Global ETD Search

181	Independent and Interacting Effects of Multiple Anthropogenic Stressors on Cold-Water Corals Weinnig, Alexis, 0000-0001-8858-4837 January 2020 (has links) Human population growth and global industrial development are driving potentially irreversible anthropogenic impacts on the natural world, including altering global climate and ocean conditions and exposing oceanic environments to a wide range of pollutants. While there are numerous studies highlighting the variable effects of climate change and pollution on marine organisms independently, there are very few studies focusing on the potential interactive effects of these stressors. The deep-sea is under increasing threat from these anthropogenic stressors, especially cold-water coral (CWC) communities which contribute to nutrient and carbon cycling, as well as providing biogenic habitats, feeding grounds, and nurseries for many fishes and invertebrates. The primary goals of this dissertation are to assess the vulnerability of CWCs to independent and interacting anthropogenic stressors in their environment; including natural hydrocarbon seepage, hydrocarbon and dispersant concentrations released during an accidental oil spill (i.e. Deepwater Horizon), and the interacting effects of climate change-related factors and hydrocarbon/dispersant exposure. To address these goals, multiple stressor experiments were implemented to assess the effects of current and future conditions [(a) temp: 8C and pH: 7.9; (b) temp: 8C and pH: 7.6; (c) temp: 12C and pH: 7.9; (d) temp: 12C and pH: 7.6] and oil spill exposure (oil, dispersant, oil + dispersant combined) on coral health using the CWC Lophelia pertusa. Phenotypic response was assessed through observations of diagnostic characteristics that were combined into an average health rating at four points during exposure and recovery. Regardless of environmental condition, average health significantly declined during 24-hour exposure to dispersant alone and increased temperature resulted in a delay in recovery (72 hours) from dispersant exposure. The overall gene expression patterns varied by coral colony, but the dispersant exposure elicited the strongest response. Gene ontology (GO) enrichment analysis revealed that L. pertusa likely experienced varying stages of the cellular stress response (CSR) during exposure to oil, dispersant, and a decrease in pH. The most severe responses were associated with the dispersant exposure including GO terms related to apoptosis, the immune system, wound healing, and stress-related responses. However, the oil exposure induced an upregulation of metabolic pathways and energy transfer but a downregulation of cell growth and development, indicating that the coral nubbins could have been reallocating resources and reducing growth to maintain cellular homeostasis. The decrease in seawater pH elicited a similar response to oil through the enrichment of terms associated with a reduction in the cell cycle and development. Interestingly, the increase in temperature did not elicit a CSR that was detectable in the gene expression data. To further investigate the influence of hydrocarbon exposure on CWCs, comparisons of gene expression profiles were conducted using Callogorgia delta colonies that live in close proximity to active hydrocarbon seepage (“seep”) areas with no current active seepage (“non-seep”) at two different sites in the Gulf of Mexico. There were fewer differentially expressed genes in the “seep” versus “non-seep” comparison (n=21) than the site comparison (n=118) but both analyses revealed GO terms indicating slight alterations in natural biological housekeeping processes, as opposed to a CSR. Our results indicate that distinct stages of the CSR are induced depending on the intensity of stress. This bolsters the idea that there is a stress response shared by all corals in response to a variety of stressors. These data provide evidence that CWCs can be more negatively impacted, both on the phenotypic and molecular levels, by exposure to chemical dispersants than to hydrocarbons alone. Gaining an understanding of how these communities respond, not only to independent stressors, but the combination of these stressors, provides vital information about how CWC communities will fair in current and future conditions. / Biology Biological oceanography Genetics Bioinformatics Deep-sea Deepwater Horizon Dispersant Gulf of Mexico Lophelia pertusa Transcriptomics
