Transformation of low-molecular linear caprolactam oligomers by the caprolactam-degrading bacterium <Emphasis Type="Italic">Pseudomonas putida</Emphasis> BS394(pBS268)

A biosensor based on the most active caprolactam-degrading strain Pseudomonas putida BS394(pBS268) was used in the study of aerobic degradation of linear caprolactam oligomers by bacterial cells. The changes in the respiratory activity of the strain depend quantitatively on caprolactam dimer concentration, making it possible to develop biosensors for detection of caprolactam oligomers in aqueous media. Based on mass spectrometry data, the scheme of transformation of linear caprolactam oligomers by the degrader strain P. putida BS394(pBS268) was proposed for the first time. It was found that oxidative transamination to respective dicarbonic acids may be one of the mechanisms of transformation of linear caprolactam oligomers. According to the scheme proposed, the ability of the caprolactam-degrading strain to transform linear oligomers results from the broad substrate specificities of two enzymes of the caprolactam degradation pathway: 2-oxoglutarate-6-aminohexanoate transaminase and 6-oxohexanoate dehydrogenase. Transformation of linear oligomers is genetically controlled by the CAP biodegradation plasmid pBS268.     

A new pathway for bacterial catabolism of 3-hydroxybenzoic acid

Abstract This paper is the first to describe the transformation of 3-hydroxybenzoate (3-HBA) by Pseudomonas putida BS893 by a new pathway via 2,3-dihydroxybenzoate (2,3-DBA) and catechol. We have compared the intermediates and appropriate enzyme activities in P. putida BS893 (pBS241) and in a cured derivative BS662 (Bph⁻) thereof, for the ascertainment of plasmid or chromosomal genetic control over 3-HBA-catabolism. The results presented show that catabolism of 3-HBA in P. putida BS893 (pBS241) is controlled by chromosomal genes.     

Phenanthrene degradation by bacteria of the genera Pseudomonas and Burkholderia in model soil systems

Degradation of phenanthrene by strains Pseudomonas putida BS3701 (pBS1141, pBS1142), Pseudomonas putida BS3745 (pBS216), and Burkholderia sp. BS3702 (pBS1143) was studied in model soil systems. The differences in accumulation and uptake rate of phenanthrene intermediates between the strains under study have been shown, Accumulation of 1-hydroxy-2-naphthoic acid in soil in the course of phenanthrene degradation by strain BS3702 (pBS143) in a model system has been revealed. The efficiency of phenanthrene biodegradation was assessed using the mathematical model proposed previously for assessment of naphthalene degradation efficiency. The efficiency of degradation of both phenanthrene and the intermediate products of its degradation in phenanthrene-contaminated soil is expected to increase with the joint use of strains P. putida BS3701 (pBS1141, pBS1142) and Burkholderia sp. BS3702 (pBS1143).     

Effect of arsenite on the physiological and cytological properties of Pseudomonas putida strains capable of degrading polycyclic aromatic hydrocarbons]

Some physiological and cytological properties of Pseudomonas putida strains resistant to arsenite and capable of degrading polycyclic aromatic hydrocarbons were studied. The resistance of P. putida BS202 (NPL-1) to arsenite proved to be determined by chromosomal genes, while the arsenite resistance of P. putida BS238 (pBS2; pBS3031) was by plasmid-borne genes. Arsenite affected the pattern and rate of growth of strain BS202 (NPL-1) in media with naphthalene or salicylate as carbon sources; particularly, it lengthened the lag phase. Electron-microscope analysis of the strains studied did not reveal any arsenite-induced destructive changes in the cell envelope. At the same time, arsenite in the growth medium induced some alterations in the structure of the outer membrane of strain BS202 (NPL-1) and the cytoplasmic membrane of strain BS238 (pBS2; pBS3031) and, in both strains, led to an increase in the density of intramembrane particles on the EF face of the freeze-fractured cytoplasmic membrane. Arsenite resistance probably evidently protects cells of both strains from greater damage. Physiological and cytological data suggest that the mechanisms of arsenite resistance in the strains studied are different.     

