p-Cymene catabolic pathway in Pseudomonas putida F1: cloning and characterization of DNA encoding conversion of p-cymene to p-cumate.

Pseudomonas putida F1 utilizes p-cymene (p-isopropyltoluene) by an 11-step pathway through p-cumate (p-isopropylbenzoate) to isobutyrate, pyruvate, and acetyl coenzyme A. The cym operon, encoding the conversion of p-cymene to p-cumate, is located just upstream of the cmt operon, which encodes the further catabolism of p-cumate and is located, in turn, upstream of the tod (toluene catabolism) operon in P. putida F1. The sequences of an 11,236-bp DNA segment carrying the cym operon and a 915-bp DNA segment completing the sequence of the 2,673-bp DNA segment separating the cmt and tod operons have been determined and are discussed here. The cym operon contains six genes in the order cymBCAaAbDE. The gene products have been identified both by functional assays and by comparing deduced amino acid sequences to published sequences. Thus, cymAa and cymAb encode the two components of p-cymene monooxygenase, a hydroxylase and a reductase, respectively; cymB encodes p-cumic alcohol dehydrogenase; cymC encodes p-cumic aldehyde dehydrogenase; cymD encodes a putative outer membrane protein related to gene products of other aromatic hydrocarbon catabolic operons, but having an unknown function in p-cymene catabolism; and cymE encodes an acetyl coenzyme A synthetase whose role in this pathway is also unknown. Upstream of the cym operon is a regulatory gene, cymR. By using recombinant bacteria carrying either the operator-promoter region of the cym operon or the cmt operon upstream of genes encoding readily assayed enzymes, in the presence or absence of cymR, it was demonstrated that cymR encodes a repressor which controls expression of both the cym and cmt operons and is inducible by p-cumate but not p-cymene. Short (less than 350 bp) homologous DNA segments that are located upstream of cymR and between the cmt and tod operons may have been involved in recombination events that led to the current arrangement of cym, cmt, and tod genes in P. putida F1.     

p-Cymene pathway in Pseudomonas putida: ring cleavage of 2,3-dihydroxy-p-cumate and subsequent reactions.

It was confirmed that 2,3-dihydroxy-p-cumate is a substrate for ring cleavage in Pseudomonas putida PL-W after growth with p-cymene or p-cumate. This compound was oxidized to pyruvate, acetaldehyde, isobutyrate, and carbon dioxide by extracts of cells, and these products appear in equimolar amounts. The transient appearance of compounds and 2,3-dihydroxy-p-cumate to a yellow intermediate (lambda max, 345 nm) without decarboxylation. Extracts of the benzene nucleus; this is followed by decarboxylation to give the 393-nm species, which gives rise to isobutyrate, acetaldehyde, and pyruvate by the hydrolytic route of meta cleavage of catechols, via 4-hydroxy-2-oxovalerate. This was confirmed with a mutant of P. putida PL-RF-1 that was unable to grow with p-cymene (or p-cumate) but was able to oxidize both compounds AND 2,3-DIHYDROXY-P-CUMATE TO A YELLOW INTERMEDIATE (LAMBDA MAX, 345 NM) WITHOUT DECARBOXYLATION. Extrats of P. putida PL-W (wild type) or a revertant of the mutant PL-RF-1 catalyzed the decarboxlation of the 345-nm intermediate with transient formation of the compound that absorbed at 393 nm. The substrate specificities of the 3,4-dioxygenative ring cleavage enzyme, and the decarboxylase were determined in crude extracts of P. putida PL-W and Pseudomonas fluorescens 007. It was conclude that 3,4-dioxygenative cleavage and decarboxylation are sequential enzyme-catalyzed reactions common to both P. putida and P. fluorescens for the oxidation of 2,3-dihydroxybenzoates. Unlike P. putida PL-W, which exclusively use the hydrolase branch, P. fluorescens 007 uses the dehydrogenase branch of the meta pathways that diverge after ring cleavage and later converge at oxoenate intermediates.     

Biotransformations catalyzed by cloned p-cymene monooxygenase from Pseudomonas putida F1

p-Cymene monooxygenase (CMO) from Pseudomonas putida F1 consists of a hydroxylase (CymA1) and a reductase component (CymA2) which initiate pcymene (p-isopropyltoluene) catabolism by oxidation of the methyl group to p-isopropylbenzyl alcohol (p-cumic alcohol). To study the possible diverse range of substrates catalyzed by CMO, the cymA1A2 genes were cloned in an Escherichia coli pT7-5 expression system and the cells were used in transformation experiments. The tested substrates include different substituents on the aromatic ring at the 2 (ortho), 3 (meta) or 4 (para) position relative to the methyl moiety. As a result, a distinct preference was observed for substrates containing at least an alkyl or heteroatom substituent at the para-position of toluene. The conversion rate of 4-chlorotoluene or 4-methylthiotoluene to the corresponding benzyl alcohol was found to be as good as the canonical substrate, p-cymene. But 3-chlorotoluene, 4-fluorotoluene and 4-nitrotoluene were relatively poor substrates. CMO is also capable of producing styrene oxide from styrene. However, the oxidation of 4-chlorostyrene to 4-chlorostyrene oxide was by far the fastest among the substrates used in this study. The various biotransformation products were identified by a combined solid phase microextraction/gas chromatographic-mass spectrometric analytical technique.     