182	Upper Range Thermal Stress Tolerance in Channel and Hybrid Catfish Strains Stewart, Heather Ann 17 May 2014 (has links) Channel catfish (Ictalurus punctatus) have a broad distribution from Canada to Mexico, suggesting that different strains may have different thermal tolerances. In aquaculture, daily temperature maximums up to 36-40°C and fluctuations of 3-6°C occur, and may be exacerbated by future climate change. To quantify differences in thermal tolerance amongst geographically-distinct channel catfish strains and corresponding hybrid catfish (I. punctatus x [blue catfish] I. furcatus): acute critical thermal maximum (CTmax), and the effects of chronic thermal regimes on growth, survival and differential gene expression were examined. Southern channel catfish had higher CTmax than northern, and channel catfish had higher CTmax than hybrid catfish. Under chronic thermal stress, hybrid catfish had the greatest survival and most consistent growth. Further, northern channel catfish had the greatest magnitude and largest amount of upregulated gene transcripts in response to high temperatures, indicating greater thermal stress. Therefore, catfish thermal tolerance varies by geographic region and species. chronic thermal stress critical thermal maxima transcriptomics temperature geographic climate hybrid catfish Channel catfish
183	Identifying Transcriptional Gene Signatures of Suicide Across Neuropsychiatric Disorders Bates, Evelyn Alden 11 July 2022 (has links) No description available. Bioinformatics Biology Biomedical Research Neurosciences suicide transcriptomics RNAseq microarray neuropsychatric disorders mitochondrial dysfunction purine metabolism neuroinflammation
184	Studies on the impact of an insect growth regulator and host plant on reproductive physiology of Lygus lineolaris Anderson, James Houston Chance 13 May 2022 (has links) (PDF) The tarnished plant bug, Lygus lineolaris, is an economically important polyphagous pest with a broad host range. With occurrence of insecticide resistance, strategies to limit its ability to reproduce, which would curb population growth, are becoming increasingly more valuable. Strategies toward this goal include the application of insect growth regulators (IGRs) and utilization of resistant cotton lines. This thesis summarizes experiments that elucidate the physiological underpinnings of the mode of action of novaluron, an IGR, and a cotton chromosome substitution (CS) line on the reproductive physiology of L. lineolaris. Investigations reported herein indicate that novaluron inhibits oviposition by inhibiting ovarian development and decreasing the expression of a gene (LlCHS-1) encoding chitin synthase. Transcriptomic analysis of ovarian tissue of L. lineolaris fed on a resistant CS line compared to a control line revealed the downregulation of genes involved in chitin synthesis and upregulation of genes involved in chitin degradation. Lygus lineolaris Insect growth regulator Novaluron Ovaries Transcriptomics Biochemistry Entomology Molecular Biology
185	Identifying cell type-specific proliferation signatures in spatial transcriptomics data and inferring interactions driving tumour growth Wærn, Felix January 2023 (has links) Cancer is a dangerous disease caused by mutations in the host's genome that makes the cells proliferateuncontrollably and disrupts bodily functions. The immune system tries to prevent this, but tumours have methods ofdisrupting the immune system's ability to combat the cancer. These immunosuppression events can for examplehappen when the immune system interacts with the tumour to recognise it or try and destroy it. The tumours can bychanging their displayed proteins on the cell surface avoid detection or by excreting proteins, they can neutralisedangerous immune cells. This happens within the tumour microenvironment (TME), the immediate surrounding of atumour where there is a plethora of different cells both aiding and suppressing the tumour. Some of these cells arenot cancer cells but can still aid the tumour due to how the tumour has influenced them. For example, throughangiogenesis, where new blood vessels are formed which feeds the tumour. The interactions in the TME can be used as a target for immunotherapy, a field of treatments which improves theimmune system's own ability at defending against cancer. Immunotherapy can for example help the immune systemby guiding immune cells towards the tumour. It is therefore essential to understand the complex system ofinteractions within the TME to be able to create new methods of immunotherapy and thus treat cancers moreefficiently. Concurrently new methods of mapping what happens in a tissue have been developed in recent years,namely spatial transcriptomics (ST). It allows for the retrieval of transcriptomic information of cells throughsequencing while still retaining spatial information. However, the ST methods which capture the wholetranscriptome of the cells and reveal the cell-to-cell interactions are not of single-cell resolution yet. They capturemultiple cells in each spot, creating a mix of cells in the sequencing. This mix of cells can be detangled, and theproportions of each cell type revealed through the process of deconvolution. Deconvolution works by mapping thesingle cell expression profile of different cell types onto the ST