915 resultados para PCR-DGGE
Resumo:
Das Wachstum von Milchsäurebakterien-Arten der Gattungen Lactobacillus, Pediococcus und Leuconostoc während der Weinfermentation kann durch die Bildung verschiedener Stoffwechselprodukte zu Weinfehlern führen. Um rechtzeitig Gegenmaßnahmen ergreifen zu können und einem Weinverderb vorzubeugen, bedarf es geeigneter Identifizierungsmethoden. Klassische mikrobiologische Methoden reichen oft nicht aus, um Mikroorganismen auf Art- und Stammniveau gezielt zu identifizieren. Wegen ihrer schnellen Durchführbarkeit und Zuverlässigkeit sind molekularbiologische Identifizierungsmethoden zur Kontrolle der mikrobiellen Flora während der Lebensmittelfermentierung in der heutigen Zeit unabdingbar. In der vorliegenden Forschungsarbeit wurden die 23S rRNA-Gensequenzen von neun Pediococcus-Typstämmen sequenziert, analysiert und phylogenetische Analysen durchgeführt. Zur Art-Identifizierung der Pediokokken wurden PCR-Primer generiert und ein Multiplex PCR System entwickelt, mit dem alle typischen Arten simultan in einer Reaktion nachgewiesen werden konnten. Die Ergebnisse der Multiplex PCR-Identifizierung von 62 Pediococcus-Stämmen aus Kulturensammlungen und 47 neu isolierten Stämmen aus Wein zeigten, dass einige Stämme unter falschen Artnamen hinterlegt waren, und dass P. parvulus im Weinanbaugebiet Rheinhessen weit verbreitet war. Die Fähigkeit der Pediococcus-Stämme zur Exopolysaccharid-Synthese wurde durch den Nachweis zweier Gene überprüft. Auf Basis der 23S rDNA-Sequenzen wurden rRNA-Sekundärstrukturen mit der neu entwickelten Software Structure Star generiert, die zum Auffinden von Zielbereichen für fluoreszenzmarkierte DNA-Sonden geeignet waren. Die Sequenzunterschiede zwischen den Pediococcus-Arten reichten aus, um zwei Gruppen durch Fluoreszenz in situ Hybridisierung differenzieren zu können. Die Verwendung unmarkierter Helfer-sonden verbesserte die Zugänglichkeit der Sonden an die rRNA, wodurch das Fluoreszenz-Signal verstärkt wurde. Um Milchsäurebakterien durch Denaturierende Gradienten Gel Elektrophorese differenzieren zu können, wurden Primer entwickelt, mit denen ein hochvariabler 23S rDNA-Bereich amplifiziert werden konnte. Die Nested Specifically Amplified Polymorphic DNA (nSAPD)-PCR wurde in der vorliegenden Arbeit zur Art- und Stamm-Differenzierung pro- und eukaryotischer Organismen angewandt. Es wurden vor allem weinrelevante Milchsäurebakterien der Gattungen Oenococcus, Lactobacillus, Pediococcus und Leuconostoc und Hefen der Gattungen Dekkera / Brettanomyces und Saccharomyces untersucht. Die Cluster-Analyse der Pediococcus-Typstämme führte zu einer unterschiedlichen Baum-Topologie im Vergleich zum phylogenetischen 23S rDNA-Stammbaum. Die Verwandtschaftsverhältnisse der untersuchten O. oeni-Stämme aus Starterkulturen konnten in Bezug auf eine frühere Cluster-Analyse reproduziert werden. Die Untersuchung von 40 B. bruxellensis-Stämmen aus rheinhessischen Weinproben zeigte eine Gruppierung der Stämme gemäß dem Ort der Probennahme. Beim Vergleich der Verwandtschaftsverhältnisse von Stämmen der Arten P. parvulus und B. bruxellensis, die aus denselben Weinproben isoliert wurden, konnte eine hohe Übereinstimmung der beiden Baum-Topologien beobachtet werden. Anhand der SAPD-PCR Untersuchung von Sekthefen aus Starterkulturen konnten alle Stämme der Art S. cerevisiae zugeordnet werden. Die nSAPD-PCR war darüber hinaus geeignet, um höhere Eukaryoten wie Weinreben zu differenzieren und es konnten die Verwandtschaftsverhältnisse von Mäusen und menschlichen Individuen durch Cluster-Analysen nachvollzogen werden. Mit Hilfe der Sequence Characterized Amplified Region (SCAR)-Technik wurden (n)SAPD-Marker in SCAR-Marker konvertiert. Die neu generierten SCAR-Primer konnten zur simultanen Art-Identifizierung von sieben weinschädlichen Milchsäurebakterien in einer Multiplex PCR erfolgreich eingesetzt werden. Die in dieser Arbeit entwickelten molekularbiologischen Identifizierungsmethoden können zum Beispiel in der mikrobiologischen Qualitätskontrolle Anwendung finden.
