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361	C. Elegans Metabolic Gene Regulatory Networks: A Dissertation Arda, H. Efsun 30 July 2010 (has links) In multicellular organisms, determining when and where genes will be expressed is critical for their development and physiology. Transcription factors (TFs) are major specifiers of differential gene expression. By establishing physical contacts with the regulatory elements of their target genes, TFs often determine whether the target genes will be expressed or not. These physical and/or regulatory TF-DNA interactions can be modeled into gene regulatory networks (GRNs), which provide a systems-level view of differential gene expression. Thus far, much of the GRN delineation efforts focused on metazoan development, whereas the organization of GRNs that pertain to systems physiology remains mostly unexplored. My work has focused on delineating the first gene regulatory network of the nematode Caenorhabditis elegans metabolic genes, and investigating how this network relates to the energy homeostasis of the nematode. The resulting metabolic GRN consists of ~70 metabolic genes, 100 TFs and more than 500 protein–DNA interactions. It also includes novel protein-protein interactions involving the metabolic transcriptional cofactor MDT-15 and several TFs that occur in the metabolic GRN. On a global level, we found that the metabolic GRN is enriched for nuclear hormone receptors (NHRs). NHRs form a special class of TFs that can interact with diffusible biomolecules and are well-known regulators of lipid metabolism in other organisms, including humans. Interestingly, NHRs comprise the largest family of TFs in nematodes; the C. elegans genome encodes 284 NHRs, most of which are uncharacterized. In our study, we show that the C. elegans NHRs that we retrieved in the metabolic GRN organize into network modules, and that most of these NHRs function to maintain lipid homeostasis in the nematode. Network modularity has been proposed to facilitate rapid and robust changes in gene expression. Our results suggest that the C. elegans metabolic GRN may have evolved by combining NHR family expansion with the specific modular wiring of NHRs to enable the rapid adaptation of the animal to different environmental cues. Caenorhabditis elegans Caenorhabditis elegans Proteins Gene Regulatory Networks Gene Expression Regulation Receptors Cytoplasmic and Nuclear Amino Acids, Peptides, and Proteins Animal Experimentation and Research Genetic Phenomena Genetics and Genomics
362	A Novel Motif in HIV-1 Nef that Regulates MIP-1β Chemokine Release in Macrophages: A Dissertation Dai, Lue 17 June 2010 (has links) Nef is an accessory protein encoded by human and simian immunodeficiency viruses (HIV and SIV), and is critical for viral pathogenicity in vivo.The structure of Nef has been resolved and the major cellular activities of Nef are generally described as down-regulation of cell surface molecules, enhancement of virus infectivity and regulation of cell signaling and activation. Macrophages represent a key target of HIV-1 infection and may contribute significantly to viral pathogenesis by facilitating viral propagation, maintaining a viral reservoir and regulating viral replication. During HIV-1 infection, various cytokines and chemokines are induced for viral advantages more than for host defense. We have previously demonstrated that HIV-1 Nef regulates the release of chemokines, MIP-1α and MIP-1ß, from infected macrophages and have proposed that this may enhance conditions for viral replication by promoting recruitment of substrate lymphocytes to sites of infection (1). However, the molecular basis for this Nef activity remains to be defined. The main goals of this thesis are to identify the functional motif in Nef that is responsible for chemokine induction in macrophages and to elucidate the relevance of this motif to other Nef functions. Using a mutagenesis approach, we have eventually identified a novel motif (KEK) that regulates chemokine production in infected macrophages after we excluded several previously described Nef motifs. This motif is conserved in both HIV-1 and SIV Nef proteins. Mutations in this domain abrogated MIP-1ß induction as well as the Nef-dependent release of other secretory factors by macrophages. However, disruption of this motif did not affect other Nef-ascribed activities such as CD4 and MHC-I down-regulation. In addition, we have determined the involvement of viral Env proteins in Nef-induced chemokine production. Distinct signaling pathways that regulate chemokine release in macrophage will also be described. Finally, several