Evidence for a transmissible catabolic plasmid in Pseudomonas putida encoding the degradation of p-cresol via the protocatechuate ortho cleavage pathway

Guiding stars to the field of dreams: Metabolically engineered pathways and microbial platforms for a sustainable lignin-based industry

Lignin is an important structural component of terrestrial plants and is readily generated during biomass fractionation in lignocellulose processing facilities. Due to lacking alternatives the majority of technical lignins is industrially simply burned into heat and energy. However, regarding its vast abundance and a chemically interesting richness in aromatics, lignin is presently regarded as the most under-utilized and promising feedstock for value-added applications. Notably, microbes have evolved powerful enzymes and pathways that break down lignin and metabolize its various aromatic components. This natural pathway atlas meanwhile serves as a guiding star for metabolic engineers to breed designed cell factories and efficiently upgrade this global waste stream. The metabolism of aromatic compounds, in combination with success stories from systems metabolic engineering, as reviewed here, promises a sustainable product portfolio from lignin, comprising bulk and specialty chemicals, biomaterials, and fuels.

A product analog bound form of 3-oxoadipate-enol-lactonase (PcaD) reveals a multifunctional role for the divergent cap domain

Lactones are a class of structurally diverse molecules that serve essential roles in biological processes ranging from quorum sensing to the aerobic catabolism of aromatic compounds. Not surprisingly, enzymes involved in the bioprocessing of lactones are often targeted for protein engineering studies with the potential, for example, of optimized bioremediation of aromatic pollutants. The enol-lactone hydrolase (ELH) represents one such class of targeted enzymes and catalyzes the conversion of 3-oxoadipate-enol-lactone into the linear β-ketoadipate. To define the structural details that govern ELH catalysis and assess the impact of divergent features predicted by sequence analysis, we report the first structural characterization of an ELH (PcaD) from Burkholderia xenovorans LB400 in complex with the product analog levulinic acid. The overall dimeric structure of PcaD reveals an α-helical cap domain positioned atop a core α/β-hydrolase domain. Despite the localization of the conserved catalytic triad to the core domain, levulinic acid is bound largely within the region of the active site defined by the cap domain, suggesting a key role for this divergent substructure in mediating product release. Furthermore, the architecture of the cap domain results in an unusually deep active-site pocket with topological features to restrict binding to small or kinked substrates. The evolutionary basis for this substrate selectivity is discussed with respect to the homologous dienelactone hydrolase. Overall, the PcaD costructure provides a detailed insight into the intimate role of the cap domain in influencing all aspects of substrate binding, turnover, and product release.

Mineralization of 4-aminobenzenesulfonate (4-ABS) by Agrobacterium sp. strain PNS-1

A bacterial strain, PNS-1, isolated from activated sludge, could utilize sulphanilic acid (4-ABS) as the sole organic carbon and energy source under aerobic conditions. Determination and comparison of 16S r DNA sequences showed that the strain PNS-1 is closely related to the species of Agrobacterium genus. Growth on 4-ABS was accompanied with ammonia and sulfate release. TOC results showed complete mineralization of sulphanilic acid. This strain was highly specific for 4-ABS as none of the sulphonated aromatics used in the present study including other ABS isomers were utilized. Strain PNS-1 could, however, utilize all the tested monocyclic aromatic compounds devoid of a sulfonate group. No intermediates could be detected either in the growth phase or with dense cell suspensions. Presence of chloramphenicol completely inhibited 4-ABS degradation by cells pregrown on succinate, indicating that degradation enzymes are inducible. No plasmid could be detected in the Agrobacterium sp. Strain PNS-1 suggesting that 4-ABS degradative genes may be chromosomal encoded.