Plasmid control of the Pseudomonas aeruginosa and Pseudomonas putida phenotypes and of linalool and p-cymene oxidation.

Two Pseudomonas strains (PpG777 and PaG158) were derived from the parent isolate Pseudomonas incognita (putida). Strain PpG777 resembles the parental culture in growth on linalool as a source of carbon and slight growth on p-cymene, whereas PaG158 grows well on p-cymene, but not on linalool or other terpenes tested, and has a P. aeruginosa phenotype. Curing studies indicate that linalool metabolism is controlled by an extrachromosomal element whose loss forms a stable strain PaG158 with the p-cymene growth and P. aeruginosa phenotype characters. The plasmid can be transferred by PpG777 to both P. putida and P. aeruginosa strains. Surprisingly, the latter assume the P. putida phenotype. We conclude that the genetic potential to oxidize p-cymene is inherent in PpG777 but expression is repressed. Similarly, this observation implies that support of linalool oxidation effectively conceals the P. aeruginosa character.     

The SOS-like reactions of Pseudomonas putida

Under ultraviolet radiation of Pseudomonas putida 1087 the SOS-similar response which is expressed in the inhibition of cell respiration and cell division with the following filamentation is revealed. In the result of introduction of pPE24 and pMH21 plasmids into the cells of P. putida 1087 for inhibition of RecA-similar protein the SOS-similar response disappears and the basic cell mass dies.     

Exchange reactions catalyzed by methioninase from Pseudomonas putida.

Highly purified methioninase from Pseudomonas putida, which catalyzes alpha, gamma-elimination reactions of homocysteine and its S-substituted derivatives as well as alpha, beta-elimination reactions of cysteine and its derivatives, was found to catalyze exchange reactions between the substituent at the gamma-carbon of homocysteine substrates and exogenously added alkanethiols, forming the corresponding S-alkylhomocysteines. It also catalyzed similar beta-exchange reactions between cysteine and alkanethiols. Thus, all the substrates for the methioninase-catalyzed elimination reactions also appear to be available for the exchange reactions.     

Metabolism of resorcinylic compounds by bacteria: orcinol pathway in Pseudomonas putida.

Enrichment cultures yielded two strains of Pseudomonas putida capable of growth with orcinol (3,5-dihydroxytoluene) as the sole source of carbon. Experiments with cell suspensions and cell extracts indicate that orcinol is metabolized by hydroxylation of the benzene ring followed successively by ring cleavage and hydrolyses to give 2 mol of acetate and 1 mol of pyruvate per mol of orcinol as shown: orcinol leads to 2,3,5-trihydroxytoluene leads to 2,4,6-trioxoheptanoate leads to acetate + acetylpyruvate leads to acetate + pyruvate. Evidence for this pathway is based on: (i) high respiratory activities of orcinol-grown cells towards 2,3,5-trihydroxytoluene; (ii) transient accumulation of a quinone, probably 2-hydroxy-6-methyl-1,4-benzoquinone, during grouth with orcinol; (iii) formation of pyruvate and acetate from orcinol, 2,3,5-trihydroxytoluene, and acetylpyruvate catalyzed by extracts of orcinol, but not by succinate-grown cells; (iv) characterization of the product of oxidation of 3-methylcatechol (an analogue of 2,3,5-trihydroxytoluene) showing that oxygenative cleavage occurs between carbons bearing methyl and hydroxyl substituents; (v) transient appearance of a compound having spectral properties similar to those of acetylpyruvate during 2,3,5-trihydroxytoluene oxidation by extracts of orcinol-grown cells. Orcinol hydroxylase exhibits catalytic activity when resorcinol or m-cresol is substituted for orcinol; hydroxyquinol and 3-methylcatechol are substrates for the ring cleavage enzyme 2,3,5-trihydroxytoluene-1,2-oxygenase. The enzymes of this pathway are induced by growth with orcinol but not with glucose or succinate.     

Initial reactions in the oxidation of naphthalene by Pseudomonas putida.

