Purification and characterization of gentisate 1,2-dioxygenases from Pseudomonas alcaligenes NCIB 9867 and Pseudomonas putida NCIB 9869

Two 3-hydroxybenzoate-inducible gentisate 1,2-dioxygenases were purified to homogeneity from Pseudomonas alcaligenes NCIB 9867 (P25X) and Pseudomonas putida NCIB 9869 (P35X), respectively. The estimated molecular mass of the purified P25X gentisate 1, 2-dioxygenase was 154 kDa, with a subunit mass of 39 kDa. Its structure is deduced to be a tetramer. The pI of this enzyme was established to be 4.8 to 5.0. The subunit mass of P35X gentisate 1, 2-dioxygenase was 41 kDa, and this enzyme was deduced to exist as a dimer, with a native molecular mass of about 82 kDa. The pI of P35X gentisate 1,2-dioxygenase was around 4.6 to 4.8. Both of the gentisate 1,2-dioxygenases exhibited typical saturation kinetics and had apparent Kms of 92 and 143 microM for gentisate, respectively. Broad substrate specificities were exhibited towards alkyl and halogenated gentisate analogs. Both enzymes had similar kinetic turnover characteristics for gentisate, with kcat/Km values of 44.08 x 10(4) s-1 M-1 for the P25X enzyme and 39.34 x 10(4) s-1 M-1 for the P35X enzyme. Higher kcat/Km values were expressed by both enzymes against the substituted gentisates. Significant differences were observed between the N-terminal sequences of the first 23 amino acid residues of the P25X and P35X gentisate 1,2-dioxygenases. The P25X gentisate 1,2-dioxygenase was stable between pH 5.0 and 7.5, with the optimal pH around 8.0. The P35X enzyme showed a pH stability range between 7.0 and 9.0, and the optimum pH was also 8.0. The optimal temperature for both P25X and P35X gentisate 1, 2-dioxygenases was around 50 degrees C, but the P35X enzyme was more heat stable than that from P25X. Both enzymes were strongly stimulated by 0.1 mM Fe2+ but were completely inhibited by the presence of 5 mM Cu2+. Partial inhibition of both enzymes was also observed with 5 mM Mn2+, Zn2+, and EDTA.     

2-pyrone-4,6-dicarboxylic acid, a catabolite of gallic acids in Pseudomonas species.

2-Pyrone-4,6-dicarboxylate hydrolase was purified from 4-hydroxybenzoate-grown Pseudomonas testosteroni. Gel filtration and electrophoretic measurements indicated that the preparation was homogeneous and gave a molecular weight of 37,200 for the single subunit of the enzyme. Hydrolytic activity was dependent upon a functioning sulfhydryl group(s) and was freely reversible; the equilibrium position was dependent upon pH, with equimolar amounts of pyrone and open-chain form present at pH 7.9. Since the hydrolase was strongly induced when the nonfluorescent organisms P. testosteroni and P. acidovorans grew with 4-hydroxybenzoate, it is suggested that 2-pyrone-4,6-dicarboxylate is a normal intermediate in the meta fission degradative pathway of protocatechuate. Laboratory strains of fluorescent pseudomonads did not metabolize 2-pyrone-4,6-dicarboxylate, but a strain of P. putida was isolated from soil that utilized this compound for growth; the hydrolase was then induced, but it was absent from extracts of 4-hydroxybenzoate-grown cells that readily catabolized protocatechuate by ortho fission reactions. 2-Pyrone-4,6-dicarboxylic acid was the major product formed when gallic acid was oxidized by purified protocatechuate 3,4-dioxygenase. Protocatechuate 4,5-dioxygenase gave only the open-chain ring fission product when gallic acid was oxidized, but the enzyme attacked 3-O-methylgallic acid, giving 2-pyrone-4,6-dicarboxylic acid as the major product. Cell suspensions of 4-hydroxybenzoate-grown P. testosteroni readily oxidized 3-O-methylgallate with accumulation of methanol.     

