Global ETD Search

361	Targeting novel soil glycosyl hydrolases by combining stable isotope probing and metagenomics Verastegui Pena, Yris Milusqui 14 February 2014 (has links) Soil represents the largest global reservoir of microbial diversity for the discovery of novel genes and enzymes. Both stable-isotope probing (SIP) and metagenomics have been used to access uncultured microbial diversity, but few studies have combined these two methods for accessing the biotechnological potential of soil genetic diversity and fewer yet have employed functional metagenomics for recovering novel genes and enzymes for bioenergy or bioproduct applications. In this research, I demonstrate the power of combining functional metagenomics and SIP using multiple plant-derived carbon substrates and diverse soils for characterizing active soil bacterial communities and recovering glycosyl hydrolases based on gene expression. Three disparate Canadian soils (tundra, temperate rainforest and agricultural) were incubated with five native carbon (12C) or stable-isotope labelled (13C) carbohydrates (glucose, cellobiose, xylose, arabinose and cellulose). Sampling at defined time intervals (one, three and six weeks) was followed by DNA extraction and cesium chloride density gradient ultracentrifugation. Denaturing gradient gel electrophoresis (DGGE) of all gradient fractions confirmed the recovery of labeled nucleic acids. Sequencing of original soil samples and labeled DNA fractions demonstrated unique heavy DNA patterns associated with all soils and substrates. Indicator species analysis revealed many uncultured and unclassified bacterial taxa in the heavy DNA for all soils and substrates. Among characterized taxa, Salinibacterium (Actinobacteria), Devosia (Alphaproteobacteria), Telmatospirillum (Alphaproteobacteria), Phenylobacterium (Alphaproteobacteria) and Asticcacaulis (Alphaproteobacteria) were the bacterial ???indicator species??? for the heavy substrates and soils tested. Both Actinomycetales and Caulobacterales (genus Phenylobacterium) were associated with metabolism of cellulose. Members of the Alphaproteobacteria were associated with the metabolism of arabinose and members of the order Rhizobiales were strongly associated with the metabolism of xylose. Annotated metagenomic data suggested diverse glycosyl hydrolase gene representation within the pooled heavy DNA. By screening only 2876 inserts derived from the 13C-cellulose heavy DNA, stable-isotope probing and functional screens enabled the recovery of six clones with activity against carboxymethylcellulose and methylumbelliferone-based substrates.
362	Bacterial diversity and denitrifier communities in arable soils Coyotzi Alcaraz, Sara Victoria January 2014 (has links) Agricultural management is essential for achieving optimum crop production and maintaining soil quality. Soil microorganisms are responsible for nutrient cycling and are an important consideration for effective soil management. The overall goal of the present research was to better understand microbial communities in agricultural soils as they relate to soil management practices. For this, we evaluated the differential impact of two contrasting drainage practices on microbial community composition and characterized active denitrifiers from selected agricultural sites. Field drainage is important for crop growth in arable soils. Controlled and uncontrolled tile drainage practices maintain water in the field or fully drain it, respectively. Because soil water content influences nutrient concentration, moisture, and oxygen availability, the effects of these two disparate practices on microbial community composition was compared in paired fields that had diverse land management histories. Libraries of the 16S rRNA gene were generated from DNA from 168 soil samples collected from eight fields during the 2012 growing season. Paired-end sequencing using next-generation sequencing was followed by read assembly and multivariate statistical analyses. Results showed that drainage practice exerted no measureable effect on the bacterial communities. However, bacterial communities were impacted by plant cultivar and applied fertilizer, in addition to sampled soil depth. Indicator species were only recovered for depth; plant cultivar or applied fertilizer type had no strong and specific indicator species. Among indicator species for soil depth (30-90 cm) were Chloroflexi (Anaerolineae), Betaproteobacteria (Janthinobacterium, Herminiimonas, Rhodoferax, Polaromonas), Deltaproteobacteria (Anaeromyxobacter, Geobacter), Alphaproteobacteria (Novosphingobium, Rhodobacter), and Actinobacteria (Promicromonospora). Denitrification in agricultural fields transforms nitrogen applied as fertilizer, reduces crop production, and emits N2O, which is a potent