Global ETD Search

771	Investigation of Dynamic Biological Systems Using Direct Injection and Liquid Chromatography Mass Spectrometry Swensen, Adam Clayton 01 December 2016 (has links) In biological systems, small changes can have significant impacts. It is, therefore, very important to be able to identify these changes in order to understand what is occurring in the organism. In many cases, this is not an easy task. Mass spectrometry has proven to be a very useful tool in elucidating biological changes even at a very small scale. Several different mass spectrometry based techniques have been developed to discover and investigate complex biological changes. Some of these techniques, such as proteomics, have been through years of development and have advanced to the point that anyone can complete complex analyses of global protein identification and measurement with relative ease. Other techniques are still developing and still have some ground to cover in terms of experimental outcome and ease of execution. Herein we show improvements we have made in high-throughput high-resolution mass spectrometry based techniques to identify and quantify small molecules that are involved in significant biological changes. To begin, we show that our improved high-resolution mass spectrometry based lipidomics techniques are capable of identifying small changes in diseased states that are associated with inflammation, mitochondrial shape and function, and cancer. With our techniques we have been able to extract, identify, and quantify several thousand unique lipid species from complex samples with confidence. Our initial studies looked at global lipidome profiles of differing tissue types from human and mouse biopsies. This was then adapted to compare the global lipidomes of diseased states against healthy states in asthmatic lung tissue, cigarette smoke treated cells, high fat high sugar (HFHS) stressed animals (with and without additional treatment), and in signaling lipids associated with cell death resistance and growth signaling in pancreatic cancer. As a result of our success with lipidomic method improvement we then adapted our techniques and knowledge for use in elucidating small molecule signaling peptides and oxidation changes in proteins. We were able to show that our improved liquid chromatography mass spectrometry based small molecule assays are capable of identifying and quantifying small peptides and protein modifications that would otherwise be undetectable using traditional techniques. This work resulted in the development of a scalable method to detect and quantify the small iron-regulatory hormone known as hepcidin from a variety of samples such as blood, urine, and cell-culture media. We were also instrumental in evaluating and revising a new ultra-high pressure liquid chromatography (UHPLC) system that allows for better separation of analytes from complex mixtures for identification and quantification. Through these advances we hope to aid researchers and clinicians to enable them to use mass spectrometry to further our knowledge about the small but significant changes that regulate complex biological systems. mass spectrometry proteomics lipidomics metabolomics cancer research liquid chromatography sphingosine kinase hepcidin ceramide Chemistry
772	Neural Mechanisms of Transcranial Magnetic Stimulation in the Treatment of Tinnitus Lowe, Andrea S. 01 April 2018 (has links) Millions of people suffer from tinnitus, a disorder for which there is currently no effective treatment or cure. My dissertation work provides insight into the neural correlates of this pervasive hearing disorder and examines how a newly emerging therapy, transcranial magnetic stimulation (TMS), affects the central auditory system in the generation of the tinnitus percept. This work has a multifold focus of: i) developing and modeling the function of a miniature magnetic coil that can be used for TMS in rodents, ii) establishing a reliable mouse model of tinnitus that can be used for assessing TMS treatment-induced changes, iii) measuring the behavioral alterations and neural changes induced by TMS throughout the auditory system in mice with tinnitus, and iv) to assay underling molecular changes in the auditory cortex (AC) related to TMS and tinnitus. Chapter 1 gives an overview of the current research on tinnitus and TMS. Chapter 2 establishes a reliable neural and behavioral assay of verifying tinnitus in a mouse model and provides further evidence that the underlying hyperactivity associated with tinnitus is initiated in the brainstem following reduced afferent input. The remainder of the dissertation examines the modulation of tinnitus in the auditory central nervous system using a miniature TMS coil. Chapter 3 of the dissertation details the creation and evaluation of a rodent-sized TMS coil, which could increase the overall effectiveness and applicability for human treatment. TMS is currently an FDA approved treatment of depression and has been shown to decrease tinnitus perception in human clinical trials, albeit with variable results. There have been few published studies of tinnitus modulation by TMS using animal models and therefore little is known about the molecular and neural bases of this potential tinnitus treatment. TMS is thought to be therapeutic because the magnetic flux generated from the electromagnetic coil induces