Global ETD Search

91	The Membrane Integration of the Hemagglutinin-Neuraminidase Glycoprotein of Newcastle Disease Virus: A Thesis Wilson, Cheryl Anne 01 May 1989 (has links) The hemagglutinin-neuraminidase (HN) molecule of Newcastle disease virus (NDV) is an integral membrane glycoprotein that is oriented with its N-terminus in the cytoplasm and its C-terminus external to the infected cell. Single spanning membrane proteins with this type of topology (N-terminus in, C-terminus out) have been classified as Type II glycoproteins, in contrast to the more common Type I glycoproteins, which are oriented in the opposite direction. (C-terminus in, N-terminus out). The membrane integration of HN protein was investigated using a wheat germ translation system to synthesize and integrate HN protein into microsomal membranes in vitro. The insertion and translocation of HN protein into microsomal vesicles was found to occur cotranslationally without signal sequence cleavage. The membrane targeting required both signal recognition particle (SRP) and SRP receptor. Membrane binding assays utilizing HN nascent chain/ribosome/SRP complexes demonstrated that the membrane insertion of HN polypeptide required the presence of GTP, in a way similar to that described for secretory, multispanning and Type I proteins. To investigate further the membrane translocation process of HN protein, the amino terminal region of HN was mutated to determine the role of this region in the membrane integration of HN. The cDNA sequence encoding the bulk of the cytoplasmic tail of the HN glycoprotein was deleted. When transcripts produced from the mutated cDNA were translated in wheat germ extract in the presence of membranes, several abnormalities were identified in the interaction of the mutant protein with membranes. Although translocation and glycosylation of the mutant protein was detected, the efficiency of membrane translocation and the stability of the mutant protein's membrane interaction were reduced. Even though a large proportion of the mutant products remained nontranslocated and unglycosylated, many of these products were inserted into membrane vesicles in a reverse orientation from the wild type HN protein. The aberrant insertion of the mutant protein required both SRP and SRP receptor. Ribosome-bound mutant nascent chains were able to insert into membranes without the addition of GTP or SRP, but this GTP-independent insertion was in reverse. Therefore, the cytoplasmic tail of the HN glycoprotein appears to playa critical role in the maintanence of faithful directionality of the protein's membrane insertion. HN Protein Glycoproteins Molecular Biology Neuraminidase Newcastle disease virus Academic Dissertations Dissertations, UMMS Life Sciences Medicine and Health Sciences
92	Inflammasomes and the Innate Immune Response Against Yersinia Pestis: A Dissertation Vladimer, Gregory I. 10 January 2013 (has links) Yersinia pestis, the causative agent of plague, is estimated to have claimed the lives of 30-50% of the European population in five years. Although it can now be controlled through antibiotics, there are still lurking dangers of outbreaks from biowarfare and bioterrorism; therefore, ongoing research to further our understanding of its strong virulence factors is necessary for development of new vaccines. Many Gram-negative bacteria, including Y. pseudotuberculosis, the evolutionary ancestor of Y. pestis, produce a hexa-acylated lipid A/LPS which can strongly trigger innate immune responses via activation of Toll-like receptor 4 (TLR4)-MD2. In contrast, Y. pestis grown at 37ºC generates a tetra-acylated lipid A/LPS that poorly induces TLR4-mediated immune activation. We have reported that expression of E. coli lpxL in Y. pestis, which lacks a homologue of this gene, forces the biosynthesis of a hexa-acylated LPS, and that this single modification dramatically reduces virulence in wild type mice, but not in mice lacking a functional TLR4. This emphasizes that avoiding activation of innate immunity is important for Y. pestis virulence. It also provides a model in which survival is strongly dependent on innate immune defenses, presenting a unique opportunity for evaluating the relative importance of innate immunity in protection against bacterial infection. TLR signaling is critical for the sensing of pathogens, and one implication of TLR4 engagement is the induction of the pro-forms of the potent inflammatory cytokines IL-1β and IL-18. Therefore Y. pestis is able to suppress production of these which are generated through caspase-1-activating nucleotide-binding domain and leucine-rich repeat (NLR)-containing inflammasomes. For my thesis, I sought to elucidate the role of NLRs and IL-18/IL-1β during bubonic and pneumonic plague infection. Mice lacking