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91	Snail Protein Family in Drosophila Neurogenesis: a Dissertation Ashraf, Shovon I. 05 September 2001 (has links) The Snail protein functions as a transcriptional regulator to establish early mesodermal cell fate in Drosophila. Later, in germ band-extended embryos, Snail is considered a pan-neural protein based on its extensive expression in neuroblasts. The evidence presented in thesis links snail expression and function in CNS. Cloning and functional characterization of a novel snail homologue, in Drosophila, are also described here. Cloning of this gene, worniu (Chinese for snail), revealed that the neural function of snail is masked by this and another closely related gene escargot. Both Escargot and Worniu contain zinc finger domains that are highly homologous to that of Snail. These three members of Snail protein family are redundantly required for CNS development. Although not affecting formation of neuroblasts, the loss of expression of these three members correlates with disruption of Nb asymmetry and division. Downstream targets of Snail protein family, in these processes, are inscuteable and string. In mutant embryos, which have the three genes deleted, the RNA expression of inscuteable and string is significantly lowered. Consistent with the gene expression defects, the mutant embryos have loss of asymmetric localization of prospero RNA in neuroblasts and nuclear localization of Prospero protein in ganglion mother cells. Transgenic expression of inscuteable and string together, in the snail family deletion mutant, efficiently restores the Prospero expression in GMC, demonstrating that the two genes are key targets of Snail in Nbs. Like in the mesoderm, in CNS Snail function depends on interaction with dCtBP co-repressor. These results suggest that Sna [Snail] family of proteins control both asymmetry and cell division of neuroblasts by activating, perhaps indirectly, the expression of inscuteable and string. Central Nervous System Drosophila Drosophila Proteins Transcription Factors Zinc Fingers Amino Acids, Peptides, and Proteins Animal Experimentation and Research Embryonic Structures Genetic Phenomena Nervous System
92	The Role of the SWI/SNF Component INI1 in Mammalian Development and Tumorigenesis: a Dissertation Guidi, Cynthia J. 14 February 2003 (has links) In vivo DNA is compacted tightly, via its association with histones and non-histone proteins, into higher-order chromatin structure. In this state, the DNA is refractory to the cellular factors that require access to DNA. The repressive nature of chromatin is alleviated in part by the action enzymes that modify chromatin structure. There are two major groups of chromatin modifying enzymes: those that post-translationally modify histones by the addition of small chemical moieties and those that utilize the energy derived from ATP hydrolysis to physically disrupt chromatin structure. The SWI/SNF enzyme belongs to this latter group. The SWI/SNF complex was identified originally in yeast. Several of its subunits are required for the expression of a subset of inducible genes. The ATPase activity is provided by the SWI2/SNF2 protein. In mammals, there are two biochemically separable SWI/SNF complexes that contain either BRG1 or BRM, both homologs of yeast SWI2/SNF2. The yeast and mammalian SWI/SNF complexes are able to disrupt the Dnase I digestion pattern of in vitro assembled mononucleosomes and arrays, as well as facilitate the accessibility of restriction nucleases and transcription factors. The mechanism by which SWI/SNF functions has yet to be elucidated. SNF5 is a component of the yeast SWI/SNF complex. It is required for sucrose fermentation and mating type switching. The mammalian homolog of Snf5 is SNF5/INI1. SNF5/INI1 was identified simultaneously by two groups as a protein that shares homology with Snf5 and via a yeast two hybrid assay as a protein that interacts with HIV integrase (INtegrase Interactor). INI1 is a component of all mammalian SWI/SNF complexes purified to date. In humans, mutations and/or deletions in INI1 are associated with a variety of cancers, including malignant rhabdoid tumors, choroid plexus carcinomas, medullablastomas, primitive neuralectodermal tumors, and some cases of leukemia. Furthermore, constitutional mutations within INI1in individuals presenting with these tumors support the role of INI1 as a tumor suppressor. In this thesis, we show that Ini1 also functions as a tumor suppressor in mice. Approximately 20% of mice heterozygous for Ini1 present with tumors. Most of these tumors are undifferentiated or poorly differentiated sarcomas with variable rhabdoid features. All tumors examined to date show loss of heterozygosity at the Ini1 locus. We also show that Ini1 is essential for embryonic development. Mice homozygous-null