Resumo:
Gut microbial acquisition during the early stage of life is an extremely important event since it affects the health status of the host. In this contest the healthy properties of the genus Bifidobacterium have a central function in newborns. The aim of this thesis was to explore the dynamics of the gut microbial colonization in newborns and to suggest possible strategies to maintain or restore a correct balance of gut bacterial population in infants. The first step of this work was to review the most recent studies on the use of probiotics and prebiotics in infants. Secondly, in order to prevent or treat intestinal disorders that may affect newborns, the capability of selected Bifidobacterium strains to reduce the amount of Enterobacteriaceae and against the infant pathogen Streptococcus agalactiae was evaluated in vitro. Furthermore, the ability of several commercial fibers to stimulate selectively the growth of bifidobacterial strains was checked. Finally, the gut microbial composition in the early stage of life in response to the intrapartum antibiotic prophylaxis (IAP) against group B Streptococcus was studied using q-PCR, DGGE and next generation sequencing. The results globally showed that Bifidobacterium breve B632 strain is the best candidate for the use in a synbiotic product coupled to a mixture of two selected prebiotic fibers (galactooligosaccharides and fructooligosaccharides) for gastrointestinal disorders in infants. Moreover, the early gut microbial composition was affected by IAP treatment with infants showing lower counts of Bifidobacterium spp. and Bacteroides spp. coupled to a decrement of biodiversity of bacteria, compared to control infants. These studies have shown that IAP could affect the early intestinal balance in infants and they have paved the way to the definition of new strategies alternative to antibiotic treatment to control GBS infection in pregnant women.
Resumo:
The investigation of phylogenetic diversity and functionality of complex microbial communities in relation to changes in the environmental conditions represents a major challenge of microbial ecology research. Nowadays, particular attention is paid to microbial communities occurring at environmental sites contaminated by recalcitrant and toxic organic compounds. Extended research has evidenced that such communities evolve some metabolic abilities leading to the partial degradation or complete mineralization of the contaminants. Determination of such biodegradation potential can be the starting point for the development of cost effective biotechnological processes for the bioremediation of contaminated matrices. This work showed how metagenomics-based microbial ecology investigations supported the choice or the development of three different bioremediation strategies. First, PCR-DGGE and PCR-cloning approaches served the molecular characterization of microbial communities enriched through sequential development stages of an aerobic cometabolic process for the treatment of groundwater contaminated by chlorinated aliphatic hydrocarbons inside an immobilized-biomass packed bed bioreactor (PBR). In this case the analyses revealed homogeneous growth and structure of immobilized communities throughout the PBR and the occurrence of dominant microbial phylotypes of the genera Rhodococcus, Comamonas and Acidovorax, which probably drive the biodegradation process. The same molecular approaches were employed to characterize sludge microbial communities selected and enriched during the treatment of municipal wastewater coupled with the production of polyhydroxyalkanoates (PHA). Known PHA-accumulating microorganisms identified were affiliated with the genera Zooglea, Acidovorax and Hydrogenophaga. Finally, the molecular investigation concerned communities of polycyclic aromatic hydrocarbon (PAH) contaminated soil subjected to rhizoremediation with willow roots or fertilization-based treatments. The metabolic ability to biodegrade naphthalene, as a representative model for PAH, was assessed by means of stable isotope probing in combination with high-throughput sequencing analysis. The phylogenetic diversity of microbial populations able to derive carbon from naphthalene was evaluated as a function of the type of treatment.
