Global ETD Search

251	Caspase Mediated Cleavage, IAP Binding, Ubiquitination and Kinase Activation : Defining the Molecular Mechanisms Required for <em>Drosophila</em> NF-кB Signaling: A Dissertation Paquette, Nicholas Paul 03 November 2009 (has links) Innate immunity is the first line of defense against invading pathogens. Vertebrate innate immunity provides both initial protection, and activates adaptive immune responses, including memory. As a result, the study of innate immune signaling is crucial for understanding the interactions between host and pathogen. Unlike mammals, the insect Drosophila melanogasterlack classical adaptive immunity, relying on innate immune signaling via the Toll and IMD pathways to detect and respond to invading pathogens. Once activated these pathways lead to the rapid and robust production of a variety of antimicrobial peptides. These peptides are secreted directly into the hemolymph and assist in clearance of the infection. The genetic and molecular tools available in the Drosophila system make it an excellent model system for studying immunity. Furthermore, the innate immune signaling pathways used by Drosophilashow strong homology to those of vertebrates making them ideal for the study of activation, regulation and mechanism. Currently a number of questions remain regarding the activation and regulation of both vertebrate and insect innate immune signaling. Over the past years many proteins have been implicated in mammalian and insect innate immune signaling pathways, however the mechanisms by which these proteins function remain largely undetermined. My work has focused on understanding the molecular mechanisms of innate immune activation in Drosophila. In these studies I have identified a number of novel protein/protein interactions which are vital for the activation and regulation of innate immune induction. This work shows that upon stimulation the Drosophila protein IMD is cleaved by the caspase-8 homologue DREDD. Cleaved IMD then binds the E3 ligase DIAP2 and promotes the K63-polyubiquitination of IMD and activation of downstream signaling. Furthermore the Yersinia pestis effector protein YopJ is able to inhibit the critical IMD pathway MAP3 kinase TAK1 by serine/threonine-acetylation of its activation loop. Lastly TAK1 signaling to the downstream Relish/NF-κB and JNK signaling pathways can be regulated by two isoforms of the TAB2 protein. This work elucidates the molecular mechanism of the IMD signaling pathway and suggests possible mechanisms of homologous mammalian systems, of which the molecular details remain unclear. Immunity Innate I-kappa B Kinase Drosophila Proteins Bacterial Proteins Yersinia pestis Amino Acids, Peptides, and Proteins Animal Experimentation and Research Bacteria Enzymes and Coenzymes Hemic and Immune Systems
252	Evasion of LPS-TLR4 Signaling as a Virulence Determinate for <em>Yersinia pestis</em> Paquette, Sara Montminy 18 December 2009 (has links) Yersinia pestis, the gram-negative causative agent of plague, is a master of immune evasion. The bacterium possesses a type three secretion system which translocates Yop effector proteins into host immune cells to inhibit a number of immune and cell signaling cascades. Interestingly, this apparatus is not expressed at low temperatures such as those found within the flea vector and is therefore neither in place nor functional when the bacteria are first transmitted into a mammalian host. However, the bacterium is still able to avoid activating the immune system, even very early during infection. When grown at 37°C (human body temperature) Y. pestis produces a tetra-acyl lipid A molecule, which is antagonistic to the human Toll like receptor 4/MD2, the major lipopolysaccharide recognition receptor. Although tetra-acyl lipid A binds this receptor complex, it does not induce signaling, and in fact inhibits the receptors interaction with other stimulatory forms of lipid A. The work undertaken in this thesis seeks to determine if the production of tetra-acyl lipid A by Y. pestis is a key virulence determinant and was a critical factor in the evolution of Y. pestis from its ancestral parent Yersinia pseudotuberculosis. By examining the enzymes involved in the lipid A biosynthesis pathway, it has been determined that Y. pestis lacks LpxL, a key enzyme that adds a secondary acyl chain on to the tetra acyl lipid A molecule. In the absence of this enzyme, Y. pestis