Global ETD Search

11	Identification of the Hmu PSTUV operon and its’ role in Heme Utilization in Rhizobia Leguminosarum ATCC 14479 Zimmer, Sarah Kathryn 01 May 2018 (has links) Iron is an essential nutrient for the proper functioning of many bacterial physiological processes. A deficiency of iron in bacteria can cause inhibition of cell growth and changes in morphology. Under iron restricted environments, microorganisms seek out different methods of acquiring iron. Our lab reported that RhizobiumLeguminosarum ATCC 14479, a gram-negative soil bacterium, is capable of utilizing heme as the sole source of iron. This work focuses on identifying and sequencing the hmuPSTUVoperon to assess its’ possible role in heme utilization in R. leguminosarum biovar trifoliiATCC 14479. We have confirmed the presence of this operon and have completed the sequencing of each gene involved in the operon. We have used in-silico analysis to assess the possible function of each gene. In the future, gene knockout will be performed to confirm the function of the hmuPSTUVoperon. Biochemistry Microbial Physiology Molecular Biology
12	Repression of β-galactosidase synthesis in Escherichia coli by salicylates Olson, Joan Carlyn 01 January 1972 (has links) Salicylic acid, and to a lesser extent aspirin, have been shown to repress β-galactosidase synthesis in Escherichia coli. The repression is not due to decreased inducer uptake, nor does it result from competition with inducer for repressor. Dinitrophenol does not exert similar effects on β-galactosidase synthesis. Cyclic adenosine 31, 51-monophosphate partially relieves the repression. The extent or the relief by cyclic adenosine monophosphate seems to depend on the concentration of salicylic acid. This indicates there may be direct interaction between the actions of cyclic adenosine monophosphate and salicylic acid in E. coli cells. Galactosidase Escherichia coli Salicylates Bacteriology Microbial Physiology Microbiology
13	Sustainable Biofuels Production Through Understanding Fundamental Bacterial Pathways Involved in Biomass Degradation and Sugar Utilization Hayes, James CM 01 January 2013 (has links) (PDF) Genomic analysis and physiological experiments conducted on the lignocellulosic biomass degrading bacterium C. phytofermentans, indicates that it can degrade and utilize a wide-range of carbohydrates as possible growth substrates. Previous experiments characterized gene expression using custom whole genome oligonucleotide microarrays. The results indicated that C. phytofermentans utilizes ATP-binding cassette (ABC) transporters for carbohydrate uptake and does not use the sole phosphoenolpyruvate-phosphotransferase system (PTS) for any of the tested substrates.Distinct sets of Carbohydrate Active Enzymes (CAZy) genes were also up-regulated on specific substrates indicative of C. phytofermentans ability to selectively degrade lignocellulosic biomass. We also identified a highly expressed cluster of genes which includes seven extracellular glycoside hydrolases and two ABC transporters with unknown specificity on a number of substrates. These results lead to the hypothesis that when grown on plant biomass, C. phytofermentansis capable of degrading and transporting all major carbohydrate components of lignocellulose biomass. To test this, C. phytofermentans was grown on three different lignocellulosic biomass substrates (Brachypodium distachyon, cornstover, and switchgrass). Gene expression and HPLC analysis indicated that C. phytofermentans is utilizing multiple substrates with multiple sugar ABC transporter clusters, glycoside hydrolases, and sugar utilization pathways being expressed. To further test this,the sugar utilization pattern for C. phytofermentans was investigated. Growth studies were performed on individual saccaharides (glucose, cellobiose, xylose, and fucose) as well as combinations of all these sugars. From these studies we determined that C. phytofermentans does not show a characteristic diauxic shift indicative of preferential sugar utilization or carbon catabolite repression (CCR). This result was supported further by HPLC analysis indicating that co-utilization of sugars was occurring, however their were differences in the rates of consumption. Expression analysis of dual sugar combinations of glucose/cellobiose, glucose/xylose, and glucose/fucose also shows that genes involved in the transport and utilization of each sugar are expressed. We also noted glucose repression of some of the glyocside hydrolases which are normally expressed on xylose and fucose. The results from this study indicate that C. phytofermentans can utilize multiple sugars simultaneously. Biofuels Biomass Degradation Simultaneous Utilization Clostridium phytofermentans Microbial Physiology