Resumo:
Musculoskeletal infections are infections of the bone and surrounding tissues. They are currently diagnosed based on culture analysis, which is the gold standard for pathogen identification. However, these clinical laboratory methods are frequently inadequate for the identification of the causative agents, because a large percentage (25-50%) of confirmed musculoskeletal infections are false negatives in which no pathogen is identified in culture. My data supports these results. The goal of this project was to use PCR amplification of a portion of the 16S rRNA gene to test an alternative approach for the identification of these pathogens and to assess the diversity of the bacteria involved. The advantages of this alternative method are that it should increase sample sensitivity and the speed of detection. In addition, bacteria that are non-culturable or in low abundance can be detected using this molecular technique. However, a complication of this approach is that the majority of musculoskeletal infections are polymicrobial, which prohibits direct identification from the infected tissue by DNA sequencing of the initial 16S rDNA amplification products. One way to solve this problem is to use denaturing gradient gel electrophoresis (DGGE) to separate the PCR products before DNA sequencing. Denaturing gradient gel electrophoresis (DGGE) separates DNA molecules based on their melting point, which is determined by their DNA sequence. This analytical technique allows a mixture of PCR products of the same length that electrophoreses through agarose gels as one band, to be separated into different bands and then used for DNA sequence analysis. In this way, the DGGE allows for the identification of individual bacterial species in polymicrobial-infected tissue, which is critical for improving clinical outcomes. By combining the 16S rDNA amplification and the DGGE techniques together, an alternative approach for identification has been used. The 16S rRNA gene PCR-DGGE method includes several critical steps: DNA extraction from tissue biopsies, amplification of the bacterial DNA, PCR product separation by DGGE, amplification of the gel-extracted DNA, and DNA sequencing and analysis. Each step of the method was optimized to increase its sensitivity and for rapid detection of the bacteria present in human tissue samples. The limit of detection for the DNA extraction from tissue was at least 20 Staphylococcus aureus cells and the limit of detection for PCR was at least 0.05 pg of template DNA. The conditions for DGGE electrophoreses were optimized by using a double gradient of acrylamide (6 – 10%) and denaturant (30-70%), which increased the separation between distinct PCR products. The use of GelRed (Biotium) improved the DNA visualization in the DGGE gel. To recover the DNA from the DGGE gels the gel slices were excised, shredded in a bead beater, and the DNA was allowed to diffuse into sterile water overnight. The use of primers containing specific linkers allowed the entire amplified PCR product to be sequenced and then analyzed. The optimized 16S rRNA gene PCR-DGGE method was used to analyze 50 tissue biopsy samples chosen randomly from our collection. The results were compared to those of the Memorial Hermann Hospital Clinical Microbiology Laboratory for the same samples. The molecular method was congruent for 10 of the 17 (59%) culture negative tissue samples. In 7 of the 17 (41%) culture negative the molecular method identified a bacterium. The molecular method was congruent with the culture identification for 7 of the 33 (21%) positive cultured tissue samples. However, in 8 of the 33 (24%) the molecular method identified more organisms. In 13 of the 15 (87%) polymicrobial cultured tissue samples the molecular method identified at least one organism that was also identified by culture techniques. Overall, the DGGE analysis of 16S rDNA is an effective method to identify bacteria not identified by culture analysis.
Resumo:
Esta tese apresenta e discute os dados obtidos a partir de trabalho experimental projetado para avaliar comparativamente o desempenho de reatores desnitrificantes em batelada, tendo etanol, metanol e gás metano como doadores de elétrons. Os experimentos foram realizados em reatores em escala de bancada. Os ensaios com gás metano objetivaram verificar a efetividade deste sub-produto de reatores anaeróbios em substituir os doadores exógenos de elétrons comumente utilizados, tais como metanol e etanol. Para alcançar o objetivo principal deste trabalho, os parâmetros cinéticos de desnitrificação, para os doadores de elétrons ensaiados, foram determinados nas diferentes condições operacionais. Além disso, as alterações ocorridas na população microbiana, ao longo do período experimental, foram avaliadas em relação à diversidade microbiana, por meio de análises microscópicas (óptica, de fluorescência e eletrônica de varredura) e da técnica de Biologia Molecular de PCR/DGGE. A completa desnitrificação foi alcançada para todos os compostos testados, e o etanol foi o doador de elétrons mais eficiente para a desnitrificação. A melhor razão carbono-nitrogênio para a desnitrificação foi igual a 1,0. Contudo, este parâmetro foi encontrado ser inadequado para utilização no processo de desnitrificação, uma vez que não expressa a capacidade real do composto usado em doar elétrons. A desnitrificação com metano ocorreu tanto na presença como na ausência de oxigênio, embora a baixas velocidades quando comparado com os outros compostos. No entanto, a configuração do reator utilizado neste estudo não foi adequada para promover a efetiva dissolução do gás metano na fase líquida. Por essa razão, sugere-se o desenvolvimento de configurações de reatores apropriadas para minimizar as resistências à transferência de massa da fase gasosa para a líquida e também desta para a biomassa.