an electric field in the brain, altering ion flow and subsequently neural function, as the excitation and inhibition of cortical networks become synchronized to the magnetic pulse. Chapter 4 demonstrates that TMS with our custom-designed miniature rodent coil can successfully reduce behavioral evidence of tinnitus in a mouse model, mainly through activating inhibitory networks in the AC. It also shows that presynaptic activity is altered in the upper layers of the AC responsible for intralaminar processing and sound perception. Finally, chapter 5 describes an in-depth proteomic analysis of over 3000 proteins from the AC, which shows that TMS and noise-induced tinnitus alter the expression of several key proteins and pathways that play a critical role in cortical excitatory and inhibitory activation. The results of this work are also important because they are the first animal model to demonstrate neural changes during TMS-treated tinnitus, creating a paradigm that can be used for optimizing parameters to improve clinical outcomes in human trials. electrophysiology maladaptive plasticity mouse model proteomics Neurosciences
773	Proteomics of the human alcoholic brain: Implications for the pathophysiology of alcohol-related brain damage Alexander-Kaufman, Kimberley Louise January 2008 (has links) Doctor of Philosophy (PhD) / Proteomics is rapidly achieving recognition as a complimentary and perhaps superior approach to examine global changes in protein abundance in complex biological systems and the value of these techniques in neuropsychiatry is beginning to be acknowledged. Characterizing the brain’s regional proteomes provides a foundation for the detection of proteins that may be involved in disease-related processes. Firstly, optimal conditions were achieved for the application of two dimensional-gel electrophoresis (2D-GE)-based proteomics with postmortem human brain tissue. These optimized techniques were then applied to soluble fractions of adjacent grey and white matter of a single cytoarchitecturally defined area (Brodmann area 9; BA9) and of two adjacent regions of frontal white matter (BA9 and CC body) from healthy individuals. These normative proteomic comparisons highlighted the importance of correct tissue sampling, i.e. proper separation of regional white matter, as heterogeneity in the respective proteomes was demonstrated. Furthermore, they stressed the necessity for future molecular brain mapping studies. The main focus of this thesis however, was to examine the proteomes of brain regions specifically vulnerable to alcohol-induced damage underlying cognitive dysfunction. Alcoholic patients commonly experience mild to severe cognitive decline. It is postulated that cognitive dysfunction is caused by an alcohol-induced region selective brain damage, particularly to the prefrontal cortex. The cerebellum is increasingly recognized for its role in various aspects of cognition and alcohol–induced damage to the cerebellar vermis could indirectly affect neurocognitive functions attributed to the frontal lobe. We used a 2D-GE-based proteomics approach to compare protein abundance profiles of BA9 grey and white matter and the cerebellar vermis from human alcoholics (neurologically uncomplicated and alcoholics complicated with liver cirrhosis) and healthy control brains. Among the protein level changes observed are disturbances in the levels of a number of thiamine-dependent enzymes. A derangement in energy metabolism perhaps related to thiamine deficiency seems to be important in all regions analysed, even where there are no clinical or pathological findings of Wernicke-Korsakoff Syndrome. Evidence of oxidative changes was also seen in all regions and effects of liver dysfunction in the vermis found. However, overall, these results highlight the complexity of this disease process in that a number of different proteins from different cellular pathways appear to be affected. By identifying changes in protein abundance levels in the prefrontal grey and white matter and the cerebellar vermis, hypotheses may draw upon more mechanistic explanations as to how chronic ethanol consumption causes the structural and functional alterations associated with alcohol-related brain damage. Furthermore, by comparing these results, we may be able to isolate disturbances in molecular pathways specific to the brain damage caused by alcohol, severe liver dysfunction and thiamine deficiency. Alcohol-related brain damage proteomics thiamine deficiency neuropathology Wernicke-Korsakoff Syndrome 2D gel electrophresis
774	Molecular studies of the response of Helicobacter hepaticus to bile, and the effect of Helicobacter bilis on human hepatoma cells Okoli, Arinze Stanley, Medical Sciences, Faculty of Medicine, UNSW January 2009 (has links) Enterohepatic Helicobacter species (EHS) are emerging infectious disease agents. Infection of the enterohepatobiliary tract of several mammals by this group of bacteria results in various pathological disorders. The availability of the Helicobacter hepaticus sequenced and annotated genome, allowed molecular characterisation of the responses of H. hepaticus to host factors such as bile. The adaptation/responses of the bacterium to bovine, porcine and human bile were investigated using proteomics and transcriptomics. Ninety-one different proteins were identified in the responses of H. hepaticus