14	Analysis of the Prevention of Biocorrosion Caused by Desulfovibrio alaskensis G20 Boring, Michael 01 January 2017 (has links) Desulfovibrio alaskensis G20 and other sulfate-reducing bacteria cause significant damage to metal pipelines and other infrastructure through a metabolic pathway that releases toxic hydrogen sulfide into their surroundings. The biocorrosion that results from the release of hydrogen sulfide creates significant economic burden, and can pose health risks for those exposed to this chemical. They are commonly present in the form of biofilms, an extracellular matrix composed of bacterial cells, polysaccharides, proteins, nucleic acids, and other materials. These biofilms are difficult to remove, and they provide protection to the bacteria within from anti-bacterial treatments. Desulfovibrio alaskensis G20 is a strain derived from a wild-type bacterium collected from an oil well corrosion site and is a model organism for understanding biofilm formation of sulfate-reducing bacteria and how these biofilms can be prevented or inhibited by techniques such as cerium oxide nanoparticle coating. To this end, samples of Desulfovibrio alaskensis G20 were grown anaerobically in 24-well and 96-well plates, and the resultant biofilm growth was measured through spectrophotometry. Several different environmental parameters were tested, including temperature, electron donor molecules, basal and enriched growth media, and oxidative stress, revealing several affinities for production of biofilm growth. Desulfovibrio alaskensis G20 biocorrosion biofouling cerium oxide biofilm Microbial Physiology
15	Discovery and characterization of bile acid and steroid metabolism pathways in gut-associated microbes Harris, Spencer 01 January 2017 (has links) The human gut microbiome is a complex microbial ecosystem residing in the lumen of our gastrointestinal tract. The type and amounts of microbes present in this ecosystem varies based on numerous factors, including host genetics, diet, and environmental factors. The human gut microbiome plays an important role in normal host physiological functions, including providing energy to colonocytes in the form of short-chain fatty acids. However, gut microbial metabolites have also been associated with numerous disease states. Current tools for analyzing the gut microbiome, such as high-throughput sequencing techniques, are limited in their predictive ability. Additionally, “-omic” approaches of studying the complex array of molecules, such as transcriptomics (RNA), proteomics (proteins), and metabolomics (previously identified physiologically active molecules), give important insight as to the levels of these molecules but do not provide adequate explanations for their production in a complex environment. With a better physiological understanding of why specific metabolites are produced by the gut microbiome, more directed therapies could be developed to target their production. Therefore, it is immensely important to study the specific bacteria that reside within the gut microbiome to gain a better understanding of how their metabolic actions might impact the host. Within this framework, this study aimed to better understand the production of secondary bile acid metabolites by bacterial in the gut microbiome. High levels of secondary bile acids are associated with numerous pathophysiological disorders including colon cancer, liver cancer, and cholesterol gallstone disease. In the current study, three bile acid metabolizing strains of bacteria that are known members of the gut microbiome were studied. A novel strain of Eggerthella lenta was identified and characterized, along with the type strain, for its ability to modulate bile acid and steroid metabolism based on the atmospheric gas composition. Additionally, it was shown that the oxidation of hydroxyl groups on primary bile acids by E. lenta C592 inhibited subsequent 7α-dehydroxylation by Clostridium scindens. The gene involved in the production of a Δ4,6-reductase enzyme, responsible for catalyzing two of the final reductive steps in the 7α-dehydroxylation pathway, was putatively identified and characterized in Clostridium scindens ATCC 35704. Lastly, the transcriptomic profile of Clostridium scindens VPI 12708 in the presence of numerous bile acids and steroid molecules was studied. These studies contribute significantly to the understanding of why specific bile acid metabolites are made by members of the gut microbiome and suggest ways of modulating their production. Gut microbiome bile acids steroids metabolism acetogenesis secondary bile acids Microbial Physiology