A strain of Pseudomonas putida that can utilize naphthalene as its sole source of carbon and energy was isolated from soil. A mutant strain of this organism, P. putida 119, when grown on glucose in the presence of naphthalene, accumulates optically pure (+)-cis-1(R),2(S)-dihydroxy-1,2-dihydronaphthalene in the culture medium. The cis relative stereochemistry in this molecule was established by nuclear magnetic resonance spectrometry. Radiochemical trapping experiments established that this cis dihydrodiol is an intermediate in the metabolism of naphthalene by P. Fluorescens (formerly ATCC, 17483), P. putida (ATCC, 17484), and a Pseudomonas species (NCIB 9816), as well as the parent strain of P. putida described in this report. Formation of the cis dihydrodiol is catalyzed by a dioxygenase which requires either NADH or NADPH as an electron donor. A double label procedure is described for determining the origin of oxygen in the cis dihydrodiol under conditions where this metabolite would not normally accumulate. Several aromatic hydrocarbons are oxidized by cell extracts prepared from naphthalene-grown cells of P. putida. The cis dihydrodiol is converted to 1,2-dihydroxynaphthalene by an NAD+-dependent dehydrogenase. This enzyme is specific for the (+) isomer of the dihydrodiol and shows a primary isotope effect when the dihydrodiol is substituted at C-2 with deuterium.     

Characterization of genes involved in the initial reactions of 4-chloronitrobenzene degradation in Pseudomonas putida ZWL73

The genes encoding enzymes involved in the initial reactions during degradation of 4-chloronitrobenzene (4CNB) were characterized from the 4CNB utilizer Pseudomonas putida ZWL73, in which a partial reductive pathway was adopted. A DNA fragment containing genes coding for chloronitrobenzene nitroreductase (CnbA) and hydroxylaminobenzene mutase (CnbB) were PCR-amplified and subsequently sequenced. These two genes were actively expressed in Escherichia coli, and recombinant E. coli cells catalyzed the conversion of 4CNB to 2-amino-5-chlorophenol, which is the ring-cleavage substrate in the degradation of 4CNB. Phylogenetic analyses on sequences of chloronitrobenzene nitroreductase and hydroxylaminobenzene mutase revealed that these two enzymes are closely related to the functionally identified nitrobenzene nitroreductase and hydroxylaminobenzene mutase from Pseudomonas strains JS45 and HS12. The nitroreductase from strain ZWL73 showed a higher specific activity toward 4CNB than nitrobenzene (approximately at a ratio of 1.6:1 for the recombinant or 2:1 for the wild type), which is in contrast to the case where the nitroreductase from nitrobenzene utilizers Pseudomonas pseudoalcaligenes JS45 with an apparently lower specific activity against 4CNB than nitrobenzene (0.16:1) [Kadiyala et al. Appl Environ Microbiol 69:6520–6526, 2003]. This suggests that the nitroreductase from 4-chloronitrobenzene utilizer P. putida ZWL73 may have evolved to prefer chloronitrobenzene to nitrobenzene as its substrate.Y.X. and J.-F.W. equally contributed to this work.     

D-lysine catabolic pathway in Pseudomonas putida: interrelations with L-lysine catabolism

The isolation of several mutant strains blocked in l-lysine degradation has permitted an assessment of the physiological significance of enzymatic reactions related to lysine metabolism in Pseudomonas putida. Additional studies with intact cells involved labeling of metabolic intermediates from radioactive l- or d-lysine, and patterns of enzyme induction in both wild-type and mutant strains. These studies lead to the conclusions that from l-lysine, the obligatory pathway is via delta-aminovaleramide, delta-aminovalerate, glutaric semialdehyde, and glutarate, and that no alternative pathways from l-lysine exist in our strain. A distinct pathway from d-lysine proceeds via Delta(1)-piperideine-2-carboxylate, l-pipecolate, and Delta(1)-piperideine-6-carboxylate (alpha-aminoadipic semialdehyde). The two pathways are independent in the sense that certain mutants, unable to grow on l-lysine, grow at wild-type rates of d-lysine, utilizing the same intermediates as the wild type, as inferred from labeling studies. This finding implies that lysine racemase in our strain, while detectable in cell extracts, is not physiologically functional in intact cells at a rate that would permit growth of mutants blocked in the l-lysine pathway. Pipecolate oxidase, a d-lysine-related enzyme, is induced by d-lysine and less efficiently by l-lysine. Aminooxyacetate virtually abolishes the inducing activity of l-lysine for this enzyme, suggesting that lysine racemase, although functionally inactive for growth purposes, may still have regulatory significance in permitting cross-induction of d-lysine-related enzymes by l-lysine, and vice versa. This finding suggests a mechanism in bacteria for maintaining regulatory patterns in pathways that may have lost their capacity to support growth. In addition, enzymatic studies are reported which implicate Delta(1)-piperideine-2-carboxylate reductase as an early step in the d-lysine pathway.     