IL-18 signaling led to increased susceptibility to wild type Y. pestis, and an attenuated strain producing a Y. pseudotuberculosis-like hexa-acylated lipid A. I found that the NLRP12, NLRP3 and NLRC4 inflammasomes were important protein complexes in maturing IL-18 and IL-1β during Y. pestis infection, and mice deficient in each of these NLRs were more susceptible to bacterial challenge. NLRC4 and NLRP12 also directed interferongamma production via induction of IL-18 against plague, and minimizing inflammasome activation may have been a central factor in evolution of the high virulence of Y. pestis. This is also the first study that elucidated a pro-inflammatory role for NLRP12 during bacterial infection. Inflammasomes Innate Immunity Yersinia pestis Virulence Factors Dissertations, UMMS Immunity, Innate Immunity Immunology and Infectious Disease
93	Nuclear Organization in Breast Cancer: A Dissertation Dobson, Jason R. 04 April 2013 (has links) The nuclear matrix (NM) is a fibrogranular network of ribonucleoproteins upon which transcriptional complexes and regulatory genomic sequences are organized. A hallmark of cancer is the disorganization of nuclear architecture; however, the extent to which the NM is involved in malignancy is not well studied. The RUNX1 and RUNX2 proteins form complexes within the NM to promote hematopoiesis and osteoblastogenesis, respectively at the transcriptional level. RUNX1 and RUNX2 are both expressed in breast cancer cells (BrCCs); however, their genome-wide BrCC functions are unknown. RUNX1 and RUNX2 activate many tumor suppressor pathways in blood and bone lineages, respectively, including attenuation of protein synthesis and cell growth via suppression of ribosomal RNA (rRNA) transcription, which appears contrary to Runx-expression in highly proliferative BrCCs. To define roles for RUNX1 and RUNX2 in BrCC phenotype, we examined the involvement of RUNX1 and RUNX2 in rRNA transcription and generated a genome-wide model for RUNX1 and RUNX2-binding and transcriptional regulation. To validate gene expression patterns identified in our screen, we developed a Real-Time qPCR primer design program, which allows rapid, high-throughput design of primer pairs (FoxPrimer). In BrCCs, RUNX1 and RUNX2 regulate genes that promote invasiveness and do not affect rRNA transcription, protein synthesis, or cell growth. We have characterized in vitro functions of Runx proteins in BrCCs; however, the relationships between Runx expression and diagnostic/prognostic markers of breast cancer (BrCa) in patients are not well studied. Immunohistochemical detection of RUNX1 and RUNX2 in BrCa tissue microarrays reveals RUNX1 expression is associated with early, smaller tumors that are ER+ (estrogen receptor), HER2+, p53-, and correlated with androgen receptor (AR) expression; RUNX2 expression is associated with late-stage, larger tumors that are HER2+. These results show that the functions and expression patterns of NM-associated RUNX1 and RUNX2 are context-sensitive, which suggests potential disease-specific roles. Two functionally disparate genomic sequence types bind to the NM: matrix associated regions (MARs) are functionally associated with transcriptional repression and scaffold associated regions (SARs) are functionally associated with actively expressed genes. It is unknown whether malignant nuclear disorganization affects the functions of MARs/SARs in BrCC. We have refined a method to isolate nuclear matrix associated DNA (NM-DNA) from a structurally preserved NM and applied this protocol to normal mammary epithelial cells and BrCCs. To define transcriptional functions for NM-DNA, we developed a computational algorithm (PeaksToGenes), which statistically tests the associations of experimentally-defined NM-DNA regions and ChIP-seq-defined positional enrichment of several histone marks with transcriptome-wide gene expression data. In normal mammary epithelial cells, NM-DNA is enriched in both MARs and SARs, and the positional enrichment patterns of MARs and SARs are strongly associated with gene expression patterns, suggesting functional roles. In contrast, the BrCCs are significantly enriched in the silencing mark H3K27me3, and the NM-DNA is enriched in MARs and depleted of SARs. The MARs/SARs in the BrCCs are only weakly associated with gene expression patterns, suggesting that loss of normal DNA-matrix associations accompanies the disease state. Our results show that structural preservation of the in situ NM allows isolation of both MARs and SARs, and further demonstrate that in a disorganized, cancerous nucleus, normal transcriptional functions of NM-DNA are disrupted. Our studies on nuclear organization in BrCC, show that the disorganized phenotype of the cancer cell nucleus is accompanied by deregulated transcriptional functions of two constituents of the NM. These results reinforce the role of the NM as an important structure-function component of gene expression regulation. Breast Neoplasms Breast Cancer Nuclear Matrix Core Binding Factor alpha Subunits Neoplasm Proteins Dissertations, UMMS Cancer Biology Cell and Developmental Biology