greenhouse gas. Agriculture is the highest anthropogenic source of N2O, which underlines the importance of understanding the microbiology of denitrification for reducing greenhouse gas emissions by altered management practices. Existing denitrifier probes and primers are biased due to their development based mostly on sequence information from cultured denitrifiers. To circumvent this limitation, this study investigated active and uncultivated denitrifiers from two agricultural sites in Ottawa, Ontario. Using DNA stable-isotope probing, we enriched nucleic acids from active soil denitrifiers by exposing intact replicate soil cores to NO3- and 13C6-glucose under anoxic conditions using flow-through reactors, with parallel native substrate controls. Spectrophotometric chemistry assays and gas chromatography confirmed active NO3- depletion and N2O production, respectively. Duplicate flow-through reactors were sacrificed after one and four week incubation periods to assess temporal changes due to food web dynamics. Soil DNA was extracted and processed by density gradient ultracentrifugation, followed by fractionation to separate DNA contributed by active denitrifiers (i.e., “heavy” DNA) from that of the background community (i.e., “light” DNA). Light and heavy DNA samples were analyzed by paired-end sequencing of 16S rRNA genes using next-generation sequencing. Multivariate statistics of assembled 16S rRNA genes confirmed unique taxonomic representation in heavy fractions from flow-through reactors fed 13C6-glucose, which exceeded any site-specific or temporal shifts in putative denitrifiers. Based on high relative abundance in heavy DNA, labelled taxa affiliated with the Betaproteobacteria (71%; Janthinobacterium, Acidovorax, Azoarcus, Dechloromonas), Alphaproteobacteria (8%; Rhizobium), Gammaproteobacteria (4%; Pseudomonas), and Actinobacteria (4%; Streptomycetaceae). Metagenomic DNA from the original soil and recovered heavy fractions were subjected to next-generation sequencing and the results demonstrated enrichment of denitrification genes with taxonomic affiliations to Brucella, Ralstonia, and Chromobacterium in heavy fractions of flow-through reactors fed 13C6-glucose. The vast majority of heavy-DNA-associated nitrite-reductase reads annotated to the copper-containing form (nirK), rather than the heme-containing enzyme (nirS). Analysis of recovered nirK genes demonstrated low sequence identity across common primer-binding sites used for the detection and quantification of soil denitrifiers, indicating that these active denitrifiers would not have been detected in molecular surveys of these same soils.
363	Análise fenotípica, genética e de bioatividade de isolados brasileiros de cianobactérias dos gêneros Fischerella e Hapalosiphon / Phenotypic, genetic and bioactivity analyses of Brazilian cyanobacterial isolates from the genera Fischerella and Hapalosiphon Tânia Keiko Shishido 31 August 2009 (has links) A afiliação genérica de Fischerella e Hapalosiphon é problemática devido à instabilidade dos caracteres morfológicos. Os gêneros Fischerella e Hapalosiphon são diferenciados pela presença de tricoma multisseriado e uni ou bisseriado, respectivamente. Porém, geneticamente esses caracteres não se mostraram diacríticos para diferenciar gêneros. Estudos moleculares de linhagens isoladas de ecossistemas brasileiros são escassos para Fischerella e inexistentes para Hapalosiphon. Neste estudo, oito linhagens de cianobactérias, pertencentes à família Hapalosiphonaceae, isoladas de água doce e solos brasileiros foram caracterizadas morfologicamente e geneticamente e analisadas para a produção de substâncias bioativas. As análises morfológicas identificaram cinco morfotípos de Fischerella (CENA19, CENA161, CENA212, CENA213, CENA214) e três de Hapalosiphon (CENA63, CENA71, CENA72). As análises filogenéticas do RNAr 16S usando neighbor-joining (NJ) e máxima verossimilhança (MV) colocaram todas as linhagens isoladas em um agrupamento com alto suporte (reamostragens de 99% NJ e MV) contendo membros da ordem Nostocales. Além disso, as linhagens de Fischerella selecionadas para o estudo agruparam-se em um clado interno com alto valor de reamostragem (100% NJ e 86% MV), com exceção da Fischerella CENA19. A posição dessa estirpe na árvore filogenética indica que necessita de revisão taxonômica. As linhagens de solo Hapalosiphon CENA71 e CENA72 também formaram um clado interno separado (99% NJ e 98% MV), mas a linhagem de água doce CENA63 foi colocada em um clado diferente (com valores de reamostragens de 99% NJ e MV), juntamente com linhagens do gênero Hapalosiphon e Westielopsis prolífica SAG 16.93, oriundas de solo. A comparação das análises filogenéticas individuais de regiões dos genes RNAr 16S, rpoC1, rbcL, tufA, e cpcBA-IGS das três linhagens