for Ini1die between days 4 and 5.5 post-fertilization due to an inability to adhere to their substratum, form trophectoderm, and expand their inner cell mass. We further characterize the function of Ini1 in tumor suppression by generating mice heterozygous for both Ini1 and either Rb or p53. While heterozygosity at the Ini1 locus appears to have no effect on the rate of tumorigenesis in Rb-heterozygous mice, many of the tumors arising in compound heterozygous mice present with an altered morphology. This finding suggests that Ini1 may contribute to tumor progression due to loss of Rb. In contrast, mice compound heterozygous for Ini1 and p53 show a marked reduction in the rate of tumorigenesis compared to p53-heterozygous mice. Furthermore, the tumor spectrum is altered in these compound heterozygous mice. These findings suggest that Ini1 may function normally to repress p53 activity. Lastly, we show that expression of the Ini1 tumor suppressor itself is regulated tightly. Tissues and cells heterozygous for Ini1 express roughly equivalent levels of Ini1 protein and mRNA as their wild-type counterparts. We further show that this compensation is mediated by an increase in the rate of transcription from the wild-type Ini1 allele. Moreover, when exogenous Ini1 is introduced into Ini1-heterozygous cells, expression from the Ini1 promoter is reduced. These data indicate that a compensatory mechanism exists to ensure that the steady-state levels of Ini1 are constant. In summary, research detailed in this thesis has contributed to our understanding of the regulation of Ini1 as well as the role this protein plays in mammalian development and tumor suppression. Chromosomal Proteins Non-Histone DNA-Binding Proteins Genes Tumor Suppressor Mammals--growth & development Mice Transgenic Tumor Suppressor Proteins Amino Acids, Peptides, and Proteins Animal Experimentation and Research Genetic Phenomena Neoplasms
93	Autoantibodies to Centrosomes are Diagnostic for Human Scleroderma and Can Be Induced by Experimental Mycoplasma Infection in Mice: A Dissertation Gavanescu, Irina Catrinel 20 December 2002 (has links) The overall objective of this thesis work was to develop new insights into the etiology of scleroderma, a human systemic autoimmune disease, by analyzing the autoantibodies to centrosome antigens that develop during the disease. Centrosomes are perinuclear organelles that form microtubule arrays, including mitotic spindles that ensure the faithful segregation of chromosomes during mitosis. These studies used a novel methodology to determine the prevalence of anti-centrosome autoantibodies in patients with scleroderma. Recombinant centrosome antigens were used to determine the antigenic specificity of anti-centrosome antibody subsets by immunoblotting. Centrosome marker antibodies were used in indirect immunofluorescence assays to distinguish centrosomes within the polymorphic staining pattern frequently given by scleroderma sera. We found that 43% of patients are autoreactive to centrosomes, a prevalence higher than has been reported for any other scleroderma autoantigen. Half of the centrosome-positive patients also had autoantibodies against other antigens used in scleroderma diagnosis. However, in the remaining half of these patients, anti-centrosome antibodies represented the sole class of autoantibodies that was detectable. Anti-centrosome antibodies were detected in only a small percentage of normal individuals and patients with other connective tissue diseases. These data suggest that anti-centrosome autoantibodies may represent a new diagnostic tool in scleroderma. Upon examination of anti-centrosome autoantibody development in an animal model, it appeared that this autoantibody specificity may develop in mice as a consequence of an infection. An infectious agent was isolated by plaque-formation from carrier mice. Further characterization of the infectious agent was undertaken to obtain information on its physical, morphological and cytopathological properties. The infectious agent was identified by sequence and unique antigenic properties to be homologous to the pig pathogen Mycoplasma hyorhinis. When reintroduced into naive mice, the murine mycoplasma triggered anti-centrosome autoantibody development. While anti-centrosome autoantibodies of IgM isotype are part of the repertoire of naive unimmunized mice, mycoplasma infection specifically triggered the development of anti-centrosome IgG. Moreover, centrosome autoreactivity was prevented by antibiotic treatment. The autoantibody response evolved to recruit additional specificities, having IgM isotypes, reactive to endoplasmic reticulum-associated autoantigens. Scleroderma Systemic Scleroderma Circumscribed Autoantigens Autoantibodies Mycoplasma Infections Amino Acids, Peptides, and Proteins Animal Experimentation and Research Bacteria Biological Factors Skin and Connective Tissue Diseases
