Global ETD Search

91	Characterizing the Molecular Switch from Proteasomes to Autophagy in Aggresome Processing Nanduri, Priyaanka January 2015 (has links) <p>Cells thrive on sustaining order and balance to maintain proper homeostatic functions. However, the primary machinery involved in protein quality control including chaperones, ubiquitin proteasome system, and autophagy all decline in function and expression with age. Failures in protein quality control lead to enhanced protein misfolding and aggregation. Efficient elimination of misfolded proteins by the proteasome system is critical for cellular proteostasis. However, inadequate proteasome capacity can lead to aberrant aggregation of misfolded proteins and inclusion body formation, which is a hallmark of numerous neurodegenerative diseases. Due to the post-mitotic nature of neurons, they are more susceptible to the collapse in proteostasis correlated with age. </p><p> </p><p>Here, we propose a cell based model of aggresome clearance using a reversible proteasome inhibitor, MG132, to identify the precise molecular machinery involved in proper processing of inclusions. It is known that once misfolded proteins are aggregated, the proteasome system can no longer degrade them. Furthermore, the continuous accumulation of aggregates often leads to aggresome formation, which results in amalgamated inclusion bodies that are simply too large for autophagosomes to engulf and degrade. Although, studies have shown that aggresomes can eventually be cleared by autophagy, the molecular mechanisms underlying this process remain unclear. </p><p>Our research reveals that regardless of impaired proteolysis, proteasomes can still stimulate autophagy-dependent aggresome clearance by producing unanchored lysine (K)63-linked ubiquitin chains via the deubiquitinating enzyme Poh1. Unanchored ubiquitin chains activate ubiquitin-binding histone deacetylase 6, which mediates actin-dependent disassembly of aggresomes. This crucial de-aggregation of aggresomes allows autophagosomes to efficiently engulf and eliminate the protein aggregates. Interestingly, the canonical function of Poh1 involves the cleavage of ubiquitin chains en bloc from proteasomal substrates prior to their degradation by the 20S core, which requires intact 26S proteasomes. In contrast, here we present evidence that during aggresome clearance, 20S proteasomes dissociate from protein aggregates, while Poh1 and selective subunits of 19S proteasomes are retained as an efficient K63 deubiquitinating enzyme complex. The dissociation of 20S proteasome components requires the molecular chaperone Hsp90. Hsp90 inhibition suppresses 26S proteasome remodeling, unanchored ubiquitin chain production, and aggresome clearance. Ultimately, we hope to apply these molecular markers of inclusion body processing to identify the underlying lesion in aggregate prone neurodegenerative disease.</p> / Dissertation Pharmacology Neurosciences Aging Autophagy Histone Deacetylase 6 Neurodegenerative Disease Proteasome Protein aggregation Ubiquitin
92	Histone Deacetylase Inhibitor MS-275 Inhibits Neuroblastoma Cell Growth by Inducing Cell Cycle Arrest, Apoptosis, Differentiation and by Targeting its Tumor Stem Cell Population Tsui, Micky Ka Hon 16 February 2010 (has links) Objective: MS-275, a phase trialed histone deacetylase inhibitor will be characterized for its ability reduce neuroblastoma (NB) viability and to target the tumor stem cell (TSC) population in neuroblastoma. Methods: Ability of MS-275 to reduce NB growth is characterized using a tumorigenic NB N-type cell line that has high differentiation potential. TSC enriched side population from NB and a reference teratocarcinoma cell line was analyzed as a model of TSC. The potential of MS-275 to modulate functional characteristics and markers of TSC was also investigated. Results: MS-275 induces a G1 cell cycle arrest, the intrinsic apoptosis pathway in NB and can potentially differentiate NB into a more terminal phenotype. NB TSC-like population is reduced following MS-275 treatment by the targeting of their self-renewal and drug pumping ability. Conclusions: By targeting both the NB and its TSC population, MS-275 has therapeutic potential for neuroblastoma. This warrants further in-vivo investigations. Cancer Histone Deacetylase Inhibitor Neuroblastoma cancer stem cell side population 0992
93	Role of TG Lipases, Arylacetamide Deacetylase and Triacylglycerol Hydrolase, in Hepatitis C Virus Life Cycle Nourbakhsh, Mahra Unknown Date No description available. Hepatitis C Virus Arylacetamide Deacetylase Triacylglycerol Hydrolase Triacylglycerol Very Low Density Lipoprotein Lipase