de Hapalosiphon e de duas linhagens de Fischerella, CENA19 e CENA161, mostrou resultados incongruentes devido as diferentes taxas evolutivas desses genes. No entanto, a análise filogenética concatenada desses genes, mostrou que a Fischerella CENA19 agrupou com as duas linhagens de Hapalosiphon CENA71 e CENA72, com alto valor de reamostragem (100%), enquanto que a Fischerella CENA 161 e a Hapalosiphon CENA63 posicionaram-se cada uma em clados separados. Os resultados indicam que a nomenclatura das linhagens de cianobactérias da família Hapalosiphonaceae necessita de revisão. Os extratos intra e extracelulares das linhagens Fischerella sp. CENA161 e CENA19 e Hapalosiphon sp. CENA71 e CENA72 mostraram efeitos inibitórios no crescimento de bactérias patogênicas. As análises em espectrômetro de massas Q-TOF MS/MS indicaram a putativa presença de aeruginopeptina, cianopeptolina, fischerelina, aeruginosina, oscilapeptilida, microcistinas e ácido tumonóico nos extratos. No extrato intracelular da Fischerella sp. CENA161 identificou-se três ou quatro variantes de microcistinas, LR, LL, FR e/ou M(O)R. Fragmentos dos genes mcyA, mcyB, mcyC, mcyD, mcyE, mcyG e mcyI dessa linhagem foram seqüenciados. Nas duas análises filogenéticas realizadas com sequências de aminoácidos de McyE e sequências concatenadas de McyD, McyE e McyG, as enzimas da microcistina sintetase ficaram agrupadas de acordo com os gêneros de cianobactérias indicando um padrão de evolução / The generic affiliation of Fischerella and Hapalosiphon is problematic due to instability of morphological characters. The Fischerella and Hapalosiphon genera are differentiated by the presence of trichome multisseriate and uni or bisseriate, respectively. However, genetically these characters were not diacritical to distinguish genera. Molecular studies of strains isolated from Brazilian ecosystems are scarce for Fischerella and absent for Hapalosiphon. In this study, eight cyanobacterial strains, belonging to Hapalosiphonaceae family, isolated from Brazilian freshwater and soil were morphologically and genetically characterized and analyzed for bioactive compound productions. The morphological analyses identified five Fischerella (CENA19, CENA161, CENA212, CENA213, CENA214) and three Hapalosiphon (CENA63, CENA71, CENA72) morphotypes. The neighbor-Joining (NJ) and maximum likelihood (ML) phylogenetic analyses of 16S rRNA placed all isolated strains in high supported (99% NJ and ML of bootstrap) cluster containing members of the order Nostocales. Furthermore, the Fischerella strains studied were grouped in an internal clade with high bootstrap value (100% NJ and 86% ML), with exception of Fischerella CENA19. The position of this strain in the phylogenetic tree indicates that it needs taxonomical revision. The soil Hapalosiphon strains CENA71 and CENA72 also formed a separated tight internal clade (99% NJ and 98% ML), but the freshwater strain CENA63 was placed in a different clade (99% NJ and ML of bootstrap value) together with Hapalosiphon strains genera and Westielopsis prolifica SAG 16.93, originated from soil. The comparison of the phylogenetic analyses of individual regions of the genes 16S rRNA, rpoC1, rbcL, tufA, and cpcBA-IGS from the three Hapalosiphon strains and the two Fischerella strains CENA19 and CENA161 showed incongruent results due to different evolutionary rates of these genes. However, the concatenated phylogenetic analysis of these genes, showed that Fischerella CENA19 grouped with the two Hapalosiphon strains CENA71 and CENA72 with high bootstrap value (100%), while Fischerella CENA 161 and Hapalosiphon CENA63 were positionated each one in separate clades. The results indicate that the nomenclature of cyanobacterial strains from the family Hapalosiphonaceae needs revision. The intra and extracellular extracts of the Fischerella sp. strains CENA161 and CENA19 and Hapalosiphon sp. strains CENA71 and CENA72 showed inhibitory effects on the growth of pathogenic bacteria. The analysis in the mass spectrometer Q-TOF MS/MS indicated the presence of aeruginopeptin, cyanopeptolin, fischerellin, aeruginosin, oscillapeptilide, microcystins and tumonoic acid in the extracts. In the intracellular extracts of Fischerella sp. CENA161, three or four variants of microcystins, LR, LL, FR and/or M(O)R, were identified. Fragments of genes mcyA, mcyB, mcyC, mcyD, mcyE, mcyG and mcyI of this strain were sequenced. In both phylogenetic analyses performed with amino acid sequences of McyE and concatenated sequences of McyD, McyE and McyG, the microcystin synthetase enzymes were grouped according to the cyanobacterial genera, indicating a pattern of evolution Análise concatenada cpcAB-IGS Filogenia Microcistina Microcistina sintetase Produtos naturais Q-TOF rbcL RNAr 16S rpoC1 TufA 16S rRNA Concatenated analysis cpcAB-IGS Microcystin Microcystin synthetase Natural products Phylogeny Q-TOF rbcL rpoC1 TufA