possible roles of the KEK motif are proposed and some preliminary results of co-immunoprecipitation experiments will be presented which aim to characterize cellular proteins involved in chemokine regulation by Nef. Collectively, our studies reveal a specific determinant within Nef that is critical for chemokine release by Nef. Identification of this motif paves the way for future studies to explore the molecular machanisms of Nef-regulated cell signaling pathways. Such knowledge may point to new therapeutic strategies that interrupt Nef function and limit the course of HIV-1 infection. nef Gene Products Human Immunodeficiency Virus Genes nef Chemokine CCL3 Chemokine CCL4 Amino Acids, Peptides, and Proteins Biological Factors Cells Genetic Phenomena Immunology and Infectious Disease Life Sciences Medicine and Health Sciences Pathology Viruses
363	Insulin Receptor Substrate-2 (IRS-2): A Novel Hypoxia-Responsive Gene in Breast Cancer: A Dissertation Mardilovich, Katerina 11 May 2011 (has links) Breast cancer is the most common malignancy among women in the U.S. While many successful treatments exist for primary breast cancer, very few are available for patients with metastatic disease. The purpose of this study was to understand the role of Insulin Receptor Subtrate-2 (IRS-2) in breast cancer metastasis. IRS-2 belongs to the IRS family of cytoplasmic adaptor proteins that mediate signaling from cell surface receptors, many of which have been implicated in cancer. Although the IRS proteins are highly homologous in structure and have some complementary functions, growing evidence supports that the IRS proteins have unique roles in cancer. IRS-1 has been shown to promote tumor cell proliferation, while IRS-2 has been positively associated with cancer cell invasion, glycolysis and tumor metastasis. In the current work, we identified IRS-2 as a novel hypoxia-responsive gene in breast carcinoma cells. In contrast, IRS-1 expression does not increase in response to hypoxia, supporting the notion of their non-overlapping functions. Hypoxia promotes the adaptation and resistance of cancer cells to chemo- and radiation therapy, and also promotes tumor cell survival, invasion and metastasis by selecting for aggressive tumor cells that can survive under stressful low oxygen conditions. We have shown that IRS-2 upregulation in response to hypoxia promotes Akt signaling and tumor cell viability and invasion. We identified a cell context-dependent role for Hypoxia Inducible Factor (HIF) in the regulation of IRS-2 expression in hypoxia, with HIF-2 playing a more dominant role than HIF-1. We also demonstrate that binding of Snail, a regulator of the EMT, to the IRS-2 promoter keeps the chromatin in an open conformation that is permissive for HIF-dependent transcription of IRS-2 in hypoxia. IRS-2 is not upregulated by hypoxia in well-differentiated epithelial-like carcinoma cells that do not express Snail, implicating IRS-2 gene expression as part of the EMT programming. In summary, we have identified an endogenous mechanism by which cancer cells can shift the balance of IRS-1 and IRS-2 to favor IRS-2 expression and function, which promotes survival, invasion, and ultimately metastasis. Understanding the mechanism of IRS-2 regulation by hypoxia may reveal new therapeutic targets for metastatic breast cancer. Breast Neoplasms Insulin Receptor Substrate Proteins Cell Hypoxia Hypoxia-Inducible Factor 1 Amino Acids, Peptides, and Proteins Cancer Biology Cells Neoplasms Skin and Connective Tissue Diseases
364	Contribution of WFS1 to Pancreatic Beta Cell Survival and Adaptive Alterations in WFS1 Deficiency: A Dissertation O'Sullivan-Murphy, Bryan M. 20 April 2012 (has links) Diabetes mellitus comprises a cohort of genetic and metabolic diseases which are characterized by the hallmark symptom of hyperglycemia. Diabetic subtypes are based on their pathogenetic origins: the most prevalent subtypes are the autoimmune-mediated type 1 diabetes mellitus (T1DM) and the metabolic disease of type 2 diabetes mellitus (T2DM). Genetic factors are major contributory aspects to diabetes development, particularly in T2DM where there is close to 80% concordance rates between monozygotic twins. However, the functional state of the pancreatic β cell is of paramount importance to the development of diabetes. Perturbations that lead to β cell dysfunction impair insulin production and secretion and precede diabetes onset. The endoplasmic reticulum (ER) is a subcellular organelle network of tubes and cisternae with multifaceted roles in cellular metabolism. Alterations to ER function such as those begotten by the accumulation