Cresol and 3-methylcatechol were identified as successive transitory intermediates of toluene catabolism by the trichloroethylene-degrading bacterium G4. The absence of a toluene dihydrodiol intermediate or toluene dioxygenase and toluene dihydrodiol dehydrogenase activities suggested that G4 catabolizes toluene by a unique pathway. Formation of a hybrid species of 180-and '60-labeled 3-methylcatechol from toluene in an atmosphere of 1802 and 1602 established that G4 catabolizes toluene by successive monooxygenations at the ortho and meta positions. Detection of trace amounts of 4-methylcatechol from toluene catabolism suggested that the initial hydroxylation of toluene was not exclusively at the ortho position. Further catabolism of 3-methylcatechol was found to proceed via catechol-2,3-dioxygenase and hydroxymuconic semialdehyde hydrolase activities.
Pseudomonas cepacia G4 possesses a novel pathway of toluene catabolism that is shown to be responsible for the degradation of trichloroethylene (TCE). This pathway involves conversion of toluene via o-cresol to 3-methylcatechol. In order to determine the enzyme of toluene degradation that is responsible for TCE degradation, chemically induced mutants, blocked in the toluene ortho-monooxygenase (TOM) pathway of G4, were examined. Mutants of the phenotypic class designated TOM Awere all defective in their ability to oxidize toluene, o-cresol, m-cresol, and phenol, suggesting that a single enzyme is responsible for conversion of these compounds to their hydroxylated products (3-methylcatechol from toluene, o-cresol, and m-cresol and catechol from phenol) in the wild type. Mutants of this class did not degrade TCE. Two other mutant classes which were blocked in toluene catabolism, TOM B-, which lacked catechol-2,3-dioxygenase, and TOM C-, which lacked 2-hydroxy-6-oxoheptadienoic acid hydrolase activity, were fully capable of TCE degradation. Therefore, TCE degradation is directly associated with the monooxygenation capability responsible for toluene, cresol, and phenol hydroxylation.
Mutants of Pseudomonas putida mt-2 that are unable to convert benzoate to catechol were isolated and grouped into two classes: those that did not initiate attack on benzoate and those that accumulated 3,5-cyclohexadiene-1,2-diol-1-carboxylic acid (benzoate diol). The latter mutants, represents by strain PP0201, were shown to lack benzoate diol dehydrogenase (benD) activity. Mutants from the former class were presumed either to carry lesions in one or more subunit structural genes of benzoate dioxygenase (benABC) or the regulatory gene (benR) or to contain multiple mutations. Previous work in this laboratory suggested that benR can substitute for the TOL plasmid-encoded xylS regulatory gene, which promotes gene expression from the OP2 region of the lower or meta pathway operon. Accordingly, structural and regulatory gene mutations were distinguished by the ability of benzoate-grown mutant strains to induce expression from OP2 without xylS by using the TOL plasmid xylE gene (encoding catechol 2,3-dioxygenase) as a reporter. A cloned 12-kb BamHI chromosomal DNA fragment from the P. aeruginosa PAO1 chromosome complemented all of the mutations, as shown by restoration of growth on benzoate minimal medium. Subcloning and deletion analyses allowed identification of DNA fragments carrying benD, benABC, and the region possessing xylS substitution activity, benR. Expression of these genes was examined in a strain devoid of benzoate-utilizing ability, Pseudomonas fluorescens PFO15. The disappearance of benzoate and the production of catechol were determined by chromatographic analysis of supernatants from cultures grown with casamino acids. When P. fluorescens PFO15 was transformed with plasmids containing only benABCD, no loss of benzoate was observed. When either benR or xylS was cloned into plasmids compatible with those plasmids containing only the benABCD regions, benzoate was removed from the medium and catechol was produced. Regulation of expression of the chromosomal structural genes by benR and xylS was quantified by benzoate diol dehydrogenase enzyme assays. The results obtained when xylS was substituted for benR strongly suggest an isofunctional regulatory mechanism between the TOL plasmid lower-pathway genes (via the OP2 promoter) and chromosomal benABC. Southern hybridizations demonstrated that DNA encoding the benzoate dioxygenase structural genes showed homology to DNA encoding toluate dioxygenase from the TOL plasmid pWW0, but benR did not show homology to xylS. Evolutionary relationships between the regulatory systems of chromosomal and plasmid-encoded genes for the catabolism of benzoate and related compounds are suggested.