364	Caracterização microbiana e remoção do alquilbenzeno linear sulfonado em reator EGSB / Microbial characterization and removal of linear alkylbenzene sulfonate in EGSB reactor Tiago Palladino Delforno 18 March 2011 (has links) O presente trabalho teve por objetivo avaliar a eficiência de remoção do surfactante aniônico alquilbenzeno linear sulfonado (LAS) em reator anaeróbio de leito granular expandido - EGSB (1,5 litros) com recirculação e alimentação com meio mineral. Além de caracterizar filogeneticamente a diversidade de bactérias na presença do surfactante. O sistema foi operado em condição mesofílica em 4 etapas: (I), (II) e (IV) com TDH de 32 horas, e (III) com TDH de 26 horas. Em todas as etapas a DQO foi em média de 609 \'+ OU -\' 137 mg/L e 14 \'+ OU -\' 1,71 mg/L de LAS afluente. As maiores remoções de LAS foram verificada nas etapas II e IV, com valores de 73,6 \'+ OU -\' 5,6% e 63,6 \'+ OU -\' 6,17%, respectivamente de. Na etapa III essa remoção foi de 47,8 \'+ OU -\' 6,2%. Por meio do balanço de massa constatou-se que 56,6% do total de LAS adicionado foram removidos compreendendo 48,4% por biodegradação e 8,2% por adsorção. A remoção de matéria orgânica não foi afetada com a adição do LAS e nem pela exposição prolongada a esse surfactante. Entretanto, a estrutura do grânulo foi comprometida quando da adição do surfactante, observado pelo aumento da concentração de sólidos totais efluente de 0,049 g/L na etapa I (sem LAS), 0,128 g/L na etapa II, 0,064 g/L na etapa III e 0,038 g/L na etapa IV, quando da adição de 14 \'+ OU -\' 1,71 mg LAS/L. Além disso, foi notada diminuição do diâmetro médio dos grânulos no decorrer da operação do reator de 0,36 cm nas etapas I e III para 0,34 cm na etapa IV. Por meio da técnica de tubos múltiplos (NMP) foi constatado aumento das bactérias anaeróbias totais e diminuição das arqueias metanogênicas, em função do tempo de operação do reator. As bactérias redutoras de ferro representaram 8% da biomassa anaeróbia na etapa IV. Por meio do seqüenciamento da região 16S do RNAr para o domínio Bacteria da biomassa da extremidade superior do reator e da biomassa do leito, foi verificado semelhança com os seguintes filos Proteobacteria, Firmicutes e Synergistetes. Notou-se diferença significativa entre as bibliotecas de clones para essas duas amostras. / This study aimed to evaluate the efficiency of removal of linear alkylbenzene sulfonate (LAS) in expanded bed reactor (1.5 liters) using granular sludge (EGSB) with recirculation and feed with mineral medium modified. The system was operated at mesophilic condition in four stages: (I) (II) and (IV) with HRT of 32 hours, and (III) with HRT of 26 hours. At all stages the COD averaged 609 \'+ OR -\' 137 mg/L and 14 \'+ OR -\' 1.71 mg/L LAS influent. The higher removals of LAS were found in stages II and IV, respectively, 73.6 \'+ OR -\' 5.6% and 63.6 \'+ OR -\' 6.17%. In stage III this removal was 47.8 \'+ OR -\' 6.2%. Through mass balance was found that 56.6% of total LAS added were removed by biodegradation comprising 48.4% and 8.2% by adsorption. The organic matter removal was not affected by the addition of LAS and not by prolonged exposure to this surfactant. However, the granule structure was compromised after the addition of surfactant, the observed increase in effluent total solids concentration of 0.049 g/L in stage I (no LAS), 0.128 g/L in stage II, 0.064 g/L in stage III and 0.038 g/L in stage IV when adding 14 \'+ OR -\' 1.71 mg/L. Furthermore, it was noticed significant decrease in mean diameter of the granules during the operation of the reactor of 0.36 cm in stages I and III to 0.34 cm in stage IV. Through the multiple tube method (MPN) was found to increase the total anaerobic bacteria and methanogenic archaea decreased depending on the time of reactor operation. Iron-reducing bacteria accounted for 8% of anaerobic bacteria total in step IV. By sequencing the 16S rRNA for the domain Bacteria biomass from the upper end of the reactor and the biomass of the bed, was found similar to the following phyla Proteobacteria, Firmicutes and Synergistetes. Significant difference was noted between the clone libraries for these two samples. Bactérias redutoras de ferro Biomassa granulada Degradação anaeróbia Gene RNAr 16S Surfactantes Técnica dos tubos múltiplos 16S rRNA gene Anaerobic degradation Granulated biomass Iron-reducing bacteria Multiple tubes technique Surfactants