cannot produce a TLR4 stimulating form of lipid A, whereas Y. pseudotuberculosis does contain the gene for LpxL and produces a stimulatory hexa acyl lipid A. To determine if the absence of LpxL in Y. pestis is important for virulence, LpxL from E. coli and Y. pseudotuberculosis were introduced into Y. pestis. In both cases the addition of LpxL led to bacterium which produced a hexa-acylated lipid A molecule and TLR4/MD2 stimulatory LPS. To verify the LpxL phenotype, lpxL was deleted from Y. pseudotuberculosis, resulting in bacteria which produce tetra-acylated lipid A and nonstimulatory LPS. Mice challenged with LpxL expressing Y. pestis were found to be completely resistant to infection. This profound attenuation in virulence is TLR4 dependent, as mice deficient for this receptor rapidly succumb to disease. These altered strains of the bacterium also act as vaccines, as mice infected with Y. pestis expressing LpxL then challenged with wild type Y. pestis do not become ill. These data demonstrate that the production of tetra-acyl lipid A is a critical virulence determinant for Y. pestis, and that the loss of LpxL formed a major step in the evolution of Y. pestis from Y. pseudotuberculosis. These bacterial strains were also used as tools to determine the contributions of different innate immune receptors and adaptor molecules to the host response during Y. pestis infection. The use of LpxL expressing Y. pestis allowed identification of the innate immune pathways critical for protection during Y. pestis infection. This model also established that CD14 recognition of rough LPS is critical for protection from Y. pestisexpressing LpxL, and activation of the IL-1 receptor and the induction of IL-1β plays a major role in this infection as well. The lipid A acylation profile of gram negative bacteria can have a direct and profound effect on the pathogenesis of the organism. This work illustrates a previously unknown and critical aspect of Y. pestis pathogenesis, which can be extended to other gram-negative pathogens. The greater detail of the contributions which different host adaptor and receptor molecules make to the overall innate immune signaling pathway will allow a better insight into how gram negative infections progress and how they are counteracted by the immune system. Alterations of the lipid A profile of Y. pestis have important implications for the production of vaccines to Y. pestis and other gram negative pathogens. Taken together, this work describes a novel mechanism for immune evasion by gram negative bacteria with consequences for understanding the immune response and the creation of more effective vaccines, both of which will decrease the danger posed by this virulent pathogen. Yersinia pestis Virulence Factors Lipid A Yersinia pseudotuberculosis Gram-Negative Bacteria Amino Acids, Peptides, and Proteins Bacteria Cells Environmental Public Health Hemic and Immune Systems Investigative Techniques Lipids Therapeutics
253	Axon Death Prevented: Wld<sup>s</sup> and Other Neuroprotective Molecules: A Dissertation Avery, Michelle A. 13 December 2010 (has links) A common feature of many neuropathies is axon degeneration. While the reasons for degeneration differ greatly, the process of degeneration itself is similar in most cases. Axon degeneration after axotomy is termed ‘Wallerian degeneration,’ whereby injured axons rapidly fragment and disappear after a short period of latency (Waller, 1850). Wallerian degeneration was thought to be a passive process until the discovery of the Wallerian degeneration slow (Wlds) mouse mutant. In these mice, axons survive and function for weeks after nerve transection. Furthermore, when the full-length protein is inserted into mouse models of disease with an axon degeneration phenotype (such as progressive motor neuronopathy), Wlds is able to delay disease onset (for a review, see Coleman, 2005). Wlds has been cloned and was found to be a fusion event of two neighboring genes: Ube4b, which encodes an ubiquitinating enzyme, and NMNAT-1 (nicotinamide mononucleotide adenylyltransferase-1), which encodes a key factor in NAD (nicotinamide adenine dinucleotide) biosynthesis, joined by a 54 nucleotide linker span (Mack et al., 2001). To address the role of Wlds domains in axon protection and to characterize the subcellular localization of Wlds in neurons, our lab developed a novel method to study Wallerian degeneration in