni was investigated. 2. The activities of histidine ammonia-lyase, histidine-2-oxoglutarate aminotransferase and urocanase are consistent with these enzymes being subject to co-ordinate control under most growth conditions. However, a further regulatory mechanism may be superimposed for histidase alone under conditions where degradation of histidine must take place for growth to occur. 3. Experiments with a urocanase(-) mutant show that urocanate is an inducer for the enzymes given above and also for N-formiminoglutamate hydrolyase and N-formylglutamate hydrolase. 4. N-Formiminoglutamate hydrolase and N-formylglutamate hydrolase are also induced by their substrates, and it is suggested that these two enzymes may be different gene products from those expressed in the presence of urocanate. 5. Induction of the enzyme system for the oxidation of imidazolylpropionate is dependent on exposure of cells to this compound.     

Thioglycolate, competitive inhibitor of urocanase.

Urocanase was inhibited by thioglycolate, 2-mercaptoethanol, dithioerythritol, and 3-mercaptopropionate. Thioglycolate inhibited competitively at low concentrations (K_i, 0.1 mM) and protected the active site from modification by sulfite. The inhibited enzyme was reactivated by dialysis. A difference spectrum peak of 328 nm for the thioglycolate-urocanase complex compared to the 327 nm absorption maximum of the NAD-thioglycolate adduct. Several nucleophiles are known to inhibit urocanase. We conclude that thioglycolate, as a nucleophilic agent, inhibits by forming an adduct with the tightly bound NAD of urocanase. These results provide indirect evidence that NAD may be the locus of substrate binding in urocanase.     

The degradation of l-histidine, imidazolyl-l-lactate and imidazolylpropionate by Pseudomonas testosteroni

1. Imidazol-5-ylpropionate and imidazol-5-yl-lactate are degraded by Pseudomonas testosteroni via inducible pathways. 2. Growth on either compound as the sole source of carbon results in the induction of the enzymes for histidine catabolism. 3. The pathway of histidine degradation in this organism, a non-fluorescent Pseudomonad, is shown to be the same as that operating in Pseudomonas fluorescens and Pseudomonas putida. It consists of the successive formation of urocanate, imidazol-4-on-5-ylpropionate, N-formimino-l-glutamate, N-formyl-l-glutamate and glutamate. 4. Whole cells of P. testosteroni accumulate urocanate in the reaction mixture when incubated with imidazolylpropionate, but only after an adaptive lag period which is removed by previous growth on imidazolylpropionate as the source of carbon. 5. Imidazolyl-lactate is oxidized to imidazolylpyruvate, which then gives rise to histidine by specific transamination with l-glutamate. 6. Cells grown on histidine, urocanate or imidazolylpropionate are also able to degrade imidazolyllactate. 7. Mutants lacking urocanase are unable to grow on imidazolylpropionate, imidazolyl-lactate, histidine or urocanate. One with impaired histidase activity cannot utilize histidine or imidazolyl-lactate, but grows normally on imidazolylpropionate or urocanate. A mutant unable to grow on imidazolylpropionate is indistinguishable from the wild-type with respect to growth on histidine, imidazolyl-lactate or urocanate. 8. Thus it is established that imidazolyl-lactate is metabolized via histidine whereas imidazolylpropionate enters the histidine degradation pathway after conversion into urocanate.     

Purine degradation in Pseudomonas aeruginosa and Pseudomonas testosteroni.

1. Adenine, hypoxanthine, xanthine and guanine are broken down in Pseudomonas aeruginosa and Pseudomonas testosteroni to allantoin by the concerted action of the enzymes adenine deaminase, guanine deaminase, NAD+-dependent xanthine dehydrogenase and uricase. 2. Uric acid is broken down by an unstable, membrane-bound uricase with an unusually low pH optimum. 3. In both strains adenine inhibits growth and xanthine dehydrogenase. A second type of inhibition is manifest only in Ps. testosteroni and concerns the regulation of the biosynthesis of amino acids of the aspartate family. Enzymic studies showed that in this strain aspartate kinase is inhibited by AMP.     

Molecular cloning and expression of the beta-hydroxysteroid dehydrogenase gene from Pseudomonas testosteroni.

The structural gene (hsd) of the Pseudomonas testosteroni encoding the 17 beta-hydroxysteroid dehydrogenase has been cloned using the cosmid vector pVK102. Escherichia coli carrying recombinant clones of hsd, isolated by immunological screening, were able to express the biologically active enzyme, as measured by the conversion of testosterone into androstenedione. Subcloning experiments, restriction and deletion analysis, and site-directed insertion mutagenesis showed that the hsd gene is located within a 1.3-kb HindIII-PstI restriction fragment. A 26.5-kDa protein encoded by a recombinant plasmid containing this Ps. testosteroni DNA restriction fragment was detected by SDS-PAGE analysis of in vitro [35S]methionine-labeled polypeptides.     