365	Etude de la maturation et de l'assemblage du ribosome eucaryote: caractérisation fonctionnelle de nouveaux facteurs trans- / Functional charaterization of new trans- factors implicated in maturation and assembly of the eukaryotic ribosome Schillewaert, Stéphanie 28 October 2011 (has links) La synthèse du ribosome est un processus compliqué, très hiérarchisé et essentiel à toutes les cellules vivantes. La complexité de ce processus tient notamment au fait que les différentes étapes de la biogenèse du ribosome eucaryote sont temporellement et spatialement organisées dans des compartiments cellulaires différents (le nucléole, le nucléoplasme et le cytoplasme). Il est toutefois connu que le pré-ARNr 35S (le précurseur de trois des quatre ARNr, les ARNr 18S, 5.8S et 25S) est pris en charge dès sa synthèse par des facteurs impliqués dans sa maturation. Ainsi, la formation d’un ribosome requiert l’association, sur le transcrit naissant, des facteurs de synthèse, au nombre de 400. Ces facteurs essentiels interagissent transitoirement avec l’ARNr et ne font pas partie des particules ribosomiques matures impliquées dans la traduction. Leur rôle est d’assister le remodelage constant du pré-ribosome et le processus d’assemblage des sous-unités.<p>Parmi ces facteurs de synthèse, nous avons caractérisé en détail, chez la levure et chez l’homme, la protéine Las1 impliquée dans la maturation des deux extrémités de l’ITS2, séquence qui sépare les ARNr 5.8S et 25S/28S. Chez la levure, en absence de la protéine Las1, les analyses de profils de polysomes révèlent un déficit de sous-unité 60S et l’apparition d’« halfmères ». Les techniques de purification d’affinité et de gradient de sédimentation nous indiquent que Las1 est associée aux pré-ribosomes 60S et qu’elle interagit avec de nombreux facteurs de synthèse de la petite, de la grande sous-unité ou des deux. De plus, Las1 copurifie avec des pré-ribosomes qui contiennent aussi les exoribonucléases 5’-3’ Rat1/Rai1 et Xrn1. Rai1 coordonne la maturation aux deux extrémités de l’ARNr 5.8S. Nous suggérons que Las1 appartient à un macrocomplexe connectant spatialement des sites de clivages éloignés sur la séquence primaire du pré-ARNr qui seraient rapprochés suite au reploiement de l’ITS2.<p>Un autre aspect de ce travail de thèse consiste en l’étude de l’assemblage des particules ribonucléoprotéiques et plus spécifiquement du pré-ribosome et des sous-unités ribosomiques eucaryotes. Nous avons utilisé la technique d’immunoprécipitation de chromatine (Ch-IP) pour caractériser l’assemblage d’une structure appelée le « SSU processome ». Celui-ci correspond à un pré-ribosome en formation ainsi que l’assemblage des protéines ribosomiques sur l’ARNr naissant.<p>Enfin, nous avons étudié le rôle d’une plateforme d’activation de méthyltransférases d’ARN et de protéines, la protéine Trm112 dans la ribogenèse. Nous avons montré que chez la levure, Trm112 est impliquée dans la synthèse du ribosome et dans la progression de la mitose. En absence de cette protéine, les pré-ARNr sont dégradés par un mécanisme de surveillance. Trm112 copurifie avec plusieurs facteurs de synthèse du ribosome dont la méthyltransférase Bud23, impliquée dans la modification post-transcriptionnelle de l’ARNr18S. Trm112 est requise pour cette méthylation et nous postulons que la protéine Bud23 est incapable de se lier aux pré-ribosomes en l’absence de Trm112.<p> / Doctorat en Sciences / info:eu-repo/semantics/nonPublished Sciences exactes et naturelles Biologie Ribosomes -- Synthesis RNA Nucleoproteins Methyltransferases Ribosomes -- Synthèse ARN Nucléoprotéines Méthyltransférases synthèse du ribosome/ribosome synthesis nucléole/nucleolus exosome ARN/RNA exosome assemblage du ribosome/ribosome assembly
366	Characterization of the Marine Sponge Amphimedon compressa Microbiome Across a Spatial Gradient Potens, Renee Michelle 20 May 2016 (has links) Diverse and ecologically important microbial communities (microbiomes) are symbiotic within marine sponges. In this study, the microbiome of Amphimedon compressa from three sample locations (Broward and Dade Counties, Southeast Florida, USA and the Southern Caribbean, Bocas del Toro, Panama) is characterized using 16S rRNA Illumina sequencing. The predominant taxa are Proteobacteria and Cyanobacteria, as expected for Low Microbial Abundance sponges, accounting for over 53% of the total microbiome community. The numbers of Operational Taxonomic Units (OTUs) decrease from Broward County (2,900) to Dade County (2,300) and then Bocas del Toro (1,200). The correlates to a decreasing north-south gradient of sponge microbiome richness and diversity. Sponge microbiome richness and Alpha diversity are nearly identical from the two closest locations (37 km), both in Southeast Florida (Tukey HSD/ANOVA; p=0.999). However Panama sponge microbiome richness and Alpha diversity are distinctly lower, with the primary driver being distance, ~1,850 km from Southeast Florida. Abiotic factors driving this trend of decreased richness and diversity include increased temperature, and