of misfolded and unfolded ER client proteins upset the ER homeostatic balance, leading to a condition termed ER stress. Subsequent sensing of ER stress by three ER transmembrane proteins, initiates an adaptive reaction to alleviate ER stress: this is known as the unfolded protein response (UPR). Divergent cascades of the UPR attempt to mitigate ER stress and restore ER homeostasis: Failing that, the UPR initiates pro-apoptotic pathways. The demand of insulin production on the β cell necessitates the presence of a highly functional ER. However, the consequence of dependence on the ER for insulin synthesis and secretion portends disaster for the functional state of the β cell. Disturbances to the ER that elicit ER stress and UPR activation causes β cell dysfunction and may lead to apoptosis. There are numerous well-characterized models of ER stress-mediated diabetes, including genetic mutations in UPR transducers and insulin. Recently, polymorphisms in Wolfram syndrome 1 (WFS1), an ER transmembrane protein involved in the UPR, were suggested to contribute to T2DM risk. In this thesis, one of the highlighted WFS1 polymorphism, H611R, was examined to identify its contribution to β cell function and viability, and hence, diabetes risk. It was revealed that augmentation of WFS1 expression increased insulin secretion and cellular content. In addition, WFS1 protected β cells against ER stress-mediated dysfunction, with a more pronounced effect in the WFS1-R611 protective allele. Subsequent gene expression analysis identified netrin-1 as a WFS1-induced survival factor. As a contributory factor to diabetes progression, ER stress and UPR are potential drug and biomarker targets. In this dissertation, a novel UPR-regulating microRNA (miRNA) family was uncovered in ER stressed, WFS1-deficient islets. These miRNAs, the miR-29 family, are induced in WFS1 -/- islets as a possible adaptive alteration to chronic ER stress conditions, and indirectly decreases the expression of UPR transducers, while directly targeting downstream ER stress-related pro-apoptotic factors. Collectively, this work extends the function of WFS1 as a protective factor in the pancreatic β cell through the induction of netrin-1 signaling. Additionally, it further strengthens the role of miRNA as regulatory members of the UPR which contribute to cell survival. Diabetes Mellitus Membrane Proteins Insulin-Secreting Cells Endoplasmic Reticulum Amino Acids, Peptides, and Proteins Cell and Developmental Biology Cells Cellular and Molecular Physiology Endocrine System Diseases Immune System Diseases Nutritional and Metabolic Diseases
365	The Role of Adaptor Protein Complex-3 Delta-Mediated HIV-1 Gag Trafficking in HIV-1 Replication: A Dissertation Kim, Adonia Lee 18 May 2012 (has links) The process of HIV-1 particle production is a multi-step process directed by the viral structural protein Gag. As Gag is the only viral protein required to form virus-like particles, it presents a viable target for anti-viral therapeutics of which there are currently none. Although the functions of Gag during the particle assembly process have been well characterized, one of the least known parts of the assembly process is how Gag is targeted to the site of virus assembly. Two main virus assembly sites have been identified in cells that support HIV-1 replication: the plasma membrane or multivesicular bodies (MVBs). However the mechanism by which Gag is targeted to either of these sites remains unknown. The δ subunit of Adaptor Protein Complex 3 has previously been identified as a cellular co-factor for HIV-1 Gag and was reported to mediate Gag trafficking to MVBs, providing a mechanism for Gag targeting to this assembly site. Additionally, AP-3δ was reported to be required for HIV-1 production, suggesting that Gag to MVB targeting is also required for HIV-1 production. The work presented in this thesis further investigates the role of AP-3δ in Gag trafficking to MVBs and its role in HIV-1 production in previously unexplored host environments. Through the use of RNA interference-mediated depletion of AP-3δ, we determined that AP-3δ is dispensible for virus replication in infected HeLa cells, chronically infected HeLa-LAV cells and infected primary human monocyte-derived macrophages. We concomitantly disrupted AP-3 function by disrupting its association with membranes and observed no effect on virus production. Collectively, these results demonstrate that AP-3δ is not required for HIV-1 replication. However, AP-3δ was demonstrated to be required for Gag targeting to MVBs thus presenting a new model for the function of AP-3δ in the context of HIV-1 replication. Adaptor Protein Complex 3 gag Gene Products Human Immunodeficiency Virus Adaptor Protein Complex delta Subunits Multivesicular Bodies Amino Acids, Peptides, and Proteins Cells Genetic Phenomena Microbiology Pathology Therapeutics Viruses