Numerical systematics of bacteria of the genus Pseudomonas

In 290 strains of bacteria belonging to the genus Pseudomonas, 120 morphological and physiologo-biochemical characters were studied and the results obtained thereby were analyzed by the methods of numerical taxonomy using computers. The majority of strains were subdivided into 11 clusters: Ps. aeruginosa (1), Ps. putida (2), Ps. rathonis (5), Ps. syringae (8), Ps. pseudoalcaligenes (9), Ps. maltophilia (10), Ps. acidovorans (11), Ps. testosteroni (12), Ps. mendocina (13), Ps. cepacia (14), Ps. fluorescens (3). The latter cluster included also the strains identified earlier as Ps. aurantiaca, Ps. lemonnieri, Ps. fluoro-violaceus, and Ps. aureofaciens. Three clusters contained strains which could not be identified and probably should be regarded as distinct species. The characteristics have been selected useful for diagnostics of the above Pseudomonas bacteria and the subgroups of Ps. fluorescens.     

Irreversible inactivation of urocanase by 4-bromocrotonate.

Urocanase from Pseudomonas putida is irreversibly inactivated by 4-bromocrotonate. At pH 6.7 and 25°, the rate of inactivation is first-order in remaining active enzyme and follows saturation kinetics with a K₁ of 180 mM and a maximum inactivation rate of 0.889 min^?1. The rate constant of inactivation decreases with pH in the pH range 5.8 to 8.5. 4-Bromocrotonate methyl ester inactivates urocanase at only 3% the rate observed with bromocrotonate while other alkylating reagents are ineffective in promoting a time-dependent loss of activity. Dihydrourocanate protects competitively against bromocrotonate inactivation; an average value of 3.3 mM at pH 6.7 is obtained for the enzyme-dihydrourocanate dissociation constant. Protection against inactivation is also offered by fumarate and crotonate, but not by maleate. The results are consistent with bromocrotonate reacting within the active site region of the enzyme.     

Cross-reactivity of antibodies raised to Pseudomonas fluorescens protease with extracellular proteins produced by meat-spoiling pseudomonads

The cross-reactivity patterns of antibodies to Pseudomonas fluorescens protease with the extracellular proteins produced by a number of meat-spoiling pseudomonads were studied. Immunoblotting studies showed that purified IgG to Ps. fluorescens protease cross-reacted with extracellular proteins in the cell culture supernatant fluids of Pseudomonas spp., including Ps. fragi and Ps. lundensis. In the case of Ps. lundensis and Pseudomonas spp. 11390, the cross-reactive moieties were of similar molecular weight to the Ps. fluorescens protease (46 kDa). However, in Ps. fragi the cross-reactive moiety was a lower molecular weight protein (8 kDa). This may represent a fragment of the active enzyme. These results indicate the presence of common antigenic determinants among the proteases of meat spoiling pseudomonads.     

Homologies between enzymes involved in steroid and xenobiotic carbonyl reduction in vertebrates, invertebrates and procaryonts.

Evidence is reported for the existence of a structurally and functionally related and probably evolutionarily conserved class of membrane-bound liver carbonyl reductases/hydroxysteroid dehydrogenases involved in steroid and xenobiotic carbonyl metabolism. Carbonyl reduction was investigated in liver microsomes of 8 vertebrate species, as well as in insect larvae total homogenate and in purified 3 alpha-hydroxysteroid dehydrogenase preparations of the procaryont Pseudomonas testosteroni, using the ketone compound 2-methyl-1,2 di-(3-pyridyl)-1-propanone (metyrapone) as substrate. The enzyme activities involved in the metyrapone metabolism were screened for their sensitivity to several steroids as inhibitors. In all fractions tested, steroids of the adrostane or pregnane class strongly inhibited xenobiotic carbonyl reduction, whereas only in the insect and procaryotic species could ecdysteroids inhibit this reaction. Immunoblot analysis with antibodies against the respective microsomal mouse liver metyrapone reductase revealed strong crossrections in all fractions tested, even in those of the insect and the procaryont. A similar crossreaction pattern was achieved when the same fractions were incubated with antibodies against 3 alpha-hydroxysteroid dehydrogenase from Pseudomonas testosteroni. The mutual immunoreactivity of the antibody species against proteins from vertebrate liver microsomes, insects and procaryonts suggests the existence of structural homologies within these carbonyl reducing enzymes. This is further confirmed by limited proteolysis of purified microsomal mouse liver carbonyl reductase and subsequent analysis of the peptide fragments with antibodies specifically purified by immunoreactivity against this respective crossreactive antigen. These immunoblot experiments revealed a 22 kDa peptide fragment which was commonly recognized by all antibodies and which might represent a conserved domain of the enzyme.     