deceased salinity in relation to precipitation-based seasons. Sponge microbiome Beta diversity as determined by Bray-Curtis Dissimilarity and Non-Metric Multidimensional Scaling documents the clustering of Panama samples as distinct from the Broward and Dade County samples. In a seasonal comparison, Broward County sponge microbiome richness (p=0.026, r2=0.92) and Alpha diversity (p=0.007, r2=0.98) are significantly different, documenting robust effects of temperature. This comparison confirms lowest microbiome OTU diversity in the season with highest precipitation and highest temperatures of 29.8 °C. These results are consistent with prior studies that report decreasing microbiome OTU richness and diversity under conditions of environmental stress such as decreased salinity and increased temperatures. Genetics Genomics High-Throughput Sequencing Illumina DNA 16S rRNA Molecular Biology Microbiology Symbionts Biodiversity Genetics Laboratory and Basic Science Research Marine Biology Molecular Genetics
367	Bacterial Communities Associated with Healthy and Diseased Acropora cervicornis (Staghorn Coral) Using High-Throughput Sequencing Walton, Charles 21 July 2017 (has links) Coral diseases were first noted in the 1960s and 1970s and have had major impacts globally on coral reef community structures. In the Caribbean, a major outbreak of white band disease has been considered responsible for the drastic decline of Caribbean Acroporids since the 1970s. In addition to white band disease, another more recently described condition known as rapid tissue loss (RTL) has had major impacts on Acropora cervicornis populations, specifically offshore Broward County Southeast Florida. While these diseases have contributed to the population decline, determining their etiologies has been elusive. Coral diseases have been characterized by shifts in their microbial counterparts within many levels of the coral host. While some coral diseases have had specific pathogens identified, research has not been able to determine pathogens for most. Evidence points toward bacterial causes for many diseases, but due to the complexity of the coral holobiont and the interaction with the environment, elucidating the causes has proven difficult. Many studies have examined the microbiomes of specific diseases and determined some potential pathogens or at least taxa playing important roles in the disease, although none have looked at RTL. Recognizing the local affect of RTL on A. cervicornis, this study set out to gain a baseline understanding of the healthy and RTL affected microbiome of A. cervicornis. 16S rRNA gene sequencing was used to examine the microbiome of completely healthy colonies, healthy regions of diseased colonies, and the disease margin of diseased colonies. Analysis of four microbial diversity metrics revealed marked increases in diversity with respect to declining health states. Additionally, community dissimilarity analysis and analysis of differentially abundant taxa exhibited distinct microbial community structures due to coral health. Several highly abundant (Rickettsiales, Rhodobacteraceae) and a few low abundance (Bdellovibrionales) taxa were identified as primary drivers of the differences. Additionally, Piscirickettsiaceae, a known fish pathogen, was consistently associated with RTL and warrants further investigation. All of the taxa identified with in RTL have been associated with other Acroporid and non-Acroporid diseases throughout the Caribbean and the rest of the world. The consistent IV association of similar taxa for coral diseases around the world, including those found in this study, supports the recent ideas of non-specific primary pathogens. While most disease studies, coral and otherwise, aim to determine a single pathogen for a single disease, this study and others suggest there could be a multitude of organisms responsible for the disease. Therefore understanding the interactions of the coral holobiont and the environment is important to understanding coral disease. While this study reveals significant changes in the bacterial community associated with RTL as well as some potential pathogens, the relationships appear complex and perhaps at a functional level rather than merely taxonomic. Furthermore, this study did not examine viruses, fungi, or protists, which could be possible pathogens. Therefore, to further develop an understanding of RTL and many other coral diseases it will be necessary to consider additional none-bacterial members of the holobiont as well as the bacterial functions and taxa coupled with the roles of environmental factors. Coral Microbiome 16S rRNA gene Rapid Tissue Loss White Syndrome Microbial Diversity Microbial Ecology 454 Pyrosequencing Animal Diseases Marine Biology Other Genetics and Genomics
