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41	Endoderm Patterning in Zebrafish: Pancreas Development: A Dissertation Alexa, Kristen M. 17 November 2009 (has links) The pancreas is located below the liver and adjacent to the small intestine where it connects to the duodenum. It consists of exocrine and endocrine components. The exocrine portion makes enzymes which are deposited in the duodenum to digest fats, proteins, and carbohydrates. Exocrine tissue also makes bicarbonates that neutralize stomach acids. The endocrine portion produces hormones such as insulin and glucagon which are released into the blood stream. These hormones regulate glucose transport into the body's cells and are crucial for energy production. The pancreas is associated with diseases such as cancer, diabetes, Annular pancreas and Nesidioblastosis. Annular pancreas and Nesidioblastosis are congenital malformations associated with excess endocrine tissue of the pancreas and its structures. Understanding the development of the pancreas might lead to insight of these diseases. The pancreas arises from the endoderm. In zebrafish, Nodal signaling activates mix-type and gata genes that then function together to regulate sox32 expression which is necessary and sufficient to induce endoderm formation. Interestingly, sox32 is exclusive to zebrafish and works synergistically with pou5f1 to regulate its own expression and turn on sox17 expression. sox17is evolutionarily conserved from zebrafish to mouse and is necessary for endoderm formation. Signals from within the endoderm and the surrounding mesoderm specify regions in the endoderm to develop into the pancreas and other endodermal organs. Sonic hedgehog (shh) expression in the foregut establishes the anterior boundary of the pancreas primordium while cdx4 expression establishes the posterior boundary, but what regulates these factors is unclear. We determined that two Three Amino Acid Loop Extension (TALE) homeodomain transcription cofactors, Meis3 and Pbx4, regulate shh expression in the anterior endoderm. Disrupting either meis3 or pbx4 reduces shh expression in the anterior endoderm. As a result, anterior ectopic insulin expression occurs outside the normal pancreatic domain. Therefore, we discovered upstream regulatory factors of shhexpression in the anterior endoderm, which is necessary for patterning the endoderm and pancreas primordium. We performed an ENU (N-ethyl-N-nitrosurea) haploid screen to look for endocrine pancreas mutants and to find other factors involved in pancreas development and patterning. From the screen, we characterized two mutants. We identified an aldh1a2 mutant, aldh1a2um22, which blocks the production of Retinoic Acid (RA) from vitamin A. While RA is known to be necessary for differentiation of the pancreas and liver, we also found it to be necessary for intestine differentiation. Two other aldh family genes exist in the zebrafish genome, but our data suggests that aldh1a2is the only Aldh that functions in endoderm differentiation and it is maternally deposited. From the screen, we discovered a second mutant, 835.4, that spontaneously arose within the background. pou5f1 expression is normal in mutant embryos, but sox32 expression is reduced and sox17 expression is lost. Downstream endoderm genes of sox17 are also lost and as a result no endodermal organs develop. Rescue experiments indicate that the mutation is located between sox32 and sox17 in the endoderm pathway. We currently have not been successful at mapping this mutation and therefore are unable to rule out the possibility that it lies in the sox17 gene. However, our data suggest that the mutation occurs in a new gene that is necessary for sox17 expression, potentially working with sox32 and/or pou5f1. Zebrafish Zebrafish Proteins Pancreas Endoderm SOX Transcription Factors Amino Acids, Peptides, and Proteins Animal Experimentation and Research Digestive System Embryonic Structures
42	VPS45p as a Model System for Elucidation of SEC1/MUNC18 Protein Function: A Dissertation Furgason, Melonnie Lynn Marie 09 December 2008 (has links) Vesicular trafficking, the movement of vesicles between organelles and the plasma membrane for secretion, consists of multiple highly regulated processes. Many protein families function as specificity and regulatory determinants to ensure correct vesicle targeting and timing of trafficking events. The SNARE proteins dock and fuse vesicles to their target membranes. Sec1/Munc18 (SM) proteins regulate membrane fusion through interactions with the SNAREs—SM proteins have been shown to act as both inhibitors and stimulators of SNARE assembly and membrane fusion. However, the details of these SM protein functions are not understood. Constructing a model of SM protein function has been challenging due to the various modes of interactions reported