366	The Subtype Specific and Cross-Reactive T Cell Responses to Influenza Viruses in Humans: A Dissertation Babon, Jenny Aurielle B. 03 April 2012 (has links) Human influenza is a contagious respiratory disease resulting in substantial morbidity and mortality worldwide. With the recent cases of avian influenza infections in humans and the heightened concern for an influenza pandemic arising from these infections, it is essential to understand host responses that would confer protective immunity to influenza. The cell-mediated immune responses to influenza virus play an important role during influenza infection. To analyze the specificity and diversity of memory T-cell responses, we performed a genome-wide screening of T cell epitopes to influenza A virus in healthy adult donors. We identified a total of 83 peptides, 54 of them novel, to which specific T cells were detectable in interferon-(IFN-γ) enzyme-linked immunosorbent spot assays (ELISPOT) using peripheral blood mononuclear cells (PBMCs) from four healthy adult donors. We found that among 11 influenza viral proteins, hemagglutinin (HA) and matrix protein 1 (M1) had more T-cell epitopes than other viral proteins. The donors were not previously exposed to H5N1 subtype, but we detected H5 HA T cell responses in two of the four donors. To confirm that HA is a major target of T cell responses we also analyzed H1 and H3 HA-specific T-cell responses using PBMC of additional 30 adult donors. Fifteen out of thirty donors gave a positive response to H3 HA peptides, whereas five of thirty donors gave a positive response to H1 HA peptides. Because we detected T cell responses to the H5 HA peptides in donors without prior exposure to H5N1 subtype, we asked if cross-reactive T cells to H5 HA peptides can be attributed to a prior exposure to H2N2 subtype, the closest HA to the H5 based on their phylogeny. We compared younger donors who have no prior exposure to H2N2 subtype and older donors who were likely to be exposed to H2N2 subtype, and both groups responded H2N2 peptides at similar level, suggesting that memory T cells cross-reactive to H5 HA peptides can be generated by prior exposure to the H1N1 and H3N2 subtypes, and the exposure to H2N2 subtype is not necessary. We subsequently identified a CD4+ T cell epitope that lies in the fusion peptide of the HA. This epitope is well conserved in all 16 subtypes of HA of influenza A and the HA of the influenza B virus. A CD4+ T cell line specific to this epitope recognizes target cells infected with various influenza A viruses including seasonal H1N1 and H3N2, a reassortant H2N1, the 2009 pandemic H1N1, H5N1 and influenza B virus in cytotoxicity assays and intracellular cytokine staining assays. Individuals who have the HLA-DRB1*09 allele have ex vivo IFN-γ responses to this epitope peptide in ELISPOT. Although natural infection or standard vaccination may not induce strong T and B cell responses to this very conserved epitope in the fusion peptide, it may be possible to develop a vaccination strategy to induce these CD4+ T cells which are cross-reactive to both influenza A and B viruses. Influenza A virus Influenza Human Cross Reactions Immunity Cellular T-Lymphocytes Amino Acids, Peptides, and Proteins Biological Factors Cells Hemic and Immune Systems Immunology and Infectious Disease Influenza Humans Respiratory Tract Diseases Virus Diseases Viruses
367	Mutations in the <em>vpu</em> and <em>env</em> Genes of HIV-1 Can Adversely Impact Infectivity: A Dissertation Richards, Kathryn H. 12 May 2008 (has links) The Human Immunodeficiency Virus (HIV) is able to infect CD4+ T cells as well as macrophages. Macrophage-tropism has been linked to determinants in the envelope of HIV. These determinants allow envelopes to exploit low levels of CD4 for infection. Macrophages are an important reservoir of virus, especially during chronic infection, and are likely responsible for the bulk of virus produced after CD4+T cells have declined. Viral factors that may impact the ability to infect macrophages are worth studying because this cell type is so important in infection. It was previously reported that the macrophage-tropic primary isolate AD8 was vpu-independent. The molecular clone YU-2, derived from brain tissue without culture, was also reported to be macrophage-tropic despite having a mutation in the vpu start codon. It was therefore possible