response to the three types of bile. These proteins participate in several key cellular processes including DNA replication; protein transcription, translation and folding; oxidative stress response; motility; virulence; and metabolism. In particular, the bacteria deployed several strategies such as inhibition of the TCA cycle and the electron transport chain as well as iron sequestration to ensure control of the levels of hydroxyl radicals. The results of this study revealed also the modulation by bile of the expression of H. hepaticus genes involved in response to oxidative stress and virulence. The responses of human HEp-2 and Huh7-derived cell-lines to H. hepaticus and Helicobacter bilis, respectively, were investigated employing proteomics and transcriptomics. One-hundred and twenty different proteins were differentially expressed in the responses of the human cells to the presence of Helicobacter spp. in the cell cultures. These proteins are involved in regulation of cell proliferation and structure; metabolism; protein transcription, translation and modification; stress response; and tumour induction. For example, in co-cultures of Huh7-derived cells and H. bilis, the activation of several mitochondrial and endoplasmic reticulum stress-related proteins and the dysregulation of several apoptosis effectors were suggested as mechanisms that could result in the death of the liver cells. Importantly, the differential expression of several tumour-related proteins by the Huh7 cells supported a possible role for Helicobacter spp. in liver cancer. Proteomics Helicobacter hepaticus Helicobacter bilis Molecular Bile Cancer Liver 2D-PAGE
775	Oxidative, inflammatory and vascular factors in Alzheimer's disease Poljak, Anne, Medical Sciences, Faculty of Medicine, UNSW January 2008 (has links) In spite of impressive recent progress, the aetiopathogenesis of Alzheimers disease (AD) remains incompletely understood. The distinctive neuropathological features of AD, in particular the plaques and tangles, have been the particular focus of most aetiological theories. It is well accepted that AD is a multifactorial disease, with alterations to a variety of brain structures and cell types, including neurons, glia and the brain vasculature. Studies of risk factors have revealed a diversity of genetic variables that interact with health, diet and lifestyle-related factors in the causation of AD. These factors influence the structure, aggregation and function of a set of proteins that are increasingly the focus of research. The work in this thesis has focused on the pathophysiological aspects of some of these proteins in a number of cellular compartments and brain. Several assays have been established and techniques utilized in the completion of this work, including; differential detergent fractionation of brain tissue, 1D and 2D PAGE, western blotting with chemiluminescence detection, ELISA assays of Abeta 1-40 and 1-42, quantitative ECNI GCMS of o- and m-tyrosine as well as metabolites of the kynurenine pathway, quantitative MALDI-TOF assay of hemorphins and LCMSMS based proteomics, to identify proteins with altered expression levels in AD relative to control brain tissue. A variety of regional differences have been observed in the biochemistry of the AD cortex which are probably the outcome of local response variations to AD pathology. One of the most consistent threads throughout this work has been an apparent resilience of the occipital lobe relative to the other brain regions, as reflected in lower overall levels of oxidative stress and increased levels of proteins associated with metabolic processes, neuronal remodeling and stress reduction. Oxidative Stress Alzheimer's disease Dementia Inflammation Vascular Mass Spectrometry Proteomics Metabolomics
776	Mapping the proteome of Streptococcus gordonii Macarthur, Deborah Jane January 2005 (has links) Streptococcus gordonii is a primary coloniser of the tooth surface where it efficiently ferments carbohydrates at pH levels above 6.0. By not being able to maintain the pH of dental plaque to a level required for enamel dissolution, the dominance of S. gordonii in dental plaque is considered a sign of a healthy oral cavity. However, upon entering the bloodstream and encountering a rise in pH, S. gordonii may become pathogenic, being one of the major causative organisms associated with infective endocarditis. Proteome analyses of S. gordonii grown at steady state in a chemostat allowed the phenotypic changes associated with alterations in pH levels characteristic of these two environments to be determined. As an initial starting point to this study, a two-dimensional electrophoresis (2- DE) reference map of S. gordonii grown at pH 7.0 was produced. Although only 50% of the S gordonii genome was available in an annotated form during the course of this study, the closely related Streptococcus pneumoniae genome (with which S. gordonii shares 97.24% DNA sequence homology) had been completed in 2001. The use of both of these databases allowed many of the S. gordonii proteins to be identified by mass spectrometry. Four hundred and seventy six protein spots, corresponding to 250 different proteins, or 12.5% of the S. gordonii proteome, were identified, giving rise to the first comprehensive proteome reference map of this oral bacterium. Of the 250 different proteins, 196 were of cellular