Global ETD Search

201	Advancements in the Synthesis and Application of Near-Infrared Imaging Reagents: A Dissertation Pauff, Steven M. 23 January 2015 (has links) Fluorescence-based imaging techniques provide a simple, highly sensitive method of studying live cells and whole organisms in real time. Without question, fluorophores such as GFP, fluorescein, and rhodamines have contributed vastly to our understanding of both cell biology and biochemistry. However, most of the fluorescent molecules currently utilized suffer from one major drawback, the use of visible light. Due to cellular autofluorescence and the absorbance of incident light by cellular components, fluorescence imaging with visible wavelength fluorophores often results in high background noise and thus a low signal-to-noise ratio. Fortunately, this situation can be ameliorated by altering the wavelength of light used during imaging. Near-infrared (NIR) light (650-900 nm) is poorly absorbed by cells; therefore, fluorophores excited by this light provide a high signal-to-noise ratio and low background in cellular systems. While these properties make NIR fluorophores ideal for cellular imaging, most currently available NIR molecules cannot be used in live cells. The first half of this thesis addresses the synthetic difficulties associated with preparing NIR fluorophores that can be used within living systems. Small molecule NIR fluorophores are inherently hydrophobic which makes them unsuitable for use in the aqueous environment of the cell. Water-solubility is imparted to these dyes through highly polar sulfonates, which subsequently prevents the dyes from entering the cell. The novel work presented here details vii synthetic routes to aid in the development of sulfonated NIR fluorophores, which can be delivered into live cells through the inclusion of an esterase-labile sulfonate protecting group. Application of these synthetic techniques should allow for the development of novel NIR fluorophores with intracellular applications. The second half of this thesis addresses the need for novel NIR imaging reagents. Although several classes of NIR scaffolds do exist, most NIR probes are derivatives of a single class, heptamethine indocyanines. The work described here increases this palette by displaying the ability of NIR oxazines to function as an imaging reagent in live cells and in vivo and as a molecular sensor of biologically-relevant environmental conditions. Combined, the work contained herein has the capacity to not only advance the current NIR toolkit, but to expand it so that fluorescence imaging can move out of the dark and into the NIR light. Near-Infrared Spectroscopy Coloring Agents Diagnostic Imaging Esterases Fluorescein Fluorescence Fluorescent Dyes Indicators and Reagents Light Optical Imaging Oxazines Rhodamines Dissertations, UMMS Spectroscopy, Near-Infrared Biochemistry Chemistry Molecular Biology
202	IRF4 Does the Balancing Act: A Dissertation Nayar, Ribhu 07 January 2015 (has links) CD8+ T cell differentiation is a complex process that requires integration of signals from the TCR, co-stimulatory molecules and cytokines. Ligation of the peptide-MHC complex with the cognate TCR initiates a downstream signaling cascade of which the IL-2 inducible T-cell kinase (ITK) is a key component. Loss of ITK results in a measured reduction in T cell activation. Consequently, Itk deficient mice have defects in thymic selection, CD8+ T cell expansion and differentiation in response to virus infections, and generate a unique population of innate-like CD8+ T cells. The mechanisms that translate TCR and ITK-derived signals into distinct gene transcription programs that regulate CD8+ T cell differentiation are not defined. Our microarray screen identified IRF4 as a potential transcription factor mediating the differentiation of innate-like T cells, and antiviral CD8+ T cell in response to acute and chronic LCMV infections. Innate-like CD8+ T cells are characterized by their high expression of CD44, CD122, CXCR3, and the transcription factor Eomesodermin (Eomes). One component of this altered development is a non-CD8+ T cell-intrinsic role for IL-4. We show that IRF4 expression is induced upon TCR signaling and is dependent on ITK activity. In contrast to WT cells, activation of IRF4-deficient CD8+ T cells