94	The Notch1-c-Myc Pathway Mediates Leukemia-Initiating Cell Activity in Mouse T-ALL Models: A Dissertation Tesell, Jessica M. 10 May 2013 (has links) Although cure rates have significantly improved for children with T-cell acute lymphoblastic leukemia (T-ALL), 20-30% undergo induction failure or relapse with most succumbing to disease. Leukemia-initiating cells (L-ICs) are hypothesized to be resistant to conventional chemotherapy and radiation and are thereby responsible for disease recurrence. Using an in vivo limiting dilution assay, we previously showed that the murine T-ALL L-IC is quite rare, with only 0.003-0.05% of cells capable of initiating disease, and demonstrated that the L-IC is a subset of the leukemic DN3 thymic progenitor population. Work described in this thesis validates the L-IC assay using two transplantation methods to rule out effects of homing and/or microenvironment on T-ALL L-IC survival and maintenance. Using this assay, we demonstrate that sustained Notch1 signaling is required for T-ALL initiation in vivo and show that treatment with a Notch1 inhibitor reduces or in some cases eliminates the L-IC population. We further analyze the effects of inhibiting c-Myc, a Notch1-regulated gene, on L-IC frequency and uncover an essential role for c-Myc in L-IC survival and expansion. Suppressing c-Myc by using specific shRNAs or a c-Myc inhibitor reduces the L-IC population and interferes with leukemia initiation. Together, these findings reveal a critical role of the Notch1-c-Myc pathway in T-ALL initiation and suggest that therapeutics targeted at this pathway could be used to treat and/or prevent disease relapse in patients. Notch1 Receptor myc Genes Dissertations, UMMS Receptor, Notch1 Genes, myc Cancer Biology
95	Structural Mechanisms of the Sliding Clamp and Sliding Clamp Loader: Insights into Disease and Function: A Dissertation Duffy, Caroline M. 15 July 2016 (has links) Chromosomal replication is an essential process in all life. This dissertation highlights regulatory roles for two critical protein complexes at the heart of the replication fork: 1) the sliding clamp, the major polymerase processivity factor, and 2) the sliding clamp loader, a spiral-shaped AAA+ ATPase, which loads the clamp onto DNA. The clamp is a promiscuous binding protein that interacts with at least 100 binding partners to orchestrate many processes on DNA, but spatiotemporal regulation of these binding interactions is unknown. Remarkably, a recent disease-causing mutant of the sliding clamp showed specific defects in DNA repair pathways. We aimed to use this mutant as a tool to understand the binding specificity of clamp interactions, and investigate the disease further. We solved three structures of the mutant, and biochemically showed perturbation of partnerbinding for some, but not all, ligands. Using a fission yeast model, we showed that mutant cells are sensitive to select DNA damaging agents. These data revealed significant flexibility within the binding site, which likely regulates partner binding. Before the clamp can act on DNA, the sliding clamp loader places the clamp onto DNA at primer/template (p/t) junctions. The clamp loader reaction couples p/t binding and subsequent ATP hydrolysis to clamp closure. Here we show that composition (RNA vs. DNA) of the primer strand affects clamp loader binding, and that the order of ATP hydrolysis around the spiral is likely sequential. These studies highlight additional details into the clamp loader mechanism, which further elucidate general mechanisms of AAA+ machinery. DNA Replication DNA-Binding Proteins DNA Primers Dissertations, UMMS Amino Acids, Peptides, and Proteins Biochemistry Molecular Biology Structural Biology
96	Structural and Mutational Analysis of Rab2A Activation by Mss4: A Dissertation Zhu, Zhongyuan 01 November 2000 (has links) The function of GTP-binding proteins (G-proteins) in diverse intracellular pathways depends on their ability to switch between two forms, a GDP-bound (inactive) form and a GTP bound (active) form in a highly regulated GTPase cycle. The inactivation step of this cycle is regulated by GTPase-activating proteins (GAPs) which increase the intrinsic rate of hydrolysis of bound GTP; the activation step is regulated by a diverse family of GDP/GTP exchange factors (GEFs). A unique model system, which consists of the 13 kDa GEF Mss4 and the monomeric G protein Rab3A involved in presynaptic neurotransmission, was