94	The Role of Itk in T Cell Development: A Dissertation Lucas, Julie Ann 14 January 2005 (has links) Itk is a member of the Tec family of non-receptor tyrosine kinases. It is expressed in T cells, NK cells, and mast cells. The purpose of this study was to determine the role of Itk in T cell development. Previous work from our lab and others has demonstrated that Itk is involved in signaling downstream of the T cell receptor and initial analysis of Itk-deficient mice revealed that these mice had some defects in T cell development. There are two stages of T cell development, the pre-T cell stage and the CD4+ CD8+ double positive stage, at which signals downstream of the T cell receptor are important. At the CD4+ CD8+ double positive stage, these signals direct two concurrent, but distinct processes known as repertoire selection and CD4/CD8 lineage commitment/differentiation. I show that there are only slight defects in development at the pre-T cell stage, presumably due to reduced TCR signaling. However these results clearly demonstrate that Itk is not essential at this stage of development. In contrast, repertoire selection, in particular positive selection, is significantly affected by the absence of Itk. Similarly, I show that Itk plays a role in lineage differentiation, although commitment to the appropriate lineage occurs normally in the absence of Itk. CD4-Positive T-Lymphocytes CD8-Positive T-Lymphocytes Cell Differentiation Protein-Tyrosine Kinase Nuclear Proteins Animal Experimentation and Research Cells Enzymes and Coenzymes Hemic and Immune Systems
95	Regulation of Transcription of Mouse Immunoglobulin Germ-Line γ1 RNA: Structural Characterization of Germ-Line γ1 RNA and Molecular Analysis of the Promoter: A Dissertation Xu, Minzhen 01 May 1991 (has links) The antibody class switch is achieved by DNA recombination between the sequences called switch (S) regions located 5' to immunoglobulin (Ig) heavy chain constant (CH) region genes. This process can be induced in cultured B cells by polyclonal stimulation and switching can be directed to specific antibody classes by certain lymphokines. These stimuli may regulate the accessibility of CH genes and their S regions to a recombinase as indicated by hypomethylation and transcriptional activity. For example, RNAs transcribed from specific unrearranged (germ-line) CH genes are induced prior to switching under conditions that promote subsequent switching to these same CH genes. The function of transcription of these germ-line CH genes is unknown. How stimuli regulate the accessibility of CHgenes is also unclear. I report in this dissertation the structure of the RNA transcribed from the unrearranged Cγ1 gene in mouse spleen cells treated with LPS plus a HeLa cell supernatant containing recombinant interleukin 4 (rIL-4). I will also show that an 150-bp region upstream of the first initiation site of germ-line γ1 RNA contains promoter and enhancer elements responsible for basal level expression and inducibility by phorbol 12-myristate 13-acetate (PMA) and synergy with IL-4 in an IgM+ B cell line, L10A6.2, and an IgG2a+B cell line, A20.3. The germ-line γ1 RNA is initiated at multiple start sites 5' to the tandem repeats of the γ1 switch (Sγ1) region. As is true for analogous RNAs transcribed from other unrearranged genes, the germ-line γ1 RNA has an I exon transcribed from the region 5' to the Sγ1 region.. The Iγ1 exon is spliced at a unique site to the Cγ1 gene. The germ-line γ1 RNA has an open-reading frame (ORF) that potentially encodes a small protein 48 amino acids in length. Elements located within the 150 bp region 5' to the first initiation site of germ-line γ1 RNA are necessary and sufficient to confer inducibility by PMA and synergy with IL-4 to a minimal thymidine kinase (TK) promoter in L10A6.2 cells but are not sufficient to confer this inducibility in A20.3 cells. Linker-scanning mutations demonstrated that these multiple elements function in a mutually dependent manner as indicated by the fact that mutation of any single element will decrease constitutive expression and inducibility by PMA and PMA plus IL-4. This 150-bp region contains several consensus sequences that bind to known or putative transcription factors, including a C/EBP binding site/IL-4 response element (in the promoter for Ia Aαkgene), four CACCC boxes, a PU box, a TGFβ inhibitory element (TIE), an interferon-αβ response element (αβIRE), and an AP-3 site. My results begin to provide a description of the mechanism of regulation of the accessibility of unrearranged germ-line Sγ1-Cγ1 gene. By activating the germ-line γ1 promoter, IL-4 induces transcription of germ-line γ1 RNA, thereby inducing accessibility of the Sγ1-Cγ1 gene. By inhibiting expression of the germ-line γ1 promoter, IFNγ and TGFβ down-regulate transcription of germ-line γ1 RNA, thus reducing the accessibility of the Sγ1-Cγ1 gene. My results also suggest that signaling via the antigen receptor on B cells may be involved in induction of switch to IgG1. Furthermore, this is the first case reported in which multiple functionally interdependent elements are needed to respond to PMA. Genes Immunoglobulin Heavy Chain Promoter Regions (Genetics) Regulatory Sequences Ribonucleic Acid Mice Germ Cells Molecular Probes Amino Acids, Peptides, and Proteins Animal Experimentation and Research Biological Factors Cells Genetic Phenomena