Pseudomonas aeruginosa PAO1 was able to utilize several aromatic biogenic amines as sole sources of carbon or nitrogen. These included the phenethylamines tyramine and dopamine and the phenethanolamines octopamine, synephrine, and norepinephrine. Initial catabolism of the phenethylamines was mediated by a membrane-bound tyramine dehydrogenase which produced 4-hydroxyphenylacetaldehyde (4HPAL) with tyramine as the substrate. The enzyme was induced by growth with both classes of amines. Initial catabolism of octopamine (except when present as the sole source of carbon and nitrogen) was mediated by a soluble enzyme with activity against the phenethanolamines but not against tyramine or dopamine. The product of the reaction with octopamine as substrate was also 4HPAL. Addition of NAD to reaction mixtures yielded 4-hydroxyphenylacetic acid and NADH. These activities, octopamine hydrolyase and 4-HPAL dehydrogenase (measured as a combined activity, OCAH-4HPALDH), were only induced by growth with phenethanolamines. However, the combined activities were not observed in extracts from cells grown with octopamine as the sole source of carbon and nitrogen, suggesting that an alternate pathway is used under this growth condition. Two independently isolated mutant strains were unable to utilize tyramine as a sole source of carbon or nitrogen. These mutants were also unable to utilize dopamine but grew at wild-type rates on the phenethanolamines. The mutations were mapped at about 70 min on the PA01 chromosome with the chromosome-mobilizing plasmid R68.45, and both were linked to the catA1, mtu-9002, tyu-9009, and puuE mutations. DNA complementing both of the mutations was cloned on a single BamHI fragment approximately 13.8 kilobase pairs in length. Analysis of a subcloned fragment showed that the two mutations were in different genes.
Five of the genes required for phosphorylative catabolism of glucose in Pseudomonas aeruginosa were ordered on two different chromosomal fragments. Analysis of a previously isolated 6.0-kb EcoRI fragment containing three structural genes showed that the genes were present on a 4.6-kb fragment in the order glucose-binding protein (gltB)-glucokinase (glk)-6-phosphogluconate dehydratase (edd). Two genes, glucose-6-phosphate dehydrogenase (zwf) and 2-keto-3-deoxy-6-phosphogluconate aldolase (eda), shown by transductional analysis to be linked to gltB and edd, were cloned on a separate 11-kb BamHI chromosomal DNA fragment and then subcloned and ordered on a 7-kb fragment. The 6.0-kb EcoRI fragment had been shown to complement a regulatory mutation, hexR, which caused noninducibility of four glucose catabolic enzymes. In this study, hexR was mapped coincident with edd. A second regulatory function, hexC, was cloned within a 0.6-kb fragment contiguous to the edd gene but containing none of the structural genes. The phenotypic effect of the hexC locus, when present on a multicopy plasmid, was elevated expression of glucokinase, glucose-6-phosphate dehydrogenase, 6-phosphogluconate dehydratase, and 2-keto-3-deoxy-6-phosphogluconate aldolase activities in the absence of inducer.Glucose catabolism in Pseudomonas aeruginosa proceeds by either an oxidative or a phosphorylative pathway ( Fig. 1; reviewed in reference 24). In the direct phosphorylative pathway, glucose is transported into the cell by a periplasmic glucose-binding protein (GLTB)-dependent active transport system. Intracellular glucose is phosphorylated by glucokinase (GLK) and converted to 6-phosphogluconate (6PG) by glucose-6-phosphate dehydrogenase (ZWF). The 6PG from this pathway and from the oxidative pathway ( Fig. 1) is further metabolized to glyceraldehyde-3-phosphate and pyruvate by the Entner-Doudoroff enzymes 6PG dehydratase (EDD) and 2-keto-3-deoxy-6-phosphogluconate (KDPG) aldolase (EDA). GLK, ZWF, EDD, and EDA are strictly co-inducible, and 6PG is thought to serve as the physiological inducer (2,8,19). The glucose transport functions are separately regulated (20).All of the genes known to be required for direct phosphorylative catabolism of glucose to pyruvate and glyceraldehyde-3-phosphate are clustered in the 39-min region of the Pseudomonas aeruginosa chromosome (7,8,36 MATERIALS AND METHODS Bacterial strains and plasmids. All bacterial strains used in this study were derived from prototrophic P. aeruginosa PAO (16) and have been described previously. The edd lesions in strains PFB57 (edd-8 hexR1) and PFB2 (edd4 hexR2) have been described previously (2,8). Both of these mutant strains also were noninducible for the other glucose catabolic enzymes ZWF, GLK, and EDA (2, 8). We have designated these regulatory mutations hexRi and hexR2.Other strains used in this study were PFB9 (edd-1) and PFB52 (edd-2) (2), PFB362 (gltBi) (7), PRP444 (glk-1) (8), PFB98 (zwf-1) (36), PFB103 (zwf-2) (37), and PAO1838 (eda-9001 met-9020) (29).Plasmids in this study w...
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