• Refine Query
  • Source
  • Publication year
  • to
  • Language
  • 17
  • 4
  • 3
  • 2
  • 1
  • 1
  • Tagged with
  • 31
  • 16
  • 12
  • 10
  • 8
  • 7
  • 5
  • 5
  • 5
  • 5
  • 4
  • 4
  • 4
  • 4
  • 3
  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
21

The role of post-transcriptional regulators in pathogenesis and secondary metabolite production in Serratia sp. ATCC 39006

Wilf, Nabil M. January 2011 (has links)
Serratia sp. ATCC 39006 (S39006) is a Gram-negative bacterium that is virulent in plant (potato) and animal (Caenorhabditis elegans) models. It produces two secondary metabolite antibiotics, prodigiosin and a carbapenem, and the plant cell wall degrading exoenzymes, pectate lyase and cellulase. A complex regulatory network controls production of prodigiosin, including a quorum sensing (QS) system, and the role of post-transcriptional regulation was investigated. It was hypothesized that Hfq-dependent small regulatory RNAs (sRNAs) might also play a role. Hfq is an RNA chaperone involved in post-transcriptional regulation that plays a key role in stress response and virulence in other bacterial species. An S39006 ∆hfq mutant was constructed and in the mutants production of prodigiosin and carbapenem was abolished, while production of the QS molecule, butanoyl homoserine lactone (BHL), was unaffected. Using transcriptional fusions, it was found that Hfq regulated the QS response regulators, SmaR and CarR. Additionally, exoenzyme production and swimming motility were decreased in the ∆hfq mutant, and virulence was attenuated in potato and C. elegans. It was also shown that the phenotype of an hfq mutant is independent of its role in regulating the stationary phase sigma factor, rpoS. In order to define the complete regulon of Hfq and identify relevant potential sRNAs, deep sequencing of strand-specific cDNAs (RNA-seq) was used to analyse the whole transcriptome of S39006 WT and the ∆hfq mutant. The regulon of another post-transcriptional regulator, RsmA, also involved in regulating prodigiosin production, was investigated by performing RNA-seq on an rsmA mutant. Moreover, global changes in the proteome of the hfq mutant was analysed using an LC-MS/MS approach with isobaric tags for relative and absolute quantification (iTRAQ). This study confirms a role for Hfq in pathogenesis and the regulation of antibiotic production in S39006, and begins to provide a systems-level understanding of Hfq and RsmA regulation using a combination of transcriptomics and proteomics.
22

Characterizing the Phenotypic and Transcriptional Responses of Salmonella Typhimurium at Stationary and Lag Phases of Growth in Response to a Low Fluid Shear Environment

January 2020 (has links)
abstract: The discovery that mechanical forces regulate microbial virulence, stress responses and gene expression was made using log phase cultures of Salmonella Typhimurium (S. Typhimurium) grown under low fluid shear (LFS) conditions relevant to those encountered in the intestine. However, there has been limited characterization of LFS on other growth phases. To advance the growth-phase dependent understanding of the effect of LFS on S. Typhimurium pathogenicity, this dissertation characterized the effect of LFS on the transcriptomic and phenotypic responses in both stationary and lag phase cultures. In response to LFS, stationary phase cultures exhibited alterations in gene expression associated with metabolism, transport, secretion and stress responses (acid, bile salts, oxidative, and thermal stressors), motility, and colonization of intestinal epithelium (adherence, invasion and intracellular survival). Many of these characteristics are known to be regulated by the stationary phase general stress response regulator, RNA polymerase sigma factor S (RpoS), when S. Typhimurium is grown under conventional conditions. Surprisingly, the stationary phase phenotypic LFS stress response to acid and bile salts, colonization of human intestinal epithelial cells, and swimming motility was not dependent on RpoS. Lag phase cultures exhibited intriguing differences in their LFS regulated transcriptomic and phenotypic profiles as compared to stationary phase cultures, including LFS-dependent regulation of gene expression, adherence to intestinal epithelial cells, and high thermal stress. Furthermore, the addition of cell-free conditioned supernatants derived from either stationary phase LFS or Control cultures modulated the gene expression of lag phase cultures in a manner that differed from either growth phase, however, these supernatants did not modulate the phenotypic responses of lag phase cultures. Collectively, these results demonstrated that S. Typhimurium can sense and respond to LFS as early as lag phase, albeit in a limited fashion, and that the lag phase transcriptomic and phenotypic responses differ from those in stationary phase, which hold important implications for the lifecycle of this pathogen during the infection process. / Dissertation/Thesis / Transcriptomic Data / Doctoral Dissertation Microbiology 2020
23