Drosophila in vivo (MacDonald et al., 2006). Using this method, we have discovered that mouse Wlds can also protect Drosophila axons for weeks after acute injury, indicating that the molecular mechanisms of Wallerian degeneration are well conserved between mouse and Drosophila. This observation allows us to use an easily manipulated genetic model to move the Wlds field forward; we can readily identify what Wlds domains give the greatest protection after injury and where in the neuron protection occurs. In chapter two of this thesis, I identify the minimal domains of Wlds that are needed for protection of severed Drosophila axons: the first 16 amino acids of Ube4b fused to Nmnat1. Although Nmnat1 and Wlds are nuclear proteins, we find evidence of a non-nuclear role in axonal protection in that a mitochondrial protein, Nmnat3, protects axons as well as Wlds. In chapter 3, I further explore a role for mitochondria in Wlds-mediated severed axon protection and find the first cell biological changes seen in a Wlds-expressing neuron. The mitochondria of Wlds- and Nmnat3-expressing neurons are more motile before injury. We find this motility is necessary for protection as suppressing the motility with miro heterozygous alleles suppresses Wldsmediated axon protection. We also find that Wlds- and Nmnat3- expressing neurons show a decrease in calcium fluorescent reporter, gCaMP3, signal after axotomy. We propose a model whereby Wlds, through production of NAD in the mitochondria, leads to an increase in calcium buffering capacity, which would decrease the amount of calcium in the cytosol, allowing for more motile mitochondria. In the case of injury, the high calcium signal is buffered more quickly and so cannot signal for the axon to die. Finally, in chapter 4 of my thesis, I identify a gene in an EMS-based forward genetic screen which can suppress Wallerian degeneration. This mutant is a loss of function, which, for the first time, definitively demonstrates that Wallerian degeneration is an active process. The mammalian homologue of the gene encodes a mitochondrial protein, which in light of the rest of the work in this thesis, highlights the importance of mitochondria in neuronal health and disease. In conclusion, the work presented in this thesis highlights a role for mitochondria in both Wlds-mediated axon protection and Wallerian degeneration itself. I identified the first cell biological changes seen in Wlds-expressing neurons and show that at least one of these is necessary for its protection of severed axons. I also helped find the first Wallerian degeneration loss-of-function mutant, showing Wallerian degeneration is an active process, mediated by a molecularly distinct axonal degeneration pathway. The future of the axon degeneration field should focus on the mitochondria as a potential therapeutic target. Nerve Tissue Proteins Neuroprotective Agents Axons Wallerian Degeneration Mitochondria Drosophila Drosophila Proteins Amino Acids, Peptides, and Proteins Animal Experimentation and Research Nervous System Neuroscience and Neurobiology
254	On the Source of Peptides for Major Histocompatibility Class I Antigen Presentation: A Dissertation Farfán Arribas, Diego José 04 April 2012 (has links) Peptides generated from cellular protein degradation via the ubiquitin-proteasome pathway are presented on MHC class I as a means for the immune system to monitor polypeptides being synthesized by cells. For CD8 + T cells to prevent the spread of an incipient infection, it appears essential they should be able to sense foreign polypeptides being synthesized as soon as possible. A prompt detection of viral proteins is of great importance for the success of an adaptive immune response. Defective ribosomal products (DRiPs) have been postulated as a preferential source which would allow for a rapid presentation of peptides derived from the degradation of all newly synthesized proteins. Although this hypothesis is intellectually appealing there is lack of experimental data supporting a mechanism that would prioritize presentation from DRiPs. In this dissertation I describe a series of experiments that probe the DRiPs hypothesis by assessing the contribution to class I presentation of model epitopes derived from DRiPs or from functional proteins. The results show that even at the early stages after mRNA synthesis DRiPs do not account for a significant fraction of the class I presented peptides. These observations suggest that the currently widespread model whereby a mechanism exists which selectively allows for DRiPs to preferentially contribute to class I antigen presentation, is incorrect. Rather, properly folded functional proteins can significantly contribute to class I antigen presentation as they are normally turned over by the ubiquitin-proteasome pathway. Histocompatibility Antigens Class I Antigen Presentation CD8-Positive T-Lymphocytes Ribosomes Amino Acids, Peptides, and Proteins Biological Factors Cells Hemic and Immune Systems Immunology and Infectious Disease