between SM proteins and their SNAREs. SM proteins interact with their cognate SNAREs and SNARE complexes through several distinct modes. The most conserved mode is an interaction with the syntaxin N-peptide; other modes of binding, such as the syntaxin closed conformation, are hypothesized to be specific for specialized cell types. In order to elucidate the general function of SM proteins, I investigated the function of the endosomal SM protein Vps45p by analyzing its interactions with its cognate syntaxin Tlg2p and its role in SNARE assembly. I had two main hypotheses: that the Tlg2p N-peptide does not solely mediate the interaction between Vps45p and Tlg2p; and that Vps45p functions to stimulate SNARE complex assembly. I systematically mapped the interaction between Vps45p and Tlg2p using various Tlg2p truncations containing the different domains of Tlg2p and discovered a second binding site on Tlg2p that corresponds to the closed conformation. The neuronal SM-syntaxin pair interacts in a similar manner, indicating that this interaction mode is conserved. To characterize the closed conformation binding mode further, and determine its relationship to the N-peptide binding mode, I developed a quantitative fluorescent electrophoretic mobility shift assay. Results indicate that these two sites do not bind simultaneously and that the N-peptide binding modulates the closed conformation affinity. Furthermore, I monitored the effect of Vps45p on SNARE complex assembly using size exclusion chromatography. Under the conditions tested, Vps45p did not appear to stimulate SNARE complex assembly. The work presented here addresses several puzzling issues in the field and significantly contributes to the construction of a new mechanistic model for SM protein function. In this new model, the SM protein is recruited to the membrane by its interaction with the syntaxin N-peptide. The SM protein then binds the syntaxin closed conformation thus inhibiting SNARE complex assembly. Upon dissociation of the SM protein from the closed conformation, an event perhaps regulated by the SM protein, syntaxin opens and interacts with the other SNAREs to form a SNARE complex. Fusion ensues, stimulated by the SM protein. Vesicular Transport Proteins Drosophila Proteins Munc18 Proteins SNARE Proteins Qa-SNARE Proteins Neurons Amino Acids, Peptides, and Proteins Animal Experimentation and Research
43	A Multiparameter Network Reveals Extensive Divergence Between <em>C. elegans</em> bHLH Transcription Factors: A Dissertation Grove, Christian A. 11 September 2009 (has links) It has become increasingly clear that transcription factors (TFs) play crucial roles in the development and day-to-day homeostasis that all biological systems experience. TFs target particular genes in a genome, at the appropriate place and time, to regulate their expression so as to elicit the most appropriate biological response from a cell or multicellular organism. TFs can often be grouped into families based on the presence of similar DNA binding domains, and these families are believed to have expanded and diverged throughout evolution by several rounds of gene duplication and mutation. The extent to which TFs within a family have functionally diverged, however, has remained unclear. We propose that systematic analysis of multiple aspects, or parameters, of TF functionality for entire families of TFs could provide clues as to how divergent paralogous TFs really are. We present here a multiparameter integrated network of the activity of the basic helix-loop-helix (bHLH) TFs from the nematode Caenorhabditis elegans. Our data, and the resulting network, indicate that several parameters of bHLH function contribute to their divergence and that many bHLH TFs and their associated parameters exhibit a wide range of connectivity in the network, some being uniquely associated to one another, whereas others are highly connected to multiple parameter associations. We find that 34 bHLH proteins dimerize to form 30 bHLH dimers, which are expressed in a wide range of tissues and cell types, particularly during the development of the nematode. These dimers bind to E-Box DNA sequences and E-Box-like sequences with specificity for nucleotides central to and flanking those E-Boxes and related sequences. Our integrated network is the first such network for a multicellular organism, describing the dimerization specificity, spatiotemporal expression patterns, and DNA binding specificities of an entire family of TFs. The network elucidates the state of bHLH TF divergence in C. elegans with respect to multiple functional parameters and suggests that each bHLH TF, despite many molecular similarities, is distinct from its family members. This functional distinction may indeed explain how TFs from a single family can acquire different biological functions despite descending from common genetic ancestry. Caenorhabditis elegans Transcription Factors Amino Acids, Peptides, and Proteins Animal Experimentation and Research Genetic Phenomena