leads to rapid and robust expression of Eomes, which is further enhanced by IL-4 stimulation. These data indicate that ITK signaling promotes IRF4 up-regulation following CD8+ T cell activation and that this signaling xii pathway normally suppresses Eomes expression, thereby regulating the differentiation pathway of CD8+ T cells. ITK deficient mice also have reduced expansion of CD8+ T cells in response to acute LCMV infections. We show that IRF4 is transiently upregulated to differing levels in murine CD8+ T cells, based on the strength of TCR signaling. In turn, IRF4 controls the magnitude of the CD8+ T cell response to acute virus infection in a dose-dependent manner. Furthermore, the expression of key transcription factors such as T cell factor 1 and Eomesodermin are highly sensitive to graded levels of IRF4. In contrast, T-bet expression is less dependent on IRF4 levels and is influenced by the nature of the infection. These data indicate that IRF4 is a key component that translates the strength of TCR signaling into a graded response of virus-specific CD8+ T cells. The data from these studies indicated a pivotal role of IRF4 in regulating the expression of T-bet and Eomes. During persistent LCMV infections, CD8+ T cells differentiate into T-bethi and Eomeshi subsets, both of which are required for efficient viral control. We show that TCR signal strength regulates the relative expression of T-bet and Eomes in antigen-specific CD8+ T cells by modulating levels of IRF4. Reduced IRF4 expression results in skewing of this ratio in favor of Eomes, leading to lower proportions and numbers of T-bet+ Eomes- precursors and poor control of LCMV Clone 13 infection. Altering this ratio in favor of T-bet xiii restores the differentiation of T-bet+ Eomes- precursors and the protective balance of T-bet to Eomes required for efficient viral control. These data highlight a critical role for IRF4 in regulating protective anti-viral CD8+ T cell responses by ensuring a balanced ratio of T-bet to Eomes, leading to the ultimate control of this chronic viral infection. Interferon Regulatory Factors CD8-Positive T-Lymphocytes Cell Differentiation Lymphocytic choriomeningitis virus T Cell Transcription Factor 1 Dissertations, UMMS Cellular and Molecular Physiology Immunity Immunology of Infectious Disease
203	A More Accessible Drosophila Genome to Study Fly CNS Development: A Dissertation Chen, Hui-Min 16 March 2015 (has links) Understanding the complex mechanisms to assemble a functional brain demands sophisticated experimental designs. Drosophila melanogaster, a model organism equipped with powerful genetic tools and evolutionarily conserved developmental programs, is ideal for such mechanistic studies. Valuable insights were learned from research in Drosophila ventral nerve cord, such as spatial patterning, temporal coding, and lineage diversification. However, the blueprint of Drosophila cerebrum development remains largely unknown. Neural progenitor cells, called neuroblasts (NBs), serially and stereotypically produce neurons and glia in the Drosophila cerebrum. Neuroblasts inherit specific sets of early patterning genes, which likely determine their individual identities when neuroblasts delaminate from neuroectoderm. Unique neuroblasts may hence acquire the abilities to differentially interpret the temporal codes and deposit characteristic progeny lineages. We believe resolving this age-old speculation requires a tracing system that links patterning genes to neuroblasts and corresponding lineages, and further allows specific manipulations. Using modern transgenic systems, one can immortalize transient NB gene expressions into continual labeling of their offspring. Having a collection of knockin drivers that capture endogenous gene expression patterns would open the door for tracing specific NBs and their progenies based on the combinatorial expression of various early patterning genes. Anticipating the need for a high throughput gene targeting system, we created Golic+ (gene targeting during oogenesis with lethality inhibitor and CRISPR/Cas “plus”), which features efficient homologous recombination in cystoblasts and a lethality selection for easy targeting candidate recovery. Using Golic+, we successfully generated T2AGal4 knock-ins for 6 representative early patterning