94	Histone Deacetylase Inhibitor MS-275 Inhibits Neuroblastoma Cell Growth by Inducing Cell Cycle Arrest, Apoptosis, Differentiation and by Targeting its Tumor Stem Cell Population Tsui, Micky Ka Hon 16 February 2010 (has links) Objective: MS-275, a phase trialed histone deacetylase inhibitor will be characterized for its ability reduce neuroblastoma (NB) viability and to target the tumor stem cell (TSC) population in neuroblastoma. Methods: Ability of MS-275 to reduce NB growth is characterized using a tumorigenic NB N-type cell line that has high differentiation potential. TSC enriched side population from NB and a reference teratocarcinoma cell line was analyzed as a model of TSC. The potential of MS-275 to modulate functional characteristics and markers of TSC was also investigated. Results: MS-275 induces a G1 cell cycle arrest, the intrinsic apoptosis pathway in NB and can potentially differentiate NB into a more terminal phenotype. NB TSC-like population is reduced following MS-275 treatment by the targeting of their self-renewal and drug pumping ability. Conclusions: By targeting both the NB and its TSC population, MS-275 has therapeutic potential for neuroblastoma. This warrants further in-vivo investigations. Cancer Histone Deacetylase Inhibitor Neuroblastoma cancer stem cell side population 0992
95	New insights into targeting the androgen receptor for cancer therapy: from selective delivery of gold nanoparticles and histone deacetylase inhibitors, to potent antagonists and inverse agonists Gryder, Berkley Eric 12 January 2015 (has links) Cancer is the second leading cause of death in the United States (more than half a million people each year), and even with billions of dollars in medical effort patients are rarely cured. This dissertation research is devoted to meeting this medical need by providing new cancer therapeutics that are more potent and safer than current chemotherapies. This is achieved by using two state of the art anticancer “warheads”: 1) gold nanoparticle (AuNP) technology and 2) a new class of epigenetic anticancer small molecules, histone deacetylase inhibitors (HDACi). These warheads are then selectively delivered to cancer cells via “homing devices” targeted to receptors that are overexpressed in the cancers. This work primarily focuses on the androgen receptor (AR) to target prostate cancer. The 1st chapter sets the stage, providing scientific rationale and background for the central hypothesis: small molecules that engage the AR can, upon conjugation to a therapeutic agent, enable selective delivery of that agent to prostate cancer cells. Chapter 2 delves into the structural molecular biology of the androgen receptor. There is a survey of the crystallographic data for all nuclear receptors, providing structural information which is used to build AR homology models for antagonist and inverse agonist modes of ligand binding. These models are used to design AR targeting ligands (Chapters 3, 5, 6 and 7). The application of the targeting technology is illustrated by attaching them to AuNPs for selective delivery to prostate cancer cells (Chapter 3). Next, in order to appreciate the importance of using targeting agents in HDACi cancer therapeutics, we reviewed this recently emerged field in Chapter 4. In this chapter we argue that the failure of HDACi in solid tumors, despite more than 500 clinical trials in the last decade, is primarily due to an inability of these small molecules to accumulate at effective concentrations in the cancer. We provide an analysis of the paradigms being pursued to overcome this barrier, including HDAC isoform selectivity, localized administration, and targeting cap groups to achieve selective tissue and cell type distribution. In Chapter 5, this last approach (targeting cap groups, or a “homing device”) is illustrated with HDACi targeted to prostate cancer via antiandrogens that bind the AR. The second generation of improved “homing devices” is disclosed in Chapter 6 (for both AuNPs and HDACi), in addition to preliminary ADMET data and safety studies in mice. Excitingly, our three dimensional understanding of binding to the AR allowed design and structure-activity-relationship studies that lead to the first reported examples of AR inverse agonists (Chapter 7) Several points of significance: • AuNP targeted to AR ∙ have the strongest binding affinity ever reported (IC50 ~14 picomolar) ∙ are actively recruited to prostate cancer cells ∙ overcome treatment resistance in advanced prostate cancer cells ∙ exhibit nanomolar anticancer potency ∙ resolved the identity of the “membrane AR” as the GPRC6A • HDACi targeted to AR ∙ have HDACi activity and AR binding affinity superior to their clinical precursors ∙ exhibit potent AR antagonist activity ∙ induce AR translocation to the nucleus in a HDACi dependent fashion ∙ selectively and potently kill prostate cancer cells that express AR ∙ are safer than Tylenol®, as tested in small animals • Pure AR binding ligand studies ∙ resulted in the discovery of the first examples of AR inverse agonists, which are vastly more potent that clinically available antiandrogens for prostate cancer ∙ work via a never-before-seen mechanism of action, by localizing to the nucleus and recruiting corepressors to actively shut off AR genes Gold nanoparticle (AuNP) Epigenetics Anticancer Small molecules Histone deacetylase inhibitors (HDACi) Androgen receptor (AR) Prostate cancer
96	Epigenetic modifiers of transgene silencing in the mouse Daniel Morgan Unknown Date (has links) It is well established that epigenetic modifications to the genome are crucial for the exquisite control of gene expression required for an organism to develop and differentiate. These modifications are maintained through mitotic rounds of cell division, but must be cleared and reset through meiosis in order for the cells of the early embryo to achieve totipotency. Although we know these mechanisms exist, the rules determining which modifications are established where on the genome and the genes involved in these processes remain poorly characterised. Much of what is known about epigenetic processes has come from studies in non-mammalian organisms, such as Drosophila. However, in our laboratory we have developed a mammalian system for identifying modifiers of epigenetic gene silencing. An ENU mutagenesis screen is being carried out using an inbred mouse line carrying a GFP transgene, with an erythroid-specific promoter, that is particularly sensitive to changes in epigenetic modifications. Currently, 14 mutant lines that display a heritable shift in GFP expression have been recovered. These have been termed Modifiers of Murine Metastable Epialleles (Mommes). When I began my PhD in 2005, we had not identified any of the mutations underlying the phenotypes observed. To confirm the efficacy of the screen, I have tested the effect of heterozygosity for null alleles of two known epigenetic modifiers, Dnmt3a and Dnmt3b, on expression of the GFP transgene. Heterozygosity for the Dnmt3b knockout allele does shift expression while heterozygosity for the Dnmt3a knockout allele does not. This highlights the limitations of the screen. With this particular screen we will only detect modifiers that are expressed during haematopoiesis in the bone marrow. I have also worked on MommeD5. MommeD5 is a semi-dominant, homozygous embryonic lethal mutation that acts as an enhancer of variegation. I have found that the MommeD5 allele carries a 7 bp deletion in the major histone deacetylase, Histone deacetylase 1 (Hdac1), and this significantly alters the C-terminus of the mutant protein. The finding of Hdac1 attests to the screen design. The MommeD5 homozygous mutants die at approximately the same time as the published knockout of Hdac1 and the heterozygous mutants show increased levels of Hdac2 and acetylated histone H3, as reported in Hdac1-deficient embryonic stem cells. In addition, I have studied the effect of heterozygosity for each of the mutations on the phenotype of the mouse. In general, heterozygous Momme mutants are viable and fertile, but show subtle abnormal phenotypes. However, in the case of MommeD5 none were observed and this may relate to the compensatory upregulation of other histone deacetylases. In the case of Dnmt3a and Dnmt3b a sex ratio distortion is seen in the colonies, with less males seen than expected. Also, Dnmt3a heterozygous mutant males that inherited the mutant allele from the dam are smaller and show an increased range of body weights compared to their wild-type male littermates. This may be an example of intangible variation, i.e. phenotypic variation observed in isogenic individuals raised in standardised environments. These results suggest that epigenetic mechanisms have a role in intangible variation, also known as developmental noise. Despite the fact that it is now acknowledged by many that stochastic events occur at the level of the cell, the idea that it can happen at the level of the whole organism is rarely considered.