96	Role of the Intestinal Immune System in the Pathogenesis of Autoimmune Diabetes in the BB Rat Model of Type 1 Diabetes Mellitus Todd, Derrick James 11 June 2001 (has links) The intestine is the largest lymphoid organ in the body, challenged constantly by an enonnous quantity and diversity of antigens. Distinct from peripheral lymphocytes, intestinal lymphocytes have evolved unique mechanisms of tolerance and appear to govern mucosal processes such as "chronic physiologic inflammation" and oral tolerance. Failure of mucosal tolerance has been implicated in the pathogenesis of several diseases, including inflammatory bowel disease, celiac disease, and even autoimmune diabetes. One population of intestinal lymphocytes, intraepithelial lymphocytes (IELs), exists within the intestinal epithelium itself and remains poorly characterized. IELs respond to unique activation signals and appear to be in part responsible for the maintenance of epithelial integrity and mucosal tolerance. Type 1 diabetes is one of the most common chronic childhood illnesses and causes significant morbidity and mortality. Type 1 diabetes mellitus is an autoimmune disease that results from immune-mediated destruction of insulin-producing pancreatic beta cells and is characterized by an absolute insulin deficiency. Several animal models are used to study the immunopathogenesis of type 1 diabetes, including the BB rat and NOD mouse. BBDP rats spontaneously develop autoimmune diabetes mellitus and are severely deficient in peripheral T cells. BBDR rats do not spontaneously develop autoimmune diabetes, have nonnal numbers of peripheral T cells, and can be induced to become diabetic by injections of a cytotoxic anti-ART2a mAb and low doses of poly I:C. The cause of autoimmune diabetes in BB rats and humans is still unknown, but both genetic and environmental factors appear to participate. I hypothesize that one important class of environmental factors--diet and enteromicrobial agents--participates in this pathogenic process through the mediation of the gut immune system. In this dissertation, I report a new method for the isolation of rat IELs that is based on the selective removal of intestinal epithelial cells under conditions that leave the basement membrane undisturbed. The yield of rat IELs using this method is 5-10 fold greater than that reported for other methods. Morphological and phenotypic analyses demonstrate that the purified cell population is comprised of IELs and is not contaminated with lamina propria or Peyer's patch lymphocytes. Phenotypic analysis reveals 5 major subsets of IELs, including populations of γδ T and natural killer (NK) cells present at levels not previously detected. I also report that rat intraepithelial NK (IENK) and peripheral NK cells are similar in morphology, in their ability to lyse NK-sensitive targets, and in their ability to suppress a one-way mixed lymphocyte culture. In contrast, IENK cells differ from splenic NK cells phenotypically, and a substantial fraction of IENK cells appear to spontaneously secrete IL-4 and/or IFN-γ. I conclude that rat IELs harbor a large population of NKR-P1A+ CD3-cells that function as NK cells but display an activated phenotype and unusual cytokine profile that clearly distinguish them from splenic NK cells. Their phenotypic and functional characteristics suggest that these distinctive intraepithelial NK cells may participate in the regulation of mucosal immunity. I next demonstrate that, prior to diabetes, both BBDP and ART2a-depleted BBDR rats have a reduced total number of IELs and exhibit a selective deficiency of IENK cell number and function as compared to control BBDR rats. The deficiency of BBDP rat IELs can be corrected by engraftment of bone marrow from histocompatible WF donors. These results suggest 1) that the peripheral lymphopenia in BBDP rats extends to the IEL compartment, particularly to IENK cells, 2) that in BBDR rats the diabetes-inducing treatment depletes IELs, particularly IENK cells, and 3) that the defect in BBDP rat IELs is intrinsic to hematopoietic cells, not intestinal stromal cells. I also establish that, unlike BBDR and WF rats, BBDP rats are also deficient in γδTCR+IELs, a population of T cells that