that vpu-independent envelopes could evolve in vivo. To examine this possibility, I constructed chimeras containing wild type or defective vpu start codons, and gp160 sequences from AD8, YU-2 or SF162 (a vpu-dependent control). I also used full length AD8 and YU-2 with wild type or defective vpu start codons. I infected macrophages with equal amounts of virus, and measured viral output over two weeks. Viruses with defective vpu start codons were released to lower levels compared to their wild type vpucounterparts. In contrast to previous reports, the AD8 envelope is not vpu-independent for replication in macrophages. The YU-2 envelope is also not vpu-independent. Macrophage-tropic envelopes from late stages of infection can be sensitive to antibodies that bind the CD4 binding site on gp120, implying that macrophage-tropic envelopes have more exposed CD4 binding sites. Neutralizing antibodies may act as modulators of macrophage-tropism over the course of infection. Using chimeras containing gp120 sequences derived from the PBMC of four HIV+patients, I examined the capacity for envelopes to infect macrophages. Three patients (MM1, 4, and 8) had macrophage-tropic envelopes before and after developing autologous neutralizing antibodies. Three patients (MM1, 4, and 23) developed heterologous antibodies against IIIB, an easily neutralized T-cell line adapted strain of HIV-1. This data indicates that macrophage-tropism in these patients is not modulated by the presence of neutralizing antibodies. The macrophage-tropism of envelopes tends to segregate depending on the tissue origin of the virus. Envelopes from two separate tissues from the same patient exhibit very different infectivity characteristics. The B33 envelope, from brain tissue, is very infectious and is macrophage-tropic, while the LN40 envelope, from lymph node tissue, is weakly infectious and is not macrophage-tropic. Replacing the entire gp41 of LN40 with that of B33 restores some infectivity to LN40. The cytoplasmic domain of gp41 contains many motifs important for assembly and infectivity. To examine which motifs are responsible for the weak infectivity of LN40, I made chimeras of gp41, as well as point mutations in gp41. The LN40 chimera containing the entire gp41 of B33 restored the most infectivity. Point mutations in the palmitoylation site, Pr55gagbinding region, and dileucine motif at the C-terminus also restored infectivity when combined. Determinants in the gp41 cytoplasmic domain are responsible for the weak infectivity of LN40; however, it is possible that there are contributing determinants in gp120, such as the ability to use low levels of CD4. Here, I examined how changes in the vpu and env genes of HIV-1 can impact infectivity, especially infectivity of macrophages. Changes that adversely impact the virus’ ability to infect macrophages may also impact the overall course of disease. However, the data here show that retaining the ability to infect, and replicate in, macrophages give HIV an advantage. I speculate that retaining the ability to infect macrophages gives the virus a reservoir for later in disease, when CD4+ T cells have been depleted, as well as way of avoiding neutralizing antibodies. This work further defines the importance of macrophages in HIV-1 infectivity and disease. HIV-1 HIV Infections Tropism Viral Envelope Proteins Macrophages Human Immunodeficiency Virus Proteins Viral Regulatory and Accessory Proteins Virus Replication Amino Acids, Peptides, and Proteins Cells Genetic Phenomena Hemic and Immune Systems Viruses
368	Role of Endoplasmic Reticulum Stress Response Signaling in T Cells: A Dissertation Pino, Steven C. 08 July 2008 (has links) T cells play a central role in cellular-mediated immunity and must become activated to participate as effector cells in the immune response. The activation process is highly intricate and involves stimulation of a number of downstream signaling pathways enabling T cells to proliferate and produce cytokines that are vital for proper effector function. This increase in protein production and protein folding activity adds to the normal physiological strain on cellular machinery. One cellular compartment that has generated a mechanism to mitigate the stress induced by increased protein production is the endoplasmic reticulum (ER). In general, an increase in cellular production of proteins that overwhelms a cell’s protein folding capability can alter ER homeostasis and lead to ER stress. To counteract this stress, an adaptive cellular mechanism known as the ER stress response (ERSR) is initiated. The ERSR allows a cell to cope with normal physiological stress