Resistance of certain strains of Pseudomonas bacteria to toxic effect of heavy metal ions]

The effect of heavy metal cations (cobalt, nickel, and copper) and the anion detergent sodium dodecyl sulfate (SDS) on the barrier properties of the plasma membrane (PM) of the Co-sensitive stain Pseudomonas putida BS394 and the Co-resistant strains Pseudomonas sp. BS501 (wild-type strain) and Pseudomonas putida BS394 (pBS501) (transformed strain) was studied by high-frequency electro-orientational spectroscopy. The cations were found to rank, in order of decreasing damage inflicted on the PM, as copper > cobalt > nickel. The strains studied were found to rank, in order of increasing resistance of the PM to damage inflicted by copper and cobalt cations, as P. putida BS394 < P. putida BS394 (pBS501) < Pseudomonas sp. BS501. In order of increasing resistance to SDS, the strains ranked inversely. The strains did not differ in sensitivity to nickel cations. Investigation of the surface of intact and trypsin-treated cells by microelectrophoresis showed that the surface layers of the cell wall of wild-type and transformed cells contained increased amounts of proteins. The surface proteins of Co-resistant cells had molecular masses of 49, 40, and 32 kDa. Exposure of Co-resistant cells to trypsin considerably reduced their resistance to cobalt cations. It is assumed that the resistance of the PM of the wild-type and transformed pseudomonads to heavy metal cations is determined by plasmid pBS501 and is related to the synthesis of protective surface proteins of the cell wall.     

Involvement of naphthalene dioxygenase in indole-3-acetic acid biosynthesis by Pseudomonas putida

Two variants of plant growth-promoting strain Pseudomonas putida BS1380 harboring the naphthalene degradative plasmid pBS2 and the recombinant plasmid pNAU64 that contains the genes encoding for naphthalene dioxygenase were constructed by conjugation. The ability of this strain to produce phytohormone indole-3-acetic acid from different carbon sources was studied. Indole-3-acetic acid synthesis by these transconjugants was 15-30 times as much in contrast to a wild-type strain with glucose as the sole carbon source. No difference was observed in other carbon or nitrogen sources. It is suggested that naphthalene dioxygenase is involved in the conversion of indole-3-pyruvic acid to indole-3-acetic acid.     

Genetic and ultrastructural analysis of different mutants of Pseudomonas putida affected in the poly-3-hydroxy-n-alkanoate gene cluster

Functional analyses of the different proteins involved in the synthesis and accumulation of polyhydroxyalkanoates (PHAs) in P. putida U were performed using a mutant in which the pha locus had been deleted (PpUDeltapha). These studies showed that: (i) Pha enzymes cannot be replaced by other proteins in this bacterium, (ii) the transformation of PpDeltapha with a plasmid containing the locus pha fully restores the synthesis of bioplastics, (iii) the transformation of PpDeltapha with a plasmid harbouring the gene encoding the polymerase PhaC1 (pMCphaC1) permits the synthesis of polyesters (even in absence of phaC2ZDFI); however, in this strain (PpUDeltapha-pMCphaC1) the number of PHAs granules was higher than in the wild type, (iv) the expression of phaF in PpUDeltapha-pMCphaC1 restores the original phenotype, showing that PhaF is involved in the coalescence of the PHAs granules. Furthermore, the deletion of the phaDFI genes in P. putida U considerably decreases (> 70%) the biosynthesis of PHAs consisting of hydroxyalkanoates with aliphatic constituents, and completely prevents the synthesis of those ones containing aromatic monomers. Additional experiments revealed that the deletion of phaD in P. putida U strongly reduces the synthesis of PHA, this effect being restored by PhaF. Moreover, the overexpression of phaF in P. putida U, or in its DeltafadBA mutant, led to the collection of PHA over-producer strains.     

TOL plasmid in Pseudomonas aeruginosa PAO: thermosensitivity of self-maintenance and inhibition of host cell growth.