Involvement of Threonine Dehydratase in Biosynthesis of the α-Ketobutyrate Prosthetic Group of Urocanase

Seventeen mutants of Pseudomonas putida that were unable to grow on threonine as nitrogen source owing to a lack of threonine dehydratase were isolated, and all were found to be unable to synthesize active urocanase. Spontaneous revertants selected for urocanase production concomitantly regained threonine dehydratase. Mutants that were unable to utilize urocanate as carbon source were also isolated, and these were defective in urocanase formation but were normal in threonine dehydratase levels. Since alpha-ketobutyrate is the prosthetic group for urocanase, these results are consistent with the proposal that threonine dehydratase is necessary for urocanase prosthetic group biosynthesis. However, the lack of urocanase activity in threonine dehydratase-negative mutants was shown not to be the result of reduced levels of endogenous free alpha-ketobutyrate, nor to the participation of threonine dehydratase in the initiation of urocanase biosynthesis through the conversion of threonyl-tRNA(Thr) to alpha-ketobutyryl-tRNA(Thr). Other alternatives for the participation of threonine dehydratase in urocanase biosynthesis are discussed.     

A method for the detection of urocanase on polyacrylamide gels and its use with crude cell extracts of Pseudomonas.

A method is described for the specific detection of urocanase activity on polyacrylamide gels. It is dependent upon the reduction of nitro blue tetrazolium by the product of the urocanase reaction using phenazine methosulphate as a coupling agent. The method has been characterized using crude cell extracts of Pseudomonas testosteroni and Pseudomonas putida. After growth of the organisms in histidine-succinate medium each extract shows only one band of urocanase activity. The enzymes from the two species have significantly different electrophoretic mobilities.     

Analysis of the catalytic domain of the lysin of the lactococcal bacteriophage Tuc2009 by chimeric gene assembling

Abstract Dye-linked alcohol dehydrogenase from Rhodopseudomonas acidophila strain M402, able to oxidize polyethylene glycols, was purified to homogeneity. The monomeric enzyme, having a molecular mass of 72 kDa, contains one PQQ and one haem c per enzyme molecule. In other respects also, the enzyme is very similar to the type I quinohaemoprotein alcohol dehydrogenases known to occur in Comamonas testosteroni, Comamonas acidovorans , and Pseudomonas putida species. However, dissimilarities exist with respect to the isoelectric points and the substrate specificities. On reinvestigating the substrate specificity of the C. testosteroni enzyme, it also appeared to exhibit good activity towards polyethylene glycols. Based on what has been reported for the polyethylene glycol-oxidizing alcohol dehydrogenase of Sphingomonas macrogoltabidus , this enzyme is quite different from that of R. acidophila . Keywords: Polyethylene glycol dehydrogenase activity; Alcohol dehydrogenase; PQQ; Haem c ; Rhodopseudomonas acidophila     

Species of Pseudomonas obtained at 7 degrees C and 30 degrees C during aerobic storage of lamb carcasses.

A total of 268 strains of Pseudomonas isolated during storage life of lamb carcasses was identified to species level. One-hundred and thirteen strains obtained at 30 degrees C were Ps. fragi (51), Ps. lundensis (17), Ps. fluorescens biovars I (10), III (9) and VI (1), Ps. putida biovar A (8 strains) and unidentified (17 strains). Species and biovars isolated at 7 degrees C (155) were Ps. fragi (101), Ps. lundensis (32), Ps. fluorescens biovar I (6), Ps. putida biovar A (8) and unidentified (8). Numerical analysis (82% SSM, UPGMA) of 'psychrotrophic' and 'mesophilic' strains resulted in the formation of nine and eight clusters respectively. The dendrograms obtained exhibited similar structures. Most of the strains of Ps. lundensis and Ps. fragi clustered together. Strains of this latter species also joined the type strain of Ps. testosteroni and appeared included with phenons containing the Ps. putida strains. There were clusters made up exclusively of strains assigned to one biovar or group (Ps. fluorescens biovars I and II and unidentified). A high level of similarity was observed between clusters of Ps. fluorescens biovar I and those containing the Ps. fragi-Ps. lundensis complex (> 74% SSM) and Ps. lundensis (> 80%). The recovery of pseudomonads seemed to be affected by the sampling day.     

Species of Pseudomonas obtained at 7°C and 30°C during aerobic storage of lamb carcasses

A total of 268 strains of Pseudomonas isolated during storage life of lamb carcasses was identified to species level. One-hundred and thirteen strains obtained at 30°C were Ps.fragi (51), Ps. lundensis (17), Ps. fluorescens biovars I (10), III (9) and VI (1), Ps. putida biovar A (8 strains) and unidentified (17 strains). Species and biovars isolated at 7°C (155) were Ps. fragi (101), Ps. lundensis (32), Ps. fluorescens biovar I (6), Ps. putida biovar A (8) and unidentified (8). Numerical analysis (82% S _SM, UPGMA) of 'psychrotrophic' and 'mesophilic' strains resulted in the formation of nine and eight clusters respectively. The dendrograms obtained exhibited similar structures. Most of the strains of Ps. lundensis and Ps. fragi clustered together. Strains of this latter species also joined the type strain of Ps. testosteroni and appeared included with phenons containing the Ps. putida strains. There were clusters made up exclusively of strains assigned to one biovar or group ( Ps. fluorescens biovars I and II and unidentified). A high level of similarity was observed between clusters of Ps. fluorescens biovar I and those containing the Ps. fragi-Ps. lundensis complex (>74% S _SM) and Ps. lundensis (>80%). The recovery of pseudomonads seemed to be affected by the sampling day.