Gentisate 1,2-dioxygenase from Pseudomonas. Substrate coordination to active site Fe2+ and mechanism of turnover

Gentisate 1,2-dioxygenase catalyzes the oxygenolytic ring cleavage of gentisate (2,5-dihydroxybenzoate) between carbons 1 and 2 to form maleylpyruvate. The essential active site Fe2+ of the enzyme binds NO to yield an EPR-active (S = 3/2) complex. Hyperfine broadening from 17O (I = 5/2) is observed in the spectrum of the enzyme-nitrosyl complex prepared in 17O-enriched water, demonstrating that water is an iron ligand. Association of gentisate with the enzyme-nitrosyl complex causes the broadening due to [17O]water to disappear, suggesting that water is displaced. Hyperfine broadening of the EPR spectrum for the gentisate-bound complex is observed when 17O is incorporated into either the carbon 1 carboxylate or carbon 2 hydroxyl substituents of gentisate, but not when it is placed in the carbon 5 hydroxyl substituent. Thus, substrate apparently binds directly to the iron through the carbon 1 carboxylate and carbon 2 hydroxyl substituents, thereby bringing the site of ring cleavage close to the active site iron. Since NO must bind to the iron to elicit an EPR signal, a total of three sites in the iron coordination appear to be available for exogenous ligands. The role of the substrate functional groups in catalysis is investigated through comparison of the reaction kinetics of gentisate analogs using the gentisate 1,2-dioxygenases isolated from Pseudomonas acidovorans and Pseudomonas testosteroni. Turnover is either eliminated or substantially reduced on replacement of any of the functional groups of gentisate. Furthermore, an electron-donating group that can tautomerize (hydroxyl or amine) is required in a ring position either ortho or para to the carbon 2 substituent for turnover. The best alternate substrate of this group is 5-aminosalicylate, which is turned over at approximately 7% of the rate of gentisate by the enzyme from P. testosteroni. Both atoms from O2 are shown to be incorporated into the product of 5-aminosalicylate turnover. This is the first direct demonstration of dioxygenase stoichiometry in the reaction of any ferrous, non-heme, aromatic ring-cleaving dioxygenase. It is proposed that the enzyme-catalyzed O2 attack on the aromatic ring of gentisate is initiated from a complex in which O2 and substrate are simultaneously coordinated to the active site iron. Subsequent dioxygen bond cleavage and insertion are proposed to be promoted by a resonance shift involving ketonization of the carbon 5 hydroxyl group.     

Phthalate metabolism in Pseudomonas testosteroni: accumulation of 4,5-dihydroxyphthalate by a mutant strain.

A mutant strain of Pseudomonas testosteroni blocked in phthalate catabolism converted phthalate into 4,5-dihydroxyphthalate. The latter compound was isolated, and its physical properties were determined. A stoichiometric conversion of the compound to protocatechuate was demonstrated spectrophotometrically with crude extracts of a protocatechuate 4,5-dioxygenase-deficient mutant. Therefore, phthalate is metabolized through 4,5-dihydroxyphthalate and protocatechuate, which is further degraded by protocatechuate 4,5-dioxygenase in P. testosteroni. By using several mutants blocked in phthalate catabolism, 4,5-dihydroxyphthalate decarboxylase was shown to be induced by phthalate. A simple spectrophotometric assay for the enzyme is also reported.     

Phthalate and 4-hydroxyphthalate metabolism in Pseudomonas testosteroni: purification and properties of 4,5-dihydroxyphthalate decarboxylase.