The TOL plasmid originally isolated in Pseudomonas putida (arvilla) mt-2 was transmissible to strains of the fluorescens group of Pseudomonas, i.e., P. putida, P. fluorescens, and P. aeruginosa, except for a strain of P. aeruginosa, strain PAO. The same strain, however, could accept the plasmid when its restriction and modification abilities were lost by mutations or by growing at high temperature. In addition, the transmissibility of the TOL plasmid from strain PAO to P. putida was low when the plasmid was modified by the donor. By using P. aeruginosa PAO carrying the TOL plasmid, the stability and genetic expression of the plasmid as well as its effect on the host cell growth were examined. Thus the self-maintenance of the plasmid was found to be thermosensitive. Furthermore, the TOL plasmid inhibited the growth of strain PAO at high temperature, accompanied by the formation of some filamentous cells. These thermosensitive properties of the TOL plasmid were host dependent and not exhibited in another strain of P. aeruginosa.     

Hybrid plasmid pBS251 containing genes for n-alkane degradation

The strain of Pseudomonas aeruginosa BS316 utilizing H-alkanes of the C6-C12 series (Alk+) harbours the 96 Md plasmid pBS250. The use of plasmid RP4 to mobilize Alk+ markers in conjugal transfer to Pseudomonas aeruginosa and Pseudomonas putida has resulted in isolation of transconjugants resistant to antibiotics (due to genes coded by plasmid RP4) and capable of growth on H-alkanes. A transconjugant from this series harbours plasmid pBS251, a derivative of plasmid RP4 containing the genes for octane and octanol catabolism. A fragment of DNA inserted into RP4 has a mol mass 3.8 Md, possesses two restriction sites for EcoRI, one site for PstI, is not restricted by SmaI and BamHI restriction endonucleases, and is localized in the region 4.5-5.7 Md on the physical map of plasmid RP4.     

Preparation of bacteria--degraders of alkylnaphthalenesulfonate by a molecular breeding method

Transconjugant strain of bacteria degraders of alkylnaphthalenesulphonate(ANS)--P Pseudomonas alcaligenes TR (NPL-41) was obtained under conditions of ANS selective pressure and flow cultivation of bacteria destructors of alkylbenzene sulphonate (ABS) P. alcaligenes TR (pABS) and naphthalene P. putida BS438 (NPL-41) and their immobilization on an inert carrier. Transconjugant P. alcaligenes TR(NPL-41) was prepared by means of conjugative transfer of plasmid NPL-41 from P. putida BS438 to P. alcaligenes TR. The check out of transconjugant under conditions of flow cultivation showed their ability to degradation of ANS. Investigation of the stability of plasmid NPL-41 in the transconjugant P. alcaligenes TR(NPL-41), obtained by molecular breeding under conditions of flow cultivation and by conjugative transfer, showed the transconjugant prepared by the former method to be more stable.     

Effects of some curing agents on phenotypic stability in Pseudomonas putida degrading ε-caprolactam

A strain of Pseudomonas putida MCM B-408 capable of utilizing ε-caprolactam (monomer of nylon-6) as the sole source of carbon and nitrogen was found to harbour a single 32-kb plasmid with the same electrophoretic mobility as that of pARI180, a reference plasmid. Acridine orange, ethidium bromide, mitomycin C and SDS failed to cure the plasmid and the phenotype. Elevated temperature alone (40°C) was found to be ineffective in curing. Phenotype, but not the plasmid, was cured at a frequency of 2.63% when acridine orange and elevated temperature (40°C) were used together. The studies therefore indicated that the phenotypic expression of caprolactam degradative genes is quite stable and that Pseudomonas putida MCM B-408 may degrade ε-caprolactam from waste-water satisfactorily without spontaneous loss of the property under adverse environmental conditions.     

Structural and functional variability of genetic systems for catabolizing polycyclic aromatic hydrocarbons in Pseudomonas putida strains

The genetic control of naphthalene, phenanthrene, and anthracene biodegradation was studied in three Pseudomonas putida strains isolated from coal tar- and oil-contaminated soils. These strains isolated from different geographical locations contained similar catabolic plasmids controlling the first steps of naphthalene conversion to salicylate (the nah1 operon), functionally inoperative salicylate hydroxylase genes, and genes of the metha-pathway of catechol degradation (the nah2 operon). Salicylate oxidation in these strains is determined by genes located in trans-position relative to the nah1 operon: in strains BS202 and BS3701, they are located on the chromosome, and in the strain BS3790, on the second plasmid.     