chosen to study the mechanism of G-protein regulation. Structure of Rab3A at high resolution The 2.0 Å crystal structure of Rab3A, bound to a non-hydrolyzable GTP-analog (GppNHp), enables a detailed description of the structural determinants that stabilize the active conformation and regulate GTPase activity within the Rab family. Although the overall structure is similar to that of GppNHp-bound Ras and other GTPases, localized but significant differences are observed in the vicinity of the conformational switch regions and the α3/β5 loop. The active conformation is stabilized primarily by extensive hydrophobic contacts between the switch I and II regions. Novel interactions with the γ phosphate, mediated by serine residues in the P-loop and switch I region, impose stereochemical constraints on the mechanism of GTP hydrolysis and provide a structural explanation for the broad range of GTPase activities within the Rab family. Residues implicated in interactions with effectors and regulatory factors map to a common face of the protein. The asymmetric distribution of charged and non-polar residues suggests a plausible orientation with respect to vesicle membranes that would position predominantly hydrophobic surfaces to interact with membrane-associated effectors and regulatory factors. Thus, the structure of Rab3A establishes a framework for understanding the molecular mechanisms underlying the function of Rab proteins in vesicle trafficking. High resolution structure of Mss4 and structure-based mutagenesis Activation of monomeric Rab GTPases, which function as ubiquitous regulators of intracellular membrane trafficking, requires the catalytic action of guanine nucleotide exchange factors. Mss4, an evolutionarily conserved Rab exchange factor, promotes nucleotide release from exocytic but not endocytic Rab GTPases. Chapter III describes the results of a high resolution crystallographic and mutational analysis of Mss4. The 1.65 Å crystal structure of Mss4 reveals a network of direct and water mediated interactions that stabilize a partially exposed structural sub-domain derived from four highly conserved but non-consecutive sequence elements. The conserved sub-domain contains the invariant cysteine residues required for Zn2+ binding as well as the residues implicated in the interaction with Rab GTPases. A strictly conserved DΦΦ motif, consisting of an invariant aspartic acid residue (Asp73) followed by two bulky hydrophobic residues (Met74 and Phe75), encodes a prominently exposed 310 helical turn in which the backbone is well ordered but the side chains of the conserved residues are highly exposed and do not engage in intramolecular interactions. Substitution of any of these residues with alariine dramatically impairs exchange activity towards Rab3A, indicating that the DΦΦ motif is a critical element of the exchange machinery. In particular, mutation of Phe75 results in a defect as severe as that observed for mutation of Asp96, which is located near the zinc binding site at the opposite end of Rab interaction epitope. Despite severe defects, however, none of the mutant proteins is catalytically dead. Taken together, the results suggest a concerted mechanism in which distal elements of the conserved Rab interaction epitope cooperatively facilitate GDP release. The basis for selective recognition of exocytic Rab family GTPases by Mss4 Rab3A is involved in Ca2+ -dependent exocytosis and neurotransmitter release. Mss4, an evolutionarily conserved Rab exchange factor, promotes nucleotide release from exocytic RabGTPase (Rab1, Rab3A, Rab8, and Rab10, Sec4 and Ypt1) but not endocytic Rab GTPases (Rab2, Rab4, Rab5, Rab6, Rab9 and Rab11). To understand the basis for selective recognition of exocytic Rab family GTPases by Mss4, a structure based mutagenesis study of Rab3A was conducted. Three residues in Rab3A (Phe51, Val61 and Thr89) were found to be critical for interaction with Mss4. Phe51 is located at the N- terminus of the switch region, adjacent to the Mg2+ and nucleotide binding site. Val61 in the β2 strand and Thr89 in the switch II region flank a triad of hydrophobic residues that is conserved in the Rab family. These residues comprise critical determinants underlying the broad specificity of Mss4 for exocytic Rab family proteins. In addition to determining the high resolution crystal structures of Rab3A and Mss4, the experiments described above identify critical structural determinants for the exchange activity of Mss4 and provide insight into the selective recognition of Mss4 by exocytic Rab GTPases. Rab3A GTP-Binding Protein GTP-Binding Proteins Academic Dissertations Dissertations, UMMS Life Sciences Medicine and Health Sciences