255	Molecular Mechanisms of Endocytosis: Trafficking and Functional Requirements for the Transferrin Receptor, Small Interfering RNAs and Dopamine Transporter: A Dissertation Navaroli, Deanna M. 30 April 2012 (has links) Endocytosis is an essential function of eukaryotic cells, providing crucial nutrients and playing key roles in interactions of the plasma membrane with the environment. The classical view of the endocytic pathway, where vesicles from the plasma membrane fuse with a homogenous population of early endosomes from which cargo is sorted, has recently been challenged by the finding of multiple subpopulations of endosomes. These subpopulations vary in their content of phosphatidylinositol 3- phosphate (PI3P) and Rab binding proteins. The role of these endosomal subpopulations is unclear, as is the role of multiple PI3P effectors, which are ubiquitously expressed and highly conserved. One possibility is that the different subpopulations represent stages in the maturation of the endocytic pathway. Alternatively, endosome subpopulations may be specialized for different functions, such as preferential trafficking of specific endocytosed cargo. To determine whether specific receptors are targeted to distinct populations of endosomes, we have built a platform for total internal reflection fluorescence (TIRF) microscopy coupled with structured illumination capabilities named TESM (TIRF Epifluorescence Structured light Microscope.) In this study, TESM, along with standard biochemical and molecular biological tools, was used to analyze the dynamic distribution of two highly conserved Rab5 and PI3P effectors, EEA1 and Rabenosyn-5, and systematically study the trafficking of transferrin. Rabenosyn-5 is necessary for proper expression of the transferrin receptor as well as internalization and recycling of transferrin-transferrin receptor complexes. Results of combining TIRF with structured light Epifluorescence (SLE) indicate that the endogenous populations of EEA1 and Rabenoysn-5 are both distinct and partially overlapping. The application of antisense oligonucleotides as potential therapeutic agents requires effective methods for their delivery to the cytoplasm of target cells. In collaboration with RXi Pharmaceuticals we show the efficient cellular uptake of the antisense oligonucleotide sd-rxRNA® in the absence of delivery vehicle or protein carrier. In this study TIRF, SLE, and biochemical approaches were utilized to determine whether sd-rxRNA traffics and functions along specific endosomal pathways. Sd-rxRNA was found to traffic along the degradative pathway and require EEA1 to functionally silence its target. These new findings will help define the cellular pathways involved in RNA silencing. Neurotransmitter reuptake and reuse by neurotransmitter transport proteins is fundamental to transmitter homeostasis and synaptic signaling. In order to understand how trafficking regulates transporters in the brain and how this system may be disregulated in monoamine-related pathologies, the transporter internalization signals and their molecular partners must be defined. We utilized a yeast two-hybrid system to identify proteins that interact with the dopamine transporter (DAT) endocytic signal. The small, membrane associated, GTPase Rin was determined to specifically and functionally interact with the DAT endocytic signal, regulating constitutive and protein kinase C (PKC) – stimulated DAT endocytosis. The results presented in this study provide new insights into functions and components of endocytosis and enhance the understanding of endocytic organization. Endocytosis Receptors Transferrin RNA Small Interfering Amino Acids, Peptides, and Proteins Cells Cellular and Molecular Physiology Neuroscience and Neurobiology Organic Chemicals