Inducible Uptake System for β-Carboxy-cis, cis-muconate in a Permeability Mutant of Pseudomonas putida

A procedure for the large-scale enzymatic synthesis of beta-carboxymuconate is described. When used as a growth substrate, beta-carboxymuconate selected for mutant strains of Pseudomonas putida that were permeable to polycarboxylic acid intermediates of the beta-ketoadipate pathway. One mutant organism, strain PRS2110, was investigated in detail. It differed from the parental strain in that it possessed a beta-carboxymuconate uptake system that was formed when the compound was supplied exogenously to the cells. The uptake system was not induced by beta-carboxymuconate supplied endogenously during growth with p-hydroxybenzoate. These observations suggested that beta-carboxymuconate was contained within a physical compartment of enzymes during growth with p-hydroxybenzoate. Support for this hypothesis came from the demonstration that enzymes of the beta-ketoadipate pathway were held together by weak chemical interactions during the chromatography of crude extracts of benzoategrown P. putida on diethylaminoethyl-cellulose columns.     

Growth and plasmid-encoded naphthalene catabolism of Pseudomonas putida in batch culture

Abstract The growth characteristics of Pseudomonas putida plasmid-harbouring strains which catabolize naphthalene via various pathways in batch culture with naphthalene as the sole source of carbon and energy have been investigated. The strains under study were constructed using the host strain P. putida BS394 which contained various naphthalene degradation plasmids. The highest specific growth rate was ensured by the plasmids that control naphthalene catabolism through the meta-pathway of catechol oxidation. The strains metabolizing catechol via the ortho -pathway grew at a lower rate. The lowest growth rate was observed with strain BS291 harbouring plasmid pBS4 which controls naphthalene catabolism via the gentisic acid pathway. Various pathways of naphthalene catabolism appear to allow these strains to grow at various rates which should be taken into account when constructing efficient degraders of polycyclic aromatic compounds.     

Molecular classification of IncP-9 naphthalene degradation plasmids

A large collection of naphthalene-degrading fluorescent Pseudomonas strains isolated from sites contaminated with coal tar and crude oil was screened for the presence of IncP-9 plasmids. Seventeen strains were found to carry naphthalene catabolic plasmids ranging in size from 83 to 120 kb and were selected for further study. Results of molecular genotyping revealed that 15 strains were closely related to P. putida, one to P. fluorescens, and one to P. aeruginosa. All catabolic plasmids found in these strains, with the exception of pBS216, pSN11, and p8909N-1, turned out to belong to IncP-9 beta-subgroup. Plasmids pBS216, pSN11, and p8909N-1 were identified as members of IncP-9 delta-subgroup. One plasmid, pBS2, contains fused replicons of IncP-9beta and IncP-7 groups. RFLP analyses of the naphthalene catabolic plasmids revealed that organisation of the replicon correlates well with the overall plasmid structure. Comparative PCR studies with conserved oligonucleotide primers indicated that genes for key enzymes of naphthalene catabolism are highly conserved among all studied plasmids. Three bacterial strains, P. putida BS202, P. putida BS3701, and P. putida BS3790, were found to have two different salicylate hydroxylase genes one of which has no similarity to the "classic" enzyme encoded by nahG gene. Discovery of a large group of plasmid with unique nahR suggested that the regulatory loop may also represent a variable part of the pathway for catabolism of naphthalene in fluorescent Pseudomonas spp.     