Phthalate is degraded through 4,5-dihydroxyphthalate and protocatechuate in Pseudomonas testosteroni NH1000. The ezyme 4,5-dihydroxyphthalate decarboxylase, catalyzing the conversion of 4,5-dihydroxyphthalate to protocatechuate and carbon dioxide, was purified approximately 130-fold from phthalate-induced cells of a protocatechuate 4,5-dioxygenase-deficient mutant of P. testosteroni. The most purified preparation showed a single protein band on sodium dodecyl sulfate-acrylamide disc gel electrophoresis with a molecular weight of 38,000. The apparent molecular weight of the native enzyme determined by Sephadex G-200 column chromatography was 150,000. Among the substrate analogs tested, only 4-hydroxyphthalate served as a substrate, which was decarboxylated to form m-hydroxybenzoate. The apparent Km values for 4,5-dihydroxyphthalate and 4-hydroxyphthalate were estimated to be 10.5 micrometer and 1.25 mM, respectively, and the Vmax for the former was 10 times larger than that for the latter. Whereas the wild-type strain could utilize 4-hydroxyphthalate as a sole source of carbon, none of the following could grow with the compound: 4,5-dihydroxyphthalate decarboxylase-deficient, m-hydroxybenzoate-nondegradable, and protocatechuate 4,5-dioxygenase-deficient mutants. Since one-step revertants of these mutants could utilize 4-hydroxyphthalate, the compound appears to be metabolized through m-hydroxybenzoate and protocatechuate in P. testosteroni NH1000.     

Evidence for isofunctional enzymes used in m-cresol and 2,5-xylenol degradation via the gentisate pathway in Pseudomonas alcaligenes.

Study of the reaction sequence by which Pseudomonas alcaligenes (P25X1) and derived mutants degrade m-cresol, 2,5-xylenol, and their catabolites has provided indirect evidence for the existence of two or more isofunctional enzymes at three different steps. Maleylpyruvate hydrolase activity appears to reside in two different proteins with different specificity ranges, one of which (MPH1) is expressed constitutively; the other (MPH11) is strictly inducible. Two gentisate 1,2-dioxygenase activities were found, one of which is constitutively expressed and possesses a broader specificity range than the other, which is inducible. From oxidation studies with intact cells, there appear to be two activities responsible for the 6-hydroxylation of 3-hydroxybenzoate, and again a broadly specific activity is present regardless of growth conditions; the other is inducible by 3-hydroxybenzoate. Three other enzyme activities are also detected in uninduced cells, viz., xylenol methylhydroxylase, benzylalcohol dehydrogenase, and benzaldehyde dehydrogenase. All apparently possess broad specificity. Fumarylpyruvate hydrolase was also detected but only in cells grown with m-cresol, 3-hydroxybenzoate, or gentisate. Mutants, derived either spontaneously or after treatment with mitomycin C, are described, certain of which have lost the ability to grow with m-cresol and 2,5-xylenol and some of which have also lost the ability to form the constitutive xylenol methylhydroxylase, benzylalcohol dehydrogenase, benzaldehyde dehydrogenase, 3-hydroxybenzoate 6-hydroxylase, and gentisate 1,2-dioxygenase. Such mutants, however, retain ability to synthesize inducibly a second 3-hydroxybenzoate 6-hydroxylase and gentisate 1,2-dioxygenase, as well as maleylpyruvate hydrolase (MPH11) and fumarylpyruvate hydrolase; MPH1 was still synthesized. These findings suggest the presence of a plasmid for 2,5-xylenol degradation which codes for synthesis of early degradative enzymes. Other enzymes, such as the second 3-hydroxybenzoate 6-hydroxylase, gentisate 1,2-dioxygenase, maleylpyruvate hydrolase (MPH1 and MPH11), and fumarylpyruvate hydrolase, appear to be chromosomally encoded and, with the exception of MPH1, strictly inducible.     

Alternative routes of aromatic catabolism in Pseudomonas acidovorans and Pseudomonas putida: gallic acid as a substrate and inhibitor of dioxygenases.