within the ER caused by increased protein translation. In this dissertation, we show that in vitro and in vivoT cell activation involving T cell receptor (TCR) ligation in the presence of costimulation initiates the physiological ERSR. Interestingly, the ERSR was also activated in T cells exposed only to TCR ligation, a treatment known to induce the ‘non-responsive’ states of anergy and tolerance. We further identified a key component of the downstream TCR signaling pathway, protein kinase C (PKC), as an initiator of physiological ERSR signaling, thus revealing a previously unknown role for this serine/threonine protein kinase in T cells. Therefore, induction of the physiological ERSR through PKC signaling may be an important ‘preparatory’ mechanism initiated during the early activation phase of T cells. If ER stress is persistent and ER homeostasis is not reestablished, physiological ER stress becomes pathological and initiates cellular death pathways through ER stress-induced apoptotic signaling. We further present data demonstrating that absence of functional Gimap5, a putative GTPase implicated to play a role in TCR signaling and maintenance of overall T cell homeostasis, leads to pathological ER stress and apoptosis. Using the BioBreeding diabetes-prone (BBDP) rat, a model for type 1 diabetes (T1D), we link pathological ER stress and ER stress-induced apoptotic signaling to the observed T cell lymphopenic phenotype of the animal. By depleting the ER stress apoptotic factor CHOP with siRNA, we were able to protect Gimap5-/-BBDP rat T cells from ER stress-induced death. These findings indicate a direct relationship between Gimap5 and maintenance of ER homeostasis for T cell survival. Overall, our findings suggest that the ERSR is activated by physiological and pathological conditions that disrupt T cell homeostasis. TCR signaling that leads to PKC activation initiates a physiological ERSR, perhaps in preparation for a T cell response to antigen. In addition, we also describe an example of pathological ERSR induction in T cells. Namely, we report that the absence of functional Gimap5 protein in T cells causes CHOP-dependent ER stress-induced apoptosis, perhaps initiated by deregulation of TCR signaling. This indicates a dual role for TCR signaling and regulation in the initiation of both the physiological and pathological ERSR. Future research that provides insights into the molecular mechanisms that govern ERSR induction in TCR signaling and regulation may lead to development of therapeutic modalities for treatment of immune-mediated diseases such as T1D. Endoplasmic Reticulum Signal Transduction T-Lymphocytes Protein Kinase C Receptors Antigen T-Cell Apoptosis Transcription Factor CHOP Amino Acids, Peptides, and Proteins Biological Factors Cells Enzymes and Coenzymes Hemic and Immune Systems Therapeutics
369	Development of a Substrate with Photo-Modulatable Rigidity for Probing Spatial and Temporal Responses of Cells to Mechanical Signals: A Dissertation Frey, Margo Tilley 01 July 2008 (has links) Topographical and mechanical properties of adhesive substrates provide important biological cues that affect cell spreading, migration, growth, and differentiation. The phenomenon has led to the increased use of topographically patterned and flexible substrates in studying cultured cells. However, these studies may be complicated by various limitations. For example, the effects of ligand distribution and porosity are affected by topographical features of 3D biological constructs. Similarly, many studies of mechanical cues are compounded with cellular deformation from external forces, or limited by comparative studies of separate cells on different substrates. Furthermore, understanding cell responses to mechanical input is dependent upon reliable measurements of mechanical properties. This work addresses each of these issues. To determine how substrate topography and focal adhesion kinase (FAK) affect cell shape and movement, I studied FAK-null (FAK -/-) and wild type mouse 3T3 fibroblasts on chemically identical polystyrene substrates with either flat surfaces or micron-sized pillars, I found that, compared to cells on flat surfaces, those on pillar substrates showed a more branched shape, an increased linear speed, and a decreased directional stability, which were dependent on both myosin-II and FAK. To study the dynamic responses to changes in substrate stiffness without other confounding effects, I developed a UV-modulatable substrate that softens upon UV irradiation. As atomic force microscopy (AFM) proved inadequate to detect microscale changes in stiffness, I first