97	I: Study of protein-carbohydrate interaction on carbohydrate arrays II: Synthesis of analogues of sphingosine base, nitric oxide donors and HDAC inhibitors / Huang, Mingchuan, January 2007 (has links) Thesis (Ph. D.)--Ohio State University, 2007. / Title from first page of PDF file. Includes bibliographical references (p. 134-148).
98	p21-activated kinase a novel therapeutic target In thyroid cancer / Porchia, Leonardo Martin. January 2007 (has links) Thesis (Ph. D.)--Ohio State University, 2007. / Title from first page of PDF file. Includes bibliographical references (p. 140-172).
99	Epigenetic crosstalk between DNA demethylation and histone acetylation Ou, Jing-Ni. January 1900 (has links) Thesis (Ph.D.). / Written for the Dept. of Pharmacology & Therapeutics. Title from title page of PDF (viewed 2009/06/10). Includes bibliographical references.
100	Class I Lysine Deacetylases Facilitate Glucocorticoid-Mediated Gene Activation and Repression Patrick, Nina M. January 2015 (has links) Lysine acetyltransferases (KATs) and lysine deacetylases (KDACs) are known to cooperate with the glucocorticoid receptor (GR) to regulate transcription. The current model of GR-mediated transcription classifies KATs as coactivators as they acetylate histones to form an open chromatin conformation and casts KDACs as corepressors that deacetylate histones and condense chromatin. Our recent studies have challenged this long-standing model. In the current study, we show that KDACs act as versatile coregulators, facilitating both the onset and maintenance of GC-induced transcriptional activation and repression. Through siRNA depletion studies, we define KDAC1 as the predominant Class I KDAC for efficient transactivation of a majority of the GR-target genes tested. KDACs 1 and 2 co-operate with each other to activate and repress a few target genes, however KDAC2 alone is not sufficient for activation or repression of the genes, thus questioning the functional redundancy of KDACs 1 and 2. Additionally, we found that there is a unique population of KDAC2 that does not associate with KDAC1 in our cell line. Through a series of siRNA depletion studies, steroid receptor coactivator proteins (SRCs) were shown to be dispensable for GC-induced gene activation and SRC2 was not required for Dex-induced transcriptional repression. We performed ChIP assays to address the mechanism by which Class I KDACs facilitate transactivation and transrepression. At GC-activated genes we found that KDACs are constitutively present at the gene enhancers and that KDAC inhibition does not affect the binding of GR or SRC proteins to chromatin. However, KDACs do influence the histone methylation status of H3K4 at GREs of activated genes and TSSs of repressed genes. To explain the change in the methylation status of this marker, we depleted LSD1, the specific demethylase for mono- and demethylation of H3K4, and found that LSD1 action is required for GC-mediated transrepression. However it is unlikely that KDAC inhibition impairs GR transactivation through effects on LSD1. Glucocorticoid signaling regulates multiple vital biological processes. Glucocorticoids play a major role in regulating carbohydrate, protein and lipid metabolism. They increase hepatic gluconeogenesis to maintain blood glucose concentration in the fasting state. GCs also act as potent anti-inflammatory molecules, stimulate lung maturation in the developing fetus, and affect bone metabolism. Additionally, excess or deficiency of GCs can lead to a variety of psychological abnormalities, indicating their role in CNS functions. Our results indicate that pharmaceutical modulation of KDACs may impair proper glucocorticoid signaling and disrupt vital biological processes. Other steroid hormone receptors function similarly to GR in regulating gene expression and could also be impacted by KDAC inhibition, thus suggesting serious physiological implications in patients. Therefore, the possibility of endocrine modulation should be taken into account when using KDAC inhibitors in the clinic. Gene Activation Gene Repression Glucocorticoid Receptor KDAC LSD1 Pharmaceutical Sciences Deacetylase

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