When 3,4-dihydroxyphenylacetic acid (homoprotocatechuic acid) was added to Pseudomonase acidovorans growing at the expense of succinate, enzymes required for degrading homoprotocatechuate to pyruvate and succinate semialdehyde were strongly induced. These enzymes were effectively absent from cell extracts of the organism grown with 4-hydroxyphenylacetic acid, and this substrate was metabolized by the catabolic enzymes of the homogentisate pathway. Two separate ring-fission dioxygenases for 3,4,5-trihydroxybenzoic acid (gallic acid) were present in cell extracts of Pseudomonas putida when grown with syringic acid, and gallate was degraded by reactions associated with meta fission. One of the two gallate dioxygenases also attacked 3-O-methylgallic acid; the other, which did not, was induced when cells were exposed to gallate. This organism possessed ortho fission enzymes, including protocatechuate 3,4-dioxygenase (EC 1.13.11.3) and cis,cis-carboxymuconate-lactonizing enzyme (EC 5.5.1.2), after induction with 3,4-dihydroxybenzoic acid (protocatechuic acid). Gallate was a substrate for protocatechuate 3,4-dioxygenase, with a Vmax about 3% of that of protocatechuate and with an apparent Km slightly lower. Gallate was a powerful competitive inhibitor of protocatechuate oxidation.     

Catabolism of benzoate and monohydroxylated benzoates by Amycolatopsis and Streptomyces spp

Eight actinomycetes of the genera Amycolatopsis and Streptomyces were tested for the degradation of aromatic compounds by growth in a liquid medium containing benzoate, monohydroxylated benzoates, or quinate as the principal carbon source. Benzoate was converted to catechol. The key intermediate in the degradation of salicylate was either catechol or gentisate, while m-hydroxybenzoate was metabolized via gentisate or protocatechuate. p-Hydroxybenzoate and quinate were converted to protocatechuate. Catechol, gentisate, and protocatechuate were cleaved by catechol 1,2-dioxygenase, gentisate 1,2-dioxygenase, and protocatechuate 3,4-dioxygenase, respectively. The requirement for glutathione in the gentisate pathway was dependent on the substrate and the particular strain. The conversion of p-hydroxybenzoate to protocatechuate by p-hydroxybenzoate hydroxylase was gratuitously induced by all substrates that were metabolized via protocatechuate as an intermediate, while protocatechuate 3,4-dioxygenase was gratuitously induced by benzoate and salicylate in two Amycolatopsis strains.     

Catabolism of benzoate and monohydroxylated benzoates by Amycolatopsis and Streptomyces spp.

Eight actinomycetes of the genera Amycolatopsis and Streptomyces were tested for the degradation of aromatic compounds by growth in a liquid medium containing benzoate, monohydroxylated benzoates, or quinate as the principal carbon source. Benzoate was converted to catechol. The key intermediate in the degradation of salicylate was either catechol or gentisate, while m-hydroxybenzoate was metabolized via gentisate or protocatechuate. p-Hydroxybenzoate and quinate were converted to protocatechuate. Catechol, gentisate, and protocatechuate were cleaved by catechol 1,2-dioxygenase, gentisate 1,2-dioxygenase, and protocatechuate 3,4-dioxygenase, respectively. The requirement for glutathione in the gentisate pathway was dependent on the substrate and the particular strain. The conversion of p-hydroxybenzoate to protocatechuate by p-hydroxybenzoate hydroxylase was gratuitously induced by all substrates that were metabolized via protocatechuate as an intermediate, while protocatechuate 3,4-dioxygenase was gratuitously induced by benzoate and salicylate in two Amycolatopsis strains.     

Phthalate and 4-hydroxyphthalate metabolism in Pseudomonas testosteroni: purification and properties of 4,5-dihydroxyphthalate decarboxylase.