genes, including lab, unpg, hkb, vnd, ind, and msh. They faithfully recapitulated the expression patterns of the targeted genes. After preserving initial NB expressions by triggering irreversible genetic labeling, we revealed the lineages founded by the NBs expressing a particular early patterning gene. Identifying the neuroblasts and lineages that express a particular early patterning gene should elucidate the genetic origin of neuroblast diversity. We believe such an effort will lead to a deeper understanding of brain development and evolution. Drosophila melanogaster Cerebrum Neural Stem Cells Body Patterning Gene Targeting Cell Lineage CRISPR-Cas Systems Dissertations, UMMS Developmental Biology Developmental Neuroscience Genetics and Genomics Genomics
204	Approaches and Considerations Towards a Safe and Effective Adeno-Associated Virus Mediated Therapeutic Intervention for GM1-Gangliosidosis: A Dissertation Weismann, Cara M. 05 August 2014 (has links) GM1 gangliosidosis is a lysosomal storage disorder caused by a deficiency in the catabolizing enzyme β-galactosidase (βgal). This leads to accumulation of GM1-ganglioside (GM1) in the lysosome inducing ER stress and cell death. GM1 gangliosidosis is primarily a disorder of the central nervous system (CNS) with peripheral organ involvement. In this work we report two major findings, 1) systemic treatment of GM1 gangliosidosis with an adenoassociated virus (AAV9) encoding mouse-βgal (mβgal) in a GM1 gangliosidosis mouse model (βGal-/-), and 2) an investigation into an intracranial injection of a therapeutic AAVrh8 encoding mβgal. Systemic treatment of GM1 gangliosidosis with AAV9 resulted in a moderate expression of enzyme in the CNS, reduction of GM1 storage, significant retention of motor function and a significant increase in lifespan. Interestingly, the therapeutic effect was more robust in females. Intracranial injections of AAVrh8 vector expressing high levels of βgal resulted in enzyme spread throughout the brain, significant retention of motor function and a significant increase in lifespan. Histological alterations were also found at the injection site in both βGal-/- and normal animals. We constructed a series of vectors with a range of decreasing enzyme expression levels to investigate the cause for the unanticipated result. Microarrays were performed on the injection site and we showed that a lower expressing AAVrh8-mβgal vector mitigated the negative response. Intracranial injection of this newly developed vector was shown to clear lysosomal storage throughout the CNS of βGal-/- mice. Taken together, these studies indicate that a combined systemic and fine-tuned intracranial approach may be the most effective in clearing lysosomal storage completely in the CNS while providing therapeutic benefit to the periphery. Dependovirus G(M1) Ganglioside GM1 Gangliosidosis Genetic Vectors Lysosomal Storage Diseases beta-Galactosidase Dissertations, UMMS Gangliosidosis, GM1 Genetics and Genomics Nervous System Diseases Neuroscience and Neurobiology Therapeutics
205	Hepatitis C Virus: Structural Insights into Protease Inhibitor Efficacy and Drug Resistance: A Dissertation Soumana, Djade I. 15 December 2015 (has links) The Hepatitis C Virus (HCV) is a global health problem as it afflicts an estimated 170 million people worldwide and is the major cause of viral hepatitis, cirrhosis and liver cancer. HCV is a rapidly evolving virus, with 6 major genotypes and multiple subtypes. Over the past 20 years, HCV therapeutic efforts have focused on identifying the best-in-class direct acting antiviral (DAA) targeting crucial components of the viral lifecycle, The NS3/4A protease is responsible for processing the viral polyprotein, a crucial step in viral maturation, and for cleaving host factors involved in activating immunity. Thus targeting the NS3/4A constitutes a dual strategy of restoring the immune response and halting viral maturation. This high priority target has 4 FDA approved inhibitors as well as several others in clinical development. Unfortunately, the heterogeneity of the virus causes seriously therapeutic challenges, particularly the NS3/4A protease inhibitors (PIs), which suffer from both the rapid emergence of drug resistant mutants as well as a lack of pan-genotypic activity. My thesis research focused on filling