Until recently, few studies were carried out in Brazil about diversity of bacterial soil communities. Aiming to characterize the bacterial population in the soil through 16S rRNA analysis, two types of soil have been analyzed: one of them characterized by intensive use where tomato, beans and corn were cultivated (CS); the other analyzed soil was under forest (FS), unchanged by man; both located in Guaíra, São Paulo State, Brazil. Using specific primers, 16S rRNA genes from metagenomic DNA in both soils were amplified by PCR, amplicons were cloned and 139 clones from two libraries were partially sequenced. The use of 16S rRNA analysis allowed identification of several bacterial populations in the soil belonging to the following phyla: Acidobacteria, Actinobacteria, Bacteroidetes, Firmicutes, Proteobacteria Verrucomicrobia in addition to the others that were not classified, beyond Archaea domain. Differences between FS and CS libraries were observed in size phyla. A larger number of phyla and, consequently, a greater bacterial diversity were found in the under-forest soil. These data were confirmed by the analyses of genetic diversity that have been carried out. The characterization of bacterial communities of soil has made its contribution by providing facts for further studies on the dynamics of bacterial populations in different soil conditions in Brazil.
Studies on the impact of Eucalyptus spp. on Brazilian soils have focused on soil chemical properties and isolating interesting microbial organisms. Few studies have focused on microbial diversity and ecology in Brazil due to limited coverage of traditional cultivation and isolation methods. Molecular microbial ecology methods based on PCR amplified 16S rDNA have enriched the knowledge of soils microbial biodiversity. The objective of this work was to compare and estimate the bacterial diversity of sympatric communities within soils from two areas, a native forest (NFA) and an eucalyptus arboretum (EAA). PCR primers, whose target soil metagenomic 16S rDNA were used to amplify soil DNA, were cloned using pGEM-T and sequenced to determine bacterial diversity. From the NFA soil 134 clones were analyzed, while 116 clones were analyzed from the EAA soil samples. The sequences were compared with those online at the GenBank. Phylogenetic analyses revealed differences between the soil types and high diversity in both communities. Soil from the Eucalyptus spp. arboretum was found to have a greater bacterial diversity than the soil investigated from the native forest area.
RESUMOEstudos sobre a atividade microbiológica que ocorre na rizosfera de diversos vegetais levaram ao descobrimento de grupos de microrganismos importantes para o desenvolvimento vegetal. Dentre eles estão as rizobactérias que são capazes de colonizar as raízes, estimulando-a diretamente ou beneficiando o crescimento e o desenvolvimento de diversas plantas. Estas bactérias são chamadas Rizobactérias Promotoras de Crescimento em Plantas (RPCP). Este trabalho teve o objetivo de isolar, identificar, testar a capacidade da solubilização de fosfato e a produção de ácido indol acético (AIA) de bactérias que habitam a rizosfera de plantas de milho. A análise parcial do gene 16S rRNA dos 58 isolados possibilitou a identificação dos gêneros, Bacillus, Burkholderia e Azospirillum, sendo os mais frequentes totalizando 68% dos isolados, seguidos de Sphingomonas, Pseudomonas, Herbaspirillum, Pantoea , Bosea. Desses, 27 apresentaram a capacidade de solubilização do fosfato e 18 foram positivos no teste colorimétrico para detecção de produção do AIA. A partir destes resultados, selecionou-se um organismo pertencente ao gênero Sphingomonas para ser testado em casa de vegetação como promotor de crescimento com as estirpes de Azospirillum brasilense (AbV5 e AbV6). As plantas foram avaliadas quanto à altura aos vinte e setenta dias após a germinação e a massa seca da parte aérea (MSPA)e parte radicular (MSPR) foi quantificada após setenta dias no encerramento do experimento. Os resultados das análises do isolado pertencente ao gênero Sphingomonas foram estatisticamente semelhantes às estirpes AbV5 e AbV6 na planta de milho indicando que este microrganismo possui potencial para ser utilizado como RPCP. Palavras-chaves: RPCP, ácido indol acético, solubilização de fosfato, Sphingomonas spp. ABSTRACT IDENTIFICATION AND EVALUATION