16	Fisiologia e formação de partículas lipídicas durante o crescimento da levedura Yarrowia lipolytica IMUFRJ 50682. / Physiology and formation of lipid particles during growth of Yarrowia lipolytica IMUFRF 50682 yeast. Bacciotti, Fernanda 06 August 2015 (has links) A levedura Yarrowia lipolytica tem sido muito investigada, especialmente por ser um microrganismo oleaginoso, ou seja, capaz de acumular grandes quantidades de lipídios, o que ocorre majoritariamente em organelas denominadas partículas lipídicas. Estes lipídios apresentam várias potenciais aplicações biotecnológicas, como por exemplo na produção de óleo microbiano (single cell oil) e na produção de biodiesel. Durante este projeto de mestrado, objetivou-se estudar a fisiologia de duas linhagens da levedura Y. lipolytica, sendo uma tradicionalmente estudada pela comunidade científica internacional (linhagem w29) e outra isolada da Baía da Guanabara, no Rio de Janeiro (linhagem IMUFRJ 50682). Foram realizados cultivos em frascos agitados tipo Erlenmeyer com defletores tampados com algodão (volume total 500 mL, volume de meio 100 mL, 28 oC e 200 rotações por minuto), durante os quais foi possível: 1) escolher um meio de cultivo de composição totalmente definida, com tiamina como único fator de crescimento, adequado a estudos de fisiologia quantitativa com esta levedura; 2) verificar que Y. lipolytica não é capaz de crescer com sacarose ou xilose como única fonte de carbono; 3) verificar que Y. lipolytica cresce com velocidade específica de crescimento máxima (Máx) de 0,49 h-1 num meio complexo contendo glicose, extrato de levedura e peptona (meio YPD), 0,31 h-1 em meio definido com glicose como única fonte de carbono e 0,35 h-1 no mesmo meio, mas com glicerol como única fonte de carbono, sem excreção de metabólitos para o meio de cultivo; 4) verificar que ocorreu limitação por oxigênio nos cultivos em frasco agitado, sendo este o motivo pelo qual as células deixaram de crescer exponencialmente; 5) verificar que o uso de ureia, em vez de sulfato de amônio, como fonte de nitrogênio, contribui para uma variação menor do pH durante os cultivos, sem prejuízo ao crescimento da levedura; 6) observar que, ao se restringir a oferta de nitrogênio à levedura (aumento da relação C/N inicial no meio de 12,6 para 126), as células têm sua morfologia alterada e apresentam maior quantidade de partículas lipídicas; 7) determinar uma composição elementar para a biomassa de Y. lipolytica (CH1,98O0,58N0,13), em que os átomos de carbono encontram-se em média mais reduzidos do que na biomassa de leveduras como Saccharomyces cerevisiae e Dekkera bruxellensis. Foram também realizados cultivos em biorreator em batelada (1 L de volume útil, 28 oC, aerobiose plena e pH controlado em 5,0), durante os quais foi possível: a) estabelecer um protocolo de cultivo para Y. lipolytica em biorreator (que envolvem agitação mecânica, aeração e uso de anti-espumante, entre outras diferenças em relação aos cultivos em frasco); b) confirmar os valores dos principais parâmetros fisiológicos apresentados por esta levedura, anteriormente obtidos a partir de cultivos em frasco; c) confirmar que o fator de conversão de substrato a células (Yx/s) é maior para cultivos realizados com glicerol como fonte única de carbono (0,53 g/g para a linhagem IMUFRJ 50682), do que com glicose (0,48 g/g para a mesma linhagem). Finalmente, cultivos realizados em quimiostato com glicerol como fonte de carbono e energia, limitados por amônio (fonte de nitrogênio, relação C/N 126), às vazões específicas de 0,25 h-1 e 0,15 h-1, permitiram observar que o número de partículas lipídicas por célula de Y. lipolytica permaneceu em torno de 2 em ambas as situações e houve uma diminuição no teor de nitrogênio nas células quando a velocidade específica de crescimento diminuiu de 0,25 para 0,15 h-1. / The yeast Yarrowia lipolytica has been intensively investigated, especially for being an oleaginous microorganism, thus possessing