Characterizing the Impact of Stress Exposure on Survival of Foodborne Pathogens

Shah, Manoj Kumar January 2019 (has links)
Bacterial pathogens transmitted by the fecal-oral route endure several stresses during survival/growth in host and non-host environments. For foodborne pathogens, understanding the range of phenotypic responses to stressors and the environmental factors that impact survival can provide insights for the development of control measures. For example, the gastrointestinal system presents acidic, osmotic, and cell-envelope stresses and low oxygen levels, but Listeria monocytogenes can withstand these stresses, causing illnesses in humans. Survival/growth characteristics may differ among L. monocytogenes strains under these stressors due to their genetic diversities. Our knowledge of such phenotypic characteristics under bile and salt stresses are inadequate. In this dissertation, variation in growth characteristics was observed among L. monocytogenes strains under bile and osmotic stresses with no evidence of cross-protection, but rather an antagonistic effect was observed with the formation of filaments when pre-exposed to 1% bile and treated with 6% NaCl. This shows that variation in stress adaptability exists among L. monocytogenes strains with the ability to form filaments under these conditions. Similarly, Salmonella survival in soil is dependent on several factors, such as soil, amendment types, moisture, irrigation, and desiccation stress. In this study, the use of HTPP (heat-treated poultry pellets) was investigated as a soil amendment in the survival/growth of Salmonella in soil extracts mimicking runoff events, and in soil cultivated with spinach plants to assess its safety for use for an organic fertilizer. The presence of HTPP in soil increased S. Newport survival with a greater likelihood of its transfer to and survival on spinach plants. Increased microbial loads and rpoS mutant showed decreased growth/survival in soil extracts, however, rpoS was not important for survival in soil under the tested conditions showing possible lack of desiccation stress. These results show that HTPP provided nutrients to the Salmonella for increased growth and survival in soil extracts and soil, respectively, which show that the use of treated BSAAO to soils may still require appropriate mitigation to minimize Salmonella Newport contamination of leafy greens in the pre-harvest environment. Overall, the results in this study increased our understanding of L. monocytogenes and Salmonella phenotypic adaptation to stressful environments.
24

Regulação da adesão de Escherichia coli enteropatogênica (EPEC) por genes de resposta à limitação nutricional e estresse. / Regulation of enteropathogenic Escherichia coli (EPEC) adhesion by genes related to nutrional shortage and stress.

Ferreira, Gerson Moura 24 August 2009 (has links)
Escherichia coli enteropatogênica (EPEC) é uma das principais causas de diarreia em crianças. Na carência de fosfato (Pi), um conjunto de genes conhecido como regulon PHO é induzido. Esse regulon é controlado pelo sistema Pst, que além de ser um transportador de Pi, reprime a expressão de PHO quando Pi é abundante, e pelo sistema de dois componentes PhoB/PhoR. A deleção de pst reduziu a adesão de EPEC à células epiteliais in vitro, pois diminuiu da expressão dos reguladores PerA/PerC, que por sua vez controlam a expressão de genes envolvidos na adesão. Este efeito foi exclusivo de pst e não devido a expressão constitutiva dos genes de PHO causada pela deleção de pst. A expressão da fímbria BFP, PerA e PerC também dependem da síntese de ppGpp, uma molécula de alarme envolvida na regulação de genes relacionados à carência nutricional. ppGpp regula positivamente a expressão de PerA e PerC. Entretanto, RpoS, o fator relacionado à resposta ao estresse, afetou negativamente o nível de adesão de EPEC e a expressão de BFP. / Enteropathogenic E. coli (EPEC) is one of the causes of diarrhea in children. Phosphate (Pi) shortage induces transcription of the genes known as the PHO regulon. These genes are controlled by the Pst system, that is also a high-affinity Pi transporter, and represses PHO expression under Pi-replete conditions. PHO is also controlled by the two-component system PhoB/PhoR. Deletion of the pst operon reduced the adhesion of EPEC to epithelial cells in vitro due to a decrease in the expression of the regulators PerA and PerC that in turn control the expression of genes related to adhesion. The constitutive expression of the PHO genes in the pst mutant was not the cause of adhesion inhibition. Expression of bfp and the regulators PerA and PerC was also dependent on ppGpp, an alarmone involved in the regulation of genes related to nutrient limitation. On the other hand, RpoS, the factor that controls the general stress response, negatively affected EPEC adhesion and bfpA expression.
25

Regulação da adesão de Escherichia coli enteropatogênica (EPEC) por genes de resposta à limitação nutricional e estresse. / Regulation of enteropathogenic Escherichia coli (EPEC) adhesion by genes related to nutrional shortage and stress.

