Global ETD Search

61	TAK1-Mediated Post-Translational Modifications Modulate Immune Response: A Dissertation Chen, Li 15 May 2015 (has links) Innate immunity is the first line of defense against invading pathogens. It provides immediate protection by initiating both cellular and humoral immune reactions in response to a wide range of infections. It is also important to the development of long-lasting and pathogen-specific adaptive immunity. Thus, studying of the innate immunity, especially the pathogen recognition and signaling modulation, is crucial for understanding the intrinsic mechanisms underlying the host defense, as well as contributing the development of the fight against infectious diseases. Drosophila is an ideal model organism for study of innate immunity. Comparing to mammals, Drosophila immunity is relative conserved and less redundant. A variety of molecular and genetic tools available add further convenience to the research in this system. My work is focused on the signaling modulation by post-translational modification after activation. In these studies I demonstrated in the center of Imd pathway, the Imd protein undergoes proteolytic cleavage, K63-polyubiquitination, phosphorylation, K63-deubiquitination and K48-polyubiquitination/degradation in a stimulation-dependent manner. These modifications of Imd play a crucial role in regulating signaling in response to infection. The characterization of ubiquitin-editing event provides a new insight into the molecular mechanisms underlying the activation and termination of insect immune signaling pathway. Drosophila Drosophila Proteins Innate Immunity Post-Translational Protein Processing Proteolysis Signal Transduction Ubiquitin Dissertations, UMMS Immunity, Innate Protein Processing, Post-Translational Biochemistry Immunity
62	Transcriptional Regulation of the Drosophila Peptidoglycan Sensor PGRP-LC by the Steroid Hormone Ecdysone: A Masters Thesis Tong, Mei 05 September 2015 (has links) Drosophila is host to the steroid hormone ecdysone, which regulates development and immune functions using a common group of transcription factors. Developmentally-induced ecdysone pulses activate the expression of the EcR, BR-C, HR46, Eip74EF, Eip75B, Eip78C, and Eip93F, which assume control of hundreds of other genes involved in the transition from larva to pupa stage. Many of the transcription factors are related to mammalian nuclear hormone receptors by homology. In addition to these transcription factors, the ecdysoneregulated GATA factors SRP and PNR are required for the proper expression of the peptidoglycan sensor PGRP-LC, which belongs to a conserved class of proteins in innate immunity. Although the transcriptional network has been elucidated in development, it is unclear why ecdysone control of PGRP-LC gene activity involves these nine transcription factors and how ecdysone is regulated in the context of an infection in vivo. An ecdysone-activated enhancer was located upstream of the PGRP-LC locus using a reporter plasmid. Female flies that lacked the enhancer had reduced PGRP-LC expression, but survived infection. Male flies did not experience these changes. Therefore, PGRP-LC enhancer appears to be a female-specific cis-regulatory element. The lack of survival phenotype could be caused by using an improper injection site. Bioinformatics software was used to identify putative individual and overlapping binding sites for some transcription factors. Site-directed mutations of the motifs reduced PGRP-LC promoter activity without abolishing the signal. These results suggest that the transcription factors assemble at multiple locations on the PGRP-LC enhancer and form strong protein-protein bonds. Septic injury led to elevated ecdysone in whole flies, which could be a neuroendocrine response to stress similar to the mammalian system. Steroid hormone regulation of immune receptors is a common theme in humans and flies, and these results could advance our understanding of the transcriptional regulation of related genes and gender differences observed in innate immune responses at the transcriptional level. Ecdysone Peptidoglycan Carrier Proteins Drosophila Drosophila Proteins Gene Expression Regulation Transcription Factors Innate Immunity Theses, UMMS Immunity, Innate Bioinformatics Genetics Immunity
63	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
64	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
65	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
66	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
67	Mitotic Response to DNA Damage in Early Drosophila Embroyos: a Dissertation Kwak, Seongae 30 April 2008 (has links) DNA damage induces mitotic exit delays through a process that requires the spindle assembly checkpoint (SAC), which blocks the metaphase to anaphase transition in the presence of unaligned chromosomes. Using time-lapse confocal microscopy in syncytial Drosophila embryos, we show that DNA damage leads to arrest during prometaphase and anaphase. In addition, functional GFP fusions to the SAC components MAD2 and Mps1, and the SAC target Cdc20 relocalize to kinetochore through anaphase arrest, and a null mad2mutation blocks damage induced prometaphase and anaphase arrest. We also show that the DNA damage signaling kinase Chk2 is required for damage induced metaphase and anaphase arrest, and that a functional GFP-Chk2 fusion localizes to kinetochores and centrosomes through mitosis. In addition, in the absence of Chk2, we find that DNA damage sufficient to fragment centromere DNA does not delay mitotic exit. We conclude that DNA damage signaling through Chk2 triggers Mad2-dependent delays in mitotic progression, both before or after the metaphase-anaphase transition. DNA Damage Mitosis Mitotic Spindle Apparatus Drosophila melanogaster Cell Cycle Proteins Drosophila Proteins Amino Acids, Peptides, and Proteins Animal Experimentation and Research Cells Embryonic Structures Genetic Phenomena Investigative Techniques