data and figuring out what proportions of expressioneach cell type produces the expression of the mix. This reveals the cellular composition of the microenvironment.But since the interactions in the TME depend on the cells current expression we need to deconvolute according tophenotype and not just cell type. In this project we were able to create a tool which automatically finds phenotypes in the single-cell data and usesthose phenotypes to deconvolute ST data. Phenotypes are found using dimensionality reduction methods todifferentiate cells according to their contribution to the variability in the data. The resulting deconvoluted data wasthen used as the foundation for describing the growth of a cancer as a system of phenotype proportions in the tumourmicroenvironment. From this system a mathematical model was created which predicts the growth and couldprovide insight into how the phenotypes interact. The tool created worked as intended and the model explains thegrowth of a tumour in the TME with not just cancer cells phenotypes but other cell phenotypes as well. However, nonew interaction could be discovered by the final model and no phenotype found could provide us with new insightsto the structure of the TME. But our analysis was able to identify structures we expect to see in a tumour, eventhough they might not be so obvious, so an improved version of our tools might be able to find even more detailsand perhaps new, more subtle interactions. spatial transcriptomics breast cancer dimensionality reduction bioinformatics deconvolution Bioinformatics and Systems Biology Bioinformatik och systembiologi
186	Understanding the dynamics of rhythmic gene expression in mammalian cells Unruh, Benjamin Alex 16 June 2023 (has links) In mammals, circadian rhythms are driven by a cell-autonomous core-clock mechanism consisting of over a dozen core-clock genes forming transcription-translation feedback loops. The core-clock mechanism also drives the rhythmic expression of downstream genes called clock-controlled genes, which are thought to be important for driving rhythmic biochemical and physiological processes. Mathematical models predict that for a gene to be rhythmically expressed, synthesis, degradation, or a combination of the two must be rhythmic. The purpose of this project was to investigate the contribution of synthesis and degradation of RNA to rhythmic gene expression. To systematically understand the contribution of synthesis, degradation, and other RNA dynamics to rhythmic gene expression, I used metabolic labeling and a novel computational pipeline to analyze transcriptomic data in synchronized NIH3T3 cells. I identified 685 rhythmically expressed RNAs with a period of 24-hour in my dataset, of those 389 were rhythmically synthesized and 24 were rhythmically degraded. Low amplitude degradation rhythms were detected more broadly in the 685 rhythmically expressed RNAs, but these were not statistically significant. Although synthesis was the primary driver of rhythmic 24-hour RNA expression, core-clock gene RNAs were regulated by both synthesis and degradation, presumably to sustain high amplitude of rhythmic expression. I also identified rhythmic RNA expression with a period of 12 and 8 hours; interestingly, degradation primarily drove rhythmic expression of these RNAs. Overall this dissertation revealed RNA dynamics that drive rhythmic gene expression. This will provide insights into how diverse circadian clock mechanisms ultimately drive tissue-specific rhythmic gene expression. / Doctor of Philosophy / Almost all organisms on Earth have an internal timekeeping system, called a circadian clock, that enables them to anticipate and respond to the day/night cycle. The circadian clock regulates diverse body processes such as the sleep/wake cycle, eating and digestion, body temperature, and blood pressure. Disruptions to the circadian clock are detrimental to health and wellbeing. Many organisms, including humans, have a core circadian clock mechanism that drives rhythmic gene expression in thousands of genes that are thought to be ultimately responsible for rhythmic biological and physiological processes. My project investigates how the core clock mechanism drives rhythmic gene expression. I found that rhythmic synthesis of RNA was a primary driver of rhythmic gene expression, but the genes involved in the core circadian clock mechanism itself was regulated by multiple rhythmic processes. Understanding rhythmic gene expression control points is integral for understanding how circadian gene expression can be changed or interrupted. Gene Expression Circadian Chronobiology RNA transcription post-transcription regulation genomics transcriptomics
187	METABOLIC NETWORK-BASED ANALYSES OF OMICS DATA Cicek, A. Ercument 23 August 2013 (has links) No description available. Bioinformatics Computer Science Metabolomics Transcriptomics Metabolic Network Gene Expression Knowledge Discovery