368	Exploration of microbial diversity and evolution through cultivation independent phylogenomics Martijn, Joran January 2017 (has links) Our understanding of microbial evolution is largely dependent on available genomic data of diverse organisms. Yet, genome-sequencing efforts have mostly ignored the diverse uncultivable majority in favor of cultivable and sociologically relevant organisms. In this thesis, I have applied and developed cultivation independent methods to explore microbial diversity and obtain genomic data in an unbiased manner. The obtained genomes were then used to study the evolution of mitochondria, Rickettsiales and Haloarchaea. Metagenomic binning of oceanic samples recovered draft genomes for thirteen novel Alphaproteobacteria-related lineages. Phylogenomics analyses utilizing the improved taxon sample suggested that mitochondria are not related to Rickettsiales but rather evolved from a proteobacterial lineage closely related to all sampled alphaproteobacteria. Single-cell genomics and metagenomics of lake and oceanic samples, respectively, identified previously unobserved Rickettsiales-related lineages. They branched early relative to characterized Rickettsiales and encoded flagellar genes, a feature once thought absent in this order. Flagella are most likely an ancestral feature, and were independently lost during Rickettsiales diversification. In addition, preliminary analyses suggest that ATP/ADP translocase, the marker for energy parasitism, was acquired after the acquisition of type IV secretion systems during the emergence of the Rickettsiales. Further exploration of the oceanic samples yielded the first draft genomes of Marine Group IV archaea, the closest known relatives of the Haloarchaea. The halophilic and generally aerobic Haloarchaea are thought to have evolved from an anaerobic methanogenic ancestor. The MG-IV genomes allowed us to study this enigmatic evolutionary transition. Preliminary ancestral reconstruction analyses suggest a gradual loss of methanogenesis and adaptation to an aerobic lifestyle, respectively. The thesis further presents a new amplicon sequencing method that captures near full-length 16S and 23S rRNA genes of environmental prokaryotes. The method exploits PacBio's long read technology and the frequent proximity of these genes in prokaryotic genomes. Compared to traditional partial 16S amplicon sequencing, our method classifies environmental lineages that are distantly related to reference taxa more confidently. In conclusion, this thesis provides new insights into the origins of mitochondria, Rickettsiales and Haloarchaea and illustrates the power of cultivation independent methods with respect to the study of microbial evolution. cultivation independent genomics metagenomics single-cell genomics metagenomic binning phylogenetics phylogenomics phylogenetic artefacts comparative genomics gene tree-species tree reconciliation rRNA amplicon sequencing Tara Oceans origin of mitochondria Alphaproteobacteria Rickettsiales Haloarchaea endosymbiosis Evolutionary Biology Evolutionsbiologi Evolutionary Biology Evolutionsbiologi
369	Étude de la régulation de l’activité de la fibrillarine : rôles des modifications post-traductionnelles / Study of fibrillarin activity regulation : roles of post-translational modifications Laforêts, Florian 01 July 2016 (has links) Le ribosome est responsable de la traduction des ARNm en protéines. Au sein du ribosome, les ARNr jouent un rôle central dans la traduction, et leurs modifications post-transcriptionnelles moduleraient l'activité traductionnelle du ribosome, impactant ainsi sur l'expression génique. Les ARNr humains contiennent 106 2'-O-méthylations, ajoutées par la fibrillarine (FBL). FBL fonctionne au sein d'un complexe snoRNP contenant les protéines Nop56, Nop58, 15.5kDa et un petit ARN nucléolaire (snoARN) à boîte C/D. La régulation de l'activité de la FBL et du complexe snoRNP à boîte C/D ne sont pas connus. Ce travail a exploité des données structurales de FBL et du complexe de méthylation pour construire un modèle permettant d'explorer les relations ses structure-fonction. L'impact de l'acétylation de FBL a également été exploré. Le 5-fluorouracile (5-FU) est un analogue de l'uracile, dont la cytotoxicité dépend de son altération du métabolisme des ARNr. Le 5-FU inhibe la maturation des ARNr et altère la localisation de plusieurs facteurs nucléolaires, dont FBL. Ce travail montre que le 5-FU induit une nouvelle acétylation de FBL en position K292. De plus, le 5-FU réduit l'association de FBL avec les membres protéiques du complexe de méthylation, et induit une baisse globale de ses interactions. De plus, ce travail propose un rôle nouveau de la déacétylase SIRT7 et de l'acétyltransférase CBP sur le complexe de méthylation. Ces enzymes semblent