44	MicroRNA Markers of Acetaminophen Toxicity: A Master's Thesis Ward, Jeanine 25 July 2012 (has links) Background To investigate plasma microRNA (miRNA) profiles indicative of hepatotoxicity in the setting of lethal acetaminophen (APAP) toxicity in mice. Methods Using plasma from APAP poisoned mice, either lethally (500 mg/kg) or sublethally (150 mg/kg) dosed, we screened commercially available murine microRNA libraries (SABiosciences, Qiagen Sciences, MD) to evaluate for unique miRNA profiles between these two dosing parameters. Results We distinguished numerous, unique plasma miRNAs both up- and down-regulated in lethally compared to sublethally dosed mice. Of note, many of the greatest up- and down-regulated miRNAs, included, but were not limited to, 574-5p, 466g, 466f-3p, 375, 29c, and 148a. There was a statistically significant increase in alanine aminotransferase levels in the lethal compared to sublethal APAP dosing groups at the 12 h time point ( P < 0.001). There was 90% mortality in the lethally compared to sublethally dosed mice at the 48 h time point ( P = 0.011). Conclusion We identified unique plasma miRNAs both up- and down-regulated in lethally dosed APAP poisoned mice. MicroRNAs Acetaminophen Animal Experimentation and Research Digestive System Organic Chemicals Pharmaceutical Preparations Therapeutics
45	DNA Damage-Induced Apoptosis in the Presence and Absence of the Tumor Suppressor p53: A Dissertation McNamee, Laura Michelle 22 October 2008 (has links) A key regulator of DNA damage-induced apoptosis is the tumor suppressor gene, p53. p53 is a transcription factor that upregulates genes involved in cell cycle arrest, apoptosis, and senescence. How p53 decides to activate one of these responses in response to DNA damage is largely unanswered. Many have hypothesized it is due to interaction with various signaling pathways and post-translational modification. The p53 tumor suppressor can be modified by SUMO-1 in mammalian cells, but the functional consequences of this modification are unclear. Conjugation to SUMO is a reversible post-translational modification that regulates several transcription factors involved in cell proliferation, differentiation, and disease. In Chapter II, we demonstrate that the Drosophila homolog of human p53 can be efficiently sumoylated in insect cells. We identify two lysine residues involved in SUMO attachment, one at the C-terminus, between the DNA binding and oligomerization domains, and one at the N-terminus of the protein. We find that sumoylation helps recruit Drosophila p53 to nuclear dot-like structures that can be marked by human PML and the Drosophila homologue of Daxx. We demonstrate that mutation of both sumoylation sites dramatically reduces the transcriptional activity of p53 and its ability to induce apoptosis in transgenic flies, providing in vivo evidence that sumoylation is critical for Drosophilap53 function. Many therapeutic cancer treatments rely on DNA-damaging agents to induce apoptosis in cancer cells. However, fifty percent of all human tumors lack functional p53 and p53 mutant cells are partially resistant to damage-induced apoptosis. Therefore, it is important to identify mechanisms to induce apoptosis independent of p53. Drosophila provides a good model system to study p53-independent apoptosis because it contains a single p53 homolog. In Chapter III, we describe a p53-independent mechanism that acts in parallel to the canonical DNA damage response pathway in Drosophila to activate apoptosis in response to inappropriately repaired chromosome breaks. Induction of chromosome aberrations by DNA damage followed by cell division results in segmental aneuploidy and reduced copy number of ribosomal protein genes. We find that activation of the pro-apoptotic gene hid by the JNK pathway acts in a p53-independent mechanism to induce apoptosis and limit the formation of aneuploid cells. Mutations in grp, the Drosophila Chk1 homolog, and puc, a negative regulator of the JNK pathway sensitize p53 mutant cells to IR-induced apoptosis. We propose a model in which the death of cells with reduced copy number of genes required for cell survival helps maintain genomic integrity following chromosome damage Apoptosis Genes p53 DNA Damage Drosophila Drosophila Proteins Amino Acids, Peptides, and Proteins Animal Experimentation and Research Cells Genetic Phenomena Neoplasms