256	Runx1 C-terminal Domains During Hematopoietic Development and Leukemogenesis: A Dissertation Dowdy, Christopher R. 25 May 2012 (has links) Runx1 is a master regulator of hematopoiesis, required for the initiation of definitive hematopoiesis in the embryo and essential for appropriate differentiation of many hematopoietic lineages in the adult. The roles of Runx1 in normal hematopoiesis are juxtaposed with the high frequency of Runx1 mutations and translocations in leukemia. Leukemia associated Runx1 mutations that retain DNA-binding ability have truncations or frame shifts that lose C-terminal domains. These domains are important for subnuclear localization of Runx1 and protein interactions with co-factors. The majority of leukemia associated Runx1 translocations also replace the C-terminus of Runx1 with chimeric fusion proteins. The common loss of Runx1 C-terminal domains in hematopoietic diseases suggests a possible common mechanism. We developed a panel of mutations to test the functions of these domains in vitro, and then developed mouse models to examine the consequences of losing Runx1 C-terminal domains on hematopoietic development and leukemogenesis in vivo. We previously observed that overexpression of a subnuclear targeting defective mutant of Runx1 in a myeloid progenitor cell line blocks differentiation. Gene expression analysis before differentiation was initiated revealed that the mutant Runx1 was already deregulating genes important for maturation. Furthermore, promoters of the suppressed genes were enriched for binding sites of known Runx1 co-factors, indicating a non-DNA-binding role for the mutant Runx1. To investigate the in vivo function of Runx1 C-terminal domains, we generated two knock-in mouse models; a C-terminal truncation, Runx1Q307X, and a point mutant in the subnuclear targeting domain, Runx1 HTY350-352AAA . Embryos homozygous for Runx1 Q307X phenocopy a complete Runx1 null and die in utero from central nervous system hemorrhage and lack of definitive hematopoiesis. Embryos homozygous for the point mutation Runx1HTY350-352AAA bypass embryonic lethality, but have hypomorphic Runx1 function. Runx1HTY350-352AAA results in defective growth control of hematopoietic progenitors, deregulation of B-lymphoid and myeloid lineages, as well as maturation delays in megakaryocytic and erythroid development. Runx1 localizes to subnuclear domains to scaffold regulatory machinery for control of gene expression. This work supports the role of transcription factors interacting with nuclear architecture for greater biological control, and shows how even subtle alterations in that ability could have profound effects on normal biological function and gene regulation. Hematopoiesis Core Binding Factor Alpha 2 Subunit Leukemia Amino Acids, Peptides, and Proteins Cell and Developmental Biology Cells Circulatory and Respiratory Physiology Genetic Phenomena Neoplasms
257	M.tb Killing by Macrophage Innate Immune Mechanisms: A Dissertation Hartman, Michelle L 07 September 2011 (has links) Macrophages infected with a heavy burden of M.tb Erdman undergo a cell death that initially resembles apoptosis but quickly transitions to necrosis. Unlike the previously reported TNF dependent apoptosis induced by avirulent Mycobacterium [1], this form of macrophage cell death is not microbicidal [2]. Microbicidal effects are observed however, when the heavily infected macrophage encounters an uninfected naïve macrophage. My studies describe in part, the crosstalk between the uninfected and infected macrophage that results in the killing of the intracellular M.tb Cell contact between the two cell populations is not necessary for this killing of bacilli to occur and the soluble “signal” of communication between the two cell populations is transferrable, without naïve macrophages present, to newly infected cells also resulting in the reduced viability of the bacilli. We have found that when the IL-1 receptor is absent in the naïve macrophage population that the co-culture antimycobacterial effect is abrogated, suggesting that IL-1 released by the infected dying macrophage is critical for naïve macrophages to respond in a way that results in the decrease in mycobacterial viability. The signaling between the two cell population ultimately converges on activation of iNOS in the infected cell however ROS appears not to be involved. Mycobacterium tuberculosis Immunity Innate Macrophages Interleukin-1 Amino Acids, Peptides, and Proteins Bacteria Bacterial Infections and Mycoses Biological Factors Cells Hemic and Immune Systems Immunology and Infectious Disease Microbiology