Gerson Moura Ferreira 24 August 2009 (has links)
Escherichia coli enteropatogênica (EPEC) é uma das principais causas de diarreia em crianças. Na carência de fosfato (Pi), um conjunto de genes conhecido como regulon PHO é induzido. Esse regulon é controlado pelo sistema Pst, que além de ser um transportador de Pi, reprime a expressão de PHO quando Pi é abundante, e pelo sistema de dois componentes PhoB/PhoR. A deleção de pst reduziu a adesão de EPEC à células epiteliais in vitro, pois diminuiu da expressão dos reguladores PerA/PerC, que por sua vez controlam a expressão de genes envolvidos na adesão. Este efeito foi exclusivo de pst e não devido a expressão constitutiva dos genes de PHO causada pela deleção de pst. A expressão da fímbria BFP, PerA e PerC também dependem da síntese de ppGpp, uma molécula de alarme envolvida na regulação de genes relacionados à carência nutricional. ppGpp regula positivamente a expressão de PerA e PerC. Entretanto, RpoS, o fator relacionado à resposta ao estresse, afetou negativamente o nível de adesão de EPEC e a expressão de BFP. / Enteropathogenic E. coli (EPEC) is one of the causes of diarrhea in children. Phosphate (Pi) shortage induces transcription of the genes known as the PHO regulon. These genes are controlled by the Pst system, that is also a high-affinity Pi transporter, and represses PHO expression under Pi-replete conditions. PHO is also controlled by the two-component system PhoB/PhoR. Deletion of the pst operon reduced the adhesion of EPEC to epithelial cells in vitro due to a decrease in the expression of the regulators PerA and PerC that in turn control the expression of genes related to adhesion. The constitutive expression of the PHO genes in the pst mutant was not the cause of adhesion inhibition. Expression of bfp and the regulators PerA and PerC was also dependent on ppGpp, an alarmone involved in the regulation of genes related to nutrient limitation. On the other hand, RpoS, the factor that controls the general stress response, negatively affected EPEC adhesion and bfpA expression.
26

Genetics and Growth Regulation in Salmonella enterica

Bergman, Jessica M. January 2014 (has links)
Most free-living bacteria will encounter different environments and it is therefore critical to be able to rapidly adjust to new growth conditions in order to be competitively successful. Responding to changes requires efficient gene regulation in terms of transcription, RNA stability, translation and post-translational modifications. Studies of an extremely slow-growing mutant of Salmonella enterica, with a Glu125Arg mutant version of EF-Tu, revealed it to be trapped in a stringent response. The perceived starvation was demonstrated to be the result of increased mRNA cleavage of aminoacyl-tRNA synthetase genes leading to lower prolyl-tRNA levels. The mutant EF-Tu caused an uncoupling of transcription and translation, leading to increased turnover of mRNA, which trapped the mutant in a futile stringent response. To examine the essentiality of RNase E, we selected and mapped three classes of extragenic suppressors of a ts RNase E phenotype. The ts RNase E mutants were defective in the degradation of mRNA and in the processing of tRNA and rRNA. Only the degradation of mRNA was suppressed by the compensatory mutations. We therefore suggest that degradation of at least a subset of cellular mRNAs is an essential function of RNase E. Bioinformatically, we discovered that the mRNA of tufB, one of the two genes encoding EF-Tu, could form a stable structure masking the ribosomal binding site. This, together with previous studies that suggested that the level of EF-Tu protein could affect the expression of tufB, led us to propose three models for how this could occur. The stability of the tufB RNA structure could be affected by the elongation rate of tufB-translating ribosomes, possibly influenced by the presence of rare codons early in the in tufB mRNA. Using proteomic and genetic assays we concluded that two previously isolated RNAP mutants, each with a growth advantage when present as subpopulations on aging wild-type colonies, were dependent on the utilization of acetate for this phenotype. Increased growth of a subpopulation of wild-type cells on a colony unable to re-assimilate acetate demonstrated that in aging colonies, acetate is available in levels sufficient to sustain the growth of at least a small subpopulation of bacteria.
27

