ABSTRACT
This study aimed at evaluating potential differences among the bacterial communities from formation water and oil samples originated from biodegraded and non-biodegraded Brazilian petroleum reservoirs by using a PCR-DGGE based approach. Environmental DNA was isolated and used in PCR reactions with bacterial primers, followed by separation of 16S rDNA fragments in the DGGE. PCR products were also cloned and sequenced, aiming at the taxonomic affiliation of the community members. The fingerprints obtained allowed the direct comparison among the bacterial communities from oil samples presenting distinct degrees of biodegradation, as well as between the communities of formation water and oil sample from the non-biodegraded reservoir. Very similar DGGE band profiles were observed for all samples, and the diversity of the predominant bacterial phylotypes was shown to be low. Cloning and sequencing results revealed major differences between formation water and oil samples from the non-biodegraded reservoir. Bacillus sp. and Halanaerobium sp. were shown to be the predominant components of the bacterial community from the formation water sample, whereas the oil sample also included Alicyclobacillus acidoterrestris, Rhodococcus sp., Streptomyces sp. and Acidithiobacillus ferrooxidans. The PCR-DGGE technique, combined with cloning and sequencing of PCR products, revealed the presence of taxonomic groups not found previously in these samples when using cultivation-based methods and 16S rRNA gene library assembly, confirming the need of a polyphasic study in order to improve the knowledge of the extent of microbial diversity in such extreme environments.
Este estudo teve como objetivo comparar as comunidades bacterianas de amostras de água de formação e de óleo de reservatórios de petróleo brasileiros com diferentes graus de biodegradação usando a técnica de PCR-DGGE. O DNA ambiental foi isolado e empregado em reações de PCR com primers bacterianos, com subseqüente separação dos fragmentos de DNAr 16S em DGGE. Os produtos de PCR foram também clonados e seqüenciados, visando à afiliação taxonômica dos membros da comunidade. Os fingerprints obtidos permitiram a comparação direta entre as comunidades bacterianas das amostras de óleo com diferentes graus de biodegradação, assim como entre as comunidades da água de formação e do óleo do reservatório não biodegradado. Perfis de DGGE muito similares foram observados para todas as amostras, e a diversidade dos filotipos bacterianos predominantes mostrou-se baixa. Os resultados de clonagem e seqüenciamento revelaram diferenças mais significativas entre as amostras de água de formação e de óleo do reservatório não biodegradado. Bacillus sp. e Halanaerobium sp. mostraram-se os componentes predominantes da comunidade bacteriana da presente na amostra de água de formação, ao passo que a amostra de óleo incluiu também Alicyclobacillus acidoterrestris, Rhodococcus sp., Streptomyces sp. e Acidithiobacillus ferrooxidans. A técnica de PCR-DGGE, combinada com clonagem e seqüenciamento dos produtos de PCR, revelou a presença de grupos taxonômicos não encontrados anteriormente nestas amostras quando métodos baseados em cultivo e na construção de bibliotecas de genes RNAr 16S foram utilizados, evidenciando a necessidade de um estudo polifásico a fim de contribuir para o conhecimento da diversidade microbiana em ambientes extremos como reservatórios de petróleo.
Subject(s)
Biodiversity , Biota , Genetic Variation , In Vitro Techniques , Polymerase Chain Reaction , Petroleum/analysis , Water Reservoirs , Biodegradation, Environmental , Methods , Methods , Water SamplesABSTRACT
Finding a new microbial source of transglutaminase (MTGase) and the study of the medium composition for MTGase production were the goals of this work. A total of 200 actinomycete-like strains were isolated from Brazilian soil samples and two of them named T10b and P20 were selected based on their ability to produce 0.15 U.mL-1 and 0.25 U.mL-1 of MTGase, respectively. Strain P20 was chosen to continue the study and was identified as Streptomyces sp. In order to optimize the MTGase activity, modifications of the usual media composition described for enzyme production were tested. The strategy adopted was: (1) screening experiment for the best carbon and nitrogen sources; (2) fractional factorial design (FFD) to elucidate the key ingredients in the media (the results indicated that the soybean flour, peptone, KH2PO4 and MgSO4.7H2O had a significant effect on MTGase) production and (3) central composite design (CCD) to optimize the concentration of the key components. The experimental results were fitted to a second-order polynomial model at the 95 percent level of significance (P < 0.05). Under the proposed optimized conditions, the model predicted a MTGase activity of 1.37 U.mL-1, very closely matching the experimental activity of 1.4 U.mL-1.