Genetic control of the histidine dissimilatory pathway in Pseudomonas putida

Summary In P. putida the first four enzymes involved in the dissimilation of histidine are induced by the first intermediate of the pathway, urocanic acid. The genes specifying these enzymes, hutH, hutU, hutF and (probably) hutI appear to be clustered on the chromosome between pcaE and pcaA (genes involved in p-hydroxybenzoic acid catabolism). Two mutants which produce the histidine-dissimilitory enzymes constitutively have been isolated. They appear to carry mutations in a regulatory locus, which maps in the same region as the structural genes of the pathway.     

Biodegradation of nitrobenzene through a hybrid pathway in Pseudomonas putida

The biodegradation of nitrobenzene was attempted by using Pseudomonas putida TB 103 which possesses the hybrid pathway combining the tod and the tol pathways. Analysis of the metabolic flux of nitrobenzene through the hybrid pathway indicated that nitrobenzene was initially oxidized to cis-1,2-dihydroxy-3-nitrocyclohexa-3,5-diene by toluene dioxygenase in the tod pathway and then channeled into the tol pathway, leading to the complete biodegradation of nitrobenzene. A crucial metabolic step redirecting the metabolic flux of nitrobenzene from the tod to the tol pathway was determined from the genetic and biochemical studies on the enzymes involved in the tol pathway. From these results, it was found that toluate-cis-glycol dehydrogenase could convert cis-1,2-dihydroxy-3-nitrocyclohexa-3,5-diene to catechol in the presence of NAD(+) with liberation of nitrite and the reduced form of NAD(+) (NADH) into the medium. (c) 1995 John Wiley & Sons, Inc.     

Chromium reduction in Pseudomonas putida.

Reduction of hexavalent chromium (chromate) to less-toxic trivalent chromium was studied by using cell suspensions and cell-free supernatant fluids from Pseudomonas putida PRS2000. Chromate reductase activity was associated with soluble protein and not with the membrane fraction. The crude enzyme activity was heat labile and showed a Km of 40 microM CrO4(2-). Neither sulfate nor nitrate affected chromate reduction either in vitro or with intact cells.     

Inducible degradation of hydroxyproline in Pseudomonas putida: pathway regulation and hydroxyproline uptake

Studies in Pseudomonas putida of the inducible degradation of hydroxyproline to alpha-ketoglutarate have indicated that either of the two epimers, hydroxy-l-proline or allohydroxy-d-proline, acts as an inducer of all the pathway enzymes. In a mutant lacking the first enzyme of the sequence, hydroxyproline-2-epimerase, which interconverts these two hydroxyproline epimers, either epimer is still equally active as an inducer of the remaining three enzymes, suggesting that each epimer has intrinsic inducer activity. The second and third enzymes of the sequence were induced coordinately. The induction process appeared to be insensitive to catabolite repression under a number of experimental conditions. The induced enzymes were stable even under conditions of nitrogen starvation and other conditions designed to increase protein turnover. In addition to inducing the degradative enzymes, the two hydroxyproline epimers were also found to induce an uptake system that concentrates hydroxyproline intracellularly. Either amino acid induced the uptake system for its epimer as well as for itself.     

A novel metabolic pathway for creatinine degradation in Pseudomonas putida 77

Abstract A simple and rapid method is described to determine the plasmid content of cyanobacteria. This procedure is a modification of the Eckhardt in-well lysis and agarose gel electrophoresis technique and can be used for both unicellular and filamentous cyanobacteria.     

Regulation of enzymes of the 3,5-xylenol-degradative pathway in Pseudomonas putida: evidence for a plasmid.

Constitutive synthesis of enzymes responsible for methyl group oxidation in 3,5-xylenol degradation and an associated p-cresol methylhydroxylase in Pseudomonas putida NCIB 9869 was shown by their retention at high specific activities in cells transferred from 3,5-xylenol medium to glutamate medium. The specific activities of other enzymes of the 3,5-xylenol pathway declined upon removal of aromatic substrate, consistent with their inducible control. Specific activities of the methyl-oxidizing enzymes showed an eventual decline concomitant with a decrease in the fraction of bacteria capable of growth with 3,5-xylenol; a simultaneous loss of the ability to grow with m-hydroxybenzoate was also observed. The property of 3,5-xylenol utilization could be transferred to another strain of P. putida. It is proposed that enzymes of the 3,5-xylenol pathway and those for conversion of p-cresol to p-hydroxybenzoate are plasmid encoded, that the early methyl-oxidizing enzymes are expressed constitutively, and that the later enzymes are inducible.