A case study of in situ oil contamination in a mangrove swamp (Rio De Janeiro, Brazil).

Mangroves are sensitive ecosystems of prominent ecological value that lamentably have lost much of their areas across the world. The vulnerability of mangroves grown in proximity to cities requires the development of new technologies for the remediation of acute oil spills and chronic contaminations. Studies on oil remediation are usually performed with in vitro microcosms whereas in situ experiments are rare. The aim of this work was to evaluate oil degradation on mangrove ecosystems using in situ microcosms seeded with an indigenous hydrocarbonoclastic bacterial consortium (HBC). Although the potential degradation of oil through HBC has been reported, their seeding directly on the sediment did not stimulate oil degradation during the experimental period. This is probably due to the availability of carbon sources that are easier to degrade than petroleum hydrocarbons. Our results emphasize the fragility of mangrove ecosystems during accidental oil spills and also the need for more efficient technologies for their remediation.

Presence of opportunistic oil-degrading microorganisms operating at the initial steps of oil extraction and handling / Presencia de microorganismos oportunistas degradadores de petróleo en la extracción y manipulación iniciales de petróleo

Hydrocarbon-degrading microorganisms from natural environments have been isolated and identified using culture-dependent or molecular techniques. However, there has been little research into the occurrence of microorganisms incorporated into crude oil in the initial steps of extraction and handling, which can reduce the quality of stored petroleum. In the present study, a packed-column reactor filled with autoclaved perlite soaked with crude oil was subjected to a continuous flow of sterile medium in order to determine the presence of potential hydrocarbon degraders. Microorganisms developed on the surface of the perlite within a period of 73 days. DNA was extracted from the biofilm and then PCR-amplified using 16S rRNA bacterial and archaeal primers and 18S rRNA eukaryotic primers. No amplification was obtained using archaeal primers. However, denaturing gradient gel electrophoresis (DGGE) revealed the presence of unique bands indicating bacterial and eukaryotic amplification. Excision of these bands, sequencing, and subsequent BLAST search showed that they corresponded to Bacillus sp. and Aspergillus versicolor. The fungus was later isolated from intact perlite in agar plates. A bacterial clone library was used to confirm the presence in the biofilm of a unique hydrocarbon-degrading bacterium closely related to Bacillus sp. Analysis of the petroleum components by gas chromatography showed that there n-alkanes, aromatic hydrocarbons, and carbazoles were degraded (AU)

Algunos autores han aislado e identificado microorganismos degradadores de petróleo utilizando técnicas moleculares o dependientes de cultivo. Sin embargo, se ha investigado poco la presencia de microorganismos que entran en contacto con el petróleo en las fases iniciales de su extracción y manipulación, circunstancia que puede reducir la calidad del petróleo almacenado. Mediante un reactor con una columna cargada con perlita esterilizada en autoclave y empapada de petróleo, y sujeto a un flujo continuo de medio estéril, determinamos la presencia de posibles degradadores de hidrocarburos. En la superficie de la perlita se desarrollaron microorganismos en un período de 73 días. Se extrajo el DNA del biofilm, y se amplificó por PCR con cebadores para el 16S rRNA de bacterias y arqueas y con cebadores para el 18S rRNA de eucariotas. No se obtuvo ampliación del DNA de arqueas, pero el análisis por electroforesis en gel con gradiente desnaturalizante (DGGE) reveló la presencia de bandas únicas en la amplificación de bacterias y eucariotas. La escisión de estas bandas, la secuenciación y la subsiguiente búsqueda en BLAST demostraron que correspondían a Bacillus sp. y a Aspergillus versicolor. El hongo fue aislado posteriormente en placas de agar a partir de perlita intacta. También se llevó a cabo una biblioteca genética bacteriana, que confirmó la presencia de una única bacteria degradadora de petróleo en el biofilm, muy próxima a Bacillus sp. El análisis de los componentes del petróleo por cromatografía de gases mostró que había habido degradación de n-alcanos, hidrocarburos aromáticos y carbazoles (AU)

GC and GC-MS characterization of crude oil transformation in sediments and microbial mat samples after the 1991 oil spill in the Saudi Arabian Gulf coast.

The massive oil discharge in the Saudi Arabian coast at the end of the 1991 Gulf War is used here as a natural experiment to study the ability of microbial mats to transform oil residues after major spills. The degree of oil transformation has been evaluated from the analysis of the aliphatic and aromatic hydrocarbons by gas chromatography (GC) and GC coupled to mass spectrometry (GC-MS). The oil-polluted microbial mat samples from coastal environments exhibited an intermediate degree of transformation between that observed in superficial and deep sediments. Evaporation, photo-oxidation and water-washing seemed to lead to more effective and rapid elimination of hydrocarbons than cyanobacteria and its associated microorganisms. Furthermore, comparison of some compounds (e.g. regular isoprenoid hydrocarbons or alkylnaphthalenes) in the oil collected in the area after the spill or in the mixtures retained by cyanobacterial growth gave rise to an apparent effect of hydrocarbon preservation in the microbial mat ecosystems.

Microbial mats on the Orkney Islands revisited: microenvironment and microbial community composition.

The microenvironment and community composition of microbial mats developing on beaches in Scapa Flow (Orkney Islands) were investigated. Analysis of characteristic biomarkers (major fatty acids, hydrocarbons, alcohols, and alkenones) revealed the presence of different groups of bacteria and microalgae in mats from Waulkmill and Swanbister beach, including diatoms, Haptophyceae, cyanobacteria, and sulfate-reducing bacteria. These analyses also indicated the presence of methanogens, especially in Swanbister beach mats, and therefore a possible role of methanogenesis for the carbon cycle of these sediments. High amounts of algal lipids and slightly higher numbers (genera, abundances) of cyanobacteria were found in Waulkmill Bay mats. However, overall only a few genera and low numbers of unicellular and filamentous cyanobacteria were present in mats from Waulkmill and Swanbister beach, as deduced from CLSM (confocal laser scanning microscopy) analysis. Spectral scalar irradiance measurements with fiber-optic microprobes indicated a pronounced heterogeneity concerning zonation and density of mainly anoxygenic phototrophs in Swanbister Bay mats. By microsensor and T-RFLP (terminal restriction fragment length polymorphism) analysis in Swanbister beach mats, the depth distribution of different populations of purple and sulfate-reducing bacteria could be related to the microenvironmental conditions. Oxygen, but also sulfide and other (inorganic and organic) sulfur compounds, seems to play an important role in the stratification and diversity of these two major bacterial groups involved in sulfur cycling in Swanbister beach mats.