Phthalate is degraded through 4,5-dihydroxyphthalate and protocatechuate in Pseudomonas testosteroni NH1000. The ezyme 4,5-dihydroxyphthalate decarboxylase, catalyzing the conversion of 4,5-dihydroxyphthalate to protocatechuate and carbon dioxide, was purified approximately 130-fold from phthalate-induced cells of a protocatechuate 4,5-dioxygenase-deficient mutant of P. testosteroni. The most purified preparation showed a single protein band on sodium dodecyl sulfate-acrylamide disc gel electrophoresis with a molecular weight of 38,000. The apparent molecular weight of the native enzyme determined by Sephadex G-200 column chromatography was 150,000. Among the substrate analogs tested, only 4-hydroxyphthalate served as a substrate, which was decarboxylated to form m-hydroxybenzoate. The apparent Km values for 4,5-dihydroxyphthalate and 4-hydroxyphthalate were estimated to be 10.5 micrometer and 1.25 mM, respectively, and the Vmax for the former was 10 times larger than that for the latter. Whereas the wild-type strain could utilize 4-hydroxyphthalate as a sole source of carbon, none of the following could grow with the compound: 4,5-dihydroxyphthalate decarboxylase-deficient, m-hydroxybenzoate-nondegradable, and protocatechuate 4,5-dioxygenase-deficient mutants. Since one-step revertants of these mutants could utilize 4-hydroxyphthalate, the compound appears to be metabolized through m-hydroxybenzoate and protocatechuate in P. testosteroni NH1000.     

17O]Water and nitric oxide binding by protocatechuate 4,5-dioxygenase and catechol 2,3-dioxygenase. Evidence for binding of exogenous ligands to the active site Fe2+ of extradiol dioxygenases

Pseudomonas testosteroni protocatechuate 4,5-dioxygenase and Pseudomonas putida catechol 2,3-dioxygenase (metapyrocatechase) catalyze extradiol-type oxygenolytic cleavage of the aromatic ring of their substrates. The essential active site Fe2+ of each enzyme binds nitric oxide (NO) to produce an EPR active complex with an electronic spin of S = 3/2. Hyperfine broadening of the EPR resonances of the nitrosyl complexes by 17O-enriched H2O shows that water is bound directly to the Fe2+ in the native enzymes, but is apparently displaced in substrate complexes. NO is not displaced by either substrates or inhibitors. The EPR spectra of several enzyme-inhibitor-NO complexes are different from those of enzyme-NO or enzyme-substrate-NO complexes and are found to be broadened by 17O-enriched water. The data show that at least 2 and perhaps 3 sites in the Fe ligation can be occupied by exogenous ligands. Furthermore, it is likely that substrates and inhibitors displace water by binding either at or near to the Fe in the nitrosyl complex. Nitric oxide binding is found to be substrate-dependent for each enzyme. Native catechol 2,3-dioxygenase exhibits KD values of 190 microM and 2.0 mM for NO binding in two types of independent sites. Only one type of site is observed in the catechol complex which exhibits a KD for NO of 3.4 microM. One type of NO binding site is observed for both the native and substrate complexed protocatechuate 4,5-dioxygenase with KD values of 360 and 3 microM, respectively. The presence of a specific site in the Fe coordination for NO which is modified in the substrate complex, suggests that O2 binding by the extradiol dioxygenases may also occur at the Fe.     

EPR and M?ssbauer studies of protocatechuate 4,5-dioxygenase. Characterization of a new Fe2+ environment