the capacity of accumulating high amounts of lipids, which mainly takes place in organeles known as lipid bodies. These lipids present several potential biotechnological appications, as in the production of single cell oil or biodiesel. During this research project, we aimed at investigating the physiology of two Y. lipolytica strains: w29, traditionally investigated by the international scientific community, and IMUFRJ 50682, isolated from the Guanabara Bay in Rio de Janeiro. Shake-flask cultivations in baffled Erlenmeyer flasks (total volume 500 mL, liquid volume 100 mL, 28 oC and 200 rotations per minute) with cotton stoppers were carried out and allowed us to: 1) choose a fully defined cultivation medium, in which tiamine is the sole growth factor, suitable for quantitative physiological studies with this yeast; 2) verify that Y. lipolytica is not capable of growing on sucrose or xylose as the sole carbon source; 3) observe that Y. lipolytica grows with a maximum specific growth rate (MAX) of 0.49 h-1 in a complex medium containing glucose, yeast extract and peptone (YPD medium), 0.31 h-1 in a defined medium with glucose as the sole carbon source, and 0.35 h-1 in the same medium, but with glycerol as the sole C-source, without excreting metabolites to the cultivation medium; 4) verify that oxygen limitation took place during our shakeflask cultivations and that this caused cells to leave the exponential growth phase; 5) verify that urea can substitute ammonium as the sole nitrogen-source for Y. lipolytica, keeping pH variations less pronounced, without compromising cell growth; 6) observe that cells presented an altered morphology and higher amounts of lipid bodies, when less nitrogen was added to the medium (C/N ratio increased from 12.6 to 126); 7) determine an elemental composition for the biomass of Y. lipolytica (CH1,98O0,58N0,13), in which the average carbon atom was more reduced with respect to the biomass of yeasts such as Dekkera bruxellensis and Saccharomyces cerevisiae. Bioreactor cultivations in batch mode (working volume 1 L, 28 oC, full aerobiosis and pH controlled at 5.0) were also carried out, which allowed us to: a) define a protocol for the cultivation of Y. lipolytica in this system (which involves mechanical agitation, aeration and the use of anti-foam, among other differences with respect to shake-flask cultivations); b) confirm the main physiological parameters presented by this yeast, previously obtained from shake-flask cultivations; c) confirm that the biomass yield on substrate (Yx/s) is higher on glycerol than on glucose (0.53 g/g and 0.48 g/g, respectively). Finally, N-limited chemostat cultivations with glycerol as the carbon and energy source and ammonium as the N-source were also performed (dilution rates of 0.25 h-1 and 0.15 h-1, C/N ratio in the medium of 126), allowing us to verify that the number of lipid particles per cell is around 2 under both conditions and that there was a decrease in the N content in the cells when the specific growth rate decreased from 0.25 to 0.15 h-1. Fisiologia microbiana Leveduras oleaginosas Microbial physiology Oleaginous yeasts Yarrowia lipolytica Yarrowia lipolytica. Lipídios
17	INSIGHTS INTO KEY GENE REGULATORY NETWORKS IN <em>BORRELIA BURGDORFERI</em> Arnold, William Kenneth 01 January 2018 (has links) Gene regulatory networks are composed of interconnected regulatory nodes created by regulatory factors of multiple types. All organisms finely tune gene expression in order to adapt to and survive within their current niche. Obligate parasitic bacteria are under extreme pressure to quickly and appropriately adapt their gene regulatory programs in order to survive within their given host. Borrelia burgdorferi is one such organism and persists in nature by alternating between two hosts; Ixodes spp. ticks and small vertebrate animals. These two hosts represent drastically different environments; requiring a unique gene regulatory program to survive and transmit between them. Microbiologists have long sought to better understand exactly what stimuli pathogens sense and how that information is relayed in to physiologic adaptation. In this work I aimed to examine two parts of this interesting field. First, I sought to better understand the stimuli B. burgdorferi sense in order to adapt to their hosts by testing several hypotheses centered on the general notion that B. burgdorferi senses both internal and external metabolic