origin while 68 were identified from the extracellular milieu. Only 14 proteins were common to both compartments. Of particular interest among the 54 uniquely identified extracellular proteins was a homologue of a peptidoglycan hydrolase that has been associated with virulence in S. pneumoniae. Among the other proteins identified were ones involved in transport and binding, energy metabolism, translation, transformation, stress response and virulence. Twelve cell envelope proteins were identified as well as 25 others that were predicted to have a membrane association based on the presence of at least one transmembrane domain. The study also confirmed the existence of 38 proteins previously designated as �hypothetical� or with no known function. Mass spectral data for over 1000 protein spots were accumulated and archived for future analysis when sequencing of the S. gordonii genome is finally completed. Following the mapping of the proteome of S. gordonii, alterations in protein spots associated with growth of the bacterium at pH intervals of 0.5 units in the pH range 5.5 - 7.5 were determined. Only 16 protein spots were shown to be significantly altered in their level of expression despite the range of pH studied. Among the differentially expressed proteins was a manganese-dependent inorganic pyrophosphatase (PpaC), which regulates expression of adhesins required for coaggregation. The expression of PpaC was highest at pH 6.5 - 7.0, the pH of a healthy oral cavity, indicating that PpaC may play an important part in dental plaque formation. Another differentially expressed protein was the heat-inducible transcription repressor (HrcA). Alterations in HrcA were consistent with its role as a negative repressor in regulating heat-shock proteins at low pH, even though no changes in the level of heat-shock proteins were observed as the pH declined. This result gave rise to the hypothesis that the possible reason cariogenic bacteria, such as Streptococcus mutans, can out compete S. gordonii at low pH might simply be due to their ability to manipulate their proteome in a complex manner for survival and persistence at low pH, unlike S. gordonii. This may imply some prevailing level of genetic regulation that is missing in S. gordonii.
777	Identification of cellular changes associated with increased production of human follicle stimulating hormone in a recombinant Chinese hamster ovary cell line Misztal, David Richard, Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW January 2008 (has links) A proteomics approach was used to identify proteins potentially implicated in the cellular response concurrent with elevated production levels of human follicle stimulating hormone in a recombinant Chinese hamster ovary cell line (Darren cells), using zinc and sodium butyrate in the production media to increase expression. To this end, 2-dimensional gel electrophoresis (2-DGE) was utilized. Firstly, several aspects of 2-DGE were developed for this investigation. Gel drying conditions were optimized, and a glycine-free blotting method is described which achieved greater efficiency in rapid transfer of proteins than those previously described. Next, hFSH expression was characterized in Darren cells. An ELISA developed for this investigation examined intracellular (expression) and extracellular (secretion) of hFSH during increased expression. These results show a disproportionate increase in intracellular hFSH (188%) expression above extracellular hFSH (41%). Chinese Hamster Ovary cells proteomics Animal cell culture chaperones hFSH 2 dimensional gel electrophoresis
778	Characterization of chromatin by use of high performance liquid chromatography-tandem mass spectrometry for insights into the epigenetics of cancer Meade, Mitchell L., January 2007 (has links) Thesis (Ph. D.)--Ohio State University, 2007. / Title from first page of PDF file. Includes bibliographical references (p. 149-167).
779	Feature extraction and similarity-based analysis for proteome and genome databases Öztürk, Özgür. January 2007 (has links) Thesis (Ph. D.)--Ohio State University, 2007. / Title from first page of PDF file. Includes bibliographical references (p. 108-119).
780	Enrichment strategy development for phosphoproteome analysis of <em>saccharomyces cerevisiae</em> Lundemo, Pontus January 2009 (has links) <p>The reversible phosphorylation of proteins is central to regulating most aspects of cell function. Malfunction in this critical cellular process have been implicated to cause diseases such as diabetes, cancer, and Alzheimer’s. Recent advances in mass spectrometry have made it possible to study this important post translational modification on a proteome-wide scale. However, to be able to do so, enrichment of phosphorylated peptides is required. Pairwise comparison of individual steps in an enrichment procedure and simultaneous improvement of data analysis resulted in a protocol which allowed high confidence identification of 2,131 unique phosphorylated peptides from 1,026 proteins. Thereby not only establishing a working protocol for phosphopeptide enrichment in the Griffin Lab, but also generating the largest list of proteins phosphorylated under normal conditions in yeast to date.</p> Proteomics mass spectrometry phosphorylation yeast IMAC SCX Sequest Other bioengineering Övrig bioteknik

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