Protocatechuate 4,5-dioxygenase from Pseudomonas testosteroni has been purified to homogeneity and crystallized. The iron containing, extradiol dioxygenase is shown to be composed of two subunit types (alpha, Mr = 17,700 and beta, Mr = 33,800) in a 1:1 ratio; such a composition has not been observed for other extradiol dioxygenases. The 4.2 K M?ssbauer spectrum of native protocatechuate 4,5-dioxygenase prepared from cells grown in 57Fe-enriched media consists of a doublet with quadrupole splitting, delta EQ = 2.22 mm/s, and isomer shift delta Fe = 1.28 mm/s, demonstrating a high spin Fe2+ site. These parameters, and the temperature dependence of delta EQ, are unique among enzymes but are strikingly similar to those reported for the reaction center of the photosynthetic bacterium Rhodopseudomonas sphaeroides R-26, suggesting very similar ligand environments. The Fe2+ of protocatechuate 4,5-dioxygenase can be oxidized, for instance by H2O2, to yield high spin Fe3+ with EPR g values around g = 6 (and g = 4.3). In the oxidized state, protocatechuate 4,5-dioxygenase is inactive; the iron, however, can be rereduced by ascorbate to yield active enzyme. Our data suggest that protocatechuate binds to Fe2+; the spectra indicate that the ligand binding is heterogenous. The M?ssbauer spectra observed here are fundamentally different from those reported earlier (Zabinski, R., Münck, E., Champion, P., and Wood, J. M. (1972) Biochemistry 11, 3212-3219). The spectra of the earlier (reconstituted) preparations, which had substantially lower specific activities, probably reflect adventitiously bound Fe3+. We discuss here how adventitiously bound iron can be identified and removed. The Fe2+ which is present in native protocatechuate 4,5-dioxygenase and its complexes with substrates and inhibitors reacts quantitatively with nitric oxide to produce a species with electronic spin S = 3/2. The EPR and M?ssbauer spectra of these complexes compare favorably with EDTA . Fe(II) . NO. We have studied the latter complex extensively and have analyzed the M?ssbauer spectra with an S = 3/2 spin Hamiltonian. EPR spectra show that protocatechuate 4,5-dioxygenase-NO complexes with substrates or inhibitors are heterogeneous and consist of several well defined subspecies. The data show that NO, and presumably also O2, has access to the active site Fe2+ in the enzyme-substrate complex. The use of EPR-detectable NO complexes as a rapid and sensitive tool for the study of the EPR silent active site iron of extradiol dioxygenases is discussed.     

Phthalate metabolism in Pseudomonas fluorescens PHK: purification and properties of 4,5-dihydroxyphthalate decarboxylase.

Pseudomonas fluorescens PHK uses 4,5-dihydroxyphthalate as the sole carbon source for o-phthalate catabolism. This intermediate is the substrate for a decarboxylase of the pathway yielding protocatechuate. The decarboxylase was purified to homogeneity by an affinity chromatography procedure in which the reaction product, protocatechuate, was used as a ligand. We describe some properties of the enzyme, including its apparent molecular weight of 420,000 as determined by gel filtration and of 66,000 after sodium dodecyl sulfate-polyacrylamide disc gel electrophoresis, consistent with a hexameric functional protein. The apparent Km for the substrate 4,5-dihydroxyphthalate was 10.4 microM. The characteristics of this enzyme are compared with those described for the isofunctional enzyme from P. testosteroni.     

Pathways of 4-hydroxybenzoate degradation among species of Bacillus.

The pathways used by three bacterial strains of the genus Bacillus to degrade 4-hydroxybenzoate are delineated. When B. brevis strain PHB-2 is grown on 4-hydroxybenzoate, enzymes of the protocatechuate branch of the beta-ketoadipate pathway are induced. In contrast, B. circulans strain 3 contains high levels of the enzymes of the protocatechuate 2,3-dioxygenase pathway after growth on 4-hydroxybenzoate. B. laterosporus strain PHB-7a degrades 4-hydroxybenzoate by a novel reaction sequence. After growth on 4-hydroxybenzoate, strain PHB-7a contains high levels of gentisate oxygenase (EC 1.13.11.4) and maleylpyruvate hydrolase. Whole cells of strain PHB-7a (grown on 4-hydroxylbenzoate) accumulate 2,5-dihydroxybenzoate (gentisate) from 4-hydroxybenzoate when incubated in the presence of 1mM alpha,alpha'-dipyridyl. Thus, strain PHB-7a appears to convert 4-hydroxybenzoate to gentisate, which is further degraded by the glutathione-independent gentisic acid pathway. These pathway delineations provide evidence that Bacillus species are derived from a diverse evolutionary background.     