46	Maintaining the Balance: Coordinating Excitation and Inhibition in a Simple Motor Circuit: A Dissertation Petrash, Hilary A. 06 August 2012 (has links) The generation of complex behaviors often requires the coordinated activity of diverse sets of neural circuits in the brain. Activation of neuronal circuits drives behavior. Inappropriate signaling can contribute to cognitive disorders such as epilepsy, Parkinson’s, and addiction (Nordberg et al., 1992; Quik and McIntosh, 2006; Steinlein et al., 2012). The molecular mechanisms by which the activity of neural circuits is coordinated remain unclear. What are the molecules that regulate the timing of neural circuit activation and how is signaling between various neural circuits achieved? While much work has attempted to address these points, answers to these questions have been difficult to ascertain, in part owing to the diversity of molecules involved and the complex connectivity patterns of neural circuits in the mammalian brain. My thesis work addresses these questions in the context of the nervous system of an invertebrate model organism, the nematode Caenorhabditis elegans. The locomotory circuit contains two subsets of motor neurons, excitatory and inhibitory, and the body wall muscle. Dyadic synapses from excitatory neurons coordinate the simultaneous activation of inhibitory neurons and body wall muscle. Here I identify a distinct class of ionotropic acetylcholine receptors (ACR-12R) that are expressed in GABA neurons and contain the subunit ACR-12. ACR-12R localize to synapses of GABA neurons and facilitate consistent body bend amplitude across consecutive body bends. ACR-12Rs regulate GABA neuron activity under conditions of elevated ACh release. This is in contrast to the diffuse and modulatory role of ACR-12 containing receptors expressed in cholinergic motor neurons (ACR-2R) (Barbagallo et al., 2010; Jospin et al., 2009). Additionally, I show transgenic animals expressing ACR-12 with a mutation in the second transmembrane domain [ACR-12(V/S)] results in spontaneous contractions. Unexpectedly, I found expression of ACR-12 (V/S) results in the preferential toxicity of GABA neurons. Interestingly loss of presynaptic GABA neurons did not have any obvious effects on inhibitory NMJ receptor localization. Together, my thesis work demonstrates the diverse roles of nicotinic acetylcholine receptors (nAChRs) in the regulation of neuronal activity that underlies nematode movement. The findings presented here are broadly applicable to the mechanisms of cholinergic signaling in vertebrate models. Caenorhabditis elegans Motor Neurons Nicotinic Receptors Amino Acids, Peptides, and Proteins Animal Experimentation and Research Nervous System Neuroscience and Neurobiology
47	Importance of the Microhabitat and Microclimate Conditions in the Northern Gray-cheeked Salamander (Plethodon montanus) Across an Elevation Gradient Chapman, Trevor 01 December 2022 (has links) The southern Appalachian Mountains have among the highest salamander diversity in the world, largely due to local speciation in the family Plethodontidae. Plethodontid salamanders (i.e., lungless salamanders) are particularly sensitive to habitat climate conditions due to their reliance on cutaneous respiration, and their immediate environmental conditions (microhabitat) likely influence their dispersion and activity more than the large-scale atmospheric conditions. The Northern Gray-cheeked salamander (Plethodon montanus) is restricted to high elevations in the Appalachian Mountains. Our goal was to investigate the relationship between P. montanus and its microhabitat by examining behavioral preference for climatic conditions, characterizing the microclimate with small-scale models, and testing for differences in stress hormones at different elevations. We found that behavioral preference is most restricted by relative humidity, microclimate models predicted far less prevalence at lower elevations than typical coarse-scale models, and stress hormones were elevated at a low elevation plot compared to a high elevation plot. lungless salamander microclimate stress hormones behavior Animal Experimentation and Research Behavior and Ethology Endocrinology Integrative Biology Other Ecology and Evolutionary Biology
48	The Identification of Cooperating Mutations in TAL1-Mediated Leukemia in the Mouse: A Dissertation Calvo, Jennifer Ann 01 September 2005 (has links) A sequential series of mutational events is necessary for the development of leukemia. The misexpression of TAL1, a basic helix-loop-helix (bHLH) transcription factor, is the most common mutation in T cell acute lymphoblastic leukemia (T-ALL). Tal1 transgenic mice develop leukemia with a long latency and incomplete penetrance indicating additional mutations are necessary to develop disease. To investigate additional mutational events that potentially contribute to TAL1-expressing T-ALL patients, we sought to identify cooperating mutations in Tal1 transgenic mice. Clinical studies implicated the loss of the INK4a/ARF locus, which encodes two tumor suppressors, p16INK4a and p14ARF, in the majority of T-ALL patients. We