may play a role in normal mucosal tolerance. In addition, I report preliminary data supporting the hypothesis that systemic autoreactivity may be initiated in the intestine; peripheral autoreactive lymphocyte populations appear to emanate first from mesenteric lymph nodes that drain the intestine, and such cells may initiate a type 2 autoimmune phenomenon driven by IL-4. Collectively, my findings support the hypothesis that a failure of mucosal tolerance in BBDP rats, perhaps secondary to deficiencies in one or more IEL subpopulations, participates in the pathogenesis of autoimmune diabetes in these animals by activating peripheral autoreactive T cells. The nature of the autoimmune response in BB rats (driven by IL-4) appears to be distinct from that of NOD mice. Despite the differences between these two well-accepted animal models of autoimmune diabetes, until more is known about the pathogenesis of type 1 DM in humans, lessons learned from both the BB rat and NOD mouse continue to be of tremendous benefit to our understanding of human disease. Lymphocytes Diabetes Mellitus Type 1 Rats Inbred BB Killer Cells Natural Animal Experimentation and Research Cells Endocrine System Diseases Hemic and Immune Systems Immune System Diseases Nutritional and Metabolic Diseases
97	Analysis of Low Zone Tolerance in Normal and B Cell-Deficient Mice Baird, Allison Michelle 26 April 1996 (has links) This thesis investigates the role of B cells as antigen-specific antigen-presenting cells (APC) in self tolerance to low concentrations of soluble self proteins and in acquired tolerance to low doses of soluble foreign protein antigens. Experiments were performed in normal and B cell-deficient animals, and tolerance induction was measured by T cell proliferation assays. T cell proliferation was reduced in B cell-deficient mice, indicating that B cells may be involved in efficient activation of naive T cells in response to protein antigen both in vivo and in vitro. To study acquired tolerance induced by low doses of soluble foreign protein antigen, normal and B cell-deficient adult mice were injected intravenously with repeated low doses (10 μg) of deaggregated ovalbumin (OVA), and then challenged with OVA in complete Freund's adjuvant. In animals treated with deaggregated OVA, the in vitro proliferative responses of LN T cells to OVA were significantly reduced, and production of the Th1 cytokine, IFN-γ, in response to OVA was lost. This occurred in both normal and B cell-deficient treated animals, indicating that B cell antigen presentation was not required for this phenomenon. B cells were also unnecessary for self tolerance of T cells to the transgenic self antigen, hen egg lysozyme (HEL), in a transgenic mouse strain with very low serum lysozyme concentration. Partial low zone tolerance induced by deaggregated, low-dose OVA was selective for the Th1 response, as measured by in vitro proliferation and IL-2 and IFN-γ production, because antibody responses of normal mice to this T cell-dependent antigen were largely unaffected. Both treated and untreated animals produced equivalent titers of anti-OVA antibodies, predominantly of the IgG1 and IgG2b isotypes, following challenge with OVA in complete Freund's adjuvant. Tolerance to low levels of the transgenic HEL self protein in mice expressing different MHC molecules was also addressed. Transgenic mice that were H-2b/b in the class II region were not tolerant to the transgenic self protein, whereas transgenic mice of the H-2b/k were tolerant. Antigen-Presenting Cells B-Lymphocytes Immunity Cellular Mice Amino Acids, Peptides, and Proteins Animal Experimentation and Research Biological Factors Cells Hemic and Immune Systems
98	A Genetic Analysis of Genomic Stability in <em>Caenorhabditis Elegans</em>: A Dissertation Auclair, Melissa M. 18 September 2007 (has links) In humans, Bloom’s Syndrome is caused by a mutation of the RecQ helicase BLM. Patients with Bloom’s Syndrome exhibit a high amount of genomic instability which results in a high incidence of cancer. Though Bloom’s Syndrome has been intensively studied, there are still many questions about the function of BLM which need to be answered. While it is clear that loss of BLM increases genomic instability, the other effects of genomic instability on the organism aside from cancer such as a potential effect on aging, have yet to be elucidated. In Chapter II, I identify new phenotypes in the C. elegans ortholog of BLM, him-6. him-6 mutants have an increased rate of cell death, a mortal germ line phenotype, and an increased rate of mutations. Upon further examination of the mutator phenotype, it was determined that the increased rate of mutations was caused by small insertions and deletions. The mutator phenotype identified in him-6 mutants closely mimics the cellular phenotype seen in Bloom’s