Gentisate pathway in Salmonella typhimurium: metabolism of m-hydroxybenzoate and gentisate

Abstract Salmonella typhimurium was shown to use the gentisate pathway to metabolize m -hydroxybenzoate and gentisate. m -Hydroxybenzoate hydroxylase and gentisate 1,2-dioxygenase were induced by growth on either gentisate or m -hydroxybenzoate. These enzymes were not detected when the bacteria were grown with glucose or glucose and either m -hydroxybenzoate or gentisate. However, both enzymes were induced when the bacteria were grown on succinate with either substrate. The maleylpyruvate isomerase required reduced glutathione and was irreversibly inhibited by N -ethylmaleimide.     

Regulation of isofunctional enzymes in Pseudomonas alcaligenes mutants defective in the gentisate pathway

The regulation of the inducible set of gentisate pathway enzymes used by Pseudomonas alcaligenes (P25X1) has been studied in strains derived from mutant strains of P25X1 that had lost the constitutive enzymes that degrade m –cresol, 2,5–xylenol and 3,5–xylenol. The enzyme, 3-hydroxybenzoate 6-hydroxylase II, that catalyzes the oxidation of 3-hydroxybenzoate to gentisate is substrate- and product-induced while gentisate dioxygenase II is substrate induced. Neither 3-hydroxybenzoate nor gentisate could induce the synthesis of maleylpyruvate hydrolase II and fumarylpyruvate hydrolase II. The results suggest that the structural genes encoding these four inducible enzymes and maleylpyruvate hydrolase I (a constitutive enzyme) exist in at least four operons. There is strict induction specificity of expression of this inducible set of gentisate pathway enzymes. 3-Hydroxy-4-methyl-benzoate failed to induce whilst 3-hydroxybenzoate and 3-hydroxy-5-methylbenzoate served as inducers of 6-hydroxylase II. Degradation of 2,5-xylenol is mediated by constitutive enzymes whereas the inducible set of enzymes are responsible for the metabolism of m -cresol and 3,5-xylenol.     

Molecular characterization of the genes pcaG and pcaH, encoding protocatechuate 3,4-dioxygenase, which are essential for vanillin catabolism in Pseudomonas sp. strain HR199

Pseudomonas sp. strain HR199 is able to utilize eugenol (4-allyl-2-methoxyphenol), vanillin (4-hydroxy-3-methoxybenzaldehyde), or protocatechuate as the sole carbon source for growth. Mutants of this strain which were impaired in the catabolism of vanillin but retained the ability to utilize eugenol or protocatechuate were obtained after nitrosoguanidine mutagenesis. One mutant (SK6169) was used as recipient of a Pseudomonas sp. strain HR199 genomic library in cosmid pVK100, and phenotypic complementation was achieved with a 5.8-kbp EcoRI fragment (E58). The amino acid sequences deduced from two corresponding open reading frames (ORF) identified on E58 revealed high degrees of homology to pcaG and pcaH, encoding the two subunits of protocatechuate 3,4-dioxygenase. Three additional ORF most probably encoded a 4-hydroxybenzoate 3-hydroxylase (PobA) and two putative regulatory proteins, which exhibited homology to PcaQ of Agrobacterium tumefaciens and PobR of Pseudomonas aeruginosa, respectively. Since mutant SK6169 was also complemented by a subfragment of E58 that harbored only pcaH, this mutant was most probably lacking a functional beta subunit of the protocatechuate 3, 4-dioxygenase. Since this mutant was still able to grow on protocatechuate and lacked protocatechuate 4,5-dioxygenase and protocatechuate 2,3-dioxygenase, the degradation had to be catalyzed by different enzymes. Two other mutants (SK6184 and SK6190), which were also impaired in the catabolism of vanillin, were not complemented by fragment E58. Since these mutants accumulated 3-carboxy muconolactone during cultivation on eugenol, they most probably exhibited a defect in a step of the catabolic pathway following the ortho cleavage. Moreover, in these mutants cyclization of 3-carboxymuconic acid seems to occur by a syn absolute stereochemical course, which is normally only observed for cis, cis-muconate lactonization in pseudomonads. In conclusion, vanillin is degraded through the ortho-cleavage pathway in Pseudomonas sp. strain HR199 whereas protocatechuate could also be metabolized via a different pathway in the mutants.     