demonstrated disease acceleration in tal1/ink4a/arf+/-, tal1/pl6ink4a+/- and tal1/p19arf+/- mice, thereby providing genetic evidence that Tal1 cooperates with loss of either p16Ink4a or p19Arf in leukemogenesis. The cooperation of Tal1 with the loss of or p16Ink4a or p19Arf, is consistent with our observation that Tal1 alters cell cycle regulation in leukemia by promoting S phase induction and apoptosis in vivo. An additional mutational event common in tal1 tumors is activation of the Notch1 signaling pathway. We provide evidence that the majority of tal1 tumors express increased levels of Notch1, and exhibit activating notch1 mutations. Additionally, tal1 tumors display sensitivity to the pharmacologic inhibition of γ-secretase activity in vitro, indicating that γ-secretase inhibitors may prove an efficacious treatment for TAL1-expressing T-ALL patients. Furthermore, we developed a doxycycline-regulated NotchIC T-ALL cell line, which will allow the identification of important Notch1IC target genes in leukemogenesis. Leukemia T-Cell Acute Mutation Transcription Factors Helix-Loop-Helix Motifs Receptors Cell Surface Amino Acids, Peptides, and Proteins Animal Experimentation and Research Genetic Phenomena Neoplasms
49	EFFECTS OF CHROMIUM ON MOUSE SPLENIC T LYMPHOCYTES AND EFFECTS OF ETHANOL EXPOSURE DURING EARLY NEURODEVELOPMENT ON BEHAVIORS IN MICE Dai, Lu 01 January 2017 (has links) The dissertation consists of three major projects with the focus on the immunotoxicity of chromium and the behavior disorders caused by early ETOH exposure respectively. Hexavalent chromium [Cr(VI)] is widely used in various industrial processes and has been recognized as a carcinogen. As the first line of host defense system, the immune system can be a primary target of Cr(VI). T cell population represents a major arm of the immune system that plays a critical role in host anti-tumor immunity. Dysfunction of T cells compromises host anti-tumor immunity resulting in oncogenesis. Using mouse splenic T cells as an in vitro model system, the present study assessed the effects of Cr(VI) on T cell functions, as the first step of our investigation of the mechanism underlying Cr(VI)-inhibited immunosurveillance and carcinogenesis. Our results showed that Cr(VI) decreased the viability of CD4+ and CD8+ T cells, inhibited T cell activation, functions, including cytokine release, and degranulation. Fetal ethanol (ETOH) exposure can damage the developing central nervous system and lead to cognitive and behavioral deficits, known as fetal alcohol spectrum disorders (FASD). The use of animal models, especially mouse models is essential for investigating the neurogenetic mechanism of fetal ETOH effects and screening pharmacotherapies against it, due to the extensive knowledge of mouse genetics. However, the availability of mouse model is limited. Via adopting various dosage, timing and administration routes of ETOH exposure, we developed two mouse models to assess behavioral or cognitive changes caused by fetal ETOH exposure in pre-weaning and adolescent period. Our results show that high dosage of ETOH exposure (4 g/kg) during PD 4-10 resulted in hyperactivity, disinhibition, and deficits in learning and memory in mouse offspring, which lays the groundwork for the future FASD research. Cr(VI) T cell immunity carcinogenesis FASD behavioral deficits mice model Animal Experimentation and Research Behavioral Neurobiology Cancer Biology Developmental Biology Developmental Neuroscience Environmental Health Immunity Toxicology
50	Possible breakdown of dopamine receptor synergism in a mouse model of Huntington's Disease Kennedy, Samantha F 20 December 2017 (has links) The model of basal ganglia function proposed by Albin, Young and Penney (1989) describes two anatomically independent motor pathways, the direct and indirect. However, under normal conditions striatal dopamine (DA) is required for the expression of motor behavior, and DAergic control of the two pathways (via D1 and D2 receptors, respectively) is dependent on co-activation. We tested for a possible breakdown of D1/D2 synergism using transgenic R6/1 mice bearing the human huntingtin allele (Htt). Motor stereotypy, observed prior to the onset of HD-related symptoms, was rated on a 5-point scale following activation of: A) D1 receptors alone, B) D2 receptors alone, and C) stimulation of both D1 and D2 receptors. Results revealed that mice with the HD allele, like their WT litter mates, depend on the co-activation of the indirect and direct motor pathways to facilitate deliberate behavior. dopamine synergism motor pathway Huntington's Disease basal ganglia striatum Animal Experimentation and Research Applied Behavior Analysis Behavioral Neurobiology Biological Psychology Neurosciences Systems Neuroscience

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