258	Transposition Driven Genomic Heterogeneity in the <em>Drosophila</em> Brain: A Dissertation Perrat, Paola N. 01 June 2012 (has links) In the Drosophila brain, memories are processed and stored in two mirrorsymmetrical structures composed of approximately 5,000 neurons called Mushroom Bodies (MB). Depending on their axonal extensions, neurons in the MB can be further classified into three different subgroups: αβ, α’β’ and γ. In addition to the morphological differences between these groups of neurons, there is evidence of functional differences too. For example, it has been previously shown that while neurotransmission from α’β’ neurons is required for consolidation of olfactory memory, output from αβ neurons is required for its later retrieval. To gain insight into the functional properties of these discrete neurons we analyzed whether they were different at the level of gene expression. We generated an intersectional genetic approach to exclusively label each population of neurons and permit their purification. Comparing expression profiles, revealed a large number of potentially interesting molecular differences between the populations. We focused on the finding that the MB αβ neurons, which are the presumed storage site for transcription-dependent long-term memory, express high levels of mRNA for transposable elements and histones suggesting that these neurons likely possess unique genomic characteristics. For decades, transposable elements (TE) were considered to be merely “selfish” DNA elements inserted at random in the genome and that they their sole function was to self-replicate. However, new studies have started to arise that indicate TE contribute more than just “junk” DNA to the genome. Although it is widely believed that mobilization of TE destabilize the genome by insertional mutagenesis, deletions and rearrangements of genes, some rearrangements might be advantageous for the organism. TE mobilization has recently been documented to occur in some somatic cells, including in neuronal precursor cells (NPCs). Moreover, mobilization in NPCs seems to favor insertions within neuronal expressed genes and in one case the insertion elevated the expression. During the last decade, the discovery of the small RNA pathways that suppress the expression and mobilization of TE throughout the animal have helped to uncover new functions that TE play. In this work, we demonstrate that proteins of the PIWI-associated RNA pathway that control TE expression in the germline are also required to suppress TE expression in the adult fly brain. Moreover, we find that they are differentially expressed in subsets of MB neurons, being under represented in the αβ neurons. This finding suggests that the αβ neurons tolerate TE mobilization. Lastly, we demonstrate by sequencing αβ neuron DNA that TE are mobile and we identify >200 de novo insertions into neurally expressed genes. We conclude that this TE generated mosaicism, likely contributes a new level of neuronal diversity making, in theory, each αβ neuron genetically different. In principle the stochastic nature of this process could also render every fly an individual. Drosophila neurons Mushroom Bodies Drosophila Proteins Amino Acids, Peptides, and Proteins Animal Experimentation and Research Genetic Phenomena Genetics and Genomics Nervous System Neuroscience and Neurobiology
259	Innate Signaling Pathways in the Maintenance of Serological Memory: A Dissertation Raval, Forum M. 21 June 2012 (has links) Long-term antiviral antibody responses provide protection from re-infection and recurrence of persistent viruses. Using a polyomavirus (PyV) mouse model, our lab has shown that MyD88-deficient mice generate low levels of virus-specific IgG after the acute phase of infection and that these IgG responses have a skewed isotype distribution with low levels of IgG2a/c. Moreover MyD88-deficient mice have reduced numbers of long-lived plasma cells in the bone marrow. These studies suggest an important role of MyD88-mediated signaling in long-term antiviral responses. Our lab has shown that T cell-deficient mice can also maintain long-term virus-specific IgG responses following PyV infection. The goal of this thesis is to evaluate the role of innate signaling pathways in maintaining