Binding of 17O-labeled substrate and inhibitors to protocatechuate 4,5-dioxygenase-nitrosyl complex. Evidence for direct substrate binding to the active site Fe2+ of extradiol dioxygenases

Pseudomonas testosteroni protocatechuate 4,5-dioxygenase catalyzes extradiol-type oxygenolytic cleavage of the aromatic ring of its substrate. The essential active site Fe2+ binds nitric oxide (NO) to produce an EPR active complex with an electronic spin of S = 3/2. Hyperfine broadening of the EPR resonances of the nitrosyl complex of the enzyme by protocatechuate (3,4-(OH)2-benzoate, PCA) enriched specifically with 17O (I = 5/2) in either the 3 or the 4 hydroxyl group shows that both groups can bind directly to the Fe2+ in the ternary complex. Analogous results are obtained for PCA binding to catechol 2,3-dioxygenase-NO complex suggesting that substrate binding by the Fe2+ may be a general property of extradiol dioxygenases. The protocatechuate 4,5-dioxygenase inhibitor, 4-17OH-benzoate binds directly to the Fe of the nitrosyl adduct of the enzyme through the OH group. Since previous studies have shown that water also is bound to the Fe in this ternary complex, but not in the ternary complex with PCA, the data strongly imply that there are 3 sites in the Fe coordination which can be occupied by exogenous ligands. 3-17OH-benzoate is an inhibitor of the enzyme but does not elicit detectable hyperfine broadening in the EPR spectrum of the nitrosyl adduct suggesting that it binds to the enzyme, but not to the Fe. The EPR spectra of ternary enzyme-NO complexes with PCA or 4-OH-benzoate labeled with 17O exclusively in the carboxylate substituent are not broadened, suggesting that this moiety does not bind to the Fe.     

New aerobic benzoate oxidation pathway via benzoyl-coenzyme A and 3-hydroxybenzoyl-coenzyme A in a denitrifying Pseudomonas sp.

A denitrifying Pseudomonas sp. is able to oxidize aromatic compounds compounds completely to CO2, both aerobically and anaerobically. It is shown that benzoate is aerobically oxidized by a new degradation pathway via benzoyl-coenzyme A (CoA) and 3-hydroxybenzoyl-CoA. The organism grew aerobically with benzoate, 3-hydroxybenzoate, and gentisate; catechol, 2-hydroxybenzoate, and protocatechuate were not used, and 4-hydroxybenzoate was a poor substrate. Mutants were obtained which were not able to utilize benzoate as the sole carbon source aerobically but still used 3-hydroxybenzoate or gentisate. Simultaneous adaptation experiments with whole cells seemingly suggested a sequential induction of enzymes of a benzoate oxidation pathway via 3-hydroxybenzoate and gentisate. Cells grown aerobically with benzoate contained a benzoate-CoA ligase (AMP forming) (0.1 mumol min-1 mg-1) which converted benzoate but not 3-hydroxybenzoate into its CoA thioester. The enzyme of 130 kDa composed of two identical subunits of 56 kDa was purified and characterized. Cells grown aerobically with 3-hydroxybenzoate contained a similarly active CoA ligase for 3-hydroxybenzoate, 3-hydroxybenzoate-CoA ligase (AMP forming). Extracts from cells grown aerobically with benzoate catalyzed a benzoyl-CoA- and flavin adenine dinucleotide-dependent oxidation of NADPH with a specific activity of at least 25 nmol NADPH oxidized min-1 mg of protein-1; NADH and benzoate were not used. This new enzyme, benzoyl-CoA 3-monooxygenase, was specifically induced during aerobic growth with benzoate and converted [U-14C]benzoyl-CoA stoichiometrically to [14C]3-hydroxybenzoyl-CoA.