Syndrome cells. This indicates that HIM-6 may behave in a similar fashion to BLM. In addition to the mutator phenotype, it was found that loss of him-6causes a shortened life span. This may provide evidence that there is a link between genomic stability and aging. In Chapter III, I identify a new role for the transcription factor DAF-16. DAF-16 in C. elegans has been intensively studied and regulates a wide variety of pathways. In this chapter, I demonstrate via the well established unc-93 assay that loss of daf-16 causes a subtle mutator phenotype in C. elegans. This indicates that DAF-16 may play a role in suppression of spontaneous mutation. When I examined other classic genomic instability phenotypes, I found at 25°C, the number of progeny in the DAF-16 mutants was significantly reduced compared to wild type worms. Additionally, I demonstrate daf-16(mu86)has a cell death defect. This study identifies several new phenotypes caused by a loss of him-6. These phenotypes provide further evidence that loss of him-6 causes genomic instability. In addition, this study also demonstrates that him-6 has a shortened life span which may be due to genomic instability. Secondly, this study identifies a new role for DAF-16 in preventing the occurrence of spontaneous mutations. This may indicate a novel function for DAF-16 in maintaining genomic stability. Caenorhabditis elegans Proteins Bloom Syndrome Genomic Instability Longevity Transcription Factors Amino Acids, Peptides, and Proteins Animal Experimentation and Research Genetic Phenomena Nutritional and Metabolic Diseases
99	Cross-Reactive Memory CD4<sup>+</sup> and CD8<sup>+</sup> T Cells Alter the Immune Response to Heterologous Secondary Dengue Virus Infections in Mice: A Dissertation Beaumier, Coreen Michele 08 February 2008 (has links) Dengue virus (DENV) infects 50-100 million people worldwide every year and is the causative agent of dengue fever (DF) and the more severe dengue hemorrhagic fever/dengue shock syndrome (DHF/DSS). There are four genetically and immunologically distinct DENV serotypes (DENV-1, DENV-2, DENV-3, and DENV-4). Evidence suggests that an increased risk for DHF/DSS during secondary infection with a heterologous DENV serotype is due to an immunopathological response mediated by serotype-cross-reactive memory T cells from the primary infection. Furthermore, epidemiological studies have shown that the sequence of infection with different DENV serotypes affects disease severity. Though much has been learned from human studies, there exist uncontrollable variables that are intrinsic in this system such as genetic factors and unknown infection histories. These factors can skew experimental results, making interpretations difficult. Therefore, a murine model to study the immunologic aspects of sequential dengue infections would be an asset to the field of dengue research. To examine the effect of sequential infection with different DENV serotypes on the CD8+ T cell response, we immunized Balb/c mice with a primary DENV infection on day 0 and subsequently challenged with a heterologous secondary DENV infection on day 28. We tested all possible sequences of infection with the four serotypes. We analyzed the T cell response to two previously defined epitopes on the DENV E (Ld-restricted) and NS3 (Kd-restricted) proteins. Using ELISPOT and intracellular cytokine staining, we measured the frequency of T cells secreting IFNγ and TNFα in response to stimulation with these epitopes during three phases: acute primary, acute secondary, and the memory phase after primary infection. We found that the T cell response in heterologous secondary infections was higher in magnitude than the response in acute primary infection or during the memory phase. We also found that the hierarchy of epitope specific responses, as measured by IFNγ secretion, was influenced by the sequence of infections. The adoptive transfer of immune serum or immune splenocytes suggested that memory T cells from the primary infection responded to antigens from the secondary infection. In vitroexperiments with T cell lines generated from mice with primary and secondary DENV infections suggested the preferential expansion of crossreactive memory T cells. In testing all of the different possible sequences of infection, we observed that two different sequences of infection (e.g., DENV-2 followed by DENV-1 versus DENV-2 followed by DENV-3) resulted in differential CD8+ T cell responses to the NS3 peptide even though both secondary infection serotypes contain the identical peptide sequence. To investigate this phenomenon, we examined the role of CD4+ T cell help on the memory CD8+ T cell response. We found that CD4+ T cell cytokine responses differ depending on the sequence of infection. In addition, it was also shown that crossreactivities of the CD4+ T cell response