two critical gaps in our structural understanding of inhibitor binding modes. The first gap in knowledge is the molecular basis by which macrocyclization of PIs improves antiviral activity. Macrocycles are hydrophobic chains used to link neighboring chemical moieties within an inhibitor and create a structurally pre-organized ligand. In HCV PIs, macrocycle come in two forms: a P1 - P3 and P2 - P4 strategy. I investigated the structural and thermodynamic basis of the role of macrocyclization in reducing resistance susceptibility. For a rigorous comparison, we designed and synthesized both a P1 - P3 and a linear analog of grazoprevir, a P2 - P4 inhibitor. I found that, while the P2 - P4 strategy is more favorable for achieving potency, it does not allow the inhibitor sufficient flexibility to accommodate resistance mutations. On the other hand, the P1 - P3 strategy strikes a better balance between potency and resistance barrier. The second gap my thesis addresses is elucidating the structural basis by which highly potent protease inhibitors function in genotype 1 but not in genotype 3, despite having an 87% sequence similarity. After mapping the amino acids responsible for this differential efficacy in genotypes 1 and 3, I engineered a 1a3a chimeric protease for crystallographic studies. My structural characterization of three PIs in complex with both the 1a3a and genotype 1 protease revealed that the loss of inhibitor efficacy in the 1a3a and GT-3 proteases is a consequence of disrupted electrostatic interactions between amino acids 168 and 155, which is critical for potent binding of quinoline and isoindoline based PIs. Here, I have revealed details of molecular and structural basis for the lack of PI efficacy against GT-3, which are needed for design of pan-genotypic inhibitors. Hepacivirus Viral Nonstructural Proteins Protease Inhibitors Hepatitis C Drug Resistance Dissertations, UMMS Biochemistry Immunopathology Immunoprophylaxis and Therapy Molecular Biology Structural Biology Virology Virus Diseases
206	Optimizing RNA Library Preparation to Redefine the Translational Status of 80S Monosomes: A Dissertation Heyer, Erin E. 06 October 2015 (has links) Deep sequencing of strand-specific cDNA libraries is now a ubiquitous tool for identifying and quantifying RNAs in diverse sample types. The accuracy of conclusions drawn from these analyses depends on precise and quantitative conversion of the RNA sample into a DNA library suitable for sequencing. Here, we describe an optimized method of preparing strand-specific RNA deep sequencing libraries from small RNAs and variably sized RNA fragments obtained from ribonucleoprotein particle footprinting experiments or fragmentation of long RNAs. Because all enzymatic reactions were optimized and driven to apparent completion, sequence diversity and species abundance in the input sample are well preserved. This optimized method was used in an adapted ribosome-profiling approach to sequence mRNA footprints protected either by 80S monosomes or polysomes in S. cerevisiae. Contrary to popular belief, we show that 80S monosomes are translationally active as demonstrated by strong three-nucleotide phasing of monosome footprints across open reading frames. Most mRNAs exhibit some degree of monosome occupancy, with monosomes predominating on upstream ORFs, canonical ORFs shorter than ~590 nucleotides and any ORF for which the total time required to complete elongation is substantially shorter than the time required for initiation. Additionally, endogenous NMD targets tend to be monosome-enriched. Thus, rather than being inactive, 80S monosomes are significant contributors to overall cellular translation. High-Throughput Nucleotide Sequencing Nucleotides RNA Gene Library Open Reading Frames Dissertations, UMMS Biochemistry Bioinformatics Cell Biology Computational Biology Genetics Molecular Biology Molecular Genetics