cues as primary signals for adaptation. I demonstrated that a second messenger system immediately downstream of a critical metabolic pathway is important during vertebrate infection and that a key regulator of virulence is itself regulated by a factor involved in DNA replication. Second, I sought to better define the topology of gene regulatory networks, known and unknown, that are important for the ability of the bacteria to adapt. The work in this section focus on the idea that B. burgdorferi gene regulatory networks are extremely complex and are not currently well defined in the literature. My studies revealed that B. burgdorferi possesses a large number of previously undefined regulatory targets, including extended 5’ and 3’ UTRs of known genes, and encodes several hundred-putative small non-coding RNAs. Furthermore, I demonstrate that two essential regulatory factors share substantial, independent, overlap in their regulons highlighting the still undefined complexity of regulatory networks at play in B. burgdorferi. pathogen gene regulatory networks gene regulation growth rate bacteria Bacteriology Microbial Physiology
18	FUNCTIONAL ANALYSES OF THE DNA- AND RNA-BINDING PROTEIN SPOVG IN <em>BORRELIA BURGDORFERI</em> Savage, Christina R. 01 January 2019 (has links) Borrelia burgdorferi, the causative agent of Lyme disease, exists in a defined enzootic cycle involving Ixodes scapularis ticks and various vertebrates. Humans can serve as an accidental host, if a tick colonized with B. burgdorferi happens to feed on a human. B. burgdorferi are also accidental pathogens: they do not make toxins, or destroy host tissue by other mechanisms. They merely transmit between vector and host to survive. In order to do this, they must effectively sense their current environment, and appropriately alter cellular processes. Understanding the regulatory mechanisms of how B. burgdorferi manages to do this has been a focus of the Stevenson lab for many years. Previous work identified SpoVG as a DNA-binding protein. Although a homologue of this protein had been implicated to serve a regulatory role in other bacteria, the Stevenson lab was the first to demonstrate a function for the protein, both for B. burgdorferi and two other bacteria. Studies contained in this body of work aim to provide insight into regulation of SpoVG by B. burgdorferi as well the impact that it has on gene regulation. By using genetic mutants, we determined that SpoVG is regulated at the levels of transcription and translation in culture by growth rate, temperature, and other regulatory factors. Additionally, we provide evidence that SpoVG regulates its own expression. Numerous genes are under control of SpoVG. Biochemical analyses revealed that SpoVG specifically interacts with DNAs and RNAs associated with genes found to be under its regulatory control. Finally, we provide evidence for SpoVG acting in concert with other known regulatory factors such as other DNA-binding proteins and the cyclic di-nucleotide second messengers cyclic-di-GMP and cyclic-di-AMP. All together, these studies provide insight into how B. burgdorferi broadly regulates cellular processes during different stages of the enzootic cycle. We hypothesize that SpoVG does this through globally manipulating the three-dimensional structure of the bacterial chromosome, and that exactly how SpoVG acts at any given point will be dependent on the other regulatory factors that are also present in the cell. Borrelia burgdorferi gene regulation SpoVG DNA-binding proteins RNA-binding proteins Microbial Physiology
19	Use of Proteomics Tools to Investigate Protein Expression in Azospirillum brasilense Khalsa-Moyers, Gurusahai K 01 May 2010 (has links) Mass spectrometry based proteomics has emerged as a powerful methodology for investigating protein expression. “Bottom up” techniques in which proteins are first digested, and resulting peptides separated via multi-dimensional chromatography then analyzed via mass spectrometry provide a wide depth of coverage of expressed proteomes. This technique has been successfully and extensively used to survey protein expression (expression proteomics) and also to investigate proteins and their associated interacting partners in order to ascertain function of unknown proteins (functional proteomics). Azospirillum brasilense is a free-living diazotrophic soil bacteria, with world-wide significance as a plant-growth promoting bacteria. Living