serological memory to persistent virus infection and to elaborate on how long-term antiviral responses can be maintained in an immunocompetent or partially immune compromised, T cell-deficient host. Regarding T cell-dependent B cell responses, I set out to investigate the upstream and downstream components of the MyD88-mediated pathways required for normal antibody isotype and long-term humoral responses. IgG2a is a predominant immunoglobulin isotype in most virus infections. Wild type mice, in response to PyV infection, primarily induce antiviral IgG2a with some IgG1. MyD88-deficient mice in response to PyV infection display attenuated levels of virus-specific IgG2a, but normal levels of IgG1. Using Unc93B1 mutant mice (3d mice), which are defective in TLRs 3, 7 and 9 signaling, I show that 3d mice also generated low levels of virus-specific IgG2a following PyV infection. Studies in individual TLR3-/-, TLR7-/- or TLR9-/- mice displayed PyV-specific IgG2a responses similar to wild type responses. TLR7 and TLR9 double deficient mice generated similar skewed antibody isotype responses, where virus-specific IgG2a was reduced compared to wild type mice. This shows that TLR7 and TLR9-MyD88 mediated pathways are important in regulating IgG2a responses during a PyV infection. To investigate what components downstream of MyD88 are involved in mediating IgG2a responses, I worked with IRF5-deficient mice. IRF5 is a transcription factor that is activated upon stimulation of TLR7 or TLR9-MyD88-mediated pathways. Moreover, IRF5-deficient mice cannot generate autoantibodies specifically of the IgG2a isotype in a mouse lupus model, suggesting that IRF5 plays an important function in mediating class switching to IgG2a. In vitro studies where IRF5-/- B cells were stimulated with TLR7 or TLR9 ligands also generated low levels of γ2a germ-line transcripts, suggesting a B cell-intrinsic role for IRF5 in regulating γ2a germ-line transcription. PyV infection of IRF5-deficient mice resulted in similar skewed isotypes as observed in MyD88-deficient and 3d mice. To investigate a B cell-intrinsic role for IRF5 in regulating IgG2a responses in vivo upon PyV infection, I transferred IRF5-/- B cells and WT T cells into RAG KO mice prior to infection and compared the responses of these mice with mice reconstituted with wild type B6 B and T cells. Diminished numbers of IgG2a+ B cells and reduced levels of virus-specific IgG in mice reconstituted with IRF5-/- B cells were seen compared to mice reconstituted with wild type B cells. Regarding the defect in long-term IgG production in MyD88-/- mice upon PyV infection, I conducted studies in IRF5-/-, 3d, single TLR3-/-, TLR7-/-, TLR9-/- and TLR7/9 double deficient mice. These studies reveal an important and redundant role for TLR7- and TLR9-MyD88 signaling in maintaining long-term anti-PyV IgG responses. To determine how MyD88 signaling affects the generation of long-lived plasma cells and memory B cells, I investigated germinal center (GC) responses in MyD88-deficient mice. A defect in GC B cell numbers is observed in MyD88-deficient mice after the acute phase of infection. The GC reaction is essential for the generation and maintenance of long-lived plasma cells and memory B cells. T follicular helper (TFH) cells are absolutely required to generate normal GC. l found reduced numbers of TFH cells in MyD88-deficient mice. Lower numbers of T FH cells suggests that poor T cell help may contribute to the diminished number of GC B cells. However, interaction with B cells is required for the formation of fully differentiated TFH cells. Along with B cell function, MyD88 signaling can affect T cell and dendritic cell function as well. Thus, it is not clear at this point whether the requirement for intact MyD88 signaling for the formation and maintenance of long-term B cell populations is completely B cell-intrinsic. Some viruses can induce T cell-independent B cell responses, perhaps due to their complex arrays of repetitive antigenic epitopes on virions, coupled with the induction of innate cytokines. Nevertheless, T cell help is usually necessary for generating long-term antibody responses in the form of long-lived plasma cells and memory B cells. In contrast, our lab has found that T cell-deficient mice infected with PyV develop long-lasting, protective antiviral IgG responses. I questioned whether these mice could generate TI B cell memory cells or long-lived