RpoS Regulon Modulation by Environmental Selection

Chiang, Sarah M. 10 1900 (has links)
<p>Regulatory interactions evolve to incorporate new genomic material and contribute to bacterial diversity. These regulatory interactions are flexible and likely provide bacteria with a means of rapid environmental adaptation. In this thesis, the RpoS regulon is used as a model system to investigate the hypothesis that regulon composition and expression are modified according to environmental pressures. Several novel findings are presented, namely the distribution of RpoS homologs in bacteria, the flexibility of the RpoS regulon, and the effect of diverse environmental pressures on RpoS regulon expression. Based on phylogenetic and reciprocal best hits analyses, RpoS was determined to be conserved in gamma-, beta-, and delta-proteobacteria, likely because it confers a selective advantage in many bacterial niches. Regulon composition, however, was highly flexible. Even between species of the same class, <em>Escherichia coli</em> and <em>Pseudomonas aeruginosa</em>, only 12 of 50 orthologs were regulated in common by RpoS. RpoS regulon flexibility may thus be the result of adaptation to different bacterial habitats. Indeed, mutations in <em>rpoS</em> and differential regulon expression could be identified among environmental <em>E. coli</em> isolates collected from diverse sources. Among environmental <em>E. coli</em> isolates, RpoS mutant frequency was found to be 0.3%, and activity of KatE, a prototypical RpoS regulon member, was undetectable in some isolates despite the presence of functional RpoS. Modulated RpoS regulon expression among environmental <em>E. coli</em> isolates is consistent with environment as a key factor shaping regulatory interactions. Regulon flexibility was similarly apparent in oxidative stress regulons, OxyR and SoxRS, of <em>E. coli</em>. SoxRS regulon function is weakly conserved, possibly due to low selective pressure for a superoxide stress response regulon in some bacterial species. Environment, therefore, is a crucial element that defines the dynamics of regulatory networks.</p> / Doctor of Philosophy (PhD)
28

The Physiological Cost of Antibiotic Resistance

Macvanin, Mirjana January 2003 (has links)
<p>Becoming antibiotic resistant is often associated with fitness costs for the resistant bacteria. This is seen as a loss of competitiveness against the antibiotic-sensitive wild-type in an antibiotic-free environment. In this study, the physiological alterations associated with fitness cost of antibiotic resistance <i>in vitro</i> (in the laboratory medium), and <i>in vivo</i> (in a mouse infection model), are identified in the model system of fusidic acid resistant (Fus<sup>R</sup>) <i>Salmonella</i> <i>enterica</i> serovar Typhimurium.</p><p>Fus<sup>R</sup> mutants have mutations in <i>fusA</i>, the gene that encodes translation elongation factor G (EF-G). Fus<sup>R</sup> EF-G has a slow rate of regeneration of active EF-G·GTP off the ribosome, resulting in a slow rate of protein synthesis. The low fitness of Fus<sup>R</sup> mutants <i>in vitro</i>, and <i>in vivo</i>, can be explained in part by a slow rate of protein synthesis and resulting slow growth. However, some Fus<sup>R</sup> mutants with normal rates of protein synthesis still suffer from reduced fitness <i>in vivo</i>. We observed that Fus<sup>R</sup> mutants have perturbed levels of the global regulatory molecule ppGpp. One consequence of this is an inefficient induction of RpoS, a regulator of general stress reponse and an important virulence factor for <i>Salmonella</i>. In addition, we found that Fus<sup>R</sup> mutants have reduced amounts of heme, a co-factor of catalases and cytochromes. As a consequence of the heme defect, Fus<sup>R</sup> mutants have a reduced ability to withstand oxidative stress and a low rate of aerobic respiration.</p><p>The pleiotropic phenotypes of Fus<sup>R</sup> mutants suggest that antibiotic resistance can be associated with broad changes in bacterial physiology. Knowledge of physiological alterations that reduce the fitness of antibiotic-resistant mutants can be useful in identifying novel targets for antimicrobial agents. Drugs that alter the levels of global transcriptional regulators such as ppGpp or RpoS deserve attention as potential antimicrobial agents. Finally, the observation that Fus<sup>R</sup> mutants have increased sensitivity to several unrelated classes of antibiotics suggests that the identification of physiological cost of resistance can help in optimizing treatment of resistant bacterial populations.</p>
29