are also sequence-dependent. Moreover, denguespecific memory CD4+ T cells can augment the secondary CD8+ T cell response. Taken together, we demonstrated that this serotype sequence-dependent phenomenon is the result of differential help provided by cross-reactive memory CD4+T cells. The findings in this novel mouse model support the hypothesis that both CD4+ and CD8+ serotype-cross-reactive memory T cells from a primary dengue virus infection alter the immune response during a heterologous secondary dengue virus infection. These data further elucidate potential mechanisms whereby the specific sequence of infection with different dengue virus serotypes influences disease outcomes in humans. Dengue Virus CD8-Positive T-Lymphocytes Immunologic Memory Cross Reactions CD4-Positive T-Lymphocytes Amino Acids, Peptides, and Proteins Animal Experimentation and Research Cells Hemic and Immune Systems Pathology Viruses
100	Distinct Permissive Pathways Mediate the Effects of Nerve Growth Factor and Lithium on Neurotensin/Neuromedin N Gene Expression in PC12 Cells: A Thesis Bullock, Bryant Paul 01 June 1992 (has links) This thesis examines the effects of nerve growth factor (NGF) and lithium on the regulation of neurotensin/neuromedin N (NT/N) gene expression in PC12 pheochromocytoma cells. In PC12 cells, the expression of the rat NT/N gene is strictly dependent on simultaneous exposure to combinations of NGF, glucocorticoids, activators of adenylate cyclase, and lithium. Transient transfection experiments indicated that a consensus AP-1 site located within the NT/N promoter is the principal target of NGF and lithium action. NGF rapidly, but transiently, induces the expression of several AP-1 genes in PC12 cells, suggesting that the effect of NGF on NT/N gene expression results from increased AP-1 activity. These results led to the prediction that the induction of NT/N gene expression should be rapid, transient and dependent on de novoprotein synthesis. These experiments also suggested that the NT/N gene is principally regulated through the initiation of transcription. However, post-transcriptional mechanisms may also be involved. Experiments in this thesis were designed to examine the regulatory mechanisms responsible for increased NT production in PC12 cells when treated with different inducer combinations and whether AP-1 factors could act as mediators in responses to NGF and lithium. Results described in this thesis indicate that the principal mechanism by which NGF and lithium regulate NT biosynthesis is by activating NT/N gene transcription. Comparison of NT/N mRNA, pro NT/N synthetic rates, proNT/N proteins and mature NT levels in induced PC12 cells, demonstrated that NGF and lithium had no effect on the translation of NT/N mRNA and had only a modest effect on post-translational processing. Nuclear run-on assays showed that NT/N transcription is transicntly activated in maximally induced cells. A rapid RNase protection assay was developed to examine both the kinetics of NT/N gene activation and whether activation requires newly synthesized proteins. Quantitation of nuclear NT/N precursor RNA. using a probe spanning the junction between exon onc and intron one, provides a sensitive measure of NT/N gene activity and by several criteria provides an accurate measure of NT/N transcription. When either NGF or lithium was combined with dexamethasone and forskolin, nuclear NT/N precursor RNA transiently accumulated, although each inducer displayed different kinetics, rapid and delayed, respectively. De novo protein synthesis was not required for activating NT/N transcription when NGF was used as the permissive agent, although newly synthesized proteins secm to be needed for subsequent down-regulation. The response to lithium displayed a marked requirement for new protein synthesis, consistent with the involvement of newly synthesized AP-1 factors. RNA blot analysis showed that lithium either alone or in combination with dexamethasone and forskolin induced c-jun and fra-1 gene expression with delayed kinetics, consistent with c-Jun/Fra-1 complexes mediating the effects of lithium on NT/N gene transcription. The pathway identified by lithium does not activate or require protein kinase C. This pathway is also active in neuronally-differentiated PC12 cells suggesting that it could be involved in the regulation of NT/N gcne exprcssion in the intact nervous system. These results and order of addition experiments demonstrate that NGF and lithium activate distinct pathways required for NT/N gene induction. Gene Expression Molecular Biology Lithium Nerve Growth Factors Neurotensin PC12 Cells Amino Acids, Peptides, and Proteins Animal Experimentation and Research Cells Enzymes and Coenzymes Genetic Phenomena Inorganic Chemicals Molecular Biology

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