97	Local Macrophage Proliferation in Adipose Tissue Is a Characteristic of Obesity-Associated Inflammation: A Dissertation Amano, Shinya U. 27 March 2013 (has links) Obesity and diabetes are major public health problems facing the world today. Extending our understanding of adipose tissue biology, and how it changes in obesity, will hopefully better equip our society in dealing with the obesity epidemic. Macrophages and other immune cells accumulate in the adipose tissue in obesity and secrete cytokines that can promote insulin resistance. Adipose tissue macrophages (ATMs) are thought to originate from bone marrow-derived monocytes, which infiltrate the tissue from the circulation. Much work has been done to demonstrate that inhibition of monocyte recruitment to the adipose tissue can ameliorate insulin resistance. While monocytes can enter the adipose tissue, we have shown here that local macrophage proliferation may be the predominant mechanism by which macrophages self-renew in the adipose tissue. We demonstrated that two cell proliferation markers, Ki67 and EdU, can be readily detected in macrophages isolated from adipose tissue of both lean and obese mice. These analyses revealed that 2-4% of ATMs in lean and 10-20% of ATMs in obese mice express the proliferation marker Ki67. Importantly, Ki67+ macrophages were identified within the adipose tissue in crown-like structures. Similarly, a 3-hour in vivo pulse with the thymidine analog EdU showed that nearly 5% of macrophages in epididymal adipose tissue of ob/ob mice were in the S-phase of cell division. Interestingly, obesity increased the rate of macrophage proliferation in adipose tissue but did not affect macrophage proliferation in other tissues. We also used clodronate liposomes to deplete circulating monocytes in obese mice. Surprisingly, monocyte depletion for a total of at least 80 hours did not cause a decrease in ATM content in adipose tissue. Prolonged exposure of mice to EdU in drinking water revealed that approximately half of the ATMs in the epididymal fat pads of ob/ob mice had proliferated locally within 80 hours. Amazingly, these rates were the same with or without monocyte depletion, meaning that the proliferating cells were not freshly recruited monocytes. Overall, these results suggest that local proliferation unexpectedly makes a major contribution to maintaining the large population of macrophages present in the obese adipose tissue in the steady state. This suggests that increased rates of local macrophage proliferation may also be partly responsible for the massive increase in ATM content that occurs in obesity. This information could have implications for future therapeutic strategies in the management of diabetes. Adipose Tissue Macrophages Obesity Inflammation Diabetes Mellitus Insulin Resistance Dissertations, UMMS Cellular and Molecular Physiology Endocrinology Nutritional and Metabolic Diseases Physiology
98	Layered Reward Signalling Through Octopamine and Dopamine in Drosophila: A Dissertation Burke, Christopher J. 10 May 2013 (has links) Evaluating our environment by deciding what is beneficial or harmful, pleasant or punishing is a part of our daily lives. Seeking pleasure and avoiding pain is a common trait all mobile organisms exhibit and understanding how rewarding stimuli are represented in the brain remains a major goal of neuroscience. Studying reward learning in the fruit fly, Drosophila melanogaster has enabled us to better understand the complex neural circuit mechanisms involved in reward processing in the brain. By conditioning flies with sugars of differing nutritional properties, we determined that flies trained with sweet but non-nutritive sugars formed robust short-term memory (STM), but not long-term memory (LTM). However, flies conditioned with a sweet and nutritious sugar or a sweet non-nutritious sugar supplemented with a tasteless nutritious compound, formed robust 24 hour LTM. These findings led us to propose a model of parallel reinforcement pathways for appetitive olfactory conditioning in the fly, in which both sweet taste and nutrient value contribute to appetitive long-term memory. We followed this line of research by examining the neural circuitry in the fly brain that represents these parallel reward pathways. We found that the biogenic amine octopamine (OA) only represents the reinforcing effects of sweet taste. Stimulation of OA neurons could replace sugar in olfactory conditioning to form appetitive STM. Surprisingly, implanting memory with OA was dependent on dopamine (DA) signaling, which although being long associated with reward in mammals, was previously linked with punishment in flies. We found that OA-reinforced memory functions through the α-adrenergic OAMB receptor in a novel subset of rewarding DA neurons that innervate the mushroom body (MB). The rewarding population of DA neurons is required for sweet and nutrient reinforced memory suggesting they may integrate both signals to drive appetitive LTM formation. In addition, OA implanted memory requires concurrent modulation of negatively reinforcing DA neurons through the β-adrenergic OCTβ2R receptor. These data provide a new layered reward model in Drosophila in which OA modulates distinct populations of both positive and negative coding DA neurons. Therefore, the reinforcement system in flies is more similar to that of mammals than previously thought. Drosophila reward conditioning Dissertations, UMMS Reward Reinforcement (Psychology) Neural Pathways Drosophila melanogaster Octopamine Dopamine Signal Transduction Neuroscience and Neurobiology