188	Identification of Novel Protein Substrates and Chemical Inhibitors of the T3SA in Shigella Silué, Navoun 17 May 2023 (has links) Enteropathogenic bacteria, such as Shigella and Salmonella, are associated with diarrheal diseases, which remain a significant cause of infant mortality worldwide. The secretion of protein effectors by the type III secretion apparatus (T3SA) is used by these pathogens to invade human cells and modulate host cell functions. First, we used RNA-Seq to analyze the differential transcriptome of Shigella flexneri when the T3SA is active or inactive. This allowed us to identify two uncharacterized genes that were temporarily named gem1 and gem3 and whose expression was regulated by MxiE and IpgC as other late substrates of the T3SA. Finally, we pursued the characterization of gem1 and gem3 at the protein level and renamed them icaT and icaR, respectively, when we found their protein products were secreted by the T3SA. Furthermore, we find homologs of icaT and icaR with a conserved MxiE box in several E. coli phylogroups. We also demonstrated that these homologous genes could be reactivated when both MxiE and IpgC were introduced in these strains. This discovery paved a new perspective on the evolution of pathogenesis into the E. coli lineage as both commensal and pathogenic strains harbored these genes. Treating infections caused by Enterobacteriaceae is becoming more challenging due to growing antibiotic resistance and no vaccines are widely available. Accordingly, the World Health Organization (WHO) recognized that we entered the "post-antibiotic era," where new antibiotics or antivirulence drugs are urgently needed, including for Shigella. The T3SA is an attractive target for antivirulence drugs, which may become alternative to classical antibiotics. Through screening 3,000 compounds, we found two novel inhibitors of the T3SA. Our data suggested that one of these candidate inhibitors, a dipyridyl-containing compound, reduces the virulence of Shigella at the transcriptional level. Indeed, the virulence inhibition occurs via the repression of the transcriptional activator VirB by the small chromosomal RNA RyhB, which is upregulated by this compound through an unknown mechanism involving the pyridyl groups. The repression of VirB induced by this molecule reduce the expression of several genes encoding parts of the T3SA. In comparison, the second compound is a quinone that seems to affect the assembly of the T3SA. RNA-Seq Shigella T3SS T3SA pINV Small RNA RyhB Transcriptomics Operon icaR icaT
189	Developmental Regulation of Translation in Parasitic Flatworms Hagerty, James Robert 01 September 2021 (has links) No description available. Biomedical Research Biology
190	A visualization interface for spatial pathway regulation data Zhang, Yang January 2018 (has links) Data visualization is an essential methodology for bioinformatics studies. Spatial Transcriptomics(ST) is a method that aims at measuring the transcriptome of tissue sections while maintaining its spacial information. Finally, the study of biological pathway focuses on a series of biochemical reactions that take place in organisms. As these studies generate a large number of datasets, this thesis attempts to combine the ST’s data with pathwayinformation and visualize it in an intuitive way to assist user comprehension and insight.In this thesis, Python was used for integrating the dataset and JavaScript libraries wereused for building the visualization. The processing of ST pathway data together with the data visualization interface are the outcomes of this thesis. The data visualization can show the regulation of pathways in the ST data and can be accessed by modern browsers. These outcomes can help users navigate the ST and pathway datasets more effectively. / Datavisualisering är en viktig del av bioinformatik. Spatial transkriptomik (ST) är en metod som mäter transkriptom, samtidigt som den behåller spatial information. Biologiskapathways å andrasidan fokuserar på biokemiska reaktioner som sker inom organismer. Dessa studier genererar mycket data, och denna avhandling försöker att kombinera ST-data med pathway information och få en intuitiv visualisering av det integrerade datat.I avhandlingen användes Python för att integrera datat och JavaScript bibliotek för attbygga visualiseringsverktyget. Avhandlingen resulterade i en metod för att integrera STdata och pathway information, samt ett visualiseringsverktyg för ovan nämnda information.Verktyget kan visa pathway regulationer i ST data och kan användas i moderna webbläsare.Forskningen resulterade i ett verktyg som kan hjälpa forskare att förstå ST och pathwaydata. Data Visualization Pathway Spatial Transcriptomics JavaScript Python Natural Sciences Naturvetenskap Chemical Sciences Kemi

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