Resumo:
A tecnologia anaeróbia tem sido utilizada com sucesso no tratamento de água residuária contendo compostos fenólicos. Recentes pesquisas incluem tais compostos entre aqueles que podem ser degradados através desse processo. O objetivo desse trabalho foi avaliar a degradação do fenol em diferentes condições nutricionais, com ênfase na redução do sulfato. Os experimentos foram realizados com meio de cultura específico para esses microrganismos anaeróbios. Foram realizados ensaios de degradação em reatores em batelada alimentados nas seguintes condições: (1) fenol e sulfato, a diferentes concentrações, com inóculo previamente enriquecido; (2) fenol, sulfato e co-substratos e; (3) fenol, sulfato e extrato de levedura. Todos os ensaios foram realizados em temperatura de 30 graus Celsius, sob agitação de 150 rpm. Foi avaliado o consumo de fenol e sulfato e, produção de metano, em função do tempo, para diferentes concentrações iniciais de fenol e sulfato. Nos ensaios com reatores alimentados com fenol (329,3 mg/l); fenol (307,3 mg/l) e sulfato (160 mg/l); fenol (322.3 mg/l), sulfato (160 mg/l) e lactato (478,16 mg/l); fenol (332,1 mg/l), sulfato (150 mg/l) e etanol (129,76 mg/l), a remoção foi de, respectivamente, 99,8%, 98,2%, 98,8% e 98,8%. Os reatores alimentados com fenol (239,7 mg/l) obtiveram 100% de eficiência na degradação em apenas 11 dias e, os reatores alimentados com fenol (234,3 mg/l) e sulfato (162,5 mg/l) e fenol (256,0 mg/l) e sulfato (500 mg/l) tiveram eficiências de degradação de, respectivamente, 98,8% e 99,3% com 17 dias de operação. Tais eficiências foram obtidas pelo acréscimo de extrato de levedura nos reatores, no início dos ensaios. A caracterização morfológica foi realizada através de microscopia óptica. A diversidade microbiana referente aos Domínios Bacteria e Archaea, além do grupo de bactérias redutoras de sulfato foi avaliada através da técnica de PCR DGGE, onde foram observadas alterações nas populações microbianas, em função das condições nutricionais. Para o Domínio Archaea não foram observadas diferenças nos ensaios realizados. Para o Domínio Bacteria e Grupo das BRS essas diferenças foram, mais facilmente, percebidas com relação ao inóculo e entre os diversos reatores. A alteração na diversidade microbiana pode ter sido decorrente da composição do meio que, nesse caso, foi específico para BRS e a composição do inóculo que continha parte previamente adaptada às BRS. Essas condições adequadas puderam propiciar surgimento e desenvolvimento de populações microbianas capazes de degradar fenol, utilizando sulfato.