aussi participer aux dérégulations du complexe de méthylation induites par le 5-FU. L'ensemble de ces résultats supportent l'implication des modifications post-traductionnelles dans la régulation du complexe de méthylation des ARNr / The ribosome is responsible for the translation of mRNA into proteins. Within the ribosome, rRNAs play a crucial role in translation, and their post-transcriptional modifications regulate the ribosome’s translational activity and impact on gene expression. The human ribosome contains 106 2’-O-methylations added by fibrillarin (FBL). FBL functions through a box C/D snoRNP complex consisting of Nop56, Nop58 and 15.5kDa along with a box C/D small nucleolar RNA (snoRNA). The regulation of FBL ad the C/D box snoRNP complexe are unknown. This work exploitated strtuctural data on FBL and the methylation complex to build a model allowing the extrapolation of structure-function relationships. The impact of FBL acetylation was also investigated. 5-FU is a uracile analog, and its cytotoxicity depends mostly on its alteration of RNA metabolism. As such, 5-FU inhibits rRNA maturation and alters the localization of nucleolar factors such as FBL. 5-FU induced a novel FBL acetylation at position K292, decreased FBL interaction with the methylation complex proteins, and induced a large scale inhibition of its interactions. This discovered a new role of the deacetylase and the acetyltransferase CBP on snoRNP integrity. Moreover, this work suggests that these enzyme participate in the 5-FU-induced alteration of snoRNP. s. This work supports the involvement of post-translational modifications in the regulation of the rRNA C/D box snoRNP 2’-O-methylation complex Fibrillarine 2’-O-méthylation ARNr Modifications post-traductionnelles 5-fluorouracile Complexe snoRNP Biogenèse des ribosomes Fibrillarin 2’-O-méthylation RRNA Post-translational modifications 5-fluorouracile SnoRNP complex Ribosome biogenesis 571.6
370	Diversidade taxonômica e potencial de biodegradação de bactérias isoladas de reservatórios de petróleo da Bacia de Campos (RJ). / Taxonomic diversity and biodegradation potential of bacteria isolated from oil reservoirs of the Campos Basin (RJ). Patrícia Ferreira Lopes 20 October 2010 (has links) O presente trabalho teve como objetivos caracterizar uma coleção de 98 bactérias isoladas de amostras de petróleo e água de formação de reservatórios da Bacia de Campos (RJ) utilizando técnicas de taxonomia molecular e avaliar o potencial de degradação de biomarcadores do petróleo. O sequenciamento e análise filogenética do gene RNAr 16S revelaram Bacillus firmus, megaterium, pumilus, sphaericus, simplex, cereus/B. thuringiensis Marinobacter lutaoensis, Halomonas shengliensis/H. alimentaria/ H.campisalis, Citreicella thiooxidans, Stenotrophomonas maltophilia, Achromobacter xylosoxidans, Micrococcus luteus, Kocuria rosea, Streptomyces alboniger/S. chartreusis /S. moderatus, Staphylococcus hominis e Staphylococcus pasteuri/S. warneri. Os resultados evidenciaram a preferência pela biotransformação do ácido nonadecanóico e esqualano. A caracterização da microbiota presente nos reservatórios e avaliação do potencial de biodegradação pode contribuir para fornecer subsídios para estudos futuros sobre os mecanismos biológicos responsáveis pela biodegradação do petróleo. / This study is aimed to characterize a collection of 98 bacteria isolated from oil and formation water samples derived from reservoirs of the Campos Basin (RJ) using molecular biology-based techniques and to evaluate the degradation potential of petroleum biomarkers. Further sequencing and phylogenetic analysis of 16S rRNA genes revealed species of Bacillus firmus, megaterium, pumilus, sphaericus, simplex, cereus/thuringiensis, Marinobacter lutaoensis, Halomonas shengliensis/H. alimentaria/H. campisalis, Citreicella thiooxidans, Stenotrophomonas maltophilia, Achromobacter xylosoxidans, Micrococcus luteus, Kocuria rosea, Streptomyces alboniger/S. chartreusis/S. moderatus, Staphylococcus hominis and Staphylococcus pasteuri/S. warneri. The results showed the preference of bacteria for the biotransformation of nonadecanoic acid and squalane. The characterization of the microbiota associated to reservoirs and the evaluation of their biodegradation potential may provide subsidies for future studies about the biological mechanisms responsible for petroleum biodegradation. Bactérias (Classificação) Biodegradação Biomarcadores do petróleo Fingerprint genético Genes RNAr 16S Petróleo - Campos (RJ) Reservatórios de petróleo RNA (Genética) Seqüenciamento genético 16S rRNA genes Bacteria (Rank) Biodegradation Genetic fingerprint Genetic sequencing Oil -Campos (RJ) Petroleum biomarkers Petroleum reservoirs RNA (Genetics)

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