207	The Identification and Targeting of Partially-Folded Conformations on the Folding Free-Energy Landscapes of ALS-Linked Proteins for Therapeutic Intervention: A Dissertation Mackness, Brian C 07 April 2016 (has links) The hallmark feature of many neurodegenerative diseases, including amyotrophic lateral sclerosis (ALS), is the accumulation of cytoplasmic inclusions of key disease-linked proteins. Two of these proteins, TDP-43 and SOD1, represent a significant proportion of sporadic and familial ALS cases, respectively. The population of potentially aggregation-prone partially-folded states on the folding free-energy landscape may serve as a common mechanism for ALS pathogenesis. A detailed biophysical understanding of the folding and misfolding energy landscapes of TDP-43 and SOD1 can provide critical insights into the design of novel therapeutics to delay onset and progression in ALS. Equilibrium unfolding studies on the RNA recognition motif (RRM) domains of TDP-43 revealed the population of a stable RRM intermediate in RRM2, with residual structure localized to the N-terminal half of the domain. Other RRM domains from FUS/TLS and hnRNP A1 similarly populate RRM intermediates, suggesting a possible connection with disease. Mutations, which enhance the population of the RRM2 intermediate, could serve as tools for deciphering the functional and misfolding roles of this partially-folded state in disease models, leading to the development of new biomarkers to track ALS progression. ALS mutations in SOD1 have been shown to destabilize the stable homodimer to result in increased populations of the monomeric and unfolded forms of SOD1. Mechanistic insights into the misfolding of SOD1 demonstrated that the unfolded state is a key species in the initiation and propagation of aggregation, suggesting that limiting these populations may provide therapeutic benefit to ALS patients. An in vitro time-resolved Förster Resonance Energy Transfer assay to screen small molecules that stabilize the native state of SOD1 has identified several lead compounds, providing a pathway to new therapeutics to treat ALS. Amyotrophic Lateral Sclerosis Mutation DNA-Binding Proteins Superoxide Dismutase Proteostasis Deficiencies Protein Folding; Protein Conformation Dissertations, UMMS Protein Folding Protein Conformation Biochemistry Nervous System Diseases Structural Biology
208	Small RNA Regulation of the Innate Immune Response: A Role for Dicer in the Control of Viral Production and Sensing of Nucleic Acids: A Dissertation Nistler, Ryan J. 09 December 2015 (has links) All organisms exist in some sort of symbiosis with their environment. The food we eat, air we breathe, and things we touch all have their own microbiota and we interact with these microbiota on a daily basis. As such, we employ a method of compartmentalization in order to keep foreign entities outside of the protected internal environments of the body. However, as other organisms seek to replicate themselves, they may invade our sterile compartments in order to do so. To protect ourselves from unfettered replication of pathogens or from cellular damage, we have developed a series of receptors and signaling pathways that detect foreign bodies as well as abnormal signals from our own perturbed cells. The downstream effector molecules that these signaling pathways initiate can be toxic and damaging to both pathogen and host, so special care is given to the regulation of these systems. One method of regulation is the production of endogenous small ribonucleic acids that can regulate the expression of various receptors and adaptors in the immune signaling pathways. In this dissertation, I present work that establishes an important protein in small ribonucleic acid regulation, Dicer, as an essential protein for regulating the innate immune response to immuno-stimulatory nucleic acids as well as regulating the productive infection of encephalomyocarditis virus. Depleting Dicer from murine embryonic fibroblasts renders a disparate type I interferon response where nucleic acid stimulation in the Dicer null cells fails to produce an appreciable interferon response while infection with the paramyxovirus, Sendai, induces a more robust interferon response than the wild-type control. Additionally, I show that Dicer plays a vital role in controlling infection by the picornavirus, encephalomyocarditis virus. Encephalomyocarditis virus fails to grow efficiently in Dicer null cells due to the inability for the virus to bind to the outside of the cell, suggesting that Dicer has a role in modulating viral infection by affecting host cellular protein levels. Together, this work identifies Dicer as a key protein in viral innate immunology by regulating both the growth of virus and also the immune response generated by exposure to pathogen associated molecular patterns. Understanding this regulation will be vital for future development of small molecule therapeutics that can either modulate the innate immune response or directly affect viral growth. innate immunity Dicer small nuclear RNA viruses Dissertations, UMMS Immunity, Innate Ribonuclease III DEAD-box RNA Helicases Encephalomyocarditis virus Immunity Immunology of Infectious Disease Virology