Resumo:
A diversidade microbiana é geralmente considerada por seu papel nos principais processos do ecossistema, tais como a decomposição da matéria orgânica e ciclos biogeoquímicos. No entanto, informações sobre o impacto da diversidade em funções menores, como degradação de xenobióticos são escassas. Nós estudamos a partir da abordagem da \'diluição para extinção\', o papel da diversidade sobre a capacidade da comunidade microbiana em degradar o fungicida clorotalonil (organoclorado). Também estudamos o comportamento da comunidade bacteriana após aplicação do pesticida no solo com e sem biochar. A diversidade microbiana do solo natural foi alterada artificialmente por diluição, constituindo um gradiente de diversidade (SN > 10-1 > 10-3 > 10-6), seguido pela inoculação em amostras de solo estéril e posterior reestruturação (15 dias). Após a reestruturação da comunidade, as amostras foram manejadas com biochar (1% m/m) e tratadas com a dose de campo do CHT. O comportamento da comunidade bacteriana foi estudo por PCR-DGGE e qPCR do gene 16S rDNA através de um experimento com molécula fria (não radiomarcada). Enquanto a capacidade de degradação do CHT foi estudada por radiorespirometria (14C-CHT). Inicialmente, a comunidade de bactérias foi influenciada pelo gradiente de diversidade obtido por diluição. A separação dos grupos bacterianos se mostrou bastante similar nos três primeiros períodos pré-aplicação do CHT (SN > 10-1 - 10-3 > 10-6), enquanto que no período de 15 dias, a dinâmica de grupos foi alterada (SN > 10-1 > 10-3 - 10-6). O fungicida e o biochar não exerceram efeitos na comunidade bacteriana no tempo zero (imediatamente após a aplicação), a modificação no perfil da comunidade foi atribuído à diluição. Nos períodos de 21 e 42 dias, o perfil comunidade bacteriana apresentou forte modificação. Os grupos bacterianos se mostraram mais dispersos quando considerado somente o CHT. Embora, a análise de ANOSIM indicou não haver diferença nas amostras com e sem biochar, sugerindo que o clorotalonil foi quem mais contribuiu na dispersão dos grupos bacterianos. No período de 42 d, a comunidade apresentou resposta positiva, sendo observado aumentos no número de bandas e no índice de Shannon em todos tratamentos. Isto possivelmente, devido a menor concentração do fungicida disponível na solução do solo, diminuindo assim, os efeitos deletérios sobre a comunidade. Os dados de qPCR não apresentaram alteração no número de copias do gene 16S rDNA em todos os tratamentos. A remoção da diversidade impactou fortemente a capacidade da comunidade bacteriana de degradar o clorotalonil. Apesar da capacidade de degradar não ter sido perdida, a mínima alteração na diversidade promoveu elevada redução na taxa de mineralização do CHT. A dissipação do CHT se mostrou rápida (D50 < 1 dia) em todos os tratamentos, além disso, a formação de 14C-resíduos não extraíveis foi constituiu um dos principais mecanismos de dissipação do CHT. A partir da degradação do fungicida, foram detectados três metabólitos. Conclui-se que a modificação por diluição da diversidade bacteriana promoveu impacto negativo na mineralização do clorotalonil. E que a formação de resíduos não extraíveis consistiu no principal mecanismo de dissipação do CHT em ambos solos.
Resumo:
Community structure of sediment bacteria in the Everglades freshwater marsh, fringing mangrove forest, and Florida Bay seagrass meadows were described based on polymerase chain reaction-denaturing gradient gel electrophoresis (PCR-DGGE) patterns of 16S rRNA gene fragments and by sequencing analysis of DGGE bands. The DGGE patterns were correlated with the environmental variables by means of canonical correspondence analysis. There was no significant trend in the Shannon–Weiner index among the sediment samples along the salinity gradient. However, cluster analysis based on DGGE patterns revealed that the bacterial community structure differed according to sites. Not only were these salinity/vegetation regions distinct but the sediment bacteria communities were consistently different along the gradient from freshwater marsh, mangrove forest, eastern-central Florida Bay, and western Florida Bay. Actinobacteria- and Bacteroidetes/Chlorobi-like DNA sequences were amplified throughout all sampling sites. More Chloroflexi and members of candidate division WS3 were found in freshwater marsh and mangrove forest sites than in seagrass sites. The appearance of candidate division OP8-like DNA sequences in mangrove sites distinguished these communities from those of freshwater marsh. The seagrass sites were characterized by reduced presence of bands belonging to Chloroflexi with increased presence of those bands related to Cyanobacteria, γ-Proteobacteria, Spirochetes, and Planctomycetes. This included the sulfate-reducing bacteria, which are prevalent in marine environments. Clearly, bacterial communities in the sediment were different along the gradient, which can be explained mainly by the differences in salinity and total phosphorus.