Expression of the human interferon alpha F gene in the obligate methylotroph Methylobacillus flagellatum KT and Pseudomonas putida

The expression of human leucocyte interferon alpha F gene in plasmid pLM-IFN alpha F-273 is controlled by a hybrid tac (trp-lac) promoter. A structural gene for interferon alpha F is a component of the hybrid operon lacZ'-IFN alpha F-TcR, that contains an E. coli trp-operon intercystronic region. Plasmid pLM IFN alpha F-273--directed interferon synthesis allows to obtain about 10(7) IU/l. This plasmid was cloned in broad-host-range vector plasmid pAYC31. The hybrid bi-repliconed plasmid containing interferon gene as well as its single-repliconed deletion derivatives obtained by the in vivo recombination, were introduced into obligate methylotroph Methylobacillus flagellatum KT and Pseudomonas putida PpG6. Methylotrophic strain and Pseudomonas were able to transcribe the interferon gene from E. coli tac promoter, the yield of interferon being 2-4-fold higher as compared with the one in the initial host.     

Conjugal transfer of a TOL-like plasmid and extension of the catabolic potential of Pseudomonas putida F1

Strain mX was isolated from a petrol-contaminated soil, after enrichment on minimal medium with 0.5% (v/v) meta-xylene as a sole carbon source. The strain was tentatively characterized as Pseudomonas putida and harboured a large plasmid (pMX) containing xyl genes involved in toluene or meta-xylene degradation pathways via an alkyl monooxygenase and a catechol 2,3-dioxygenase. This new TOL-like plasmid was stable over two hundred generations and was self-transferable. After conjugal transfer to P. putida F1, which possesses the Tod chromosomal toluene biodegradative pathway, the transconjugant P. putida F1(pMX) was able to grow on benzene, toluene, meta-xylene, para-xylene, and ethylbenzene compounds as the sole carbon sources. Catechol 2,3-dioxygenases of the transconjugant cells presented a more relaxed substrate specificity than those of parental cells (strain mX and P. putida F1).     

The dehalogenase gene dehI from Pseudomonas putida PP3 is carried on an unusual mobile genetic element designated DEH.

As a result of the production of two dehalogenases (DehI and DehII), Pseudomonas putida PP3 utilized halogenated alkanoic acids, such as 2-monochloropropionic acid (2MCPA), as sole sources of carbon and energy. The DehI gene (dehI) was carried on a mobile genetic element (DEH) located on the chromosome of strain PP3. DEH recombined with target plasmid DNAs at high frequencies (e.g. 3.8 x 10(-4) per RP4.5 plasmid transferred). The regulated expression of dehI was detected in P. putida, Pseudomonas aeruginosa, and Escherichia coli strains containing derivative plasmids of RP4.5 and pWW0 recombined with DEH. Movement of DEH from the unstable RP4 derivatives pNJ5000 and pMR5 resulted in the insertion of DEH into the chromosome of RecA+ strains of P. putida but not in RecA+ nor RecA- strains of E. coli. Rescue of DEH from the chromosome of P. putida KT2441 onto plasmid RP4 involved recombination at a frequency (2.7 x 10(-4) per RP4 plasmid transferred) comparable to that observed in strain PP3. The DEH element was not classified as a conventional transposon because it did not move as a discrete DNA fragment: dehI-containing inserts in plasmid DNA targets varied in size between 6 and 13 kb. In addition, DEH exhibited a marked preference for insertion into a specific site on the plasmid pWW0, but its transposition, independent of host recombinational systems, remains to be demonstrated. However, the transposonlike characteristics of DEH included the conservation of restriction endonuclease sites, high-frequency recombination with different target replicons (plasmid and chromosomal DNA), and promiscuous insertion into plasmid RP4-based replicons. Therefore, it is proposed that DEH is an unusual mobile genetic element.     

Catabolism of biphenyl by Pseudomonas putida BS 893 strain containing the biodegradation plasmid pBS241

The isolation and identification of biphenyl catabolism products in Pseudomonas putida BS 893 (pBS241) showed the presence of benzoic, m-hydroxybenzoic and cinnamic acids. The two latter compounds were not found in biphenyl degradation by other bacterial strains. P. putida BS 893 (pBS241) differed from other biphenyl-positive Pseudomonas strains in the enzyme activity. These differences may stem from peculiarities in the pathway of biphenyl catabolism controlled by plasmid pBS241.