209	Memory CD8+ T Cell Function during Mycobacterium Tuberculosis Infection: A Dissertation Carpenter, Stephen M. 30 June 2016 (has links) T cell vaccines against Mycobacterium tuberculosis (Mtb) and other pathogens are based on the principle that memory T cells rapidly generate effector responses upon challenge, leading to pathogen clearance. Despite eliciting a robust memory CD8+ T cell response to the immunodominant Mtb antigen TB10.4 (EsxH), we find the increased frequency of TB10.4-specific CD8+ T cells conferred by vaccination to be short-lived after Mtb challenge. To compare memory and naïve CD8+ T cell function during their response to Mtb, we track their expansions using TB10.4-specific retrogenic CD8+ T cells. We find that the primary (naïve) response outnumbers the secondary (memory) response during Mtb challenge, an effect moderated by increased TCR affinity. To determine whether the expansion of polyclonal memory T cells is restrained following Mtb challenge, we used TCRb deep sequencing to track TB10.4-specific CD8+ T cells after vaccination and subsequent challenge in intact mice. Successful memory T cells, defined by their clonal expansion after Mtb challenge, express similar CDR3b sequences suggesting TCR selection by antigen. Thus, both TCR-dependent and independent factors affect the fitness of memory CD8+ responses. The impaired expansion of the majority of memory T cell clonotypes may explain why some TB vaccines have not provided better protection. Tuberculosis Mycobacterium tuberculosis CD8-Positive T-Lymphocytes T-Lymphocytes Vaccination Vaccines Dissertations, UMMS Bacterial Infections and Mycoses Bacteriology Immunology of Infectious Disease Immunoprophylaxis and Therapy Pathogenic Microbiology
210	Characterizing the Disorder in Tristetraprolin and its Contribution to Post-Transcriptional Gene Regulation: A Dissertation Deveau, Laura M. 05 May 2016 (has links) RNA-binding proteins (RBPs) are important for a wide variety of biological processes involved in gene regulation. However, the structural and dynamic contributions to their biological activity are poorly understood. The tristetraprolin (TTP) family of RBPs, including TTP, TIS11b and TIS11d, regulate the stability of mRNA transcripts encoding for key cancer-related proteins, such as tumor necrosis factor- and vascular endothelial growth factor. Biophysical studies have shown that the RNA binding domain, consisting of two CCCH zinc fingers (ZFs), is folded in the absence of RNA in TIS11d and TIS11b. In TTP, however, only ZF1 adopts a stable fold, while RNA is required to completely fold the tandem zinc finger (TZF). The focus of this research was to understand the origin and biological significance of the structural differences observed for the TZF domains of TTP and TIS11d. Three residues were shown to control the affinity for the structural Zn2+ and determine the folding of ZF2 in the absence of RNA. The partially-folded TZF domain of TTP has greater selectivity for RNA sequences than the fully folded TZF domain of TIS11d. The mRNA destabilizing activity of TTP was increased when the partially disordered RBD of TTP was replaced with the fully structured TZF domain of TIS11d. Disruption of the structure and/or dynamics of the TZF domain observed in the disease-associated mutations of TIS11d, P190L and D219E, results in aberrant cytoplasmic localization. This work demonstrates that the extent of RBD folding in the TTP family is important for differential RNA recognition, mRNA turnover, and protein localization in vivo. RNA-Binding Proteins Tristetraprolin Zinc Fingers Messenger RNA Post-Transcriptional Gene Regulation Dissertations, UMMS RNA, Messenger Amino Acids, Peptides, and Proteins Biochemistry Biophysics Molecular Biology Structural Biology

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