99	The Role of Inducible T Cell Kinase (Itk) in the Development of Innate T Cells and in the Formation of Protective Memory Responses: A Dissertation Prince, Amanda L. 27 February 2013 (has links) T cell development in the thymus produces multiple lineages of cells, including conventional naïve CD4+ and CD8+ T cells, regulatory T cells, and innate T cells. Innate T cells encompass γδ T cells, invariant natural killer (iNKT) cells, mucosal-associated invariant T (MAIT) cells, and H2-M3-restricted cells (Berg, 2007). Although they are a minor subset of all thymocytes, innate T cells develop in the thymus and share characteristics of the innate and adaptive immune systems (Berg, 2007). These lymphocytes undergo antigen receptor rearrangement and are able to exert their effector function immediately upon ex vivo stimulation (Berg, 2007). However, in several strains of mice harboring mutations in T cell signaling proteins or transcriptional regulators, conventional CD8+ T cells develop as innate cells that share characteristics with memory T cells (Atherly et al., 2006b; Broussard et al., 2006; Fukuyama et al., 2009; Gordon et al., 2011; Verykokakis et al., 2010b; Weinreich et al., 2010). One of these signaling proteins, inducible T cell kinase (Itk) is a nonreceptor protein tyrosine kinase that signals downstream of the T cell receptor (TCR) (Berg et al., 2005). Upon TCR activation, Itk is activated and recruited to the TCR signaling complex, where Itk interacts with Src homology 2 (SH2) domain-containing leukocyte phosphoprotein of 76 kDa (SLP-76), linker for activation of T cells (LAT), and phospholipase C γ1 (PLCγ1) (Berg et al., 2005). Thus, in Itk-deficient mice, TCR signaling is disrupted, which results in mature CD4- CD8+ (CD8SP) thymocytes that are CD44high, CD62Lhigh, CD122+, and CXCR3+ and that express high levels of the transcription factor, Eomesodermin (Eomes) (Atherly et al., 2006b; Broussard et al., 2006; Weinreich et al., 2010). Recently, it was determined that the development of these innate CD8SP thymocytes in itk-/- mice is dependent on IL-4 produced in the thymic environment by a poorly characterized subset of CD3+ thymocytes expressing the transcriptional regulator, promyelocytic leukemia zinc finger (PLZF) (Gordon et al., 2011; Verykokakis et al., 2010b; Weinreich et al., 2010). Here we show that a sizeable proportion of mature CD4+ CD8- (CD4SP) thymocytes in itk-/- mice also develop as Eomesodermin+ innate T cells. These Eomes+ innate CD4+ T cells are CD44high, CD62Lhigh, CD122+, and CXCR3+ (Atherly et al., 2006b; Broussard et al., 2006; Dubois et al., 2006; Weinreich et al., 2010). Surprisingly, neither CD4SP nor CD8SP innate thymocytes in itk-/- mice are dependent on γδ T cells for their development as was previously hypothesized (Alonzo and Sant'Angelo, 2011). Instead, both subsets of innate itk-/- T cells require the presence of a novel PLZF-expressing, SAP-dependent thymocyte population that is essential for the conversion of conventional CD4+ and CD8+ T cells into Eomesodermin-expressing innate T cells with a memory phenotype. This novel subset of PLZF-expressing SAP-dependent innate T cells preferentially home to the spleen and mesenteric lymph nodes and have a restricted TCR repertoire. Thus, we have christened this subset as CD4+ PLZF + MAIT-like cells. We have characterized multiple subsets of innate T cells that expand in the absence of Itk. Therefore, we were interested in how innate T cells respond to infection. Although Itk KO mice have defects in cytolytic function and cytokine production during an acute infection, these mice are able to clear viral infections (Atherly et al., 2006a; Bachmann et al., 1997). Hence, we hypothesized that Itk-deficient memory CD8+ T cells would be able to provide protection upon a challenge infection. Conversely, we found this not to be true although Itk-deficient memory CD8+ T cells were present in similar frequencies and cell numbers as WT memory CD8+ T cells at 42 days post-infection. Furthermore, Itk-deficient memory CD8+ T cells were able to produce