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Natural environmental gradients provide important information about the ecological constraints on plant and microbial community structure. In a tropical peatland of Panama, we investigated community structure (forest canopy and soil bacteria) and microbial community function (soil enzyme activities and respiration) along an ecosystem development gradient that coincided with a natural P gradient. Highly structured plant and bacterial communities that correlated with gradients in phosphorus status and soil organic matter content characterized the peatland. A secondary gradient in soil porewater NH4 described significant variance in soil microbial respiration and β-1-4-glucosidase activity. Covariation of canopy and soil bacteria taxa contributed to a better understanding of ecological classifications for biotic communities with applicability for tropical peatland ecosystems of Central America. Moreover, plants and soils, linked primarily through increasing P deficiency, influenced strong patterning of plant and bacterial community structure related to the development of this tropical peatland ecosystem.
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The ability of a previously PCB-enriched microbial culture from Venice Lagoon marine sediments to dechlorinate pentachlorophenol (PCP) and 2,3,5-trichlorophenol (2,3,5-TCP) was confirmed under anaerobic conditions in microcosms consisting of site water and sediment. Dechlorination activities against Aroclor 1254 PCB mixture were also confirmed as control. Pentachlorophenol was degraded to 2,4,6-TCP (75.92±0.85 mol%), 3,5-DCP (6.40±0.75 mol%), and phenol (15.40±0.87 mol%). From the distribution of the different dechlorination products accumulated in the PCP-spiked cultures over time, two dechlorination pathways for PCP were proposed: (i) PCP to 2,3,4,6-TeCP, then to 2,4,6-TCP through the removal of both meta double-flanked chlorine substituents (main pathway); (ii) alternately, PCP to 2,3,5,6-TeCP, 2,3,5-TCP, 3,5-DCP, then phenol, through the removal of the para double-flanked chlorine, followed by ortho single-flanked chlorines, and finally meta unflanked chlorines (minor pathway). Removal of meta double-flanked chlorines is thus preferred over all other substituents. 2,3,5-TCP, that completely lacks double-flanked chlorines, was degraded to 3,5-DCP through removal of the ortho single-flanked chlorine, with a 99.6% reduction in initial concentration of 2,3,5-TCP by week 14. 16S rRNA PCR-DGGE using Chloroflexi-specific primers revealed a different role of the two microorganisms VLD-1 and VLD-2, previously identified as dechlorinators in the Aroclor 1254 PCB-enriched community, in the dehalogenation of chlorophenols. VLD-1 was observed both in PCP- and TCP-dechlorinating communities, whereas VLD-2 only in TCP-dechlorinating communities. This indicates that VLD-1 and VLD-2 may both dechlorinate ortho single-flanked chlorines, but only VLD-1 is able to remove double-flanked meta or para chlorines.
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Soybean ( Glycine max [L.] Merr.) root rot is an important disease of soybean under continuous cropping, and root rot is widely distributed throughout the world. This disease is extremely harmful, and it is difficult to prevent and control. The study aimed to elucidate the composition of root rot pathogenic fungal communities in the continuous cropping of soybean. In this study, we employed PCRDGGE technology to analyze the communities of root rot pathogenic fungi in soybean rhizosphere soil subjected to continuous cropping during a season with a high incidence of root rot in Heilongjiang province, China, the main soybean producing area in China. The results of 13 DGGE bands were analyzed by phylogenetic revealed that the predominant root rot pathogenic fungi in rhizosphere soil in the test area were Pythium ultimum and Fusarium species. The results of cluster analysis showed that the duration of continuous cropping, the soybean variety and the plant growth stage all had significant effects on the diversity of root rot pathogenic fungi in rhizosphere soil.