developed and validated a microsphere indentation method that is compatible with fluorescence microscopy. The results obtained with this method were comparable to those obtained with AFM. The UV-modulatable substrates softened by ~20-30% with an intensity of irradiation that has no detectable effect on 3T3 cells on control surfaces. Cells responded to global softening of the substrate with an initial retraction followed by a gradual reduction in spread area. Precise spatial control of softening is also possible - while there was little response to posterior softening, anterior softening elicited a pronounced retraction and either a reversal of cell polarity or a significant decrease in spread area if the cells move into the softened region. In conclusion, these techniques provide advances in gaining mechanistic insight into cellular responses to topographical and mechanical cues. Additionally, there are various other potential applications of the novel UV-softening substrate, particularly in regenerative medicine and tissue engineering. Cell Adhesion Focal Adhesion Protein-Tyrosine Kinases Cell Culture Techniques 3T3 Cells Biocompatible Materials Cell Aggregation Cell Movement Myosin Type II Mice Amino Acids, Peptides, and Proteins Anatomy Animal Experimentation and Research Cells Enzymes and Coenzymes Investigative Techniques
370	Regulation of DNA Replication Origins in Fission Yeast: A Dissertation Kommajosyula, Naveen 03 August 2009 (has links) Cells need to complete DNA replication in a timely and error-free manner. To ensure that replication is completed efficiently and in a finite amount of time, cells regulate origin firing. To prevent any errors from being transmitted to the next generation, cells have the checkpoint mechanism. The S-phase DNA damage slows replication to allow the cell to repair the damage. The mechanism of replication slowing by the checkpoint was not clear in fission yeast, Schizosaccharomyces pombe, at the start of my thesis. The downstream targets of the DNA damage checkpoint in fission yeast were also unclear. I worked on identifying the downstream targets for the checkpoint by studying if Cdc25, a phosphatase, is a target of the checkpoint. Work from our lab has shown that origin firing is stochastic in fission yeast. Origins are also known to be inefficient. Inefficient origins firing stochastically would lead to large stretches of chromosome where no origins may fire randomly leading to long replication times, an issue called the random gap problem. However, cells do not take a long time to complete replication and the process of replication itself is efficient. I focused on understanding the mechanism by which cells complete replication and avoid the random gap problem by attempting to measure the firing efficiency of late origins. Genome-wide origin studies in fission yeast have identified several hundred origins. However, the resolution of these studies can be improved upon. I began a genome-wide origin mapping study using deep sequencing to identify origins at a greater resolution compared to the previous studies. We have extended our origin search to two other Schizosaccharomyces species- S. octosporus and S. japonicus.There have been no origin mapping studies on these fission yeasts and identifying origins in these species will advance the field of replication. My thesis research shows that Cdc25 is not a target of the S-phase DNA damage checkpoint. I showed that DNA damage checkpoint does not target Cdc2-Y15 to slow replication. Based on my preliminary observation, origin firing might be inhibited by the DNA damage checkpoint as a way to slow replication. My efforts to measure the firing efficiency of a late replicating sequence were hindered by potentially unidentified inefficient origins firing at a low rate and replicating the region being studied. Studying the origin efficiency was maybe further complicated by neighboring origins being able to passively replicate the region. To identify origins in recently sequenced Schizosaccharomyces species, we initiated the genome-wide origin mapping. The mapping was also done on S. pombe to identify inefficient origins not mapped by other mapping studies. My work shows that deep sequencing can be used to map origins in other species and provides a powerful tool for origin studies. DNA Replication Schizosaccharomyces pombe Proteins Protein-Serine-Threonine Kinases Replication Origin Cell Cycle Proteins CDC2 Protein Kinase Gene Expression Regulation Fungal DNA Damage Amino Acids, Peptides, and Proteins Enzymes and Coenzymes Fungi Genetic Phenomena

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