68	Identification of a Command Neuron Directing the Expression of Feeding Behavior in <em>Drosophila melanogaster</em>: A Dissertation Flood, Thomas F. 12 May 2011 (has links) Feeding is one of the most important behaviors for an animal’s survival. At a gross level, it is known that the nervous system plays a major role in the expression of this complex behavior, yet a detailed understanding of the neural circuits directing feeding behavior remains unknown. Here we identify a command neuron in Drosophila melanogaster whose artificial activation, using dTrpA1, a heat-activated cation channel, induces the appearance of complete feeding behavior. We use behavioral, genetic, cellular and optical imaging techniques to show that the induced behavior is composed of multiple motor programs and can function to uptake exogenous, even noxious, material. Furthermore, we resolve the neuron’s location to the subesophageal ganglion, characterize its pre and post-synaptic sites, and determine its responsiveness to sucrose stimulation. Interestingly, the neuron’s dendritic field is proximal to sweet sensing axon terminals and its baseline activity corresponds to the fly’s satiation state, suggesting a potential point of integration between sensory, motor and motivational systems. The identification of a command neuron for feeding in a genetically tractable organism provides a useful model to develop a deeper understanding of the neural control of this ubiquitous and evolutionarily ancient behavior. feeding neuron activity Drosophila melanogaster Feeding Behavior Neurons Drosophila Proteins TRPC Cation Channels Amino Acids, Peptides, and Proteins Animal Experimentation and Research Behavioral Neurobiology Nervous System Neuroscience and Neurobiology
69	Role of Glia in Sculpting Synaptic Connections at the Drosophila Neuromuscular Junction: A Dissertation Fuentes Medel, Yuly F. 27 January 2012 (has links) Emerging evidence in both vertebrates and invertebrates is redefining glia as active players in the development and integrity of the nervous system. The formation of functional neuronal circuits requires the precise addition of new synapses. Mounting evidence implicates glial function in synapse remodeling and formation. However, the precise molecular mechanisms governing these functions are poorly understood. My thesis work begins to define the molecular mechanisms by which glia communicate with neurons at the Drosophila neuromuscular junction (NMJ). During development glia play a critical role in remodeling neuronal circuits in the CNS. In order to understand how glia remodel synapses, I manipulated a key component of the glial engulfment machinery, Draper. I found that during normal NMJ growth presynaptic boutons constantly shed membranes or debris. However, a loss of Draper resulted in an accumulation of debris and ghost boutons, which inhibited synaptic growth. I found that glia use the Draper pathway to engulf these excess membranes to sculpt synapses. Surprisingly, I found that muscle cells function as phagocytic cells as well by eliminating immature synaptic ghost boutons. This demonstrates that the combined efforts of glia and muscle are required for the addition of synapses and proper growth. My work establishes that glia play a crucial role in synapse development at the NMJ and suggests that there are other glial-derived molecules that regulate synapse function. I identified one glial derived molecule critical for the development of the NMJ, a TGF-β ligand called Maverick. Presynaptically, Maverick regulates the activation of BMP pathway confirmed by reducing the transcription of the known target gene Trio. Postsynaptically, it regulates the transcription of Glass bottom boat (Gbb) in the muscle suggesting that glia modulate the function of Gbb and consequently the activation of the BMP retrograde pathway at NMJ. Surprisingly, I also found that glial Maverick regulates the transcription of Shaker potassium channel, suggesting that glia potentially could regulate muscle excitability and consequently modulate synaptic transmission. Future work will elucidate such hypothesis. My work has demonstrated two novel roles for glia at the NMJ. First is that glia engulfing activity is important for proper synaptic growth. Second is that the secretion of glial-derived molecules are required to orchestrate synaptic development. This further supports that glia are critical active players in maintaining a functional nervous system. Drosophila Drosophila Proteins Neuroglia Neuromuscular Junction Presynaptic Terminals Synapses Synaptic Transmission Amino Acids, Peptides, and Proteins Animal Experimentation and Research Cells Nervous System Neuroscience and Neurobiology
70	The role of integrin-dependent cell matrix adhesion in muscle development / Jani, Klodiana. January 2009 (has links) No description available. Cell adhesion. Integrins -- Metabolism. Striated muscle -- Metabolism. Integrins -- metabolism. Carrier Proteins -- metabolism. Drosophila Proteins -- metabolism. Cell Adhesion -- physiology. Muscle, Skeletal -- metabolism.

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