within the rhizosphere of cereal grasses, its diverse metabolism is important for its survival in the competitive rhizospheric environment. The recently sequenced genome of strain Sp245 provided a basis for the proteome studies accomplished in this work. After initial mass spectrometer parameter optimization studies, the expressed proteomes of two strains of Azospirillum brasilense, Sp7 and Sp245, grown under both nitrogen fixing and optimal growth (non nitrogen fixing) conditions were analyzed using a bottom up proteomics methodology. Further proteome studies were conducted with A. brasilense strain Sp7 in order to ascertain the effect of one chemotaxis operon, termed Che1. In this study, proteomic surveys were conducted on two bacterial derivative strains, created earlier, which lacked either a forward signaling pathway or an adaptation pathway. The proteomic surveys conducted in this work provide a foundation for further biochemical investigations. In order to facilitate further investigation and a movement into functional proteomics, a set of destination vectors was created that contain a variety of tandem affinity tags. The addition of tandem affinity tags to a protein allow for generic purification schemes, and can facilitate future studies to investigate proteins of interest discovered in the first expression proteomic surveys of A. brasilense. Taken together, this dissertation provides a valuable data set for investigation into the physiology of A. brasilense and further provides biochemical tools for analysis of the functional protein interactions of A. brasilense cells. Proteomics Azospirillum brasilense nitrogen fixation chemotaxis Microbial Physiology Other Microbiology
20	Genomic and Molecular Analysis of the Exopolysaccharide Production in the Bacterium <i>Thauera aminoaromatica</i> MZ1T Jiang, Ke 01 May 2011 (has links) Thauera aminoaromatica MZ1T is an exopolysaccharide (EPS)-producing Gram negative bacterium isolated from the wastewater treatment plant of a major industrial chemical manufacturer as the causal agent for poor sludge dewatering. It shares common features with other known Thauera spp. (i.e. Thauera aromatica, and Thauera selenatis), being capable of degrading aromatic compounds anaerobically and using acetate and succinate as carbon sources. It is unique among the Thauera spp. in its production of abundant EPS which results in viscous bulking and poor sludge dewaterability. In this respect, it is similar to Azoarcus sp. EbN1 and BH72. Thaueran is the proposed name for EPS produced by MZ1T for research purpose. The focus of this research is to fully characterize the microorganism and identify and characterize the genes responsible for thaueran synthesis and export through bioinformatics, transposon mutagenesis, gene clone and expression, reverse transcriptase quantitative real time PCR, and genome sequencing and annotation. Ultimately, this knowledge will contribute to control of viscous bulking and sludge dewatering problems. However, a broader range of important environmental biotechnical processes may be forthcoming from understanding thaueran synthesis. They may include thaueran remedial solutions for heavy metal and radionuclide immobilization, anaerobic carbon channeling and sequestration, greenhouse gas mitigation through acetate incorporation into thaueran, and novel applications such as thaueran-mediated wound healing. Sequencing of MZ1T genome has been accomplished through collaboration with the Joint Genome Institute (JGI). The genome size is 4.5 Mbp, GC content is 68.3%, and there are 4,092 protein coding genes. Three putative thaueran gene clusters were found within the genome. One tight cluster with a size of 20.67kb encoding 14 genes may contain most necessary genes for thaueran formation and export. Another two clusters are loosely organized. Through transposon mutagenesis, mutants not producing abundant thaueran and not flocculating have been obtained and verified, and were further used in reverse transcriptase quantitative real time PCR to compare the differential expression levels of the presumable EPS genes among mutants, wild type MZ1T and under different growth conditions. The results indicated a correlation of the expression level of the test genes and the abundance of EPS. genomic molecular bacterium EPS benefit annotation Bacteriology Bioinformatics Life Sciences Microbial Physiology

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