Three types of phenol and p-cresol catabolism in phenol- and p-cresol-degrading bacteria isolated from river water continuously polluted with phenolic compounds

A total of 39 phenol- and p-cresol-degraders isolated from the river water continuously polluted with phenolic compounds of oil shale leachate were studied. Species identification by BIOLOG GN analysis revealed 21 strains of Pseudomonas fluorescens (4, 8 and 9 of biotypes A, C and G, respectively), 12 of Pseudomonas mendocina, four of Pseudomonas putida biotype A1, one of Pseudomonas corrugata and one of Acinetobacter genospecies 15. Computer-assisted analysis of rep-PCR fingerprints clustered the strains into groups with good concordance with the BIOLOG GN data. Three main catabolic types of degradation of phenol and p-cresol were revealed. Type I, or meta-meta type (15 strains), was characterized by meta cleavage of catechol by catechol 2,3-dioxygenase (C23O) during the growth on phenol and p-cresol. These strains carried C23O genes which gave PCR products with specific xylE-gene primers. Type II, or ortho-ortho type (13 strains), was characterized by the degradation of phenol through ortho fission of catechol by catechol 1,2-dioxygenase (C12O) and p-cresol via ortho cleavage of protocatechuic acid by protocatechuate 3,4-dioxygenase (PC34O). These strains carried phenol monooxygenase gene which gave PCR products with pheA-gene primers. Type III, or meta-ortho type (11 strains), was characterized by the degradation of phenol by C23O and p-cresol via the protocatechuate ortho pathway by the induction of PC34O and this carried C23O genes which gave PCR products with C23O-gene primers, but not with specific xylE-gene primers. In type III strains phenol also induced the p-cresol protocatechuate pathway, as revealed by the induction of p-cresol methylhydroxylase. These results demonstrate multiplicity of catabolic types of degradation of phenol and p-cresol and the existence of characteristic assemblages of species and specific genotypes among the strains isolated from the polluted river water.

The beta-ketoadipate pathway and the biology of self-identity

The beta-ketoadipate pathway is a chromosomally encoded convergent pathway for aromatic compound degradation that is widely distributed in soil bacteria and fungi. One branch converts protocatechuate, derived from phenolic compounds including p-cresol, 4-hydroxybenzoate and numerous lignin monomers, to beta-ketoadipate. The other branch converts catechol, generated from various aromatic hydrocarbons, amino aromatics, and lignin monomers, also to beta-ketoadipate. Two additional steps accomplish the conversion of beta-ketoadipate to tricarboxylic acid cycle intermediates. Enzyme studies and amino acid sequence data indicate that the pathway is highly conserved in diverse bacteria, including Pseudomonas putida, Acinetobacter calcoaceticus, Agrobacterium tumefaciens, Rhodococcus erythropolis, and many others. The catechol branch of the beta-ketoadipate pathway appears to be the evolutionary precursor for portions of the plasmid-borne ortho-pathways for chlorocatechol degradation. However, accumulating evidence points to an independent and convergent evolutionary origin for the eukaryotic beta-ketoadipate pathway. In the face of enzyme conservation, the beta-ketoadipate pathway exhibits many permutations in different bacterial groups with respect to enzyme distribution (isozymes, points of branch convergence), regulation (inducing metabolites, regulatory proteins), and gene organization. Diversity is also evident in the behavioral responses of different bacteria to beta-ketoadipate pathway-associated aromatic compounds. The presence and versatility of transport systems encoded by beta-ketoadipate pathway regulons is just beginning to be explored in various microbial groups. It appears that in the course of evolution, natural selection has caused the beta-ketoadipate pathway to assume a characteristic set of features or identity in different bacteria. Presumably such identities have been shaped to optimally serve the diverse lifestyles of bacteria.

Self-mobilization and organization of the genes encoding the toluene metabolic pathway of Pseudomonas mendocina KR1