OF BACTERIA ISOLATED FROM ROOTS OF MAIZEResearches about microbiological activity on many plants rizosphere led to the discovery of groups of important microrganisms for plants development. Among them there are the rizobacteria able to colonize the roots, stimulating directly or benefiting many plants. These bacteria are called Growth Promoting Rizobacteria or GPR. In view of this, the present study was performed, aiming to isolate, identify and test phosphate solubilization and acetic indol acid (AIA) production in bacteria that lives in maize roots. The partial analysis of the 16S rRNA gene of the 58 isolates enabled the identification of the genres Bacillus, Burkholderia and Azospirillum, and the most frequent totaling 86% of the isolates, followed by Sphingomonas, Pseudomonas, Herbaspirillum, Pantoea and Bosea. Out of the 58 isolates, 27 showed the capacity of phosphate solubilization and 18 were positive to the AIA production colorimetric detection test. From these results was chosen an organism belonging to the genre Sphingomonas to be tested at greenhouse as growth promoter with the strains Azospirillum brasiliense (AbV5 e AbV6). The plants were assessed twenty and seventy days after germination. Dry ...
SUMMARYAuxin-producing bacteria inhabit the roots of orchids and can bring benefits to the host plant. Plants of this family are multiplied by in vitro assimbiotic conditions and little is known about the role of these microorganisms for ex vitro acclimatization. Four auxin-producing rhizobacteria isolated from the specie Cattleya walkeriana were evaluated for their ability to promote survival and growth of in vitro germinated plantlets during ex vitro acclimatization. Partial sequencing of the 16S rRNA genes of bacteria cultures from root velamen of this epiphytic species identified them as Bacillus, Burkholderia, Enterobacter and Curtobacterium. The presence of indole compounds in the filtered supernatants of liquid cultures was quantified by colorimetric assay and confirmed by HPLC. Indole-3-lactic acid (ILA) and indole-3-acetaldehyde (IAAld) were present in high quantities, except in Enterobacter sp. cultures, where in indole-3-acetic acid (IAA) and indole-3-pyruvic acid (IPA) were more prevalent. These rhizobacteria were inoculated into asymbiotically-germinated plantlets of the host orchid, acclimatized in greenhouse for 90 days and assessed for their growth-promoting ability. The lowest ability to promote growth was observed for Burkholderia sp. and Curtobacterium sp., while Bacillus sp. and Enterobacter sp. improved growth in all evaluated characteristics and increased the percentage of plantlet survival. This
BackgroundThe genus Burkholderia is widespread in diverse ecological niches, the majority of known species are soil bacteria that exhibit different types of non-pathogenic interactions with plants. Burkholderia species are versatile organisms that solubilize insoluble minerals through the production of organic acids, which increase the availability of nutrients for the plant. Therefore these bacteria are promising candidates for biotechnological applications.ResultsBurkholderia sp. (R 3.25 isolate) was isolated from agricultural soil in Ponta Grossa-PR-Brazil and identified through analysis of the 16S rDNA as a strain classified as Burkholderia gladioli. The expression of membrane-bound acid phosphatase (MBAcP) was strictly regulated with optimal expression at a concentration of phosphorus 5 mM. The apparent optimum pH for the hydrolysis of p-nitrophenylphosphate (PNPP) was 6.0. The hydrolysis of PNPP by the enzyme exhibited a hyperbolic relationship with increasing concentration of substrate and no inhibition by excess of substrate was observed. Kinetic data revealed that the hydrolysis of PNPP exhibited cooperative kinetics with n = 1.3, Vm = 113.5 U/mg and K0.5 = 65 μM. The PNPPase activity was inhibited by vanadate, p-hydroxymercuribenzoate, arsenate and phosphate, however the activity was not inhibited by calcium, levamisole, sodium tartrate, EDTA, zinc, magnesium, cobalt, ouabain, oligomycin or pantoprazol.ConclusionThe synthesis of membrane-bound non-specific acid phosphatase, strictly regulated by phosphate, and its properties suggest that this bacterium has a potential biotechnological application to solubilize phosphate in soils with low levels of this element, for specific crops.