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The human activities responsible for the ambient degradation in the modern world are diverse. The industrial activities are preponderant in the question of the impact consequences for brazilian ecosystems. Amongst the human activities, the petroliferous industry in operation in Potiguar Petroliferous Basin (PPB) displays the constant risk of ambient impacts in the integrant cities, not only for the human populations and the environment, but also it reaches the native microorganisms of Caatinga ground and in the mangrove sediment. Not hindering, the elaboration of strategies of bioremediation for impacted areas pass through the knowledge of microbiota and its relations with the environment. Moreover, in the microorganism groups associated to oil, are emphasized the sulfate-reducing prokaryotes (SRP) that, in its anaerobic metabolism, these organisms participate of the sulfate reduction, discharging H2S, causing ambient risks and causing the corrosion of surfaces, as pipelines and tanks, resulting in damages for the industry. Some ancestries of PRS integrate the Archaea domain, group of microorganisms whose sequenced genomes present predominance of extremophilic adaptations, including surrounding with oil presence. This work has two correlated objectives: i) the detection and monitoring of the gene dsrB, gift in sulfate-reducing prokaryotes, through DGGE analysis in samples of mDNA of a mangrove sediment and semiarid soil, both in the BPP; ii) to relate genomic characteristics to the ecological aspects of Archaea through in silico studies, standing out the importance to the oil and gas industry. The results of the first work suggest that the petrodegraders communities of SRP persist after the contamination with oil in mangrove sediment and in semiarid soil. Comparing the populations of both sites, it reveals that there are variations in the size and composition during one year of experiments. In the second work, functional and structural factors are the probable cause to the pressure in maintenance of the conservation of the sequences in the multiple copies of the 16S rDNA gene. Is verified also the discrepancy established between total content GC and content GC of the same gene. Such results relating ribosomal genes and the ambient factors are important for metagenomic evaluations using PCR-DGGE. The knowledge of microbiota associated to the oil can contribute for a better destination of resources by the petroliferous industry and the development of bioremediation strategies. Likewise, search to lead to the best agreement of the performance of native microbiota in biogeochemical cycles in Potiguar Petroliferous Basin ecosystem
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为了考察生物脱氮系统中硝化菌群 (氨氧化菌和亚硝酸氧化菌 )的种群多样性及硝化菌群随溶解氧降低的种群变化规律 ,并建立一套行之有效的用于自养生物脱氮系统中功能微生物菌群的快速分子检测技术 ,采用DGGE (变性梯度凝胶电泳 )分子检测技术对硝化菌群的 16SrDNA的特异性PCR扩增产物进行了分析 ,结果表明 :OLAND生物脱氮系统中氨氧化菌和亚硝酸氧化菌随溶解氧的降低表现出了不同的种群变化规律 ,氨氧化菌种群多样性受溶解氧的影响非常大 ,而亚硝酸氧化菌的种群多样性比较单一 ,且不受溶解氧的影响。结合FISH (全细胞荧光原位杂交 )分析结果表明 ,在OLAND限氧稳定运行后期 ,亚硝化单胞菌属 (Nitrosomonas)是主要的氨氧化菌 ,占OLAND限氧亚硝化阶段反应器中总细菌数的 72 .5 %左右
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A diversidade genética de fungos micorrízicos arbusculares (FMA) presentes na rizosfera de genótipos de milho tropicais, selecionados como contrastantes para eficiência no uso de fósforo (P), foi avaliada pela técnica de eletroforese em gel de gradiente desnaturante (DGGE). Fragmentos de DNA ribossômico (rDNA) foram amplificados por PCR, utilizando primers específicos para as famílias Acaulosporaceae e Glomaceae de fungos micorrízicos. Na análise por DGGE, os primers para as famílias Acaulosporaceae e Glomaceae foram eficientes na diferenciação das populações micorrízicas. Os genótipos de milho tiveram uma maior influência na comunidade de FMA da rizosfera do que o nível de P no solo. Os perfis de DGGE revelaram bandas que estavam presentes somente nos genótipos eficientes no uso de P (L3 e HT3060), sugerindo que alguns grupos de FMA foram estimulados por estes genótipos. As espécies Acaulospora longula, A. rugosa, A. scrobiculata, A. morrowiae e Glomus caledonium foram encontradas somente na rizosfera dos genótipos de milho eficientes no uso de P cultivados em solos com baixo teor de fósforo. Uma maior diversidade micorrízica foi encontrada nas amostras coletadas em solos de plantio direto, comparados com solos de plantio convencional. A efetiva colonização das raízes por FMA pode aumentar a eficiência de uso de P de cultivares em solos sob baixo P, influenciando a produção de milho em solos ácidos do Cerrado.