The Physiological Cost of Antibiotic Resistance

Macvanin, Mirjana January 2003 (has links)
Becoming antibiotic resistant is often associated with fitness costs for the resistant bacteria. This is seen as a loss of competitiveness against the antibiotic-sensitive wild-type in an antibiotic-free environment. In this study, the physiological alterations associated with fitness cost of antibiotic resistance in vitro (in the laboratory medium), and in vivo (in a mouse infection model), are identified in the model system of fusidic acid resistant (FusR) Salmonella enterica serovar Typhimurium. FusR mutants have mutations in fusA, the gene that encodes translation elongation factor G (EF-G). FusR EF-G has a slow rate of regeneration of active EF-G·GTP off the ribosome, resulting in a slow rate of protein synthesis. The low fitness of FusR mutants in vitro, and in vivo, can be explained in part by a slow rate of protein synthesis and resulting slow growth. However, some FusR mutants with normal rates of protein synthesis still suffer from reduced fitness in vivo. We observed that FusR mutants have perturbed levels of the global regulatory molecule ppGpp. One consequence of this is an inefficient induction of RpoS, a regulator of general stress reponse and an important virulence factor for Salmonella. In addition, we found that FusR mutants have reduced amounts of heme, a co-factor of catalases and cytochromes. As a consequence of the heme defect, FusR mutants have a reduced ability to withstand oxidative stress and a low rate of aerobic respiration. The pleiotropic phenotypes of FusR mutants suggest that antibiotic resistance can be associated with broad changes in bacterial physiology. Knowledge of physiological alterations that reduce the fitness of antibiotic-resistant mutants can be useful in identifying novel targets for antimicrobial agents. Drugs that alter the levels of global transcriptional regulators such as ppGpp or RpoS deserve attention as potential antimicrobial agents. Finally, the observation that FusR mutants have increased sensitivity to several unrelated classes of antibiotics suggests that the identification of physiological cost of resistance can help in optimizing treatment of resistant bacterial populations.
30

Exploring microbial community dynamics: Positive selection for gain of RpoS function in Escherichia coli & microbial profiling of the Niagara Region

Botts, Steven January 2016 (has links)
A thesis submitted to the School of Graduate Studies in partial fulfillment of the requirements for the degree Master of Science / The effect of changing environmental conditions on microbial population structure can be observed at both the species and community level. Within the Escherichia coli species, null mutations in the RpoS stationary phase regulator are commonly selected by growth on poor carbon sources. In contrast, mutations which restore RpoS function may provide a selective advantage for cells exposed to environmental stress. The loss and subsequent restoration of RpoS form a population-level switch for adaptation within poor carbon and high stress environments. To investigate selection for RpoS reversion, we exposed rpoS-deficient E. coli to high salt concentrations and assessed the phenotype of presumptive mutants. 3-9% of salt-resistant mutants contained reversion mutations within rpoS, while in 91-97% the loss of RpoS function was maintained and mutations at alternative gene loci were identified. These results show that RpoS function can be restored in deficient E. coli under selective pressure. At the community level, the application of next-generation sequencing (NGS) technology to characterize environmental microbial diversity can potentially augment traditional water quality monitoring methods. To investigate the use of NGS in identifying microbial taxa within the Niagara Region, we collected water samples from Lake Erie, Lake Ontario, and nearby areas and examined the metagenome of microbial communities. A QIIME (Quantitative Insights Into Microbial Ecology) analysis of sequence data identified significant differences in relative microbial abundance with respect to sample metadata (e.g. location and subtype), significant correlations between relative abundance and quantitative parameters (e.g. Escherichia coli counts and fecal DNA markers), and detected pathogen-containing taxa at a relative abundance of 0.1-1.5%. These results show that sequence-based analyses can be used in conjunction with traditional identification methods to profile the metagenomic community of environmental samples and predict water quality. Both within-species and community-wide analyses thus offer insight into how microbial populations respond and adapt to environmental fluctuations. / Thesis / Master of Science (MSc) / The effect of changing environmental conditions on microbial population structure can be observed at both the species and community level. Within the Escherichia coli species, we investigated reversion of loss of function mutations in the RpoS protein regulator in high salt conditions and identified RpoS restoration under selective pressure. At the community level, we examined the microbial DNA of water samples from the Niagara Region under select environmental conditions and assessed the viability of next-generation sequencing in augmenting traditional water quality monitoring methods. Both within-species and community-wide analyses offer insight into how microbial populations respond and adapt to environmental fluctuations.

Page generated in 0.0365 seconds