plasma cells. I show that long-lasting anti-PyV antibody in T cell-deficient mice was not due to the presence of long-lived plasma cells or memory B cell responses. TCRβδ deficient mice, which lack both CD4 and CD8 T cells, had ~10 a times higher virus load persisting in various organs. Therefore, I hypothesized that the high level of persistent PyV antigen, in completely T cell-deficient mice, may activate naïve B cell populations continuously, thereby maintaining the long-lasting IgG responses. Prior to PyV infection, T cell-deficient mice received wild type CD8 T cells, which reduced PyV loads, and this was associated with decreased levels of antiviral serum IgG over time. As in TCRβδ deficient mice, high PyV loads were detected in the bone marrow, which is the site for B cell lymphopoiesis, I questioned how B cells develop in the presence of PyV antigen and still stay responsive to PyV, generating long-term antiviral IgG responses in the periphery. Studies have shown that self-antigens that trigger both B cell receptor signaling and TLR-MyD88 signaling pathways in the bone marrow lead to the breaking of B cell tolerance and production of autoantibody in the periphery. Thus, we hypothesized that high PyV levels in the bone marrow signal through both B cell-receptors and TLRs, allowing continuous antiviral antibody production by B cells. Using mice that are deficient in T cells and MyD88 signaling, I found that PyV-specific TI IgG levels gradually decreased, supporting this hypothesis. Thus, high PyV loads and innate signaling together can break B cell tolerance. During a persistent virus infection this can result in sustaining long-term protective T cell-independent IgG responses. Immunity Innate Serology Polyomavirus Polyomavirus Infections Immunoglobulin G Amino Acids, Peptides, and Proteins Animal Experimentation and Research Hemic and Immune Systems Immunology and Infectious Disease Virus Diseases Viruses
260	Single-Molecule Imaging Reveals that Argonaute Re-Shapes the Properties of its Nucleic Acid Guides: A Dissertation Salomon, William E. 07 December 2015 (has links) Small RNA silencing pathways regulate development, viral defense, and genomic integrity in all kingdoms of life. An Argonaute (Ago) protein, guided by a tightly bound, small RNA or DNA, lies at the core of these pathways. Argonaute uses its small RNA or DNA to find its target sequences, which it either cleaves or stably binds, acting as a binding scaffold for other proteins. We used Co-localization Single-Molecule Spectroscopy (CoSMoS) to analyze target binding and cleavage by Ago and its guide. We find that both eukaryotic and prokaryotic Argonaute proteins re-shape the fundamental properties of RNA:RNA, RNA:DNA, and DNA:DNA hybridization: a small RNA or DNA bound to Argonaute as a guide no longer follows the well-established rules by which oligonucleotides find, bind, and dissociate from complementary nucleic acid sequences. Counter to the rules of nucleic acid hybridization alone, we find that mouse AGO2 and its guide bind to microRNA targets 17,000 times tighter than the guide without Argonaute. Moreover, AGO2 can distinguish between microRNA-like targets that make seven base pairs with the guide and the products of cleavage, which bind via nine base pairs: AGO2 leaves the cleavage products faster, even though they pair more extensively. This thesis presents a detailed kinetic interrogation of microRNA and RNA interference pathways. We discovered sub-domains within the previously defined functional domains created by Argonaute and its bound DNA or RNA guide. These sub-domains have features that no longer conform to the well-established properties of unbound oligonucleotides. It is by re-writing the rules for nucleic acid hybridization that Argonautes allow oligonucleotides to serve as specificity determinants with thermodynamic and kinetic properties more typical of RNA-binding proteins than that of RNA or DNA. Taken altogether, these studies further our understanding about the biology of small RNA silencing pathways and may serve to guide future work related to all RNA-guided endonucleases. Small Interfering RNA Argonaute Proteins RNA Interference Drosophila Proteins Nucleic Acid Hybridization MicroRNAs Molecular Imaging Dissertations, UMMS RNA, Small Interfering Amino Acids, Peptides, and Proteins Biochemistry Molecular Biology

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