The toluene metabolic pathway of Pseudomonas mendocina KR1 is chromosomally encoded, but the pathway could be transferred by conjugation from strain KR1 to the chromosome of P. aeruginosa or P. putida. Such transconjugants utilized toluene, p-cresol, and p-hydroxybenzaldehyde. However, transconjugants were unable to further transfer toluene genes to other recipients unless Pseudomonas sex factor R68.45 was present in trans. Although the genes encoding the upper pathway for toluene metabolism in P. mendocina KR1 are sufficiently linked to permit their coordinate mobilization, they were found to be encoded in three independently regulated units: one encoding toluene-4-monooxygenase, a second encoding p-cresol methylhydroxylase and p-hydroxybenzaldehyde dehydrogenase, and a third encoding p-hydroxybenzoate hydroxylase. The last two regulatory units were cloned from the chromosome of a P. aeruginosa transconjugant onto a plasmid designated pRO1999. Analysis of pRO1999 showed that genes encoding p-cresol methylhydroxylase and p-hydroxybenzaldehyde dehydrogenase are organized as an operon; the gene encoding p-hydroxybenzaldehyde dehydrogenase is transcribed first, and this is followed by transcription of the gene encoding p-cresol methylhydroxylase. This operon is regulated by a positively acting regulator. The P. mendocina KR1 gene encoding p-hydroxybenzoate hydroxylase was linked to, but independently regulated from, the genes encoding toluene-4-monooxygenase, p-cresol methylhydroxylase, and p-hydroxybenzaldehyde dehydrogenase.

Diversity of Pseudomonas plasmids: to what extent?

Results obtained in studies of the biology of Pseudomonas plasmids are presented here as a mini-review. These data indicate that plasmids are ubiquitous in Pseudomonas, but the frequency of their occurrence varies greatly in particular species, or groups of species and in different microbial habitats. Some species of Pseudomonas, for instance P. aeruginosa, possess great diversity of plasmids both from the viewpoint of their incompatibility properties and their ability to endow bacteria with additional features such as resistance to antibiotics or heavy metals, degradation of xenobiotics or inhibition of phage development.

Separation and partial characterization of the enzymes of the toluene-4-monooxygenase catabolic pathway in Pseudomonas mendocina KR1

The route of toluene degradation by Pseudomonas mendocina KR1 was studied by separating or purifying from toluene-grown cells the catabolic enzymes responsible for oxidation of p-cresol through the ring cleavage step. Enzymatic transformations corresponding to each of the metabolic steps in the proposed degradative pathway were conducted with cell-free preparations. p-Cresol was metabolized by the enzyme p-cresol methylhydroxylase to p-hydroxybenzaldehyde. p-Hydroxybenzaldehyde was further oxidized by partially purified enzyme preparations to p-hydroxybenzoate and subsequently hydroxylated to form protocatechuate. Protocatechuate was then oxidized by ortho ring cleavage.

Catabolic plasmids of environmental and ecological significance

The environmental and ecological significance of catabolic plasmids and their host strains are discussed in the context of their potential application for environmental biotechnology. Included is a comprehensive list of naturally occurring discrete catabolic plasmids isolated from either natural habitats or selective enrichment studies. General properties, such as plasmid maintenance, stability and transfer, are discussed together with the techniques for plasmid detection and monitoring in the environment. The issues concerning the construction of catabolic strains with new or broader substrate ranges and the uses of monocultures or consortia for in situ treatment are addressed.

pWW174: a large plasmid from Acinetobacter calcoaceticus encoding benzene catabolism by the beta-ketoadipate pathway

Acinetobacter calcoaceticus RJE74 contains a large transmissible catabolic plasmid, pWW174, of about 200 kb, which encodes its ability to grow on benzene (Bzn+). pWW174 was unstable in Acinetobacter hosts and was lost at high frequency in the absence of selection for Bzn+. The catabolic pathway appeared to be via benzene cis-glycol, catechol and the beta-ketoadipate (ortho) pathway. pWW174 encodes a catechol 1,2-oxygenase which is significantly more thermolabile than the chromosomally determined enzyme. pWW174 was able to complement all cat mutants (catechol to central metabolites) of A. calcoaceticus ADP1 (BD413) tested. Two regions of the plasmid were cloned, one carrying catA, the gene for catechol 1,2-oxygenase, and another carrying catBCDE, the subsequent four enzymes of the beta-ketoadipate pathway: these two regions appeared to be separated by at least 10 kbp. Hybridization indicated homology between the plasmid cat genes and the corresponding chromosomal genes of ADP1.