RESUMO Este trabalho teve por objetivo estimar e comparar a diversidade microbiana de um solo tratado com lodo de esgoto (BAR 1N) com o mesmo solo sem tratamento (controle). A utilização do lodo de esgoto de origem industrial ou domiciliar em solos agrícolas como adubo orgânico é considerado, atualmente, uma alternativa promissora para disposição final deste resíduo. Estudos moleculares que utilizam a análise do gene 16S rRNA permitem a obtenção de informações relevantes acerca da ecologia microbiana, pois acredita-se que apenas 10% desses microorganismos podem ser cultivados. O DNA genômico dos micro-organismos presentes em ambos os solos foi extraído, clonado e, após amplificação por PCR, foi feito o sequenciamento do gene 16S rRNA. As sequências obtidas foram submetidas à análise de similaridade de nucleotídeos com o banco de dados GenBank para que pudessem ser identificadas e classificadas. Após a análise dos filogramas observou-se um número elevado de micro-organismos não identificados nos solos analisados. Os resultados demonstraram que os filos bacterianos que se destacaram foram Acidobacteria e Proteobacteria. Análises filogenéticas revelaram diferenças entre os solos, mostrando por meio de índice de diversidade bacteriana que o solo controle apresentou maior diversidade quando comparado ao solo BAR 1N. O filo Nitrospira revelou-se significativamente afetado pela aplicação do lodo de esgoto.
Fungi constitute an important part of the soil ecosystem, playing key roles in decomposition, cycling processes, and biotic interactions. Molecular methods have been used to assess fungal communities giving a more realistic view of their diversity. For this purpose, total DNA was extracted from bulk soils cultivated with tomato (STC), vegetables (SHC), and native forest (SMS) from three sites of the Taquara Branca river basin in Sumaré County, São Paulo State, Brazil. This metagenomic DNA was used as a template to amplify fungal 18S rDNA sequences, and libraries were constructed in Escherichia coli by cloning PCR products. The plasmid inserts were sequenced and compared to known rDNA sequences in the GenBank database. Of the sequenced clones, 22 were obtained from the SMS sample, 18 from the SHC sample, and 6 from the STC sample. Although most of the clone sequences did not match the sequences present in the database, individual amplified sequences matched with Glomeromycota (SMS), Fungi incertae sedis (SMS), and Neocallimastigomycota (SHC). Most of the sequences from the amplified taxa represent uncultured fungi. The molecular analysis of variance (AMOVA) indicated that fluctuations observed of haplotypes in the composition may be related to herbicide application.
Nowadays, due to the expansion of agricultural borders, it is highly desirable to increase the sustained productivity of sugarcane cultivars using the knowledge of soil microbial communities. In this study, twelve shotgun metagenomic datasets based on genomic DNA from soil were analyzed using the Metagenomics Rapid Annotation using Subsystem Technology (MG-RAST) and Statistical Analysis of Metagenomic Profiles (STAMP) to assess differential responses for the total soil bacterial community composition and nitrogen-cycling microbial community functional potential in soils from sugarcane field with pre-harvest burning and adjacent forest in dry and wet seasons in Southeast Brazil. The soil bacterial community revealed higher abundance for Actinobacteria in forest soil than sugarcane soil in dry and wet seasons, and an opposite pattern for Proteobacteria and Planctomycetes in these soils in both seasons. The results obtained in this study based on the KEEG map suggest that the forest soil has a higher nitrogen-cycling microbial community functional potential compared to the sugarcane soil, independently of the season. The gene sequences associated with carbohydrate metabolism were the most frequent in all soil metagenomes. Taken together, the results confirm previous findings regarding the effects of forest conversion to sugarcane production area, providing new insights regarding to this conversion through the prism of the seasonality and pre-harvesting method on microbially mediated nitrogen cycle in sugarcane production fields.
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