IFNγ and exert cytolytic function upon stimulation. Although the function of Itk-deficient memory CD8+ T cells appeared to be intact, we found that these cells were unable to expand in response to a challenge infection. Remarkably, conventional memory CD8+ T cells lacking Itk were able to expand and form protective memory responses upon challenge. Thus, the inability of Eomes+ innate CD8+ T cells to form protective memory responses does not appear to be intrinsic to cells deficient in Itk. This thesis is divided into six major chapters. The first chapter will provide an introduction to T cell development and the role of Itk in T cell development. Additionally, it will introduce a variety of innate T cell subsets that will be discussed throughout this thesis and will provide an overview of CD4+ and CD8 + T cell differentiation during infection. This section will explain the role of Itk in CD4+ helper T cell differentiation and describe how Itk-deficient CD8+ T cells respond to acute infection. The introduction will also discuss the generation of conventional memory CD8+ T cells. The second chapter will provide the details of the experimental procedures used in this thesis. The third chapter will describe the characterization and development of Eomes+ innate CD4+ T cells that develop in the absence of Itk. Additionally, this chapter will address the subset of PLZF+ innate T cells that induce the expression of Eomes in innate T cells. The fourth chapter will further characterize and explore the development of itk-/- CD4+ PLZF+ MAIT-like T cells. The fifth chapter will examine the role of Eomes + innate CD8+ T cells in protective memory responses. Chapters three through five will display work that is in preparation to be submitted to a peer-reviewed journal. The sixth chapter will discuss the results of this thesis and their implications. Protein-Tyrosine Kinases Innate Immunity CD4-Positive T-Lymphocytes CD8-Positive T-Lymphocytes Dissertations, UMMS Immunity, Innate Immunity
100	Investigation of Multiple Concerted Mechanisms Underlying Stimulus-induced G1 Arrest in Yeast: A Dissertation Pope, Patricia A. 03 June 2013 (has links) Progression through the cell cycle is tightly controlled, and the decision whether or not to enter a new cell cycle can be influenced by both internal and external cues. For budding yeast one such external cue is pheromone treatment, which can induce G1 arrest. Two distinct mechanisms are known to be involved in this arrest, one dependent on the arrest protein Far1 and one independent of Far1, but the exact mechanisms have remained enigmatic. The studies presented here further elucidate both of these mechanisms. We looked at two distinct aspects of the Far1-independent arrest mechanism. First, we studied the role of the G1/S regulatory system in G1 arrest. We found that deletion of the G1/S transcriptional repressors Whi5 and Stb1 compromises Far1-independent arrest, but only partially, and that this partial arrest failure correlates to partial de-repression of G1/S transcripts. Deletion of the CKI Sic1, however, is more strongly required for arrest in the absence of Far1, though not when Far1 is present. Together, this demonstrates that functionally overlapping regulatory circuits controlling the G1/S transition collectively provide robustness to the G1 arrest response. We also sought to reexamine the phenomenon of pheromone-induced loss of G1/S cyclin proteins, which we suspected could be another Far1-independent arrest mechanism. We confirmed that pheromone treatment has an effect on G1 cyclin protein levels independent of transcriptional control. Our findings suggest that this phenomenon is dependent on SCFGrr1but is at least partly independent of Cdc28 activity, the CDK phosphorylation sites in Cln2, and Far1. We were not, however, able to obtain evidence that pheromone increases the degradation rate of Cln1/2, which raises the possibility that pheromone reduces their synthesis rate instead. Finally, we also studied the function of Far1 during pheromone-induced G1 arrest. Although it has been assumed that Far1 acts as a G1/S cyclin specific CDK inhibitor, there has been no conclusive evidence that this is the case. Our data, however, suggests that at least part of Far1’s function may actually be to interfere with Cln-CDK/substrate interactions since we saw a significant decrease of co-pulldown of Cln2 and substrates after treatment with pheromone. All together, the results presented here demonstrate that there are numerous independent mechanisms in place to help robustly arrest cells in G1. G1 Phase Cell Cycle Checkpoints Pheromones Saccharomyces cerevisiae Dissertations, UMMS Cell Biology Cellular and Molecular Physiology Molecular Biology

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