Alternative Naphthalene Metabolic Pathway Includes Formation of ortho-Phthalic Acid and Cinnamic Acid Derivatives in the Rhodococcus opacus Strain 3D.

Naphthalene, as a component of crude oil, is a common environmental pollutant. Biochemical and genetic aspects of naphthalene catabolism have been examined in most detail in the bacteria of Pseudomonas genus. In pseudomonads, the key intermediate in naphthalene degradation is salicylate. In this study, we investigated the ability of Rhodococcus opacus strain 3D to utilize naphthalene as a sole carbon and energy source. The characteristic feature of this strain is the inability to grow in the mineral medium supplemented with salicylate (typical intermediate of naphthalene degradation in Gram-negative bacteria). The absence of salicylate hydroxylase activity and salicylate accumulation in the course of R. opacus 3D cultivation in the mineral medium supplemented with naphthalene indicated existence of an alternative pathway of naphthalene oxidation. At the same time, R. opacus 3D was able to use monoaromatic compounds (salts of gentisic, ortho-phthalic, and 2-hydroxycinnamic acids and coumarin) as growth substrates. Based on the analysis of enzymatic activities, identification of the reaction intermediates, genetic determinants, and growth substrates, we concluded that R. opacus 3D carries out naphthalene degradation through an alternative pathway via formation of ortho-phthalic acid, which is untypical for pseudomonads. Using mass spectrometry, we showed for the first time that salicylic acid associate formed in trace amounts in the process of naphthalene degradation is not further metabolized and accumulated in the growth medium in a form of a dimer.

[Ratio [13C]/[12C] as an index for express estimation of hydrocarbon-oxidizing potential of microbiota in soil polluted with crude oil].

The hydrocarbon-oxidizing potential of soil microbiota and hydrocarbon-oxidizing microorganisms introduced into soil was studied based on the quantitative and isotopic characteristics of carbon in products formed in microbial degradation of oil hydrocarbons. Comparison of CO2 production rates in native soil and that polluted with crude oil showed the intensity of microbial mineralization of soil organic matter (SOM) in the presence of oil hydrocarbons to be higher as compared with non-polluted soil, that is, revealed a priming effect ofoil. The amount of carbon of newly synthesized organic products (cell biomass and exometabolites) due to consumed petroleum was shown to significantly exceed that of SOM consumed for production of CO2. The result of microbial processes in oil-polluted soil was found to be a potent release of carbon dioxide to the atmosphere.

[Rhizosphere strain of Pseudomonas chlororaphis capable of degrading naphthalene in the presence of cobalt/nickel].

Combination of genetic systems of degradation of polyaromatic hydrocarbons, resistance to heavy metals, and promotion of plant growth/protection is one of the approaches to the creation of polyfunctional strains for phytoremediation of soils after combined contamination with organic pollutants and heavy metals. A plant-growth-promoting rhizosphere strain Pseudomonas chlororaphis PCL1391 (pBS216*, pBS501) has been obtained, in which the nah operon of plasmid pBS216 provides naphthalene biodegradation and the cnr-like operon of plasmid pBS501 provides resistance to cobalt and nickel due to the withdrawal of heavy metal cations from the cells. In the presence of 100 microM of nickel, the viability, growth rate, and naphthalene biodegradation efficiency of the resistant strain PCL1391 (pBS216*, pBS501) were much higher as compared with the sensitive PCL1391 (pBS216). During the growth of the resistant strain, in contrast to the sensitive strain, nickel (100 microM) had no inhibiting effect on the activity of the key enzymes of naphthalene biodegradation.

[Effect of naphthalene biodegradation plasmids on physiological characteristics of rhizospheric bacteria of the genus Pseudomonas].

Specific growth rate, duration of the lag phase, stability of plasmids, and activities of the key enzymes involved in naphthalene biodegradation were studied in rhizospheric pseudomonades carrying structurally similar plasmids pOV17 and pBS216. It was demonstrated that these plasmids determined various levels of catechol 2,3-dioxygenase activities. The structural rearrangements in the plasmid pBS216 could "switch off" the genes of catechol oxidation meta-pathway. It was shown that certain combinations of biodegradation plasmids and bacterial hosts, such as Pseudomonas chlororaphis PCL1391(pBS216), P. chlororaphis PCL1391(pOV17), and P. putida 53a(pOV17), were considerably more efficient than natural variants in their growth characteristics and stability of the biodegradation activity, having a potential for bioremediation of soils polluted with polycyclic aromatic hydrocarbons (PAHs).

[Biodegradation of phenanthrene by Pseudomonas bacteria bearing rhizospheric plasmids in model plant-microbial associations]. / Biodegradatsiia fenantrena rizosfernymi plazmidosoderzhashchimi bakteriami roda Pseudomonas v model'nykh rastitel'no-mikrobnykh assotsiatsiiakh.

The consumption phenanthrene in soil by model plant-microbial associations including natural and transconjugant plasmid-bearing rhizospheric strains of Pseudomonas fluorescens and P. aureofaciens degrading polycyclic aromatic hydrocarbons was studied. It was shown that phytoremediation of soil polluted with phenanthrene in the rhizosphere of barley (Hordeum sativum L.) was inefficient with the absence of the degrading strains. Inoculation of barley seeds with both natural and transconjugant plasmid-bearing Pseudomonas strains able to degrade polycyclic aromatic hydrocarbons (PAH) protected plants from the phytotoxic action of phenanthrene and favored its degradation in soil. Rape (Brassica napus L.) was shown to be an appropriate sentinel plant, sensitive to phenanthrene, which can be used for testing the efficiency of phenanthrene degradation in soil. The biological test with the use of sensitive rape plants can be applied for estimation of the efficiency of phyto/bioremediation of PAH-polluted soils.